Human Histatin 8

Objectives: The aims of this study were to investigate the efficacy of Histatin-1 in wound closure as well as effects on gene expression of nicotine-treated human Periodontal Ligament Fibroblast cells (HPDL) in vitro. Design: HPDL grown in 2.5% culture medium treated with 10 ng/ml Histatin - 1 in the presence/absence of 0.5 µM nicotine were subjected to wound assay and migration was studied at 0 h, 6 h, 12 h and 24 h. Cells grown in 2.5% medium served as control. Cell migration was studied by wound gap and transwell migration assays. The effect of Histatin-1 on expression of matrix metalloproteinase 8 (MMP-8), insulin-like growth factor 1 (IGF-1), transforming growth factor beta (TGF-β), collagen type I (COL1) and plasminogen activator inhibitor 1 (PAI-1) were studied. Results: Histatin-1 treatment significantly decreased percentage wound gap at 12 h (62.96 ± 3.22 vs 79.23 ± 1.73; p < 0.05) and at 24 h (38.78 ± 7.59 vs 75.21 ± 4.94; p < 0.001) compared with controls. In nicotine+Histatin-1 treated cells, wound gap decreased to 70.2 ± 2.9% (p < 0.01) at 24 h compared to nicotine alone in which 82 ± 1.64% of wound gap was retained. Transwell migration assays showed significant migration of HPDL with Histatin-1 (p < 0.05). Gene expression demonstrated significant upregulation for IGF-1, TGF β, COL1 and PAI-1 with Histatin-1. Conclusion: Histatin-1 significantly mitigated the effect of nicotine in wound healing assay involving HPDL fibroblast cells at 24 h. Histatin-1 aided wound closure is attributed to the upregulation of IGF-1, TGF β, COL1, and PAI-1 genes.

Background: The use of salivary diagnostics is increasing because of its noninvasiveness, ease of sampling, and the relatively low risk of contracting infectious organisms. Saliva has been used as a biological fluid to identify and validate RNA targets in head and neck cancer patients. The goal of this study was to develop a robust, easy, and cost-effective method for isolating high yields of total RNA from saliva for downstream expression studies. Methods: Oral whole saliva (200 μL) was collected from healthy controls (n = 6) and from patients with head and neck cancer (n = 8). The method developed in-house used QIAzol lysis reagent (Qiagen) to extract RNA from saliva (both cell-free supernatants and cell pellets), followed by isopropyl alcohol precipitation, cDNA synthesis, and real-time PCR analyses for the genes encoding β-actin ("housekeeping" gene) and histatin (a salivary gland-specific gene). Results: The in-house QIAzol lysis reagent produced a high yield of total RNA (0.89-7.1 μg) from saliva (cell-free saliva and cell pellet) after DNase treatment. The ratio of the absorbance measured at 260 nm to that at 280 nm ranged from 1.6 to 1.9. The commercial kit produced a 10-fold lower RNA yield. Using our method with the QIAzol lysis reagent, we were also able to isolate RNA from archived saliva samples that had been stored without RNase inhibitors at -80 °C for >2 years. Conclusions: Our in-house QIAzol method is robust, is simple, provides RNA at high yields, and can be implemented to allow saliva transcriptomic studies to be translated into a clinical setting.

Background: Histatins are histidine rich polypeptides produced in the parotid and submandibular gland and secreted into the saliva. Histatin-3 and -5 are the most important polycationic histatins. They possess antimicrobial activity against fungi such as Candida albicans. Histatin-5 has a higher antifungal activity than histatin-3 while histatin-3 is mostly involved in wound healing in the oral cavity. We found that these histatins, like other polycationic peptides and proteins, such as LL-37, lysozyme and histones, interact with extracellular actin. Results: Histatin-3 and -5 polymerize globular actin (G-actin) to filamentous actin (F-actin) and bundle F-actin filaments. Both actin polymerization and bundling by histatins is pH sensitive due to the high histidine content of histatins. In spite of the equal number of net positive charges and histidine residues in histatin-3 and -5, less histatin-3 is needed than histatin-5 for polymerization and bundling of actin. The efficiency of actin polymerization and bundling by histatins greatly increases with decreasing pH. Histatin-3 and -5 induced actin bundles are dissociated by 100 and 50 mM NaCl, respectively. The relatively low NaCl concentration required to dissociate histatin-induced bundles implies that the actin-histatin filaments bind to each other mainly by electrostatic forces. The binding of histatin-3 to F-actin is stronger than that of histatin-5 showing that hydrophobic forces have also some role in histatin-3- actin interaction. Histatins affect the fluorescence of probes attached to the D-loop of G-actin indicating histatin induced changes in actin structure. Transglutaminase cross-links histatins to actin. Competition and limited proteolysis experiments indicate that the main histatin cross-linking site on actin is glutamine-49 on the D-loop of actin. Conclusions: Both histatin-3 and -5 interacts with actin, however, histatin 3 binds stronger to actin and affects actin structure at lower concentration than histatin-5 due to the extra 8 amino acid sequence at the C-terminus of histatin-3. Extracellular actin might regulate histatin activity in the oral cavity, which should be the subject of further investigation.