Further Characterization of Human Salivary Anticandidal Activities in a Human Immunodeficiency Virus-Positive Cohort by Use of Microassays

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Clinical and Diagnostic Laboratory Immunology, November 1999, p. 851-855, Vol. 6, No. 6
1071-412X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Further Characterization of Human Salivary Anticandidal Activities in a Human Immunodeficiency Virus-Positive Cohort by Use of Microassays

Alan L. Lin,¹ Qinghong Shi,¹ Dorthea A. Johnson,² Thomas F. Patterson,³^,⁴ Michael G. Rinaldi,⁴^,⁵ and Chih-Ko Yeh¹^,²^,⁴^,^*

Departments of Dental Diagnostic Science,¹ Community Dentistry,² Medicine,³ and Pathology,⁵ University of Texas Health Science Center at San Antonio, and Geriatric Research, Education and Clinical Center, Audie L. Murphy Division, South Texas Veterans Health Care System,⁴ San Antonio, Texas

Received 16 February 1999/Returned for modification 20 May 1999/Accepted 30 July 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Salivary anticandidal activities play an important role in oral candidal infection. R. P. Santarpia et al. (Oral Microbiol.Immunol. 7:38-43, 1992) developed in vitro anticandidal assaysto measure the ability of saliva to inhibit the viability of Candidaalbicans blastoconidia and the formation of germ tubes by C. albicans.In this report, we describe modifications of these assays foruse with small volumes of saliva (50 to 100 µl). For healthy subjects,there is strong inhibition of blastoconidial viability in stimulatedparotid (75%), submandibular-sublingual (74%), and whole (97%)saliva, as well as strong inhibition of germ tube formation (>80%)for all three saliva types. The susceptibility of several Candidaisolates to inhibition of viability by saliva collected from healthysubjects is independent of body source of Candida isolation (blood,oral cavity, or vagina) or the susceptibility of the isolate tothe antifungal drug fluconazole. Salivary anticandidal activitiesin human immunodeficiency virus (HIV)-infected patients were significantlylower than those in healthy controls for inhibition of blastoconidialviability (P < 0.05) and germ tube formation (P < 0.001). Stimulatedwhole-saliva flow rates were also significantly lower (P < 0.05)for HIV-infected patients. These results show that saliva of healthyindividuals has anticandidal activity and that this activity isreduced in the saliva of HIV-infected patients. These findingsmay help explain the greater incidence of oral candidal infectionsfor individuals withAIDS.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Saliva contains many antifungal proteins, e.g., histatins (16), lysozyme (6, 13, 24), lactoferrin (8, 11), andsecretory immunoglobulin A. Several studies have demonstratedassociations between oral candidal status and concentrations ofsalivary histatins (1, 5) or lysozyme (25). Methods todirectly evaluate anticandidal activities of saliva have beenreported previously (21). These assays are based on the abilityof saliva to inhibit blastoconidial viability of Candida albicansor to inhibit the formation of germ tubes by C. albicans. Typically,C. albicans organisms grow as single ellipsoidal cells calledblastoconidia. In the presence of inducing environmental signals,e.g., alterations of pH, temperature, and nutrients, C. albicanscan assume a hyphal and/or pseudohyphal form (3). Germ tubeformation is the first step in the conversion of blastoconidiato hyphal form. Human saliva from healthy individuals will inhibitC. albicans blastoconidial viability and will inhibit the formationof germ tubes by C. albicans (21). Previous reports show thatsalivary anticandidal activities are severely compromised in AIDSpatients (18).

Assays of salivary antifungal capacities are useful for investigation of the pathogenesis of oral candidal infections. However,such investigations are limited, perhaps because the current methodsrequire a minimum of 1 ml of saliva for a single assay. In casesof hyposalivation or xerostomia, a common occurrence for humanimmunodeficiency virus (HIV)-AIDS patients (21, 25), the abilityto obtain 1 ml of saliva can be difficult. In the present study,we have modified existing anticandidal assays for use with smallerquantities of saliva and we have optimized the assay conditionsfor these modified methods. We have used these assays to characterizesalivary anticandidal activities against several strains of Candidaisolated from different body sites. We also used these assaysagainst Candida strains which were either resistant or susceptibleto the antifungal drug fluconazole. Finally, we used these assaysto characterize the anticandidal activities of stimulated wholesaliva obtained from a cohort of HIV-AIDSpatients.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Subjects. To develop and characterize the microanticandidal assays, multiple stimulated whole- and glandular saliva samples were collectedfrom four medically healthy male volunteers. The mean age was41 years with a range from 26 to 52 years. These volunteers tooknomedications.

