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GENETICS OF
MICROORGANISMS
QUESTIONS OF LECTURE
• 1. Introduction
• 2. Genetics of microorganisms
• 3. Genotypic and phenotypic variations
• 4. Transmission of genetic material
GENETICS
• Genetics is the study of heredity and variation, seeking to understand the causes of the resemblances and differences between parents and their progeny
Genetics of microorganisms• The «central dogma» of molecular
biology is that DNA carries genetic information, which is transcribed on to RNA and then translated as the particular polypeptide
• (DNA - RNA - polypeptide) • An exception exists in the case of some
viruses genetic material is RNA instead of DNA
Genetics of microorganisms• The DNA molecule is composed of two chains
of nucleotides bound together in the form of a «double helix»
• Each chain has a backbone of desoxyribose and phosphate residues arranged alternately
• Attached to each desoxyribose is one of four nitrogenous bases, the purines: adenine (A) and guanine (G), and the pyrimidines: thymine (T) and cytosine (C)
• Adenine is always linked to thymine, and guanine to cytosine: A=T, G=C
Genetics of microorganisms• Genetic information is stored in the DNA as a
code, the unit of the code (codon) consisting of a sequence of three bases (the code is triplet)
• Each codon specifies for a single aminoacid, but the code is «degenerate» so that more than one codon may exist for the same aminoacid
• A segment of DNA carrying codons specifying for a particular polypeptide is called a «cistron» or gene
• The bacterial chromosome carries about 1000-4000 cistrons.
Genetics of microorganisms
Structure of operon• Lac Lac P Lac O Lac Z - Y -A• Regulator Promotor Operator Structural genes
• For transcription of RNA for the enzyme synthesis, the RNA polymerase has to attach to the promotor region and travel along the structural genes in sequence.
• The transfer of genetic information from DNA to RNA is called transcription and from RNA to protein is called translation.
Genetics of microorganisms• RNA is structurally similar to DNA except for three
major differences:• It contains the sugar ribose (desoxyribose in DNA)• One of pyrimidine base is uracile instead thymine
in DNA• There are 3 distinct types of RNA on the basis of
structure and function:• 1. Messenger RNA (m RNA)• 2. Ribosomal RNA (r RNA)• 3. Transfer RNA (t RNA)• DNA acts as the template for the synthesis of
mRNA.
Genotypic and phenotypic variations
• The sum total of genes the make up the genetic apparatus of a cell establishes its genotype.
• The phenotype («phaeno»: display) is the physical expression of the genotype in a given environment.
Genotypic and phenotypic variations
• Phenotypic variations are influenced by the environment, limited in range by the genotype, temporary and not heritable.
• Variations are genotypic when they are due to alterations in the genome. Genotypic variations are stable, heritable and not influenced by the environment.
• They may occur by mutation, or by one of the mechanisms of genetic transfer or exchange, such as transformation, transduction, lysogenic conversion and conjugation.
Mutation• Mutation is a heritable variation caused by an
alteration in the nucleotide sequence at some point of the DNA
• The sequence of nucleotides in DNA can change in either of 2 ways:
• (a) by substitution of one base pair for another as the result of a replication error – transition or transvertion.
• by breakage of the sugar phosphate back bone with subsequent deletion or insertion of a DNA segment.
MUTATIONS IN BACTERIA– Spontaneous (replication error )– Induced (mutations are induced by a variety of
physical, chemical and biological agents)Physical agents are radiations, heats etc.Chemical agents are nitroso compounds,
alkylating agents, base analogs, and others.
TRANSFORMATION
• Definition: It is the transfer of genetic information through the agency of free DNA. Pieces of DNA involved in transformation may carry 10 to 50 genes. Factors affecting transformation
– DNA size and state
– Competence of the recipient (Bacillus, Haemophilus, Neisseria, Streptococcus)
TRANSFORMATION
– Recombination
• Significance– Phase variation– Recombinant DNA technology
• Steps– Uptake of DNA
• Gram +
• Gram -
TRANSDUCTION
• Definition: Gene transfer from a donor to a recipient by way of a bacteriophage
• Bacteriophage (phage): A virus that infects bacteria
Phage Composition and Structure
• Composition– Nucleic acid
• Genome size• Modified bases
– Protein• Protection• Infection
• Structure (T4)– Size (80 X 100 nm)
– Head or capsid– Tail
Tail
Tail Fibers
Base Plate
Head/Capsid
Contractile Sheath
Infection of Host Cells by Phages
• Irreversible attachment– Base plate
• Adsorption–Tail fibers– Receptor is LPS for T4
• Nucleic acid injection
• Sheath Contraction
• DNA uptake
Microbe Library, American Society for Microbiology
www.microbelibrary.org
TRANSDUCTION
• Types of transduction
– Generalized - Transduction in which potentially any dornor bacterial gene can be transferred.
