1 Division of Sexually Transmitted Disease Prevention, National Center for HIV, STD, and TB Prevention, Centers for Disease Control and Prevention, Atlanta, GA
2 Department of Pediatrics, Emory University School of Medicine, Atlanta, GA
3 Division of Viral and Rickettsial Diseases, National Center for Infectious Diseases, Centers for Disease Control and Prevention, Atlanta, GA
Correspondence to Dr. Erika Samoff, Division of Sexually Transmitted Disease Prevention, National Center for HIV, STD, and TB Prevention, Mailstop E-02, Centers for Disease Control and Prevention, 1600 Clifton Road NE, Atlanta, GA 30333 (e-mail: erika.samoff{at}gmail.com).
Received for publication January 13, 2005. Accepted for publication April 29, 2005.
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ABSTRACT |
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adolescent; Chlamydia trachomatis; Neisseria gonorrhoeae; longitudinal studies; papillomavirus, human; sexually transmitted diseases; Trichomonas vaginalis; vaginosis, bacterial
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INTRODUCTION |
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The association between a history of sexually transmitted infection and cervical cancer has been explored most thoroughly for C. trachomatis. Case-control studies controlling for HPV infection status have demonstrated an association between detection of antibodies to C. trachomatis and the development of cervical cancer (1, 2
, 6
, 7
), providing supporting evidence for this hypothesis. A retrospective study demonstrated an increased risk of cervical cancer in women who had a history of C. trachomatis infection (7
). These studies showed an association between C. trachomatis infection and subsequent cervical cancer but were unable to evaluate the role of concurrent C. trachomatis and HPV infections, either because the concurrency of these infections could not be determined or because few participants with concurrent infection were present in the study populations.
It is possible that changes in the host response to HPV that occur during concurrent infection may decrease the host's ability to resolve the HPV infection. If present, this effect would be detected as increased persistence of HPV infection. Persistence of HPV infection has been closely associated with progression to cancer (810
). Therefore, detection of an association between concurrent C. trachomatis infection and increased HPV persistence would support the association between C. trachomatis infection and cervical cancer and would suggest a mechanism for this association. To evaluate the effect of concurrent infection on HPV infection, we analyzed data from a prospective longitudinal cohort study. We examined associations between concurrent C. trachomatis infection and other genital tract infections and type-specific HPV persistence.
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MATERIALS AND METHODS |
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In this analysis, we evaluated study data collected between January 1999 and May 2003. During that period, 621 girls were enrolled. Data for girls not enrolled in the study were not available.
Data collection
A questionnaire was administered in private by trained interviewers as previously described (11). The questionnaire included questions on demographic factors, sexual and reproductive history, condom use, and drug and alcohol use.
Papanicolaou testing and HPV detection
At the time of pelvic examination, cervical cells from the endo- and ectocervix were collected using the Cytyc plastic broom collection kit and placed in 20 ml of PreservCyt cytologic fixative following the manufacturer's protocol for a routine diagnostic ThinPrep Papanicolaou smear (Cytyc Corporation, Marlborough, Massachusetts); this procedure was performed at every visit. ThinPrep Papanicolaou smears were prepared and evaluated in the hospital cytopathology laboratory. The cytologic finding, based on the Bethesda classification (12), was recorded from the resulting clinical report.
Residual PreservCyt cervical material was retrieved from the cytology laboratory. A 3-ml aliquot of resuspended cells was washed with 5 ml of Dulbecco's phosphate-buffered saline (Gibco BRL, Gaithersburg, Maryland) and extracted with the MasterPure total nucleic acid extraction kit (Epicentre, Madison, Wisconsin) using minor modifications to the manufacturer's protocol as previously described (11). One blank tube was included for every 10 samples to monitor cross-sample contamination.
