Glossary of cellular and molecular biology (M–Z) (this page) lists terms beginning with the letters M through Z.
This glossary is intended as introductory material for novices (for more specific and technical detail, see the article corresponding to each term). It has been designed as a companion to Glossary of genetics and evolutionary biology, which contains many overlapping and related terms; other related glossaries include Glossary of virology and Glossary of chemistry.
Any very large molecule composed of dozens, hundreds, or thousands of covalently bonded atoms, especially one with biological significance. Many important biomolecules, such as nucleic acids and proteins, are polymers consisting of a repeated series of smaller monomers; others such as lipids and carbohydrates may not be polymeric but are nevertheless large and complex molecules.
Any of a class of relatively long-lived phagocytic cells of the mammalian immune system which are activated in response to the presence of foreign materials in certain tissues and subsequently play important roles in antigen presentation, stimulating other types of immune cells, and killing or engulfing parasitic microorganisms, diseased cells, or tumor cells.[3]
The branch of medicine and medical science that involves the study, diagnosis, and management of hereditary disorders, and more broadly the application of knowledge about human genetics to medical care.
A specialized type of cell division that occurs exclusively in sexually reproducingeukaryotes, during which DNA replication is followed by two consecutive rounds of division to ultimately produce four genetically unique haploid daughter cells, each with half the number of chromosomes as the original diploid parent cell. Meiosis only occurs in cells of the sex organs, and serves the purpose of generating haploid gametes such as sperm, eggs, or spores, which are later fused during fertilization. The two meiotic divisions, known as Meiosis I and Meiosis II, may also include various genetic recombination events between homologous chromosomes.
A supramolecular aggregate of amphipathiclipid molecules which when suspended in a polar solvent tend to arrange themselves into structures which minimize the exposure of their hydrophobic tails by sheltering them within a ball created by their own hydrophilic heads (i.e. a micelle). Certain types of lipids, specifically phospholipids and other membrane lipids, commonly occur as double-layered sheets of molecules when immersed in an aqueous environment, which can themselves assume approximately spherical shapes, acting as semipermeable barriers surrounding a water-filled interior space. This is the basic layout used for the biological membranes enclosing all cells, vesicles, and membrane-bound organelles.
The structure of a typical mature protein-coding messenger RNAormRNA, drawn approximately to scale. The coding sequence (green) is bounded by untranslated regions at both the 5'-end (yellow) and the 3'-end (pink). Prior to export from the nucleus, a 5' cap (red) and a 3' poly(A) tail (black) are added to help stabilize the mRNA and prevent its degradation by ribonucleases.
The complete set of chemical reactions which sustain and account for the basic processes of life in all living cells,[2] especially those involving: 1) the conversion of energy from food into energy available for cellular activities; 2) the breakdown of food into simpler compounds which can then be used as substrates to build complex biomolecules such as proteins, lipids, and nucleic acids; and 3) the degradation and excretion of toxins, byproducts, and other unusable compounds known as metabolic wastes. In a broader sense the term may include all chemical reactions occurring in living organisms, even those which are not strictly necessary for life but instead serve accessory functions. Many specific cellular activities are accomplished by metabolic pathways in which one chemical is ultimately transformed through a stepwise series of reactions into another chemical, with each reaction catalyzed by a specific enzyme. Most metabolic reactions can be subclassified as catabolicoranabolic.
An intermediate or end product of metabolism, especially degradative metabolism (catabolism);[2] or any substance produced by or taking part in a metabolic reaction. Metabolites include a huge variety of small molecules generated by cells from various pathways and having various functions, including as inputs to other pathways and reactions, as signaling molecules, and as stimulators, inhibitors, and cofactorsofenzymes. Metabolites may result from the degradation and elimination of naturally occurring compounds as well as of pharmaceutical compounds.
(of a linear chromosome or chromosome fragment) Having a centromere positioned in the middle of the chromosome, resulting in chromatid arms of approximately equal length.[5]
The covalent attachment of a methyl group (–CH 3) to a chemical compound, protein, or other biomolecule, either spontaneously or by enzymatic catalysis. Methylation is one of the most widespread natural mechanisms by which nucleic acids and proteins are labelled. The methylation of nucleobases in a DNA molecule inhibits recognition of the methylated sequence by DNA-binding proteins, which can effectively silence the expression of genes. Specific amino acidsinhistones are also commonly methylated, which can change nucleosome positioning and similarly activate or repress nearby loci. Contrast demethylation.
Any of a class of transferaseenzymes which catalyze the covalent bonding of a methyl group (–CH 3) to another compound, protein, or biomolecule, a process known as methylation.
A group that "aims to provide a standard for the representation of DNA microarraygene expression data that would facilitate the exchange of microarray information between different data systems".[6]
Any of a diverse class of small membrane-bound organellesorvesicles found in the cells of many eukaryotes, especially plants and animals, usually having some specific metabolic function and occurring in great numbers in certain specialized cell types. Peroxisomes, glyoxysomes, glycosomes, and hydrogenosomes are often considered microbodies.
Achromosomaldeletion that is too short to cause any apparent change in morphology under a light microscope, though it may still be detectable with other methods such as sequencing.
A long, thin, flexible, rod-like structure composed of polymeric strands of proteins, usually actins, that occurs in abundance in the cytoplasm of eukaryotic cells, forming part of the cytoskeleton. Microfilaments comprise the cell's structural framework. They are modified by and interact with numerous other cytoplasmic proteins, playing important roles in cell stability, motility, contractility, and facilitating changes in cell shape, as well as in cytokinesis.
The smaller of the two types of nuclei that occur in pairs in the cells of some ciliated protozoa. Whereas the larger macronucleusispolyploid, the micronucleus is diploid and generally transcriptionally inactive except for the purpose of sexual reproduction, where it has important functions during conjugation.[2]
Also short tandem repeat (STR)orsimple sequence repeat (SSR).
A type of satellite DNA consisting of a relatively short sequenceoftandem repeats, in which certain motifs (ranging in length from one to six or more bases) are repeated, typically 5–50 times. Microsatellites are widespread throughout most organisms' genomes and tend to have higher mutation rates than other regions. They are classified as variable number tandem repeat (VNTR) DNA, along with longer minisatellites.
The centrally constricted region that forms across the central axis of a cell during cell division, constricted by the closing of the contractile ring until the daughter cells are finally separated.[2]
In plant cells, the outermost layer of the cell wall; a continuous, unified layer of extracellular pectins which is the first layer deposited by the cell during cytokinesis and which serves to cement together the primary cell walls of adjacent cells.[4]
An incorrect pairingofnucleobasesoncomplementarystrandsofDNAorRNA; i.e. the presence in one strand of a duplex molecule of a base that is not complementary (by Watson–Crick pairing rules) to the base occupying the corresponding position in the other strand, which prevents normal hydrogen bonding between the bases. For example, a guanine paired with a thymine would be a mismatch, as guanine normally pairs with cytosine.[10]
The insertion of an incorrect amino acid in a growing peptide chain during translation, i.e. the inclusion of any amino acid that is not the one specified by a particular codon in an mRNA transcript. Mistranslation may originate from a mischargedtransfer RNA or from a malfunctioning ribosome.[10]
The selective degradation of mitochondria by means of autophagy; i.e. the mitochondrion initiates its own degradation. Mitophagy is a regular process in healthy populations of cells by which defective or damaged mitochondria are recycled, preventing their accumulation. It may also occur in response to the changing metabolic needs of the cell, e.g. during certain developmental stages.
Ineukaryotic cells, the part of the cell cycle during which the division of the nucleus takes place and replicated chromosomes are separated into two distinct nuclei. Mitosis is generally preceded by the S phaseofinterphase, when the cell's DNA is replicated, and either occurs simultaneously with or is followed by cytokinesis, when the cytoplasm and plasma membrane are divided into two new daughter cells. Colloquially, the term "mitosis" is often used to refer to the entire process of cell division, not just the division of the nucleus.
The proportion of cells within a sample which are undergoing mitosis at the time of observation, typically expressed as a percentage or as a value between 0 and 1. The number of cells dividing by mitosis at any given time can vary widely depending on organism, tissue, developmental stage, and culture media, among other factors.[2]
The abnormal exchange of genetic material between homologous chromosomes during mitosis (as opposed to meiosis, where it occurs normally). Homologous recombination during mitosis is relatively uncommon; in the laboratory, it can be induced by exposing dividing cells to high-energy electromagnetic radiation such as X rays. As in meiosis, it can separate heterozygous alleles and thereby propagate potentially significant changes in zygosity to daughter cells, though unless it occurs very early in development this often has little or no phenotypic effect, since any phenotypic variance shown by mutant lineages arising in terminally differentiated cells is generally masked or compensated for by neighboring wild-type cells.[2]
The presence of more than one different ploidy level, i.e. more than one number of sets of chromosomes, in different cells of the same cellular population.[10]
The branch of biology that studies biological activity at the molecular level, in particular the various mechanisms underlying the biological processes that occur in and between cells, including the structures, properties, synthesis, and modification of biomolecules such as proteins and nucleic acids, their interactions with the chemical environment and with other biomolecules, and how these interactions explain the observations of classical biology (which in contrast studies biological systems at much larger scales).[11] Molecular biology relies largely on laboratory techniques of physics and chemistry to manipulate and measure microscopic phenomena. It is closely related to and overlaps with the fields of cell biology, biochemistry, and molecular genetics.
Any of various molecular biology methods designed to replicate a particular molecule, usually a DNAsequence, many times inside the cells of a natural host. Commonly, a recombinant DNA fragment containing a gene of interestisligated into a plasmidvector, which competent bacterial cells are then induced to uptake in a process known as transformation. The bacteria, carrying the recombinant plasmid, are then allowed to proliferate naturally in cell culture, so that each time the bacterial cells divide, the plasmids are replicated along with the rest of the bacterial genome. Any functioning gene of interest will be expressed by the bacterial cells, and thereby its gene products will also be cloned. The plasmids or gene products, which now exist in many copies, may then be extracted from the bacteria and purified. Molecular cloning is a fundamental tool of genetic engineering which is employed for a wide variety of purposes, often to study gene expression, to amplify a specific gene product, or to generate a selectable phenotype.