These anticandidal microassays were used to characterize the anticandidal activity of the saliva of HIV-AIDS patients (n =12 males; 39 ± 6.7 years) who were recruited from participantsin the Fluconazole Efficacy Study (T. F. Patterson, Departmentof Medicine, University of Texas Health Science Center at SanAntonio). The mean CD4⁺ lymphocyte count was 162.4 ± 165.0 cells/µl (mean ± standarddeviation [SD]). All patients were taking anti-HIV and/or anti-AIDSmedications including lamivudine, stavudine, zudovudine, didanosine(ddI), delavirdine, nevirapine, indinavir, nelfinavir, ritonavir,or saquinavir. No patient took fluconazole or other anticandidalmedications at the time of saliva collection. Stimulated whole-salivasamples collected from 17 male healthy volunteers (23 to 53 yearsold with a mean of 31 years) were used as controls for the studieswith the HIV-AIDSpatients.

This study was approved by the Institutional Review Boards of the University of Texas Health Science Center at San Antonioand the Audie L. Murphy Division, South Texas Veterans HealthCare System. Informed consent was obtained from allparticipants.

Saliva collection and treatment. Stimulated whole saliva was obtained by having subjects chew paraffin wax. Stimulated parotid saliva was obtained by usinga modified Carlson-Crittenden cup placed over Stenson's duct andheld in place with gentle suction (23). Submandibular-sublingualsaliva was collected with gentle suction by using a plastic micropipette(4) held at the orifices of Wharton's and Bartholin's ductsin the floor of the mouth (26). For stimulation of glandularsaliva, the dorsolateral surfaces of the tongue were swabbed witha 2% citric acid solution at intervals of 30 s. The saliva collectiontime was 5 min. The collected saliva was immediately placed onice. All saliva samples were adjusted to pH 4.5 with glacial aceticacid. For whole-saliva samples, 2 mM phenylmethylsulfonyl fluoride(PMSF) was added to prevent proteolysis. The acidified salivawas boiled for either 2.5 (parotid and submandibular-sublingualsaliva) or 10 (whole saliva) min. After cooling on ice for 20min, the samples were centrifuged (16,000 × g, IEC CentraMP4Rcentrifuge, rotor 851, 4°C) for 30 min. These treatments effectivelyremoved all endogenous Candida organisms from all types of saliva.The supernatant was either used immediately for antifungal assaysor stored at $-$ 70°C.

Saliva pool for assay control. Stimulated whole saliva was collected from several healthy donors, and the salivas were combined. This saliva pool was processedas described above, and the supernatant was stored in small aliquotsat $-$ 70°C. When patient and healthy control samples were evaluated,a sample of this pool was included on each day to ensure assayreproducibility. If the percent inhibition for this assay controlpool was less than 90%, the saliva samples were evaluated againon anotherday.

Assay of salivary inhibition of blastoconidial viability. The C. albicans isolates used in this project were isolated from HIV-AIDS patients. These isolates were from different bodysites and had different susceptibilities to the anticandidal drugfluconazole. An isolate was considered fluconazole sensitive whenthe MIC of fluconazole was $<=$ 8 µg/ml. The MICs for the two fluconazole-resistantisolates (2520 and 566) were $>=$ 64 µg/ml.

The microassay of salivary inhibition of blastoconidial viability was performed by modifications of the method of Pollocket al. (18). C. albicans organisms were grown to late log phase(optical density of 1.4 to 1.6 at 600 nm). After centrifugationat 16,000 × g for 5 min at 4°C and washing with sterilized water,the Candida suspension was adjusted to 3 × 10⁶ CFU/ml with 25 mM sodium acetate buffer (pH 4.5). The incubationmixture contained 5 µl of Candida suspension and either 95 µlof saliva or 95 µl of 25 mM sodium acetate buffer (control). Theincubation time for this mixture was 1 h at 37°C for stimulatedparotid or submandibular-sublingual saliva and 4 h for whole saliva.After this incubation, the mixture was diluted 100-fold with 25mM MES [2-(N-morpholino)ethanesulfonic acid] buffer (pH 6). Thediluted mixture was then further incubated at 37°C for 4 h (glandularsaliva samples) or 3 h (whole-saliva samples). After this secondincubation, 100 µl was inoculated onto a Sabouraud dextrose agarplate containing chloramphenicol (0.01%). The CFU were countedafter 24 h of incubation at 37°C. The percent inhibition of blastoconidialviability for each sample was calculated in comparison with thecontrol (containing no saliva) according to the following formula:[1 $-$ (CFU in saliva/CFU in buffer control)] × 100. Duplicate determinationswere done for each sample. All patient and healthy control salivaryassays included a pooled saliva sample (described above) as anassaycontrol.

