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Molecular Diagnostics.pptx

Alisha Shaikh
Alisha Shaikh

This document discusses molecular diagnostics techniques. It begins by introducing molecular diagnostics and its significance in detecting pathogens, genetic mutations, and biomarkers. It then describes several key techniques used in molecular diagnostics, including nucleic acid amplification methods like PCR, isothermal amplification, and hybridization techniques. It also discusses methods like microarrays, genotyping, and mass spectrometry. The document provides examples of how these techniques are applied to detect various infectious diseases and genetic conditions.

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Applications of Biotechnology In Molecular Diagnostics MODULE II T. Y. BSC. BIOTECHNOLOGY
INTRODUCTION • Molecular Diagnostics is the detection of pathogenic mutations in DNA and RNA samples to aid in detection, diagnosis, subclassification, prognosis and monitoring response to therapy. • It covers correct and accurate identification of causative agents like microbes in microbial diseases, particular genetic sequences in genetic diseases and protein levels. • Specificity and Sensitivity important tools in diagnosis. • Nucleic-based diagnosis originate from localization, Identification, and Characterization of genes responsible for human disease. It also determines how these genes and proteins are interacting in a cell. It focuses upon patterns, gene and protein activity patterns in different types of cells. • This diagnostics uncovers the sets of changes and captures this information as expression patterns. Also called "molecular signatures," these expression patterns are improving the clinicians' ability to diagnose diseases.
SIGNIFICANCE OF MOLECULAR DIAGNOSTICS • Detection of infectious diseases such as human immunodeficiency virus (HIV), hepatitis B virus (HBV), hepatitis C virus (HCV), human papilloma virus (HPV), cytomegalovirus (CMV), Chlamydia trachomatis, Neisseria gonorrhoeae, and Mycobacterium tuberculosis. • Other molecular tests are applied in forensic medicine, paternity testing, tissue typing, oncology, and food and beverage testing. • Molecular diagnostic testing can be performed on very small amounts of tissue obtained from many different types of procedures, including small biopsies and fine-needle aspirates. • Testing can even be performed on archival material (material that has been collected in the past and fixed in formalin). It is usually not necessary to take extra tissue for these tests, since most of them can be performed on tissue that is left over after routine diagnostic analysis.
TECHNIQUES INVOLVED IN MOLECULAR DIAGNOSTICS • Nucleic Acid Amplification Techniques: PCR and its modifications, Isothermal amplifications • Nucleic Acid Hybridization Techniques: FISH( Fluorescent In Situ Hybridization), Line probe assay • Microarrays • Genotyping • Mass Spectometry
NUCLEIC ACID AMPLIFICATION TECHNIQUES 1. PCR (Polymerase Chain Reaction) • PCR is used in molecular diagnostics due to its exquisite sensitivity and specificity. • PCR allows the amplification of millions of identical DNA copies from an originally small amount of pathogen genome in a clinical sample. Principle: • The target DNA is first extracted then denatured at high temperature. • Specific oligonucleotide primers are annealed to the DNA in a lower temperature, followed by an extension phase during which the DNA polymerase enzyme copies the template strand. • This cycle is repeated, usually 30 to 40 times, resulting in millions of identical DNA copies
Applications Of PCR: • PCR is increasingly applied in the diagnosis of viruses, bacteria, parasites, and fungi. • Qualitative PCR is widely used for a range of infections including herpesviruses (HSV, VZV, CMV, EBV), enteroviruses, parvoviruses, respiratory viruses, SARSCoV, and poxviruses, as well as general or specific bacterial screening, such as Neisseria meningitidis, Streptococcus pneumoniae, Bordetella pertussis, and Borrelia spp PCR Modifications used in Molecular Diagnostics a. Real time PCR: • Also known as qPCR or quantitative PCR • The accumulation of amplification product is measured as the reaction progresses, in real time, with product quantification after each cycle. • Real-time PCR takes advantage of a fluorescent reporter, which gives signal in direct proportion to the amount of PCR amplicon. • The method allows real-time detection and quantification of PCR amplicons following each thermal cycle.
• A melting curve analysis method differentiates PCR amplicons according to length and different guanine cytosine contents. • This can be used as an alternative to sequencing for detection of the different strains of the pathogen or gene mutations related to antibiotic resistance (e.g. meticillin*-resistant Staphylococcus aureus and vancomycin-resistant enterococci). • Real-time PCR is rapid with high sample throughput, and usually is more sensitive and specific in comparison to conventional methods. Graph of qPCR
b. Ligase chain reaction (LCR): • LCR is a modification of PCR. In this method, two adjacent probes hybridize to one strand of the target DNA. The small gap between the two adjacent primers is recognized by a highly specific thermostable DNA ligase, and ligated to form a single probe. The ligated products then serve as templates for the amplification process. LCR allows the detection of only single base pair mutations, and it is very specific. The most common application of LCR is in the diagnostics of Chlamydia trachomatis in cervical and urine samples. Ligase Chain Reaction
C. Multiplex PCR • Multiplex PCR is a particular kind of reaction that can amplify more than one locus linked to multiple microbes, hence, helps in simultaneous detection of various microorganisms by a single PCR reaction. This method is just similar to the previous method except that several specific primers are combined in a single PCR assay. • Several multiplex PCR assays have been reported in which foodborne pathogens have been detected, for instance, a rapid multiplex PCR simultaneously detected five important pathogens including L. monocytogenes, Shigella flexner, Salmonella enteritidis, E. coli O157:H7, and S. aureus in artificially contaminated pork. This highly specific, efficient, and sensitive method also found that 80% meat samples were positive for these pathogens by using five primer sets specific to these microbes.
2. Isothermal Amplification • Unlike PCR, isothermal amplification techniques are based on a distinct enzyme that does not require thermocycling (heating and cooling cycles), which can take several hours. Isothermal amplification is rapid; it usually requires less than an hour to perform. • However, the technique is currently fairly expensive. We describe here some of the best-known isothermal amplification methods. a. Nucleic acid sequence-based amplification (NASBA): • In NASBA analysis which is performed in isothermal conditions, the target RNA is converted to double- stranded DNA by using T7 RNA polymerase, RNaseH, and a primer with a T7 promoter. • The DNA acts as a template to produce multiple copies of RNA with a polarity opposite that of the target, which can be used for the production of additional DNA templates. • NASBA is also suitable for DNA, with slight modifications in the early steps of the process. • A recent example of NASBA technology in clinical diagnostics is a real-time multiplex. NASBA assay for the detection of Mycoplasma pneumoniae, Chlamydophila pneumoniae, and Legionella spp. in respiratory specimens
Transcription-mediated amplification (TMA): The principle of TMA is similar to NASBA, except that it uses the RNaseH activity of reverse transcriptase, whereas NASBA uses a separate enzyme for that. Due to the introduction of West Nile virus (WNV) in to the US since 1999, screening of primary WNV infection in blood donors was initiated. Currently, TMA is referred to as the most sensitive nucleic acid test commercially available for WNV infection, and is used on a large scale for blood donor screening in the US. Another clinical example of a large-scale and worldwide use of TMA technology is in the detection of Chlamydia trachomatis and Neisseria gonorrhoeae in urine and urogenital swab specimens. Strand displacement amplification (SDA): SDA is another isothermal amplification method. The first set of primers containing a restriction site is annealed to DNA template. Second primers are then annealed adjacent to the first ones and start amplification, after which restriction enzyme HincII is introduced in order to nick the synthesized DNA. An exonuclease deficient form of the Klenow fragment of Escherichia coli DNA polymerase I starts the amplification again, displacing the newly synthesized strands. Similar to other isothermal amplification techniques, the amplification process of SDA is very efficient. SDA is used, for example, in the diagnosis of N. gonorrhoeae infection from female endocervical swabs and male first-void urine samples.
