Course Content
Introduction and scope of genetics
0/4
Introduction
Application of genetics
Branches of genetics
Scope of genetics
History of genetics
0/1
History of genetics
Cell division (mitosis, meiosis, and cell cycle)
0/3
Cell cycle
Significance of mitosis and meiosis
Classification of chromosome
Life cycles (virus, bacteria, Neurospora, Aspergillus, maize, and man)
0/13
Some terminologies
Lifecycle of Human
Lifecycle of Maize
Lifecycle of virus
Lifecycle of virus
Viral reproduction in host cells
Viral reproduction in host cells
Lifecycle of Bacteria
Asexual Reproduction in Bacteria
Sexual Reproduction in Bacteria
Lifecycle of Neurospora
Lifecycle of Aspergillus
Reproduction in Aspergillus
Mendel’s laws of segregation and independent assortment
0/5
Reason for selection of pea plant
Important terms
Law of segregation
Law of dominance :
Law of independent assortment
Probability and statistical testing
0/3
Introduction
Binomial expansion
Probability of a combination of two independent events
Gene action and interaction
0/6
Introduction
Inter allelic or intra genic interaction
Non allelic or intergenic gene interaction
Pleiotropic effects of gene
Penetrance
Expressivity
Sex determination and sex linkage
0/8
Sex determination
Mechanism of sex determination in Animals
Sex expression in drosophila
Single gene affecting sex determination
Mechanism of sex determination in plants
Sex linkage
Characteristics of sex-linked inheritance
Non-disjunction
Linkage and crossing over
0/5
Linkage
Crossing over
Types of crossing over
Interference
Recombination
Extra-nuclear inheritance – genes in organelles, maternal effect, criteria for extra-nuclear inheritance
0/4
Introduction
Characteristics of Extranuclear inheritance
Criteria for extrachromosomal inheritance
Maternal effects
Nucleic acids
0/7
Deoxyribose nucleic Acid (DNA)
Ribonucleic acid (RNA)
Types of RNA
DNA replication
Transcription
Translation
Genetic code
Mutation – genic, chromosomal and molecular levels
0/4
Introduction
Types of mutation
Some mutagens and their effects
Polyploidy
Chromosomal aberrations, euploidy, and aneuploidy
0/7
Introduction
Structural change
Aneuploidy
Euploid
Application of haploid
Autopolyploids
Allopolyploids
Transposable genetic elements
0/3
Introduction
Characteristics of transposable genetic elements
Significance of transposons
Gene regulation
0/4
Introduction
Gene regulation in Prokaryotes
Terminologies
Lac operon in E.coli
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Characteristics of Extranuclear inheritance

  1. Reciprocal Differences:
  • Characters which are governed by cytoplasmic inheritance invariably exhibit marked differences in reciprocal crosses in F1, whereas in case of nuclear inheritance such differences are not observed except in case of sex-linked genes.

 

 

  1. Maternal Effects
  • In case of cytoplasmic inheritance, distinct maternal effects are observed. This is mainly due to more contribution of cytoplasm to the zygote by female parent than male parent. Generally, ovum contributes more cytoplasm to the zygote than sperm.

 

  1. Mappability:
  • Nuclear genes can be easily mapped on chromosomes, but it is very difficult to map cytoplasmic genes or prepare linkage map for such genes. Now chloroplast genes in Chlamydomonas and maize, and mitochondrial genes in human and yeast have been mapped.

 

  1. Non-Mendelian Segregation:
  • The mendelian inheritance exhibits typical segregation pattern. Such typical segregation is not observed in case of cytoplasmic inheritance. The segregation when occurs, is different from mendelian segregation.

 

  1. Somatic Segregation:
  • Characters which are governed by cytoplasmic genes usually exhibit segregation in somatic tissues such as leaf variegation. Such segregation is very rare for nuclear genes.

 

  1. Infection-Like Transmission:
  • Cytoplasmic traits in some organisms exhibit infections like transmission. They are associated with parasites, symbionts or viruses present in the cytoplasm. Such cases do not come under true cytoplasmic inheritance.

 

 

  1. Governed by Plasma Genes:
  • The true cases of cytoplasmic inheritance are governed by chloroplast or mitochondrial DNA. In other words, plasma genes are made of cp-DNA or mt-DNA.
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