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Microbial Genetics. Genetics – the study of heredity The science of genetics explores: Transmission of biological traits from parent to offspring Expression and variation of those traits Structure and function of genetic material How this material changes.
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Microbial Genetics Genetics – the study of heredity The science of genetics explores: • Transmission of biological traits from parent to offspring • Expression and variation of those traits • Structure and function of genetic material • How this material changes
Levels of Structure and Function of the Genome • Genome – sum total of genetic material of a cell (chromosomes + mitochondria/chloroplasts and/or plasmids) • Genome of cells – DNA • Genome of viruses – DNA or RNA
- DNA complexed with protein constitutes the genetic material as chromosomes - Bacterial chromosomes are a single circular loop - Eukaryotic chromosomes are multiple and linear
Chromosome is subdivided into genes, thefundamental unit of heredity Segment of DNA that contains the necessary code to make a protein or RNA molecule Three basic categories of genes: Genes that code for proteins – structural genes Genes that code for RNA Genes that control gene expression – regulatory genes
Genotype - the genetic makeup of an organism • Phenotype - The expression of the genotype creates observable traits
Genomes Vary in Size • Smallest virus – 4-5 genes • E. coli – single chromosome containing 4,288 genes; 1 mm; 1,000X longer than cell • Human cell – 46 chromosomes containing 31,000 genes; 6 feet; 180,000X longer than cell
DNA • Two strands twisted into a double helix • Basic unit of DNA structure is a nucleotide • Each nucleotide consists of 3 parts: • A 5 carbon sugar – deoxyribose • A phosphate group • A nitrogenous base – adenine, guanine, thymine, cytosine • Nucleotides covalently bond to form a sugar-phosphate linkage – the backbone • Each sugar attaches to two phosphates – • 5′ carbon and 3′ carbon
DNA • Nitrogenous bases covalently bond to the 1′ carbon of each sugar and span the center of the molecule to pair with an appropriate complementary base on the other strand • Adenine binds to Thymine with 2 hydrogen bonds • Guanine binds to Cytosine with 3 hydrogen bonds • Antiparallel strands 3′ to 5′ and 5′ to 3′ • Order of bases constitutes the DNA code
Significance of DNA Structure • Maintenance of code during reproduction - Constancy of base pairing guarantees that the code will be retained • Providing variety - order of bases responsible for unique qualities of each organism
DNA Replication • Making an exact duplicate of the DNA involves 30 different enzymes • Begins at an origin of replication • Helicase unwinds and unzips the DNA double helix • An RNA primer is synthesized at the origin of replication • DNA polymerase III adds nucleotides in a 5′ to 3′ direction • Leading strand – synthesized continuously in 5′ to 3′ direction • Lagging strand – synthesized 5′ to 3′ in short segments; overall direction is 3′ to 5′
DNA polymerase I removes the RNA primers and replaces them with DNA • When replication forks meet, ligases link the DNA fragments along the lagging strand to complete the synthesis • Separation of the daughter molecules is complete
DNA replication is semiconservative because each chromosome ends up with one new strand of DNA and one old strand.