Fluorescence in situ hybridization (FISH) : • The FISH technique allows the detection of microbial nucleic acid directly from the sample (or cultured sample) without prior nucleic acid amplification. • Briefly, the technique consists of specimen fixation on a microscope slide, hybridizing the prepared sample with a specific fluorescent-labelled probe, and visual detection of the hybridization with a fluorescent microscope. • In medical microbiology, the technique is used, e.g. in determination of antibiotic resistance and detection of Helicobacter pylori from gastric biopsy specimens. Identifying bacteria from CSF or Staphylococcus aureus from blood cultures NUCLEIC ACID HYBRIDIZATION TECHNIQUES
Line probe assay • The line probe assay (LiPA) is another nucleic acid hybridization test, in which specific oligonucleotide probes are attached at known locations on a nitrocellulose strip as parallel lines and hybridized with biotin-labelled PCR products. • One of the widely used LiPA applications is rapid detection of rifampicin resistance in Mycobacterium tuberculosis. • The LiPA technique is also applied in the detection of antiviral drug-resistant mutations of HBV.
Microarrays consist of a two-dimensional matrix of biomolecules which are printed or synthesized on a glass, silicon, plastic or nylon membrane. Microarrays can detect both nucleic acids and antibodies, which attach to the immobilized biomolecule, which can be, e.g., an oligonucleotide or a protein. Positive reaction can be detected with highly advanced scanners by use of target labelling with fluorescent probes or antibodies MICROARRAYS
• Genotyping refers to the Identification of variations of different strains or subtypes of the pathogen at nucleic acid level. • Genotyping of PCR amplicons can be performed by direct sequencing, by reverse hybridization to genotype-specific probes, by restriction fragment length polymorphism, or by detection of single nucleotide polymorphisms with mass spectrometry. • Direct sequencing is usually considered as the gold standard as it provides accurate and extensive data. Genotyping plays an important role in the management of HCV infection, as response to treatment considerably varies between different genotypes; patients with HCV genotype 2 or 3 infection respond better to treatment than those with genotype 1 infection. • Both direct sequencing and probe hybridization approaches are widely used for HCV genotyping. • An example of genotyping currently moving into routine practice is human papilloma virus (HPV) typing. Eight oncogenic HPV types (16, 18, 31, 33, 35, 45, 52, and 58) are responsible for 80% of cervical cancers and cervical intraepithelial neoplasia worldwide; distinct patterns are seen in different regions. Genotyping for the oncogenic HPV types enables risk assessment, personalized clinical management and early intervention in women with mildly abnormal Pap results. • Genotyping is also widely used for molecular epidemiology and in identifying antimicrobial resistance and high-risk strains. Genotyping
• Mass spectrometry allows the measurement of the molecular mass of a sample, which can be utilized in various clinical diagnostic settings. • In this technique, the sample is first ionized, the ions are separated according to their mass-to-charge ratios, and finally the separated ions are detected according to the ion current. Ionization of the sample can be done in various ways, of which matrix-assisted laser desorption/ionization (MALDI) is widely used in the genotyping of single nucleotide polymorphisms. • MALDI mass spectrometry is an important tool in typing of bacteria and viruses, which is useful, e.g. in detecting hyper virulent or antimicrobial drug resistant strains. The technique has been introduced, e.g. for genotyping of HCV and monitoring of quasi species (a cloud of variant RNA viruses that arise from mutations over time within a viral isolate) in chronic HCV infection. • It is also used in the detection of hyper virulent N. meningitidis strains; only five of the 13 serogroups are frequently associated with invasive disease. Recently, a method based on broad-range RT-PCR followed by electrospray ionization mass spectrometry has been applied for monitoring of global spread of novel influenza virus genotypes. Mass spectrometry
DIAGNOSTIC BIOMARKERS • A Diagnostic Biomarker detects or confirms the presence of a disease or condition of interest, or identifies an individual with a subtype of the disease. • Biological markers (biomarkers) have been defined as “cellular, biochemical or molecular alterations that are measurable in biological media such as human tissues, cells, or fluids.” • Biomarkers are biological characteristics that can be objectively measured and evaluated as an indicator of normal biological processes, pathogenic processes, or pharmacological responses to a therapeutic intervention. In practice, biomarkers include tools and technologies that can aid in understanding the prediction, cause, diagnosis, progression, regression, or outcome of treatment of disease. • Biomarkers can also reflect the entire spectrum of disease from the earliest manifestations to the terminal stages. • Biomarkers can also provide insight into disease progression, prognosis, and response to therapy.
Capabilities of Biomarkers: •Describing the events between exposure and disease •Establishment of dose-response •Identification of early events in the natural history •Identification of mechanisms by which exposure and disease are related •Reduction in misclassification of exposures or risk factors and disease •Establishment of variability and effect modification •Enhanced individual and group risk assessments
Examples Of Diagnostic Biomarkers • Sweat chloride may be used as a diagnostic biomarker to confirm cystic fibrosis •Certain cystic fibrosis transmembrane conductance regulator (CFTR) mutations may be used as diagnostic biomarkers for evaluating treatment for cystic fibrosis, to select patients more likely to respond to particular treatments (i.e., to serve as a predictive biomarker) •Galactomannan may be used as a diagnostic biomarker to classify patients as having probable invasive aspergillosis for enrollment into clinical trials of antifungal agents for treatment of invasive aspergillosis. •Blood sugar or hemoglobin A1c (HbA1c) may be used as a diagnostic biomarker to identify patients with Type 2 diabetes mellitus (DM) •Repeated blood pressure readings obtained outside the clinical setting in adults 18 years and older may be used as a diagnostic biomarker to identify those with essential hypertension •Glomerular filtration rate (GFR) may be used as a diagnostic biomarker to identify patients with chronic kidney disease •Ejection fraction may be used as a diagnostic biomarker in patients with heart failure to identify patients with a subset of disease (those with low ejection fraction or preserved ejection fraction)
Role of markers in disease diagnosis • Identification of individuals destined to become affected or who are in the ―preclinical stages of the illness •Reduction in disease heterogeneity in clinical trials or epidemiologic studies •Reflection of the natural history of disease encompassing the phases of induction, latency and detection • Target for a clinical trial. • Provide a means of monitoring the state of progression of disease and the effectiveness of therapeutic options.
Immunodiagnostic Techniques • Immunodiagnostic assays are procedures that utilize products of the immune response as integral parts of the test. Basically, immunodiagnostic assays use antibodies generated either against a single antigen or antigens associated with a specific analyte, pathogen, or disease condition. •Immunodiagnostics Techniques Using: 1. Fluorogenic reporters 2. Electro-Chemiluminescent tags 3. DNA reporters 4. Label free immunoassays
Fluroscent Immunoassay using flurogenic reporters •Fluorescent immunoassays were developed to detect patient antibodies to a large number of viruses, bacteria, and parasites, and to detect auto antibodies in patients suffering from diseases. •In the typical fluorescent antibody assay, blood specimens from patients suspected of having a pathogenic infection were incubated with antigen preparations attached to glass microscope slides. Normally, these antigen preparations consisted of whole formalin-fixed bacteria or parasites, or histological specimens cut to about 5 microns thickness. • If antibodies to the pathogen were present in the patient blood sample, they would specifically bind to the antigen fixed on the slide. After incubating for 30 minutes to two hours, the patient antibody mixture was washed off and a second antibody preparation, coupled with a fluorescent dye, was added. If patient antibodies were present, the second antibody would specifically attach to them during the incubation period. •The glass slides were then washed again, dried, and a mounting agent with counter stain was added to the slide before cover slipping. •Slides were then visually observed under a fluorescent microscope. Positive reactions were indicated by the antigen preparation showing complete peripheral fluorescence, and strength of the reaction was determined by serial titration of the blood specimen.
