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Research Article

Unbiased Proteomics Analysis Demonstrates Significant Variability in Mucosal Immune Factor Expression Depending on the Site and Method of Collection

  • Kenzie M. Birse equal contributor,

    equal contributor Contributed equally to this work with: Kenzie M. Birse, Adam Burgener

    Affiliations: Department of Medical Microbiology, University of Manitoba, Winnipeg, Manitoba, Canada, Proteomics Group, National Lab for HIV Immunology, Public Health Agency of Canada, Winnipeg, Manitoba, Canada

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  • Adam Burgener equal contributor,

    equal contributor Contributed equally to this work with: Kenzie M. Birse, Adam Burgener

    Affiliations: Department of Medical Microbiology, University of Manitoba, Winnipeg, Manitoba, Canada, Proteomics Group, National Lab for HIV Immunology, Public Health Agency of Canada, Winnipeg, Manitoba, Canada, National Lab for HIV Immunology, Public Health Agency of Canada, Winnipeg, Manitoba, Canada

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  • Garrett R. Westmacott,

    Affiliation: Mass Spectrometry Core Facility, National Microbiology Laboratory, Public Health Agency of Canada, Winnipeg, Manitoba, Canada

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  • Stuart McCorrister,

    Affiliation: Mass Spectrometry Core Facility, National Microbiology Laboratory, Public Health Agency of Canada, Winnipeg, Manitoba, Canada

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  • Richard M. Novak,

    Affiliation: Section of Infectious Diseases, University of Illinois, Chicago, Illinois, United States of America

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  • T. Blake Ball mail

    tball@cc.umanitoba.ca

    Affiliations: Department of Medical Microbiology, University of Manitoba, Winnipeg, Manitoba, Canada, Proteomics Group, National Lab for HIV Immunology, Public Health Agency of Canada, Winnipeg, Manitoba, Canada, Department of Medical Microbiology, University of Nairobi, Nairobi, Kenya, National Lab for HIV Immunology, Public Health Agency of Canada, Winnipeg, Manitoba, Canada

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  • Published: November 14, 2013
  • DOI: 10.1371/journal.pone.0079505
  • Published in PLOS ONE

Abstract

Female genital tract secretions are commonly sampled by lavage of the ectocervix and vaginal vault or via a sponge inserted into the endocervix for evaluating inflammation status and immune factors critical for HIV microbicide and vaccine studies. This study uses a proteomics approach to comprehensively compare the efficacy of these methods, which sample from different compartments of the female genital tract, for the collection of immune factors. Matching sponge and lavage samples were collected from 10 healthy women and were analyzed by tandem mass spectrometry. Data was analyzed by a combination of differential protein expression analysis, hierarchical clustering and pathway analysis. Of the 385 proteins identified, endocervical sponge samples collected nearly twice as many unique proteins as cervicovaginal lavage (111 vs. 61) with 55% of proteins common to both (213). Each method/site identified 73 unique proteins that have roles in host immunity according to their gene ontology. Sponge samples enriched for specific inflammation pathways including acute phase response proteins (p = 3.37×10−24) and LXR/RXR immune activation pathways (p = 8.82×10−22) while the role IL-17A in psoriasis pathway (p = 5.98×10−4) and the complement system pathway (p = 3.91×10−3) were enriched in lavage samples. Many host defense factors were differentially enriched (p<0.05) between sites including known/potential antimicrobial factors (n = 21), S100 proteins (n = 9), and immune regulatory factors such as serpins (n = 7). Immunoglobulins (n = 6) were collected at comparable levels in abundance in each site although 25% of those identified were unique to sponge samples. This study demonstrates significant differences in types and quantities of immune factors and inflammation pathways collected by each sampling technique. Therefore, clinical studies that measure mucosal immune activation or factors assessing HIV transmission should utilize both collection methods to obtain the greatest representation of immune factors secreted into the female genital tract.

Introduction

Mucosal secretions provide a barrier against invading pathogens and microorganisms. In the case of HIV-1, heterosexual intercourse is the main route of new infections [1], making the mucosa of the female genital tract (FGT) the first site of contact for male to female HIV-1 transmission. This mucosal surface is complex, and contains an abundance of soluble innate immune factors that are important for HIV-1 acquisition. Such factors include RANTES [2] MIPα, MIPβ, SLPI [3], Elafin [4], [5], LL-37 [6], α/β-defensins [7], [8], Lysozyme, Lactoferrin, Calprotectin, Histone H2A [9], Cystatins, Serpins [10] as well as many other anti-proteases [11]. The composition and balance of these factors may influence susceptibility to HIV-1, as shown in studies of HIV-exposed seronegative (HESN) individuals and individuals who succumb to infection [4], [11][16]. These factors may have an impact on local viral replication, establishing the viral load set point and the rate of disease progression [17]. Also, follow-up studies to determine the correlates of protection in HIV vaccines that have shown promise such as the Thai RV144 trial [18] have emphasized the importance of mucosal immune responses in reduced acquisition [19]. Therefore, it is critical that these factors are properly measured to understand early events in HIV pathogenesis and transmission.

Recent clinical trials have indicated that increased immune activation in the FGT has been attributed to increased risk of HIV-infection. The importance of mucosal inflammation was exemplified by the failure of the detergent microbicide, nonoxynol-9, which increased HIV-infection risk and was associated with an increase in inflammation status in the FGT [20]. Furthermore, the lack of efficacy in the Centre for AIDS Programme of Research in South Africa (CAPRISA-004) microbicide trial may also have been attributed to increased baseline immune activation and pro-inflammatory cytokine production [16], [21]. However, as the biological determinants of FGT inflammation and the immune pathways important for HIV-susceptibility have not yet been defined, defining techniques and protocols to efficiently and accurately monitor a broad range of factors involved with inflammation and immune activation in the mucosal compartment will be essential for future clinical trials and the development of future intervention technologies.

