The mRNA will have codons AUG-CCA-GUA-GGC-CAC
Yes, if the dummy strand, which is the non-template DNA strand, were used to make a protein, the resulting protein sequence would not correspond to the original DNA template sequence correctly. This would lead to a protein with a different amino acid sequence and potentially non-functional or misfolded protein.
That would be ducky you
The strand of mRNA produced from the DNA sequence GCA TTA would be complementary to the DNA template strand. The corresponding mRNA sequence would be CUG AAU, where adenine (A) pairs with uracil (U) in RNA, cytosine (C) pairs with guanine (G), and guanine (G) pairs with cytosine (C).
The sequence of the mRNA transcribed from the DNA gene TTACAGGTCCCA would be complementary to the template strand of the DNA. Since mRNA is synthesized using uracil (U) instead of thymine (T), the corresponding mRNA sequence would be AAUGUCCAGGGU. This sequence reflects the direct transcription of the DNA template, replacing each thymine with uracil.
The leading strand would utilize the 3' to 5' template DNA strand as a guide for continuous synthesis of complementary DNA in the 5' to 3' direction by DNA polymerase during DNA replication.
Yes, if the dummy strand, which is the non-template DNA strand, were used to make a protein, the resulting protein sequence would not correspond to the original DNA template sequence correctly. This would lead to a protein with a different amino acid sequence and potentially non-functional or misfolded protein.
The complementary strand of DNA to the template strand TACGGCTA would be ATGCCGAT.
During transcription the DNA double helix is separated into two individual strands. Each strand may serve as a template for RNA polymerase, which travels along the DNA structure in a 3' to 5' direction. As it progresses down the strand, RNA polymerase synthesizes a pre-messenger RNA strand that is complementary to the sequence on the DNA template. For example if the DNA sequence on the template was 5' ATACA 3', then the pre mRNA sequence synthesized would be 3' UAUGU 5'. (Remember, RNA synthesis utilizes the nucleotide uracil instead of thyamine).
That would be ducky you
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.
During DNA replication, the enzyme DNA polymerase catalyses the formation of new strands of DNA, using the old strands as models. DNA has a double-helix structure, with two strands forming each helix. Each strand is made up of DNA nucleotides, with the genetic information encoded in the sequence of different nucleotides (different nucleotides are distinguished by molecules called 'bases' attached to them, so the sequence of nucleotides is known as the 'base sequence'). The base sequence of one strand is complementary to that of its' neighbour - the base A binds with T, and C with G, so if one strand had the sequence ATTACA, the base sequence of the complementary strand would be TAATGT. When DNA polymerase creates a new DNA strand, it does so by matching nucleotides to the base sequence of one of the strands - the template strand. New nucleotides are brought in, which match the template in a complementary fashion (ie. A-T, C-G), and join to become one new strand. This new strand is complementary to the template.
The sequence of nucleotides of the complementary strand will be the nucleotides which bind to the nucleotides of the template. In DNA, adenine binds to thymine and cytosine binds to guanine. The complementary strand will therefore have an adenine where the template strand has a thymine, a guanine where the template has a cytosine, etc. For example: If the template strand is ATG-GGC-CTA-GCT Then the complementary strand would be TAC-CCG-GAT-CGA
Ttg ga
The sequence of the mRNA transcribed from the DNA gene TTACAGGTCCCA would be complementary to the template strand of the DNA. Since mRNA is synthesized using uracil (U) instead of thymine (T), the corresponding mRNA sequence would be AAUGUCCAGGGU. This sequence reflects the direct transcription of the DNA template, replacing each thymine with uracil.
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.
Ttg ga
The leading strand would utilize the 3' to 5' template DNA strand as a guide for continuous synthesis of complementary DNA in the 5' to 3' direction by DNA polymerase during DNA replication.