Current laboratory diagnosis of pathogens causing pneumonia.
Abstract
Respiratory tract infection, especially pneumonia, is a significant cause of morbidity and mortality worldwide. Although rapid and accurate identification of the pathogens and the corresponding treatment, which is based on the microbiological results, is required in the healthcare setting, the current clinical tests lack high sensitivity and flexibility. As of yet, a comprehensive approach has not been able to work these issues out. Meanwhile, the development of molecular techniques enables the detection of organisms from respiratory specimens speedily as well as precisely and aids the settlement of such issues. With our novel approach that employs relative quantification, we successfully set the cutoff value to discriminate the causative pathogen from colonizing commensal organisms by real-time PCR. In this way, a diagnostic system for respiratory pathogens was devised and validated through clinical sample testing. In this chapter, a real-time PCR-based test capable of differentiating causative pathogens in respiratory specimens is described, and also its principle and the utility of this approach are illustrated.
Keywords
- PCR
- real-time PCR
- pneumonia
- respiratory tract infection
- sputum
- HIRA-TAN
- commensal organism
- foreign organism
- non-commensal organism
- nucleic acid amplification test
- NAAT
1. Introduction
Pneumonia is a common disease in healthcare settings and is a significant cause of morbidity and mortality worldwide. Despite there being a mere two-dozen species of pathogens responsible for most cases of pneumonia, the causative pathogen cannot be identified by clinical tests involving smear and culture of sputum, antigen tests, and serological assays in up to 50% of the cases [1–4]. Therefore, the identification of the causative pathogen(s) with high detection power will allow for the selection of targeted antibiotics. Accordingly, timely identification has been shown to reduce the mortality rate and, on a long-term basis, the emergence of drug-resistant pathogens [5]. To identify such pathogens and thus to obtain the desired benefits, a clinical test is required that is sensitive, rapid, accurate, easily performed, and cost-effective.
The development and wide usage of molecular techniques, such as polymerase chain reaction (PCR), brought about remarkable advances in clinical medicine. Detection of causative pathogens in pneumonia has been optimized in the last few decades, and from that point, PCR has played a principal role in laboratory medicine [6–8]. Currently PCR-based approaches, however, are mainly used to identify foreign organisms (such as
In this chapter, a real-time PCR-based test which is capable of differentiating therapeutic targets from detected colonizing commensal organisms in respiratory samples is described, and also its principle and the utility of this approach are illustrated.
2. Clinical approach and current strategy for pneumonia
Pneumonias are as of now classified as either the community-acquired pneumonia (CAP) or the hospital-acquired pneumonia (HAP), depending on the place pneumonia is acquired (Figure 1). Each has a specific spectrum of causative pathogens and allows medical professionals to speculate on the causative pathogen and initiate empirical antimicrobial therapy covering most of the speculated pathogens (Figure 2). Following confirmation of the causative pathogen, the antimicrobial should be switched/de-escalated to more specific and appropriate medication.
3. Organisms in respiratory tract infection
3.1. Conventional diagnostic tools for causative pathogens
A wide variety of laboratory tests including culture-based methods, antigen tests, and serology have been available for diagnosis and treatment of pneumonia (Table 1). Nevertheless, despite comprehensive evaluations with a range of different tests, as many as 40% of the causative pathogens causing CAP, HCAP, and HAP remain undiagnosed (Figure 2). While defining the pathogenic role of the respiratory organisms during pneumonia is still difficult, a commensal organism and foreign organism are often considered to be a causative pathogen when the below criteria are met. These criteria have provided legitimate results and thus have been used in clinical practice.
3.2. Commensal organism
Commensal organisms form part of human normal flora in the respiratory system (e.g.,
3.3. Foreign organism (non-commensal organism)
Foreign organisms account for a small portion of pneumonias (e.g.,
3.4. Criteria for commensal organisms to be the causative pathogen
A commensal organism that fulfills at least one of the following three criteria is considered to be a causative pathogen when (1) an organism is identified from the normally sterile site (blood or pleural effusion); (2) a morphologically compatible organism, coexisting with abundant neutrophils, is observed through Gram staining and later confirmed by sputum culture; or (3) for
3.5. Criteria for foreign organisms to be the causative pathogen
Foreign organisms that fulfill at least one of the following two criteria are considered to be a causative pathogen when (1) an organism is identified by culture, antigen test (involving serum, urine or nasopharyngeal specimen), or PCR test or (2) a paired serological test reveals a significant increase in antibody titer (more than four times).