The most commonly used techniques to sample the FGT mucosa involve the use of cervicovaginal lavages and/or Weck-Cel cervical sponges, which are largely standardised, inexpensive and minimally invasive [22][24]. Each method collects secretions from different compartments of the FGT. Cervicovaginal lavages are designed to collect secretions primarily from the lower FGT, which includes the ectocervix and the vaginal vault, and Weck-Cel cervical sponges are designed to collect secretions primarily from the upper FGT, which includes the endocervix and the endometrium. However, it is unknown which technique and/or site sampled is most informative, and most relevant with respect to inflammation and the collection of immune factors. Although previous studies examining sampling techniques have noted some differences between the methods [23], these have been limited to a small list of pre-defined immune factors such as Secretory leukocyte peptidase inhibitor (SLPI), Human neutrophil peptides (HNP) 1–3, and Lactoferrin, despite the need to measure many other mucosal factors important in HIV-1 susceptibility and inflammation. Therefore, a comprehensive examination is warranted to better evaluate these collection techniques and the sites primarily sampled by each.

This study uses an unbiased systems biology proteomics approach via tandem mass spectrometry to compare FGT secretions using different collection methods to determine the qualitative and quantitative differences in the captured immune factors. Proteomics confers advantages to other methods as it can provide a global view of biological factors in a given sample and has been effective in monitoring the often difficult to measure, mucosal immune responses [11], [12], [14], [25]. The mucosal secretions collected by paired cervicovaginal lavages (CVL) and Weck-Cel cervical sponges (CER) were compared from 10 healthy women. In this study, we show considerable differences in both the number and abundance of mucosal factors identified in either collection method due to both the site of collection and sampling technique.

Materials and Methods

Ethics Statement & Study Population

Study participants were women at low risk for HIV acquisition. To participate they had to meet the following criteria: never used crack, never exchanged sex for money, drugs or shelter, no more than one sexual partner in the last 6 months, no more than 5 sexual partners in the last 5 years, and no history of sexually transmitted infections. Study participation required written, informed consent, and was approved by the human subjects committee of the University of Illinois at Chicago. All of the participants underwent testing for Bacterial vaginosis, Trichomonas vaginitis, Neisseria gonorrhoeae, and Chlamydia trachomatis at the time of collection. Samples positive for any of these tests were excluded from the study. Participants included in this study were between the ages of 18 to 27 and were not on any form of hormonal contraception. Of the ten individuals included in this study, 8 were in their luteal phase and 2 were in their follicular phase of the menstrual cycle, and 2 out of the 10 had vaginal sex within 24 hours of sample collection. These factors should not confound the data obtained from this study as both CVL and CER samples were collected from the same individual at the same time. Any effect of these factors will be represented equally in sampling techniques.

Cervicovaginal Lavage (CVL) and Weck-Cel Cervical Sponge (CER) Sample Collection

For all participants, a speculum was inserted into the vagina and the cervix was located. Four cotton tipped brushes were used to swab the posterior, lateral, frontal and ectocervical areas of the FGT for standard sexually transmitted infection testing. Next, a Weck-Cel cervical sponge was inserted into the cervical os and allowed to sit for one minute to allow for the collection of secreted factors from the upper FGT, the endocervix and the endometrium. The Weck cells were weighed in spin-x tubes before collection and after collection to determine the volume collected. The volume eluted from each sponge was ~100–200 µL. After the sponge’s removal, the cervicovaginal lavage sample was obtained by washing 10 cc of normal saline over the vaginal vault and ectocervix. The saline lavage solution was then redrawn using the same syringe of which it was instilled. All samples were immediately stored on ice and subsequently frozen at −80°C within 1 hour of sample collection.

Protein Digestion and Preparation for MS Analysis

CVL and CER sample protein content was measured by standard BCA protein assay (Novagen). One hundred micrograms from ten CVL samples and ten matching CER samples obtained from the same individual were each individually denatured with urea exchange buffer (8 M Urea GE HealthCare, 50 mM HEPES Sigma, pH 8.0) for 20 minutes at room temperature placed into Nanosep filter cartridges (10 kDa). After centrifugation samples were treated with 25 mM dithiothreitol (Sigma) for 20 minutes, then 50 mM iodoacetamide (Sigma) for 20 minutes, and washed with 50 mM HEPES buffer. Trypsin (Promega) was added (2 µg/100 µg protein) and incubated at 37°C overnight in the cartridge. Peptides were eluted off the filter with 50 mM HEPES, and were dried via vacuum centrifugation. The samples were then cleaned of salts and detergents by reversed-phase liquid chromatography (high pH RP, Agilent 1200 series micro-flow pump, Water XBridge column) using a step-function gradient such that all peptides elute into a single fraction for each sample. The fractions were then dried via vacuum centrifugation and kept at −80°C until analyzed by mass spectrometry.

Mass Spectrometry Analysis

The same amount of total protein from each sample was then prepared for label-free tandem mass spectrometry analysis. Fractions were re-suspended in 2% acetonitrile (Fisher Scientific), 0.1% formic acid (EMD Canada) and injected into a nano-flow LC system (Easy nLC, Thermo Fisher) connected inline to a LTQ Orbitrap XL (Thermo Fisher) mass spectrometer. All spectra were processed using Mascot Distiller v2.3.2 (Matrix Science), and database searching was done with Mascot v2.3 (Matrix Science). Searches were performed against UniProtKB/SwissProt (2012-05) Human (v3.87) database. Label-free protein expression levels based on MS peak intensities were calculated using Progenesis LC-MS software (v4.0 Nonlinear Dynamics). The relative abundance ratios of these proteins were calculated by dividing each value by the average intensity across all samples. Statistical analysis of protein expression was performed by one-way analysis of variance (ANOVA). Complete details of liquid chromatography, mass spectrometry instrument settings, data generation and the complete protein expression data set can be found at our public database (www.corefacility.ca/proteomics/data/burg​ener/pubs/PLOS).

