1. Introduction
Mycoplasmas (mushroom form) are eubacteria included within the class Mollicutes (from latin mollis = “soft,” cutis = “skin”), which comprises the smallest and simplest self-replicating bacteria. Mycoplasma spp. possess distinctive features such as lack of a rigid cell wall envelope, sterol incorporation into their own plasma membrane, reduced cellular (0.3–0.8 μm diameter), and genome sizes (0.58–2.20 Mbp). In addition, they are characterized by fastidious growth requirements, fried-egg or mulberry-shaped colonies on agar, and they are not affected by β-lactams [1–4]. Due to their reduced genome sizes, mycoplasmas exhibit restricted metabolic and physiological pathways for replication and survival [3, 4]. This explains why these bacteria display strict dependence to their hosts for acquisition of amino acids, nucleotides, lipids, and sterols as biosynthetic precursors [3–5].
Several species are pathogenic in humans, including M. pneumoniae, which is implicated in 20–40% of community acquired pneumonia, M. genitalium, and M. hominis which are involved in pelvic inflammatory diseases [6]. There is an evidence for Mycoplasma infections playing a role in Gulf war syndrome/illness. M. fermentans has been found in the blood of Gulf war veterans at a much higher rate than in the overall population [7, 8]. Mycoplasmas are thought to be responsible for a number of unexplained symptoms, especially chronic fatigue states. M. salivarium, M. orale, M. buccale, M. faucium, and M. lipophilum are part of the normal flora of the human oropharynx and are generally regarded as commensal organisms except in immunocompromised patients [9, 10].
Difficulties of Mycoplasma spp. diagnosis include but are not limited to the fact that they are usually overlooked as “viral infection”; the symptoms are neither specific nor diagnostic as well as difficulties in culturing the organism from clinical samples and its maintenance in vitro and the very long incubation period required (up to 21 days). In addition, the diagnostic laboratory tests are unreliable, as although serological tests of Mycoplasma are the mainstay of laboratory diagnosis, these tests lack the sensitivity and specificity due to the poor specific immune response of the host [11–13].
Due to the lack of information about Mycoplasma infections among Egyptian patients, this study was done in order to characterize the different species of Mycoplasma among patients admitted to public and university hospitals in Cairo, Egypt. Studying the distribution patterns of pathogens among patients admitted to local and university hospitals in Egypt and particularly the greater Cairo metropolis can be used as a measure for understanding the dissemination of pathogens, as a large number of the population, both local residents of Cairo and outside, relies on these hospitals due to socioeconomic factors. In addition, in this study, a comparison was established between traditional (cultural, biochemical, and serotyping methods) and the molecular methods for the detection of mycoplasmas.
2. Materials and Methods
2.1. Isolation, Identification, and Biochemical Testing
Specimens were collected from El-Omrania Sader, El-kasr El-Einy, Bolak, and Om El-Masrien hospitals (all are public and university hospitals in greater Cairo area) and El-Borg Laboratories (private clinical lab with several branches in Cairo). A total of 110 specimens were collected (35 throat swabs and 75 sputum samples) from apparently sick patients. All sick patients showed respiratory symptoms, like sore throat, hoarseness, coryza, sneezing or cough (upper respiratory tract) or shortness of breath, asthma, bronchitis, or pneumonia (lower respiratory tract). Throat swabs were collected from patients who showed sore throat symptoms and sputum samples were collected from patients who had asthma, bronchitis, or shortness of breath. A total of 30 specimens (10 throat swabs and 20 sputum samples) were collected from apparent healthy individuals randomly. Healthy individuals had no respiratory symptoms but were chosen based on being at high risk. They were chosen from hospitals’ laboratories staff members, nurses, technicians, or workers in close contact with the patients. In addition, 30 Rota virus lyophilized vaccines samples were examined. All samples were collected during the period from January 2012 to January 2014.
All specimens and samples were examined for Mycoplasma spp. using pleuropneumonia-like organism broth and agar media (PPLO) (Difco, MI, USA). Culture and purification procedures were followed as previously described [10, 11, 14]. Purified isolates were maintained as agar strips (agar blocks) in sterile Bijou bottles and frozen at −20°C. Unopened plates were examined under stereo (dissecting) microscope (Leitz, Germany), where the surface of the medium was scanned to visualize the colonies. Digitonin sensitivity test was carried out to differentiate between Mycoplasma and Acholeplasma genera using filter paper discs impregnated with 0.2 mL of 1.5% (W/V) ethanol solution of digitonin and dried overnight. Mycoplasma spp. show digitonin sensitivity while Acholeplasma spp. are resistant [15]. Biochemical identification was used for further testing of Mycoplasma spp. Glucose fermentation, arginine deamination, urea hydrolysis tests, and serological detection using antiserum impregnated discs were performed as previously described [16–18].
