Protein biosynthesis

From Wikipedia, the free encyclopedia

Protein biosynthesis (Synthesis) is the process in which cells build proteins. The term is sometimes used to refer only to protein translation but more often it refers to a multi-step process, beginning with amino acid synthesis and transcription which are then used for translation. Protein biosynthesis, although very similar, differs between prokaryotes and eukaryotes.

1 Amino acid synthesis
2 Transcription
3 Events following Protein Biosynthesis (Protein Synthesis)
4 See also
5 External links

[edit] Amino acid synthesis

Main article: Amino acid synthesis

Amino acids are the monomers which are polymerized to produce proteins. Amino acid synthesis is the set of biochemical processes (metabolic pathways) which build the amino acids from carbon sources like glucose. Not all amino acids may be synthesised by every organism, for example adult humans have to obtain 8 of the 20 amino acids from their diet.

The amino acids are then loaded onto tRNA molecules for use in the process of translation.

[edit] Transcription

Main article: Transcription (genetics)

Transcription is the process by which an mRNA template, carrying the sequence of the protein, is produced for the translation step from the genome. Transcription makes the template from one strand of the DNA double helix, called the template strand. Transcription takes place in 3 stages.

Transcription starts with the process of initiation. RNA polymerase, the enzyme which produces RNA from a DNA template, binds to a specific region on DNA that designates the starting point of transcription. This binding region is called the promoter. As the RNA polymerase binds on to the promoter, the DNA strands are beginning to unwind.
The second process is elongation. RNA polymerase travels along the template (noncoding) strand, synthesizing a ribonucleotide polymer. RNA polymerase does not use the coding strand as a template because a copy of any strand produces a base sequence complementary to the strand which is being copied. Therefore DNA from the noncoding strand is used as a template to copy the coding strand.
The third stage is termination. As the polymerase reaches the termination stage, modifications are required for the newly transcribed mRNA to be able to travel to the other parts of the cell, including cytoplasm and endoplasmic reticulum for translation. A 5' cap is added to the mRNA to protect it from degradation. In eukaryotes, poly-A-polymerase adds a poly-A tail onto the 3’ end for stabilization, protection from cytoplasmic hydrolytic enzymes and as a template for further process. Also in eukaryotes (higher organisms) the vital process of splicing occurs at this stage by the spliceosome enzyme. It removes the introns (non-coding bits of genetic material) and glues together the exons (the segments that code for a specific protein).
The mRNA now exits the nuclear pore to be translated.

[edit] Events following Protein Biosynthesis (Protein Synthesis)

The events following biosynthesis include post-translational modification and protein folding. During and after synthesis, polypeptide chains often fold to assume, so called, native secondary and tertiary structures. This is known as protein folding.

Many proteins undergo post-translational modification. This may include the formation of disulfide bridges or attachment of any of a number of biochemical functional groups, such as acetate, phosphate, various lipids and carbohydrates. Enzymes may also remove one or more amino acids from the leading (amino) end of the polypeptide chain, leaving a protein consisting of two polypeptide chains connected by disulfide bonds.

[edit] See also

[edit] External links

Science aid:Protein synthesis For high school
Flash animation at McGraw-Hill genetics-Protein%20Synthesis
Protein Synthesis
Transcription

Translation
Protein Synthesis Animation Wesleyan University Learning Objects animation of protein synthesis.
Interactive Java simulation of transcription initiation. From Center for Models of Life at the Niels Bohr Institute.

Protein primary structure and posttranslational modifications
General:	Protein biosynthesis \| Peptide bond \| Proteolysis \| Racemization \| N-O acyl shift
N-terminus:	Acetylation \| Formylation \| Myristoylation \| Pyroglutamate \| methylation \| glycation \| myristoylation (Gly) \| carbamylation
C-terminus:	Amidation \| Glycosyl phosphatidylinositol (GPI) \| O-methylation \| glypiation \| ubiquitination \| sumoylation
Lysine:	Methylation \| Acetylation \| Acylation \| Hydroxylation \| Ubiquitination \| SUMOylation \| Desmosine \| deamination and oxidation to aldehyde\| O-glycosylation \| imine formation \| glycation \| carbamylation
Cysteine:	Disulfide bond \| Prenylation \| Palmitoylation
Serine/Threonine:	Phosphorylation \| Glycosylation
Tyrosine:	Phosphorylation \| Sulfation \| porphyrin ring linkage \| flavin linkage \| GFP prosthetic group (Thr-Tyr-Gly sequence) formation \| Lysine tyrosine quinone (LTQ) formation \| Topaquinone (TPQ) formation
Asparagine:	Deamidation \| Glycosylation
Aspartate:	Succinimide formation
Glutamine:	Transglutamination
Glutamate:	Carboxylation \| polyglutamylation \| polyglycylation
Arginine:	Citrullination \| Methylation
Proline:	Hydroxylation
←Amino acids		Secondary structure→