Histatin was first discovered (isolated) in 1988, with functions that's responsible in keeping homeostasis inside the oral cavity, helping in the formation of pellicles, and assist in bonding of metal ions.[3]
The structure of histatin is unique depending on whether the protein of interest is histatin 1, 3 or 5. Nonetheless, histatins mainly possess a cationic (positive) charge due to the primary structure consisting mostly of basic amino acids. An amino acid that is crucial to histatin's function is histidine. Studies show that the removal of histidine (especially in histatin 5) resulted in reduction of antifungal activity.[4]
Histatins are antimicrobial and antifungal proteins, and have been found to play a role in wound-closure.[5][6] A significant source of histatins is found in the serous fluid secreted by Ebner's glands, salivary glands at the back of the tongue, and produced by acinus cells.[7] Here they offer some early defense against incoming microbes.[8]
The three major histatins are 1, 3, and 5, which contains 38, 32, and 24 amino acids, respectively. Histatin 2 is a degradation product of histatin 1, and all other histatins are degradation products of Histatin 3 through the process of post-translational proteolysis of the HTN3 gene product.[9] Therefore there are only two genes, HTN1 and HTN3.
^Edgerton M, Jang WS (2012-01-01). "Salivary Histatins: Structure, Function, and Mechanisms of Antifungal Activity". Candida and Candidiasis, Second Edition. pp. 185–194. doi:10.1128/9781555817176.ch13. ISBN978-1-55581-539-4.
^Piludu M, Lantini MS, Cossu M, Piras M, Oppenheim FG, Helmerhorst EJ, Siqueira W, Hand AR (November 2006). "Salivary histatins in human deep posterior lingual glands (of von Ebner)". Archives of Oral Biology. 51 (11): 967–73. doi:10.1016/j.archoralbio.2006.05.011. PMID16859632.