Examples Of Flurogenic Reporters 1. Fluorescein Isothiocyanate (FITC) 2. Tetramethylrhodamine Isothiocyanate (TRITC). These isothiocyanates will crosslink to amino, sulfhydryl, imidazoyl, tyrosyl or carbonyl groups on a protein. However, only the derivatives of primary and secondary amines generally yield stable products. Reactions are most efficient at pH 8-9, and must be performed in an amine-free buffer such as carbonate/bicarbonate. 3. DAPI (4', 6-diamidino-2-phenylindole) : DAPI is a fluorescent dye that binds selectively to double stranded DNA and forms strongly fluorescent DNA-DAPI complexes with high specificity. It is commonly used to detect mycoplasma in cell culture via fluorescence microscopy. 4. Propidium Iodide
Electrochemiluminescenc e •Electrochemiluminescent immunoassay (ECLIA) uses electrochemical compounds that generate light electrochemically, linked with the cycle reaction of the oxidative reduction. •With optimization of reaction solutions, selection of appropriate conjugation method, and development of suitable compounds such as Ru(bpy)3 2+ and tetrapentylammonium (TPA), it became possible to apply electrochemiluminescent technology to immunoassays •Ru(bpy)3 2+ has a reaction site for the conjugation of analytes using activation reagent such as NHS. •The conjugate generates light on the surface of gold electrodes. Ru(bpy)3 on solid phase and TPA are oxidized on the surface of electrodes to form Ru(bpy)3 2+ and TPA+, respectively. TPA+ spontaneously loses electrons. •Ru(bpy)3 3+ can generate emission light at 620 nm when it returns to Ru(bpy)3 2+ as a ground state through reduction with TPA.
•The efficiency of light generation (quantum yield) depends on the proximity between the electrode and the conjugate and, thereby, on the diffusion mobility of the conjugate. •Free conjugates can generate more light than conjugates fixed on the solid phase as a result of immune reaction. This allows easy access to the homogeneous assay format, but relatively high background noise interferes with assay sensitivity, as it does in other homogeneous assays. •The assay protocol for the determination of analytes is as follows: magnetic microparticles coated with antibody as the solid phase and sample mix together for immune reaction. After washing for bound and free conjugates by magnetic separation according to the assay format, the solid-phase suspension is introduced into the detector with the electrode to measure chemiluminescence.
DNA Reporters • Genes that are used in genetic analysis because their products are easy to detect are known as reporter genes. They are often used to report on gene expression, although they may also be used for other purposes, such as detecting the location of a protein or the presence of a particular segment of DNA , or even if two proteins interact. •Easily assayble enzymes as DNA Reporters 1. ꞵ- Galactosidase 2. Alkaline Phosphatase 3. Luciferase 4. Green Fluorescent Proteins
1. ꞵ- Galactosidase •One of the first reporter genes for monitoring gene expression was the lacZ gene encoding β-galactosidase. This enzyme normally splits lactose, a compound sugar found in milk, into the simpler sugars glucose and galactose. However, β-galactosidase will also split a wide range of galactose compounds (i.e., galactosides) both natural and artificial. •The two most commonly used artificial galactosides are ONPG and X-gal. ONPG (o-nitrophenyl galactoside) is split into o-nitrophenol and galactose. The o-nitrophenol is yellow and soluble, so it is easy to measure quantitatively. •X-gal (5-bromo-4-chloro-3-indolyl β-D-galactoside) is split into galactose plus the precursor to an indigo type dye. Oxygen in the air converts the precursor to an insoluble blue dye that precipitates out at the location where the lacZ gene is expressed. Substrate 1: Lactose
Substrate 2: ONPG Substrate 3:X -Gal
2. Alkaline Phosphatase Another reporter gene is the phoA gene that encodes alkaline phosphatase. This enzyme cleaves phosphate groups from a broad range of substrates . Like β-galactosidase, alkaline phosphatase will use a variety of artificial substrates: (1) o-Nitrophenyl phosphate is split, releasing yellow o-nitrophenol. (2) X-phos (5-bromo-4-chloro-3-indolyl phosphate) consists of an indigo dye precursor joined to phosphate. After the enzyme splits this, exposure to air converts the dye precursor to a blue dye, as in the case of X-gal. (3) 4-Methylumbelliferyl phosphate releases a fluorescent compound when the phosphate is removed. Substrate 1 Substrate 2
•Alkaline phosphatase removes phosphate groups from various substrates. •When the phosphate group is removed from o-nitrophenyl phosphate, a yellow dye is released. •When the phosphate is removed from X-phos, further reaction with oxygen produces an insoluble blue dye as for Xgal. •Additionally, alkaline phosphatase releases a fluorescent molecule when the phosphate is removed from 4-methylumbelliferyl phosphate.
3. Light Emission by Luciferase As a Reporter System •A more sophisticated reporter gene encodes luciferase. This enzyme emits light when provided with a substrate known as luciferin. •Luciferase is found naturally in assorted luminous creatures from bacteria to deep-sea squid. The lux genes from bacteria and the luc genes from fireflies produce different brands of luciferase, but both work well as reporter genes. FIG: Luciferase Degrades Luciferin and Emits Light Luciferase is an enzyme that alters the structure of luciferin. When the structure is altered, a pulse of light is emitted, which is detected by a photodetector. The luciferin shown in this figure is FMN (flavin mononucleotide), which is used by bacterial luciferases.
•The luciferins used by the different types of luciferase are chemically different. •Bacterial luciferase uses the reduced form of the co-factor FMN (flavin mononucleotide) as its luciferin. Oxygen and a long chain aldehyde (R-CHO) are also needed. Both the reduced FMN and the aldehyde are oxidized. •Different groups of eukaryotes make several chemically distinct luciferins that are used solely for light emission. •Firefly luciferase requires ATP as well as oxygen and firefly luciferin •If DNA carrying a gene for luciferase is incorporated into a target cell, it will emit light only when the appropriate luciferin is added. Although high-level expression of luciferase can be seen with the naked eye, usually the amount of light is small and must be detected with a sensitive electronic apparatus such as a luminometer or a scintillation counter.
Green Fluorescent Proteins as reporters •Unlike the products of most reporter genes, green fluorescent protein (GFP) is not an enzyme, and it does not need a nonprotein co-factor for it to fluoresce. •GFP is a stable and nontoxic protein from jellyfish that can be visualized by its inherent green fluorescence. Consequently, GFP can be directly observed in living tissue without the need for adding any reagents. •The cloned gene for GFP originally came from the jellyfish Aequorea victoria. This form of GFP is excited by long wavelength UV light (excitation maximum 395 nm) and emits at 510 nm in the green. A variety of genetically engineered variants of GFP are also in use.
1. Fusions of regulatory regions and promoters to the gfp gene have been used to monitor the expression of many genes (B) Phase contrast and (C) Fluorescence emission of germlings of the fungus Aspergillus nidulans. Original GFP was used to label the nucleus and a red GFP variant (DsRed) for the mitochondria Applications of GFP
2. GFP is widely used to localize proteins within the cell GFP can be used to reveal where a protein is localized within the cell. The first step is to fuse the GFP gene in frame with all or part of the structural gene that encodes the protein of interest. The fused construct is then expressed in a host cell. The cells are excited with long wavelength UV light and visualized under the microscope. If the protein is normally located in the membrane, as in this example, the cell membrane will fluoresce green in the microscope.