HPV detection and typing was performed using the Roche line blot assay (Roche Molecular Systems, Inc., Pleasanton, California) as previously described (11). This assay uses HPV L1 consensus polymerase chain reaction with biotinylated PGMY09/11 primer sets and ß-globin as an internal control for sample amplification (13
, 14
). Total nucleic acid from CaSki (cervical carcinoma) cells harboring HPV 16 was used as the positive control. Amplicons (10 µl) were evaluated for ß-globin and HPV bands using 1.5 percent agarose gel electrophoresis stained with ethidium bromide, and those with an HPV band were hybridized to the typing strips. Samples with an HPV band that did not hybridize to the strip were sequenced for determination of HPV type as previously described (15
). Samples negative for ß-globin and HPV were considered inadequate for interpretation.
Specimen collection and detection of concurrent infections
Specimens were collected for detection of C. trachomatis, N. gonorrhoeae, Trichomonas vaginalis, and bacterial vaginosis at every study visit. First-catch urine specimens were collected for C. trachomatis and N. gonorrhoea testing for all study participants, using ligase chain reaction (LCx; Abbott Laboratories, Abbott Park, Illinois), polymerase chain reaction (COBAS AMPLICOR; Roche Diagnostic Systems, Branchburg, New Jersey), or strand displacement amplification (BD ProbeTec; BD Biosciences, Sparks, Maryland), according to manufacturers' instructions. Because of changing testing protocols, a cervical swab was also collected for some participants and tested for C. trachomatis and N. gonorrhoea with ligase chain reaction or strand displacement amplification.
In 355 visits where results of urine and cervical C. trachomatis testing were available, discrepant results were found for 12 visits (at eight visits the urine specimen only was positive; at four the cervical specimen only was positive). In 354 visits with results from urine and cervical N. gonorrhoea testing, discrepant results were found for eight visits (at seven the urine specimen only was positive; at one the cervical specimen only was positive). Any positive C. trachomatis or N. gonorrhoea test was considered a positive result.
Lateral-wall vaginal swabs were collected for T. vaginalis and bacterial vaginosis testing. T. vaginalis infection was detected through wet mount examination of vaginal fluid under microscopy and was confirmed by at least one other reader (E. H. K. or M. K. S.). For detection of bacterial vaginosis, vaginal swabs were rolled onto clean glass slides, air-dried, Gram-stained, and read (E. H. K.) using Nugent's criteria (16); a Nugent's score of 710 was considered evidence of bacterial vaginosis. Samples for bacterial vaginosis analysis were not collected during the first year of the study.
Study participants with C. trachomatis, N. gonorrhoea, T. vaginalis, or bacterial vaginosis were treated with appropriate directly observed one-dose therapy. Cure of C. trachomatis and N. gonorrhoea infections was evaluated by urine testing, and no treatment failures were detected.
Data analysis
To evaluate factors associated with HPV persistence, we limited our analysis to pairs of visits where 1) HPV was detected at the initial visit of the pair, 2) HPV detection data were available for a subsequent visit, and 3) the visits were separated by at least 6 months. Any visit pair meeting these criteria was included in the analysis. More than one visit pair could be contributed by one study participant. Therefore, a study participant with three study visits separated by 6 months and detection of HPV 18 and HPV 53 at visits 1 and 2 and detection of HPV 26 at visit 2 would contribute two visit pairs (visits 12 and visits 23). A type-specific persistent outcome occurred when at least one of the HPV types detected at the initial visit of the pair was also detected at the second visit; if none of the types present at the initial visit were detected at the second visit, the outcome was considered nonpersistent (17). Therefore, the study participant described above would contribute one outcome of 6-month persistence for each of HPV 18 and HPV 53 and one nonpersistent outcome for HPV 26.
One negative test was considered a marker of clearance. Redetection of an HPV type after a single negative result (a sequence of successive tests with positivenegativepositive findings, suggesting a potential false-negative result) occurred rarely (nine times) in these data. Omission of these events did not alter the results of the analysis.
