Contents of this page:
GTP-binding proteins
Initiation of protein
synthesis
Elongation
Termination
Eukaryotic translation
Introduction: Coverage of this topic will be limited. Essential details of protein synthesis are covered in many courses, and are presented well in the textbook. These notes will focus on structural aspects, and on protein factors involved in initiation, elongation, and termination of protein synthesis, many of which are GTP-binding proteins, and other proteins that control GDP/GTP exchange or GTPase activity of these GTP-binding proteins. Bacterial translation mechanisms will be emphasized. The more complex process of mammalian translation and its regulation will be only briefly introduced.
Heterotrimeric G-proteins, and the related family of small GTP-binding proteins, are introduced in the notes on cell signals. A GTP-binding protein has a different conformation depending on whether it has bound to it GTP or GDP. Usually bound GTP stabilizes the active conformation. Hydrolysis of the bound GTP to GDP + Pi converts the protein to the inactive conformation. Reactivation occurs by release of bound GDP in exchange for GTP.
Small GTP-binding proteins require helper proteins to facilitate GDP/GTP exchange or to promote GTP hydrolysis.
A guanine
nucleotide exchange factor (GEF)
induces a conformational change that makes the nucleotide-binding site of a GTP-binding protein more
accessible to the aqueous intracellular milieu, where GTP is usually present
at higher concentration than GDP. Thus a GEF causes a GTP-binding protein to
release GDP and bind GTP (GDP/GTP exchange).
A GTPase activating protein (GAP) causes a GTP-binding protein to hydrolyze its bound GTP to GDP + Pi. The active site for GTP hydrolysis is on the GTP-binding protein, although the GAP may contribute an essential active site residue. |
GEFs and GAPs may be separately regulated. Unique GEFs and GAPs interact with different GTP-binding proteins.
Members of the family of small GTP-binding proteins have diverse functions. In some cases, the difference in conformation associated with substitution of GDP for GTP allows a GTP-binding protein to serve as a "switch". In other cases the conformational change may serve a mechanical role or alter the ability of the protein to bind to membranes. For a list of some small GTP-binding proteins and their roles, see the section on cell signals.
Initiation of protein synthesis in E. coli requires initiation factors IF-1, IF-2, and IF-3. The sequence of events is summarized in the diagram on p. 1323 of Biochemistry, 3rd Edition, by Voet & Voet..
IF-3 binds to the 30S ribosomal subunit, freeing it from its complex with the 50S subunit.
IF-1 assists binding of IF-3 to the 30S ribosomal subunit. Binding of IF-1 also occludes the A site domain of the small ribosomal subunit, helping to insure that the initiation aminoacyl-tRNA, fMet-tRNAfMet, can bind only in the P site and that no other aminoacyl-tRNA can bind in the A site during initiation.
IF-2 is a small GTP-binding protein. IF-2-GTP binds the initiator fMet-tRNAfMet and helps it to dock with the small ribosome subunit.
As the mRNA binds, IF-3 helps to
correctly position the complex such that the tRNAfMet interacts via base
pairing with the mRNA initiation codon (
As the large ribosomal subunit joins the complex, GTP bound to IF-2 is hydrolyzed, leading to dissociation of IF-2-GDP and dissociation of IF-1.The large ribosomal subunit serves as GAP (GTPase activating protein) for IF-2.
Once the two ribosomal subunits come together, the mRNA is threaded through a curved channel that wraps around the "neck" region of the small subunit (see Chime exercise below).
Elongation requires participation of elongation factors EF-Tu (also called EF1A), EF-Ts (EF1B) and EF-G (EF2). Two of these, EF-Tu and EF-G, are small GTP-binding proteins.
Elongation cycle: The diagram below, showing the positions of EF-Tu, EF-G, and tRNAs relative to the ribosome during the elongation cycle, was provided by Dr. Joachim Frank.
Colors: The
large ribosome subunit is cyan, the
small ribosome subunit pale yellow,
EF-Tu red, and
EF-G blue.
tRNAs are gray (free or complexed with EF-Tu), magenta (binding at A site), green (in P site), yellow or brown (in the process of
exiting).
Dr. Frank's laboratory group at the Wadsworth Center, New York State Department
of Health, used cryo-EM and 3D image reconstruction to determine ribosomal
structures and positions of EF-Tu and EF-G. Structures of EF-Tu and EF-G
are based on separate X-ray crystallographic studies.
