Microbial Genetics Molecular Biology

MICROBIAL GENETICS – MOLECULAR BIOLOGY

DNA REPLICATION AND GENE EXPRESSION

The genetics of the cell encompass the replication and expression of the cell’s hereditary information. The hereditary information of all living cells is encoded in the cell’s deoxyribonucleic acid molecule(s) (DNA). The information within the DNA determines the metabolic and structural nature of the organism. The double helical nature of the DNA macromolecule is critical for its replication. The revelation of the DNA double helix by James Watson and Francis Crick in 1953 revolutionized biology. This discovery of the structure of DNA quickly revealed how hereditary information is transmitted from one generation to the next.

Replication of the hereditary information of a cell involves synthesizing new DNA molecules that have the same nucleotide sequence as the genome of the parental organism, a process that requires great precision (Replication = DNA DNA). The genome of the progeny must contain the appropriate information to permit the survival and growth of the organism. Because changes in the sequence of nucleotides can alter the characteristics of an organism considerably, the process of DNA replication is designed to ensure that the progeny receive an accurate copy of the genetic information of the parent cell.

Expression of genetic information involves using information encoded within the DNA to direct the synthesis of proteins. DNA contains regulatory genes that control gene expression. By specifying and regulating protein synthesis, the genetic informational macromolecules define and control the metabolic capabilities of microorganisms. The order of nucleotides in the DNA is used to specify the order of amino acids in a protein. The information in the DNA molecule is initially transferred to ribonucleic acid (RNA) molecules in a process called transcription (Transcription = DNA RNA). The message encoded in the mRNA molecule is then translated into the sequence of amino acids that comprise the protein (Translation = RNA protein).

DNA (DEOXYRIBONUCLEIC ACID)

DNA is the macromolecule that stores the hereditary information of the cell. It is composed of subunits, called nucleotides that are like the letters of the “genetic alphabet”. The order of the nucleotides specifies the genetic information of the cell and contains the mechanisms for controlling genetic expression. As such, DNA is sometimes called the “master molecule”. The sequence of nucleotides within the DNA molecule encodes all the potential properties of that cell by determining the sequence of amino acids in a particular protein. This is like saying that the arrangement and number of letters used to create a word define its meaning. The genetic code, based on only the “few letters” (nucleotides) in its “alphabet”, provides the necessary chemical basis for encoding the genetic information and thus creating the great diversity of living organisms.

Deoxyribonucleotides

DNA macromolecules are made up of numerous subunits called deoxyribonucleotides. These deoxyribonucleotides often are referred to as nucleotides, a genetic term that also describes the ribonucleotides in RNA. Each deoxyribonucleotide consists of a nucleic acid base, the sugar deoxyribose, and phosphate.

Four different nucleic acid bases occur in the nucleotides of DNA: adenine, guanine, cytosine, and thymine. Adenine (A) and guanine (G) are purines, which are moleclules composed of two fused rings. Cytosine (C) and thymine (T) are pyrimidines, which have only one ring. Purines and pyrimidines are heterocyclic molecules: their rings contain two kinds of atoms, carbon and nitrogen, instead of just carbon. The nucleic acid bases are attached to the deoxyribose sugars to form deoxyribonucleosides, and the deoxyribonucleosides are joined to a phosphate group on carbon 5′ of the sugar to form the deoxyribonucleotide subunits of DNA.

GENETIC MUTATION, RECOMBINATION, AND MAPPING

Changes in the sequence of nucleotides of a cell’s DNA occur by mutation (from the Latin word mutare, meaning to change). Various types of mutations introduce modifications into DNA with varying degrees of frequency. Mutations produce multiple allelic forms of the same gene and recombinational processes permit further redistribution of genetic information. (Alleles: corresponding forms of a gene. When both copies of the gene are identical, the cell is homozygous. When the corresponding copies of the gene differ, the cell is heterozygous). Recombination involves exchange of DNA segments from differing genomes. This establishes new combinations of genes. Heritable changes in the sequence of nucleotides of cells introduce variability into the gene pool of microbial populations. Genetic variability typically occurs within a population or within cells of a given organism. The genes of one bacterial cell may differ slightly, for example, from the genes of another bacterial cell within the same species. Heterogeneity within the gene pool may give some organisms a competitive advantage for survival. This forms the basis for evolution according to the Darwinian principle of survival of the fittest. Diversity within the gene pool establishes the basis for the selective evolution of microorganisms. Recombinant DNA technology also permits the directed formation of cells with specific genes that may come from divergent sources.

