Combination with antimicrobial peptide lyses improves loop-mediated isothermal amplification based method for Chlamydia trachomatis detection directly in urine sample

All C. trachomatis specific LAMP assay primer sets (Additional file 1: Table S1) were designed to target highly conserved region of the C. trachomatis cryptic plasmid within coding sequence 2 - CDS2 [13] using Basic Local Alignment Search Tool-BLAST (http://​blast.​ncbi.​nlm.​nih.​gov) and LAMP Designer 1.10 software (PREMIER Biosoft USA). Additionally loop primers (LF/LB) were designed to accelerate amplification time and increase sensitivity. Primers were screened for their high sensitivity towards DNA target and for the absence of the non-specific background on LF strips. Oligonucleotides that contain sequence elements that promote secondary structures, hairpins or primer-primer interactions were avoided (using OligoAnalyser tool). Primers FIP and LF were 5′ labelled with biotin and BIP and LB primers with FAM to allow product detection on the LF strips. Primers were obtained from Microsynth AG (Balgach, Switzerland).

C. trachomatis specific LAMP reaction was carried out according to the protocol supplied by Eiken Chemical Co. Ltd [35] with reaction total volume 50 μl. Bst polymerase was replaced with Bsm polymerase (Thermo Fisher Scientific Inc. USA) and 1.2 μl of template DNA and 15 μl of ddH20 were used. For untreated samples 5 μl of urine sample and 11.2 μl of ddH20 were used. All LAMP reactions were performed at 63 °C for 21 min and analysed on the LF strips (AMODIA Bioservice GmbH) according to manufacturer’s protocol. In order to confirm C. trachomatis amplification product specificity the reaction product was cut with PmlI restrictase (Thermo Fisher Scientific Inc. USA). The amplification product was considered specific if the signal on the LF disappeared after treatment with restrictase.

For quantitative analysis 0.5 μl EvaGreen (Biotium) fluorescent and 0.3 μl ROX (Thermo Fisher Scientific Inc. USA) reference dyes were added into standard LAMP reaction prepared as described above. Primers without Biotin/FAM labelling were used and product was detected using Applied Biosystems 7900HT Real-Time PCR System. A standard curve was constructed using serial dilutions of BglII linearized pGL3-CDS2 plasmid [13] at concentrations from 10⁸- 10⁴ with a 4 parallels. qLAMP was performed at 63 °C with 40 cycles, each 1 min long, data reading after 30 s.

C. trachomatis strain UW-36/Cx genomic DNA (ATCC® VR-886D™) was obtained from ATCC (American Culture Collection) and CDS2 target copy number was determined by qPCR (Applied Biosystems) using pGL3-CDS2 plasmid and following primers: Fw 5′- CTCCTTGGAGCATTGTCTGG- 3′ and Rw 5′-CGGATGCGATGAACAGTTTG- 3′.

Lysates used for LAMP reaction were prepared by treating 30 μl of clinical patient’s urine sample with 4 μl of 1 × antimicrobial peptide lysis mix (SelfD Technologie GmbH, Leipzig, Germany; commercial component) for 5 min according to the protocol supplied by SelfD Technologie GmbH. Each lysate contained 12 % (from final volume) of peptide lysis mix and subsequently 1.2 % of peptide lysis mix in each LAMP reaction. Heat-treated samples were prepared by pre-heating urine at 90 °C for 5 min and then cooled down on ice. 5 μl of each lysates (heated urine or treated with antimicrobial peptide lysis mix) were then applied for C. trachomatis specific LAMP amplification. Pooled urine was only used (C. trachomatis negative urine mix from 5 men and 5 women in equal volumes) for assay sensitivity/specificity analysis.

Statistical analyses of C. trachomatis specific LAMP assay’s limit of detection were performed with XLSTAT, 95 % confidence interval (CI) was calculated using logistic regression model. Assay sensitivity and specificity was calculated using online tool from MedCalc (http://​www.​medcalc.​org/​calc/​diagnostic_​test.​php) confidence interval for 95 %.

First-void morning urine samples were collected from 650 patients from 18 to 25 year old (316 females and 334 males) attending Sexual Health Clinique (Tartu, Estonia) from October 2013 to December 2014. Urine samples were self-collected into a clean polypropylene container (average sample volume of 25–35 ml) without preservative and led by patients to the Sexual Health Clinique on the same day. Criteria for patient enrolment in the study were recent change of the sexual partner, multiple sexual partners, unprotected sexual intercourse, STI of the partner, and symptoms of the sexually transmitted disease.

Human urine contains variety of critical components that may inhibit the amplification entirely or only partially and by that prolong the amplification time. For instance, high concentration of urea in the sample (more than 50 mmol l⁻¹) can lead even to the degradation of the polymerase [15, 36, 37]. In order to simplify pathogen detection procedure and make it more applicable for POC device settings, the DNA purification step prior the amplification was excluded. The amplification procedure has to take place directly in urine sample without previous concentration of the pathogen genetic material. Therefore, it is essential that developed amplification method has to tolerate as higher percentage of urine in the reaction mixture as possible allowing to increase the whole assay sensitivity as more targets are available for amplification. Our results demonstrated that reactions containing 15 % of urine did not give any signal when analysed on lateral flow strips, indicating that 21 min of amplification time was insufficient for target amplification. 5–10 % of urine in reaction mixture gave positive signal in all replicates (n = 5) (Fig. 1b). This observation was also confirmed by quantitative LAMP analysis where addition of 5–10 % urine did not affect amplification time (Fig. 1a). In the presence of 15–20 % of urine however, the amplification time should be prolonged up to 30 min indicating inhibitory effect of the urine components on LAMP reaction (Fig. 1a). Therefore based on this data, 10 % of urine was used as a sample material in all subsequent experiments. Our results showed that minimum reaction time required for product formation on LF strips was 21 min when as low as 100 copies of template per reaction were used in LAMP reaction containing not more than 10 % of crude urine sample (Additional file 1: Table S2). This enabled to reduce assay amplification procedure from recommended 1 h to 21 min without losing reaction sensitivity.

