Epigenetics

Question 1

What is epigenetics

Answer 1

• term coined by Waddington in 1942
• epi=above (above genetics)
• refers to changes in gene expression driven by alterations of chromatic structure or DNA structure
• not differences in DNA sequences

Question 2

Molecular processes leading to epigenetic changes

Answer 2

1. Changes in patterns of DNA methylation
2. Chemical modifications of histone proteins
3. RNA molecules that affect chromatin structure and gene expression

• common attributes
  
  • alters expression of genes
  • stably transmitted through mitosis, sometimes through meiosis
  • mostly related to changes in chromatin structure

Question 3

DNA methylation

Answer 3

• most common form is the conversion of cytosine to 5-methylcytosine
• typically targets CG positions
  
  • referred to as CpG dinucleotides
• the C on opposite strands are both methylated, leading to diagonal methylation pairs
• in plants, methylation also occurs at CpNpG trinucleotides
• genome regions rich in CpG pairs are known as CpG islands
  
  • often in or near gene promoter regions
• CpG islands not methylated when genes are actively transcribed
  
  • methylation of CpG islands near a gene —> repression of transcription

Question 4

Maintenance of methylation through cycles of DNA replication

Answer 4

• methyltransferases turn C into 5-methylcytosine
• demethylases remove methyl groups
• DNA replication of fully methylated DNA leads to hemimethylated DNA
  
  • only one strand is methylated
  • then the methyl groups on one strand attract methytransferases, causing non-methylated daughter strand to be methylated
  • results in fully methylated DNA

Question 5

DNA methylation and bees

Answer 5

• determines the difference between a queen bee and a worker bee
• bee larvae destined to be queens are fed royal jelly
  
  • royal jelly silences Dnmt3, which is involved in methylation
  • future Queen bees have less methylated DNA —> more active genes
  • functional ovaries develop

-in worker bees, the Dnmt3 gene is active and genes are methylated

Question 6

Repression of transcription by DNA methylation

Answer 6

• methyl groups sit in major grooves of DNA
• inhibits binding of transcription factors and other proteins needed for tanscription
• also attracts proteins that directly repress transcription
• attracts histon deactylase enzymes that remove acetyl groups from tails of histone proteins, altering chromatin structure and further repressing transcription

Question 7

Histone modifications

Answer 7

• in eukaryotic cells DNA is complexed to histone proteins to form nucleosomes, basic repeating units of chromatin
• many chemical modifications of histones, often positively charged tails
• histone acetylation destabilizes chromatin, making it more open
  
  • increased transcription
• histone methylation decrease or increase transcription
• mechanisms for maintenance of histone modification across cell division not as well understood as DNA methylation

Question 8

Epigenetics effects of RNA molecules

Answer 8

• X chromosome inactivation is best understood example
• involves long non-coding RNA called Xist
• siRNA that silence genes implicated in other examples
• also microRNAs
• how RNA-mediated epigenetic effects are maintained across cell generations not well understood
  
  • small RNAs may be transmitted in cytoplasm

Question 9

X inactivation

Answer 9

• in all female mammals, 1 copy of X chromosome is inactivated in all cells
• inactivation occurs early in development, then inactive H remains so for all remaining cells divisions (=an epigenetic change)
• leads to a patchy distribution of active maternally and paternally derived X chromosomes
• RNA coded by Xist gene on X chromosome coats one X but not the other, leading to inactivation
• Xist RNA recruits PRC2 which produces histone modification

Question 10

Paramutation in Corn

Answer 10

• B1 locus influences pigmentation
• B1B1 homozygote = high expression = purple
• B’B’ homozygote = low expression = light pigment
• B1B’ heterozygote = light pigment…..
• B1 and B’ allele sequences are IDENTICAL
• B’ converts B1 allele to B’* allele
• paramutation of B1 locus requires presence of 7 tandem repeats 100kb upstream
• both alleles have the repeats, but different chromatin structures
• open chromatin stimulates expression of B1
• closed chromatin represses expression of B1
• siRNAs produced from tandem repeats converts B1 —> B’*

Question 11

Normal roles of epigenetic imprinting

Answer 11

• differentiation of cells during development, from pluripotent stem cells, to particular tissue types, involves epigenetic silencing
• genomic imprinting
  
  • some genes are expressed differently depending on whether the allele comes from the mother or the father

Question 12

DNA methylation and Cancer

Answer 12

• altered DNA methylation patterns though to play important roles in cancer
• CpG islands in percentromeric heterochromatin are normally hypermethylated
  
  • in tumour cells they become hypomethylated, leading to genomic instability, more recombination, and aneuploidy
• growth regulatory genes (tumour suppression genes) are normally hypomethylated
  
  • in cancers they become hypermethylated
  • this causes transcription to be silenced

Question 13

Methylation and aging

Answer 13

• studies have shown that genome-wide methylation increases as humans age
• strong correlation between chronological age and methylation age predicted by a model
• some individuals age relatively fast, some slow, in terms of methylation accumulation
• males accumulate methylation faster than females

Question 14

Monozygotic twins

Answer 14

• not completely identical because of epigenetics
• patterns of histone acetylation and methylation diverge over time
• likely in response to different life experiences

Question 15

Dutch Hunger Winter and epigenetic hardships

Answer 15

• sever famine in Netherlands in winter of 1945
  
  • 20,000 people died of starvation
• children of women who were pregnant at the time suffered life long health effects
  
  • heavier, higher triglycerides, LDL cholesterol, obesity, diabetes etc
  • 10% higher mortality rate by 68 years
• study of methylation patterns in 2000s found difference linked to famine and health conditions later in life
• of 15loci linked to growth and metabolic disease, showed difference in methylation patterns compared to control groups born before and after famine
• May reflect an adaption to hardship

Question 16

Epigenetic effects from 1998 ice storm

Answer 16

• ice storm affected Ontario, Quebec, New England
• study recruited women pregnant at the time and assessed degree of hardship they experienced
• 13 years later found a distinctive methylation signature in T cells in kids of the pregnant women
  
  • long term health consequences not known yet

Question 17

Detecting DNA methylation

Answer 17

• REs can be used to detect methylation
• some REs sensitive to methylation (ie. will not cut if DNA is methylated)
• isoschizomers (REs that are NOT sensitive to methylation) recognize the same sequence and will cut whether or not it is methylated
• can compare cut patterns from methylation sensitive and non-sensitive REs
• use is limited to examining methylation in RE cut sites

Question 18

Detecting DNA methylation 2

Answer 18

• bisulfite sequencing is more powerful than REs
• relies on conversion of unmethylated cytosines to uracil, which is read during DNA sequencing as thymine
• compare output of DNA sequencing from both

-treatment with sodium bisulfite converts C to U