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Detection and Identification of Microorganisms

Detection and Identification of Microorganisms. Chapter 12. Applications of Molecular Based Testing in Clinical Microbiology. Rapid or high-throughput identification of microorganisms Those that are difficult or time-consuming to isolate e.g., Mycobacteria Hazardous organisms

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Detection and Identification of Microorganisms

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  1. Molecular Diagnostics Detection and Identification of Microorganisms Chapter 12

  2. Molecular Diagnostics Applications of Molecular Based Testing in Clinical Microbiology • Rapid or high-throughput identification of microorganisms • Those that are difficult or time-consuming to isolate • e.g.,Mycobacteria • Hazardous organisms • e.g.,Histoplasma, Coccidiodes • Those without reliable testing methods • e.g.,HIV, HCV • High-volume tests • e.g.,S. pyogenes, N.gonorrhoeae, C. trachomatis

  3. Molecular Diagnostics Applications of Molecular Based Testing in Clinical Microbiology • Detection and analysis of resistance genes • mecA oxacillin resistance in Staphylococcus aureus • vanA, vanB, and vanC vancomycinresistance in Enterococcus • katG and inhA isoniazidresistance in M. tuberculosis • Genotyping • Mycobacterium, HCV, and HIV • Reclassification of microorganisms for epidemiological purposes, and to predict therapeutic efficacy • Discovery of new microorganisms

  4. Molecular Diagnostics Specimen Collection • Preserve viability/nucleic acid integrity of target microorganisms • Viability is not much critical for molecular testing • DNA and especially RNA can be damaged in lysed or nonviable cells • Avoid contamination that could yield false-positive results • Due to the sensitivity of molecular testing • Appropriate time and site of collection (blood, urine, other) • Obtimize the likely presence of the infectious agent • E.g., Salmonella typhi is initially present in peripheral blood but not in urine or stool until at least 2 weeks after infection • Use proper equipment (coagulant, wood, or plastic swab shafts) • E.g., Plastics are less adherent to the microorganisms and will not interfere with PCR reagents as do emanations from wooden shafted swabs

  5. Molecular Diagnostics Sample Preparation • Depending on the microorganism more rigorous lysis procedures may be required • Mycobacteria and fungi have thick cell walls that are more difficult to lyse than other bacteria and parasites. • Gram-positive bacteria cell wall is thicker than gram-negative bacteria • Mycoplasma, lacks a cell wall, thus avoid spontaneous lysis of the cells and loss of nucleic acids • The concentration of organisms within the clinical sample must be considered. • Centrifuge to concentrate the fluid and the organisms within the fluid

  6. 6 Molecular Diagnostics Molecular Diagnostics Sample Preparation • Inhibitors of enzymes used in molecular analysis may be present in clinical specimens • Acidic polysaccharides in sputum or polymerase inhibitors in CSF • if RNA is to be analyzed • inactivation or removal of RNases in the sample and in all reagents and materials that come into contact with the sample

  7. Molecular Diagnostics Quiz • In order to increase the stringency of a PCR reaction we need to, • Decrease the annealing temperature and increase the annealing time • Increase the annealing temperature and increase the annealing time • Decrease the annealing temperature and decrease the annealing time • Increase the annealing temperature and decrease the annealing time

  8. Molecular Diagnostics PCR Detection of Microorganisms: Quality Control • PCR and other amplification methods are extremely sensitive and very specific. For accurate test interpretation, use proper controls. • Positive control: positive template • Negative template control: negative template • Amplification control: omnipresent template unrelated to target • Reagent blank/contamination control: no template present

  9. Molecular Diagnostics PCR Quality Control: Internal Controls • Homologous extrinsic • wild-type–derived control with a nontarget-derived sequence insert • Added to every sample after nucleic acid extraction and before amplification • Amplification occurs using the same primers as for the target • Good for ensuring that amplification occurs in the sample • does not control for target nucleic acid degradation during extraction. Target sequence

  10. 10 Molecular Diagnostics Molecular Diagnostics PCR Quality Control: Internal Controls Target sequence • Heterologous extrinsic • Nontarget-derived controls • Added to every sample before nucleic acid extraction • Will ensure that extraction and amplification procedures are acceptable • A second set of primers must also be added to the reaction for this control to be amplified. • The procedure must be optimized such that the amplification of the control does not interfere with the amplification of the target.

