Abstract
Background
The purpose of this study was to evaluate the prevalence of Chlamydia trachomatis, Neisseria gonorrhoeae, Mycoplasma genitalium and Ureaplasma urealyticum infections in infertile men that consulted our outpatient departments using a novel simultaneous amplification testing (SAT) that is RNA-detection based. The possible impact of C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infections on semen parameters was also noted in the present study.
Methods
A total of 2607 males that were diagnosed with infertility were included in this study. C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infections were detected in the urine samples using SAT method. Related data, including semen parameters and age as well as C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infections were collected and analyzed.
Results
A total of 51 and 1418 urine samples were found positive for M. genitalium RNA and U. urealyticum RNA, respectively, while the prevalence of C. trachomatis and N. gonorrhoeae was relatively lower. Men with positive M. genitalium RNA and U. urealyticum RNA had higher sperm DNA fragmentation index (DFI) while the comparisons of other semen parameters yielded nonsignificant results between the RNA positive and negative group. A multivariate linear regression analysis revealed that U. urealyticum and M. genitalium infections posed significant factors of DFI (adjusted R2 = 46.2%).
Conclusions
Our study suggested a relative high prevalence of U. urealyticum and M. genitalium infection based on this novel SAT detection method. U. urealyticum and M. genitalium infection could possibly impair male fertility potential through promoting sperm DNA damage.
Keywords: Simultaneous amplification testing, Chlamydia trachomatis, Neisseria gonorrhoeae, Mycoplasma genitalium, Ureaplasma urealyticum, Male infertility, Sperm DNA fragmentation index
Background
Male infertility is a world health problem affecting about 10–15% of couples, which accounts for half of the infertile cases [1]. The cause of male infertility has been multi-dimensional, in which the role of genitourinary tract infections has been the focus in contemporary medicine. The major genitourinary tract infections include Chlamydia trachomatis, Neisseria gonorrhoeae, mycoplasma species (Mycoplasma genitalium and Mycoplasma hominis), ureaplasma species (Ureaplasma urealyticum and Ureaplasma parvum) and Treponema pallidum. The exact mechanisms that genitourinary pathogens affecting male fertility potential remains unknown. The inflammatory processes triggered by genitourinary pathogens can lead to deterioration of spermatogenesis and seminal tract obstruction. The apoptosis process associated with inflammatory conditions could possibly result in the impaired semen parameters, although the relationship between the infections and semen parameters are still under debate [2].
The diagnosis of genitourinary pathogens have been based on bacterial culture, which are time consuming and fail to show adequate sensitivity. Recently, the diagnosis methods based on nucleic acid amplification methods have been widely applied in clinic, being feasible and having relative high sensitivity and specificity [3]. The first voided urine specimen has been proven be just as accurate as a urethral swab in the detection of C. trachomatis and N. gonorrhoeae [4]. Notably, a novel simultaneous amplification testing method (SAT) based on isothermal amplification of pathogens RNA has been reported providing accurate and rapid detection of several pathogens [5, 6]. To the best of our knowledge, there is no data available published regarding the prevalence of C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum in infertile men using this novel SAT method. Therefore, in the present study, we aimed to observe the prevalence of C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum in 2607 urine samples based on SAT methods of infertile men included, and to investigate the association between genitourinary infections and semen parameters. This study helps to define the diagnostic role of genitourinary infections in the assessment of male fertility potential.
Methods
Study population
The present multicentre study involved following medical centers: the First Affiliated Hospital of Wenzhou Medical University, Changhai Hospital, the 324 Hospital of PLA while the data was summarized and analyzed in the Case Western Reserve University and the First Affiliated Hospital of Wenzhou Medical University. From February 2016 to June 2016, we recruited males complained of infertility diagnosed with having had no pregnancies in the past of unprotected intercourse with their partners for more than 1 year that attended the outpatient department of the participated centers. All patients underwent semen analysis, semen chromatin structure assay (SCSA) analysis and C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum test using urine samples with SAT method. The exclusion criteria were male with reproductive system abnormalities, hormonal abnormalities, varicocele, heavy use of smoking or alcohol, exposure to physical or chemical agents with known negative reproductive effects, other causes of infertility that has been medical proven, advanced female partner age ≥38 years, detected female causes of infertility with medical evidence. Participants were also asked to confirm that they did not have any genitourinary symptoms such as pain, micturition, urethral discharge or dysuria.
