DNA Genetic Material

DNA is made up of deoxyribonucleotides, which are the building blocks of genetic material. It is acidic in nature, and it may be found in the nucleus of the cell where it functions. Mischer discovered the DNA cell or DNA in 1869, and he gave it the scientific name nuclein. After that, Altmann discovered that they are acidic in nature, and as a result, he dubbed them nucleic acids (acidic in nature). 

DNA

DNA is an abbreviation for “Deoxyribonucleic Acid,” which is a genetic material found in all prokaryotic and eukaryotic cells, as well as in many viruses, and which encodes genetic material for the transmitting inherited traits. DNA is found in all prokaryotic and eukaryotic cells, as well as in many viruses.

Genetic information is carried by DNA, which is an organic macromolecule composed of two polynucleotide chains that spiral around each other to form a double helix structure. DNA is crucial for the development, operation, growth and reproduction of all organisms, as well as many viruses.

Properties of  a genetic material 

• It should have the capability of storing genetic information, among other things.
• It should be able to produce at a high rate in subsequent generations with minimal effort.
• It should serve as the foundation for the transfer of the genetic characteristics that it has the ability to govern.
• It needs to participate in gene activity, which ultimately leads in the expression of the features within the organism.

Experiments for DNA  as a genetic material 

The evidence that DNA serves as the genetic information for the vast majority of organisms can be broadly classified into two categories:

1. Direct evidence 
2. Evidence that is not directly related

Direct evidence

The following experiments, which demonstrate that DNA is the genetic material, are considered direct evidence of this claim:

A Bacterial Transformation Experiment Conducted by Griffith

• The bacterium Diplococcus pneumoniae (or Streptococcus pneumoniae), which induces pneumonia in mammals, was studied by Frederich Griffith, a British bacteriologist, in a series of tests done in 1928.
• He cultured the bacteria in the culture plates and discovered that they form two types of colonies, namely, gram-positive and gram-negative.Because these microorganisms have a mucous (polysaccharide) layer on their surface, they produce smooth, shiny colonies. i. S-strain (capsulated type): It makes smooth, glossy colonies. These are highly contagious and can cause pneumonia.

This strain (R-strain, non-capsulated type) is characterised by the formation of rough colonies on the surface of the colony due to the absence of a mucous (polysaccharide) coating. These are non-virulent and do not cause pneumonia in healthy individuals.

• He carried out a series of experiments, which are detailed below:  Injecting S-strain into mice caused the mice to become ill and die as a result of the infection.

Experiment with Hershey and Chase

Based on Griffith’s experiment, Avery and his team were able to isolate DNA and demonstrate that DNA is the genetic component. However, it was not widely recognised till Hershey and Chase published the results of their experimental work.

Alfred Hershey and Martha Chase embarked on a quest to discover the genetic material contained within living creatures in 1952. Their investigations provided unequivocal evidence that DNA is a form of genetic material. For Hershey and Chase’s experiment, bacteriophages (viruses that infect bacteria) were the most important component.

The virus does not have its own mechanism of replication; instead, it relies on the host to carry out this function. As soon as they attach themselves to a host cell, the genetic material contained within them is passed to the host. It was the goal of Hershey and Chase’s experiment to determine whether it was protein or DNA that served as the genetic material that was introduced into the bacteria.

Indirect evidence

• localisation :-Without a stable place for the genetic material within the cell, the genes will not operate properly. DNA is always found largely within the chromosomes of eukaryotic cells, which are found in the nucleus of the cell.
• stability :- DNA does not undergo the anabolic and catabolic processes that occur in the cell, as do several other macromolecules.
• sensitivity to mutagens :- The genetic material should be subjected to mutations and should be sensitive to mutagens (such as UV-rays, X-rays, and other radiation sources) as well as a variety of other chemical substances.

Conclusion

As a result of the foregoing debate, it can be stated that both DNA and RNA can operate as genetic material, with DNA being preferred for storage of genetic information due to its greater stability. The genetic material that was provided by the Hershey and Chase experiment served as confirmation of the existence of DNA. Evidence that DNA serves as genetic material has been accumulating for a long time. The ability to reproduce, stability, the ability to undergo mutation, and the ability to express itself in the form of Mendelian traits are all prerequisites for superior genetic material.