Label Free Immunoassays ● Label-free technologies quantitate biomolecules by sensing a change in a physical parameter caused by biomolecular interactions. ● Typically, the physical parameter is refractive index, optical thickness, energy, or mass. ● Using this approach, immunoassays based on label-free technologies, i.e. label-free immunoassays (LFIAs), are able to measure antibody-antigen binding in real time, achieving immunometric quantitation without attaching a reporter molecule (enzyme, fluorophore, etc.) to the immunocomplex. ● Conventional label-free technologies include surface plasmon resonance, isothermal titration calorimetry, and quartz crystal microbalance.
Surface Plasmon Resonance SPR-based biosensors are currently the most commonly used devices for optical biosensing applications. SPR-based sensing has recently emerged as a valuable technique for measuring binding constants, association and dissociation rate constants, and stoichiometry for bimolecular binding interaction kinetics in a number of emerging biological areas. The practical applications of SPR analyses includes kinetic analysis, equilibrium analysis and concentration analysis. Kinetic and equilibrium analyses are used to characterize bimolecular interaction (ligand–analyte binding, antibody–antigen interaction, receptor characterization etc.) in a label-free, real-time manner
Isothermal titration calorimetry ● Used for the label-free measurement of the binding affinity and thermodynamics of biomolecular interactions to understand function and mechanisms at molecular level. ● Isothermal Titration Calorimetry is used to measure reactions between biomolecules. ● The methodology allows determination of the binding affinity, stoichiometry, and entropy and enthalpy of the binding reaction in solution, without the need to use labels. ● When binding occurs, heat is either absorbed or released and this is measured by the sensitive calorimeter during gradual titration of the ligand into the sample cell containing the biomolecule of interest.
Quartz Crystal Microbalance ● The quartz crystal microbalance (QCM) is a biosensor platform that incorporates a mechanical transducer, which operates on the principle of mass detection. ● QCM-based biosensors have gained significant interest in the field of pathogen detection due to their ability to detect virtually any type of biomolecule via a label-free method . Moreover, the rapid detection process and the high sensitivity of QCM systems are particularly attractive for the development of novel diagnostic tools. ● QCM systems can detect virtually any type of molecule because mass is an intrinsic property of all substances, making it a versatile platform for detecting the diverse types of disease biomarkers. ● Molecular recognition events at the crystal surface are instantaneously reflected in the frequency response without the need for labelling procedures, resulting in a short detection time, typically between 30 min to 1 h.
Binding event increases the resolution of the frequency response, which effectively lowers the detection limit of the biosensor.
Latest development in Label Free Immunoassays ● In the past decade, label-free technologies have advanced into the era of dip-in-solution sensing probes. ● The resulting LFIAs are open access, making them similar to plate-format assays without complicated sample delivery or fluidics. This allows for simple experiment workflows and makes new LFIAs well-suited for clinical laboratory applications. ● A new technology of this kind is thin-film interferometry (TFI), which incorporates a thin glass rod as a sensing probe that transmits light to form thin-film interference on a sensing surface. When biomolecules bind to the sensing surface and change its optical thickness, the interference pattern also changes relative to the number of bound biomolecules. In this way, this method measures the quantity of bound biomolecules in real time.
Cellular Genomics in Diagnostics
What is Cellular Genomics? • Cellular genomics is the study of the genetic makeup of a single cell – from the cell’s entire DNA code (its genome), to the secondary code that organises the genome (its epigenome), and the total genetic output of the cell (its transcriptome). Exquisitely detailed and massively high- throughput, cutting-edge cellular genomics technologies make it possible to unlock unknown insights into how cells work individually, and how they function together. • Cellular genomics can revolutionise our understanding of complex diseases, particularly cancer, immunological and neurological diseases.
Overview of single-cell genomics to understand disease pathogenesis of heart failure
Single cell multi omics: The simultaneous detection of DNA sequences and RNA expression profiles enables the identification of disease-causing variants and their association with gene expression. There are novel methods to simultaneously extract information from DNA and RNA . By physically separating mRNA from genomic DNA using oligo-dT bead capture and performing whole-transcriptome and whole-genome amplifications. Study of multiple perturbations with single cell readouts:Multiple perturbations with single-cell readout has been developed to analyze epigenetic regulation , enhancer–promoter interactions, protein expression , and morphological and phenotypical assessments. Immunoprofiling: The diversity of the vertebrate adaptive immune system is based on somatic rearrangements of V(D)J genes encoding the T-cell receptor (TCR) α and β chains; therefore, simultaneous analysis of TCR sequence (clonality) and gene expression from individual cells provides a deeper understanding of molecular behavior in the adaptive immune system. By integrating single-cell transcriptomes with clonal information during the development of the human thymus.
• Human diseases often affect specific cell types within organ systems. • In some disorders, such as amyloid lateral sclerosis (ALS), the disease impacts a single cell type representing a minor population of all cells in the tissue, as is the case for the motor neurons in ALS. • Because tissues are composed of heterogeneous cell types, studying cell-type-specific features of human pathological conditions demands alternatives to conventional genomics approaches, such as bulk tissue RNA sequencing. • Recent advances in single-cell genomics, in particular single-cell RNA sequencing, are opening new avenues for identifying the exact molecular changes that are associated with pathology in specific cell types
Functional Genomics in Diagnostics
What is functional genomics? • Functional genomics is the study of how the genome and its products, including RNA and proteins, function and interact to affect different biological processes. • The field of functional genomics includes transcriptomics, proteomics, metabolomics and epigenomics, as these all relate to controlling the genome leading to expression of particular phenotypes. • By studying whole genomes— clinical genomics, transcriptomes and epigenomes—functional genomics allows the exploration of the diverse relationship between genotype and phenotype, not only for humans as a species but also in individuals, allowing an understanding and evaluation of how the functional genome ‘contributes’ to different diseases. • Functional variation in disease can help us better understand that disease.
Clinical Functional Genomic Pathway: Functional genomic analysis can be performed on a patient sample using highthroughput technologies like bulk RNA sequencing or newer methods, including spatial transcriptomics, to provide insight into the cellular transcriptome. These are compatible with next generation sequencing (NGS) which is a massively parallel, high-throughput technology that rapidly determines the order of nucleotides in entire genomes or targeted regions . It is also possible to use microarrays to profile multi-gene expression, however, while this method is more cost-effective, it does not give the same complete picture as RNA sequencing or spatial transcriptomics. If only a small number of genes need to be tested, real-time PCR provides a highly sensitive and cost- efficient method of choice. Downstream bioinformatic analysis of the patient’s unique functional genome can identify diseases or disorders, allowing for a tailored treatment plan specific to the patient. This more accurate diagnosis and treatment results in better prognosis for patients and is the fundamental basis of precision medicine.
Use of functional genomics in diagnosing cancer The field of functional genomics is of great relevance clinically to cancer patients, where most research and development is currently focused. Changes in the genome or epigenome can cause cancer by promoting uncontrolled cell growth or causing the immune system to fail to destroy tumors. Using a clinical functional genomics approach can allow for earlier and more accurate cancer diagnosis, leading to more accurate treatment options and better prognosis for patients.

