ΤψC arm is one of the structures that cloverleaf tRNA molecules have. The ΤψC arm is important for the proper folding of the molecules as it interacts with other structures within the same noucleotide sequence.
The tRNA anticodon for TAC would be AUG. However, tRNA does not transcribe DNA and would not come in contact with the nitrogen base thymine. A better question would be what is the tRNA anticodon for the mRNA codon UAC.
The base sequences on tRNA that are complementary to the codons on mRNA are known as anti-codons. These match up with the codons to ensure the correct amino acid is added to the polypeptide (protein) chain being created. U binds with A, G binds with C.
The shape of tRNA is specifically designed to be able to accept the amino acid according to its anticodon. If tRNA was in any other shape, aminoacyl tRNA synthetase, the enzyme that adds amino acid to tRNA, would not be able to transfer the amino acid to tRNA.
The anticodon is a sequence of the tRNA that compliments the matching t base pairs on the mRNA. The anticodon is an amino acid specific to the tRNA molecule.
It can. If the codon has an "A," then its anticodon must have a "T."
The anticodon of a tRNA molecule has only three nitrogen bases. The anticodon is complementary to a codon of mRNA at the ribosome. The tRNA molecule carries a specific amino acid from the cytoplasm to its complementary mRNA codon, where it will be incorporated into the new protein being made.
Because c-g-a-t-c-c-g-t-t contains thymine and is therefore from the DNA, the tRNA sequence that may derive from this is C-G-A-U-C-C-G-U-U
The tRNA anticodon for TAC would be AUG. However, tRNA does not transcribe DNA and would not come in contact with the nitrogen base thymine. A better question would be what is the tRNA anticodon for the mRNA codon UAC.
The base sequences on tRNA that are complementary to the codons on mRNA are known as anti-codons. These match up with the codons to ensure the correct amino acid is added to the polypeptide (protein) chain being created. U binds with A, G binds with C.
tRNA does not copy a strand of DNA - that is what mRNA does.So for the DNA strand ATT-CGA-CCT-ACG:the mRNA strand would be UAA-GCU-GGA-UGCtRNA is responsible for carrying the correct amino acid to match up with the codon (three letter code) on the mRNA. The first codon here is UAA - which is a stop codon - meaning the peptide chain being created will not proceed beyond this.
125 psi
the "t" in tRNA stands for transfer. the whole thing would be Transfer Ribonucleic Acid the "t" in tRNA stand for transfer. therefore it would be Transfer Ribonucleic Acid
The shape of tRNA is specifically designed to be able to accept the amino acid according to its anticodon. If tRNA was in any other shape, aminoacyl tRNA synthetase, the enzyme that adds amino acid to tRNA, would not be able to transfer the amino acid to tRNA.
Yes, but in tRNA it does not. With RNA, A pairs with U, T pairs with A, C with G, and G with C. For example if your thing was ACT, GCA, TTC your RNA would be; UGA, CGU, AAG
The anticodon is a sequence of the tRNA that compliments the matching t base pairs on the mRNA. The anticodon is an amino acid specific to the tRNA molecule.
It can. If the codon has an "A," then its anticodon must have a "T."
3 *** if u want more explanation. basically it is called translation. tRNA decodes the message. If mRNA is AUG, tRNA will attach an anitcodon. Since there is no T in RNA then for A it will be U. For U it will be A and then G will base pair with C. So you will have an anticodon of UAC - which will bring in the amino acid methionine.