The sequence of events, as summarized in the diagram above and on p. 1327, is as follows:
EF-Tu-GTP binds and delivers an aminoacyl-tRNA to the A site on the ribosome. EF-Tu recognizes & binds all aminoacyl-tRNAs with approximately the same affinity, when each tRNA is bonded to the correct (cognate) amino acid. tRNAs for the different amino acids have evolved to differ slightly in structure, to compensate for different binding affinities of amino acid side-chains, so that the aminoacyl-tRNAs all have similar affinity for EF-Tu.
The tRNA must have the
correct anticodon to interact with the mRNA
codon positioned at the A site to form a
base pair of appropriate geometry.
Universally conserved bases of 16S rRNA interact with and sense the
configuration of the minor groove of the
short stretch of double helix formed from the first 2 base pairs of
the codon/anticodon complex. A particular
ribosomal conformation is stabilized by this interaction,
providing a mechanism for detecting whether the correct tRNA has bound.
Proofreading in part involves release of the
aminoacyl-tRNA prior to peptide bond formation, if the appropriate ribosomal
conformation is not generated by this interaction. The change in ribosomal conformation associated with formation of a correct codon-anticodon complex leads to altered positions of active site residues in the bound EF-Tu, with activation of EF-Tu GTPase activity. The ribosome thus functions as GAP for EF-Tu. |
When EF-Tu delivers the aminoacyl-tRNA to the ribosome, the
tRNA
initially has a distorted conformation.
As GTP on EF-Tu is hydrolyzed to GDP + Pi , EF-Tu undergoes a large conformational change and dissociates from the complex. The tRNA conformation relaxes, and the acceptor stem is repositioned to promote peptide bond formation. This process is called accommodation. Accommodation includes rotation of the single-stranded 3' end of the acceptor stem of the A-site tRNA around an axis that bisects the peptidyl transferase center of the ribosomal large subunit. This positions the 3' end with its attached amino acid in the active site, near the 3' end of the P-site tRNA, and adjacent to the mouth of the tunnel through which nascent polypeptides exit the ribosome. The diagram at right is from the file to be explored by Chime below. For images depicting the proposed rotational movement, see Fig. 5B in a website maintained by A. E. Yonath. |
EF-Ts functions as GEF to reactivate EF-Tu. Interaction with EF-Ts causes EF-Tu to release its bound GDP. Upon dissociation of EF-Ts, EF-Tu binds GTP, which is present in the cytosol at higher concentration than GDP.
The difference in conformation of EF-Tu, depending on whether GDP or GTP occupies its nucleotide binding site, is apparent from crystal structures to be viewed below. In two of the crystals, GDPNP, a non-hydrolyzable analog of GTP, is present in the nucleotide-binding site of EF-Tu. |
Studio exercise: Students should work in groups of 3, with one of the 3 files assigned to each student in the group. Please use colors and displays exactly as specified in the instructions, so that the images can be compared. Each student should view and compare all 3 structures by observing displays prepared by other members of the group:
Question: Does substitution of GTP (GDPNP) for GDP, or the binding of aa-tRNA, have a greater effect on conformation of EF-Tu?
Transpeptidation (peptide bond formation)
involves nucleophilic attack
of the amino N
of the amino acid that is linked to the 3' hydroxyl of the terminal
adenosine of the tRNA in the
A site
on the carbonyl C
of the amino acid (with attached nascent polypeptide) in ester linkage to
the tRNA in the P site.
The reaction is promoted by the geometry of the active site consisting
solely of residues of the 23S rRNA of
the large ribosomal subunit. No
protein is found at the active site. (Review Chime exercise
on the large ribosomal subunit.) The 23S rRNA may be considered a
"ribozyme." As part of the reaction a proton (H+) is extracted from the attacking amino N. This H+ is then donated to the hydroxyl of the tRNA in the P site as the ester linkage is cleaved.
|
The nascent polypeptide (one amino acid longer) is now linked to the A-site tRNA. However, translocation has already partly occurred, because of the earlier rotation of the single-stranded 3' end of the A-site tRNA toward the P-site, which positioned the aminoacyl moiety for catalysis. The unloaded tRNA in the P site will shift to the E (exit) site during translocation. |
Additionally, it has been postulated that translocation is spontaneous after peptide bond formation because the deacylated tRNA in the P site has a higher affinity for the E site, and the peptidyl-tRNA in the A site has a higher affinity for the P site.
