All GRE Subject Test: Biochemistry, Cell, and Molecular Biology Resources
Example Questions
Example Question #2 : Translation And Proteins
Chloramphenicol prevents protein translation by which of the following mechanisms?
It blocks the translocation reaction on ribosomes
It blocks the binding of aminoacyl tRNA to the A site of the ribosome
It blocks initiation of RNA chains by binding to RNA polymerase
It blocks the peptidyl transferase reaction on ribosomes
It blocks the peptidyl transferase reaction on ribosomes
Tetracycline blocks the binding of aminoacyl tRNA to the A site of the ribosome.
Cyclohexamide blocks the translocation reaction on ribosomes.
Rifamycin blocks the initiation of RNA chains by binding to RNA polymerase.
Chloramphenicol blocks the pepidyl transferase reaction on the ribosome.
Example Question #461 : Gre Subject Test: Biochemistry, Cell, And Molecular Biology
During translation, which site in the ribosome allows for tRNA moelcules to enter the complex?
P site
R site
E site
A site
A site
The ribosomal complex has three sites where tRNA moelcules can be oriented during the process of translation: the A site, the P site, and the E site. During polypeptide elongation, a tRNA with an attached amino acid will enter at the A site. It will then move to the P site, now holding the growing polypeptide chain. All tRNAs no longer holding an amino acid will exit the ribosome at the E site.
Example Question #4 : Translation And Proteins
On which of the following molecules could you find an anticodon?
tRNA
rRNA
mRNA
miRNA
tRNA
In order to make sure that the proper amino acid is added to the growing polypeptide chain, an anticodon found on the tRNA carrying the amino acid must be a match for the codon found on the mRNA.
Example Question #3 : Translation And Proteins
Which of the following most accurately describes the chronological order of ribosome biogenesis in eukaryotes?
Ribosomal proteins are translated in the nucleous and transported to the cytoplasm. At the same time, rRNA genes are being rapidly transcribed in the nucleolus. rRNA and ribosomal proteins form the 60S and 40S subunits in the cytoplasm, where they join to form a functional ribosome.
Ribosomal proteins are translated in the cytoplasm and transported to the nucleolus. At the same time, rRNA genes are being rapidly transcribed in the nucleolus. rRNA and ribosomal proteins form the 60S and 40S subunits in the nucleolus and are then transported to the cytoplasm for functional ribosome assembly.
Ribosomal proteins are translated in the cytoplasm and transported to the nucleolus. At the same time, rRNA genes are being rapidly transcribed in the cytoplasm. rRNA and ribosomal proteins form the 60S and 40S subunits in the cytoplasm.
Ribosomal proteins are translated in the cytoplasm and transported to the nucleolus. At the same time, rRNA genes are being rapidly transcribed in the nucleolus. rRNA and ribosomal proteins form the 50S and 30S subunits in the nucleolus and are then transported to the cytoplasm for functional ribosome assembly.
Ribosomal proteins are translated in the cytoplasm. At the same time, rRNA genes are being rapidly transcribed in the nucleolus. rRNA is transported to the cytoplasm where the rRNA and ribosomal proteins form the 60S and 40S ribosomal subunits.
Ribosomal proteins are translated in the cytoplasm and transported to the nucleolus. At the same time, rRNA genes are being rapidly transcribed in the nucleolus. rRNA and ribosomal proteins form the 60S and 40S subunits in the nucleolus and are then transported to the cytoplasm for functional ribosome assembly.
Ribosomal proteins are translated in the cytoplasm and rRNA genes are transcribed in the nucleolus. Following protein translation, these proteins enter the nucleus through nuclear pores and localize to the nucleolus. Here, transcribed rRNA associates with the ribosomal proteins to form the 60S and 40S eukaryotic ribosomal subunits. Prokaryotes have 50S and 30S subunits. The ribosomal subunits then translocate to the cytoplasm where they join together to form fully functional ribosomes.
Example Question #462 : Gre Subject Test: Biochemistry, Cell, And Molecular Biology
How many ribosomal binding sites are there and what are their functions?