Names of the most common bases in DNA and RNA and corresponding names of nucleosides and nucleotides containing these bases.

Nucleic acid base / Nucleoside / Nucleotide
Adenine (DNA or RNA) / Adenosine / Adenylate (or adenylic acid)
Cytosine (DNA or RNA) / Cytidine / Cytidylate (or cytidylic acid)
Guanine (DNA or RNA) / Guanosine / Guanylate (or guanylic acid)
Thymine (DNA) / Thymide / Thymidylate (or thymidylic acid)
Uracil (RNA) / Uridine / Uridylate (or uridylic acid)

MUTATIONS

A mutation is a heritable change in the nucleotide sequence of a cell’s DNA. Changes in the cell’s hereditary molecules sometimes occur as a result of mistakes made during DNA replication. These mutations sometimes occur during DNA replication despite the mechanisms that are designed to ensure the fidelity of the process, which includes the proofreading activities of DNA polymerases.

Types of mutations

1. Base substitutions

A base substitution mutation occurs when one pair of nucleotide base in the DNA is replaced by another.

1. Missense mutations

Type of a base substitution that results in the change in the amino acid inserted into the polypeptide chain specified by the gene in which the mutation occurs.

1. Silent mutations

Mutations that do not alter the phenotype of an organism and therefore go undetected.

1. Nonsense mutation

A mutation in which a codon specifying an amino acid is altered to a nonsense codon.

1. Polor mutations

Mutations that prevent the translation of subsequent polypeptides coded for in the same mRNA molecule.

1. Suppressor mutation

A mutation that alleviates the effects of an earlier mutation at a different locus.

1. Lethal mutations

Mutations that result in the death of a microorganism or its inability to reproduce.

1. Nutritional mutations

Mutations that alter the nutritional requirements of the progeny of a microorganism.

RECOMBINATION

Recombination occurs when there is an exchange of genetic information among different DNA molecules that results in a reshuffling of genes. This process can produce numerous new combinations of genetic information. Recombination of genetic information from two different cells produces progeny that contain genetic information derived from two potentially different genomes.

Recombinant DNA technology

Recombinant DNA technology is the intentional recombination of genes from different sources by artificial means. This is the basis for the creation of new genetic varieties of organisms, which is known a genetic engineering. It is the foundation of the “biotechnological revolution.”

Genetic engineering uses enzymes to cut out target genes and to join DNA to form recombinant DNA that may come from diverse sources; for example, bacterial and human DNA can be combined in a recombinant DNA molecule by genetic engineering. Bacterial production of Human Insulin comes as a result of genetic engineering. Human insulin (humulin) is produced by recombinant strains of Escherichia coli. One recombinant strain is genetically engineered to produce the A protein and a second recombinant strain, the B protein. The two proteins are then chemically combined to produce commercial humulin. The humulin produced functions as normal human insulin.

Genetic engineering holds great promise in industry and medicine because various proteins of economic importance or use in curing disease may be produced. However, the potential of genetic engineering to short-circuit evolution has raised numerous ethical, legal, and safety questions. Concerning the development of genetically engineered organisms designed for deliberate release into the environment, the questions of whether novel genomes will survive in the environment, whether they will transfer to other microorganisms and spread, and whether this dissemination could represent a serious biological hazard to human health and the environment are being actively debated.

In spite of the stated concern, there is little question that through genetic engineering the quality of human life can be improved. Therefore, one must weigh these ethical questions against the benefits that can be derived through genetic engineering.

GENETIC AND PHYSICAL MAPPING

Recombinants formed from different allelic forms of multiple genes can be used to determine the relative locations of genes on a chromosome, thus producing a genetic map of the chromosome. Genetic mapping is based on recombinational frequency analysis that reveals new combinations of alleles that contain mutations (genetic differences between the alleles). The extent of recombination between genes on the same chromosome, for example, on a bacterial chromosome, can be used to establish a genetic map. The occurrence of recombinants that result from mating is used to establish a map showing the order and relative locations (loci) of genes.

The map distance between two genes is given by the formula:

Map distance = number of recombinants x 100

Total number of progeny