Need help preparing for the Biology section of the MCAT? MedSchoolCoach expert, Ken Tao, will teach everything you need to know about Watson-Crick Model of DNA within Nucleic Acids. Watch this video to get all the MCAT study tips you need to do well on this section of the exam!
In April of 1953, Francis Crick and James D. Watson published an article in the journal Nature entitled, "Molecular Structure of Nucleic Acids: A Structure for Deoxyribose Nucleic Acid." In this article, they detailed their discovery of the structure of DNA. The Watson-Crick model of DNA, as it has since been called, helps to explain how DNA functions and illustrates the fundamental interactive forces that hold DNA molecules together.
Watson-Crick Base Pairing
Both DNA and RNA are made from nucleotides, which include phosphates, five-carbon sugars, and nitrogenous bases. The interactions between the nitrogenous bases are termed Watson-Crick base pairing. There is the possible combinations of base pairing: Adenine with thymine, adenine with uracil, and cytosine with guanine.
Note that the adenine and thymine/uracil base pairs involve only two hydrogen bonds, whereas the cytosine and thymine base pair involves three hydrogen bonds. This difference in hydrogen bonds means that the cytosine and thymine base pair is held together more strongly than either the adenine and thymine or adenine and uracil base pairs. In this way, it would take more energy to break the cytosine and thymine base pair bonds compared to the adenine and thymine or adenine and uracil base pair bonds.
Watson-Crick Model
The model for the structure of DNA that Francis Crick and James D. Watson developed consists of a double helix formed between two antiparallel, single-stranded DNA molecules.
The named "double-helix" refers to the fact that in this model, there are two single-stranded molecules that are bound in a helical shape. Also, it is important to note that the two strands of the double helix molecule are antiparallel. In one direction, one strand goes from the 5' to 3' direction, whereas in the other direction, the other strand goes from the 3' to 5' direction. In other words, the strands go in opposite directions. Furthermore, on the side of the double helix molecule is what is termed the sugar-phosphate backbone, referring to alternating molecules of sugar and phosphate on the outside or "backbone" of the molecule.
Base Pair Interactions
The Watson-Crick DNA model displays how the nitrogenous bases of both DNA strands interact with each other at the center of the double helix. This interaction is favorable because the two strands are complementary to each other based on Watson-Crick base pairing. Where adenine is present on one strand, thymine is on the other strand. Similarly, where guanine is on one of the single-stranded DNA molecules, cytosine is on the other. The strands are held together by the hydrogen bonds between the base pairs.
Also, aside from hydrogen bonds, the two strands of DNA are held together by what is termed base stacking. Base stacking refers to the fact that the nitrogenous bases are stacked on top of each other. Since the nitrogenous bases are aromatic, they can form favorable interactions with the bases stacked above and below them.
Watson-Crick DNA Model & DNA Replication
The Watson-Crick model of DNA is important because it implies a simple mechanism for DNA replication. DNA is genetic material, and in order to pass on genetic material to offspring, there has to be some way to replicate it. The double-helix model consists of two single-stranded, complementary DNA molecules. In this way, it would be possible to separate the two strands and use them as templates to create copies of DNA. Doing this would produce two identical copies of DNA, which is what happens during DNA replication.
Hybridization
Hybridization refers to the process by which one DNA or RNA molecule binds to a complementary DNA or RNA molecule. Complementary, in this case, means that the base pairs between the molecules are complementary to each other. For example, if one DNA molecule has the sequence AGTCCT in the 5' to 3' direction, then the complementary DNA molecule would have the sequence AGGACT in the 3' to 5' direction. In other words, the two molecules would be antiparallel to each other.
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8 сен 2024