Clustering and Pathway Analysis

Cluster analysis was performed using Cluster software, version 3.0, and data was visualized using TreeView software, version 1.1.5 (13). CVL samples and CER samples were grouped separately in Perseus, version 1.3.0.4 (Max Planck Institute of Biochemistry), and all proteins were filtered based on p-values as determined by One-way ANOVA (p<0.05). Clustering of differentially abundant proteins was generated by unsupervised centroid linkage hierarchical clustering using Pearson correlation coefficient as the distance metric. Each main dendrogram branch specific to the enrichment of proteins based on collection method from the cluster analysis was analyzed by Ingenuity Pathway Analysis (Ingenuity Systems, www.ingenuity.com, Mountain view, CA). The association between proteins in the dataset and the canonical pathways in the Ingenuity Pathway Knowledge base was measured as a ratio of the number of molecules from the data that maps to a pathway divided by the total number of molecules known to map the canonical pathway. A right-tailed Fisher’s Exact Test (with Benjamini-Hochberg multiple testing correction) was used to calculate the p-value of the probability that the association between each protein in the dataset and canonical pathway is random. Pathways with p-values <0.05 and at least 2 proteins selected were considered as potential pathways associated with each branch in the cluster analysis. Functional annotation of the proteins differentially expressed by either collection method was performed using DAVID Bioinformatics Resources (6.7); biological functions were determined based on gene ontologies. Graphical representation of innate factors was constructed using GraphPad Prism (5.0a, GraphPad Software) using Mann-Whitney statistical tests.

Results

Mass Spectrometry Analysis of Mucosal Proteins Identifies Large Numbers of Proteins Specific to Cervicovaginal Lavages and Endocervical Sponge Samples

An unbiased, label-free proteomics approach was used to identify and quantify proteins recovered using the two most commonly used collection methods of mucosal secretions from the FGT. To allow a direct comparison, matching CER and CVL samples were collected from 10 healthy women donors. Protein concentration varied between collection methods as CER samples had an average of 2.65 µg/µL, and CVL samples had an average of 0.63 µg/µL. Based on the determined concentrations, equal amounts of total protein from each sample was then digested, processed and individually analyzed by mass spectrometry as outlined in the Materials and Methods.

A total of 385 unique proteins were identified with high confidence. The relative abundance ratios of these proteins were calculated by dividing each value by the average intensity across all samples. A complete list of proteins and their relative abundance based on sample type are available as supplemental information (Table S1). A Venn diagram was constructed to illustrate the overlap and the number of unique proteins identified by each method (Figure 1). While 213 unique proteins were identified by both sampling techniques, 111 were identified solely in the CER samples, and another 61 unique proteins were exclusive to CVL samples. Of the 213 unique proteins common to both sampling techniques, 73 were found to have roles in immune functions according to their gene ontology.

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Figure 1. Venn diagram of the number of unique proteins collected via either sampling technique.

Weck-Cel cervical sponge (CER) method (111), the cervicovaginal lavage (CVL) method (61), and the number of overlapping proteins identified by both methods (213).

doi:10.1371/journal.pone.0079505.g001

To visually map the differences in protein abundances found in common across each technique, hierarchical clustering analysis was performed on the dataset. The cluster software utilizes algorithms to calculate relatedness between study participants and between protein expression patterns, and then constructs a representative dendrogram. For example, proteins of the same family, or pathway, will group more closely together as compared to proteins from another family. Proteins that showed a differential abundance (p<0.05 as determined by one-way ANOVA) (121) were analyzed using a correlation – uncentered similarity metric and unsupervised centroid linkage hierarchical clustering to produce a hierarchical clustering heat map (Figure 2). A clear pattern emerged in the dendrogram based on the sample collection method used. For example, branch 1 (top branch) clustered 68 proteins that were overabundant in the secretions collected by the CER samples, and branch 2 (bottom branch) clustered 50 proteins that were overabundant in the secretions collected by CVL. The cluster analysis was able to clearly discriminate between sampling techniques by protein abundance, which reflects a bias in each technique’s ability to capture specific protein factors, and the types of factors primarily secreted by each compartment of the FGT.

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Figure 2. Protein abundance patterns differentiate proteins identified and recovered by both collection methods.

the Weck-Cel cervical sponge method (CER) and the cervicovaginal lavage method (CVL) (Proteins shown (121) were identified as differentially abundant by one-way ANOVA (p<0.05)). Clustering of proteins was generated by unsupervised centroid linkage hierarchical clustering using the Pearson correlation coefficient as the distance metric. Protein abundance levels are shown in colour, with red indicating overabundant proteins and green indicating underabundant proteins compared to the median of all samples for either collection method.

doi:10.1371/journal.pone.0079505.g002

Site of Collection and Sampling Technique Differentially Enriches for Specific Inflammation Pathways and Functions

The two branches were further analyzed using Ingenuity Pathway Analysis Software to determine the top pathways associated with the proteins identified using each collection method (Table 1). The top two pathways associated with branch 1 (CER-enriched proteins) were immune activation pathways including the Acute Phase Response Signaling pathway with 20 out of 177 proteins of the pathway identified (p = 3.37×10−24), and the Liver X Receptor/Retinoid X Receptor (LXR/RXR) Activation pathway with 17 out of 136 protein identified (p = 8.82×10−22) in this pathway. Less significant associations were found with branch 2 (CVL-enriched proteins) which corresponded to pathways involved in innate immunity including the IL-17A in Psoriasis pathway with 2 out of 13 proteins identified (p = 5.98×10−4), and the Complement System pathway with 2 out of 35 proteins identified (p = 3.91×10−3). This indicates that pathways involved with acute phase responses; immune activation and innate immunity are differentially enriched depending on the site and collection method.

