In this article we will discuss about:- 1. Chemistry of DNA 2. Chromatin 3. Chemistry of RNA 4. Structural Organization of RNA 5. DNA and GENE 6. Biological Importance of Nucleic Acids.

Contents:

  1. Chemistry of DNA
  2. Chromatin
  3. Chemistry of RNA
  4. Structural Organization of RNA
  5. DNA and GENE
  6. Biological Importance of Nucleic Acids

1. Chemistry of DNA:

a. The four types of monomelic units of DNA are adenylate, guanylate, cytidylate and thymidylate.

b. The monomeric units form a single strand of DNA which are held in polymeric form by 3′, 5′-phosphodiester bridges.

c. The informational content of DNA is available in the sequence in which these monomers are ordered.

d. The polymer possesses a polarity; one end has a 5′-hydroxyl or phosphate terminus while the other has a 3′-phosphate or hydroxyl moiety.

e. Since the genetic information is available in the monomeric units within the poly­mers, there is existence of a mechanism reproducing of replicating this specific in­formation with a high degree of fidelity.

f. In DNA molecules the concentration of Adenosine (A) nucleotides equals that of thymidine (T) nucleotides (A=T). The concentration of guanosine (G) nucleo­tides equals that of cytidine (C) nucleotides (G=C). This accelerated Watson, Crick and Wilkins in 1953 to pro­pose a model of double-stranded DNA molecule.

g. The 2 strands of this double-stranded mol­ecule are held together by hydrogen bonds between the purine and pyrimidine bases. The pairings between the purine and pyrimidine nucleotides on the opposite strands are dependent upon hydrogen bonding of A with T and G with C.

h. The 2 strands of the double helical mol­ecule are anti-parallel i.e. one strand runs in the 5′ to 3′ direction and the other in the 3′ to 5′ direction. Since the informa­tion resides in the sequence of nucleotides on one strand, the opposite strand is con­sidered as “antisense” i.e. the complement of the “sense” strand.

i. Three (3) hydrogen bonds hold the gua­nosine nucleotide to the cytosine nucle­otide and A-T pair is held together by 2 hydrogen bonds. Therefore, they are rep­resented as G = C and A = T. G-C bond is stronger by 50%.

j. The B form has a pitch of 3.4 nm per turn and within the single turn 10 base pairs exist.

k. The double-stranded structure in solution can be melted by increasing temperature or decreasing salt concentration.

Segment of a Structure of DNA Molecule

l. The double-stranded DNA molecule shows the properties of a fibre and it is a viscous material in solution and loses its viscosity upon denaturation.

m. In the major and minor grooves winding along the molecule parallel to the phosphodiester backbones, specific pro­teins interact with DNA molecules.

n. In some organisms such as bacteria, bac­teriophage and many DNA-containing animal viruses, the two ends of the DNA molecules are jointed to create a closed circle with no terminus. This does not de­stroy the polarity of the two molecules but it eliminates all 3′ and 5′ free hydroxyl and phosphoryl groups.

Double Helical Structure of DNA

o. It contains 1,600 to 9,000 nucleotides. The molecules are long and its length is 250 times greater than its breadth. Its structure is highly complex.

p. Heat, acid and alkali denature DNA.

2. Chromatin:

a. Chromatin is the chromosomal material extracted from nuclei of cells.

b. It consists of a long double-stranded DNA molecules and a nearly equal mass of histones as well as smaller amount of non­-histone proteins and a small quantity of RNA.

c. It contains a 10 nm repeating unit. The repeating units occur every 200 base pairs.

Base Pairing between Adenosine and Thymidine, Cytidine and Guanosine


3. Chemistry of RNA:

a. RNA is polymer of purine and pyrimidine ribonucleotides linked together by 3′, 5′-phosphodiester bridges.

b. The sugar moiety in RNA is ribose.

c. It contains uracil instead of thymine in addition to adenine, guanine and cytosine.

d. It exists as a single-stranded molecule rather than as a double-stranded helical molecule.

e. Since it is a single-stranded molecule, its guanine content does not necessarily equal its cytosine content and its adenine content does not necessarily equal its uracil content.

Hairpin Structure of RNA

f. It can be hydrolyzed by alkali to 2′, 3′ cyclic diesters of the mononucleotides. An intermediate in this hydrolysis is the 2′, 3′, 5′-triester which cannot be formed in DNA hydrolysis by alkali because of the absence of a 2′-hydroxyl group. The al­kali liability of RNA is useful diagnostically and analytically.

g. RNA molecule does not hybridize with the “antisense” strand of the DNA of its gene. Therefore, the sequence of RNA molecule (except U being replaced by T) is the same as that of the “antisense” strand of the gene. Small amounts of double- stranded RNA have been detected from mammalian organisms including humans which may probably be associated with RNA viruses.

h. It contains 60 to 6,000 nucleotides. The molecule is un-branched.

Relationship between the Sequence of an RNA Transcript

4. Structural Organization of RNA:

There are 3 main classes of RNA molecules in all prokaryotic and eukaryotic organisms.

These are:

a. Messenger RNA (m RNA).

b. Transfer RNA (tRNA) or soluble RNA.

c. Ribosomal RNA (rRNA).

a. The Messenger RNA (mRNA):

i. The messenger RNA is single-stranded and complementary to the sense strand of DNA.

Expression of Genetic Information in DNA

ii. The 5′ terminus of messenger RNA is ‘”capped” by a 7-methylguanosine triphos­phate which is linked to an 2′- O methyl ribonucleoside at its 5′-hydroxyl through the 3 phosphates. The protein-synthesiz­ing machinery begins translating the mRNA into proteins at the 5′ or capped terminus. The 3’-hydroxyl terminus has attached a polymer of adenylate residues 20-250 nucleotides in length.

iii. It is the most heterogeneous in size and stability.