After type-specific assessment of persistence, outcomes were grouped into high-risk (types 16, 18, 26, 31, 33, 35, 39, 45, 5153, 55, 56, 58, 59, 66, 68, 73, 82, and 83) and low-risk (types 6, 11, 40, 42, 54, 57, and 84) HPV types, according to the association between type and oncogenicity. If persistence of any high-risk type occurred over the period of a visit pair, one episode of high-risk persistence was generated; if no high-risk infection persisted, one outcome of nonpersistent high-risk infection was generated. Therefore, the example study participant described above would contribute one outcome of high-risk persistence over visits 12 and one outcome of nonpersistence over visits 23. These criteria were also applied to detection of low-risk virus types. If both high-risk and low-risk types were detected at the initial visit of a pair, one high-risk episode and one low-risk episode were contributed. Since persistence of more than one HPV type over a given pair of visits was not uncommon, use of one outcome per risk type per visit pair is conservative. Clearance of two virus types over a single pair of visits may reflect the same immunologic event; therefore, counting this event twice may inappropriately magnify the effect seen.
Logistic regression using generalized estimating equations with an exchangeable correlation structure, a method appropriate for correlated data (18), was used to evaluate associations between type-specific high- or low-risk persistence and concurrent infections (C. trachomatis, N. gonorrhoea, T. vaginalis, bacterial vaginosis, or more than one type of HPV) detected at the initial visit of the visit pair and to assess the role of potential confounders or effect modifiers (lifetime and current numbers of sex acts or sex partners, time between study visits, age, smoking, oral contraceptive use, parity, and douching) (17
, 19
22
). Univariate analyses were used to assess two-way associations; variables significant in univariate analysis were entered into a multivariate model, and determination of significance was based on robust standard errors.
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RESULTS |
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Behavioral and demographic characteristics of this population are presented in table 1. The majority of the analyzed participants were African-American and in high school, with a median age at first sex of 14 years. The prevalence of all sexually transmitted infections evaluated in this population was high. Concurrent infection with more than one of these sexually transmitted agents was not uncommon; infection with both C. trachomatis and N. gonorrhoea or C. trachomatis and T. vaginalis was detected in 26 (17 percent) of the 151 study participants contributing analyzable visits.
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We evaluated whether HPV persistence was associated with abnormal cytologic findings, as has been reported for other populations (10, 23
). Persistence was associated with detection of low- or high-grade squamous intraepithelial lesions (p < 0.01); 19 (59 percent) of 32 low- or high-grade squamous intraepithelial lesions identified were detected at a visit at which high-risk HPV persistence was also detected (i.e., the second visit of a visit pair). Only four of these lesions were high-grade squamous intraepithelial lesions.
Risk factor analysis
Data on the detection and persistence of high- and low-risk HPV types and the proportions of participants coinfected with C. trachomatis, N. gonorrhoea, T. vaginalis, bacterial vaginosis, or another HPV type at the initial visit of the visit pair are shown in table 3. A higher proportion of high-risk HPV types persisted if any evaluated sexually transmitted infection was present at the initial visit of the pair; for example, among high-risk infections at visits with concurrent C. trachomatis infection, 53 percent persisted, while 39 percent of infections at visits with no concurrent C. trachomatis infection persisted. This pattern was not seen for low-risk HPV types.
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Age, smoking (ever smoking; reported at baseline), oral contraceptive use (90 days prior to the second visit of the pair), parity (ever giving birth; reported at baseline), and douching (90 days prior to the second visit of the pair) may affect cervical and vaginal tissue and/or may have been associated with persistence in other studies. We evaluated associations between these variables and HPV persistence. No association was detected with any of these variables in univariate or multivariate analysis, except smoking. Although smoking was significantly associated with high-risk HPV persistence in univariate analysis, when it was entered into multivariate analysis including concurrent infection with C. trachomatis and another HPV type, this variable was not significant, and odds ratios for C. trachomatis and more than one HPV type were not altered.