Describing cells, proteins, or molecules descended or derived from a single clone (i.e. from the same genome or genetic lineage) or made in response to a single unique compound. Monoclonal antibodies are raised against only one antigen or can only recognize one unique epitope on the same antigen. Similarly, the cells of some tissues and neoplasms may be described as monoclonal if they are all the asexual progeny of one original parent cell.[2] Contrast polyclonal.
Amoleculeorcompound which can exist individually or serve as a building block or subunit of a larger macromolecular aggregate known as a polymer.[4] Polymers form when multiple monomers of the same or similar molecular species are connected to each other by chemical bonds, either in a linear chain or a non-linear conglomeration. Examples include the individual nucleotides which form nucleic acid polymers; the individual amino acids which form polypeptides; and the individual proteins which form protein complexes.
A synthetic nucleic acid analogue connecting a short sequence of nucleobases into an artificial antisenseoligomer, used in genetic engineeringtoknockdowngene expressionbypairing with complementary sequences in naturally occurring RNA or DNA molecules, especially mRNA transcripts, thereby inhibiting interactions with other biomolecules such as proteins and ribosomes. Morpholino oligomers are not themselves translated, and neither they nor their hybrid duplexes with RNA are attacked by nucleases; also, unlike the negatively charged phosphates of normal nucleic acids, the synthetic backbones of Morpholinos are electrically neutral, making them less likely to interact non-selectively with a host cell's charged proteins. These properties make them useful and reliable tools for artificially generating mutant phenotypes in living cells.[10]
The presence of two or more populations of cells with different genotypes in an individual organism which has developed from a single fertilized egg. A mosaic organism can result from many kinds of genetic phenomena, including nondisjunction of chromosomes, endoreduplication, or mutations in individual stem cell lineages during the early development of the embryo. Mosaicism is similar to but distinct from chimerism.
Any protein which converts chemical energy derived from the hydrolysis of nucleoside triphosphates such as ATP and GTP into mechanical work in order to effect its own locomotion, by propelling itself along a filament or through the cytoplasm.[4]
Composed of more than one cell. The term is especially used to describe organisms or tissues consisting of many cells descendant from the same original parent cell which work together in an organized way, but may also describe colonies of nominally single-celled organisms such as protists and bacteria which live symbiotically with each other in large groups. Contrast unicellular.
Any physical or chemical agent that changes the genetic material (usually DNA) of an organism and thereby increases the frequency of mutations above natural background levels.
1. The process by which the genetic information of an organism is changed, resulting in a mutation. Mutagenesis may occur spontaneously or as a result of exposure to a mutagen.
2. Inmolecular biology, any laboratory technique by which one or more genetic mutations are deliberately engineered in order to produce a mutant gene, regulatory element, gene product, or genetically modified organism so that the functions of a genetic locus, process, or product can be studied in detail.
Any permanent change in the nucleotide sequence of a strand of DNAorRNA, or in the amino acid sequence of a peptide. Mutations play a role in both normal and abnormal biological processes; their natural occurrence is integral to the process of evolution. They can result from errors in replication, chemical damage, exposure to high-energy radiation, or manipulations by mobile genetic elements. Repair mechanisms have evolved in many organisms to correct them. By understanding the effect that a mutation has on phenotype, it is possible to establish the function of the gene or sequence in which it occurs.
One of two possible orientations by which a linear DNA fragment can be inserted into a vector, specifically the one in which the gene maps of both fragment and vector have the same orientation.[10] Contrast u orientation.
In the process of being synthesized; incomplete; not yet fully processed or mature. The term is commonly used to describe strandsofDNAorRNA which are actively undergoing synthesis during replicationortranscription, respectively, or sometimes a complete, fully transcribed RNA molecule before any alterations have been made (e.g. polyadenylationorRNA editing), or a peptide chain actively undergoing translation by a ribosome.[10]
Any amino acid, natural or artificial, that is not one of the 20 or 21 proteinogenic amino acids encoded by the standard genetic code. There are hundreds of such amino acids, many of which have biological functions and are specified by alternative codes or incorporated into proteins accidentally by errors in translation. Many of the best known naturally occurring ncAAs occur as intermediates in the metabolic pathways leading to the standard amino acids, while others have been made synthetically in the laboratory.[13]
Any segment of DNA that does not encode a sequence that may ultimately be transcribed and translated into a protein. In most organisms, only a small fraction of the genome consists of protein-coding DNA, though the proportion varies greatly between species. Some non-coding DNA may still be transcribed into functional non-coding RNA (as with transfer RNAs) or may serve important developmental or regulatory purposes; other regions (as with so-called "junk DNA") appear to have no known biological function.
Any molecule of RNA that is not ultimately translated into a protein. The DNA sequence from which a functional non-coding RNA is transcribed is often referred to as an "RNA gene". Numerous types of non-coding RNAs essential to normal genome function are produced constitutively, including transfer RNA (tRNA), ribosomal RNA (rRNA), microRNA (miRNA), and small interfering RNA (siRNA); other non-coding RNAs (sometimes described as "junk RNA") have no known function and are likely the product of spurious transcription.
A type of point mutation which results in a premature stop codon in the transcribedmRNA sequence, thereby causing the premature termination of translation, which results in a truncated, incomplete, and often non-functional protein.
Also nonsynonymous substitutionorreplacement mutation.
A type of mutation in which the substitution of one nucleotide base for another results, after transcription and translation, in an amino acid sequence that is different from that produced by the original unmutated gene. Because nonsynonymous mutations always result in a biological change in the organism, they are often subject to strong selection pressure. Contrast synonymous mutation.
The end of a linear chain of amino acids (i.e. a peptide) that is terminated by the free amine group (–NH 2) of the first amino acid added to the chain during translation. This amino acid is said to be N-terminal. By convention, sequences, domains, active sites, or any other structure positioned nearer to the N-terminus of the polypeptide or the folded protein it forms relative to others are described as upstream. Contrast C-terminus.
Any DNA molecule contained within the nucleus of a eukaryotic cell, most prominently the DNA in chromosomes. It is sometimes used interchangeably with genomic DNA.
A sub-cellular barrier consisting of two concentric lipid bilayermembranes that surrounds the nucleusineukaryotic cells. The nuclear envelope is sometimes simply called the "nuclear membrane", though the structure is actually composed of two distinct membranes, an inner membrane and an outer membrane.
The principle that the nuclei of essentially all differentiated cells of a mature multicellular organism are genetically identical to each other and to the nucleus of the zygote from which they descended; i.e. they all contain the same genetic information on the same chromosomes, having been replicated from the original zygotic set with extremely high fidelity. Even though all adult somatic cells have the same set of genes, cells can nonetheless differentiate into distinct cell types by expressing different subsets of these genes. Though this principle generally holds true, the reality is slightly more complex, as mutations such as insertions, deletions, duplications, and translocations as well as chimerism, mosaicism, and various types of genetic recombination can all cause different somatic lineages within the same organism to be genetically non-identical.
A fibrous network of proteins lining the inner, nucleoplasmic surface of the nuclear envelope, composed of protein filaments similar to those that make up the cytoskeleton. It may function as a scaffold for the various contents of the nucleus such as nuclear proteins and chromosomes.[3]
Anamino acid sequence within a protein which serves as a molecular signal marking the protein for transport into the nucleus, typically consisting of one or more short motifs containing positively charged amino acids exposed on the mature protein's surface (especially lysines and arginines). Though all proteins are translated in the cytoplasm, many whose primary biological activities occur inside the nucleus, e.g. transcription factors, require nuclear localization signals identifiable by molecular chaperones in order to cross the nuclear envelope. Contrast nuclear export signal.
A complex of membrane proteins that creates an opening in the nuclear envelope through which certain molecules and ions are permitted to pass in order to cross the envelope and thus enter or exit the nucleus (analogous to the channel proteins in the cell membrane). The nuclear envelope typically has thousands of pores, which selectively regulate the exchange of specific materials between the nucleoplasm and the cytoplasm, including nuclear proteins, which are synthesized in the cytoplasm but function in the nucleus, as well as messenger RNAs, which are transcribed in the nucleus but must be translated in the cytoplasm.[4][3]
Any RNA molecule located within a cell's nucleus, whether associated with chromosomes or existing freely in the nucleoplasm, including small nuclear RNA (snRNA), enhancer RNA (eRNA), and all newly transcribed immature RNAs, codingornon-coding, prior to their export to the cytosol (hnRNA).
The mechanisms by which molecules cross the nuclear envelope surrounding a cell's nucleus. Though small molecules and ions can cross the membrane freely, the entry and exit of larger molecules is tightly regulated by nuclear pores, so that most macromolecules such as RNAs and proteins require association with transport factors in order to be chaperoned across.
Any of a class of enzymes capable of cleaving phosphodiester bonds connecting adjacent nucleotides in a nucleic acid molecule (the opposite of a ligase). Nucleases may nick oneorcut bothstrands of a duplex molecule, and may cleave randomly or at specific recognition sequences. They are ubiquitous and imperative for normal cellular function, and are also widely employed in laboratory techniques.
A long, polymericmacromolecule made up of smaller monomers called nucleotides which are chemically linked to one another in a chain. Two specific types of nucleic acid, DNA and RNA, are common to all living organisms, serving to encode the genetic information governing the construction, development, and ordinary processes of all biological systems. This information, contained within the order or sequence of the nucleotides, is translated into proteins, which direct all of the chemical reactions necessary for life.
The precise order of consecutively linked nucleotides in a nucleic acid molecule such as DNAorRNA. Long sequences of nucleotides are the principal means by which biological systems store genetic information, and therefore the accurate replication, transcription, and translation of such sequences is of the utmost importance, lest the information be lost or corrupted. Nucleic acid sequences may be equivalently referred to as sequences of nucleotides, nitrogenous bases, nucleobases, or, in duplex molecules, base pairs, and they correspond directly to sequences of codons and amino acids.