– Specialized (Restricted) - Transduction in which only certain donor genes can be transferred
Generalized Transduction
• Release of phage
• Phage replication and degradation of host DNA
• Assembly of phages particles
• Infection of recipient• Homologous recombination
• Infection of Donor
Potentially any donor gene can be transferred
BACTERIOPHAGES EXHIBIT TWO TYPES OF LIFE CYCLE:
In the virulent or lytic cycle, large numbers of progeny phages are built up inside the host bacterium, which ruptures to release them.
In the temperate or nonlytic cycle, the phage DNA becomes integrated with the bacterial chromosome as the prophage and is transferred to the daughter cells. This process is called lysogenic or phage convertion.
CONJUGATION• Definition: Gene transfer from a
donor to a recipient by direct physical contact between cells
• Mating types in bacteria– Donor
• F factor (Fertility factor) is a transfer factor that contains the genetic information necessary for the synthesis of the sex pilus and for self-transfer. Cells carrying the F factor are called F+ cells. F factor may exist in the «integrated state» or inserted into the host chromosome. Such cells are known as Hfr cells.
Donor
Recipient– Recipient• Lacks an F factor
Mechanism of F+ x F- Crosses
• DNA transfer– Origin of
transfer– Rolling circle
replication
• Pair formation
– Conjugation bridge
Microbe Library, American Society for Microbiology
www.microbelibrary.org
Transposable Genetic Elements
• Definition: Segments of DNA that are able to move from one location to another
• Properties– “Random” movement– Not capable of self replication (not a replicon)– Transposition mediated by site-specific
recombination• Transposase
– Transposition may be accompanied by duplication
Types of Transposable Genetic Elements
• Insertion sequences (IS)– Definition: Elements that carry no other genes
except those involved in transposition– Nomenclature - IS1– Structure– Importance
• Mutation
•Plasmid insertion
•Phase variation
TransposaseABCDEFG GFEDCBA
Types of Transposable Genetic Elements
• Transposons (Tn)– Definition: Elements that carry other genes
except those involved in transposition– Nomenclature - Tn10– Structure
• Composite Tns
– Importance
• Antibiotic resistance
IS ISResistance Gene(s)
IS ISResistance Gene(s)
Most of the transposons
in the genomeare stably
silenced and many of them
have been “tamed” and do
important cellular jobs
PLASMIDS• Definition:
Extrachromosomal genetic elements that are capable of autonomous replication (replicon)
• Episome - a plasmid that can integrate into the chromosome
Classification of Plasmids• Transfer properties
– Conjugative are transferred from bacterium to bacterium (usually members of the same species or of very closely related species) through conjugation
– Nonconjugative• Phenotypic effects
– Fertility (F-plasmids)– Bacteriocinogenic plasmid (Col-plasmid)– Resistance plasmid (R factors) (R-plasmid)– Enterotoxin plasmid (Ent-plasmid)– Haemolysin plasmid (Hly-plasmid)
Structure of R Factors
• RTF– Conjugative
plasmid– Transfer genes Tn 9
Tn
21
Tn 10
Tn 8
RTF
R determinant
• R determinant– Resistance genes– Transposons
Genetic Engineering• It is now possible to isolate the genes coding for any
desired protein from microorganisms and introduce them into suitable microorganisms, in which the genes would be functional directing the production of the specific protein. This is known as the Recombinant-DNA technology or Genetic engineering.
Plasmid DNA vaccination• Multivalent DNA vaccine
for malaria.
• Against tuberculosis
• Against hepatitis B virus.
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