The nucleotide sequence of the mRNA strand is determined by the DNA template strand during transcription. If the DNA template sequence is, for example, 3'-ATCGTAGC-5', the corresponding mRNA sequence synthesized would be 5'-UAGCAUCG-3'. The mRNA sequence consists of complementary RNA nucleotides, where adenine (A) pairs with uracil (U) and cytosine (C) pairs with guanine (G).
DNA is not made into mRNA, it is transcribed by mRNA. The DNA molecule is split into two strands by the enzyme helicase. One strand is the sense strand and the other is the anti-sense strand. Then mRNA nucleotides pair with their complimentary DNA bases on the antisense strand. The enzyme RNA polymerase causes the mRNA nucleotides to bond with one another, forming a strand of mRNA.
During transcription, the mRNA strand is synthesized using the template DNA strand, which runs in the 3' to 5' direction. The mRNA is created in the 5' to 3' direction, meaning that RNA polymerase adds complementary RNA nucleotides to the growing strand. For example, if the DNA template strand has a sequence of 3'-ATCGTA-5', the resulting mRNA would have the sequence 5'-UAGCAU-3'.
400 codons.Because 3 consecutive nucleotides in a gene together form a codon which codes for amino acids.
The DNA sequence responsible for an mRNA codon is found in the coding region of a gene, specifically in the form of triplet base pairs. During transcription, RNA polymerase synthesizes mRNA by complementary pairing with the DNA template strand, where each group of three nucleotides (codon) in the mRNA corresponds to a specific amino acid or stop signal in protein synthesis. For example, if the DNA sequence is A-T-G, the corresponding mRNA codon would be U-A-C. Thus, the sequence of nucleotides in DNA directly determines the sequence of codons in mRNA.
The sequence of amino acids (forming a protein) that result from the mRNA strand CAG-AAG-UUC-CUC-UCG-C would be: Glutamine-Threonine-Phenylalanine-Leucine-Serine Each codon must be three bases long - therefore the end of this mRNA sequence 'C' cannot code for an amino acid. There would also need to be a stop codon at the end to complete translation.
DNA is not made into mRNA, it is transcribed by mRNA. The DNA molecule is split into two strands by the enzyme helicase. One strand is the sense strand and the other is the anti-sense strand. Then mRNA nucleotides pair with their complimentary DNA bases on the antisense strand. The enzyme RNA polymerase causes the mRNA nucleotides to bond with one another, forming a strand of mRNA.
During transcription, the mRNA strand is synthesized using the template DNA strand, which runs in the 3' to 5' direction. The mRNA is created in the 5' to 3' direction, meaning that RNA polymerase adds complementary RNA nucleotides to the growing strand. For example, if the DNA template strand has a sequence of 3'-ATCGTA-5', the resulting mRNA would have the sequence 5'-UAGCAU-3'.
The sense strand of DNA is the strand that has the same sequence as the mRNA that is transcribed from DNA. The antisense strand is the complementary strand of the sense strand, which is used as a template for mRNA synthesis. The mRNA is transcribed from the antisense strand and contains the same sequence as the sense strand.
3 nucleotides
400 codons.Because 3 consecutive nucleotides in a gene together form a codon which codes for amino acids.
DNA is transcribed into mRNA through a process called transcription. During transcription, an enzyme called RNA polymerase reads the DNA sequence and creates a complementary mRNA strand by matching nucleotides. This mRNA strand carries the genetic information from the DNA and serves as a template for protein synthesis.
The complimentary strand of MRNA would be AAUUCCGG.
The DNA sequence responsible for an mRNA codon is found in the coding region of a gene, specifically in the form of triplet base pairs. During transcription, RNA polymerase synthesizes mRNA by complementary pairing with the DNA template strand, where each group of three nucleotides (codon) in the mRNA corresponds to a specific amino acid or stop signal in protein synthesis. For example, if the DNA sequence is A-T-G, the corresponding mRNA codon would be U-A-C. Thus, the sequence of nucleotides in DNA directly determines the sequence of codons in mRNA.
To determine the amino acid sequence from mRNA, one can use the genetic code to translate the sequence of nucleotides in the mRNA into a sequence of amino acids. Each set of three nucleotides, called a codon, corresponds to a specific amino acid. By reading the mRNA sequence in groups of three nucleotides and matching them to the genetic code, one can determine the corresponding amino acid sequence.
To change DNA to mRNA, a process called transcription occurs. During transcription, an enzyme called RNA polymerase reads the DNA sequence and creates a complementary mRNA strand by matching nucleotides. This mRNA strand carries the genetic information from the DNA and can then be used to make proteins through a process called translation.
The sequence of amino acids (forming a protein) that result from the mRNA strand CAG-AAG-UUC-CUC-UCG-C would be: Glutamine-Threonine-Phenylalanine-Leucine-Serine Each codon must be three bases long - therefore the end of this mRNA sequence 'C' cannot code for an amino acid. There would also need to be a stop codon at the end to complete translation.
The mRNA sequence generated from the DNA strand tgacgca would be acugcgu. This is because mRNA is complementary to the DNA template strand, so DNA base T pairs with mRNA base A, DNA base G pairs with mRNA base C, DNA base A pairs with mRNA base U, and DNA base C pairs with mRNA base G.