  11. 11 Molecular Diagnostics Molecular Diagnostics PCR Quality Control: Internal Controls • Heterologous intrinsic • Eukaryotic genes. • ensures that human nucleic acid is present in the sample in addition to controlling for extraction and amplification • Requires two amplification reactions for the sample, or the amplification procedure be multiplexed Target sequence

  12. Molecular Diagnostics Quality Control: False Positives • Contamination: check reagent blank • Dead or dying organisms: retest 3–6 weeks after antimicrobial therapy • Detection of less than clinically significant levels

  13. Molecular Diagnostics Quality Control: False negative • Improper collection, specimen handling • Extraction/amplification failure: check internal controls • Technical difficulties with chemistry or instrumentation: check method and calibrations

  14. 14 Molecular Diagnostics Molecular Diagnostics Selection of Sequence Targetsfor Detection of Microorganisms

  15. 15 Molecular Diagnostics Molecular Diagnostics

  16. Molecular Diagnostics Mechanisms for Development of Resistance to Antimicrobial Agents • Enzymatic inactivation of agent • Altered target • Altered transport of agent in or out • Acquisition of genetic factors from other resistant organisms

  17. Molecular Diagnostics Advantages of Molecular Detection of Resistance to Antimicrobial Agents • Mutated genes are strong evidence of resistance • Rapid detection without culturing • Direct comparison of multiple isolates in epidemiological investigations

  18. Molecular Diagnostics Molecular Epidemiology • Epidemic: rapidly spreading outbreak of an infectious disease • Pandemic: a disease that sweeps across wide geographical areas • Epidemiology: collection and analysis of environmental, microbiological, and clinical data

  19. Molecular Diagnostics Molecular Epidemiology • Phenotypic analysis measures biological characteristics of organisms. • Molecular epidemiology is a genotypic analysis targeting genomic or plasmid DNA. • Species, strain, or type-specific DNA sequences are the sources of genotype information.

  20. Molecular Diagnostics O = Outbreak strain 1-6 = Isolates = Changes from outbreak strain Pulsed-field Gel Electrophoresis (PFGE) Organisms with large genomes or multiple chromosomes DNA is digested with infrequently cutting restriction enzymes Large fragments (hundreds of thousands of base pairs) are resolved by PFGE Patterns of organisms will differ depending on the chromosomal DNA sequence of the organisms

  21. Molecular Diagnostics Criteria for PFGE Pattern Interpretation: Rule of Three *Compared to the outbreak strain.

  22. Molecular Diagnostics M O Arbitrarily Primed PCR: Random Amplification of Polymorphic DNA (RAPD) M = Molecular weight marker O = Outbreak strain Four isolates differ from the outbreak strain.

  23. Molecular Diagnostics Enterobacterial repetitive intergenic consensus Repetitive extragenicpalindromic Interspersed Repetitive Elements PCR amplification priming outward from repetitive elements generates strain-specific products. Is the unknown (U) strain A or B?

  24. Molecular Diagnostics Comparison of Molecular Epidemiology Methods

  25. Molecular Diagnostics Viruses • “Classical methods” of detection include antibody detection, antigen detection, or culture. • Molecular methods of detection include target, probe, and signal amplification. • Tests are designed for identification of viruses, determination of viral load (number of viruses per ml of fluid), and genotyping by sequence analysis.

  26. Molecular Diagnostics Test Performance Features for Viral Load Measurement

  27. Molecular Diagnostics Viral Genotyping • Viral genes mutate to overcome antiviral agents. • Gene mutations are detected by sequencing. • Primary resistance mutations affect drug sensitivity but may slow viral growth. • Secondary-resistance mutations compensate for the primary-resistance growth defects.

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