Assay of salivary inhibition of germ tube formation. The salivary germ tube inhibition microassay was performed by modifications of the method described by Santarpia et al. (21).Late-log-phase C. albicans (optical density per milliliter of1.4 to 1.6 at 600 nm) or a static colony (diluted to 3 × 10⁷ CFU/ml in water) was used. The assay mixture for parotid andsubmandibular-sublingual saliva contained 6.5 µl of 27.2 mg offilter-sterilized N-acetylglucosamine per ml, 15 µl of fetal bovineserum (FBS), 10 µl of the freshly prepared Candida suspension,and either 50 µl of saliva or 50 µl of 20 mM acetate buffer (control).In order to obtain optimal conditions for germ tube formationin the whole-saliva assay system, 32.5 µl of FBS was required.After incubation for 3 h at 37°C, the mixture was sonicated for15 min. An aliquot of the mixture was examined under an Olympusmicroscope (magnification, ×400). A total of 300 blastoconidiaand germ tubes were counted, and the percent inhibition of blastoconidialgermination was calculated according to the following formula:[1 $-$ (% germ tubes in saliva/% germ tubes in buffer control)]×100.

Statistical analysis. The data in the text is given as the mean ± 1 SD or as the median and the 25th to 75th percentile. Analysis of variance wasused to study the differences in susceptibility of different Candidaisolates to saliva inhibition. The nonparametric Mann-WhitneyU test was used to compare the differences in salivary anticandidalactivities and flow rates between the HIV-positive cohort andthe healthygroup.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Anticandidal activities could be demonstrated with small quantities (50 to 100 µl) of saliva. Two oral C. albicans isolatesfrom AIDS patients (1215 and 566) were used during the characterizationof salivary anticandidal assays. Since the results with the twostrains were similar, only the results for saliva against isolate1215 are presented in Table 1. The data shown in Table 1 isthe result of multiple saliva samples taken at different timesfrom a single healthy volunteer. All saliva samples, i.e., parotid,submandibular-sublingual, and whole saliva, had strong inhibitionof both C. albicans blastoconidial viability and germ tube formation.Similar anticandidal activities were observed for three otherhealthy subjects (data not shown).

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TABLE 1. Anticandidal activities in whole and glandular saliva collected from a single healthy subject^a

The inhibition of blastoconidial viability against a variety of C. albicans isolates was examined in stimulated whole, parotid,and submandibular-sublingual saliva. The data is shown in Table2. In these assays, whole and submandibular-sublingual salivawere from a single donor while the parotid saliva studies usedsaliva from two individuals. Since the methods to analyze anticandidalactivities in individual glandular and whole saliva were slightlydifferent, a comparison of anticandidal activities among wholesaliva, parotid saliva, and submandibular-sublingual saliva wasnot performed. There were significant differences among the salivatypes in the susceptibilities of different Candida isolates toinhibition of blastoconidial viability (P < 0.001 for each salivatype). In order to see if salivary inhibition of blastoconidialviability was related to fluconazole sensitivity, strains of fluconazole-sensitiveand -resistant Candida were included. Strong salivary inhibitionof blastoconidial viability was detected for all Candida isolates,regardless of fluconazole sensitivity or resistance. The rangeof salivary inhibition of blastoconidial viability was 98.5 to55.3% for whole saliva, 97.9 to 68.3% for parotid saliva, and91.3 to 21.3% for submandibular-sublingual saliva. This data suggeststhat the susceptibilities of different candidal isolates to inhibitionof blastoconidial viability by saliva might be independent ofbody site of isolation and the susceptibility of the Candida strainto fluconazole. The salivary inhibition of blastoconidial viabilityagainst isolates from blood (593) and vagina (2520, 456, and 3741)was comparable to that for isolates from the oral cavity (566,1215, and 969). Two isolates (540, an oral isolate, and 546, isolatedfrom blood) appeared to be more resistant to salivary inhibitionof blastoconidial viability. Both isolates were susceptible tofluconazole, an antifungal drug. Our preliminary studies alsosuggest that there was no apparent difference in salivary inhibitionof blastoconidial viability between Candida organisms isolatedfrom AIDS patients (1215 and 566) and those from patients withdenture stomatitis (data not shown).

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TABLE 2. Salivary inhibition of blastoconidial viability with different Candida isolates^a

Germ tube formation of all tested Candida isolates was also inhibited by whole, parotid, and submandibular-sublingual saliva.The susceptibilities of six candidal isolates to inhibition ofgerm tube formation by parotid saliva (>86.3%) and submandibular-sublingualsaliva (73 to 95%) are shown in Fig. 1. Again, this data suggeststhat there were no differences specifically related to isolationsite or to fluconazole susceptibility.

