The Scientific Research Notes Of S. Sunkavally (years: 2002-2011).
4197-4200.
seen from Canada
seen from China
seen from China
seen from China

seen from Germany

seen from United States
seen from United States
seen from Cyprus
seen from Philippines
seen from United States

seen from India

seen from Malaysia

seen from United States

seen from Singapore
seen from United States

seen from United States
seen from Singapore
seen from United States
seen from United States

seen from Russia
The Scientific Research Notes Of S. Sunkavally (years: 2002-2011).
4197-4200.
New Post has been published on https://ramneetkaur.com/regulation-gene-expression/
Regulation of gene expression
(adsbygoogle = window.adsbygoogle || []).push();
Regulation of gene expression
It is the metabolic, physiological or environmental conditions that regulate the expression of genes.
Housekeeping or constitutive genes: genes whose products are continuously required by the cell hence they continuously transcribe and translate.
Non-constitutive genes: genes whose products are not continuously required by the cell & if they continuously transcribe and translate there will be a lot of wastage.
Regulation of expression of such genes is a must.
In eukaryotes:
Genes can be regulated at
Transcriptional level.
During processing i.e., splicing.
Transport of mRNA from the nucleus to the cytoplasm.
Translational level.
In prokaryotes:
Genes are regulated at the transcriptional level.
There are 2 systems of regulations:
An inducible system and a repressible system.
In the inducible system, addition of a substance induces transcription of certain genes. They are associated with catabolic processes. It is always OFF. E.g., lac operon.
In the repressible system, addition of a substance stops transcription of certain genes. They are associated with anabolic processes. It is always ON. E.g., Tryptophan operon.
An operon
An operon consists of different sets of genes which together regulate gene expression.
A Structural gene; that transcribes to form mRNA, which translates to form protein
A promoter gene; to which RNA polymerase binds.
A regulator gene; which synthesizes a protein called repressor that can bind to the operator.
An operator gene; when repressor binds to the operator RNA polymerase cannot bind to the promoter and when repressor does not bind to operator RNA polymerase binds to the promoter.
Each operon has its specific operator and specific repressor.
(adsbygoogle = window.adsbygoogle || []).push();
The lac operon
Given by Francis Jacob and Jacque Monod in E.coli.
lac operon
It is an inducible system and the inducer is lactose/allolactose, the substrate for β-galactosidases. It regulates the switching on and off of the operon.
The structural gene is polycistronic as it has three genes (z, y & a).
z codes for β-galactosidases which catalyze the hydrolysis of lactose (a disaccharide) into glucose and galactose.
y codes for β-galactoside permease, a transport protein that pumps lactose into the cell.
a codes for β-galactoside transacetylase, which transfers an acetyl group to galactose.
Only z & y are required for lactose catabolism.
The regulator gene i.e., ‘i’ codes for the repressor of lac.
The operator gene i.e., ‘o’.
The promoter gene i.e., ‘p’.
When lactose is provided in the growth medium of the bacteria, permease helps to transported it into the cell.
A very low expression of lac operon is present all the time in the cell, otherwise, lactose cannot enter the cell.
Lactose induces the operon in the following manner:
In the absence of lactose (the inducer),
The repressor formed by the regulator gene is an active repressor, it binds to the operator
Due to which RNA polymerase cannot bind to the promoter preventing transcription.
In the presence of lactose (the inducer),
The inducer inactivates the repressor so it cannot bind to the operator.
Hence RNA polymerase binds to the promoter causing transcription.
Regulation of lac operon by repressor is a negative regulation.
(adsbygoogle = window.adsbygoogle || []).push();