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Molecular Diagnostics.pptx

  • 1. Applications of Biotechnology In Molecular Diagnostics MODULE II T. Y. BSC. BIOTECHNOLOGY
  • 2. INTRODUCTION • Molecular Diagnostics is the detection of pathogenic mutations in DNA and RNA samples to aid in detection, diagnosis, subclassification, prognosis and monitoring response to therapy. • It covers correct and accurate identification of causative agents like microbes in microbial diseases, particular genetic sequences in genetic diseases and protein levels. • Specificity and Sensitivity important tools in diagnosis. • Nucleic-based diagnosis originate from localization, Identification, and Characterization of genes responsible for human disease. It also determines how these genes and proteins are interacting in a cell. It focuses upon patterns, gene and protein activity patterns in different types of cells. • This diagnostics uncovers the sets of changes and captures this information as expression patterns. Also called "molecular signatures," these expression patterns are improving the clinicians' ability to diagnose diseases.
  • 3. SIGNIFICANCE OF MOLECULAR DIAGNOSTICS • Detection of infectious diseases such as human immunodeficiency virus (HIV), hepatitis B virus (HBV), hepatitis C virus (HCV), human papilloma virus (HPV), cytomegalovirus (CMV), Chlamydia trachomatis, Neisseria gonorrhoeae, and Mycobacterium tuberculosis. • Other molecular tests are applied in forensic medicine, paternity testing, tissue typing, oncology, and food and beverage testing. • Molecular diagnostic testing can be performed on very small amounts of tissue obtained from many different types of procedures, including small biopsies and fine-needle aspirates. • Testing can even be performed on archival material (material that has been collected in the past and fixed in formalin). It is usually not necessary to take extra tissue for these tests, since most of them can be performed on tissue that is left over after routine diagnostic analysis.
  • 4. TECHNIQUES INVOLVED IN MOLECULAR DIAGNOSTICS • Nucleic Acid Amplification Techniques: PCR and its modifications, Isothermal amplifications • Nucleic Acid Hybridization Techniques: FISH( Fluorescent In Situ Hybridization), Line probe assay • Microarrays • Genotyping • Mass Spectometry
  • 5. NUCLEIC ACID AMPLIFICATION TECHNIQUES 1. PCR (Polymerase Chain Reaction) • PCR is used in molecular diagnostics due to its exquisite sensitivity and specificity. • PCR allows the amplification of millions of identical DNA copies from an originally small amount of pathogen genome in a clinical sample. Principle: • The target DNA is first extracted then denatured at high temperature. • Specific oligonucleotide primers are annealed to the DNA in a lower temperature, followed by an extension phase during which the DNA polymerase enzyme copies the template strand. • This cycle is repeated, usually 30 to 40 times, resulting in millions of identical DNA copies
  • 6. Applications Of PCR: • PCR is increasingly applied in the diagnosis of viruses, bacteria, parasites, and fungi. • Qualitative PCR is widely used for a range of infections including herpesviruses (HSV, VZV, CMV, EBV), enteroviruses, parvoviruses, respiratory viruses, SARSCoV, and poxviruses, as well as general or specific bacterial screening, such as Neisseria meningitidis, Streptococcus pneumoniae, Bordetella pertussis, and Borrelia spp PCR Modifications used in Molecular Diagnostics a. Real time PCR: • Also known as qPCR or quantitative PCR • The accumulation of amplification product is measured as the reaction progresses, in real time, with product quantification after each cycle. • Real-time PCR takes advantage of a fluorescent reporter, which gives signal in direct proportion to the amount of PCR amplicon. • The method allows real-time detection and quantification of PCR amplicons following each thermal cycle.
  • 7. • A melting curve analysis method differentiates PCR amplicons according to length and different guanine cytosine contents. • This can be used as an alternative to sequencing for detection of the different strains of the pathogen or gene mutations related to antibiotic resistance (e.g. meticillin*-resistant Staphylococcus aureus and vancomycin-resistant enterococci). • Real-time PCR is rapid with high sample throughput, and usually is more sensitive and specific in comparison to conventional methods. Graph of qPCR
  • 8. b. Ligase chain reaction (LCR): • LCR is a modification of PCR. In this method, two adjacent probes hybridize to one strand of the target DNA. The small gap between the two adjacent primers is recognized by a highly specific thermostable DNA ligase, and ligated to form a single probe. The ligated products then serve as templates for the amplification process. LCR allows the detection of only single base pair mutations, and it is very specific. The most common application of LCR is in the diagnostics of Chlamydia trachomatis in cervical and urine samples. Ligase Chain Reaction
  • 9. C. Multiplex PCR • Multiplex PCR is a particular kind of reaction that can amplify more than one locus linked to multiple microbes, hence, helps in simultaneous detection of various microorganisms by a single PCR reaction. This method is just similar to the previous method except that several specific primers are combined in a single PCR assay. • Several multiplex PCR assays have been reported in which foodborne pathogens have been detected, for instance, a rapid multiplex PCR simultaneously detected five important pathogens including L. monocytogenes, Shigella flexner, Salmonella enteritidis, E. coli O157:H7, and S. aureus in artificially contaminated pork. This highly specific, efficient, and sensitive method also found that 80% meat samples were positive for these pathogens by using five primer sets specific to these microbes.
  • 10. 2. Isothermal Amplification • Unlike PCR, isothermal amplification techniques are based on a distinct enzyme that does not require thermocycling (heating and cooling cycles), which can take several hours. Isothermal amplification is rapid; it usually requires less than an hour to perform. • However, the technique is currently fairly expensive. We describe here some of the best-known isothermal amplification methods. a. Nucleic acid sequence-based amplification (NASBA): • In NASBA analysis which is performed in isothermal conditions, the target RNA is converted to double- stranded DNA by using T7 RNA polymerase, RNaseH, and a primer with a T7 promoter. • The DNA acts as a template to produce multiple copies of RNA with a polarity opposite that of the target, which can be used for the production of additional DNA templates. • NASBA is also suitable for DNA, with slight modifications in the early steps of the process. • A recent example of NASBA technology in clinical diagnostics is a real-time multiplex. NASBA assay for the detection of Mycoplasma pneumoniae, Chlamydophila pneumoniae, and Legionella spp. in respiratory specimens
  • 11. Transcription-mediated amplification (TMA): The principle of TMA is similar to NASBA, except that it uses the RNaseH activity of reverse transcriptase, whereas NASBA uses a separate enzyme for that. Due to the introduction of West Nile virus (WNV) in to the US since 1999, screening of primary WNV infection in blood donors was initiated. Currently, TMA is referred to as the most sensitive nucleic acid test commercially available for WNV infection, and is used on a large scale for blood donor screening in the US. Another clinical example of a large-scale and worldwide use of TMA technology is in the detection of Chlamydia trachomatis and Neisseria gonorrhoeae in urine and urogenital swab specimens. Strand displacement amplification (SDA): SDA is another isothermal amplification method. The first set of primers containing a restriction site is annealed to DNA template. Second primers are then annealed adjacent to the first ones and start amplification, after which restriction enzyme HincII is introduced in order to nick the synthesized DNA. An exonuclease deficient form of the Klenow fragment of Escherichia coli DNA polymerase I starts the amplification again, displacing the newly synthesized strands. Similar to other isothermal amplification techniques, the amplification process of SDA is very efficient. SDA is used, for example, in the diagnosis of N. gonorrhoeae infection from female endocervical swabs and male first-void urine samples.