There are three sites. A site binds free tRNA before ribosomal exit, P site binds aminoacyl-tRNA, E site binds peptidyl-tRNA
There are two sites. A site binds free tRNA before ribosomal exit, P site binds peptidyl-tRNA
There are two sites. A site binds free tRNA before ribosomal exit, P site binds aminoacyl-tRNA
There are three sites. A site binds aminoacyl-tRNA, P site binds peptidyl-tRNA, E site binds free tRNA before ribosomal exit
There are three sites. A site binds peptidyl-tRNA, P site binds aminoacyl-tRNA, E site binds free tRNA before ribosomal exit
There are three sites. A site binds aminoacyl-tRNA, P site binds peptidyl-tRNA, E site binds free tRNA before ribosomal exit
The correct answer is there are three sites. A site binds aminoacyl-tRNA, P site binds peptidyl-tRNA, E site binds free tRNA before ribosomal exit.
Example Question #1 : Help With Translation Processes
Which of the following is not a type of modification that can occur after translation?
Proteasomal degradation
5' capping
Trimming
Phosphorylation
5' capping
Post-translational modifications that may occur after a protein is translated include numerous processes to alter the structure or function of the protein. Trimming modification involves removal of the N- or C - terminal propeptides from zymogens to generate mature proteins. Covalent alterations, including phosphorylation, glycosylation and hydroxylation, are frequently used to modify the structure or energy state of a protein. Proteasomal degradation requires the attachment of ubiquitin to defective proteins to tag them for degradation and digestion. Amino acids from degraded proteins can often be recycled to generate new molecules.
5' capping occurs in the nucleus after transcription and is required for transport of RNA out of the nucleus prior to translation.
Example Question #3 : Translation And Proteins
Which of the following is not a phase in translation?
Modification
Termination
Elongation
Initiation
Modification
There are four phases in translation: activation, initiation, elongation, and termination. Activation is the process that joins the correct amino acid to the correct tRNA. When the tRNA has an amino acid bound to it, it is "charged." Initiation occurs when the small ribosomal subunit binds the 5' end of mRNA, with the help of initiation factors and other proteins. The structure then recruits a methionine tRNA to the start codon to begin the elongation process. Elongation occurs as charged tRNA molecules transfer their amino acids to the growing polypeptide. Termination results when a stop codon is recognized by release factors and the completed protein is released from the ribosome.
Modification of the transcript occurs after translation has been completed.
Example Question #4 : Translation And Proteins
Which of the following ensures that viral gene translation occurs even when host translation is inhibited?
5' guanine cap
3' poly-A tail
Promoter
5' untranslated region (UTR)
Internal Ribosomal Entry Sites (IRES)
Internal Ribosomal Entry Sites (IRES)
Viruses utilize IRES to allow translation to occur in a 5' cap-independent manner. Translational machinery (ribosomes) are located to the IRES so that translation can occur. 5' guanine cap and 3' poly-A tails are mRNA modifications that are normally necessary to initiate translation, but are cap-dependent. The promoter regulates genes expression on the level of transcription, whereas the 5' UTR regulates translation.
Example Question #3 : Translation And Proteins
Which amino acid is the "start" amino acid in a peptide chain?
Threonine
Methionine
Arginine
Lysine
Tyrosine
Methionine
The correct answer is methionine. The ATG codon triplet in a mRNA strand codes for the start of the peptide, and this first amino acid that is coded by ATG is methionine.
Example Question #31 : Rna, Transcription, And Translation
Most translation occurs by a mRNA cap-dependent mechanism, however, translation can occur by cap-independent initiation. One mechanism by which eukaryotic cells can initiate cap-independent translation is by which of the following approaches?
Poly(A)-binding protein
Internal ribosome entry site
elF4F initiation complex
None of these
5' mRNA cap
Internal ribosome entry site
The correct answer is the internal ribosome entry site. This site is a specific nucleotide sequence that allows for translation initiation in the middle of a mRNA sequence, rather than at the 5' end, and does not require the cap-dependent elF4F initiation complex or the 5'cap. The poly(A)-binding protein complexes with the 3' end of mRNA strands during translation initiation via the cap-dependent mechanism.