Semen analyses
Routine semen analyses were conducted by one examer according to the 4th edition of World Health Organization (WHO) laboratory manual for the examination and processing of human semen. Sperm parameters including seminal value, concentration, progressive (PR%) motility (a + b%) and normal sperm morphology were collected for further analyses. Azoospermia was defined as the absence of spermatozoa, oligospermia as the sperm concentration <20 × 106/ml, asthenospermia as PR% <40%, teratospermia as normal morphology of spermatozoa <15%.
Semen chromatin structure assay (SCSA)
Semen chromatin structure assay was performed by one examer using flow cytometry SCSA methods described previously [7]. Briefly, the acid induced sperm nuclear DNA denaturation, the semen samples were processed with acridine orange staining. Acridine orange binds to the fragmented sperm DNA that fluoresces red while the double-strand DNA fluoresces green. The SCSA parameters are calculated based on the red/(red + green) fluorescence intensity. The SCSA parameters included DFI as the percentage of the denatured sperm DNA that fluoresces red and high DNA stainability (HDS) as the percentage of sperm with abnormally high DNA statinability.
C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum detection in urine samples in infertile men using SAT methods
The presence of genitourinary pathogen was carried out in urine specimens. The presence of C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum 16S rRNA in urine samples of infertile males, which has highly conserved sequence, were detected using SAT methods, according to the methods of the manufacture (Shanghai Rendu biotechnology Co., Ltd). Briefly, the genitourinary pathogen 16S rRNA were isolated from the sample and reverse transcribed to generate cDNA fragment. The specific 16S rRNA sense primer and anti-sense primer contains T7 promoter sequence, and is used for RNA fragment amplification. The probe sequence was labeled with 6-carboxyfluorescein (FAM) at the 5′ end and with quencher 4-[4-(dimethylamino) phenylazo] benzoic acid N-succinimidylester (DABCYL) at the 3′ end. Real-time PCR was performed in a real-time PCR system (Applied Biosystems Inc., Foster City, CA, USA).
Statistical analyses
One-way Kolmogorov–Smirnov was used to test the normal distribution. Continuous variables were presented as mean ± standard deviation (SD) and compared by independent sample t test. The Chi square test or Fisher’s exact Chi square was used to for categorical variables; quantitative data non-normally distributed were presented as median (interquartile range) and compared using non-parametric test. Multivariate linear regression with likelihood ratio test was used to observe the significant predictors of DFI.
Results
Prevalence of C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infection in infertile males
A total of 2607 urine samples of infertile males were collected and analyzed in the present study. A relative high prevalence of U. urealyticum was found in the detected urine samples (1418/2607, 54.5%). A total of 27 patients were positive for C. trachomatis (27/2607, 1.0%), 51 patients were positive for M. genitalium (51/2607, 2.0%), 6 patients were positive for N. gonorrhoeae (6/2607, 0.2%). Mix infection, defined as more than one pathogen infection, was also common in the detected samples (148/2607, 5.9%). A total of 957 samples were found negative for C. trachomatis, N. gonorrhoeae, M. genitalium or U. urealyticum infections (Table 1).