Sometimes used interchangeably with nitrogenous base or simply base.
Any of the five primary or canonical nitrogenous bases – adenine (A), guanine (G), cytosine (C), thymine (T), and uracil (U) – that form nucleosides and nucleotides, the latter of which are the fundamental building blocks of nucleic acids. The ability of these bases to form base pairs via hydrogen bonding, as well as their flat, compact three-dimensional profiles, allows them to "stack" one upon another and leads directly to the long-chain structures of DNA and RNA. When writing sequences in shorthand notation, the letter N is often used to represent a nucleotide containing a generic or unidentified nucleobase.
An irregularly shaped region within a prokaryotic cell which contains most or all of the cell's genetic material, but is not enclosed by a nuclear membrane as in eukaryotes.
The basic structural subunit of chromatin used in packaging nuclear DNA such as chromosomes, consisting of a core particle of eighthistone proteins around which double-stranded DNA is wrapped in a manner akin to thread wound around a spool. The technical definition of a nucleosome includes a segment of DNA about 146 base pairs in length which makes 1.67 left-handed turns as it coils around the histone core, as well as a stretch of linker DNA (generally 38–80 bp) connecting it to an adjacent core particle, though the term is often used to refer to the core particle alone. Long series of nucleosomes are further condensed by association with histone H1 into higher-order structures such as 30-nm fibers and ultimately supercoiledchromatids. Because the histone–DNA interaction limits access to the DNA molecule by other proteins and RNAs, the precise positioning of nucleosomes along the DNA sequence plays a fundamental role in controlling whether or not genes are transcribed and expressed, and hence mechanisms for moving and ejecting nucleosomes have evolved as a means of regulating the expression of particular loci.
nucleosome-depleted region (NDR)
A region of a genome or chromosome in which long segments of DNA are bound by few or no nucleosomes, and thus exposed to manipulation by other proteins and molecules, especially implying that the region is transcriptionally active.
The nucleobases (blue) are the five specific nitrogenous bases canonically used in DNA and RNA. A nucleobase bonded to a pentose sugar (either riboseordeoxyribose; yellow) is known as a nucleoside (yellow + blue). A nucleoside bonded to a single phosphate group (red) is known as a nucleoside monophosphate (NMP) or a nucleotide (red + yellow + blue). When not incorporated into a nucleic acid chain, free nucleosides can bind multiple phosphate groups: two phosphates yields a nucleoside diphosphate (NDP), and three yields a nucleoside triphosphate (NTP).
A large spherical or lobular organelle surrounded by a dedicated membrane which functions as the main storage compartment for the genetic material of eukaryotic cells, including the DNA comprising chromosomes, as well as the site of RNA synthesis during transcription. The vast majority of eukaryotic cells have a single nucleus, though some cells may have more than one nucleus, either temporarily or permanently, and in some organisms there exist certain cell types (e.g. mammalian erythrocytes) which lose their nuclei upon reaching maturity, effectively becoming anucleate. The nucleus is one of the defining features of eukaryotes; the cells of prokaryotes such as bacteria lack nuclei entirely.[2]
Agene that has the potential to cause cancer. In tumor cells, such genes are often mutated and/or expressed at abnormally high levels.
one gene–one polypeptide
Also one gene–one proteinorone gene–one enzyme.
The hypothesis that there exists a large class of genes in which each particular gene directs the synthesis of one particular polypeptideorprotein.[10] Historically it was thought that all genes and proteins might follow this rule by definition, but it is now known that many or most proteins are composites of different polypeptides and therefore the product of multiple genes, and also that some genes do not encode polypeptides at all but instead produce non-coding RNAs, which are never translated.
A functional unit of gene expression consisting of a cluster of adjacent structural genes which are collectively under the control of a single promoter, along with one or more adjacent regulatory sequences such as operators which affect transcription of the structural genes. The set of genes is transcribed together, usually resulting in a single polycistronicmessenger RNA molecule, which may then be translated together or undergo splicing to create multiple mRNAs which are translated independently; the result is that the genes contained in the operon are either expressed together or not at all. Regulatory proteins, including repressors, corepressors, and activators, usually bind specifically to the regulatory sequences of a given operon; by some definitions, the genes that code for these regulatory proteins are also considered part of the operon.
A spatially distinct compartment or subunit within a cell which has a specific, specialized function. Organelles occur in both prokaryotic and eukaryotic cells. In the latter they are often separated from the cytoplasm by being enclosed with their own membranebilayer (whence the term membrane-bound organelles), though organelles may also be functionally specific areas or structures without a surrounding membrane; some cellular structures which exist partially or entirely outside of the cell membrane, such as cilia and flagella, are also referred to as organelles. There are numerous types of organelles with a wide variety of functions, including the various compartments of the endomembrane system (e.g. the nuclear envelope, endoplasmic reticulum, and Golgi apparatus), mitochondria, chloroplasts, lysosomes, endosomes, and vacuoles, among others. Many organelles are unique to particular cell types or species.
A particular location within a DNA molecule at which DNA replication is initiated. Origins are usually defined by the presence of a particular replicator sequence or by specific chromatin patterns.
An abnormally high level of gene expression which results in an excessive number of copies of one or more gene products. Overexpression produces a pronounced gene-related phenotype.[15][16]
Also Tumor protein P53 (TP53), transformation-related protein 53 (TRP53), and cellular tumor antigen p53.
A class of regulatory proteins encoded by the TP53 gene in vertebrates which bind DNA and regulate gene expression in order to protect the genome from mutation and block progression through the cell cycle if DNA damage does occur.[4] It is mutated in more than 50% of human cancers, indicating it plays a crucial role in preventing cancer formation.
Anucleic acid sequence of a double-stranded DNAorRNA molecule in which the unidirectional sequence (e.g. 5' to 3') of nucleotides on one strand matches the sequence in the same direction (e.g. 5' to 3') on the complementary strand. In other words, a nucleotide sequence is said to be palindromic if it is equal to its own reverse complement. Palindromic motifs are common in most genomes and are capable of forming hairpins.
The movement of a solute across a membrane by traveling down an electrochemical or concentration gradient, using only the energy stored in the gradient and not any energy from external sources.[3] Contrast active transport.
Any simple sugar or monosaccharide containing five carbon atoms. The compounds ribose and deoxyribose are both pentose sugars, which, in the form of cyclic five-membered rings, serve as the central structural components of the ribonucleotides and deoxyribonucleotides that make up RNA and DNA, respectively.
Any of a class of membrane proteins which attach only temporarily to the cell membrane, either by penetrating the lipid bilayer or by attaching to other proteins which are permanently embedded within the membrane.[17] The ability to reversibly interact with membranes makes peripheral membrane proteins important in many different roles, where they commonly function as regulatory subunitsofchannel proteins and cell surface receptors. Protein domains often undergo rearrangement, dissociation, or conformational changes when they interact with the membrane, resulting in the activation of their biological activity.[18]Inprotein purification, peripheral membrane proteins are typically more water-soluble and much easier to isolate from the membrane than integral membrane proteins.
1. The tendency of a moving cell to continue moving in the same direction as previously; that is, even in isotropic environments, there inevitably still exists an inherent bias by which, from instant to instant, cells are more likely not to change direction than to change direction. Averaged over long periods of time, however, this bias is less obvious and cell movements are better described as a random walk.[3]
2. The ability of some viruses to remain present and viable in cells, organisms, or populations for very long periods of time by any of a variety of strategies, including retroviral integration and immune suppression, often in a latent form which replicates very slowly or not at all.[3]
A shallow, transparent plastic or glass dish, usually circular and covered with a lid, which is widely used in biology laboratories to hold solid or liquid growth media for the purpose of culturing cells. They are particularly useful for adherent cultures, where they provide a flat, sterile surface conducive to colony formation from which scientists can easily isolate and identify particular colonies.
A type of cell which functions as part of the immune system by engulfing and ingesting harmful foreign molecules, bacteria, and dead or dying cells in a process known as phagocytosis.
The process by which foreign molecules, cells, and small particulate matter is engulfed and ingested via endocytosis by specialized cells known as phagocytes (a class which includes macrophages and neutrophils).[4]
A large, intracellular, membrane-bound vesicle formed as a result of phagocytosis and containing whatever previously extracellular material was engulfed during that process.[4]
The complete set of phenotypes that are or can be expressed by a genome, cell, tissue, organism, or species; the sum of all of its manifest chemical, morphological, and behavioral characteristics or traits.
phenomic lag
A delay in the phenotypicexpression of a genetic mutation owing to the time required for the manifestation of changes in the affected biochemical pathways.[12]
The composite of the observable morphological, physiological, and behavioral traits of an organism that result from the expression of the organism's genotype as well as the influence of environmental factors and the interactions between the two.
Also phosphodiester backbone, sugar–phosphate backbone, and phosphate–sugar backbone.
The linear chain of alternating phosphate and sugar compounds that results from the linking of consecutive nucleotides in the same strand of a nucleic acid molecule, and which serves as the structural framework of the nucleic acid. Each individual strand is held together by a repeating series of phosphodiester bonds connecting each phosphate group to the riboseordeoxyribose sugars of two adjacent nucleotides. These bonds are created by ligases and broken by nucleases.
A defining element of nucleic acid structure is the linear chain of alternating sugars (orange) and phosphates (yellow) known as the phosphate backbone, which acts as a scaffold to which nucleobases are attached. The phosphorus atom of each phosphate group forms two ester bonds to specific carbon atoms within the pentose sugars—ribose in RNA and deoxyribose in DNA—of two adjacent nucleosides.
A pair of ester bonds linking a phosphate molecule with the two pentose rings of consecutive nucleosides on the same strand of a nucleic acid. Each phosphate forms a covalent bond with the 3' carbon of one pentose and the 5' carbon of the adjacent pentose; the repeated series of such bonds that holds together a long chain of nucleotides in DNA and RNA molecules is known as the phosphate or phosphodiester backbone.
