Genetics Final

nucleosomes

"pearls on a string" histones with DNA wrapped around them folds up and forms chromatin which is important for dna storage

polycistronic mRNA

1 mRNA for multiple proteins

mendels postulates

1. unit factors exist in pairs 2. dominant vs recessive 3. segregation occurs independently during gamete formation

human chromosome number

23 pairs

dna polarity

5' to 3' because of carbon bonding on the base

transcription

DNA ---> RNA rna polymerase process: opens up dna (histone acetylation) and unwinds dna (gyrase) activation of promoter to bind polymerase via transcription factors processing (splicing, 5' cap, poly A tail to 3' end) leaves nucleus

dihybrid cross

F2 genotype: ----- F2 phenotype: 9:3:3:1 traits from two different genes

monohybrid cross

F2 genotype: 1:2:1 F2 phenotype: 3:1 traits from one gene

bases of RNA

G-C A-U

bases of DNA

G-C: strongest bond (3H) A-T: 2H

translation

RNA-----> proteins ribosomes in the cytoplasm (rRNA)

PCR

amplification of a specific gene region uses TAQ polymerase (copies 5' to 3' forward direction) temp changes and primers instead of cellular machinery

dna strands

antiparallel, complementary

phosphodiester bonds

backbones of DNA

hydrogen bonds

bonds between opposing DNA strands

codominance

both alleles are expressed eg: AB blood type

incomplete dominance

both alleles are partially expressed and form an intermediary phenotype eg: red and white flowers=pink flowers

lethal alleles

cause death dihybrid: 2:1 eg: huntingtons (progressive lethality) or agouti (early development/fetal lethality)

frame shift mutation

caused by a mutation that changes A of AUG

multiple alleles

different forms of a gene are expressed in a population

euchromatin vs heterochromatin

euchromatin: gene expression, can become heterochromatin through methylation heterochromatin: regulatory, no transcription

recombination

exchange of genetic material between homologous chromosomes exchanged at points called chiasmata genes that are close together are less likely to go through recombination

genotype

genetic profile of an organism

dna methylation

increases compactness

histone acetylation

increases relaxedness by making histones less positively charged

nondisjunction

is when chromosomes fail to separate properly eg down syndrome

sex linkage

linkage due to being on the X chromosome eg: eye color in flies

chromatin

more condensed during cell division and is more relaxed during G phase most relaxed during gene expression

chromosomes

not uniform because of centromeres, telomeres, genes, and regulatory sequences ( lines, sines, transposons) gene areas are less dense compared to highly repetitive areas majority non coding dna

phenotype

observed traits of an organism

dna replication

occurs in the S phase makes 1 copy semiconservative enzymes: helicase: opens helix gyrase: relaxes tension polymerase III: copies dna and proofreads polymerase I: fills gaps after primer removal rna primers: binds polymerase made by primase attaches to leading and lagging strands 5' to 3' direction to proofread (cant go 3' to 5' because there is no phosphate energy source) exonuclease: removes primers dna ligase: attaches ends together via phosphodiester bonds origin: place where dna replication starts humans have many plasmids have one (circular dna)

epistasis

one gene masks a different gene can be dominant or recessive, agonistic or antagonistic eg: H factor blood type

histones

parts of nucleosomes that are the disc-shaped octamer protein complex

parts of dna

phosphate group, nitrogenous base, deoxyribose sugar

gene linkage

probability of genes on the same chromosome being inherited together far apart: not likely (increased independent assortment) close together: likely to be inherited together

primers

small pieces of dna that work by complementing the template strand and allowing polymerase to bind for dna synthesis

start and stop codons

start: AUG stop: UGA UAG UAA

meisosis

steps: P: crossing over, breakdown of nuclear envelope M: chromosome alignment A: chromosome/allele separation T: chromosome recondensation 2 haploid cells P: new spindle formation M: chromosome alignment A: sister chromatid separation T: chromosome recondensation 4 non identical haploid cells 2n ----> 4n 4 copies of chromatids reduces genetic material by half

genes

the basic units of heredity

gene expression

turning on transcription or translation regulation: transcription factors: activators, repressors regulatory sequences: enhancers, silencers activators bind enhancers repressors behind silencers operons: one promoter controlling multiple genes eukaryotes do NOT have operons operators are regulatory sequences

heterozygous

two different alleles

homozygous

two of the same alleles