2.2. Molecular Identification
Positive isolates were further confirmed by PCR amplification of the 16S rRNA gene using Mycoplasma specific primers: forward primer: 5′-GGGAGCAAACAGGATTAGATACCCT-3′ and reverse primer: 5′-TGCACCATCTGTCACTCTGTTAACCTC-3′, [19]. Positive Mycoplasma pneumoniae isolates were further typed by PCR amplification of the P1 cytadhesin gene using the forward primer: 5′-CCGCGAAGAGCAATGAAAAACTCC-3′ and reverse primer: 5′-TCGAGGCGGATCATTTGGGGAGGT-3′, [20]. For both PCR reactions, DNA extraction was done as previously described [21, 22]. The reaction was performed using 5 μL of 10x PCR buffer, 4 μL of 25 mM Mgcl2, 20 pmoles of each primer, 1 ng of DNA, 5 μL of 200 μM dNTP, and 1.25 units of Taq polymerase in final volume of 50 μL using purified water. Amplification conditions were denaturation at 94°C for 10 min followed by 35 cycles of denaturation at 94°C for 1 min, primer annealing at 60°C (16S rRNA gene) or 58°C (P1 cytadhesin gene) for 1 min, and elongation at 72°C for 1 min; the cycling was followed by a final extension step at 72°C for 10 min. PCR reactions were purified using AxyPrep PCR clean-up kit (Axygen Biosciences, CA, USA); then sequencing reactions were performed by (MacroGen, MD, USA). Sequences were then submitted to NCBI GenBank using BankIt (http://www.ncbi.nlm.nih.gov/WebSub/?tool=genbank).
4. Discussion
The study of Mycoplasma has become important in understanding chronic diseases. As both an extracellular and an intracellular pathogen, a better understanding of the virulence mechanisms of Mycoplasma spp. will provide fresh understanding of how to diagnose and combat this pathogen. The aim of this study was to screen respiratory samples for possible presence of Mycoplasma spp. and to conduct a comparative study between conventional and molecular methods for their detection among Egyptian patients. No doubt that rapid diagnosis of mycoplasmas leads to rapid choice and initiation of the most appropriate antimicrobial treatment and, consequently, rapid treatment and control of Mycoplasma infections avoiding its fatal complications.
Bacteriological examination was done for respiratory specimens (from both apparently sick and apparently healthy individuals) and vaccines samples collected during the period from January 2012 to January 2014. Different techniques were used for detection and identification of Mycoplasma. Culture technique included primary isolation, bacteriological examination, biochemical identification, and serotyping. Microscopic examination identified Mycoplasma according to colony appearance; then biochemical characterization was carried out followed by serological typing using growth inhibition test for the isolates in each biochemical group against specific antisera. In this study, 39 out of 170 samples (22.94%) were positive for Mycoplasma, where Mycoplasma spp. were detected more frequently in throat swabs (31.11%, in 14 out of 45 total swabs) than sputum (26.31%, in 25 out of the 95 total sputum specimens). All vaccine samples were negative for Mycoplasma. Rota virus vaccine is an example of a live attenuated vaccine so it has a high risk of Mycoplasma contamination. Mycoplasma contamination of cell culture (used for vaccine preparation) is a serious concern for biopharmaceutical industry. Contamination usually originates from components of cell culture medium such as serum or is introduced via individuals working in the laboratory or manufacturing facility. Consequently, any Mycoplasma contamination, if present, could indicate that insufficient care has been taken during vaccine manufacture or quality control. Sensitivity to digitonin was performed to differentiate the sterol requiring Mollicutes (Mycoplasma, Ureaplasma, Entomoplasma, Spiroplasma, and Anaeroplasma) from the non-sterol-requiring Mollicutes (Mesoplasma, Acholeplasma, and Asteroleplasma). In agreement with previous studies, all positive isolates (39 isolates) were digitonin sensitive [23]. Six species of Mycoplasma were isolated, namely, M. salivarium 10/39 (25.64%), M. orale 10/39 (25.64%), M. buccale 7/39 (17.95%), M. hominis 6/39 (15.38%), M. pneumoniae 5/39 (12.82%), and M. fermentans 1/39 (2.56%).