Any of a subclass of lipids consisting of a central alcohol (usually glycerol) covalently bonded to three functional groups: a negatively charged phosphate group, and two long fatty acid chains. This arrangement results in a highly amphipathic molecule which in aqueous solutions tends to aggregate with other, similar molecules in a lamellar or micellar conformation with the hydrophilic phosphate "heads" oriented outward, exposing them to the solution, and the hydrophobic fatty acid "tails" oriented inward, minimizing their interactions with water and other polar compounds. Phospholipids are the major structural membrane lipid in almost all biological membranes except the membranes of some plant cells and chloroplasts, where glycolipids dominate instead.[3]
Any of a class of membrane-bound organelles found in the cells of some eukaryotes such as plants and algae which are hypothesized to have evolved from endosymbioticcyanobacteria; examples include chloroplasts, chromoplasts, and leucoplasts. Plastids retain their own circular chromosomes which replicate independently of the host cell's genome. Many contain photosynthetic pigments which allow them to perform photosynthesis, while others have been retained for their ability to synthesize unique chemical compounds.
1. Variability in the size, shape, or staining of cells and/or their nuclei, particularly as observed in histology and cytopathology, where morphological variation is frequently an indicator of a cellular abnormality such as disease or tumor formation.
2. Inmicrobiology, the ability of some microorganisms such as certain bacteria and viruses to alter their morphology, metabolism, or mode of reproduction in response to changes in their environment.
The number of complete sets of chromosomes in a cell, and hence the number of possible alleles present within the cell at any given autosomal locus.
A cell's ploidy level is defined by the number of copies it has of each specific chromosome: if the cell has two copies of each of three distinct chromosomes, it is said to be diploid (2N).
The addition of a series of multiple adenosineribonucleotides, known as a poly(A) tail, to the 3'-end of a primary RNA transcript, typically a messenger RNA. A class of post-transcriptional modification, polyadenylation serves different purposes in different cell types and organisms. In eukaryotes, the addition of a poly(A) tail is an important step in the processing of a raw transcript into a mature mRNA, ready for export to the cytoplasm where translation occurs; in many bacteria, polyadenylation has the opposite function, instead promoting the RNA's degradation.
Describing cells, proteins, or molecules descended or derived from more than one clone (i.e. from more than one genome or genetic lineage) or made in response to more than one unique stimulus. Antibodies are often described as polyclonal if they have been produced or raised against multiple distinct antigens or multiple variants of the same antigen, such that they can recognize more than one unique epitope.[2] Contrast monoclonal.
Amacromolecule composed of multiple repeating subunitsormonomers; a chain or aggregation of many individual molecules of the same compound or class of compound.[2] The formation of polymers is known as polymerization and generally only occurs when nucleation sites are present and the concentration of monomers is sufficiently high.[3] Many of the major classes of biomolecules are polymers, including nucleic acids and polypeptides.
Any of a wide variety of molecular biology methods involving the rapid production of millions or billions of copies of a specific DNA sequence, allowing scientists to selectively amplify fragments of a very small sample to a quantity large enough to study in detail. In its simplest form, PCR generally involves the incubation of a target DNA sample of known or unknown sequence with a reaction mixture consisting of oligonucleotideprimers, a heat-stable DNA polymerase, and free deoxyribonucleotide triphosphates (dNTPs), all of which are supplied in excess. This mixture is then alternately heated and cooled to pre-determined temperatures for pre-determined lengths of time according to a specified pattern which is repeated for many cycles, typically in a thermal cycler which automatically controls the required temperature variations. In each cycle, the most basic of which includes a denaturation phase, annealing phase, and elongation phase, the copies synthesized in the previous cycle are used as templates for synthesis in the next cycle, causing a chain reaction that results in the exponential growth of the total number of copies in the reaction mixture. Amplification by PCR has become a standard technique in virtually all molecular biology laboratories.
The process by which polymers are created from their constituent monomers; a chemical reaction or series of reactions in which monomeric subunits are covalently linked together into a polymeric chain or three-dimensional structure; e.g. the polymerization of a nucleic acid chain by linking consecutive nucleotides, a reaction catalyzed by a polymerase.
A long, continuous, and unbranched polymeric chain of amino acidmonomers linked by covalent peptide bonds, typically longer than a peptide. Proteins generally consist of one or more polypeptides folded or arranged in a biologically functional way.
(of a cell or organism) Having more than two homologous copies of each chromosome; i.e. any ploidy level that is greater than diploid. Polyploidy may occur as a normal condition of chromosomes in certain cells or even entire organisms, or it may result from errors in cell division or mutations causing the duplication of the entire chromosome set.
The condition of a cell or organism having at least one more copy of a particular chromosome than is normal for its ploidy level, e.g. a diploid organism with three copies of a given chromosome is said to show trisomy. Every polysomy is a type of aneuploidy.
Any effect on the expression or functionality of a gene or sequence that is a consequence of its location or position within a chromosome or other DNA molecule. A sequence's precise location relative to other sequences and structures tends to strongly influence its activity and other properties, because different loci on the same molecule can have substantially different genetic backgrounds and physical/chemical environments, which may also change over time. For example, the transcription of a gene located very close to a nucleosome, centromere, or telomere is often repressed or entirely prevented because the proteins that make up these structures block access to the DNA by transcription factors, while the same gene is transcribed at a much higher rate when located in euchromatin. Proximity to promoters, enhancers, and other regulatory elements, as well as to regions of frequent transpositionbymobile elements, can also directly affect expression; being located near the end of a chromosomal arm or to common crossover points may affect when replication occurs and the likelihood of recombination. Position effects are a major focus of research in the field of epigenetic inheritance.
A strategy for identifying and cloningacandidate gene based on knowledge of its locus or position alone and with little or no information about its products or function, in contrast to functional cloning. This method usually begins by comparing the genomes of individuals expressing a phenotype of unknown provenance (often a hereditary disease) and identifying genetic markers shared between them. Regions defined by markers flanking one or more genes of interest are cloned, and the genes located between the markers can then be identified by any of a variety of means, e.g. by sequencing the region and looking for open reading frames, by comparing the sequence and expression patterns of the region in mutant and wild-type individuals, or by testing the ability of the putative gene to rescue a mutant phenotype.[10]
The unprocessed, single-stranded RNA molecule produced by the transcription of a DNA sequence as it exists before post-transcriptional modifications such as alternative splicing convert it into a mature RNA product such as an mRNA, tRNA, or rRNA. A precursor mRNAorpre-mRNA, for example, is a type of primary transcript that becomes a mature mRNA ready for translation after processing.
A short, single-strandedoligonucleotide, typically 5–100 bases in length, which "primes" or initiates nucleic acid synthesis by hybridizing to a complementary sequence on a template strand and thereby provides an existing 3'-end from which a polymerase can extend the new strand. Natural systems exclusively use RNA primers to initiate DNA replication and transcription, whereas the in vitro syntheses performed in many laboratory techniques such as PCR often use DNA primers. In modern laboratories, primers are carefully designed, often in "forward" and "reverse" pairs, to complement specific and unique sequences within genomic DNA, with consideration given to their melting and annealing temperatures, and then purchased from commercial suppliers which create oligonucleotides on demand by de novo synthesis.
Any reagent used to make a single measurement in a biochemical assay such as a gene expression experiment. Molecules which have a specific affinity for one or more other molecules may be used to probe for the presence of those other molecules in samples of unknown composition. Probes are often labelled or otherwise used as reporters to indicate whether or not a specific chemical reaction is taking place. See also hybridization probe.
probe-set
A collection of two or more probes designed to measure a single molecular species, such as a collection of oligonucleotides designed to hybridize to various parts of the mRNA transcripts generated from a single gene.
A sequence or region of DNA, usually 100–1,000 base pairs long, to which transcription factors bind in order to recruit RNA polymerase to the sequence and initiate the transcription of one or more genes. Promoters are located upstream of the genes they transcribe, near the transcription start site.
Any of a class of enzymes which catalyze proteolysis, i.e. the decomposition of proteins into smaller polypeptides or individual amino acids, by cleaving peptide bonds via hydrolysis. Proteases are ubiquitous components of numerous biological pathways, and therefore it is often necessary to inhibit them in order for laboratory techniques involving protein activity to be effective.
Apolymericmacromolecule composed of one or more long chainsofamino acids linked by peptide bonds. Proteins are the three-dimensional structures created when these chains fold into specific higher-order arrangements following translation, and it is this folded structure which determines a protein's chemical activity and hence its biological function. Ubiquitous and fundamental in all living organisms, proteins are the primary means by which the activities of life are performed, participating in the vast majority of the biochemical reactions that occur inside and outside of cells. They are often classified according to the type(s) of reaction(s) they facilitate or catalyze, by the chemical substrate(s) they act upon, or by their functional role in cellular activity; e.g. as structural proteins, motor proteins, enzymes, transcription factors, or links within biochemical pathways.
An assembly or aggregate of multiple proteins held together by intermolecular forces, especially one with a particular biological function. Complexes may include many of the same protein or all different proteins. Numerous cellular activities, including DNA replication, transcription, and translation, rely on protein complexes.[4]
Any of the 20 canonical amino acids which are encoded by the standard genetic code and incorporated into peptides and ultimately proteins during translation. The term may also be inclusive of an additional two amino acids encoded by non-standard codes which can be incorporated by special translation mechanisms.
The decomposition of proteins into their component polypeptides or individual amino acidsbycleaving the peptide bonds linking the amino acids together via hydrolysis. Proteolysis is an important reaction used not only for degrading and inactivating proteins but sometimes also to activate them by removing amino acid residues which inhibit their activity.[3] It is usually catalyzed by enzymes known as proteases.
The entire set of proteins that is or can be expressed by a particular genome, cell, tissue, or species at a particular time (such as during a single lifespan or during a specific developmental stage) or under particular conditions (such as when compromised by a certain disease).
The biological contents enclosed within a membrane-bound space, variously referring to the cytoplasm, or the cytoplasm and nucleoplasm considered collectively, and sometimes exclusive of vacuoles.
