Lecture 14 - Phenotypic variation and inheritance

Question 1

what is inheritance?

Answer 1

inheritance or heredity:
> some traits (physical or biochemical characteristics) are heritable - they are passed on from one generation to the next.
>related individuals look more alike than unrelated ones.

Question 2

define heredity

Answer 2

the phenomenon by which offspring resemble their parents

Question 3

define variation

Answer 3

why offspring are not identical

Question 4

what are the principles of heredity?

Answer 4

> inherited characteristics are determined by genes
all individuals of a species have the same base set of genes
variation is due to gene mutation
variants of the same gene - alleles - account for variant traits.

Question 5

what s a genotype?

Answer 5

> genotype is the allelic constitution of an individual (can refer to one, a few, or many loci)

Question 6

what is a phenoype?

Answer 6

the trait value of an individual (under the combined influence of genotype an environment)
> e.g., brown eyes/blue eyes

Question 7

how do you get different alleles of a gene?

Answer 7

changes in genotype arise from mutation of genomic DNA

> mutations are changes in the DNA sequence

Question 8

what are the different types of mutations?

Answer 8

> point mutations - single nt changes
insertions or deletions
translocations, deletions or duplications - large scale chromosomal changes.
- silent, mis-sense and non-sense
mutations can be in the coding region or the non-coding region of DNA.
mutations can occur in somatic cells or germ cells.

Question 9

what type of mutation can cause leukaemia?

Answer 9

a reciprocal translocation
> the ABL oncogene from chromosome 9 is replaced with a segment from chromosome 22.
>chromosome 22 now has the ABL gene and is now called BCR-ABL.
>this is called the Philadelphia chromosome.
>causes an over proliferation of cells, thus leukaemia

Question 10

what are the causes of mutations?

Answer 10

> spontaneous mutations result from internal cellular processes
- mis-incorporation of nucleotides during DNA replication
- these are mainly due to very rare errors during DNA replication (and the molecular DNA repair machinery in the cell takes care of most of them)
- in humans mutation rate is ~ 1 in every 2x10^8 base, or about 100-200 mutations accumulating from one generation to the next.
- errors during meiosis causing chromosomal abnormalities (wrong pairing up of homologous chromosomes)
induced mutations result from external mutagens
- e.g., UV light, mutagens such as chemicals (represses repair)

Question 11

what are the outcomes of mutations?

Answer 11

> loss of function mutations
- interfere with the ability of a gene to code for a fully functioning protein
- or can be regulatory mutations affecting gene’s promoter
- mis-sense - changes amino acids
- non-sense - produces a stop codon
silent mutations
- have no affect on protein function
gain of function
- these are usually dominant and result in a protein with altered functionality.

Question 12

what is an example of a genetic disease caused by a mutation in a single amino acid?

Answer 12

sickle cell disease:
> in the gene sequence for hemoglobin, an A is swapped for a T, causing the sequence to change from thr pro glu glu to thr pro VAL glu
> this single nt change leads to sickle cell anemia

Question 13

what is the difference between smatic and germ line mutations?

Answer 13

> somatic mutations occur in the soma, the cells of the boy not involved in producing sex cells
germ line mutations happen in the germ cells, and are therefore inherited.
most mutations occur in the soma

Question 14

what is an example of a mutation in the somatic cells?

Answer 14

cancer

> cancer is the outcome of mis-regulation of the cell cycle caused by genetic mutations

Question 15

what is an example of a cancer that occurs in the germ line and is therefore heritable?

Answer 15

some forms of breast cancer and ovarian cancer. E.g., BRC1 and BRC 2 genes.

Question 16

what are some other sources of variation aside from mutations?

Answer 16

> reproduction

> bacteria have other strategies

Question 17

what causes genetic variation in bacteria?

Answer 17

> they are highly genetically variable
mutations and rapid reproduction (which propagates new mutations clonally)
horizontal DNA transfer and genetic recombination

Question 18

describe the rapid reproduction and mutations in baceria

Answer 18

> spontaneous mutation occurs in E.coli gene 1 x 10^7 per cell division
but 2 x10^10 new cells each day in a persons intestine.
therefore 2000 bacteria with mutations in a given gene each day
note that the 2000 bacteria may carry mutations in the same gene, but they are not the same mutation.
4300 E.coli genes, therefore up to 4300 x 2000 = 9 million E.coli variants per human host per day.

Question 19

what are the mechanisms for horizontal gene tranfer in bacteria?

Answer 19

CONJUNCTION
> transfer by direct cell to cell contact via a pilus and a conjugative plasmid
TRANSFORMATION
> uptake and incorporation of naked DNA
TRANSDUCTION
> transfer of chromosomal or plasmid DNA from cell to cell by a bacterial virus (bacteriophage)

Question 20

how does conjunction occur?

Answer 20

> sex pili allow bacteria to exchange DNA via conjunction (the closest a bacterium can get to sexual reproduction)
Plasmid mediated DNA transfer
conjugative plasmids are capable of initiating plasmid transfer from cell to cell by direct contact - conjugation (no ‘chromosomal’ DNA gets exchanged)
plasmids that promote conjugation may be referred to as fertility factors (or F - plasmids), they initiate the pilus formation and the transfer of its own copy into the recipient cell.
CHARACTERISITICS:
F plasmids are large (often > 25kbp)
broad host range (horizontal gene transfer between species)
often contain multiple antibiotic resistance genes
learn diagram from Grace

Question 21

describe transformation

Answer 21

> transformation with naked DNA
some bacteria take up DNA from the environment and integrate it into their chromosome.
e.g., Streptococcus pneumoniae
limited DNA of same (or closely related) species
relies on “recombination” with “homologus” DNA sequence in the genome also used today to transform plasmid DNA into bacteria.

Question 22

who discovered transformation?

Answer 22

griffith in the 1920s

Question 23

describe transduction

Answer 23

> learn heather’s diagram, but pretty much mediated via bacteriophages

Question 24

decribe transposon-mediated DNA transfer

Answer 24

> mechanism of DNA transfer within the cell.
transposons are lengths of DNA that can ‘jump’ from one site to another
contain genes that promote integration and ‘excision’
- can integrate into the DNA - genomic or plasmid
- can cut themselves out of the DNA - excise
- can reintegrate somewhere else

Question 25

what is the relationship between transpoons and antibiotic resistance?

Answer 25

> many transposons contain genes that encode for resistance to antibiotics
when a transposon is carried on a conjugative plasmid these resistance genes can spread rapdily throughout bacterial populations
common in hospitals (antibiotic rich environments)
eukaryotes and prokaryotes
mobile genetic elements

Question 26

how do transposons mediated antibiotic resistance?

Answer 26

transposition genes can insert themselves around the gene for antibiotic resistance, then when they excise again, they carry the sandwiched antibiotic-resistance gene along with them.