To validate our conclusions, we reran the regression analyses with unstructured and autoregressive correlation structures. The same factors were found to be significant and nonsignificant using these correlation structures.
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DISCUSSION |
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The finding that concurrent infection with C. trachomatis is associated with HPV persistence accords with studies demonstrating an association between serologic evidence of exposure to C. trachomatis and cervical cancer (1, 7
, 24
). Our findings suggest a mechanism by which concurrent C. trachomatis infection may be associated with the development of cervical cancer, since persistence of HPV is the strongest risk factor for the development of cervical cancer (23
, 24
, 29
).
Analyses of the association between C. trachomatis and cervical cancer have evaluated women many years after initiation of sexual activity. In this paper, we report an association between C. trachomatis and HPV persistence in a relatively young population with a median of 2.6 years since first sex (range, 0.15.7 years), which suggests that long-term infection with C. trachomatis is not necessary to detect an association between C. trachomatis and HPV persistence. Thus, C. trachomatis may influence the natural history of HPV infection soon after infection by affecting persistence. In a population in which C. trachomatis was associated with cervical cancer, C. trachomatis DNA was detected in Papanicolaou smears performed many years before cancer diagnosis but not in Papanicolaou smears performed close in time to the cancer diagnosis (25, 30
); this supports the idea that concurrent infection with C. trachomatis may affect HPV early in the course of HPV infection.
Other studies have evaluated factors associated with HPV persistence. The only other sexually transmitted agent associated with HPV persistence is human immunodeficiency virus (31, 32
). While human immunodeficiency virus infection may have local as well as systemic effects on HPV persistence, the effect of C. trachomatis infection is likely to be localized at the cervix.
The association between C. trachomatis infection and persistence may reflect host or infectious agent-derived factors. Detection of an association between high-risk HPV persistence and concurrent C. trachomatis infection but not N. gonorrhoea or T. vaginalis infection suggests that the association is due to factors specific to C. trachomatis infection; however, the small number of concurrent infections with N. gonorrhoea and T. vaginalis may have limited our ability to detect an association with HPV persistence.
C. trachomatis infection may increase susceptibility to HPV on a cellular level by increasing access to the basal epithelium due to microabrasions or by altering characteristics of epithelial cells, increasing the viral load of the infection and facilitating persistence. Alternatively, concurrent infection with C. trachomatis may impede clearance of HPV by inducing a shift in the immune response to the HPV infection. Cellular (T-helper cell type 1) immune responses have been shown to be important in the clearance of HPV lesions (33). Unresolved C. trachomatis infection has been associated with a humoral (T-helper cell type 2) immune response (34
, 35
), and inflammatory infiltrates seen in C. trachomatis infection are characterized by a high proportion of plasma cells, in contrast to the histopathology of gonorrhea infection, wherein a lower proportion of the inflammatory infiltrate is composed of plasma cells (36
). Therefore, modulation of the cervical immune response toward a T-helper cell type 2 response may be a C. trachomatis-specific effect which increases persistence of HPV. Evaluations of the immunologic milieu surrounding the cervices of coinfected women as compared with women infected with HPV only would test this hypothesis. It is possible that concurrent infection with other sexually transmitted agents may exacerbate the effect of C. trachomatis on HPV persistence; further evaluation of concurrent infection with more than one sexually transmitted agent would also be valuable.
The effect of infection with multiple HPV types on persistence may be due to an increased viral load, which has been associated with persistence (8, 37
), or it may reflect host susceptibility to both infection and persistence. The importance of host factors in susceptibility to infection with multiple HPV types is underscored by the observation that infection with multiple HPV types occurred more commonly than would be expected if independence of acquisition of the different types was assumed, in an analysis controlling for sexual behavior (38
). However, this study did not control for sex partner's age, which was a predictor of baseline HPV infection in our study population (11
). Two studies have reported no association between persistence and infection with multiple HPV types (39
, 40
), while one other study has reported this association (17
). Further evaluation of this issue is needed, particularly because a vaccine for HPV may alter the population of infecting types for vaccinated populations and thereby alter the frequency of infection with multiple types.