A plant, fungal, or bacterial cell which has had its cell wall removed by mechanical, chemical, or enzymatic means; or the complete contents (the protoplasm) of an intact cell excluding the cell wall.
A double-ringed heterocyclic organic compound which, along with pyrimidine, is one of two molecules from which all nitrogenous bases (including the nucleobases used in DNA and RNA) are derived. Adenine (A) and guanine (G) are classified as purines. The letter R is sometimes used to indicate a generic purine; e.g. in a nucleotide sequence read, R may be used to indicate that either purine nucleobase, AorG, can be substituted at the indicated position.
putative gene
A specific nucleotide sequence suspected to be a functional gene based on the identification of its open reading frame. The gene is said to be "putative" in the sense that no function has yet been described for its products.
The irreversible condensation of chromatin inside the nucleus as the cell undergoes necrosisorapoptosis, resulting in a compact mass which stains strongly and is conspicuous under a microscope.[10] It is followed by karyorrhexis.
A single-ringed heterocyclic organic compound which, along with purine, is one of two molecules from which all nitrogenous bases (including the nucleobases used in DNA and RNA) are derived. Cytosine (C), thymine (T), and uracil (U) are classified as pyrimidines. The letter Y is sometimes used to indicate a generic pyrimidine; e.g. in a nucleotide sequence read, Y may be used to indicate that either pyrimidine nucleobase – C, T, or U – can be substituted at the indicated position.
Acell culture in which there is little or no active cell growth or replication but in which the cells nonetheless continue to survive, as observed with some confluent cultures.[2]
A popular description of the path followed by a locomotive cell or particle when there is no bias in movement, i.e. when the direction of movement at any given instant is not influenced by the direction of movement in the preceding instant. The essential randomness of cell movement in a uniform environment is only apparent over long periods of time, however; in the short term, cells can and do exhibit a tendency to continue moving in the same direction.[3]
A way of dividing the nucleotide sequence in a DNAorRNA molecule into a set of consecutive, non-overlapping triplets, which is how the sequence is interpreted or "read" by proteins and ribosomes during translation. In coding DNA, each triplet is referred to as a codon and corresponds to a particular amino acid to be added to the nascent peptide during translation. In general, only one reading frame (the so-called open reading frame) in a given section of a nucleic acid can be used to make functional proteins, but there are exceptions in a few organisms. A frameshift mutation results in a shift in the normal reading frame and affects all downstream codons.
The measurement and manipulation of the rate of reannealingofcomplementary strands of DNA, generally by heating and denaturing a double-stranded molecule into single strands and then observing their rehybridization at a cooler temperature. Because the base pairG+C requires more energy to anneal than the base pair A+T, the rate of reannealing between two strands depends partly on their nucleotide sequence, and it is therefore possible to predict or estimate the sequence of the duplex molecule by the time it takes to fully hybridize. Reassociation kinetics is studied with C0t analysis: fragments reannealing at low C0t values tend to have highly repetitive sequences, while higher C0t values imply more unique sequences.[10]
A protein which initiates a cellular response to an external stimulus or propagates a molecular signal by binding a specific extracellular ligand, often a dedicated signaling molecule. Numerous types of receptors exist which serve an enormous variety of functions. Cell-surface receptors, such as those that bind acetylcholine and insulin, are embedded within the cell membrane with their binding sites exposed to the extracellular space; intracellular receptors, including many hormone receptors, are located in the cytoplasm, where they bind ligands that have diffused across the membrane and into the cell.[4]
A type of chromosomal translocation by which there is a reciprocal exchange of chromosome segments between two or more non-homologouschromosomes. When the exchange of material is evenly balanced, reciprocal translocations are usually harmless.
Any DNA molecule in which laboratory methods of genetic recombination have brought together genetic material from multiple sources, thereby creating a sequence that would not otherwise be found in a naturally occurring genome. Because DNA molecules from all organisms share the same basic chemical structure and properties, DNA sequences from any species, or even sequences created de novobyartificial gene synthesis, may be incorporated into recombinant DNA molecules. Recombinant DNA technology is widely used in genetic engineering.
The smallest unit of a DNA molecule capable of undergoing homologous recombination, i.e. a pair of consecutive nucleotides, adjacent to each other in cis.[10]
A group of non-contiguous genes which are regulated as a unit, generally by virtue of having their expression controlled by the same regulatory element or set of elements, e.g. the same repressororactivator. The term is most commonly used with prokaryotes, where a regulon may consist of genes from multiple operons.
1. The process by which certain biological molecules, notably the nucleic acidsDNA and RNA, produce copies of themselves.
2. A technique used to estimate technical and biological variation in experiments for statistical analysisofmicroarray data. Replicates may be technical replicates, such as dye swaps or repeated array hybridizations, or biological replicates, biological samples from separate experiments which are used to test the effects of the same experimental treatment.
The eye-shaped structure that forms when a pair of replication forks, each growing away from the origin, separates the strands of the double helix during DNA replication.
The point at which the paired strands of a double-stranded DNA molecule are separated by helicase during DNA replication, breaking the hydrogen bonds between the complementary strands and thereby forming a structure with two branching single strands of DNA. Once unpaired, these strands serve as templates from which DNA polymerase synthesizes the leading strand and lagging strand. As replication proceeds, helicase moves along the DNA and continues to separate the strands, causing the replication fork to move as well.[3] A pair of replication forks forms when helicases work in opposite directions from a single origin of replication, creating a replication eye.
replication rate
The speed at which deoxyribonucleotides are incorporated into an elongating chain by DNA polymerases during DNA replication; or more generally the speed at which any chromosome, genome, cell, or organism makes a complete, independently functional copy of itself.
The entire complex of molecular machinery that carries out the process of DNA replication, including all proteins, nucleic acids, and other molecules which participate at an active replication fork.
reporter
AnMIAME-compliant term to describe a reagent used to make a single measurement in a gene expression experiment. MIAME defines it as "the nucleotide sequence present in a particular location on the array".[8] A reporter may be a segment of single-stranded DNA that is covalently attached to the array surface. See also probe.
The restoration of a defective cell or tissue to a healthy or normal condition,[10] or the reversion or recovery of a mutant gene to its normal functionality, especially in the context of experimental genetics, where an experiment (e.g. a drug, cross, or gene transfer) resulting in such a restoration is said to rescue the normal phenotype.
The spontaneous rejoining of an experimentally broken chromosome which restores the original configuration.
restitution nucleus
Anucleus containing twice the expected number of chromosomes owing to an error in cell division, especially an unreduced, diploid product of meiosis resulting from the failure of the first or second meiotic division.
Also restriction endonuclease, restriction exonuclease, or restrictase.
Anendonucleaseorexonucleaseenzyme that recognizes and cleaves a nucleic acid molecule into fragments at or near specific recognition sequences known as restriction sites by breaking the phosphodiester bonds of the nucleic acid backbone. Restriction enzymes are naturally occurring in many organisms, but are also routinely used for artificial modification of DNA in laboratory techniques such as restriction cloning.
A diagram of known restriction sites within a known DNA sequence, such as a plasmidvector, obtained by systematically exposing the sequence to various restriction enzymes and then comparing the lengths of the resulting fragments, a technique known as restriction mapping. See also gene map.
A short, specific sequence of nucleotides (typically 4 to 8 bases in length) that is reliably recognized by a particular restriction enzyme. Because restriction enzymes usually bind as homodimers, restriction sites are generally palindromic sequences spanning both strands of a double-stranded DNA molecule. Restriction endonucleases cleave the phosphate backbone between two nucleotides within the recognized sequence itself, but other types of restriction enzymes make their cuts at one end of the sequence or at a nearby sequence.
An experimental approach in molecular genetics in which a researcher starts with a known gene and attempts to determine its function or its effect on phenotype by any of a variety of laboratory techniques, commonly by deliberately mutating the gene's nucleic acid sequence or by repressing or silencing its expression and then screening the mutated organisms for obvious changes in phenotype. When the gene of interest is the only one in the genome whose expression has been manipulated, any observed phenotypic changes are assumed to be influenced by it. This is the opposite of forward genetics, in which a known phenotype is linked to one or more unknown genes.
Apolymericnucleic acid molecule composed of a series of ribonucleotides which incorporate a set of four nucleobases: adenine (A), guanine (G), cytosine (C), and uracil (U). Unlike DNA, RNA is more often found as a single strand folded onto itself, rather than a paired double strand. Various types of RNA molecules serve in a wide variety of essential biological roles, including coding, decoding, regulating, and expressinggenes, as well as functioning as signaling molecules and, in certain viral genomes, as the primary genetic material itself.
Amonosaccharide sugar which, as D-ribose in its pentose ring form, is one of three primary components of the ribonucleotides from which ribonucleic acid (RNA) molecules are built. Ribose differs from its structural analog deoxyribose only at the 2' carbon, where ribose has an attached hydroxyl group that deoxyribose lacks.
A DNA sequence that codes for ribosomal RNA (rRNA). In many eukaryotic genomes, rDNA occupies large, highly conserved regions of multiple chromosomes and is rich in both genes and repeats.
A type of non-coding RNA which is found in and is the primary constituent of ribosomes, binding to ribosomal proteins to form the small and large subunits. It is ribosomal RNA which enables ribosomes to perform protein synthesis by working as a ribozyme that catalyzes the set of reactions comprising translation. Ribosomal RNA is transcribed from the corresponding ribosomal DNA (rDNA), and is the predominant form of RNA found in most cells, effecting the translation of all encoded proteins despite never being translated itself.
A macromolecular complex made of both RNA and protein which serves as the site of protein synthesis. Ribosomes have two subunits, each of which consists of one or more strands of ribosomal RNA bound to various ribosomal proteins: the small subunit, which reads the messages encoded in messenger RNA molecules, and the large subunit, which links amino acids in sequence to form a polypeptide chain. Ribosomes are fundamental and ubiquitous in all cell types and are used by all known forms of life.