Table 1.
n | % | |
---|---|---|
Uninfected | 957 | 36.7 |
CT C. trachomatis only | 27 | 1.0 |
MG M. genitalium only | 51 | 2.0 |
NG N. gonorrhoeae only | 6 | 0.23 |
UU U. urealyticum only | 1418 | 54.5 |
Mixed infection | 148 | 5.68 |
C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infection and semen parameters
The comparisons in terms of semen concentration, seminal volume, PR%, normal morphology, DFI, HDS were conducted between the pathogens positive and negative group, which were demonstrated in Table 2. The patients in M. genitalium positive group tended to have higher DFI% than that in M. genitalium negative cases (25.29 ± 15.70 versus 19.01 ± 12.80, p = 0.03). U. urealyticum positive subjects had about 10% higher DFI than U. urealyticum negative subjects (30.30 ± 16.90 versus 20.09 ± 10.56, p = 0.02). However, we failed to identify this significant differences between C. trachomatis positive and C. trachomatis negative groups, either between N. gonorrhoeae positive and N. gonorrhoeae negative groups. The mean values of seminal volume, sperm concentration, PR%, normal morphology and HDS were neither related to the detection of C. trachomatis RNA nor to those of N. gonorrhoeae or U. urealyticum and M. genitalium RNA in the detected specimens.
Table 2.
Sperm concentration (×106/ml) | Semen volume (ml) | PR (%) | Normal morphology (%) | DFI (%) | HDS (%) | |
---|---|---|---|---|---|---|
CT C. trachomatis | ||||||
Positive | 55.70 ± 30.80 | 3.18 ± 1.40 | 29.00 ± 19.10 | 9.13 ± 4.58 | 25.90 ± 14.45 | 10.15 ± 8.70 |
Negative | 61.08 ± 40.67 | 3.42 ± 1.41 | 29.67 ± 18.78 | 11.45 ± 5.90 | 21.61 ± 10.50 | 12.19 ± 7.10 |
MG M. genitalium | ||||||
Positive | 57.10 ± 41.40 | 3.51 ± 1.30 | 30.08 ± 18.01 | 12.10 ± 4.48 | 25.29 ± 15.70 | 11.65 ± 5.79 |
Negative | 59.65 ± 41.90 | 3.09 ± 1.60 | 25.89 ± 19.01 | 10.10 ± 5.45 | 17.01 ± 12.80 | 15.57 ± 4.40 |
NG N. gonorrhoeae | ||||||
Positive | 67.80 ± 30.90 | 3.78 ± 1.60 | 30.53 ± 17.20 | 15.67 ± 5.78 | 20.19 ± 15.67 | 15.00 ± 9.00 |
Negative | 55.08 ± 30.61 | 3.50 ± 1.39 | 28.54 ± 18.34 | 11.45 ± 6.89 | 20.10 ± 15.09 | 13.43 ± 9.61 |
UU U. urealyticum | ||||||
Positive | 50.50 ± 34.89 | 3.89 ± 1.21 | 21.90 ± 21.43 | 12.78 ± 6.89 | 30.30 ± 16.90 | 17.68 ± 6.05 |
Negative | 56.90 ± 34.54 | 3.80 ± 1.30 | 21.29 ± 21.45 | 13.45 ± 6.89 | 20.09 ± 10.56 | 14.46 ± 5.01 |
The distribution of C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum positive cases in azoospermia versus non-azoospermia cases, oligospermia versus non-oligospermia, asthenospermia versus asthenospermia and teratospermia versus teratospermia cases were also analyzed. 2 semen specimens (2/27, 7.4%) were azoospermic in the 27 cases that were C. trachomatis positive while it was 11 (11/27, 40.7%), 17/27 (63.0%), 15/27 (55.6%) for oligospermia, asthenospermia and teratospermia cases, respectively. Neither C. trachomatis nor N. gonorrhoeae, M. genitalium or U. urealyticum positive was found to be related with azoospermia, oligospermia, asthenospermia or teratospermia in the current study (Table 3).
Table 3.
