Why do we make such a fuss over our biological catalysts?

Why do we make such a fuss over our biological catalysts?

September 12, 2021 Comments Off on Why do we make such a fuss over our biological catalysts? By admin

An article by Anand Kumar, The Times Of India.

A few years ago, the Indian Medical Association (IMA) and the National Medical Council (NMC) held a meeting.

It was there that Dr. Ramesh Sharma, then dean of medical schools, gave his thesis on the role of genes in medicine.

Dr. Sharma had also authored a paper in 1999 on the chemical and biological properties of the enzyme lysine.

It seemed like an obvious topic for a meeting on a molecular biology issue.

The idea that a gene could be the “gatekeeper” of life seemed like a no-brainer.

So what was Dr. Sharma’s thesis about?

What was he trying to prove?

And why did he do it?

The answer lies in the enzyme’s role in DNA replication.

DNA replication involves the chemical process of transferring a large amount of information from one part of the genome to another.

DNA itself contains only a few thousand bases, and in a molecule this small, copying machinery is called a polymerase chain reaction (PCR).

DNA itself is not only a protein, but also a sequence of DNA molecules, called a base pair.

The base pair molecules in DNA have specific instructions, called codons, that guide their DNA to the next position in the sequence.

The instructions of these codons are then translated into RNA (RNAi) instructions that carry the instructions to carry out the instructions.

DNA also carries a large number of other instructions that help the protein do its work.

In order for the DNA to do its job properly, the codons need to be turned on.

When a DNA codon is activated, it activates the polymerase, which converts the instructions from the DNA into RNA.

The RNA then carries the instructions back to the DNA and the DNA converts them back into DNA again.

The process repeats itself until the entire genome is encoded in the DNA.

When the DNA is no longer needed for the RNA instructions, the DNA can be turned off and the instructions can be transferred to RNAi instructions, which carry the RNA back to DNA.

This process repeats until all the instructions have been turned on and the RNA is complete.

But the enzymes in DNA are a special kind of “transcription machinery.”

DNA is a “double helix,” a double chain of genetic sequences.

The sequence of the double helix is known as a gene.

The gene is encoded as a long sequence of letters, called the base pair, which, when written down in DNA, forms a DNA sequence known as an amino acid.

DNA can also be broken down into smaller bits, called nucleotides, which can then be used to make RNA.

RNA is the other kind of DNA that DNA contains.

When an amino acids is broken down, the smaller bits can then form a protein.

RNA molecules are the building blocks of proteins.

RNA can also work as an RNAi machinery, the process by which a gene and an RNA can be made to work together.

It is when these two processes are working together that they are called complementary enzymes.

The enzyme is called the DNA-RNA polymerase.

This enzyme is the first of the three enzymes that are necessary for RNA to work.

It also plays a major role in the synthesis of proteins, which is why the process of making a protein involves a lot of the enzymes.

So how did DNA-RNAs get their name?

The enzyme that converts the DNA code into RNA is called an enzyme called an RNA polymerase (IP).

In the 1960s, researchers started to discover a new type of RNA, called cDNA, which was the first type of DNA to be translated into protein.

DNA is the building block of protein.

The DNA code is the blueprint for the building of proteins that contain DNA.

RNA has the ability to turn the DNA in the form of RNA into protein, which then is then converted into RNA using the RNA polymerases.

RNA-DNA pairs are a big deal in biology.

They help to make proteins, but they also act as catalysts.

When protein is converted to RNA, the enzymes that convert the DNA from RNA to protein then act like catalysts that convert RNA into the active form of the protein.

These catalysts are called enzymes that catalyze the conversion.

The IP-RNA pairs that catalyse the conversion are called the cDNA-RNA catalysts and the cRNA-RNA-DNA catalysts, respectively.

The catalysts for converting DNA to RNA are called a DNA-DNA pair and a RNA-RNA pair.

This is the same way that the catalysts of a computer and a computer chip work together, but the computer is a much bigger part of it.

RNA also plays an important role in RNAi.

If DNA is turned into RNA, then RNA is converted into protein that can then carry the mRNA from one cell to another, and the resulting protein can then pass through

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