AnRNA molecule with enzymatic activity,[4] i.e. one that is capable of catalyzing one or more specific biochemical reactions, similar to proteinenzymes. Ribozymes function in numerous capacities, including in ribosomes as part of the large subunit ribosomal RNA.
Any of a class of polymeraseenzymes that synthesize RNA molecules from a DNA template. RNA polymerases are essential for transcription and are found in all living organisms and many viruses. They build long single-stranded polymers called transcripts by adding ribonucleotides one at a time in the 5'-to-3' direction, relying on the template provided by the complementary strand to transcribe the nucleotide sequence faithfully.
Aribonucleoprotein complex which works to silence endogenous and exogenous genes by participating in various RNA interference pathways at the transcriptional and translational levels. RISC can bind both single-stranded and double-stranded RNA fragments and then cleave them or use them as guides to target complementary mRNAs for degradation.
A type of chromosomal translocation by which double-strand breaks at or near the centromeres of two acrocentricchromosomes cause a reciprocal exchange of segments that gives rise to one large metacentric chromosome (composed of the long arms) and one extremely small chromosome (composed of the short arms), the latter of which is often subsequently lost from the cell with little effect because it contains very few genes. The resulting karyotype shows one fewer than the expected total number of chromosomes, because two previously distinct chromosomes have essentially fused together. Carriers of Robertsonian translocations are generally not associated with any phenotypic abnormalities, but do have an increased risk of generating meiotically unbalanced gametes.
A method of DNA sequencing based on the in vitroreplication of a DNA template sequence, during which fluorochrome-labeled, chain-terminating dideoxynucleotides are randomly incorporated in the elongating strand; the resulting fragments are then sorted by size with electrophoresis, and the particular fluorochrome terminating each of the size-sorted fragments is detected by laser chromatography, thus revealing the sequence of the original DNA template through the order of the fluorochrome labels as one reads from small-sized fragments to large-sized fragments. Though Sanger sequencing has been replaced in some contexts by next-generation methods, it remains widely used for its ability to produce relatively long sequence reads (500+ nucleotides) and its very low error rate.
Anin vitro nucleic acid hybridization reaction in which one polynucleotide component (either DNAorRNA) is supplied in great excess relative to the other, causing all complementary sequences in the other polynucleotide to pair with the excess sequences and form hybrid duplex molecules.[10]
Any genetic material (e.g. a gene or any other DNA sequence) which can enhance its own replication and/or transmission into subsequent generations at the expense of other genes in the genome, even if doing so has no positive effect or even a net negative effect on the fitness of the genome as a whole. Selfish elements usually work by producing self-acting gene products which repeatedly copy and paste their own coding sequences into other parts of the genome, independently of normal DNA replication (as with transposable elements); by facilitating the uneven swapping of chromosome segments during genetic recombination events (as with unequal crossing over); or by disrupting the normally equal redistribution of replicated material during mitotisormeiosis such that the probability that the selfish element is present in a given daughter cell is greater than the normal 50 percent (as with gene drives).
The standard mode of DNA replication that occurs in all living cells, in which each of the two parental strands of the original double-stranded DNA molecule are used as template strands, with DNA polymerases replicating each strand separately and simultaneously in antiparallel directions. The result is that each of the two double-stranded daughter molecules is composed of one of the original parental strands and one newly synthesized complementary strand, such that each daughter molecule conserves the precise sequence of information (indeed the very same atoms) from one-half of the original molecule. Contrast conservative replication and dispersive replication.
Three different modes of DNA replication. In semiconservative replication, each of the two daughter molecules is built from one of the original parental strands and one newly synthesized strand. In conservative replication, the original parent molecule remains intact while the replicated molecule is composed of two newly synthesized strands. In dispersive replication, each of the daughter molecules is an uneven mix of old and new, with some segments consisting of the two parental strands and others consisting of two newly synthesized strands. Only semiconservative replication occurs naturally.
A distinction made between the individual strands of a double-stranded DNA molecule in order to easily and specifically identify each strand. The two complementary strands are distinguished as sense and antisense or, equivalently, the coding strand and the template strand. It is the antisense/template strand which is actually used as the template for transcription; the sense/coding strand merely resembles the sequence of codons on the RNA transcript, which makes it possible to determine from the DNA sequence alone the expected amino acid sequence of any protein translated from the RNA transcript. Which strand is which is relative only to a particular RNA transcript and not to the entire DNA molecule; that is, either strand can function as the sense/coding or antisense/template strand.
Any codon that specifies an amino acid, as opposed to a stop codon, which does not specify any particular amino acid but instead signals the end of translation.
Asequence logo depicts the statistical frequency with which each nucleobase (or amino acid) occurs within a given sequence. Each position in the sequence is represented by a vertical stack of letters; the total height of the stack indicates the degree of consensus at that position between all of the aligned sequences, and the height of each individual letter in the stack indicates the proportion of the aligned sequences having that nucleobase at that position. A single very large letter filling most of the stack indicates that most or all of the aligned sequences have that particular nucleobase at that position.
The determination of the order or sequenceofnucleotides in a nucleic acid molecule, or of amino acids in a peptide, by any means. Sequences are usually written as a linear string of letters which conveniently summarizes much of the atomic-level structure of the molecule.
In condensed chromosomes where the positioning of the centromere creates two segments or "arms" of unequal length, the shorter of the two arms of a chromatid. Contrast long arm.
A type of neutral mutation which does not have an observable effect on the organism's phenotype. Though the term "silent mutation" is often used interchangeably with synonymous mutation, synonymous mutations are not always silent, nor vice versa. Missense mutations which result in a different amino acid but one with similar functionality (e.g. leucine instead of isoleucine) are also often classified as silent, since such mutations usually do not significantly affect protein function.
Any substitution of a single nucleotide which occurs at a specific position within a genome and with measurable frequency within a population; for example, at a specific base position in a DNA sequence, the majority of the individuals in a population may have a cytosine (C), while in a minority of individuals, the same position may be occupied by an adenine (A). SNPs are usually defined with respect to a "standard" reference genome; an individual human genome differs from the reference human genome at an average of 4 to 5 million positions, most of which consist of SNPs and short indels. See also polymorphism.
Any DNA molecule that consists of a single nucleotide polymer or strand, as opposed to a pair of complementary strands held together by hydrogen bonds (double-stranded DNA). In most circumstances, DNA is more stable and more common in double-stranded form, but high temperatures, low concentrations of dissolved salts, and very high or low pH can cause double-stranded molecules to decompose into two single-stranded molecules in a denaturation process known as melting; this reaction is exploited by naturally occurring enzymes such as those involved in DNA replication as well as by laboratory techniques such as polymerase chain reaction.
A pair of identical copies (chromatids) produced as the result of the DNA replication of a chromosome, particularly when both copies are joined together by a common centromere; the pair of sister chromatids is called a dyad. The two sister chromatids are ultimately separated from each other into two different cells during mitosisormeiosis.
A class of small RNA molecules engineered so as to change conformation conditionally in response to cognate molecular inputs, often with the goal of controlling signal transduction pathways in vitroorin vivo.
A class of small RNA molecules whose primary function is to direct the chemical modification of other RNAs, mainly transfer RNAs (tRNA), small nuclear RNAs (snRNA), and especially ribosomal RNAs (rRNA) as a part of ribosome synthesis in the nucleolus. SnoRNAs contain antisense sequences that complement sequences within these target RNAs and guide ribonucleoprotein complexes to them, which can then catalyze specific nucleoside modifications, typically methylationorpseudouridylation.
A subclass of microRNAs, originally described in nematodes, which regulate the timing of developmental events by binding to complementary sequences in the 3' untranslated regionsofmessenger RNAs and inhibiting their translation. In contrast to siRNAs, which serve similar purposes, stRNAs bind to their target mRNAs after the initiation of translation and without affecting mRNA stability, which makes it possible for the target mRNAs to resume translation at a later time.
Any biological cell forming the body of an organism, or, in multicellular organisms, any cell other than a gamete, germ cell, or undifferentiated stem cell. Somatic cells are theoretically distinct from cells of the germ line, meaning the mutations they have undergone can never be transmitted to the organism's descendants, though in practice exceptions do exist.
Amolecular biology method used for detecting a specific sequenceinDNA samples. The technique combines separation of DNA fragments by gel electrophoresis, transfer of the DNA to a synthetic membrane, and subsequent identification of target fragments with radio-labeled or fluorescent hybridization probes.
Also intergenic spacer (IGS)ornon-transcribed spacer (NTS).
Any sequence or region of non-coding DNA separating neighboring genes, whether transcribed or not. The term is used in particular to refer to the non-coding regions between the many repeated copies of the ribosomal RNA genes.[12] See also intergenic region.
spatially-restricted gene expression
The expression of one or more genes only within a specific anatomical region or tissue, often in response to a paracrine signal. The boundary between the jurisdictions of two spatially restricted genes may generate a sharp phenotypic gradient there, as with striping patterns.
The genetic code used by the vast majority of living organisms for translatingnucleic acid sequences into proteins. In this system, of the 64 possible permutations of three-letter codons that can be made from the four nucleotides, 61 code for one of the 20 amino acids, and the remaining three code for stop signals. For example, the codon CAG codes for the amino acid glutamine and the codon UAA is a stop codon. The standard genetic code is described as degenerate or redundant because some amino acids can be coded for by more than one different codon.
The standard genetic code specifies a set of 20 different amino acids from triplet arrangements of the four different RNAnucleobases (A, G, C, and U). To read this chart, choose one of the four letters in the innermost ring and then move outward, adding two more letters to complete a codon triplet: a total of 64 unique codons can be made this way, 61 of which signal the addition of one of the 20 amino acids (identified by single-letter abbreviation as well as by full name and chemical structure) to a nascent peptide chain, while the remaining three codons are stop codons signalling the termination of translation. Also indicated are some of the chemical properties of the amino acids and the various ways in which they can be modified.
