The ideas we just talked about on the last page are more or less encapsulated by one of Chargaff's rules, which are a series of rules about the composition of DNA that were used by Watson and Crick to help determine DNA structure. Now there were a number of different rules Chargaff developed. However, we're really just going to focus on the one that deals with the base composition of DNA and it's more or less summarized by the statement that in a double-stranded molecule of DNA, the amount of adenine equals the amount of thymine and the amount of guanine equals the amount of cytosine. Likewise, the amount of purines will be equal to the amount of pyrimidines. And again, these are the ideas we were just talking about on the previous page. Watson and Crick didn't just use Chargaff's rules to determine DNA structure though. They also used an x-ray crystallography image from Rosalind Franklin, pictured right here. And the image they used, you can see right next to her, was called photo 51. I love this name. It's like super mysterious sounding, right? Like area 51, photo 51. It's great. And basically, what this image showed Watson and Crick is that DNA had a simple structure and it had substituents that were about 3.4Å apart and of course, those substituents are the bases we now know about. That is an important number to know guys, 3.4Å apart, make sure you memorize that. Alright. So the structure of DNA that Watson and Crick came up with is called a double helix. The double helix contains 2 grooves in it actually. A major groove and a minor groove and I'm going to trace those out for you so that you can, maybe see them a little better here. So, the minor groove is this smaller one in this opening right here and it kinda snakes along this way in the molecule. The major groove, on the other hand, And you can actually before we go there, you can actually see the minor groove right here. It's this space. The major groove, on the other hand, is this big open area here and you can see it wraps around the molecule like that and it's pictured over here as this big open area like that. So, the main point of these grooves is this is how stuff interacts with DNA. It binds into DNA generally using the major groove though sometimes the minor groove is used by certain specific proteins. But obviously, lots of proteins and enzymes need to bind DNA to carry out gene expression and to regulate gene expression. Now, it's important to note that the structural bonds of DNA are all single bonds. And that makes the molecule pretty flexible. And if you think about it, the nucleotides are also with the exception of some double bonds in the bases of course and the phosphate groups, the nucleotides are made of many single bonds as well and this means that they're also quite flexible and actually, nucleotides can have 2 conformations that you can see right here. There is the synform and the antiform. And basically, that is just a flip flop of the base on this single around on that single bond between these positions. However, in our DNA, the anti-form is generally the conformation seen. Syn is much less common. Also, that is the worst arrow I've ever drawn in my life. So, I'm redrawing it. Boom. Anti-form is more common. Alright. Now let's flip the page.
- 1. Introduction to Biochemistry4h 34m
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- Characteristics of Life12m
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- Review 1: Nucleic Acids, Lipids, & Membranes2h 47m
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- Review 2: Biosignaling, Glycolysis, Gluconeogenesis, & PP-Pathway3h 12m
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- Review 3: Pyruvate & Fatty Acid Oxidation, Citric Acid Cycle, & Glycogen Metabolism2h 26m
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- Review 4: Amino Acid Oxidation, Oxidative Phosphorylation, & Photophosphorylation1h 48m
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- Practice: Amino Acid Oxidation 12m
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- Practice: Oxidative Phosphorylation 15m
- Practice: Oxidative Phosphorylation 24m
- Practice: Oxidative Phosphorylation 35m
- Practice: Photophosphorylation 15m
- Practice: Photophosphorylation 21m
Nucleic Acids 3: Study with Video Lessons, Practice Problems & Examples
Chargaff's rules state that in double-stranded DNA, the amount of adenine equals thymine, and guanine equals cytosine, indicating a balance between purines and pyrimidines. Watson and Crick utilized Rosalind Franklin's x-ray crystallography image, photo 51, revealing DNA's double helix structure with bases spaced 3.4 angstroms apart. The double helix features major and minor grooves, crucial for protein binding during gene expression. DNA's flexibility arises from single bonds in nucleotides, with the anti conformation being predominant. Understanding these structural elements is essential for grasping DNA's role in genetics.
Nucleic Acids 3
Video transcript
Here’s what students ask on this topic:
What are Chargaff's rules and why are they important for understanding DNA structure?
Chargaff's rules state that in double-stranded DNA, the amount of adenine (A) equals the amount of thymine (T), and the amount of guanine (G) equals the amount of cytosine (C). This indicates a balance between purines (A and G) and pyrimidines (T and C). These rules were crucial for Watson and Crick in determining the double helix structure of DNA. The complementary base pairing suggested by Chargaff's rules explained how DNA could replicate and store genetic information. Understanding these rules helps in grasping the molecular basis of genetics and the mechanisms of DNA replication and transcription.
How did Rosalind Franklin's photo 51 contribute to the discovery of DNA's structure?
Rosalind Franklin's photo 51, an x-ray crystallography image, was pivotal in revealing the structure of DNA. The image showed that DNA had a helical structure with bases spaced 3.4 angstroms apart. This information was used by Watson and Crick to model the double helix structure of DNA. The regular spacing of the bases suggested a repeating structure, which was essential for understanding how DNA could store genetic information and replicate accurately. Franklin's work provided the critical evidence needed to confirm the helical nature of DNA, leading to the groundbreaking discovery of its double helix structure.
What are the major and minor grooves in DNA, and what is their significance?
The double helix structure of DNA features two types of grooves: the major groove and the minor groove. The major groove is the larger, more accessible groove, while the minor groove is smaller and less accessible. These grooves are significant because they are the sites where proteins and other molecules interact with DNA. Most DNA-binding proteins, including transcription factors, bind to the major groove due to its size and accessibility. The grooves play a crucial role in gene expression and regulation, as they allow specific proteins to recognize and bind to particular DNA sequences.
Why is the anti conformation of nucleotides more common in DNA?
The anti conformation of nucleotides is more common in DNA because it is more stable and energetically favorable compared to the syn conformation. In the anti conformation, the base is positioned away from the sugar-phosphate backbone, reducing steric hindrance and allowing for more efficient base pairing and stacking interactions. This conformation supports the double helix structure of DNA, facilitating the proper alignment of complementary bases (A with T and G with C) and maintaining the overall stability and functionality of the DNA molecule.
How does the flexibility of DNA arise from its structural bonds?
DNA's flexibility arises from the single bonds present in its sugar-phosphate backbone and the nucleotides. These single bonds allow for rotational freedom, enabling the DNA molecule to bend and twist without breaking. This flexibility is crucial for various biological processes, such as DNA replication, transcription, and packaging within the cell nucleus. The ability of DNA to adopt different conformations and accommodate interactions with proteins and other molecules is essential for its role in gene expression and regulation.