100% satisfaction guarantee Immediately available after payment Both online and in PDF No strings attached
logo-home
Summary Chapter 3 Regulation of gene expression $3.23
Add to cart

Summary

Summary Chapter 3 Regulation of gene expression

2 reviews
 23 views  1 purchase
  • Course
  • Institution
  • Book

This is a summary of chapter 3 Regulation of gene expression. With all of my summaries for this course I passed it with an 8!

Preview 2 out of 7  pages

  • No
  • Chapter 3
  • March 26, 2021
  • 7
  • 2019/2020
  • Summary

2  reviews

review-writer-avatar

By: isisboskeljon • 8 months ago

review-writer-avatar

By: kallah2002 • 2 year ago

avatar-seller
Chapter 3 – Regulation of gene expression
Transcription
Transcription: DNA  (m)RNA – takes place in nucleus
Translation: mRNA  protein – takes place on ribosomes in the cytoplasm

Regulatory elements in promotor region
Promotor: site for initiation of transcription on 5’ side it contains:
1. TATA-box; docking site for RNA polymerase II (holo-enzyme)
2. Transcription factor response elements; specific
sequences of DNA recognized by transcription
factors
Transcription factor binds to response element  RNA
polymerase II (holo-enzyme) binds to TATA-box 
transcription starts

Transcription factors
 ± 3000 TF in humans
 TF can bind to DNA
 They recognize specific DNA sequence (response elements)

Co-activators / suppressors are supportive molecules that
interact with the DNA-binding proteins (TF) to promote /
suppress RNA transcription

TF activity regulation:
1. Dimerization: TF never acts by itself but requires another protein to dimerize
with
2. Ligand binding: TF requires ligands to bind with
3. Expression restricted to particular cell types: specific TF give cell their
identities
4. Covalent modifications (phosphorylation): some TF are phosphorylated and
cannot enter the nucleus or if they are not phosphorylated they can enter the
nucleus
5. Cellular localization

TF consists of number of domains with specific functions:
All TF:
 DNA binding domain; enable transcription
factor to bind to DNA
o Zinc finger
o Helix-loop-helix
o Helix-turn-helix
o Leucine zipper
 Transcriptional activation domain (connects TF to transcription machinery (Pol
II)

Some TF: (domains to control activity of TF)
 Dimerization domain: facilitates protein-
protein interactions between the 2 molecules

, 3 TF can give rise to 6 different dimers with different transcriptional activation
properties. 3 homodimers and 3 heterodimers
o Example: AP-1 (activation protein 1); jun and fos genes
18 possible combinations are possible
Jun = pro-proliferative
Jun B = anti-proliferative

 Ligand binding domain: some transcription factors only function upon binding
of a ligand
Example is steroid hormone receptors
o Example: retinoic acid (vitamin A) receptor (RAR); RAR repress
transcription in the absence of RA
RA interact with ligand binding domain
receptor and transcription takes place
o Example:
Glucocorticoid interact with ligand binding
domain. The ligand binding domain is
required for the glucocorticoid to move to
the nucleus and bind to response element
in DNA

All the domains function independently

How to examine (onderzoeken) TF binding?
1. EMSA (electrophoretic mobility shift assay): piece
of radiolabelled DNA is used
a. Put on a gel; band low in the gel
b. Nuclear extract is added to radiolabelled
DNA  allow transcription factors to find a
response element  put on a gel; band high in the gel
because migration is slowed down
2. DNAse fooprinting:
DNAse is used to chop of the DNA. If there is a protein (response
element)present on this DNA it will protect the DNA from being
degraded by DNAse.
This is put on a gel. On the left there are no proteins so a lot of
degradation on the right there are proteins so a lot of protection from
degradation
3. ChIP-seq experiment: allow you to get a genome
wide view of where your protein of interest is bound
to DNA
DNA + bound protein  fragment DNA  perform
immunoprecepitate; antibodies bind to your protein
of interest  release DNA  prepare sequencing
library  sequence  map sequence tags to
genome & identify peaks

How to examine promotors/enhancers?

The benefits of buying summaries with Stuvia:

Guaranteed quality through customer reviews

Guaranteed quality through customer reviews

Stuvia customers have reviewed more than 700,000 summaries. This how you know that you are buying the best documents.

Quick and easy check-out

Quick and easy check-out

You can quickly pay through credit card or Stuvia-credit for the summaries. There is no membership needed.

Focus on what matters

Focus on what matters

Your fellow students write the study notes themselves, which is why the documents are always reliable and up-to-date. This ensures you quickly get to the core!

Frequently asked questions

What do I get when I buy this document?

You get a PDF, available immediately after your purchase. The purchased document is accessible anytime, anywhere and indefinitely through your profile.

Satisfaction guarantee: how does it work?

Our satisfaction guarantee ensures that you always find a study document that suits you well. You fill out a form, and our customer service team takes care of the rest.

Who am I buying these notes from?

Stuvia is a marketplace, so you are not buying this document from us, but from seller biomedicalsciencesvu. Stuvia facilitates payment to the seller.

Will I be stuck with a subscription?

No, you only buy these notes for $3.23. You're not tied to anything after your purchase.

Can Stuvia be trusted?

4.6 stars on Google & Trustpilot (+1000 reviews)

56326 documents were sold in the last 30 days

Founded in 2010, the go-to place to buy study notes for 14 years now

Start selling
$3.23  1x  sold
  • (2)
Add to cart
Added