T-A-C-G-A-T
The complementary strand for CGATTAC would be GCTAATG. C and G are always paired together, and A and T are always paired together.
This Process Is Called DNA Transcription. *Apex*
ssb protein bind to the lagging strand as leading strand is invovled in dna replication and lagging strand is invovled in okazaki fragment formation
The complement DNA strand to "gtattcttcaagagatcgg" is "ccgatctcttgaagaatac". This is achieved by replacing each nucleotide with its complementary base: A with T, T with A, C with G, and G with C.
A strand of replicated DNA formed during prophase is called a sister chromatid. Sister chromatids are identical copies of each other produced during DNA replication and are held together by a structure called the centromere.
The 2nd strand matching DNA refers to the strand that can pair with the original DNA sequence through complementary base pairing. In DNA replication, this matching strand is synthesized by DNA polymerase according to the sequence on the original template strand.
The base on one strand pair with the base on the other strand, adenine with thymine, and cytosine with guanine, they join together by hydrogen bonds. Parent
To determine the complementary DNA strand, you would pair each base of the original DNA strand with its corresponding complementary base: adenine (A) pairs with thymine (T), and cytosine (C) pairs with guanine (G). For example, if the original strand is ATCG, the complementary strand would be TAGC. This base-pairing rule ensures that the two strands of DNA are complementary, allowing for proper replication and function.
Adenine only binds with Thymine, and Guanine only binds to Cytosine in DNA. In RNA however,Thymine is replaced with Uracil which binds to Adenine.
Very accurate to the base pair. The quality of the specimen matters as DNA can degrade. Short strand sequences (10-12 base pairs) can still be determined by PCR from one strand of hair.
Each new DNA molecule has an identical base-pair pattern as the original DNA molecule due to the semiconservative nature of DNA replication. This means that one strand of the original DNA molecule serves as a template for the synthesis of a new complementary strand during replication, resulting in two daughter DNA molecules with identical base sequences.
DNA usually comes in a double stranded helix, but if there is only one strand provided, complimentary base pairing occurs. Adenine and Thymine pair, as do Guanine and Cytosine. Given a sequence of DNA, using this, you can find its complementary strand.
The complementary base pair is important in DNA replication because it ensures that the new DNA strand is an exact copy of the original strand. This pairing allows for accurate replication of genetic information, which is crucial for maintaining the integrity of the genetic code and passing on correct information to new cells.
The new strand is complementary to the original strand. This means that the bases on the new strand pair with the bases on the original strand according to the rules of base pairing (A with T and G with C).
The matching DNA strand is called the complementary strand. In DNA, the bases pair specifically: adenine (A) pairs with thymine (T), and cytosine (C) pairs with guanine (G). This complementary base pairing is essential for the structure of DNA and plays a crucial role in processes like DNA replication and transcription.
The opposite strand in DNA will have bases that pair with the original strand according to the base pairing rules: adenine with thymine and cytosine with guanine. So, if the original sequence is ATCG, the opposite strand will be TAGC.
GGATCGA. Each base in the original DNA strand pairs with its complementary base (A with T and C with G) in the new strand during DNA replication.