|
Gram stain, urine antigen | Culture |
|
Culture | |
|
Gram stain | Culture |
|
Gram stain | Culture |
|
Gram stain | Chocolate agar culture |
(Non-fermenter) | ||
|
Gram stain | Culture |
|
Culture | |
|
Culture | |
|
Selective agar culture | |
(Enterobacteria) | ||
|
Gram stain | Culture |
|
Culture | |
|
Culture | |
Anaerobes | Gram stain from sterile sample | Anaerobic culture |
|
NAAT | Serology CF, PPLO culture |
|
NAAT, urine antigen | BCYE culture |
|
NAAT | Serology MIF |
|
NAAT | Serology MIF |
|
NAAT | Serology IIF |
|
NAAT, AFB smear | Lowenstein-Jensen culture |
|
Anaerobic culture, microscopy for sulfur granules | |
|
Gram stain, AFB smear | Culture |
|
NAAT, Giemsa stain | |
|
GMS stain, Galactomannan test | Sabouraud agar culture |
|
Antigen test | Sabouraud agar culture |
|
Antigen test | Serology CF, Sabouraud agar culture |
|
Serology ID, Sabouraud agar culture | |
Influenza virus | NAAT, rapid antigen | |
Parainfluenza virus | NAAT | Serology EIA |
RS virus | NAAT, rapid antigen | |
|
NAAT | Serology EIA |
Adenovirus | NAAT, antigen test | |
|
pp65 antigen | |
|
Microscopy for ova | Microscopy for ova or worms |
3.6. Issues with applying conventional diagnostic tools for identifying causative pathogens in respiratory samples
Although an organism requires specific agar or a unique detection assay, applying such different kinds of diagnostic tools for all patients with pneumonia is not practical and feasible from the standpoint of labor required. Moreover, the most significant issue is the culture-based method, which is a standard test for respiratory samples containing colonizing organisms or normal flora. It is not capable of discriminating a causative pathogen from isolated commensal organisms.
4. A real-time PCR for respiratory samples
4.1. Applying molecular techniques to identifying the causative pathogens in respiratory tract infection
Nucleic acid amplification test (NAAT), such as a PCR-based test or reverse transcription-PCR (RT-PCR), for purulent sputum is a logical and beneficial strategy. Firstly, if PCR cannot detect a suspected pathogen, the pathogen is less likely to be the causative pathogen due to the highly sensitive nature of PCR which can amplify even small numbers of pathogens. Secondly, PCR is capable of identifying foreign organisms that cannot grow on the standard culture agar. Thus, their detection conclusively yields the causative pathogens. Thirdly, PCR is a speedy test, and the result can be delivered to medical professionals in an early phase of the treatment. Finally, from the standpoint of NAAT, organisms causing respiratory tract infections can be simply divided into two categories; commensal organism and foreign organism (see Sections 3.2 and 3.3). Therefore, PCR does not require the pathogen-specific agar or growth conditions since all organisms are dealt with at the nucleic acid (DNA or RNA) level in the laboratory.
4.2. Issues with applying molecular diagnostic tools for identifying causative pathogens in respiratory samples
A major problem associated with a PCR-based test, similar to conventional methods, is its inability to discriminate a commensal organism causing pneumonia from the same organism colonizing in the airway.
Given the unique aspect of sputum, we assumed that, although setting a cutoff value by the direct quantification of bacterial cell number in respiratory samples would fluctuate and thus provide indistinct discrimination between causative pathogen and colonizing organism, using the relative quantification would be more stable even using the sputum which lacks homogeneity and reproductivity. To overcome this challenge, we proposed the “battlefield hypothesis,” in which the ratio of pathogen to human cells in the respiratory samples would be an indicator for the dominant pathogen in the “pneumonia battlefield.” The principal of this hypothesis is that the relative number of combatants (i.e., pathogens) causing the current state of pneumonia is considered a major determinant.
4.3. Battlefield hypothesis
With the battlefield hypothesis, the ratio of the cell number of a commensal organism to human cell numbers is assumed to be an index of the organism’s pathogenic role. When pneumonia occurs, the number of human cells, mostly inflammatory cells, drastically climbs at the site of infection where that of causative pathogen exceeds the human cells (Figure 3A). On the other hand, pathogens that merely colonize the affected area do not proliferate. In a real-time PCR-based system specializing in quantification, the specific primers and probe can amplify the target sequence log proportionally, in which the ratio of pathogen to human cells is formulated as ΔCtpathogen = −(Ctpathogen − Cthuman) (Figure 3B). As indicated by the battlefield hypothesis, a threshold value that discriminates commensal organisms from organisms colonizing the airway would be set up as ΔCtpathogen cutoff (Figure 3C).
