Sem 2 Iar Syllabus

Get Started. It's Free
or sign up with your email address
Sem 2 Iar Syllabus by Mind Map: Sem 2 Iar Syllabus

1. biophysics

1.1. introduction to biophysics

1.2. Atomic Structure

1.3. Spectroscopic Techniques

1.4. Microscopic Techniques

1.5. Separation Techniques

2. Bioinformatics

2.1. Basics to bioinformatics

2.2. Biological databases and Public resources

2.3. Sequence Alignment techniques and analysis

2.4. Phylogenetic analysis

2.5. Structural bioinformatics

2.6. Emerging techniques in computational Biology

3. genetics

3.1. unit 1

3.1.1. early concept of inheritance, Mendel experiments,Extension and Exceptions of Mendelian laws, lethal genes, codominance, incomplete dominance, genetic interacrtion "Epistasis" Types of epistasis, complementary grenes, multiple allels, pleiotropy, and genetic heterogeneity,

3.1.2. Nature and structure of genetic material, organisation of DNA in genome, Genetic Code, Replication Trascription, Translation, gene regulation in Eukaryotes

3.2. Unit 2

3.2.1. Sex determination in plants and animals

3.2.2. Differentiation and Sex linkage

3.2.3. Sex-limited traits and diseases

3.2.4. Linkage and Recombination Basic concepts

3.2.5. Mutation basic concept

3.2.5.1. Structural Changes in chromosomes

3.2.5.1.1. Deletions

3.2.5.1.2. Duplications

3.2.5.1.3. Inversions

3.2.5.1.4. Translocations

3.2.5.2. Numerical changes in chromosomes

3.2.5.2.1. Aneuploidy

3.2.5.2.2. Polyploidy

3.2.5.3. Numerical changes in human Chromosomes

3.2.5.4. Mutagenesis

3.2.5.5. Detection of Mutant

3.3. Unit 3

3.3.1. Genetic mapping

3.3.2. Genetic mapping Of P-element Generated mutation in Drosophila

3.3.3. Calculating linkage and map distance

3.3.4. Extra- Chromosomal Inheritance

3.3.5. Male Sterility and Genetic Incompatibility

3.3.6. Discussion about quantitative traits of inheritance

3.3.7. Transposable genetic elements

3.4. Unit 4

3.4.1. Virus

3.4.1.1. Structure of virus

3.4.2. Bacteria

3.4.3. Genes and Behavior

3.4.4. How gene influences the behaviour in different animals

3.4.5. Genetics and evolution

3.4.6. Epigenetics

4. cell biology

4.1. Introduction to the concept of cell

4.2. Tools in cell biology

4.3. cell wall and the cell membrane

4.4. Molecular structure and function of major cell orgenelles

4.4.1. Nucleus

4.4.2. Chloroplast

4.4.3. Mitochondria

4.4.4. Lysosomes

4.4.5. Vacuoles

4.5. Endomembrane System

4.5.1. Endoplasmic Reticulum

4.5.2. Golgi Apparatus

4.5.3. Lysosomes

4.5.4. Peroxisomes

4.5.5. Vacuoles

4.6. Organellar Genome

4.6.1. Mitochondrial genome

4.6.2. Chloroplast genome

4.6.3. manipulations in the genome

4.7. Ribiosomes

4.8. The cytoskeleton

4.8.1. Microtubulers

4.8.2. Microfilaments

4.8.3. Intermediate Filaments

4.8.4. Actin - Myosin cytoskeleton

4.8.5. Cilia and flagella

4.8.6. centrioles

4.8.7. Extracellular Matrix and cell Adhesion

4.9. The cell cycle

4.10. Regulation of the cell cycle

4.10.1. mammalian cells

4.10.2. check points

4.11. Signal Transduction

4.12. Signal transduction Families

4.13. Clinical relevance of signal transduction

5. immunology

5.1. Immune system and its organisation

5.2. Antigen, Immunogen and their sensing

5.3. Major Histocompatibiity complex and antigen presentation

5.4. Costimulation and t-cell Activation

5.5. Humoral Immunity

5.6. Immunodiagnostics

5.7. Antibody Engineering

5.8. Vaccination

5.9. Immunology of disases

6. biostatistics

6.1. Introduction

6.2. Measures of central tendency

6.3. Introduction to probability

6.4. Introduction to Hypothesis testing

6.5. Regression and correlation

6.6. Applicaion of biostatistical tools in genetics, microbial growth kinetics, biological database sample analysis, environmental monitoring.