Azoospermia | Oligospermia | Asthenospermia | Teratospermia | |||||
---|---|---|---|---|---|---|---|---|
Yes (106) | No (2445) | Yes (1230) | No (1377) | Yes (1507) | No (1100) | Yes (1310) | No (1297) | |
C. trachomatis CT-positive (n = 27) | 2 (1.88%) | 25 (1.02%) | 11 (0.89%) | 16 (1.16%) | 17 (1.13%) | 10 (0.91%) | 15 (1.15%) | 12 (0.93%) |
M. genitalium MG-positive (n = 51) | 2 (1.88%) | 49 (2.00%) | 24 (1.95%) | 27 (1.96%) | 31 (2.06%) | 20 (1.82%) | 27 (2.06%) | 24 (1.85%) |
N. gonorrhoeae NG-positive (n = 51) | 0 (0%) | 6 (0.24%) | 3 (0.24%) | 3 (0.22%) | 3 (0.20%) | 3 (0.27%) | 3 (0.23%) | 3 (0.23%) |
U. urealyticum UU-positive (n = 1418) | 56 (52.8%) | 1362 (55.7%) | 679 (50.7%) | 816 (54.1%) | 816 (54.1%) | 602 (54.7%) | 702 (53.6%) | 716 (55.2%) |
C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infection and DFI elevation
DFI was the only semen parameter that correlated with pathogen infection in the current study. Hence, all parameters were introduced into multivariate linear regression analysis in the prediction of DFI. The results indicated that U. urealyticum and M. genitalium infections accounted for 46.2% of the variability in the prediction of DFI: U. urealyticum positive, p = 0.023; M. genitalium positive, p = 0.030 (Table 4).
Table 4.
DFI% | Partial regression coefficient | SE | p | HDS% | Partial regression coefficient | SE | p |
---|---|---|---|---|---|---|---|
Constant | 20.50 | 9.60 | 0.100 | 18.29 | 8.23 | 0.340 | |
Age | 0.15 | 2.30 | 0.850 | 0.10 | 0.56 | 0.340 | |
UU U. urealyticum | |||||||
U. urealyticum UU-negative | Reference | ||||||
U. urealyticum UU-positive | 8.56 | 5.18 | 0.023 | −6.23 | 10.35 | 0.42 | |
MG M. genitalium | |||||||
M. genitalium MG-negative | Reference | ||||||
M. genitalium MG-positive | 6.26 | 2.45 | 0.030 | 2.20 | 9.35 | 0.59 |
Discussion
Male genitourinary tract infections has always been the focus of debate in the era of male infertility. It is also estimated that approximately 15% of male infertility is related to genital tract infection [8]. C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum are common genitourinary tract pathogens and are widely studied in the current literature. It is also difficult to identify these infections due to their being clinically silent nature, the possibility of contamination with other organisms and the culture difficulty [9].
In our study, C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infection was detected in 1.0, 2.0, 0.2 and 54.5% of infertile men, respectively. Huang et al. found that U. urealyticum and M. genitalium infections were found in 19.6 and 2.5% in infertile males, respectively [10]. C. trachomatis prevalence showed a wide variance, with reported rates of 0.4–42.3% in asymptomatic males in infertile couples [11]. N. gonorrhoeae was less evaluated in the current literature when compared to C. trachomatis, M. genitalium and U. urealyticum. In another study, N. gonorrhoeae was detected in 6.5% of infertile men, compared with 0% of fertile men [12]. These ambiguous results on the prevalence of detected pathogens can, at least partly, be the effect of differential diagnostic criteria and detection methods applied in different studies.
The consequences of genitourinary infections in the era of male fertility are still underdetermined, as well as the impact on semen parameters and sperm fertilizing capacity in the field of assisted reproductive medicine. Some studies failed to find any correlation between C. trachomatis infection and semen alternations [13, 14], while others reported a decrease in seminal volume, sperm concentration, motility and morphology [15–17] with C. trachomatis infections. Additionally, The semen quality impairments induced by N. gonorrhoeae and M. genitalium were not fully clarified in the field, with some studies reported a detrimental effect of genital pathogens on male fertility potential, while others reported altered alternation in semen parameters [2]. The heterogeneity in the male infertility diagnostic criteria and genital pathogens detection methods in different studies can partially interpret these ambiguous results. On the other hand, the effect of the presence of genital pathogens in semen on assisted reproductive technology consequences was also not fully clarified. Barbeyrac et al. found in a prospective study with 277 couples involved that the clinical pregnancy rate was comparable between the presence and absence of C. trachomatis infection biomarker [18]. However, in another prospective observational study, patients with C. trachomatis serology positive results had significant lower cumulative pregnancy rate than that in patients with C. trachomatis serology negative results in non-IVF treatments [19].