In order to verify the hypothesis, we first screened
1 | 11 | ||||||
SFTPC | Fw | GCAGTGCCTACGTCTAAGCTG | 16S rRNA | Fw | AGTAATACTTTAGAGGCGAACGGGTGA | ||
(U02948.1) | Rv | TAGATGTAGTAGAGCGGCACCTC | (NC_000912.1) | Rv | TCTACTTCTCAGCATAGCTACACGTCA | ||
130 bp | Dp | CGAGATGCAGGCTCAGCACCCTC | 227 bp | Dp | ACCAACTAGCTGATATGGCGCA | ||
12 | |||||||
53KD-antigen | Fw | GCAACCACGGTAGCAACACAAATTA | |||||
(E12535) | Rv | AATTGAGCGACGTTTTGTTGCATCT | |||||
364 bp | Dp | AGCGGCTGTCAAATCTGGAATAAAAG | |||||
2 | 13 | ||||||
lytA | Fw | ACGCAATCTAGCAGATGAAGCA | ompA | Fw | GTATGTTCATGCTTAAGGCTGTTTTCAC | ||
(AE005672) | Rv | TCGTGCGTTTTAATTCCAGCT | (X56980.1) | Rv | TCCCACATAGTGCCATCGATTAATAAAC | ||
75 bp | Dp | TGCCGAAAACGCTTGATACAGGGAG | 291 bp | Dp | CCAGAAGAGCAAATTAGAATAGCGAGCA | ||
3 | 14 | ||||||
16S rRNA | Fw | TTGACATCCTAAGAAGAGCTCAGAGA | Transposase | Fw | GTCTTAAGGTGGGCTGCGTG | ||
(Z22806.1) | Rv | CTTCCCTCTGTATACGCCATTGTAGC | (M80806) | Rv | CCCCGAATCTCATTGATCAGC | ||
267 bp | Dp | ATGGCTGTCGTCAGCTCGTGTT | 295 bp | Dp | AGCGAACCATTGGTATCGGACGTTTATGG | ||
4 | 15 | ||||||
copB | Fw | GACGGGTGAGTAATGCCTAGGA | 16S rRNA | Fw | AGGCTAATCTTAAAGCGCCAGGCC | ||
(U69982.1) | Rv | CCACTGGTGTTCCTTCCTATATCT | (FR799709) | Rv | GCATGCTTAACACATGCAAGTCGAAC | ||
298 bp | Dp | AGTGGGGGATCTTCGGACCTCA | 198 bp | Dp | CATATTCCTACGCGTTACTCACCCGT | ||
5 | 16 | ||||||
23S rRNA | Fw | TCCAAGTTTAAGGTGGTAGGCTG | mip | Fw | TAACCGAACAGCAAATGAAAGACG | ||
(AJ549386) | Rv | ACCACTTCGTCATCTAAAAGACGAC | (S72442.1) | Rv | AAAACGGTACCATCAATCAGACGA | ||
94 bp | Dp | AGGTAAATCCGGGGTTTCAAGGCC | 264 bp | Dp | TGATGGCAAAGCGTACTGCTGAA | ||
6 | 17 | ||||||
gapA | Fw | TGAAGTATGACTCCACTCACGGT | BP485 | Fw | CGAGCCACTGTTTCTATTGATTGA | ||
(M66869) | Rv | CTTCAGAAGCGGCTTTGATGGCTT | (BX640412) | Rv | CGGGCCTCATCTTCGTTCAG | ||
670 bp | Dp | CCGGTATCTTCCTGACCGACGA | 118 bp | Dp | TGTGCGTGTTTTCCCCAGAGCCCC | ||
7 | 18 | ||||||
femB | Fw | TGGCCACTATGAGTTAAAGCTTGC | MPB64 | Fw | ATCCGCTGCCAGTCGTCTTCC | ||
(DQ352467) | Rv | TCATAATCAATCACTGGACCGCGA | (NC_000962) | Rv | CTCGCGAGTCTAGGCCAGCAT | ||
162 bp | Dp | CGAGGTCATTGCAGCTTGCTTACTTA | 238 bp | Dp | CCGGACAACAGGTATCGATAGCGCC | ||
8 | 19 | ||||||
phoA | Fw | CGAAGAGGATTCACAAGAACATACC | ITS 16-23S rRNA | Fw | AGCACCACGAAAAGCACTCCAATT | ||
(M29670) | Rv | GGTCTGGTCGGTCAGTCCAA | (AM709724) | Rv | CGAACGCATCAGCCCTAAGGACTA | ||
94 bp | Dp | CGGGCCATACGCCGCAATACGCA | 243 bp | Dp | CCTGAGACAACACTCGGTCGATCC | ||
20 | |||||||
16S rRNA | Fw | CAAGTCGAACGGAAAGGCCTCT | |||||
(M29572) | Rv | GCCGTATCTCAGTCCCAGTGTG | |||||
257 bp | Dp | TACCGGATAGGACCTCAAGACGC | |||||
9 | Metallo-beta-lactamase | 21 | |||||
IMP | Fw | GGCAGYATTTCCTCTCATTTTCATAGC | dnaJ | Fw | ACCCGTGTGATGAGTGCAAAGGC | ||
(AY625689) | Rv | AATTTGTRGCTTGAACCTTACCGTCTT | (AB292544.1) | Rv | GTAAAGCTGACCGGAACTGTGACG | ||
134 bp | Dp | ATTCTCGATCTATCCCCACGTATGCA | 231 bp | Dp | AGGACGGACAGCGGATCAGACT | ||
10 | Methicillin-resistant |
22 | |||||
mecA | Fw | AACTACGGTAACATTGATCGCAAC | 5S rRNA | Fw | GTGTACGTTGCAAAGTACTCAGAAGA | ||
(AY786579) | Rv | CTTTGGTCTTTCTGCATTCCTGGA | (AF461782) | Rv | GATGGCTGTTTCCAAGCCCA | ||
112 bp | Dp | AGATGGTATGTGGAAGTTAGATTGGGA | 346 bp | Dp | CTAGGATATAGCTGGTTTTCTGCGAA | ||
23 | |||||||
