AGTCG (I'm assuming your strand was written in the normal 5' to 3' order, and I wrote mine in that order as well, which means the last residue in my strand pairs with the first residue in your strand, and vice versa).
gct ga
ATG CC
The process of DNA replication.
It joins up with its complementary strand. I may then be used to make RNA.
Guanine
The template and non-template strands of DNA are complementary.This means that if a T (thymine)occurs on one strand, there must be an A (adenine) in that position on the other strand, and that C (cytosine) is always opposite G (guanine), following the rules of complementary base pairing.There are other names for the two strands, but Googling them shows there is a lot of confusion out there! The terms "template strand" and "non-template stand" seem to be the only ones that everyone uses consistently. The template strand is the strand along which messenger RNA is synthesized, and has, of course, a base sequence complementary to that of the RNA.The term "gene" is often applied to the non-template strand, the argument being that the non-template DNA strand and the mRNA have the same base sequence (except that where DNA has T, RNA has U, uracil).In transcription, RNAP uses template strand to make a copy of mRNA. Complementary to template strand is the coding strand, which sequence is identical to mRNA sequence except for the substitution of U for T. Although the coding strand is not used as a template for common transcription events, it is called coding because its sequence is used as a copy in mRNA sequence. For the case of "sense", terminologically template strand is called antisense, and coding strand is called the sense strand.Template/non-coding/antisenseNon-template/coding/senseMany people confuse complementary sequences with palindromic sequence which you can find in restriction system recognition sequences. Although the template strand yields a sense (functional) sequence in mRNA and thus a properly-folded protein, the complementary strand of it, non-template strand upon being transcribed yields a totally different and non-functional protein. However in terms of transcription of palindrome, both strands yield the same mRNA sequence, thus the same protein.Coding strand of a particular gene can be on one of either two strands of DNA, and thus this applies to the opposite strand of the said strand for the non-coding strand. The direction of transcription on a double-stranded DNA depends on whether the upper or lower strand is being transcribed. Therefore on a linearised genome, transcription occurs to the left for certain genes and to the right for the remaining genes.
The template sequence would be 5' TTGATGGCT 3'. You can find any DNA template sequence by finding the complementary base pair sequence for the mrna sequence. To do this, remember that A matches with U or T (U is used in the RNA strands wheras T is used in the DNA strands) and G matches with C (and vice versa). Next just flip the 5' and 3' ends because the complementary strands are always antiparallel to each other.
CAT GT. -APEX Learning
The strand is called the parental strand. the gene being copied would depend on which protein is needed.
The template strand is used to make a complementary copy. This is a type of DNA strand.
The process of DNA replication.
It joins up with its complementary strand. I may then be used to make RNA.
GCT GA :)
AGTCG (I'm assuming your strand was written in the normal 5' to 3' order, and I wrote mine in that order as well, which means the last residue in my strand pairs with the first residue in your strand, and vice versa).
Guanine
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
The new strands have new complementary bases on one side and the other is made of the original strand. A strand of DNA has two strands that are complementary to each other in a double helix. When it gets copied one side is used as a template for the new side being added on, the bases cytosine and guanine match up and the bases adenine and thymine match up to each other. For example: If the original DNA strand has this order: 3' G-A-T-A-A-C-C 5' then the new complementary strand has: 5' C-T-A-T-T-G-G 3'
The template and non-template strands of DNA are complementary.This means that if a T (thymine)occurs on one strand, there must be an A (adenine) in that position on the other strand, and that C (cytosine) is always opposite G (guanine), following the rules of complementary base pairing.There are other names for the two strands, but Googling them shows there is a lot of confusion out there! The terms "template strand" and "non-template stand" seem to be the only ones that everyone uses consistently. The template strand is the strand along which messenger RNA is synthesized, and has, of course, a base sequence complementary to that of the RNA.The term "gene" is often applied to the non-template strand, the argument being that the non-template DNA strand and the mRNA have the same base sequence (except that where DNA has T, RNA has U, uracil).In transcription, RNAP uses template strand to make a copy of mRNA. Complementary to template strand is the coding strand, which sequence is identical to mRNA sequence except for the substitution of U for T. Although the coding strand is not used as a template for common transcription events, it is called coding because its sequence is used as a copy in mRNA sequence. For the case of "sense", terminologically template strand is called antisense, and coding strand is called the sense strand.Template/non-coding/antisenseNon-template/coding/senseMany people confuse complementary sequences with palindromic sequence which you can find in restriction system recognition sequences. Although the template strand yields a sense (functional) sequence in mRNA and thus a properly-folded protein, the complementary strand of it, non-template strand upon being transcribed yields a totally different and non-functional protein. However in terms of transcription of palindrome, both strands yield the same mRNA sequence, thus the same protein.Coding strand of a particular gene can be on one of either two strands of DNA, and thus this applies to the opposite strand of the said strand for the non-coding strand. The direction of transcription on a double-stranded DNA depends on whether the upper or lower strand is being transcribed. Therefore on a linearised genome, transcription occurs to the left for certain genes and to the right for the remaining genes.
The template sequence would be 5' TTGATGGCT 3'. You can find any DNA template sequence by finding the complementary base pair sequence for the mrna sequence. To do this, remember that A matches with U or T (U is used in the RNA strands wheras T is used in the DNA strands) and G matches with C (and vice versa). Next just flip the 5' and 3' ends because the complementary strands are always antiparallel to each other.