Gcu aga
Ucg cga GAC UAU
the DNA strand GTT ACC would be transcribed to CAA UGG.
gac uau Gac uau GAC UAU
The template strand of DNA is used to make a complementary copy during DNA replication, while the antisense (non-coding) strand is used as a template for complementary mRNA synthesis during transcription.
RNA polymerase reaches the beginning of the gene
GCUAGA :)
Ucg cga GAC UAU
the DNA strand GTT ACC would be transcribed to CAA UGG.
gac uau Gac uau GAC UAU
Transcription produces a strand of messenger RNA that is complementary to the DNA that it transcribed. For example, the DNA sequence AGTCGA would be transcribed by messenger RNA as UCAGCU.
The template strand of DNA is used to make a complementary copy during DNA replication, while the antisense (non-coding) strand is used as a template for complementary mRNA synthesis during transcription.
RNA polymerase reaches the beginning of the gene
During transcription, only one DNA strand is used as a template to synthesize an mRNA molecule. This strand is called the template or antisense strand. The other DNA strand, known as the coding or sense strand, is not used because it has the same sequence as the mRNA molecule being produced, except with thymine instead of uracil. Transcribing both strands would be redundant and energetically wasteful.
During transcription, the DNA template is used to create a complementary strand of mRNA (messenger RNA). An A on the DNA template is complementary to a U on the mRNA, T to A and C to G. Therefore the complementary mRNA of TAC-GCG-CAT-TGT-CGT-CTA-GGT-TTC-GAT-ATA-TTA-GCT-ACG is: UTG-CGC-GUA-ACA-GCA-GAU-CCA-AAG-CUA-UAU-AAU-CGA-UGC
AAC CT would produce TTG GA The coding strand is the DNA strand that has the same base sequence as the RNA transcript. It contains codons, and the non-coding strand has anti-codons instead.
No. All strands can be replicated, just depends on where the enzyme decides to land and unzip it. Anyways, all DNA molecules would be adequate templates since they are all identical copies of each other.
At first during transcription, RNA polymerase binds the promoter region of a gene to be transcribed. The end product would be the synthesized mRNA.