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Table 1. Protein pathways selectively enriched based on FGT compartment/collection method.

doi:10.1371/journal.pone.0079505.t001

The two major branches of hierarchical clustering map were then further grouped using DAVID Functional Annotation Bioinformatics MicroArray Analysis tool [26], [27], which grouped proteins based on their major biological functions according to their gene ontology (Figure 3). Of those proteins found to be overabundant in secretions from the upper FGT collected via CER samples, 28% had immune response functions. Similarly, but to a lesser degree, 8% of the proteins found to be overabundant in secretions primarily from the lower FGT collected via CVL samples had immune response functions. These slight functional differences can partially be attributed to the differences in unique proteins identified by each method/site. For example, specific defense response proteins found in CER samples included Beta-2-microglobulin, Haptoglobin, and Complement component C3 to name a few, whereas the specific defense response proteins identified in CVL samples differed and included proteins such as Calprotectin (S100-A8/A9), Cathepsin G, and Neutrophil defensin-1. This demonstrates that each method and site of collection collects proteins involved in overlapping immune pathways, but each is differentially enriched for specific members of these pathways. Therefore, specific protein recovery is variable based on either collection method and/or the specific compartment of the FGT from which the secretions were primarily collected.

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Figure 3. The biological functions of the proteins determined via hierarchical cluster analysis.

Proteins associated with Branch 1 (i) and Branch 2 (ii) of the hierarchical cluster analysis according to their gene ontology determined via the functional annotation tool from DAVID Bioinformatics Resources.

doi:10.1371/journal.pone.0079505.g003

Antimicrobial and Immune Mediator Expression Varies Considerably in Abundance between CVL and CER Samples

Antimicrobial factors and other immune regulators with described involvement in mucosal immune activation were examined in greater detail due to their involvement with immune activation as well as antiviral defense. These included antimicrobial and HIV inhibitory factors such as SLPI [3], [28], Defensins [7], [8], Lysozyme C [29], Mucins [30], mucosal IgA [31], [32]; antibacterial factors of the S100 protein family [33], protease inhibitors such as Serpins [10], [34], [35], A2ML1 and Cystatins [11], [29]; and proteases such as Cathepsins [36].

Antimicrobial factors identified from both sites were quantified and the abundance values compared as shown in Figure 4A. Many of these were found to be significantly different between compartments such as Cathepsin G and Lysozyme C which were found to be overabundant in CVL as compared to CER (3-fold increase, p = 0.002 and 1.7-fold increase, p = 0.04, respectively) and Cystatin B which was found to be overabundant in CER as compared to CVL (4.4-fold increase, p = 0.01). Other potential antimicrobial factors (Figure 4B), such as A2ML1, Haptoglobin, and Mucin 16 were found to be differentially abundant based on sampling technique, with A2ML1 overabundant in CVL (2.7-fold increase, p = 0.004,), and Haptoglobin and Mucin-16 overabundant in CER (2.5-fold increase, p = 0.04 and 2.5-fold increase, p = 0.03, respectively).

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Figure 4. Box plots demonstrating the abundances of various immune factors important for host defense.

CER (endocervical sponge, red) and CVL (cervicovaginal lavage, blue). A: General antimicrobial factors, B: Potential antimicrobials, C: S100 calcium-dependent S100 family members, D: Serpin family members, E: Immunoglobulins (heavy chain variants). Significance values are shown as follows: * = <0.05, ** = <0.005 (Mann-Whitney statistical tests).

doi:10.1371/journal.pone.0079505.g004

Many calcium-binding proteins from the S100 Family were identified in both sites using the different collection methods used in this study (Figure 4C). S100 proteins are ion-binding proteins that are known to be associated with native anti-inflammatory processes [37][39]. Certain members were found to be differentially abundant based on sampling technique/compartment, such members include: S100-A4, -A6, -A8, -A9 and -P. Members S100-A4, S100-A6 and S100-P were all found to be significantly overabundant in the CER samples (5.3-fold increase, p<0.0001, 4.8-fold increase p = 0.0007 and 2.8-fold increase, p = 0.01, respectively), and members S100-A8 and S100-A9, also known as Calprotectin were found to be significantly overabundant in CVL (3.8-fold increase, p = 0.01 and 3.6-fold increase, p = 0.01, respectively). Serpins were also recovered by both collection methods, and have recently been described as important factors in HIV-1 susceptibility [12], [15] as they have been shown to be anti-inflammatory proteins and possess inhibitory properties against HIV-1 [10], [34]. Serpin B13 and B3 were significantly overabundant in CVL (2.9-fold increase, p = 0.01 and 3.2-fold increase, p = 0.007, respectively), and Serpin A3 was significantly overabundant in CER (3.4-fold increase, p = 0.03) as shown in Figure 4D. The detection of immunoglobulins was comparable by each method (Figure 4E), but 25% of immunoglobulins detected were only found in CER samples including IgA-2. The statistical distribution of these antimicrobial factors as well as the percentage of participants where an antimicrobial factor was reliably detected (found within +/−1 standard deviation) are shown in Tables 26. A complete list of all proteins identified and their basic statistics are available as supplemental information (Table S2), which can be found at our public database. (www.corefacility.ca/proteomics/data/burg​ener/pubs/PLOS).

