Researchers utilized recently published telomere-to-telomere genomes of humans, chimpanzees, bonobos, gorillas, and two ...

double-helical model for the structure of DNA. Watson and Crick's discovery was also made possible by recent advances in model building, or the assembly of possible three-dimensional structures ...

The two decide to team up to create a three-dimensional model of DNA, which they believe must have ... The pair have a “Eureka” moment upon seeing this image, realizing that DNA must have a double ...

Here is a view of the double helix -- the subject of Rosalind ... Crick were able to piece together the first accurate model of DNA. Shown here is the structure of naked DNA -- DNA without all ...

According to the conservative replication model, the entire original DNA double helix serves as a template for a new double helix, such that each round of cell division produces one daughter cell ...

Our findings also demonstrate that the rules of complementarity that Watson and Crick defined in their iconic double-helical model of DNA structure need to be expanded. In the model proposed by ...

By creating a more true-to-life representation of DNA's environment, researchers at Northwestern University have discovered ...

The original model of DNA structure created by Crick and Watson Crick and Watson's feat was to realise that there are two strands that coil around each other to form a double helix. The two ...

Certain DNA sequences can form structures other than the canonical double helix. These alternative DNA conformations—referred to as non-B DNA—have been implicated as regulators of cellular ...

(Image: Wikimedia Commons, CC SA 3.0) The most common type of base pairing is the Watson-Crick base pair, named after James Watson and Francis Crick, who first proposed the double helix structure of ...

Not all DNA is in the double helix form described in textbooks since the 1950’s. Quadruple helix DNA, also known as G-quadruplex DNA, was identified in the human genome several decades ago, and ...

A fiber sensor inspired by the shape of DNA, developed by researchers at Shinshu University, introduces a new design for more durable, flexible fiber sensors in wearables. Traditional fiber sensors ...