If the tRNA has the sequence UUA, then the mRNA it reads from will have the sequence complementary to UUA, which is AAU. RNA uses the nucleic acid uracil instead of the DNA counterpart, thymine.
The bases of mRNA coded for by a DNA segment are complementary to the original DNA sequence. If the DNA sequences are ATCG, the corresponding mRNA bases will be UAGC.
The sequence of mRNA is directly dependent on the sequence of DNA in the process of transcription. During transcription, RNA polymerase reads the DNA sequence and synthesizes a complementary mRNA strand. Changes in the DNA sequence can result in changes in the mRNA sequence, affecting the protein product that is ultimately produced.
A codon is found in the DNA sequence and in the mRNA sequence. The anticodon is the opposite sequence that would match with the sequence of the codon and allows pairing of the anticodon with the codon
There would be 393 bases on the mRNA strand corresponding to 131 amino acids, as each amino acid is coded for by a sequence of three bases (1 codon). By multiplying the number of amino acids by 3, you can determine the total number of bases required to encode the protein sequence on mRNA.
A codon in DNA or mRNA is a group of three nitrogenous bases that encode for one specific amino acid. The sequence of codons in the mRNA is read during translation to determine the amino acid sequence of a protein.
tRNA contains an anticodon which is a sequence of three nitrogen bases that is complimentary to a particular mRNA codon.
the sequence of bases in DNA
The base sequence of mRnas is 'determined by the base sequence of nucleotides in Dna.' The base sequence is transformed into information via the triplet codons of The Genetic Code.
A 3-base sequence of nitrogen bases on a molecule of mRNA is called a codon.
mRNA bases are put into the correct order during a process called transcription. Enzymes called RNA polymerases transcribe the DNA template into mRNA by matching complementary bases (A with U, G with C) to ensure the correct sequence. This process is essential for making a functional mRNA that can be used to produce proteins.
The complimentary strand of MRNA would be AAUUCCGG.
The bases of mRNA coded for by a DNA segment are complementary to the original DNA sequence. If the DNA sequences are ATCG, the corresponding mRNA bases will be UAGC.
The sequence of mRNA is directly dependent on the sequence of DNA in the process of transcription. During transcription, RNA polymerase reads the DNA sequence and synthesizes a complementary mRNA strand. Changes in the DNA sequence can result in changes in the mRNA sequence, affecting the protein product that is ultimately produced.
The sequence of amino acids in a protein is determined by the sequence of nucleotides in the mRNA, and this is determined by the sequence of nucleotide bases in the DNA.
A codon is found in the DNA sequence and in the mRNA sequence. The anticodon is the opposite sequence that would match with the sequence of the codon and allows pairing of the anticodon with the codon
There would be 393 bases on the mRNA strand corresponding to 131 amino acids, as each amino acid is coded for by a sequence of three bases (1 codon). By multiplying the number of amino acids by 3, you can determine the total number of bases required to encode the protein sequence on mRNA.
3 bases are needed to specify an mRNA codon.