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Table 2. Basic abundance variation of general antimicrobial factors collected via Weck-Cel cervical sponge and cervicovaginal lavage as determined by mass spectrometry.

doi:10.1371/journal.pone.0079505.t002
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Table 3. Basic abundance variation of potential antimicrobial factors collected via Weck-Cel cervical sponge and cervicovaginal lavage as determined by mass spectrometry.

doi:10.1371/journal.pone.0079505.t003
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Table 4. Basic abundance variation of S100 calcium-dependent family members collected via Weck-Cel cervical sponge and cervicovaginal lavage as determined by mass spectrometry.

doi:10.1371/journal.pone.0079505.t004
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Table 5. Basic abundance variation of serpin family members collected via Weck-Cel cervical sponge and cervicovaginal lavage as determined by mass spectrometry.

doi:10.1371/journal.pone.0079505.t005
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Table 6. Basic abundance variation of immunoglobulins (heavy chain variants) collected via Weck-Cel cervical sponge and cervicovaginal lavage as determined by mass spectrometry.

doi:10.1371/journal.pone.0079505.t006

Of the 37 identified antimicrobial factors examined here, seven factors (Cathepsin G, Lysozyme C, A2ML1, S100-A8, S100-A9, Serpin B3 and Serpin B13) were recovered at statistically higher amounts in CVL, and another seven different factors (Cystatin B, Mucin-16, Haptoglobin, S100-A4, S100-A6, S100-P, and Serpin A3) were recovered at statistically higher amounts in CER samples. Furthermore, twelve previously described anti-HIV factors were identified in both collection methods: SLPI, Neutrophil defensin-1, Lysozyme C, Cystatin A, DMBT1, and Mucin 5B, Lactotransferrin, Histone H1.5, Histone H2B, Cystatin B, Serpin A1, and Serpin A3. Based on these results, it is clear that the anatomical site of collection and/or method of collection can have a drastic impact on the quantity and type of mucosal factors identified particularly inflammatory and innate immune factors.

Discussion

Mucosal secretions are commonly used to evaluate the expression of innate immune factors and genital immune activation status. This form of evaluation is important for determining the safety and efficacy of HIV-1 prevention technologies such as microbicides and vaccines [22][24]. This study is the first to employ a systems biology approach to qualify the potential factors captured using the two most common sample collection methods in the FGT. Here we found that, each site sampled by its own collection method enriches for different inflammation pathways, and each method collects site-specific abundances of antimicrobial factors including anti-HIV-1 factors.

Immune activation has been identified as a major determinant of HIV-infection risk and the monitoring of these processes will be very important for therapeutic design. These results indicated that specific inflammation pathways were enriched in CER compared to CVL, which included the acute phase response and LXR/RXR activation pathways. These two pathways play significant roles in infection and/or inflammation events. The acute phase response is a major contributor to early-stage resistance against HIV-1 infection [35] and has been shown to be specifically up regulated in HIV-resistant individuals [11]. The LXR/RXR activation pathway causes alterations in lipoprotein metabolism to provide immediate protection to the host from potential damage that may occur during the acute stage of infection. Together, these pathways are meant to provide protection against microbes using non-specific defense mechanisms of the innate immune system. This is consistent with the fact that CER samples represent more of the endocervical secretions, and these soluble mediators may act as a barrier to prevent the invasion of pathogenic organisms into the relatively sterile environment of the uterus. In contrast, the proteins found to be significantly overabundant in CVL were involved in pathways related to the innate immune response. The top two enriched pathways were the role of IL-17A in psoriasis pathway and the complement system pathway. IL-17A plays an essential role in inducing an epithelially-derived antimicrobial response against extracellular pathogens [40]. It has been shown to increase the expression of skin derived antimicrobial peptides including β-defensins, Psoriasin (S100A7) and Calprotectin (S100A8/A9) in keratinocytes [40]. The complement system pathway, a well-known and understood component of the innate immune system, involves a cascade of enzyme activations that bridge the innate and acquired immune systems [41], [42]. This is consistent with the fact that CVL’s represent more proteins from the vaginal vault, which is in constant contact with commensal bacteria and requires these responses to maintain a healthy mucosal barrier. Clearly these collection methods impose a bias to enriched inflammation pathways as they sample specific compartments differentially. This adds yet another layer to the rationale that it is critical to sample both the upper and the lower compartments of the FGT to provide the most comprehensive representation of inflammation responses especially when evaluating mucosal therapeutics.

This proteomic study identified many factors with known HIV inhibitory properties in different mucosal secretions of the FGT, such factors include SLPI, Cystatin A & B, Lactotransferrin, Mucin 5B, Neutrophil defensin 1, Lysozyme C, DMBT1, Histones, Serpin A3 and A1, Calprotectin (S100 A8/A9), and mucosal IgA. Each of these anti-HIV factors were recovered in both CVL and CER; although abundances between compartments varied, with Neutrophil defensin-1, Lysozyme C, Calprotectin and Cystatin A found higher in CVL; Cystatin B and Serpin A3 found higher in CER; and Lactotransferrin, Histone H1.5, Histone H2B, Serpin A1, DMBT1, Mucin 5B and SLPI found in roughly equal amounts regardless of sampling site. The differences in abundances are likely demonstrating a compartmentalized difference in secreted immune function or sampling technique specificity. For example, CVL collects secretions primarily from the lower FGT which consists of the vaginal vault and ectocervix. This compartment is at the forefront of immunological defence, as it is met with the physical stress of sexual intercourse and the constant exposure to commensal microbiota and invasive pathogens [43]. Protection is conferred by a multilayered epithelium as well as numerous immune cells housed within the strata of these layers and submucosa. Conversely, CER samples are designed to collect secretions from the upper FGT, the endocervix and the endometrium. The upper FGT differs from the lower FGT, as its epithelium only consists of a single layer of columnar epithelial cells leaving it even more vulnerable to pathogens. Thus, the upper FGT has different immune mechanisms to compensate for its vulnerability [44]. These differences have been shown through studies examining immune factor expression with the ectocervix secreting the majority of proteins involved in innate immunity such as antiproteases, complement components and antimicrobial factors, while the endometrium secretes proteins mainly involved in tissue development [25]. Interestingly, of the three tissues examined, the endometrium produced many factors, which promote HIV infectivity. This compartmentalized difference is reinforced by the findings of our study which found an overlap in the immune factors collected by CVL and those that are known to be predominant immune factors expressed in the ectocervix [25]. However, Burgener et al.’s study also showed specific factors such as SLPI to be highest in abundance in endocervical tissue, whereas our study did not find a significant difference in CVL versus CER. Reasons for such results may be due to: sample cross contamination between CVL and CER collection, for instance cervical sponges may also collect secretions from the lower FGT upon removal or secretions from the upper FGT may be present in the lower FGT through natural process, or it may be due to certain factors being overexpressed in the tissue itself which is not reflected in the secretions examined. This provides evidence that both sampling techniques should ideally be used when measuring mucosal immune factors.