Structure of tRNA

iv. It passes from nucleus to cytoplasm con­veying information in a gene to the pro­tein-synthesizing machinery where each serves as a template on which a specific sequence of amino acids is polymerized to form a specific protein molecule, the ultimate gene product.

v. It has a large molecular weight of 30,000 to 50,000 to have the coded information corresponding to long polypeptide chains.

vi. In mammalian nuclei, the immediate prod­ucts of gene transcription are another class of RNA molecule which are quite large and heterogeneous in size. These hetero­geneous nuclear RNA (HnRNA) may ex­ceed 107 Daltons whereas the mRNA mol­ecules are generally smaller than 2 x 106 Daltons. These HnRNA molecules are proc­essed to generate the mRNA molecules which then enter the cytoplasm to serve as templates for protein synthesis.

b. The Transfer RNA (tRNA) or Soluble RNA (sRNA):

i. The transfer RNA molecules amount to 10 to 20 per cent, of the total cellular RNA molecules.

ii. They consist of about 75 nucleotides and have molecular weight of 25,000.

iii. There are at least 20 tRNA molecules in every cell, one corresponds to each of the 20 amino acids required for protein syn­thesis.

iv. They serve as adaptors for the translation of the information in the sequence of nucleotides of the mRNA into specific amino acids.

v. The primary structure allows extensive folding and intrastrand complementarity to generate a significant secondary struc­ture which appears like a cloverleaf as in Fig. 8.7.

vi. All tRNA molecules have a common CCA sequence at the 3′ termini. The carboxyl groups of amino acids are attached to the 3′-hydroxyl group of the adenosyl moi­ety through an ester bond.

vii. The anticodon loop at the end of a base- paired stem recognizes the triplet nucle­otide or codon of the template mRNA.

viii. In nearly all tRNA molecules, there is a loop containing the nucleotides of ribothymine and pseudouridine for bind­ing amino acyl tRNA by ribosome and another loop containing the minor base dihydrouracil recognition of tRNA.

ix. They are quite stable in prokaryotes and less stable in eukaryotes.

c. The Ribosomol RNA (rRNA):

i. Ribosomes are nucleoprotein particles and reticular granules of 100-150A, in diam­eter which act as the machinery for the synthesis of proteins from mRNA tem­plates. They contain 80 per cent of the RNA within the cell.

ii. On the ribosomes, the mRNA and tRNA molecules interact to translate into a spe­cific protein molecule the information transcribed from the gene.

iii. Ribosomal particles are very complex. The mammalian ribosome contains 2 ma­jor nucleoprotein subunits — a larger one (60 S) and a smaller one (40 S).

iv. The 60 S subunit contains a 5 S ribosomal RNA, (rRNA), a 5.8 S rRNA and a 28 S rRNA.

v. There are also more than 50 specific polypeptides. The smaller (40 S) subunit contains a single 18 S rRNA and approxi­mately 30 polypeptide chains.

vi. The 5 S rRNA has its own precursor which is independently transcribed.

vii. In the cytoplasm, the ribosomes remain quite stable and capable of many transla­tions.

5. DNA and GENE:

a. The most important constituent of chro­mosomes is DNA. The double — stranded helix of DNA is tightly coiled in each chro­mosomes thread.

b. The unit of genetic information is the gene or cistron.

c. Gene is a segment of the DNA molecule containing about 600 base pairs. The ge­netic message is carried in the sequence of bases along the DNA strand.

d. In the process of transcription, the genetic message is transferred to the messenger RNA which carries it to the ribosomes.

e. The genes are arranged in orderly manner along the length of the DNA molecule in the chromosome.

f. Each gene for any particular characteristic has its counterpart in the corresponding locus on the homologous chromosome and these two genes form an allelic pair.

When both loci of a pair carry genes with the same characteristics, say tallness, then the individual is said to be homozygous with respect to that characteristic.

When one of the pair tallness and the other gene shortness, the individual is heterozygous.

6. Biological Importance of Nucleic Acids:

a. Nucleic acids are able to reproduce their kind or to store or express and transmit genetic information.

b. They undergo mutation.

c. In cell division, the nucleic acid chain is duplicated preserving in each daughter cell the information contained in the par­ent cell. So the double helix unravels and each of the two original strands then serves as a template for the synthesis of another complementary chain.

d. According to the “pairing rule” in DNA, adenine can only combine with thymine and guanine only with cytosine. The newly synthesized strand will be exactly constituted in its nucleotide sequence as was the original complementary strand of the parent strand. The result is the synthe­sis of two pairs of strands.

e. DNA produces a messenger RNA (mRNA) which helps in placing amino acids in the code for protein synthesis.

f. RNA functions primarily in the cytoplasm of the cell as a template in connection with the synthesis of proteins as well as in the ribosomes. The formation of RNA tem­plate is directed by nuclear DNA.

g. Ribosomal RNA (rRNA) and transfer RNA (tRNA) are also involved in protein syn­thesis.

h. RNA can be synthesized by RNA- polymerase which is dependent on the presence of DNA acting as a template.

i. Adenylic acid in combination with two molecules of phosphate is the biochemi­cal unit of energy exchange in all cells which is said to be ATP. 10. Biological oxidation-reduction involves the transport of hydrogen atoms or elec­trons through organized systems of sub­stances called hydrogen acceptors or elec­trons transport agents. The hydrogen ac­ceptors are nucleotides such as NAD, FAD etc..

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