10 NGS Categories

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Tags: metagenomics, NGS, protein, nucleic acid, sequencing, genomics

  1. RNA Sequencing: RNA sequencing (RNA-Seq) is a technique used to study the transcriptome, or the complete set of RNA molecules expressed within a cell or tissue. This approach allows researchers to analyze gene expression patterns, identify novel transcripts, and detect alternative splicing events.

  2. Whole Genome Sequencing: Whole genome sequencing (WGS) is a method that determines the complete DNA sequence of an organism's genome. This technique provides comprehensive information about an organism's genetic makeup, including the identification of genes, regulatory elements, and variations such as single nucleotide polymorphisms (SNPs) and structural variants.

  3. Amplicon Sequencing: Amplicon sequencing involves the targeted sequencing of specific genomic regions or genes using polymerase chain reaction (PCR) to amplify the regions of interest before sequencing. This approach is often used to study specific genetic variations or target known functional regions in the genome.

  4. Exome Sequencing: Exome sequencing targets the protein-coding regions of the genome, known as the exome. These regions account for approximately 1-2% of the genome but contain the majority of disease-causing genetic variations. Exome sequencing is used to identify novel disease-associated genes and mutations in known genes.

  5. CRISPR Validation (genoTYPER-NEXT): CRISPR validation is a process to assess the efficiency and specificity of CRISPR/Cas9-mediated genome editing. genoTYPER-NEXT is a high-throughput sequencing platform used to validate CRISPR/Cas9-induced mutations by sequencing the target sites and identifying the exact mutations generated by the editing process.

  6. Targeted Sequencing: Targeted sequencing is a method that focuses on sequencing specific genomic regions or genes of interest, rather than the entire genome. This approach is more cost-effective and allows for higher sequencing depth, providing better resolution for detecting low-frequency genetic variations.

  7. Metagenomics: Metagenomics is the study of genetic material obtained directly from environmental samples, such as soil or water, without the need for culturing individual organisms. This approach allows researchers to analyze the composition, diversity, and functional potential of complex microbial communities.

  8. Epigenomics: Epigenomics is the study of epigenetic modifications on a genome-wide scale, including DNA methylation, histone modifications, and non-coding RNA molecules. These modifications play essential roles in gene regulation and can have long-lasting effects on an organism's phenotype without changing the DNA sequence.

  9. Immunogenomics: Immunogenomics is the study of the genetic and epigenetic factors that influence the immune system and its response to various stimuli, including pathogens, allergens, and self-antigens. This field integrates genomic, transcriptomic, and epigenomic data to better understand the molecular mechanisms underlying immune responses and develop novel therapies for immune-related diseases.

  10. Proteomics is a branch of molecular biology that focuses on the large-scale study of proteins within an organism or a specific biological system. Unlike genomics, which deals with the study of DNA and gene sequences, proteomics investigates the structure, function, and interactions of proteins. Proteins are crucial for many cellular processes, and their functions are dictated by their structure, abundance, and modifications.

    There are several key aspects and techniques in proteomics:

    • Protein identification: Identifying the proteins present in a given sample, such as a cell, tissue, or body fluid, is a fundamental aspect of proteomics. Mass spectrometry is the most commonly used technique for protein identification, often combined with liquid chromatography to separate complex protein mixtures before analysis.

    • Protein quantification: Measuring the relative or absolute abundance of proteins in a sample is important for understanding their biological roles and potential involvement in disease processes. Techniques like label-free quantification, stable isotope labeling, and targeted mass spectrometry approaches (e.g., selected reaction monitoring) are commonly used for protein quantification.

    • Post-translational modifications (PTMs): PTMs are chemical modifications that occur after protein synthesis, such as phosphorylation, glycosylation, and acetylation. They can alter a protein's activity, stability, localization, or interaction with other molecules. Mass spectrometry-based approaches and specific enrichment techniques are used to identify and quantify PTMs.

    • Protein-protein interactions: Investigating how proteins interact with one another is crucial for understanding cellular processes and signaling pathways. Techniques like yeast two-hybrid screens, affinity purification-mass spectrometry (AP-MS), and proximity labeling methods can reveal protein-protein interactions.

    • Structural proteomics: This area focuses on determining the three-dimensional structures of proteins, which provide insights into their functions and interactions. Techniques like X-ray crystallography, nuclear magnetic resonance (NMR) spectroscopy, and cryo-electron microscopy (cryo-EM) are used to determine protein structures.

    • Functional proteomics: This aspect of proteomics aims to understand the biological roles of proteins and their involvement in cellular processes. Techniques like RNA interference (RNAi), CRISPR/Cas9-mediated gene editing, and activity-based protein profiling (ABPP) are used to study protein functions and identify potential drug targets.

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