GAT-B Biotechnology Syllabus PDF

Summary

This document provides a syllabus for the Graduate Aptitude Test in Biotechnology (GAT-B). It outlines the topics covered in two sections, one focusing on 10+2 level subjects and the other on graduate-level topics. The test uses multiple-choice questions.

Full Transcript

Graduate Aptitude Test – Biotechnology (GAT-B) – Syllabus

For admission to DBT supported Post Graduate (DBT PG) Programme in Biotechnology at
participating host institutions and universities.

The question paper for GAT-B will have two sections:
Section A: Section A will have 60 compulsory multiple choice questions of the level of 10+2in the subjects:
Physics, Chemistry, Mathematics and Biology. Each correct answer is of One (1) mark. There will be negative
marking and for each wrong answer, Half (1/2 or 0.5) mark will be deducted.

Section B: Section B will have multiple choice questions of Bachelor’s (Graduate) level requiring thinking
and analysis. There will be questions from Basic Biology, Life Sciences, Biotechnology andallied areas as per
syllabus given here. There will be 100 questions out of which candidates will have to attempt 60 questions.
Each correct answer is of Three (3) marks. There will be negative marking and for each wrong answer, One
(1) mark will be deducted.

Un-answered/un-attempted question will be given Zero (0) mark.

To answer a question, candidate needs to choose one option as correct option.

GRADUATE APTITUDE TEST-BIOTECHNOLOGY (GAT-B)

Number of Number of Questions
Sections Marks
Questions to be attempted

Section A (Multiple choice questions of 10+2 level in the
subjects: Physics, Chemistry,Mathematics and Biology). 60 60 1*60 = 60

Section B (Multiple choice questions of Graduate level in
the subjects: Basic Biology, Life Sciences, Biotechnology
100 60 3*60 = 180
and allied areas as per syllabus given here).

Total 160 120 240

Syllabus for Section A is of 10+2 level in the subjects of Physics, Chemistry, Mathematics and
Biology.

Syllabus for Section B is of Graduate level as given here:

Biomolecules-structure and functions; Biological membranes, structure, action potential and transport
processes; Enzymes- classification, kinetics and mechanism of action; Basic concepts and designs of
metabolism (carbohydrates, lipids, amino acids and nucleic acids) photosynthesis, respiration and electron
transport chain; Bioenergetics.

Viruses- structure and classification; Microbial classification and diversity (bacterial, algal and fungal); Methods in
microbiology; Microbial growth and nutrition; Aerobic and anaerobic respiration; Nitrogen fixation; Microbial
diseases and host-pathogen interaction.

Prokaryotic and eukaryotic cell structure; Cell cycle and cell growth control; Cell-Cell communication, Cell
signaling and signal transduction.

Molecular structure of genes and chromosomes; Mutations and mutagenesis; Nucleic acid replication,
transcription, translation and their regulatory mechanisms in prokaryotes and eukaryotes; Mendelian
inheritance; Gene interaction; Complementation; Linkage, genetics (plasmids, transformation, transduction,
conjugation); Horizontal gene transfer and Transposable elements; RNA interference; DNA damage and repair;
Chromosomal variation; Molecular basis of genetic diseases.
Principles of microscopy-light, electron, fluorescent and confocal; Centrifugation- high speed and ultra;
Principles of spectroscopy-UV, visible, CD, IR, FTIR, Raman, MS, NMR; Principles of chromatography- ion
exchange, gel filtration, hydrophobic interaction, affinity, GC, HPLC, FPLC; Electrophoresis; Microarray.
History of Immunology; Innate, humoral and cell mediated immunity; Antigen; Antibody structure and function;
Molecular basis of antibody diversity; Synthesis of antibody and secretion; Antigen-antibody reaction;
Complement; Primary and secondary lymphoid organ; B and T cells and macrophages; Major
histocompatibility complex (MHC); Antigen processing and presentation; Polyclonal and monoclonal
antibody; Regulation of immune response; Immune tolerance; Hypersensitivity; Autoimmunity; Graft versus
host reaction.

Major bioinformatics resources and search tools; Sequence and structure databases; Sequence analysis
(bimolecular sequence file formats, scoring matrices, sequence alignment, phylogeny); Data mining and
analytical tools for genomic and proteomic studies; Molecular dynamics and simulations (basic concepts
including force fields, protein-protein, protein-nucleic acid, protein- ligand interaction).

Restriction and modification enzymes; Vectors; plasmid, bacteriophage and other viral vectors, cosmids, Ti
plasmid, yeast artificial chromosome; mammalian and plant expression vectors; cDNA and genomic DNA
library; Gene isolation, cloning and expression; Transposons and gene targeting; DNA labeling; DNA
sequencing; Polymerase chain reactions; DNA fingerprinting; Southern and northern blotting; In- situ
hybridization; RAPD, RFLP; Site-directed mutagenesis; Gene transfer technologies; Gene therapy.

Totipotency; Regeneration of plants; Plant growth regulators and elicitors; Tissue culture and Cell suspension
culture system: methodology, kinetics of growth and, nutrient optimization;

Production of secondary metabolites by plant suspension cultures; Hairy root culture; transgenic plants; Plant
products of industrial importance.

Animal cell culture; media composition and growth conditions; Animal cell and tissue preservation; Anchorage and
non-anchorage dependent cell culture; Kinetics of cell growth; Micro & macro-carrier culture; Hybridoma
technology; Stem cell technology; Animal cloning; Transgenic animals.

Chemical engineering principles applied to biological system, Principle of reactor design, ideal and non- ideal
multiphase bioreactors, mass and heat transfer; Rheology of fermentation fluids, Aeration and agitation;
Media formulation and optimization; Kinetics of microbial growth, substrate utilization and product formation;
Sterilization of air and media; Batch, fed-batch and continuous processes; Various types of microbial and
enzyme reactors; Instrumentation control and optimization; Unit operations in solid-liquid separation and
liquid-liquid extraction; Process scale-up, economics and feasibility analysis.

Engineering principle of bioprocessing - Upstream production and downstream; Bioprocess design and
development from lab to industrial scale; Microbial, animal and plant cell culture platforms; Production of
biomass and primary/secondary metabolites; Biofuels, Bioplastics, industrial enzymes, antibiotics; Large
scale production and purification of recombinant proteins; Industrial application of chromatographic and
membrane based bio-separation methods; Immobilization of biocatalysts (enzymes and cells) for
bioconversion processes; Bioremediation-Aerobic and anaerobic processes for stabilization of solid / liquid
wastes.

Tissue culture and its application, Micropropagation. Meristem culture and production of virus-free plants.
Anther and microspore culture. Embryo and ovary culture. Protoplast isolation. Protoplast fusion-somatic
hybrids, cybrid. Somaclones, Synthetic seeds. In vitro germplasm conservation. Cryopreservation. Organelle
DNA, Satellite-and repetitive DNAs. DNA repair. Regulation of gene expression. Recombinant DNA
technology-cloning vectors, restriction enzymes, gene cloning. Methods of gene transfer in plants.
Achievements and recent developments of genetic engineering in agriculture. Development of transgenics for
biotic & abiotic stress tolerance, bioethics, terminator technology, nanotechnology, DNA fingerprinting, gene
silencing.

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