In our study cohort, more than half of the infertile males (54.5%) was found to have U. urealyticum infection. U. urealyticum is a natural inhabitant of the male urethra [20], while the role of U. urealyticum infections in male infertility pathogenesis are not fully determined. U. urealyticum infections has been implicated as the causative pathogen of urethritis, prostatitis and epididymitis [20]. Some researches failed to identify any correlation between U. urealyticum presence and semen alternations [11, 21], while others have reported a impairment on semen concentration [22], motility and morphology [11, 23]. U. urealyticum might have deleterious effect on sperm DNA integrity, leading to an impairment of embryo development. Sperm DNA integrity was assessed by DFI, known as sperm DNA fragmentation index, are now arising increasing attention for its diagnostic capabilities of male fertility potential and pregnancy outcome [24, 25]. U. urealyticum infections was found to induce sperm DNA damage and seminal reactive oxygen species and thus involved in male infertility pathogenesis in one study [26]. U. urealyticum was also found to cause sperm DNA denaturation both in vivo and in vitro, thus impairing embryonic development [27]. The rationality of U. urealyticum screening before ART cycles has also been fully acknowledged. Montagut et al. noted a significant reduction in the pregnancy rate in the U. urealyticum infected group [28], while there were another study reporting similar fertilization rate and pregnancy rate between the absence and presence of U. urealyticum in semen, although a higher abortion rate in the U. urealyticum positive was observed [29]. Notably, the possible influence of other detected genital pathogens infections on sperm DNA integrity had been noted in limited studies. Gallegos et al. found patients with C. trachomatis and M. genitalium infections have increased DFI and have DFI decreased from antibiotic therapy that aiming to control C. trachomatis and M. genitalium infections [30]. In our male infertility cohort, we found the routine semen parameters, including semen concentration, PR% and morphology remained unaltered regardless of C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infections. However, U. urealyticum and M. genitalium infections was associated with the increase of DFI in the present study, indicating the male infertility potential impairments caused by genitourinary pathogens could possibly be mediated by a hazard impact on sperm DNA integrity.
Nucleic acid amplification tests (NAATs) has proven to provide the sensitivity, specificity and ease of specimen transport than that of any other tests available in the diagnosis of chlamydial and gonococcal infections, which was noted in the recommendations for C. trachomatis and N. gonorrhoeae detection issued by US Centers for Disease Control (CDC) and prevention [31]. Additionally, the detection progress based on RNA detection, including transcription-mediated amplification (TMA) and SAT methods has gained arising attention. TMA assay in C. trachomatis detection had higher sensitivity observed compared to that in DNA-based PCR detection assay [32]. This advantage of this approach is the presence of multiple copies of 16S rRNA per cell, leading to a possible higher sensitivity in comparison of PCR assays that is DNA-based that target single-copy genes. This TMA assay has proven to be the optimal methods in M. genitalium detection, facilitating a sensitive, specific and throughput test for MG detection [33].
