Key chemical property of DNA would have to be that it is composed of nucleotides held together by phosphodiester bonds, this nucleotides consist of a deoxyribose sugar, a phosphate group and a nitrogenous base, this nitrogenous base is the source of variation in a DNA molecule because the nitrogenous base can be either Adenine, Cytosine, Thymine or Guanine.
In physical terms we can say that DNA has a double helix structure consisting of two anti parallel strands identical to each other joined together through the nitrogenous bases by hydrogen bonds, Adenine and Guanine are purines witch are double ringed structures and Cytosine and Thymine are pyrimidines witch are single ringed structures. A purine can only join with a pyrimidine, in DNA Adenine will bond with only thymine and cytosine with guanine.
The physical properties of strawberry DNA, such as its double helix structure and base pair composition, are similar to the structure of DNA molecules in general. The double helix structure allows DNA to be stable and compact, while the specific base pair sequences encode genetic information. These physical properties enable DNA to store and transmit genetic information accurately.
I believe that this is a multi million pound question....
DNA helps to determine the growth, development, and reproduction of a plant. It also influences the plant's traits such as color, size, shape, and resistance to diseases.
In DNA chromatography, scientists use the principles of chemistry to separate DNA molecules based on their size, charge, or other properties. By utilizing specialized columns and buffers, DNA fragments can be separated and analyzed based on their interactions with the chromatography medium, providing valuable information about DNA structure and function.
DNA fragments can be separated based on size and charge. Size separation is typically achieved through gel electrophoresis, where smaller fragments move faster through a gel matrix than larger ones. Charge separation is also utilized in electrophoresis, as DNA molecules are negatively charged and migrate towards the positive electrode when an electric field is applied. These properties allow for effective separation and analysis of DNA fragments.
by gross chemical properties.
The physical properties of strawberry DNA, such as its double helix structure and base pair composition, are similar to the structure of DNA molecules in general. The double helix structure allows DNA to be stable and compact, while the specific base pair sequences encode genetic information. These physical properties enable DNA to store and transmit genetic information accurately.
In their DNA or RNA.
DNA
they have different properties.
As far as DNA and RNA, nitrogen is an absolutely necessary part of their formation.
I believe that this is a multi million pound question....
James D. Watson and Francis Crick were prominent in the discovery on DNA. (Deoxyribonucleic acid) Though, some believe that Rosalind Franklin discovered the strictures of DNA before Watson and Crick. These people were the first to write about DNA, it's properties, and it's structural traits.
DNA helps to determine the growth, development, and reproduction of a plant. It also influences the plant's traits such as color, size, shape, and resistance to diseases.
A phosphate group can be found in molecules such as ATP, DNA, RNA, and phospholipids. It is often attached to other molecules to impart energy or structural properties.
In DNA chromatography, scientists use the principles of chemistry to separate DNA molecules based on their size, charge, or other properties. By utilizing specialized columns and buffers, DNA fragments can be separated and analyzed based on their interactions with the chromatography medium, providing valuable information about DNA structure and function.
DNA fragments can be separated based on size and charge. Size separation is typically achieved through gel electrophoresis, where smaller fragments move faster through a gel matrix than larger ones. Charge separation is also utilized in electrophoresis, as DNA molecules are negatively charged and migrate towards the positive electrode when an electric field is applied. These properties allow for effective separation and analysis of DNA fragments.