A term used to describe the end of a double-stranded DNA molecule where one strand is longer than the other by one or more nucleobases, creating a single-stranded "overhang" of unpaired bases, in contrast to a so-called "blunt end", where no such overhang exists because the terminal nucleobases on each strand are base-paired with each other. Blunt ends and sticky ends are relevant when ligating multiple DNA molecules, e.g. in restriction cloning, because many restriction enzymes cut DNA in a way that leaves behind terminal overhangs in the digested fragments. These sticky-ended molecules ligate much more readily with other sticky-ended molecules having complementary overhangs, allowing scientists to ensure that specific DNA fragments are ligated together in specific places.
Acodon that signals the termination of protein synthesis during translation of a messenger RNA transcript. In the standard genetic code, three different stop codons are used to dissociate ribosomes from the growing amino acid chain, thereby ending translation: UAG (nicknamed "amber"), UAA ("ochre"), and UGA ("opal"). Contrast start codon.
strand
An individual chain of nucleotides comprising a nucleic acid polymer, existing either singly (in which case the nucleic acid molecule is said to be single-stranded) or paired in a duplex (in which case it is said to be double-stranded).
stringency
The effect of conditions such as temperature and pH upon the degree of complementarity that is required for a hybridization reaction to occur between two single-stranded nucleic acid molecules. In the most stringent conditions, only exact complements can successfully hybridize; as stringency decreases, an increasing number of mismatches can be tolerated by the two hybridizing strands.[14]
Aprotein which as its primary function contributes to the mechanical shape and structure of cells, organelles, or tissues (e.g. collagen and actin), as distinguished from proteins which serve some other purpose, such as enzymes. This distinction is not well-defined, however, as many proteins have both structural and non-structural roles.[2]
The subdivision of the interior of a cell into functionally distinct spaces or compartments (e.g. membrane-bound organelles) and the localization or delegation of particular cellular functions and activities to these particular spaces; or the determination by any of various laboratory methods (e.g. fluorescent labelling) of the precise location(s) within a cell where a specific molecule has occupancy, or at which a specific activity occurs.
(of a linear chromosome or chromosome fragment) Having a centromere positioned close to but not exactly in the middle of the chromosome, resulting in chromatid arms of slightly different lengths.[5] Compare metacentric.
1. A chemical compound or molecule upon which a particular enzyme directly acts, often but not necessarily binding the molecule by forming one or more chemical bonds.[2] See also ligand.
2. The substance, biotic or abiotic, upon which an organism grows or lives, or by which it is supported; e.g. a particular growth medium used in cell culture. See also substratum.
substratum
A solid surface to which a cell or organism adheres or by which it is supported, or over which it moves.[3] See also substrate.
subunit
A single unit of a multi-unit compound or molecular aggregate; e.g. a monomer from which a larger polymer is composed (as with nucleotidesinnucleic acids), or an individual polypeptide chain in a multi-chain protein, or an entire protein which participates alongside other proteins as part of a protein complex.[2][4]
A type of cell culture in which individual cells or aggregates of cells are suspended in a gently agitated liquid growth medium. Many prokaryotic and eukaryotic cell types readily proliferate in suspension cultures, but they are particularly useful for culturing non-adherent cell lines such as hematopoietic cells, plant cells, and insect cells. Compare adherent culture.
Any of a class of transmembranetransporter proteins which facilitate the transport of two or more different molecules across the membrane at the same time and in the same direction; e.g. glucose and sodium ions. Contrast antiporter and uniporter.
Amultinucleate cell, i.e. a cell containing more than one nucleus or, in the broadest sense, more than one nuclear genome (a meaning which is equated with polyploidy). Syncytia may form as a result of cell fusion between uninucleate cells, migration of a nucleus from one cell to another, or multiple nuclear divisions without accompanying cytokinesis (forming a coenocyte).[12] The term may also refer to cells which are interconnected by specialized membranes with gap junctions as in some neuromuscular cell types.
A type of mutation in which the substitution of one nucleotide base for another results, after transcription and translation, in an amino acid sequence which is identical to the original unmutated sequence. This is possible because of the degeneracy of the genetic code, which allows different codons to code for the same amino acid. Though synonymous mutations are often considered silent, this is not always the case; a synonymous mutation may affect the efficiency or accuracy of transcription, splicing, translation, or any other process by which genes are expressed, and thus become effectively non-silent. Contrast nonsynonymous mutation.
A pattern within a nucleic acid sequence in which one or more nucleobases are repeated and the repetitions are directly adjacent (i.e. tandem) to each other. An example is ATGACATGACATGAC, in which the sequence ATGAC is repeated three times.
(of a linear chromosome or chromosome fragment) Having a centromere positioned at the terminal end of the chromosome (near or within the telomere), resulting in only a single arm.[5] Compare acrocentric.
A region of repetitivenucleotide sequences at each end of a linear chromosome which protects the end of the chromosome from deterioration and from fusion with other chromosomes. Since each round of replication results in the shortening of the chromosome, telomeres act as disposable buffers which are sacrificed to perpetual truncation instead of nearby genes; telomeres can also be lengthened by the enzyme telomerase.
A DNA sequence or its RNA complement which signals the termination of transcription by triggering processes that ultimately arrest the activity of RNA polymerase or otherwise cause the release of the RNA transcript from the transcriptional complex. Terminator sequences are usually found near the ends of the coding sequencesofgenes and operons. They generally function after being themselves transcribed into the nascent RNA strand, whereupon the part of the strand containing the sequence either directly interacts with the transcriptional complex or forms a secondary structure such as a hairpin loop which signals the recruitment of enzymes that promote its disassembly.[10]
One of the four standard nucleosides used in DNA molecules, consisting of a thyminebase with its N9 nitrogen bonded to the C1 carbon of a deoxyribose sugar. The prefix deoxy- is commonly omitted, since there are no ribonucleoside analogs of thymidine used in RNA, where it is replaced with uridine instead.
Apyrimidinenucleobase used as one of the four standard nucleobases in DNA molecules. Thymine forms a base pair with adenine. In RNA, thymine is not used at all, and is instead replaced with uracil.
Gene function and expression which is restricted to a particular tissue or cell type. Tissue-specific expression is usually the result of an enhancer which is activated only in the proper cell type.
Any of a class of DNA-binding enzymes which catalyze changes in the topological state of a double-stranded DNA molecule by nickingorcutting the sugar-phosphate backbone of one or both strands, relaxing the torsional stress inherent in the double helix and unwinding or untangling the paired strands before re-ligating the nicks. This process is usually necessary prior to replication and transcription. Topoisomerases thereby convert DNA between its relaxed and supercoiled, linked and unlinked, and knotted and unknotted forms without changing the sequence or overall chemical composition, such that the substrate and product molecules are structural isomers, differing only in their shape and their twisting, linking, and/or writhing numbers.
A molecule or a specific atom within a molecule that has been chemically or radioactively labelled so that it can easily be tracked or followed through a biochemical process or located in a cell or tissue.[4]
Affecting a gene or sequence on a different nucleic acid molecule or strand. A locus or sequence within a particular DNA molecule such as a chromosome is said to be trans-acting if it or its products influence or act upon other sequences located relatively far away or on an entirely different molecule or chromosome. For example, a DNA-binding protein acts "in trans" if it binds to or interacts with a sequence located on any strand or molecule different from the one on which it is encoded. Contrast cis-acting.
A product of transcription; that is, any RNA molecule which has been synthesized by RNA polymerase using a complementary DNA molecule as a template. When transcription is completed, transcripts separate from the DNA and become independent primary transcripts. Particularly in eukaryotes, multiple post-transcriptional modifications are usually necessary for raw transcripts to be converted into stable and persistent molecules, which are then described as mature, though not all transcribed RNAs undergo maturation. Many transcripts are accidental, spurious, incomplete, or defective; others are able to perform their functions immediately and without modification, such as certain non-coding RNAs.
The first step in the process of gene expression, in which an RNA molecule, known as a transcript, is synthesized by enzymes called RNA polymerases using a gene or other DNA sequence as a template. Transcription is a critical and fundamental process in all living organisms and is necessary in order to make use of the information encoded within a genome. All classes of RNA must be transcribed before they can exert their effects upon a cell, though only messenger RNA (mRNA) must proceed to translation before a functional protein can be produced, whereas the many types of non-coding RNA fulfill their duties without being translated. Transcription is also not always beneficial for a cell: when it occurs at the wrong time or at a functionless locus, or when mobile elements or infectious pathogens utilize the host's transcription machinery, the resulting transcripts (not to mention the waste of valuable energy and resources) are often harmful to the host cell or genome.
A simplified diagram of transcription. RNA polymerase (RNAP) synthesizes an RNA transcript (blue) in the 5'-to-3' direction, using one of the DNA strands as a template, while a complex of multiple transcription factors binds to a promoter upstream of the gene.
Any protein that controls the rate of transcription of genetic information from DNAtoRNA by binding to a specific DNA sequence and promotingorblocking the recruitment of RNA polymerase to nearby genes. Transcription factors can effectively turn "on" and "off" specific genes in order to make sure they are expressed at the right times and in the right places; for this reason, they are a fundamental and ubiquitous mechanism of gene regulation.
The specific location within a gene at which RNA polymerase begins transcription, defined by the specific nucleotide or codon corresponding to the first ribonucleotide(s) to be assembled in the nascent transcript (which is not necessarily the same as the first codon to be translated). This site is usually considered the beginning of the coding sequence and is the reference point for numbering the individual nucleotides within a gene. Nucleotides upstream of the start site are assigned negative numbers and those downstream are assigned positive numbers, which are used to indicate the positions of nearby sequences or structures relative to the TSS. For example, the binding site for RNA polymerase might be a short sequence immediately upstream of the TSS, from approximately -80 to -5, whereas an intron within the coding region might be defined as the sequence starting at nucleotide +207 and ending at nucleotide +793.
transcription unit
The segment of DNA between the initiation site and the termination site of transcription, containing the coding sequences for one or more genes. All genes within a transcription unit are transcribed together into a single transcript during a single transcription event; the resulting polycistronic RNA may subsequently be cleaved into separate RNAs, or may be translated as a unit and then cleaved into separate polypeptides.[10]
The intermittent nature of transcription and translation mechanisms. Both processes occur in "bursts" or "pulses", with periods of gene activity separated by irregular intervals.
