GATE Biotechnology Syllabus

Subject Code: BT

Course Structure

Course Syllabus

Section A: Engineering Mathematics

• Linear Algebra −
  • Matrices and determinants
  • Systems of linear equations
  • Eigen values and Eigen vectors
• Calculus −
  • Limit, continuity and differentiability
  • Partial derivatives
  • Maxima and minima
  • Sequences and series
  • Test for convergence
  • Fourier Series
• Differential Equations −
  • Linear and nonlinear first order ODEs
  • Higher order ODEs with constant coefficients
  • Cauchy’s and Euler’s equations
  • Laplace transforms
  • PDE-Laplace
  • Heat and wave equations
• Probability and Statistics −
  • Mean, median, mode and standard deviation
  • Random variables
  • Poisson
  • Normal and binomial distributions
  • Correlation and regression analysis
• Numerical Methods −
  • Solution of linear and nonlinear algebraic equations
  • Integration of trapezoidal and Simpson’s rule
  • Single and multistep methods for differential equations

Section B: General Biotechnology

Unit 1: Biochemistry

• Biomolecules-structure and functions −
  • Biological membranes
  • Structure
  • Action potential
  • Transport processes
• Enzymes −
  • Classification
  • Kinetics and mechanism of action
• Basic concepts and designs of metabolism −
  • Carbohydrates
  • Lipids
  • Amino acids
  • Nucleic acids
  • Photosynthesis
  • Respiration
  • Electron transport chain
• Bioenergetics

Unit 2: Microbiology

• 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

Unit 3: Cell Biology

• Prokaryotic and eukaryotic cell structure
• Cell cycle and cell growth control
• Cell-Cell communication
• Cell signaling and signal transduction

Unit 4: Molecular Biology and Genetics

• 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, recombination and chromosome mapping

• Extra chromosomal inheritance

• Microbial genetics (plasmids, transformation, transduction, conjugation)

• Horizontal gene transfers and Transposable elements

• RNA interference

• DNA damage and repair

• Chromosomal variation

• Molecular basis of genetic diseases

Unit 5: Analytical Techniques

• 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

Unit 6: Immunology

• 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

Unit 7: Bioinformatics

• Major bioinformatics resources and search tools

• Sequence and structure databases

• Sequence analysis −

  • Biomolecular 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)

Section C: Recombinant DNA Technology

• 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

Section D: Plant and Animal Biotechnology

• Totipotency
• Regeneration of plants
• Plant growth regulators and elicitors
• Tissue culture and Cell suspension culture system −
  • Methodology
  • Kinetics of growth
  • 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

Section E: Bioprocess Engineering and Process Biotechnology

• 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

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