16S rRNA | Fw | CCTTCGGGTTGTAAACCTCTTTCGAC | |||||
(DQ659898) | Rv | TTGGGGTTGAGCCCCAAGTTTTCA | |||||
191 bp | Dp | AAGAAGCACCGGCCAACTACGTGC |
4.4. Determination of the ΔCtpathogen cutoff
We then confirmed that the primers and probes were specific to seven representative commensal organisms (
4.5. HIRA-TAN system
Accordingly, we devised a PCR-based test for sputum samples that can distinguish causative pathogens from detected commensal organisms. Moreover, combining the described PCR system for “commensal organisms” with a PCR detection system for “foreign organisms” constitutes the HIRA-TAN (human cell-controlled identification of the respiratory agent from “TAN,” which means sputum in Japanese), which involved 23 PCR with organism-specific target genes for quantifying 7 commensal organisms, 13 foreign organisms, 2 drug resistance-related genes (DRRG), and the human specific gene (as the internal control) (Table 2). HIRA-TAN was capable of screening 23 target genes simultaneously and diagnosing the therapeutic targets among commensal and foreign organisms in a single assay, which was able to be completed within 4 h. The technical details in the real-time PCR and the HIRA-TAN system were discussed in more detail in Refs. [12, 14].
4.6. Criteria for detected organisms to be the therapeutic target by HIRA-TAN system
In the HIRA-TAN system, the cutoff value was determined for each commensal organism, which enabled us to discriminate the
Technically, since opportunistic organisms, such as
5. Materials and methods
5.1. Respiratory specimen
In Section 5, samples and their treatment will be described. Sputum, induced sputum, or sputum obtained by intratracheal aspiration (sputum hereafter) was collected from patients with pneumonia. The sample was homogenized by pipetting and dispensed into two tubes; one was submitted for a standard microbiological test (microscopic examination and culture) and the other for nucleic acid extraction and real-time PCR analysis. To assess the pathogenic role with an appropriate sample, sputum with M2–P3 macroscopic appearance and a Cthuman <27 (the human-specific gene with Ct (threshold cycle) value by the real-time PCR) were studied [15]. Classification of the gross appearance of the sputum (M1, M2, P1, P2, and P3) was according to Miller and Jones [16].
5.2. DNA preparation from sputum
There are several kit options available for DNA extraction depending on the sample type; however, only column-based extraction has been used for most respiratory specimens due to their viscosity [14]. The sample was diluted with an equal volume of phosphate-buffered saline (PBS) and homogenized by vortexing. 200 μL of the homogenate was mixed with 200 μL AL buffer (Qiagen, Tokyo, Japan) containing 20 μL proteinase K (Takara Bio Inc., Shiga, Japan), and the resultant mixture was incubated at 56°C for 1 h. The DNA was extracted with 100 μL TE buffer using QIAamp DNA Blood Mini Kit (Qiagen, Tokyo, Japan). The DNA concentration, based on the absorbance, was determined in a spectrophotometer GeneQuant Pro (GE Healthcare, Tokyo, Japan). The ratio of nucleic acid to protein absorbance (260 nm/280 nm) was calculated as an index of the purity of DNA samples [14].