A previous study that specifically examined sampling techniques including CVL, vaginal swabs and endocervical swabs determined that secretions collected by CVL have higher anti-Escherichia coli activity over swabs, and both endocervical/vaginal swabs and CVL have comparable anti-HIV-1 activity [23]. This antimicrobial activity found in the secretions collected by endocervical/vaginal swabs and CVL is supported by the results of this study as there were a multitude of antimicrobial factors recovered and identified via both CER and CVL collection methods. The presence of high abundance antimicrobials such as S100 A8/A9, Lysozyme C, SLPI, and Defensins in CVL likely had contributing effects to its anti-E. coli activity, although antimicrobial and antiviral activity was not assessed in this study. Therefore, sampling techniques may have an impact on the measured antiviral response against HIV and other FGT infections; this may have important implications for studies and trials that monitor this activity.

It should be noted that there are other non-biological considerations for each collection method. For instance, CVL samples are more dilute than CER samples, which can make detection of low abundance proteins more challenging using mass spectrometry as the detection method. However, CVL provides a large sample volume for testing, typically recovers higher total protein content (assuming a 10 mL wash), and does not require an elution step as with sponges, which could result in protein loss. CER samples are more concentrated, sample more proteins from the upper FGT, but take longer to acquire and have smaller volumes with which to work. Another caveat of our study is the collection methods themselves, as noted above there are differences between swabs and lavages. A vaginal swab would have allowed for a more accurate comparison to an endocervical swab as it would have been a more accurate representation of the lower FGT than a lavage. Yet, the primary goal of our study was to examine the most commonly used sampling techniques of the female genital tract’s mucosa, particularly those that are used in clinical trials. Therefore, we chose to examine cervicovaginal lavage as it is the most highly used method to sample the mucosa of the female genital tract, followed by the endocervical sponge, therefore we felt it was more relevant to study those two collection methods.

There were some limitations to this study that warrant consideration. Although this proteomics technique was able to identify 385 unique proteins, other important immune factors such as cytokines and chemokines were not well represented in the analysis. This is likely due to their low abundance in mucosal secretions, which was below the detection threshold of the mass spectrometer. Therefore, we cannot comment on the impact of sample methodology on these factors. Further studies will also be needed to better dissociate between the type of collection method used and the site of collection to allow better localization of where specific innate factors are being secreted and from what cell types. Still, this study provides foundational information as it compares the most commonly used techniques and demonstrates that each collection method varies considerably in both types of mucosal factors collected as well as their abundances.

In summary, CER samples collected nearly twice as many unique proteins as CVL (111 vs. 61), yet each method still collected method/site-specific abundances of inflammatory pathways and antimicrobial factors. Therefore, neither the CER nor the CVL collection method is superior to the other, but together provide a more comprehensive scope of the immune mediators secreted by both the upper and lower compartments of the FGT. As it is still unclear which factors are important in immune activation of the FGT and/or HIV susceptibility, future research should be prudent to utilize both sampling techniques to obtain the greatest recovery and most accurate measurement of the biomarkers naturally produced in the FGT. This information should be taken into consideration for studies evaluating mucosal immune responses in the development of mucosal therapeutics such as microbicides and vaccines or other aspects of reproductive immunology.

Supporting Information

Table S1.

All proteins identified and quantified via Weck-Cel cervical sponge and cervicovaginal lavage collection methods.

doi:10.1371/journal.pone.0079505.s001

(XLSX)

Table S2.

Basic abundance variation of all proteins collected via Weck-Cel cervical sponge and cervicovaginal lavage as determined by mass spectrometry.

doi:10.1371/journal.pone.0079505.s002

(XLSX)

Acknowledgments

We would like to express our gratitude to all study subjects for their participation, and many thanks to Fiona Lynch and Ellen Verlen for sample collection. We would also like to thank Max Abou and Dr. Patrick Chong, Ph.D. for their technical support.

Author Contributions

Conceived and designed the experiments: KMB AB RN TBB. Performed the experiments: KMB SM. Analyzed the data: KMB GRW. Contributed reagents/materials/analysis tools: AB GRW RN TBB. Wrote the paper: KMB AB.