Our results agree with previous work in which M. salivarium was found to be the most common Mycoplasma isolate obtained from human respiratory tract among other Mycoplasma spp. [10]. According to the same study, mycoplasmas isolated from humans were classified into widespread, common, and less common or rare; M. salivarium and M. orale are widespread; M. hominis is common while M. buccale, M. pneumoniae, and M. fermentans are less common. Many Mycoplasma spp. exist as commensals of the oropharynx, M. salivarium and M. orale being the most commonly found species [11]. In addition to the previous two Mycoplasma spp., M. buccale, M. facium, and M. lipophilium are all part of the normal flora of the human oropharynx and are generally regarded as commensal organisms. In a previous study, M. orale has been detected in between 30 and 60% of throat swabs from adults, whereas M. salivarium has been detected in between 60% and 80% of swabs and M. buccale, M. faucium, and M. lipophilum were observed in <5% of cases [10]. The role of M. orale and M. salivarium in disease is limited to few reported infections, such as septic arthritis in immunocompromised hosts. In a previous survey carried out on bronchoalveolar lavage, M. salivarium was the most commonly Mycoplasma spp. isolate and was detected more frequently from HIV-positive cases (18%) than from HIV-negative (8%) [24].
In our study, M. pneumoniae accounted for 5/39 (12.82%) of the cases. The same frequency of isolation of M. pneumoniae coincided with a previous local study done in Egypt as well as another study done in Saudi Arabia [25, 26]. In Yemen, M. pneumoniae was recovered from pulmonary complications in 14.4% of patients [27]. In England and Wales one in seven children aged 5–14 years with respiratory signs tested positive for M. pneumoniae from October 2011 to January 2012 [28]. In all the previous studies, Bronchopneumonia and lobar pneumonia were the most frequent underlying clinical conditions among M. pneumoniae cases. M. hominis was found in 6/39 (15.38%) of positive Mycoplasma isolates, but it was not isolated from sputum or throat swabs of the apparently healthy group demonstrating that it could be a potential pathogen; the same observation was previously described in a study in which M. hominis was identified in 15/107 (14.01%) of positive Mycoplasma spp. isolates obtained from noncontrol clinically ill patients [19]. M. hominis can colonize the human respiratory tract and has been found in respiratory secretions in up to 3% of healthy persons and in up to 6% of persons with chronic respiratory tract disease [29, 30].
In our study, characterization of the antibiotic resistance and sensitivity pattern against different antimicrobials using disc diffusion test was carried on M. pneumoniae isolates, using different classes of antibiotics; it was very challenging as plates were examined for inhibition zones existing around the disc to the distance where colonies start to appear, under the dissecting microscope as recommended [31]. Our study revealed that M. pneumoniae was highly sensitive to macrolides, followed by fluoroquinolones and tetracyclines. However, the isolates were less sensitive (partially resistant) to aminoglycosides and resistant to lincomycin. These results are in agreement with previous studies in which it was found that macrolides, tetracyclines, and fluoroquinolones eliminate mycoplasmas efficiently both in vivo and in vitro [32–34]. The antimicrobial agents of choice for treating lower respiratory tract M. pneumoniae infections are the macrolides in both adults and children [4].
Clinical presentation of Mycoplasma spp. is variable and diagnosis confirmation is a challenge to even the most experienced clinicians [13]. Bacterial culture was generally considered as the gold standard detection method of mycoplasmosis. Culture requires specialized media and is time consuming (up to 21 days). Due to the vast reduction in time in comparison with culture, PCR has been used increasingly for M. pneumoniae detection. Molecular methods have lessened the reliance on the problematic serological detection systems. Several gene targets have been used for amplification including the 16S ribosomal RNA gene, the elongation factor tuf, the P1 cytadhesin gene, and repetitive elements [35, 36].
In this study PCR was used for detection of Mycoplasma spp. using primers targeting a highly conserved region of 16S ribosomal RNA gene. The positive samples showed amplification products of 280 bp bands. In addition, PCR was used also for specific detection of M. pneumoniae P1 cytadhesin gene, where the positive samples showed amplification products of 375 bp bands on electrogram. This result was supported by other works in which PCR was investigated as a means of diagnosing M. pneumoniae infections [37]. The target DNA sequence was a 375 bp segment of the P1 virulence protein. This DNA segment was amplified from pure cultures of M. pneumoniae but not in other species of Mycoplasma, Acholeplasma, or Ureaplasma.
Development and application of molecular-based methods during the past two decades has significantly improved the ability to detect and identify mycoplasmas and ureaplasmas in clinical specimens, enabled expansion of knowledge about the diseases they may cause, and provided more rapid and accurate diagnosis. This study and other numerous studies indicated that an amplified DNA detection system was simple, rapid and combines maximum sensitivity with high specificity [38]. The future of diagnostic Mycoplasmology and epidemiological research rests with molecular-based technology.