Interaction with the ribosome, which functions as GAP (GTPase activating protein) for EF-G, causes EF-G to hydrolyze its bound GTP to GDP + Pi. EF-G-GDP then dissociates from the ribosome. A domain of EF-G appears to function as its own GEF (guanine nucleotide exchange factor) to regenerate EF-G-GTP.
The continued codon-anticodon base paring of the tRNA in the E site is postulated to have a role in preventing potentially serious frame-shift errors, e.g., such as would occur if the tRNAs were to able to shift laterally by one base pair. Normally the empty tRNA is released from the E site only after binding of the correct aminoacyl-tRNA at the A site causes a decreased affinity for tRNA in the E site.
Explore below the 30S moiety of a bacterial ribosome, complexed with a short genetically engineered mRNA, and with tRNAPhe in each of the A, P, and E (exit) sites. Due to limited resolution, proteins and rRNA display only as backbone. File PDB-1GIX: Structure solved by M. M. Yusupov, G. Z. Yusupova, A. Baucom, K. Lieberman, T. N. Earnest, J. H. D. Cate & H. F. Noller in 2001. Structural information for the co-crystallized 50S subunit is in a separate data file (1GIY).
Recommended display options: Separately select and display each of the following as sticks with color CPK:
Now select chain 1 (one) and display
as ball & stick with color CPK. This is
a small fragment of mRNA. Now select chain d (tRNA in
E-site), display as sticks with
color CPK. Question: Which constituents of the 30S ribosomal subunit predominantly interact with mRNA and tRNAs bound to A & P sites: rRNA or protein? |
Chain termination requires participation of release factors RF-1, RF-2, and RF-3. RF-3 is a small GTP-binding protein. The process is summarized on p. 1335.
RF-1 and RF-2 recognize and bind to STOP codons. One or the other binds when a stop codon is reached.
RF-3-GTP facilitates binding of RF-1 or RF-2 to the ribosome. Once the release factors occupy the A site on the ribosome, the ribosomal Peptidyl Transferase catalyzes transfer of the peptidyl group to water (hydrolysis). Hydrolysis of GTP on RF-3, to GDP + Pi, causes a conformational change that results in dissociation of release factors.
A ribosomal recycling factor (RRF) is required, with EF-G-GTP and IF-3, for release of uncharged tRNA from the P site, and dissociation of the ribosome from mRNA with separation of the two ribosomal subunits.
Websites with animations depicting protein translation:
Animation of protein elongation from the laboratory of J. Frank of the Wadsworth Center, based on Cryo-EM and X-Ray observations of structures of the ribosome, elongation factors, and tRNA.
Animation of the ribosome in translation from the laboratory of V. Ramakrishnan, based on crystal structures of the ribosome and various protein factors.
Translation of mRNA is highly regulated in multi-cellular eukaryotic organisms, whereas in prokaryotes regulation occurs mainly at the level of transcription.
Protein factors that mediate and control translation are more numerous in eukaryotes than in prokaryotes. Eukaryotic factors are designated with the prefix "e".
Initiation of protein synthesis is much more complex in eukaryotes, and requires a large number of protein factors. Some eukaryotic initiation factors (e.g., eIF3 and eIF4G) serve as scaffolds, with multiple domains that bind other proteins during assembly of large initiation complexes. Usually a pre-initiation complex forms, including several initiation factors along with the small ribosomal subunit and the loaded initiator tRNA, Met-tRNAiMet. This then binds to a separate complex that includes mRNA and other initiation factors including ones that interact with the 5' methylguanosine cap and the 3' poly-A tail, structures unique to eukaryotic mRNA. Within this complex mRNA is thought to be circularized via interactions between factors that associate with the 5' cap and with a poly-A binding protein. A simplified diagram of the eukaryotic initiation complex once it has reached the initiation codon is found in the WormBook.
After the initiation complex assembles, it
translocates along the
mRNA in a process called
scanning, until the initiation codon is
reached. Scanning is facilitated by eukaryotic initiation factor
eIF4A, which functions as an
ATP-dependent helicase
to unwind mRNA secondary structure while
releasing bound proteins. A
short sequence of bases adjacent to the
For a summary diagrams, see Voet & Voet p. 1324, and Figure 1 of the article by Hinnebusch (requires a subscription to TIBS).
Some eukaryotic mRNAs have what is called an internal ribosome entry site (IRES), far from the 5' capped end, at which initiation may occur without the scanning process.
Copyright © 1998-2008 by Joyce J. Diwan. All rights reserved.
Additional material on Protein Synthesis: |