The entire set of RNA molecules (often referring to all types of RNA but sometimes exclusively to messenger RNA) that is or can be expressed by a particular genome, cell, population of cells, or species at a particular time or under particular conditions. The transcriptome is distinct from the exome and the translatome.
The deliberate experimental introduction of exogenous nucleic acids into a cell or embryo. In the broadest sense the term may refer to any such transfer and is sometimes used interchangeably with transformation, though some applications restrict the usage of transfection to the introduction of naked or purified non-viral DNAorRNA into cultured eukaryotic cells (especially animal cells) resulting in the subsequent incorporation of the foreign DNA into the host genome or the non-hereditary modification of gene expression by the foreign RNA. As a contrast to both standard non-viral transformation and transduction, transfection has also occasionally been used to refer to the uptake of purified viral nucleic acids by bacteria or plant cells without the aid of a viral vector.[10]
A special class of RNA molecule, typically 76 to 90 nucleotides in length, that serves as a physical adapter allowing mRNA transcripts to be translated into sequences of amino acids during protein synthesis. Each tRNA contains a specific anticodon triplet corresponding to an amino acid that is covalently attached to the tRNA's opposite end; as translation proceeds, tRNAs are recruited to the ribosome, where each mRNA codon is paired with a tRNA containing the complementary anticodon. Depending on the organism, cells may employ as many as 41 distinct tRNAs with unique anticodons; because of codon degeneracy within the genetic code, several tRNAs containing different anticodons carry the same amino acid.
A type of RNA molecule in some bacteria which has dual tRNA-like and mRNA-like properties, allowing it to simultaneously perform a number of different functions during translation.
Any gene or other segment of genetic material that has been isolated from one organism and then transferred either naturally or by any of a variety of genetic engineering techniques into another organism, especially one of a different species. Transgenes are usually introduced into the second organism's germ line. They are commonly used to study gene function or to confer an advantage not otherwise available in the unaltered organism.
The entire set of messenger RNA molecules that are translated by a particular genome, cell, tissue, or species at a particular time or under particular conditions. Like the transcriptome, it is often used as a proxy for quantifying levels of gene expression, though the transcriptome also includes many RNA molecules that are never translated.
Any of a class of self-acting enzymes capable of binding to the flanking sequences of the transposable element which encodes them and catalyzing its movement to another part of the genome, typically by an excision/insertion mechanism or a replicative mechanism, in a process known as transposition.
The process by which a nucleic acid sequence known as a transposable element changes its position within a genome, either by excising and re-inserting itself at a different locus (cut-and-paste) or by duplicating itself and inserting into another locus without moving the original element from its original locus (copy-paste). These reactions are catalyzed by an enzyme known as a transposase which is encoded by a gene within the transposable element itself; thus the element's products are self-acting and can autonomously direct their own replication. Transposed sequences may re-insert at random loci or at sequence-specific targets, either on the same DNA molecule or on different molecules.
Any of a class of chemical compounds which are ester derivatives of glycerol, consisting of a glycerol backbone connected to any three fatty acid substituents via ester bonds. Triglycerides are one of three major classes of esters formed by fatty acids in biological systems, along with phospholipids and cholesteryl esters. They are the primary constituent of adipose tissue in vertebrates.
Any sequence in which an individual nucleotide tripletisrepeated many times in tandem, whether in a gene or non-coding sequence. At most loci some degree of repetition is normal and harmless, but mutations which cause specific triplets (especially those of the form CnG) to increase in copy number above the normal range are highly unstable and responsible for a variety of genetic disorders.
triplet
A unit of three successive nucleotides in a DNAorRNA molecule.[10] A triplet within a coding sequence that codes for a specific amino acid is known as a codon.
The directional growth or movement of a cell or organism in response to a stimulus, e.g. light, heat, the pull of gravity, or the presence of a particular chemical, such that the response is dependent on the direction of the stimulus (as opposed to a non-directional nastic response). Positive tropism is growth or movement toward the stimulus; negative tropism is away from the stimulus.[2] See also taxis and kinesis.
The labelling of a biomolecule (often another protein) by covalently attaching a ubiquitin protein to it, thus making it identifiable to molecules capable of recognizing ubiquitin epitopes.
A type of transport protein which catalyzes the movement of a single, specific solute or chemical species across a lipid membrane in either direction.[4] Contrast antiporter and symporter.
unique DNA
Also non-repetitive DNA.
A class of DNA sequences determined by C0t analysis to be present only once in the analyzed genome, as opposed to repetitive sequences. Most structural genes and their introns are unique.[10]
Any non-coding sequence which is transcribed along with a protein-coding sequence, and thus included within a messenger RNA, but which is not ultimately translated during protein synthesis. A typical mRNA transcript includes two such regions: one immediately upstream of the coding sequence, known as the 5' untranslated region (5'-UTR), and one downstream of the coding sequence, known as the 3' untranslated region (3'-UTR). These regions are not removed during post-transcriptional processing (unlike introns) and are usually considered distinct from the 5' cap and the 3' polyadenylated tail (both of which are later additions to a primary transcript and not themselves products of transcription). UTRs are a consequence of the fact that transcription usually begins considerably upstream of the start codon of the coding sequence and terminates long after the stop codon has been transcribed, whereas translation is more precise. They often include motifs with regulatory functions.
upregulation
Also promotion.
Any process, natural or artificial, which increases the level of gene expression of a certain gene. A gene which is observed to be expressed at relatively high levels (such as by detecting higher levels of its mRNA transcripts) in one sample compared to another sample is said to be upregulated. Contrast downregulation.
Apyrimidinenucleobase used as one of the four standard nucleobases in RNA molecules. Uracil forms a base pair with adenine. In DNA, uracil is not used at all, and is instead replaced with thymine.
One of the four standard nucleosides used in RNA molecules, consisting of a uracilbase with its N9 nitrogen bonded to the C1 carbon of a ribose sugar. In DNA, uridine is replaced with thymidine.
Any of a class of enclosed, fluid-filled compartments present in many eukaryotic cells as well as bacteria, often large and conspicuous under the microscope and serving any of a huge variety of functions, including acting as a resizable reservoir for the storage of water, metabolic waste, toxins, or foreign material; maintaining cellular homeostasis and hydrostatic pressure; supporting immune functions; housing symbiotic bacteria; and assisting in the degradation and recycling of old cellular components.[2]
Variation or irregularity in a particular phenotype, especially a conspicuous visible trait such as color or pigmentation, occurring simultaneously in different parts of the same individual organism due to any of a variety of causes, such as X-inactivation, mitotic recombination, transposable element activity, position effects, or infection by pathogens.
Any membrane-bound space completely enclosed by its own membrane, which is separate though usually derived from other membranes (often the cell membrane) either by budding or by mechanical disruption such as sonication.[3] The term is applied to many different structures but especially to the small, roughly spherical compartments created during endocytosis and exocytosis, as well as to lysosomes and various other small intracellular or extracellular organelles.[2]
The process of determining the entirety or near-entirety of the DNA sequences comprising an organism's genome with a single procedure or experiment, generally inclusive of all chromosomal and extrachromosomal (e.g. mitochondrial) DNA.
The phenotype of the typical form of a species as it occurs in nature; a product of the standard "normal" allele at a given locus, as opposed to that produced by a non-standard mutant allele.
One of two sex chromosomes present in organisms which use the XY sex-determination system, and the only sex chromosome in the X0 system. The X chromosome is found in both males and females and typically contains much more gene content than its counterpart, the Y chromosome.
The process by which one of the two copies of the X chromosome is silenced by being irreversibly condensed into transcriptionally inactive heterochromatin in the cells of female therian mammals. A form of dosage compensation, X-inactivation prevents females from producing twice as many gene products from genes on the X chromosome as males, who only have one copy of the X chromosome. Which X chromosome is inactivated is randomly determined in the early embryo, making it possible for cell lineages with different inactive Xs to exist in the same organism.
The degree to which multiple copies of a gene, chromosome, or genome have the same genetic sequence; e.g. in a diploid organism with two complete copies of its genome (one maternal and one paternal), the degree of similarity of the alleles present in each copy. Individuals carrying two different alleles for a particular gene are said to be heterozygous for that gene; individuals carrying two identical alleles are said to be homozygous for that gene. Zygosity may also be considered collectively for a group of genes, or for the entire set of genes and genetic loci comprising the genome.
A type of eukaryotic cell formed as the direct result of a fertilization event between two gametes. In multicellular organisms, the zygote is the earliest developmental stage.
^ abcdefghijklmnopqrLackie, J. M. (2013). The Dictionary of Cell and Molecular Biology (5th ed.). Amsterdam: Academic Press/Elsevier. ISBN978-0-12-384931-1.
^ abcdefghijklmnoAlberts, Bruce; Johnson, Alexander; Lewis, Julian; Raff, Martin; Roberts, Keith; Walter, Peter (2002). "Glossary". Molecular Biology of the Cell(Available from the National Center for Biotechnology Information) (4th ed.). New York: Garland Science.
^ abcKlug, William S.; Cummings, Michael R. (1986). Concepts of Genetics (2nd ed.). Glenview, Ill.: Scott, Foresman and Company. ISBN0-673-18680-6.
^ abLewin, Benjamin (2003). Genes VIII. Upper Saddle River, NJ: Pearson Prentice Hall. ISBN0-13-143981-2.
^"overexpression". Oxford Living Dictionary. Oxford University Press. 2017. Archived from the original on February 10, 2018. Retrieved 18 May 2017. The production of abnormally large amounts of a substance which is coded for by a particular gene or group of genes; the appearance in the phenotype to an abnormally high degree of a character or effect attributed to a particular gene.
^"overexpress". NCI Dictionary of Cancer Terms. National Cancer Institute at the National Institutes of Health. 2011-02-02. Retrieved 18 May 2017. overexpress In biology, to make too many copies of a protein or other substance. Overexpression of certain proteins or other substances may play a role in cancer development.