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FIG. 1. Salivary inhibition of germ tube formation with different Candida isolates. The saliva of a healthy person was used. The height of the column indicates the mean percentage of inhibition with the SD being indicated by the error bars. The mean is based on three separate determinations. Closed columns indicate stimulated parotid saliva (SP), while open columns indicate stimulated submandibular-sublingual saliva (SS).

Anticandidal activities in paraffin-chewing-stimulated whole saliva of 12 HIV-infected patients and 17 healthy controls wereevaluated by these anticandidal assay methods. The HIV-infectedindividuals had significantly lower (~40%) median salivary flowrates than those of healthy controls (P < 0.05, Table 3). Isolates1215 and 540 were used to study salivary inhibition of blastoconidialviability, whereas isolates 1215 and 566 were used to study salivaryinhibition of germ tube formation. Almost all saliva samples fromthe healthy controls had 100% inhibition of both blastoconidialviability and germ tube formation. The median inhibition of blastoconidialviability by saliva from HIV-positive patients was significantlylower than that of the controls (P < 0.05, Table 3). The mediansalivary inhibition of Candida germ tube formation was also significantlyreduced in HIV-positive patients compared to that for controls(P < 0.001, Table 3).

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TABLE 3. Comparison of anticandidal activities for whole saliva from HIV-positive patients and healthy controls^a

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this study, we have modified published salivary anticandidal assays (21) for use with smaller quantities of saliva, andwe have further characterized these assays. Using these in vitrobioassays, we have demonstrated that stimulated whole, parotid,and submandibular-sublingual saliva have strong anticandidal activities,i.e., inhibition of blastoconidial viability and inhibition ofgerm tube formation. Saliva appears to have a very broad spectrumof anticandidal activities. Although the susceptibilities of Candidaisolates to saliva may be varied, the relative susceptibilityor resistance of different C. albicans isolates to saliva wasnot related to the body site of isolation or to fluconazole resistanceor susceptibility (Table 2 and Fig. 1).

Although saliva contains many antifungal proteins, it also contains the nutrients for Candida growth (5, 17). Therefore,salivary inhibition of blastoconidial viability in vitro can bedetected only indirectly. The assay for inhibition of blastoconidialviability is based on damage of the C. albicans cell membraneby preincubation in saliva followed by incubation in a nonnutrientbuffer leading to the inability of the organism to grow (21).As indicated in the previous report (21), the assay for inhibitionof blastoconidial viability was sensitive to pH, saliva preincubationtime, boiling time, and yeast cell concentration. We found thatthe saliva sample could be stored at a low temperature and successfullyused for the anticandidal assays if the saliva had been acidifiedand boiled before freezing. If the saliva samples were frozenbefore being acidified and boiled, about 40% of the activity forinhibition of blastoconidial viability was lost (data not shown).Studies have also suggested that germinated Candida organismsare less susceptible to killing by other salivary anticandidalproteins, i.e., histatins (24). We have tested the salivaryinhibitory activities toward germinated Candida and blastoconidiaby using glandular saliva. There was no difference in salivaryinhibition of Candida blastoconidial viability between these twoforms (data notshown).

In our assay, a relatively high yeast-to-saliva ratio was used, which should increase the possible detection of mild alterationsin salivary inhibition of blastoconidial viability. The proteaseinhibitor, PMSF, was not needed in the previous report, for whicha larger quantity of saliva was used in the assay (21). However,in our study, the addition of the protease inhibitor PMSF wascritical to preserve the inhibition of blastoconidial viabilityfor treated whole saliva. However, it is possible that PMSF couldhave a negative effect on germ tube formation. Previous studieshave shown that germ tube formation is dependent on the concentrationsof serum (3a). We found that the concentration of FBS in theincubation mixture had to be almost doubled (increased from 18%in the non-PMSF-treated glandular saliva samples to 33% in thePMSF-treated whole-saliva samples) for germ tube formation tooccur at a low level in the saliva-treated sample. By increasingthe FBS concentration for the whole-saliva samples so that a lowlevel of germ tube formation occurred in saliva from healthy people,we believe we have overcome any negative effect of PMSF on germtubeformation.