5.3. Real-time PCR
Although a variety of PCR methodologies and devices are available, an illustration of the details of our approach is given. The final solution of the PCR contained 12.5 μL of the Takara Premix Ex Taq (Takara Bio Inc., Shiga, Japan), 300 nM of each primer, 100–300 nM of the fluorescence-labeled TaqMan probe, 1.0 μL of purified DNA, and deionized distilled water up to 25.0 μL. The PCR for 23 target genes was multiplexed in 16 reactions and amplified using in a single assay. The PCR was performed by starting at 95°C for 30 s followed by 40 cycles at 95°C for 8 s, 61°C for 25 s, and 72°C for 20 s using the SmartCycler II (Cepheid, Sunnyvale, CA). The sequences of primer and probe were described in Table 2.
6. Practical application of HIRA-TAN system
6.1. Prospective study
We designed a prospective study to investigate the validity of the cutoff values we set up for the commensal organisms in the HIRA-TAN system. The aim of the study was the proportion of samples in which ΔCtpathogen was greater than the cutoff value (diagnosed as the therapeutic target by HIRA-TAN), compared to the proportion of the samples in which each commensal organism was shown to be the causative pathogen (diagnosed as the causative pathogen by microbiological methods (Table 1)). The study was performed between February 06, 2009, and October 14, 2010, at the Saitama Medical University Hospital and other six participating institutes. Five-hundred and sixty eight patients with pneumonia were enrolled, and the results of the microbiological examinations were summarized in Ref. [12] and Figure 2. The identification rates for
6.2. Overall identification capacity of therapeutic targets by real-time PCR-based test
Overall performance of the HIRA-TAN system to identify both the therapeutic targets (commensal organisms judged by the ∆Ct cutoff and foreign organisms detected by the real-time PCR) was altogether 60–70% en masse, which was comparable to what was attained by an extensive search using multiple detection methods [10, 18, 19]. However, it is supposed to reach its limit to identify the causative pathogens using primers and probe of only bacteria, and for a thorough investigation, incorporating PCR systems for viruses, anaerobes, and fungus will be required.
6.3. Beneficial aspects of PCR-based system for identifying pathogen
The most prominent feature of the HIRA-TAN is its ability to identify the causative pathogen for the pneumonias from among the commensal organisms detected in the sputum. Clinically, without this ability, this system would have been only partially useful, since more than half of pneumonias are caused by commensal organisms (Figure 2). And this system does not require the use of pathogen-by-pathogen identification methods (unique agar or a specific antibody for an organism). The easily performed comprehensive test covers a wide variety of pathogens in a single assay, which will reduce the time and labor spent on cumbersome procedures. The HIRA-TAN procedure now provides a comprehensive detection system for causative pathogens of pneumonia.
The HIRA-TAN system can also be expanded to include more pathogens, thereby increasing its abilities. The addition of any respiratory viruses or particular fungi to the screening protocol is straightforward [6, 9–11, 20]. Likewise, the inclusion of other commensal organisms, such as
6.4. Drawback of newly emerged PCR system
Currently the ability of the HIRA-TAN system to determine if MRSA is the causative pathogen is lacking. This is largely due to the fact that the determination and establishment of the cutoff value for a given microorganism in the HIRA-TAN system still require the conventional sputum examination. To date we have not been able to determine the ΔCtMRSA cutoff, and this will take more time and the availability of properly analyzed clinical samples to be established. Likewise, the diagnosis of
7. Conclusion
In this chapter, the principle and utility of a real-time PCR-based diagnostic test for the causative pathogen in respiratory samples was described. Although rapid and accurate identification of pathogens and corresponding treatment based on the microbiological results are required in the healthcare setting, the current clinical tests lacking high sensitivity and a comprehensive approach have not been able to work these issues out. Development of molecular techniques and their usefulness enables the detection of organisms from the clinical specimens speedily as well as precisely and aids the settlement of such issues. With our novel approach that employs the relative quantification, we successfully set up the cutoff value to differentiate the causative pathogen from colonizing commensal organisms by PCR, with which a real-time PCR-based diagnostic system was devised and validated through clinical sample testing. Although this may be only one instance among many comprehensive systems, innovating such systems will help patients struggling with these disorders in the future.
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