Cheryl Davis

Human Submandibular Saliva Inhibits Human Immunodeficiency Virus Type 1 Infection by Displacing Envelope Glycoprotein gp120 from the Virus

Human submandibular saliva reduces human immunodeficiency virus type 1 (HIV-1) infection in vitro. To define the mechanism of inhibition, virus was incubated with saliva or medium, velocity sucrose gradient centrifugation was performed, and fractions were analyzed for p24 and gp120. The results show that after incubation with saliva, the envelope glycoprotein was displaced from both a laboratory-adapted and a low-passage clinical HIV-1 isolate. To identify the salivary protein(s) responsible, submandibular saliva was fractionated by anion- exchange chromatography. Protein fractions containing anti-HIV activity were assayed for their ability to strip gp120 from virus. The partially purified active fractions contained two high-molecular-weight sialyated glycoproteins identified as salivary agglutinin and mucin, as well as several lower-molecular-weight proteins. It thus appears that specific salivary proteins interact with HIV-1 to strip gp120 from the virus with a resultant decrease in infectivity.

Salivary agglutinin inhibits HIV type 1 infectivity through interaction with viral glycoprotein 120.

Salivary agglutinin (SAG) is a high molecular mass glycoprotein (340 kDa) that plays important roles in innate immunity. SAG has been found to specifically inhibit HIV-1 infectivity and to bind to virus through the envelope protein gp120. Although SAG binds to gp120 of the virus, the exact nature of this binding has not been characterized. Using surface plasmon resonance technology, we have found that SAG interacts with recombinant envelopes derived from diverse HIV-1 isolates with K(D) values ranging from 10(-7) to 10(-10) M, comparable to gp120-sCD4 binding. Furthermore, SAG binding to gp120 is Ca(2+) dependent. sCD4 prebound to gp120 failed to abrogate SAG binding, suggesting a distinct mechanism for SAG inhibition of HIV-1 infectivity. Inhibition by monoclonal antibodies specific for carbohydrates also implicates the involvement of carbohydrates in the interaction between SAG and gp120. These results argue that the anti-HIV-1 activity of SAG is due to carbohydrate-mediated binding to gp120. A demonstration that SAG is related to lung scavenger receptor, gp-340, further suggests the roles of SAG in preventing pathogen invasion at the entry portal and raises its potential as an anti-HIV-1 drug candidate.

Comparison of oral fluid collectors for use in a rapid point-of-care diagnostic device.

ABSTRACT Orally based diagnostic testing is emerging as an alternative, noninvasive method for analyzing a variety of analytes. These analytes include pathogens, antibodies, drugs, and nucleic acids. In the present study we developed a protocol for evaluation of collectors that could be used in orally based, point-of-care diagnostics. A performance comparison was carried out with a number of commercially available collectors, and their ability to deliver fluid, proteins, bacteria, and nucleic acid from pathogens compatible with PCR was assessed. The collectors were all capable of picking up and delivering test materials, albeit at various levels.

Submandibular Salivary Proteases: Lack of a Role in Anti-HIV Activity:

Whole human saliva contains a number of proteolytic enzymes, mostly derived from white blood cells and bacteria in the oral cavity. However, less information is available regarding proteases produced by salivary glands and present in salivary secretions. In the present study, we have analyzed submandibular saliva, collected without contaminating cells, and identified multiple proteolytic activities. These have been characterized in terms of their susceptibility to a series of protease inhibitors. The submandibular saliva proteases were shown to be sensitive to both serine and acidic protease inhibitors. We also used protease inhibitors to determine if salivary proteolytic activity was involved in the inhibition of HIV infectivity seen when the virus is incubated with human saliva. This anti-HIV activity has been reported to occur in whole saliva and in ductal saliva obtained from both the parotid and submandibular glands, with highest levels of activity present in the latter fluid. Protease inhibitors, at concentrations sufficient to block salivary proteolytic activity in an in vitro infectivity assay, did not block the anti-HIV effects of saliva, suggesting that the salivary proteases are not responsible for the inhibition of HIV-1 infectivity.

Bacterial agglutinin activity in the saliva of human identical and fraternal twins

The major factor in human saliva responsible for the specific aggregation of oral streptococci is a high molecular-weight glycoprotein (agglutinin). To determine if the level of this glycoprotein in whole and parotid saliva was genetically determined, agglutinin activity for Streptococcus sanguis and Streptococcus mutans in saliva obtained from identical and fraternal twins was compared. Evidence for the heritability of agglutinin activity and also parotid flow rate and total protein was obtained. There was no evidence for a significant genetic contribution to salivary sodium concentration.