It has been suggested that the hyphal form of Candida is more virulent than the blastoconidial form in vivo. Formation ofhyphae appears to enhance the adhesion of Candida to host epithelialcells and also to enhance tissue invasion (7, 20). In vitro,saliva inhibition of germ tube formation is dependent on the concentrationsof FBS and yeast cells as well as pH (2, 21). In our assaysystem, 18 and 33% FBS were found to be the optimal concentrationsfor glandular saliva and whole saliva, respectively. Unlike theprevious report, which used water for the control in the germtube formation assays (21), we used a sodium acetate buffer(25 mM, pH 4.5) as the control germination mixture, since salivasamples were acidified to 4.5 with acetic acid immediately aftercollection. We found that germ tube formation with use of acetatebuffer for the control was reduced (approximately 20%; data notshown) compared to that with use ofwater.

Oral candidal infection is a common oral manifestation in HIV-infected patients (9, 14). HIV-positive patients usuallyhave lower salivary flow rates, as demonstrated in our study.Most of our HIV-infected cohort were taking multiple anti-HIVdrugs as well as drugs for management of HIV infection. Many ofthese are known to cause mouth dryness. A small proportion ofthe HIV-positive subjects may develop Sjögren's-like syndromeduring the course of HIV infection (22). Several studies havedemonstrated a relationship between the occurrence of oral candidiasisand a decreased salivary flow rate (12, 14). In our currentstudy, we have used our anticandidal microassays to demonstratethat the salivary anticandidal activities of whole saliva arecompromised in HIV-positive patients. These results confirm observationsof a previous study (18) which demonstrated that stimulatedwhole, parotid, and submandibular-sublingual saliva from AIDSpatients had decreased salivary anticandidal activities (12).Both the inhibition of blastoconidial viability and the inhibitionof germ tube formation in whole saliva were reduced in our HIV-positivepatients. Reductions of concentrations or activities of salivaryantifungal proteins, such as histatins and secretory immunoglobulinA, may account for the loss of anticandidal activities in HIV-positivepatients (10, 15, 19). Current investigations in our laboratoryare studying whether salivary antifungal components are alteredin these HIV-positive patients and whether there is a relationshipbetween salivary anticandidal activities and the progression ofHIVinfection.

In conclusion, we have modified salivary anticandidal assays for use with small volumes of saliva. The requirement for smallervolumes of saliva enables the study of salivary anticandidal activitiesin subjects with very low flow rates. We have found that humansaliva has strong anticandidal activities and that there is adecrease in the salivary anticandidal activities in severely immunocompromisedpatients. This loss of salivary anticandidal activity in AIDSpatients merits furtherelucidation.

	ACKNOWLEDGMENTS

This work was supported by Public Health Service grants DE-12188 (to C.-K.Y.) and DE-11381 (to T.F.P.) from the National Instituteof Dental and CraniofacialResearch.

We also acknowledge the contributions of Jose L. Lopez-Ribot and MartaCaceres.

	FOOTNOTES

^* Corresponding author. Mailing address: Geriatric Research, Education and Clinical Center (182), Audie L. Murphy Division,South Texas Veterans Health Care System, San Antonio, TX 78284.Phone: (210) 617-5197. Fax: (210) 617-5312. E-mail: yeh{at}uthscsa.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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5. Jainkittivong, A., D. A. Johnson, and C.-K. Yeh. 1998. The relationship of salivary histatin levels and oral Candida carriage. Oral Microbiol. Immunol. 13:181-187[Medline].

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Antimicrob. Agents Chemother.	Clin. Microbiol. Rev.	Infect. Immun.
J. Clin. Microbiol.	J. Virol.	ALL ASM JOURNALS

1.	Atkinson, J. C., C.-K. Yeh, F. G. Oppenheim, D. Bermudez, B. J. Baum, and P. C. Fox. 1990. Evaluation of salivary antimicrobial proteins following HIV-1 infection. J. Acquir. Immune Defic. Syndr. 3:41-48.
2.	Brant, E. C., R. P. Santarpia III, and J. J. Pollock. 1990. The role of pH in salivary histidine-rich polypeptide antifungal germ tube inhibitory activity. Oral Microbiol. Immunol. 5:336-339[Medline].
3.	Buffo, J., M. A. Herman, and D. R. Soll. 1984. A characterization of pH-regulated dimorphism in Candida albicans. Mycopathologia 85:21-30[Medline].
3a.	Dabrowa, N., J. W. Landau, and V. D. Newcomer. 1965. The antifungal activity of physiologic saline in serum. J. Invest. Dermatol. 45:368-377[Medline].
4.	Fox, P. C. 1989. Saliva composition and its importance in dental health. Compend. Contin. Educ. Dent. Suppl. 13:S457-S460.
5.	Jainkittivong, A., D. A. Johnson, and C.-K. Yeh. 1998. The relationship of salivary histatin levels and oral Candida carriage. Oral Microbiol. Immunol. 13:181-187[Medline].
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