Traditional methods of screening for genitourinary pathogens, like urethral swabs, are usually embarrassing and invasive, while noninvasive methods are clearly preferred by patients. Using RNA-based SAT testing method for C. trachomatis screening, the urine-based screening had a sensitivity and specificity 87.7 and 99.4%, respectively, which is nearly identical to those samples obtained from urethral swab (sensitivity 95.9%, specificity 99.4%) from a evidence-based medicine view [4], suggesting this urine-based noninvasive screening to be a potential alternative to invasive methods. On the other hand, the urine samples for and genitourinary pathogens detection, had been demonstrated a high concordance with semen specimens, with concordance 100% observed for C. trachomatis, M. genitalium and 85% for U. urealyticum detection [12]. The study of Gdoura et al. have also demonstrated a high concordance between semen and urine specimens for the detection of C. trachomatis, U. urealyticum and M. genitalium detection [11]. These data shed valuable light on the utility potential of urine specimens for the detection of genitourinary pathogens using SAT method, while offers a high concordance compared with semen specimens, thus facilitating the interpretation of the possible effect of these detected pathogens on semen quality and male infertility.
Several limitations should paid attention to our study. First, this is retrospective cohort study with no fertile males as “control” group included, which resulted in limited statistical power as well as provided limited information concerning the impact of C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infections on male fertility potential. U. urealyticum and M. genitalium was found in 6.5 and 0.65% of the fertile males, respectively [10]. U. urealyticum and M. genitalium was found to cause sperm DFI elevation in the current study, this no “control” design makes the interpretation of the results less convincing for the prevalence of these pathogens in “control” fertile males was not detected. Second, the present study failed to compare the clinical performance in terms of prevalence, sensitivity and specificity of this novel SAT method and other existing detection method, such as bacterial culture and DNA-based assay, therefore more studies comparing this SAT and other assay are needed to uncover the advantage and disadvantage of this novel SAT method.
Despite these limitations, there are some advantages of our study that should take consideration. First, this was a cohort study with relatively large sample size (2607 cases) that evaluated C. trachomatis, N. gonorrhoeae, M. genitalium and U. urealyticum infections in infertile males and association with semen parameters. Second, to the best of our knowledge and belief, this was the first report regarding this novel SAT method using urine samples in the diagnose of genitourinary pathogens, thus providing the first hand evidence of the possible clinical utility of this SAT method. Third, the present study shed valuable light on the possibility that M. genitalium and U. urealyticum infections could cause sperm DNA damage other than impairing routine sperm parameters, thus providing the evidential proof that male genitourinary pathogens could impair male fertility potential, and this effect was possibly DFI mediated.
Conclusions
In conclusion, using this novel SAT method, we detected a relative high prevalence of M. genitalium and U. urealyticum infections in urine samples of a infertile men cohort. Our findings indicated that M. genitalium and U. urealyticum infections could impair sperm DNA integrity, thus was likely to cause male infertility.
Authors’ contributions
LQ, QXS and JLF designed the project; HYL, GL and HHJ collected and analyzed the data; QL and HHJ wrote the manuscript. All authors read and approved the final manuscript.
Acknowledgements
Thanks are given to the patients enrolled in this study.
Competing interests
The authors declare that they have no competing interests.
Availability of data and materials
The datasets used and/or analysed during the current study available from the corresponding author on reasonable request.
Consent for publication
We have obtained consent to publish from the participant to report individual patient data.
Ethics approval and consent to participate
This study has been approved by the appropriate ethics committee of the First Affiliated Hospital of Wenzhou Medical University (Approval Number: 20160202). Informed consent was also obtained from all individual participants included in the study.
Funding
The study was supported by the National Natural Science Foundation of China (Nos. 81670695 and 81500579) and cstc2012jjA10147 and China-America Promotion Society for Medical Doctor (CapsMD).
Publisher’s Note
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Contributor Information
Ling Qing, Email: lingqing112567@163.com.
Qi-Xiang Song, Email: qixiangsongqwe@163.com.
Jian-Li Feng, Email: jianlifengasd@163.com.
Hai-Yan Li, Email: haiyanlizxc@163.com.
Guiming Liu, Email: guimingliurty@126.com.
Hai-Hong Jiang, Phone: +86-577-55579260, Email: jianghh.md@foxmail.com.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Data Availability Statement
The datasets used and/or analysed during the current study available from the corresponding author on reasonable request.