central dogma- protein synthesis Flashcards
4 ways to regulate protein synthesis
- amount of transcription that occurs
- stability of mRNA transcript
- location of protein
- destruction of protein
what complexes help with transcription regulation and what do they do? what histone modifications can be done for transcription regulation?
histones: regulated by host of nuclear proteins
-chromatin remodelling complexes: reposition nucleosomes on DNA to either expose or obscure gene regulatory elements (i.e. promoters)
-chromatin writer complexes: carry out histone modification (i.e methylation, acetylation, phosphorylation)
histone modifications:
-histone acetylation: open chromatin and increase transcription via histone acetyltransferases
–> deacetylation reverse these changes and promotes chromatin condensation
–> methylate histones and DNA
-histone methylation: transcriptional activation or repression (depends on the histone residue)
-DNA methylation: transcriptional silencing
mRNA stability (regulate protein synthesis)
-the longer mRNA lasts in cytosol= more protein made via translation
-non-coding RNA (i.e. miRNA or siRNA) could promote destruction of mRNA transcript
-specific proteins can bind mRNA and prevent degradation= more protein synthesis
–> i.e. transferrin: protein receptor that brings iron into the cell (no transferrin receptor made in high iron, receptor made in low iron to bring iron into cell)
targeting of cellular location (protein synthesis regulation)
-cells limit protein to particular location
-proteins needed for intracellular cytosolic use are translated on free ribosomes in the cytosol
-if destined for nucleus mitochondria or peroxisomes:
–> once translated in cytosol, specific amino acid signal in the polypeptide will target the protein for its intracellular location
-proteins destined fro lysosomes, ER, cell membrane or section need to be directed to the rough ER for translation in a process called co-translational transfer
a) translation begins of a free ribosome in the cytosol
b) signal peptide sequence is translated, which binds a single recognition particle (SRP)
-binding of SRP strops translation and directs the ribosome to the rough ER when it binds to a SRP receptor
-translation re-starts with the growing polypeptide moving through a channel into the lumen of the rough ER
-once in the rough ER, the signal peptide sequence is removed
-if a protein needs to be inserted into a cell membrane, it will contain a stop transfer sequence
-when the stop transfer sequence comes into contact with the translocator, translation is paused
-translocator will discharge the polypeptide into the phospholipid bilayer of the ER membrane
-translation resumes until polypeptide is complete
what are the types of histone modification and what complex are they done by?
done by chromatin writer complexes
-histone acetylation
-histone methylation
-DNA methylation
when is co-translational transfer needed? and when is it not needed?
for proteins destine for the lysosomes, ER, cell membrane
not needed for proteins destined to nucleus, mitochondria, or peroxisomes
what particle is used in co-translational transfer to get a protein into the rough ER
signal recognition particle
what sequence is necessary if a protein needs to be inserted into a cell membrane?
stop transfer sequence