  • 12. Fluorescence in situ hybridization (FISH) : • The FISH technique allows the detection of microbial nucleic acid directly from the sample (or cultured sample) without prior nucleic acid amplification. • Briefly, the technique consists of specimen fixation on a microscope slide, hybridizing the prepared sample with a specific fluorescent-labelled probe, and visual detection of the hybridization with a fluorescent microscope. • In medical microbiology, the technique is used, e.g. in determination of antibiotic resistance and detection of Helicobacter pylori from gastric biopsy specimens. Identifying bacteria from CSF or Staphylococcus aureus from blood cultures NUCLEIC ACID HYBRIDIZATION TECHNIQUES
  • 13. Line probe assay • The line probe assay (LiPA) is another nucleic acid hybridization test, in which specific oligonucleotide probes are attached at known locations on a nitrocellulose strip as parallel lines and hybridized with biotin-labelled PCR products. • One of the widely used LiPA applications is rapid detection of rifampicin resistance in Mycobacterium tuberculosis. • The LiPA technique is also applied in the detection of antiviral drug-resistant mutations of HBV.
  • 14. Microarrays consist of a two-dimensional matrix of biomolecules which are printed or synthesized on a glass, silicon, plastic or nylon membrane. Microarrays can detect both nucleic acids and antibodies, which attach to the immobilized biomolecule, which can be, e.g., an oligonucleotide or a protein. Positive reaction can be detected with highly advanced scanners by use of target labelling with fluorescent probes or antibodies MICROARRAYS
  • 15. • Genotyping refers to the Identification of variations of different strains or subtypes of the pathogen at nucleic acid level. • Genotyping of PCR amplicons can be performed by direct sequencing, by reverse hybridization to genotype-specific probes, by restriction fragment length polymorphism, or by detection of single nucleotide polymorphisms with mass spectrometry. • Direct sequencing is usually considered as the gold standard as it provides accurate and extensive data. Genotyping plays an important role in the management of HCV infection, as response to treatment considerably varies between different genotypes; patients with HCV genotype 2 or 3 infection respond better to treatment than those with genotype 1 infection. • Both direct sequencing and probe hybridization approaches are widely used for HCV genotyping. • An example of genotyping currently moving into routine practice is human papilloma virus (HPV) typing. Eight oncogenic HPV types (16, 18, 31, 33, 35, 45, 52, and 58) are responsible for 80% of cervical cancers and cervical intraepithelial neoplasia worldwide; distinct patterns are seen in different regions. Genotyping for the oncogenic HPV types enables risk assessment, personalized clinical management and early intervention in women with mildly abnormal Pap results. • Genotyping is also widely used for molecular epidemiology and in identifying antimicrobial resistance and high-risk strains. Genotyping
  • 16. • Mass spectrometry allows the measurement of the molecular mass of a sample, which can be utilized in various clinical diagnostic settings. • In this technique, the sample is first ionized, the ions are separated according to their mass-to-charge ratios, and finally the separated ions are detected according to the ion current. Ionization of the sample can be done in various ways, of which matrix-assisted laser desorption/ionization (MALDI) is widely used in the genotyping of single nucleotide polymorphisms. • MALDI mass spectrometry is an important tool in typing of bacteria and viruses, which is useful, e.g. in detecting hyper virulent or antimicrobial drug resistant strains. The technique has been introduced, e.g. for genotyping of HCV and monitoring of quasi species (a cloud of variant RNA viruses that arise from mutations over time within a viral isolate) in chronic HCV infection. • It is also used in the detection of hyper virulent N. meningitidis strains; only five of the 13 serogroups are frequently associated with invasive disease. Recently, a method based on broad-range RT-PCR followed by electrospray ionization mass spectrometry has been applied for monitoring of global spread of novel influenza virus genotypes. Mass spectrometry
  • 17.
  • 18.
  • 19. DIAGNOSTIC BIOMARKERS • A Diagnostic Biomarker detects or confirms the presence of a disease or condition of interest, or identifies an individual with a subtype of the disease. • Biological markers (biomarkers) have been defined as “cellular, biochemical or molecular alterations that are measurable in biological media such as human tissues, cells, or fluids.” • Biomarkers are biological characteristics that can be objectively measured and evaluated as an indicator of normal biological processes, pathogenic processes, or pharmacological responses to a therapeutic intervention. In practice, biomarkers include tools and technologies that can aid in understanding the prediction, cause, diagnosis, progression, regression, or outcome of treatment of disease. • Biomarkers can also reflect the entire spectrum of disease from the earliest manifestations to the terminal stages. • Biomarkers can also provide insight into disease progression, prognosis, and response to therapy.
  • 20. Capabilities of Biomarkers: •Describing the events between exposure and disease •Establishment of dose-response •Identification of early events in the natural history •Identification of mechanisms by which exposure and disease are related •Reduction in misclassification of exposures or risk factors and disease •Establishment of variability and effect modification •Enhanced individual and group risk assessments
  • 21. Examples Of Diagnostic Biomarkers • Sweat chloride may be used as a diagnostic biomarker to confirm cystic fibrosis •Certain cystic fibrosis transmembrane conductance regulator (CFTR) mutations may be used as diagnostic biomarkers for evaluating treatment for cystic fibrosis, to select patients more likely to respond to particular treatments (i.e., to serve as a predictive biomarker) •Galactomannan may be used as a diagnostic biomarker to classify patients as having probable invasive aspergillosis for enrollment into clinical trials of antifungal agents for treatment of invasive aspergillosis. •Blood sugar or hemoglobin A1c (HbA1c) may be used as a diagnostic biomarker to identify patients with Type 2 diabetes mellitus (DM) •Repeated blood pressure readings obtained outside the clinical setting in adults 18 years and older may be used as a diagnostic biomarker to identify those with essential hypertension •Glomerular filtration rate (GFR) may be used as a diagnostic biomarker to identify patients with chronic kidney disease •Ejection fraction may be used as a diagnostic biomarker in patients with heart failure to identify patients with a subset of disease (those with low ejection fraction or preserved ejection fraction)
  • 22. Role of markers in disease diagnosis • Identification of individuals destined to become affected or who are in the ―preclinical stages of the illness •Reduction in disease heterogeneity in clinical trials or epidemiologic studies •Reflection of the natural history of disease encompassing the phases of induction, latency and detection • Target for a clinical trial. • Provide a means of monitoring the state of progression of disease and the effectiveness of therapeutic options.
  • 23. Immunodiagnostic Techniques • Immunodiagnostic assays are procedures that utilize products of the immune response as integral parts of the test. Basically, immunodiagnostic assays use antibodies generated either against a single antigen or antigens associated with a specific analyte, pathogen, or disease condition. •Immunodiagnostics Techniques Using: 1. Fluorogenic reporters 2. Electro-Chemiluminescent tags 3. DNA reporters 4. Label free immunoassays
  • 24. Fluroscent Immunoassay using flurogenic reporters •Fluorescent immunoassays were developed to detect patient antibodies to a large number of viruses, bacteria, and parasites, and to detect auto antibodies in patients suffering from diseases. •In the typical fluorescent antibody assay, blood specimens from patients suspected of having a pathogenic infection were incubated with antigen preparations attached to glass microscope slides. Normally, these antigen preparations consisted of whole formalin-fixed bacteria or parasites, or histological specimens cut to about 5 microns thickness. • If antibodies to the pathogen were present in the patient blood sample, they would specifically bind to the antigen fixed on the slide. After incubating for 30 minutes to two hours, the patient antibody mixture was washed off and a second antibody preparation, coupled with a fluorescent dye, was added. If patient antibodies were present, the second antibody would specifically attach to them during the incubation period. •The glass slides were then washed again, dried, and a mounting agent with counter stain was added to the slide before cover slipping. •Slides were then visually observed under a fluorescent microscope. Positive reactions were indicated by the antigen preparation showing complete peripheral fluorescence, and strength of the reaction was determined by serial titration of the blood specimen.