Our study had several limitations. We do not know whether these results are generalizable to a population with lower rates of C. trachomatis and HPV infection. The relatively short follow-up time limited our ability to evaluate persistence of longer than 6 months. HPV persistence has been evaluated at 4, 6, 9, 12, and 24 months and as being present at two sequential or nonsequential visits, irrespective of the intervening time. Several studies have evaluated 6-month persistence (8, 10
, 17
, 39
), making this measurement useful for comparing results. Cervical cancer develops over a longer period of time, making evaluation of long-term persistence important to confirm the role of C. trachomatis in progression to cancer.
Many of the HPV infections we evaluated were initially detected at the baseline visit, making any analysis of incidence impossible and limiting our ability to draw conclusions about duration of infection. In the situation of infection with more than one type of HPV, it is possible that the times of infection differed and one or more of the infections was recently incident. Therefore, persistence of more than 6 months may reflect differing lengths of persistence. Detection of one HPV type at two sequential visits cannot distinguish between persistent infection and reinfectiona limitation shared by all studies of this type. However, lack of a detectable association between the number of sex partners or sex acts and persistence suggests that we detected persistence rather than reinfection. Relatively low numbers of study participants with persistent low-risk HPV infection were expected; this made evaluation of associations with persistence of low-risk types difficult, and the fact that no associations were seen may have been due to sample size as well as biologic differences between high- and low-risk types. The use of more than one C. trachomatis or N. gonorrhoea test in a subset of our study samples could have created a bias toward detecting these infections at visits with multiple tests; however, because the number of discrepant results between tests was very low, it is likely that any bias introduced was minimal. The test we used to detect T. vaginalis, the wet mount technique, is relatively insensitive, and this may have resulted in an inability to detect an association between T. vaginalis infection and HPV persistence. Finally, the limited age range in our study made assessment of the effect of age difficult, and we were not able to assess the role of nutritional factors or another coinfection associated with cervical cancer, herpes simplex virus type 2.
Our results demonstrate an association between infection with C. trachomatis and outcomes of HPV infection in adolescents with risky sexual behaviors. C. trachomatis screening is recommended for all sexually active adolescents. C. trachomatis screening coverage among adolescents is estimated to be as low as 27 percent in some states, and the median estimated C. trachomatis screening coverage for all states is 60 percent (41). C. trachomatis infection is a common sexually transmitted disease with outcomes that include infertility, and concurrent C. trachomatis infection may influence HPV outcomes; therefore, efforts need to be made to improve C. trachomatis screening coverage.
These results suggest that concurrent infections can affect the host's ability to resolve HPV infection, and as such they emphasize the value of screening and treatment for sexually transmitted infections. This study further demonstrates an effect of concurrent infection with HPV and C. trachomatis, supporting a possible role for C. trachomatis infection in the development of cervical cancer.
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ACKNOWLEDGMENTS |
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The authors gratefully acknowledge the participation of the study coordinators and interviewers. They also acknowledge Jason Dover, Angelica Wendt, Carol Farshy, Ruth Ann Tucker, and Juanita Onyekwuluje for laboratory support and Billy Litchfield for administrative support. Finally, the authors thank the Cytyc Corporation (Marlborough, Massachusetts) for the gift of ThinPrep supplies and Roche Molecular Systems (Pleasanton, California) for provision of Roche line blot materials.
These data were presented at the 53rd annual conference of the Centers for Disease Control and Prevention Epidemic Intelligence Service, Atlanta, Georgia, April 1923, 2004.
Partial program and salary support were provided to M. K. S. by the Cytyc Corporation.
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References |
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