References

  1. 1. UNAIDS (2011) UNAIDS World AIDS Day Report 2011.
  2. 2. Cocchi F, DeVico AL, Garzino-Demo A, Arya SK, Gallo RC, et al. (1995) Identification of RANTES, MIP-1 alpha, and MIP-1 beta as the major HIV-suppressive factors produced by CD8+ T cells. Science 270: 1811–1815. doi: 10.1126/science.270.5243.1811
  3. 3. McNeely TB, Dealy M, Dripps DJ, Orenstein JM, Eisenberg SP, et al. (1995) Secretory leukocyte protease inhibitor: a human saliva protein exhibiting anti-human immunodeficiency virus 1 activity in vitro. J Clin Invest 96: 456–464. doi: 10.1172/jci118056
  4. 4. Iqbal SM, Ball TB, Levinson P, Maranan L, Jaoko W, et al. (2009) Elevated elafin/trappin-2 in the female genital tract is associated with protection against HIV acquisition. AIDS 23: 1669–1677. doi: 10.1097/qad.0b013e32832ea643
  5. 5. Ghosh M, Shen Z, Fahey JV, Cu-Uvin S, Mayer K, et al. (2010) Trappin-2/Elafin: a novel innate anti-human immunodeficiency virus-1 molecule of the human female reproductive tract. Immunology 129: 207–219. doi: 10.1111/j.1365-2567.2009.03165.x
  6. 6. Levinson P, Choi RY, Cole AL, Hirbod T, Rhedin S, et al. (2012) HIV-neutralizing activity of cationic polypeptides in cervicovaginal secretions of women in HIV-serodiscordant relationships. PLoS One 7: e31996. doi: 10.1371/journal.pone.0031996
  7. 7. Quinones-Mateu ME, Lederman MM, Feng Z, Chakraborty B, Weber J, et al. (2003) Human epithelial beta-defensins 2 and 3 inhibit HIV-1 replication. AIDS 17: F39–48. doi: 10.1097/00002030-200311070-00001
  8. 8. Tanabe H, Ouellette AJ, Cocco MJ, Robinson WE Jr (2004) Differential effects on human immunodeficiency virus type 1 replication by alpha-defensins with comparable bactericidal activities. J Virol 78: 11622–11631. doi: 10.1128/jvi.78.21.11622-11631.2004
  9. 9. Cole AM (2006) Innate host defense of human vaginal and cervical mucosae. Curr Top Microbiol Immunol 306: 199–230.
  10. 10. Shapiro L, Pott GB, Ralston AH (2001) Alpha-1-antitrypsin inhibits human immunodeficiency virus type 1. FASEB J 15: 115–122. doi: 10.1096/fj.00-0311com
  11. 11. Burgener A, Rahman S, Ahmad R, Lajoie J, Ramdahin S, et al. (2011) Comprehensive proteomic study identifies serpin and cystatin antiproteases as novel correlates of HIV-1 resistance in the cervicovaginal mucosa of female sex workers. J Proteome Res 10: 5139–5149. doi: 10.1021/pr200596r
  12. 12. Burgener AB, Boutilier J, Wachihi C, Kimani J, Carpenter M, et al. (2008) Identification of differentially expressed proteins in the cervical mucosa of HIV-1-resistant sex workers. J Proteome Res 7: 4446–4454. doi: 10.1021/pr800406r
  13. 13. Broliden K (2010) Innate molecular and anatomic mucosal barriers against HIV infection in the genital tract of HIV-exposed seronegative individuals. J Infect Dis 202 Suppl 3S351–355. doi: 10.1086/655964
  14. 14. Burgener A, Mogk K, Westmacott G, Plummer F, Ball B, et al.. (2012) Salivary basic proline-rich proteins are elevated in HIV-exposed seronegative men who have sex with men. AIDS.
  15. 15. Lajoie J, Juno J, Burgener A, Rahman S, Mogk K, et al. (2012) A distinct cytokine and chemokine profile at the genital mucosa is associated with HIV-1 protection among HIV-exposed seronegative commercial sex workers. Mucosal Immunol 5: 277–287. doi: 10.1038/mi.2012.7
  16. 16. Sokal DC, Karim QA, Sibeko S, Yende-Zuma N, Mansoor LE, et al. (2013) Safety of tenofovir gel, a vaginal microbicide, in South African women: results of the CAPRISA 004 Trial. Antivir Ther. 18: 301–10. doi: 10.3851/imp2311
  17. 17. Borrow P, Shattock RJ, Vyakarnam A (2010) Innate immunity against HIV: a priority target for HIV prevention research. Retrovirology 7: 84. doi: 10.1186/1742-4690-7-84
  18. 18. Rerks-Ngarm S, Nitayaphan S, Kaewkungwal J, Chiu J, Paris R, et al. (2009) Vaccination with ALVAC and AIDSVAX to prevent HIV-1 infection in Thailand. N Enlg J Med 361: 2209–2220. doi: 10.1056/nejmoa0908492
  19. 19. Rerks-Ngarm S, Paris RM, Chunsutthiwat S, Premsri N, Namwat C, et al. (2013) Extended evaluation of the virologic, immunologic, and clinical course of volunteers who acquiredHIV-1 infection in a phase III vaccine trial of ALVAC-HIV and AIDSVAX(R) B/E. J Infect Dis. 207: 1195–205. doi: 10.1093/infdis/jis478
  20. 20. Klasse PJ, Shattock RJ, Moore JP (2006) Which topical microbicides for blocking HIV-1 transmission will work in the real world? PLoS Med 3: e351. doi: 10.1371/journal.pmed.0030351
  21. 21. Naranbhai V, Karim SS, Altfeld M, Samsunder N, Durgiah R, et al. (2012) Innate Immune activation enhances HIV acquisition in women, diminishing the effectiveness of tenofovir microbicide gel. J Infect Dis. 206: 993–1001. doi: 10.1093/infdis/jis465
  22. 22. Cummins JE Jr, Doncel GF (2009) Biomarkers of cervicovaginal inflammation for the assessment of microbicide safety. Sex Transm Dis 36: S84–91. doi: 10.1097/olq.0b013e3181994191