  • 25.
  • 26. Examples Of Flurogenic Reporters 1. Fluorescein Isothiocyanate (FITC) 2. Tetramethylrhodamine Isothiocyanate (TRITC). These isothiocyanates will crosslink to amino, sulfhydryl, imidazoyl, tyrosyl or carbonyl groups on a protein. However, only the derivatives of primary and secondary amines generally yield stable products. Reactions are most efficient at pH 8-9, and must be performed in an amine-free buffer such as carbonate/bicarbonate. 3. DAPI (4', 6-diamidino-2-phenylindole) : DAPI is a fluorescent dye that binds selectively to double stranded DNA and forms strongly fluorescent DNA-DAPI complexes with high specificity. It is commonly used to detect mycoplasma in cell culture via fluorescence microscopy. 4. Propidium Iodide
  • 27. Electrochemiluminescenc e •Electrochemiluminescent immunoassay (ECLIA) uses electrochemical compounds that generate light electrochemically, linked with the cycle reaction of the oxidative reduction. •With optimization of reaction solutions, selection of appropriate conjugation method, and development of suitable compounds such as Ru(bpy)3 2+ and tetrapentylammonium (TPA), it became possible to apply electrochemiluminescent technology to immunoassays •Ru(bpy)3 2+ has a reaction site for the conjugation of analytes using activation reagent such as NHS. •The conjugate generates light on the surface of gold electrodes. Ru(bpy)3 on solid phase and TPA are oxidized on the surface of electrodes to form Ru(bpy)3 2+ and TPA+, respectively. TPA+ spontaneously loses electrons. •Ru(bpy)3 3+ can generate emission light at 620 nm when it returns to Ru(bpy)3 2+ as a ground state through reduction with TPA.
  • 28. •The efficiency of light generation (quantum yield) depends on the proximity between the electrode and the conjugate and, thereby, on the diffusion mobility of the conjugate. •Free conjugates can generate more light than conjugates fixed on the solid phase as a result of immune reaction. This allows easy access to the homogeneous assay format, but relatively high background noise interferes with assay sensitivity, as it does in other homogeneous assays. •The assay protocol for the determination of analytes is as follows: magnetic microparticles coated with antibody as the solid phase and sample mix together for immune reaction. After washing for bound and free conjugates by magnetic separation according to the assay format, the solid-phase suspension is introduced into the detector with the electrode to measure chemiluminescence.
  • 29. DNA Reporters • Genes that are used in genetic analysis because their products are easy to detect are known as reporter genes. They are often used to report on gene expression, although they may also be used for other purposes, such as detecting the location of a protein or the presence of a particular segment of DNA , or even if two proteins interact. •Easily assayble enzymes as DNA Reporters 1. ꞵ- Galactosidase 2. Alkaline Phosphatase 3. Luciferase 4. Green Fluorescent Proteins
  • 30. 1. ꞵ- Galactosidase •One of the first reporter genes for monitoring gene expression was the lacZ gene encoding β-galactosidase. This enzyme normally splits lactose, a compound sugar found in milk, into the simpler sugars glucose and galactose. However, β-galactosidase will also split a wide range of galactose compounds (i.e., galactosides) both natural and artificial. •The two most commonly used artificial galactosides are ONPG and X-gal. ONPG (o-nitrophenyl galactoside) is split into o-nitrophenol and galactose. The o-nitrophenol is yellow and soluble, so it is easy to measure quantitatively. •X-gal (5-bromo-4-chloro-3-indolyl β-D-galactoside) is split into galactose plus the precursor to an indigo type dye. Oxygen in the air converts the precursor to an insoluble blue dye that precipitates out at the location where the lacZ gene is expressed. Substrate 1: Lactose
  • 32. 2. Alkaline Phosphatase Another reporter gene is the phoA gene that encodes alkaline phosphatase. This enzyme cleaves phosphate groups from a broad range of substrates . Like β-galactosidase, alkaline phosphatase will use a variety of artificial substrates: (1) o-Nitrophenyl phosphate is split, releasing yellow o-nitrophenol. (2) X-phos (5-bromo-4-chloro-3-indolyl phosphate) consists of an indigo dye precursor joined to phosphate. After the enzyme splits this, exposure to air converts the dye precursor to a blue dye, as in the case of X-gal. (3) 4-Methylumbelliferyl phosphate releases a fluorescent compound when the phosphate is removed. Substrate 1 Substrate 2
  • 33. •Alkaline phosphatase removes phosphate groups from various substrates. •When the phosphate group is removed from o-nitrophenyl phosphate, a yellow dye is released. •When the phosphate is removed from X-phos, further reaction with oxygen produces an insoluble blue dye as for Xgal. •Additionally, alkaline phosphatase releases a fluorescent molecule when the phosphate is removed from 4-methylumbelliferyl phosphate.
  • 34. 3. Light Emission by Luciferase As a Reporter System •A more sophisticated reporter gene encodes luciferase. This enzyme emits light when provided with a substrate known as luciferin. •Luciferase is found naturally in assorted luminous creatures from bacteria to deep-sea squid. The lux genes from bacteria and the luc genes from fireflies produce different brands of luciferase, but both work well as reporter genes. FIG: Luciferase Degrades Luciferin and Emits Light Luciferase is an enzyme that alters the structure of luciferin. When the structure is altered, a pulse of light is emitted, which is detected by a photodetector. The luciferin shown in this figure is FMN (flavin mononucleotide), which is used by bacterial luciferases.
  • 35. •The luciferins used by the different types of luciferase are chemically different. •Bacterial luciferase uses the reduced form of the co-factor FMN (flavin mononucleotide) as its luciferin. Oxygen and a long chain aldehyde (R-CHO) are also needed. Both the reduced FMN and the aldehyde are oxidized. •Different groups of eukaryotes make several chemically distinct luciferins that are used solely for light emission. •Firefly luciferase requires ATP as well as oxygen and firefly luciferin •If DNA carrying a gene for luciferase is incorporated into a target cell, it will emit light only when the appropriate luciferin is added. Although high-level expression of luciferase can be seen with the naked eye, usually the amount of light is small and must be detected with a sensitive electronic apparatus such as a luminometer or a scintillation counter.
  • 36. Green Fluorescent Proteins as reporters •Unlike the products of most reporter genes, green fluorescent protein (GFP) is not an enzyme, and it does not need a nonprotein co-factor for it to fluoresce. •GFP is a stable and nontoxic protein from jellyfish that can be visualized by its inherent green fluorescence. Consequently, GFP can be directly observed in living tissue without the need for adding any reagents. •The cloned gene for GFP originally came from the jellyfish Aequorea victoria. This form of GFP is excited by long wavelength UV light (excitation maximum 395 nm) and emits at 510 nm in the green. A variety of genetically engineered variants of GFP are also in use.
  • 37. 1. Fusions of regulatory regions and promoters to the gfp gene have been used to monitor the expression of many genes (B) Phase contrast and (C) Fluorescence emission of germlings of the fungus Aspergillus nidulans. Original GFP was used to label the nucleus and a red GFP variant (DsRed) for the mitochondria Applications of GFP
  • 38. 2. GFP is widely used to localize proteins within the cell GFP can be used to reveal where a protein is localized within the cell. The first step is to fuse the GFP gene in frame with all or part of the structural gene that encodes the protein of interest. The fused construct is then expressed in a host cell. The cells are excited with long wavelength UV light and visualized under the microscope. If the protein is normally located in the membrane, as in this example, the cell membrane will fluoresce green in the microscope.