LAMP urine tolerance was tested in the presence of 0 %, 5 %, 10 %, 15 % and 20 % of pooled patient urine. Results were analyzed quantitatively (A) and using LF strips (B). For quantitative analysis, remaining amplification time was calculated as an average time compared to 0 % urine reaction at standard DNA dilutions 10⁸, 10⁷, 10⁶, 10⁵ and 10⁴ target copies per reaction. For LF strips detection, reaction was performed in the presence of 100 template copies in five parallels; two bands confirm the successful outcome of DNA amplification and a negative result is indicated by the presence of a single black band on the test strip.

To eliminate the possibility that antimicrobial peptide lysis mix itself could inhibit LAMP reaction and find out the best concentration of lysis mix that could be applied in LAMP reaction, different lysis mix concentrations were tested. As a result addition of up to 1.2 % of antimicrobial peptide mix did not inhibit LAMP reaction as the amplification time was not altered. Based on this data up to 1.2 % of peptide lysis mix was used in LAMP assay without significant inhibition of amplification efficiency (Fig. 2).

Assay tolerance was tested in the presence of 0 %, 0.6 %, 1.2 %, and 1.8 % of 1 × antimicrobial peptide lysis mix (SelfD Technologie GmbH, Leipzig, Germany; commercial component). Results were analysed quantitatively. For quantitative analysis, remaining amplification time was calculated as an average time compared to 0 % antimicrobial peptide lysis mix reaction at standard DNA dilutions 10⁸, 10⁷, 10⁶, 10⁵ and 10⁴ target copies per reaction.

Probit analysis showed that assay was sensitive enough to detect 25 plasmid copies per reaction in water (0.95 value) (Additional file 1: Figure S1). As developed assay does not contain DNA purification step it was important to estimate if 10 % of crude urine can affect the sensitivity. For that pooled urine samples were spiked with different amount of C. trachomatis genomic DNA. As a result, in the presence of 10 % urine sensitivity of LAMP assay reduced approximately three times and established LOD was 70 target copies per reaction (0.95 value) (Table 1).

These results are in good correlation with urine inhibition experiment, where addition of 10 % urine prolonged LAMP amplification time (Fig. 1a) and can be the reason why amplification activity was decreased approximately three times (Table 1).

Although LAMP primers were designed targeting pathogen specific region, their specificity had to be experimentally verified. C. trachomatis specific LAMP assay was further analysed for possible non-specific reactivity using excess amount of genomic DNA from human and 30 microorganisms potentially present in human urine (Additional file 1: Table S3). As a result C. trachomatis specific LAMP assay did not give cross-reactivity with any examined pathogen’s DNA and is highly specific in detection of chlamydia from human urine, fitting well for molecular diagnostic system.

To determine the prevalence of chlamydia in symptomatic and asymptomatic patients the urine samples subjected to clinical study (N = 650) were additionally evaluated. 157 out of 650 patients (24 %), had symptoms of STI and 493 patients (76 %) were asymptomatic. 51 % of the patients were males and 49 % females, with an average age of 22 years (18–25 years old). Chlamydia was diagnosed in 39 male patients and 47 female patients out of which only 12 (31 %) and 13 (28 %) had symptoms, respectively. Clinical data confirmed that C. trachomatis infection is mainly asymptomatic, which makes it difficult to diagnose and estimate the real prevalence in human population (Additional file 1: Table S4; Table S5).

C. trachomatis specific LAMP assay clinical sensitivity and specificity was validated in a study, comprising 91 freshly collected patient urine samples selected randomly from 650 clinical specimens. Although the number of specimens is not enough to provide high statistical power of the clinical study it was calculated to be minimal sample size to perform cost-effective assay validation with peptide lysis mix. First-void morning urine samples were self-collected by 56 male and 34 female patients and the overall prevalence of C. trachomatis among tested group was 12 %. Collected urine samples were subjected in parallel for C. trachomatis specific LAMP assay and Roche Cobas 4800 CT/NG test, a conventional technique for C. trachomatis detection. According to Roche Cobas 4800 CT/NG test 11 out of 91 had chlamydia infection. Two different sample pre-treatment strategies were tested and compared to untreated samples: heating at 90 °C for 5 min and incubation with peptide lysis mix for 5 min. From 80 C. trachomatis negative samples all tested negative in all treatments and no false-negatives were detected. Results showed that highest assay sensitivity (73 %) was obtained when using peptide/detergent lysis mix (out of 11 C. trachomatis positive urine samples 8 tested positive and 3 tested negative in the LAMP reaction) whereas pre-treatment with heat showed 64 % of assay sensitivity, and sensitivity dropped to 55 % when urine samples were left untreated (Table 2).

These data clearly shows that pre-treatment of urine samples prior to amplification provide a better access of pathogen DNA material. All 80 chlamydia negative samples were detected as negative by developed LAMP assay, thus clinical specificity was estimated to 100 %.