  23. 23. Dezzutti CS, Hendrix CW, Marrazzo JM, Pan Z, Wang L, et al. (2011) Performance of swabs, lavage, and diluents to quantify biomarkers of female genital tract soluble mucosal mediators. PLoS One 6: e23136. doi: 10.1371/journal.pone.0023136
  24. 24. Keller MJ, Herold BC (2009) Understanding basic mechanisms and optimizing assays to evaluate the efficacy of vaginal microbicides. Sex Transm Dis 36: S92–95. doi: 10.1097/olq.0b013e318199417d
  25. 25. Burgener A, Tjernlund A, Kaldensjo T, Abou M, McCorrister S, et al. (2013) A systems biology examination of the human female genital tract shows compartmentalization of immune factor expression. J Virol. 87: 5141–50. doi: 10.1128/jvi.03347-12
  26. 26. Huang da W, Sherman BT, Lempicki RA (2009) Systematic and integrative analysis of large gene lists using DAVID bioinformatics resources. Nat Protoc 4: 44–57. doi: 10.1038/nprot.2008.211
  27. 27. Huang da W, Sherman BT, Lempicki RA (2009) Bioinformatics enrichment tools: paths toward the comprehensive functional analysis of large gene lists. Nucleic Acids Res 37: 1–13. doi: 10.1093/nar/gkn923
  28. 28. Hirbod T, Reichard C, Hasselrot K, Soderlund J, Kimani J, et al. (2008) HIV-1 neutralizing activity is correlated with increased levels of chemokines in saliva of HIV-1-exposed uninfected individuals. Curr HIV Res 6: 28–33. doi: 10.2174/157016208783571964
  29. 29. Venkataraman N, Cole AL, Svoboda P, Pohl J, Cole AM (2005) Cationic polypeptides are required for anti-HIV-1 activity of human vaginal fluid. J Immunol 175: 7560–7567. doi: 10.4049/jimmunol.175.11.7560
  30. 30. Habte HH, de Beer C, Lotz ZE, Roux P, Mall AS (2010) Anti-HIV-1 activity of salivary MUC5B and MUC7 mucins from HIV patients with different CD4 counts. Virol J 7: 269. doi: 10.1186/1743-422x-7-269
  31. 31. Kaul R, Trabattoni D, Bwayo JJ, Arienti D, Zagliani A, et al. (1999) HIV-1-specific mucosal IgA in a cohort of HIV-1-resistant Kenyan sex workers. AIDS 13: 23–29. doi: 10.1097/00002030-199901140-00004
  32. 32. Devito C, Hinkula J, Kaul R, Lopalco L, Bwayo JJ, et al. (2000) Mucosal and plasma IgA from HIV-exposed seronegative individuals neutralize a primary HIV-1 isolate. AIDS 14: 1917–1920. doi: 10.1097/00002030-200009080-00006
  33. 33. Morizane S, Gallo RL (2012) Antimicrobial peptides in the pathogenesis of psoriasis. J Dermatol 39: 225–230. doi: 10.1111/j.1346-8138.2011.01483.x
  34. 34. Munch J, Standker L, Adermann K, Schulz A, Schindler M, et al. (2007) Discovery and optimization of a natural HIV-1 entry inhibitor targeting the gp41 fusion peptide. Cell 129: 263–275. doi: 10.1016/j.cell.2007.02.042
  35. 35. Kramer HB, Lavender KJ, Qin L, Stacey AR, Liu MK, et al. (2010) Elevation of intact and proteolytic fragments of acute phase proteins constitutes the earliest systemic antiviral response in HIV-1 infection. PLoS Pathog 6: e1000893. doi: 10.1371/journal.ppat.1000893
  36. 36. Moriuchi H, Moriuchi M, Fauci AS (2000) Cathepsin G, a neutrophil-derived serine protease, increases susceptibility of macrophages to acute human immunodeficiency virus type 1 infection. J Virol 74: 6849–6855. doi: 10.1128/jvi.74.15.6849-6855.2000
  37. 37. Sroussi HY, Berline J, Dazin P, Green P, Palefsky JM (2006) S100A8 triggers oxidation-sensitive repulsion of neutrophils. J Dent Res 85: 829–833. doi: 10.1177/154405910608500910
  38. 38. Ikemoto M, Murayama H, Itoh H, Totani M, Fujita M (2007) Intrinsic function of S100A8/A9 complex as an anti-inflammatory protein in liver injury induced by lipopolysaccharide in rats. Clin Chim Acta 376: 197–204. doi: 10.1016/j.cca.2006.08.018
  39. 39. Otsuka K, Terasaki F, Ikemoto M, Fujita S, Tsukada B, et al. (2009) Suppression of inflammation in rat autoimmune myocarditis by S100A8/A9 through modulation of the proinflammatory cytokine network. Eur J Heart Fail 11: 229–237. doi: 10.1093/eurjhf/hfn049
  40. 40. Pappu R, Rutz S, Ouyang W (2012) Regulation of epithelial immunity by IL-17 family cytokines. Trends Immunol 33: 343–349. doi: 10.1016/j.it.2012.02.008
  41. 41. Rodriguez RML-V, A. and Lopez-Larrea (2012) C (2012) Immune system evolution. Adv Exp Med Bio 739: 237–251.
  42. 42. Ricklin D, Hajishengallis G, Yang K, Lambris JD (2010) Complement: a key system for immune surveillance and homeostasis. Nat Immunol 11: 785–797. doi: 10.1038/ni.1923
  43. 43. Pudney J, Quayle AJ, Anderson DJ (2005) Immunological microenvironments in the human vagina and cervix: mediators of cellular immunity are concentrated in the cervical transformation zone. Biol Reprod 73: 1253–1263. doi: 10.1095/biolreprod.105.043133
  44. 44. Shacklett BL, Greenblatt RM (2011) Immune responses to HIV in the female reproductive tract, immunologic parallels with the gastrointestinal tract, and research implications. Am J Reprod Immunol 65: 230–241. doi: 10.1111/j.1600-0897.2010.00948.x