  • 39. Label Free Immunoassays ● Label-free technologies quantitate biomolecules by sensing a change in a physical parameter caused by biomolecular interactions. ● Typically, the physical parameter is refractive index, optical thickness, energy, or mass. ● Using this approach, immunoassays based on label-free technologies, i.e. label-free immunoassays (LFIAs), are able to measure antibody-antigen binding in real time, achieving immunometric quantitation without attaching a reporter molecule (enzyme, fluorophore, etc.) to the immunocomplex. ● Conventional label-free technologies include surface plasmon resonance, isothermal titration calorimetry, and quartz crystal microbalance.
  • 40. Surface Plasmon Resonance SPR-based biosensors are currently the most commonly used devices for optical biosensing applications. SPR-based sensing has recently emerged as a valuable technique for measuring binding constants, association and dissociation rate constants, and stoichiometry for bimolecular binding interaction kinetics in a number of emerging biological areas. The practical applications of SPR analyses includes kinetic analysis, equilibrium analysis and concentration analysis. Kinetic and equilibrium analyses are used to characterize bimolecular interaction (ligand–analyte binding, antibody–antigen interaction, receptor characterization etc.) in a label-free, real-time manner
  • 41. Isothermal titration calorimetry ● Used for the label-free measurement of the binding affinity and thermodynamics of biomolecular interactions to understand function and mechanisms at molecular level. ● Isothermal Titration Calorimetry is used to measure reactions between biomolecules. ● The methodology allows determination of the binding affinity, stoichiometry, and entropy and enthalpy of the binding reaction in solution, without the need to use labels. ● When binding occurs, heat is either absorbed or released and this is measured by the sensitive calorimeter during gradual titration of the ligand into the sample cell containing the biomolecule of interest.
  • 42. Quartz Crystal Microbalance ● The quartz crystal microbalance (QCM) is a biosensor platform that incorporates a mechanical transducer, which operates on the principle of mass detection. ● QCM-based biosensors have gained significant interest in the field of pathogen detection due to their ability to detect virtually any type of biomolecule via a label-free method . Moreover, the rapid detection process and the high sensitivity of QCM systems are particularly attractive for the development of novel diagnostic tools. ● QCM systems can detect virtually any type of molecule because mass is an intrinsic property of all substances, making it a versatile platform for detecting the diverse types of disease biomarkers. ● Molecular recognition events at the crystal surface are instantaneously reflected in the frequency response without the need for labelling procedures, resulting in a short detection time, typically between 30 min to 1 h.
  • 43. Binding event increases the resolution of the frequency response, which effectively lowers the detection limit of the biosensor.
  • 44. Latest development in Label Free Immunoassays ● In the past decade, label-free technologies have advanced into the era of dip-in-solution sensing probes. ● The resulting LFIAs are open access, making them similar to plate-format assays without complicated sample delivery or fluidics. This allows for simple experiment workflows and makes new LFIAs well-suited for clinical laboratory applications. ● A new technology of this kind is thin-film interferometry (TFI), which incorporates a thin glass rod as a sensing probe that transmits light to form thin-film interference on a sensing surface. When biomolecules bind to the sensing surface and change its optical thickness, the interference pattern also changes relative to the number of bound biomolecules. In this way, this method measures the quantity of bound biomolecules in real time.
  • 45. Cellular Genomics in Diagnostics
  • 46. What is Cellular Genomics? • Cellular genomics is the study of the genetic makeup of a single cell – from the cell’s entire DNA code (its genome), to the secondary code that organises the genome (its epigenome), and the total genetic output of the cell (its transcriptome). Exquisitely detailed and massively high- throughput, cutting-edge cellular genomics technologies make it possible to unlock unknown insights into how cells work individually, and how they function together. • Cellular genomics can revolutionise our understanding of complex diseases, particularly cancer, immunological and neurological diseases.
  • 47. Overview of single-cell genomics to understand disease pathogenesis of heart failure
  • 48. Single cell multi omics: The simultaneous detection of DNA sequences and RNA expression profiles enables the identification of disease-causing variants and their association with gene expression. There are novel methods to simultaneously extract information from DNA and RNA . By physically separating mRNA from genomic DNA using oligo-dT bead capture and performing whole-transcriptome and whole-genome amplifications. Study of multiple perturbations with single cell readouts:Multiple perturbations with single-cell readout has been developed to analyze epigenetic regulation , enhancer–promoter interactions, protein expression , and morphological and phenotypical assessments. Immunoprofiling: The diversity of the vertebrate adaptive immune system is based on somatic rearrangements of V(D)J genes encoding the T-cell receptor (TCR) α and β chains; therefore, simultaneous analysis of TCR sequence (clonality) and gene expression from individual cells provides a deeper understanding of molecular behavior in the adaptive immune system. By integrating single-cell transcriptomes with clonal information during the development of the human thymus.
  • 49. • Human diseases often affect specific cell types within organ systems. • In some disorders, such as amyloid lateral sclerosis (ALS), the disease impacts a single cell type representing a minor population of all cells in the tissue, as is the case for the motor neurons in ALS. • Because tissues are composed of heterogeneous cell types, studying cell-type-specific features of human pathological conditions demands alternatives to conventional genomics approaches, such as bulk tissue RNA sequencing. • Recent advances in single-cell genomics, in particular single-cell RNA sequencing, are opening new avenues for identifying the exact molecular changes that are associated with pathology in specific cell types
  • 50.
  • 51. Functional Genomics in Diagnostics
  • 52. What is functional genomics? • Functional genomics is the study of how the genome and its products, including RNA and proteins, function and interact to affect different biological processes. • The field of functional genomics includes transcriptomics, proteomics, metabolomics and epigenomics, as these all relate to controlling the genome leading to expression of particular phenotypes. • By studying whole genomes— clinical genomics, transcriptomes and epigenomes—functional genomics allows the exploration of the diverse relationship between genotype and phenotype, not only for humans as a species but also in individuals, allowing an understanding and evaluation of how the functional genome ‘contributes’ to different diseases. • Functional variation in disease can help us better understand that disease.
  • 53. Clinical Functional Genomic Pathway: Functional genomic analysis can be performed on a patient sample using highthroughput technologies like bulk RNA sequencing or newer methods, including spatial transcriptomics, to provide insight into the cellular transcriptome. These are compatible with next generation sequencing (NGS) which is a massively parallel, high-throughput technology that rapidly determines the order of nucleotides in entire genomes or targeted regions . It is also possible to use microarrays to profile multi-gene expression, however, while this method is more cost-effective, it does not give the same complete picture as RNA sequencing or spatial transcriptomics. If only a small number of genes need to be tested, real-time PCR provides a highly sensitive and cost- efficient method of choice. Downstream bioinformatic analysis of the patient’s unique functional genome can identify diseases or disorders, allowing for a tailored treatment plan specific to the patient. This more accurate diagnosis and treatment results in better prognosis for patients and is the fundamental basis of precision medicine.
  • 54.
  • 55. Use of functional genomics in diagnosing cancer The field of functional genomics is of great relevance clinically to cancer patients, where most research and development is currently focused. Changes in the genome or epigenome can cause cancer by promoting uncontrolled cell growth or causing the immune system to fail to destroy tumors. Using a clinical functional genomics approach can allow for earlier and more accurate cancer diagnosis, leading to more accurate treatment options and better prognosis for patients.