Difference between revisions of "Organization of genetics topics"
From Genetics Wiki
(One intermediate revision by the same user not shown) | |||
Line 15: | Line 15: | ||
**LOD scores | **LOD scores | ||
*cytological genetics | *cytological genetics | ||
− | **chromosomes, mitosis and meiosis | + | **chromosomes, mitosis and meiosis |
**sex chromosomes and sex determination systems | **sex chromosomes and sex determination systems | ||
− | **aneuploidy and polyploidy | + | **nondisjunction, aneuploidy and polyploidy |
**distinction between the germ-line and the soma | **distinction between the germ-line and the soma | ||
*molecular genetics | *molecular genetics | ||
Line 60: | Line 60: | ||
**personal genomics | **personal genomics | ||
**developmental genetics | **developmental genetics | ||
+ | **conservation genetics | ||
**genetic anthropology | **genetic anthropology |
Latest revision as of 12:54, 22 August 2014
I am interested in what people thin the best organization of genetics topics might be.
Genetics is a vast, rapidly changing field. There are connections to other diverse fields such as psychology, law, medicine, history, and teaching. A classic way to divide genetics topics is into classical, molecular, and population genetics; however, I suspect this leaves out important areas.
The topics I would like an introductory genetics class to cover (or at least touch on in an introductory sense) include:
- classical genetics
- Mendelian Inheritance and Punnet squares
- Complementation tests
- Genetic linkage and recombination
- Punnet squares and epistasis
- alleles and morphs
- penetrance and expressivity
- pedigree analysis
- LOD scores
- cytological genetics
- chromosomes, mitosis and meiosis
- sex chromosomes and sex determination systems
- nondisjunction, aneuploidy and polyploidy
- distinction between the germ-line and the soma
- molecular genetics
- gene structure, gene expression regulation, protein structure, and the central dogma
- genome structure and organization
- types of mutations and their effects
- metabolic pathways, developmental pathways, and epistasis
- transposable elements and other forms of selfish genes
- genotype/phenotype association tests
- comparison of model organisms and viral versus bacterial versus eukaryotic genetics
- methods of genetic engineering and germ line transformation
- genetic tools such as binary expression systems, PCR, Sanger sequencing, next generation sequencing, restriction endonucleases, and plasmid engineering, FISH, probes, chip hybridization
- forward genetics and reverse genetics
- X-inactivation, imprinting and epigenetics
- population genetics
- inbreeding and population structure
- average heterozygosity and effective population size, the coalescent
- selection and genetic drift
- tests of neutrality
- quantitative genetics
- parent-offspring regression
- heritability and phenotype variance
- breeder's equation
- twin studies
- evolutionary genetics
- species phylogeny
- gene evolution and gene families
- evo-devo
- supporting statistical logic
- probability rules
- binomial distributions
- normal distribution
- Poisson distribution
- the chi-square test and degrees of freedom
- linear regression
- means and variance
- interdisciplinary
- the history of eugenics and current laws regarding genetic data
- GMO crops including examples, methods, ethics, and economics
- genetic pest management
- medical and cancer genetics
- personal genomics
- developmental genetics
- conservation genetics
- genetic anthropology