Information stored on the DNA molecule is conveyed to RNA molecules through the process of transcription • The information contained in the RNA molecule is then used to produce proteins in the process of translation
Gene-Protein Connection • Each triplet of nucleotides on the RNA specifies a particular amino acid • A protein’s primary structure determines its shape and function • Proteins determine phenotype. Living things are what their proteins make them. • DNA is mainly a blueprint that tells the cell which kinds of proteins to make and how to make them
RNAs • Single-stranded molecule made of nucleotides • 5 carbon sugar is ribose (DNA has deoxyribose) • 4 nitrogen bases – adenine, uracil, guanine, cytosine
RNA • 3 types of RNA: • Messenger RNA (mRNA) – carries DNA message through complementary copy; message is in triplets called codons • Transfer RNA (tRNA) – made from DNA; secondary structure creates loops; bottom loop exposes a triplet of nucleotides called anticodon which designates specificity and complements mRNA; carries specific amino acids to ribosomes • Ribosomal RNA (rRNA) – component of ribosomes where protein synthesis occurs
Transcription: The First Stage of Gene Expression • RNA polymerase binds to promoter region upstream of the gene • RNA polymerase adds nucleotides complementary to the template strand of a segment of DNA in the 5′ to 3′ direction • Uracil is placed as adenine’s complement • At termination, RNA polymerase recognizes signals and releases the transcript • 100-1,200 bases long
Translation: The Second Stage of Gene Expression • All the elements needed to synthesize protein are brought together on the ribosomes • The process occurs in five stages: initiation, elongation, termination, and protein folding and processing
The Genetic Code • Represented by the mRNA codons and the amino acids they specify • Code is universal • Code is redundant
Translation • Ribosomes assemble on the 5′ end of an mRNA transcript • Ribosome scans the mRNA until it reaches the start codon, usually AUG • A tRNA molecule with the complementary anticodon and methionine amino acid enters the P site of the ribosome and binds to the mRNA
Translation • A second tRNA with the complementary anticodon fills the A site • A peptide bond is formed • The first tRNA is released and the ribosome slides down to the next codon • Another tRNA fills the A site and a peptide bond is formed • This process continues until a stop codon is encountered
Translation Termination • Termination codons – UAA, UAG, and UGA – are codons for which there is no corresponding tRNA • When this codon is reached, the ribosome falls off and the last tRNA is removed from the polypeptide
Prokaryotic transcription and translation Polyribosomal complex allows for the synthesis of many protein molecules simultaneously from the same mRNA molecule.
Eukaryotic Transcription and Translation • Do not occur simultaneously – transcription occurs in the nucleus and translation occurs in the cytoplasm • Eukaryotic start codon is AUG, but it does not use formyl-methionine • Eukaryotic mRNA encodes a single protein, unlike bacterial mRNA which encodes many • Eukaryotic DNA contains introns – intervening sequences of noncoding DNA – which have to be spliced out of the final mRNA transcript
Regulation of Protein Synthesis and Metabolism • Genes are regulated to be active only when their products are required • In prokaryotes this regulation is coordinated by operons, a set of genes, all of which are regulated as a single unit
Operons • 2 types of operons: • Inducible – operon is turned ON by substrate: catabolic operons - enzymes needed to metabolize a nutrient are produced when needed • Repressible – genes in a series are turned OFF by the product synthesized; anabolic operon –enzymes used to synthesize an amino acid stop being produced when they are not needed
Lactose Operon: Inducible Operon Made of 3 segments: • Regulator – gene that codes for repressor • Control locus – composed of promoter and operator • Structural locus – made of 3 genes each coding for an enzyme needed to catabolize lactose – b-galactosidase – hydrolyzes lactose permease – brings lactose across cell membrane b-galactosidase transacetylase – uncertain function
Lac Operon • Normally off • In the absence of lactose, the repressor binds with the operator locus and blocks transcription of downstream structural genes • Lactose turns the operon on • Binding of lactose to the repressor protein changes its shape and causes it to fall off the operator. RNA polymerase can bind to the promoter. Structural genes are transcribed.
Arginine Operon: Repressible • Normally on and will be turned off when the product of the pathway is no longer required • When excess arginine is present, it binds to the repressor and changes it. Then the repressor binds to the operator and blocks arginine synthesis.
Mutations: Changes in the Genetic Code • A change in phenotype due to a change in genotype (nitrogen base sequence of DNA) is called a mutation • A natural, nonmutated characteristic is known as a wild type (wild strain) • An organism that has a mutation is a mutant strain, showing variance in morphology, nutritional characteristics, genetic control mechanisms, resistance to chemicals, etc.
Causes of Mutations • Spontaneousmutations – random change in the DNA due to errors in replication that occur without known cause • Induced mutations – result from exposure to known mutagens, physical (primarily radiation) or chemical agents that interact with DNA in a disruptive manner
Categories of Mutations • Point mutation – addition, deletion, or substitution of a few bases • Missense mutation – causes change in a single amino acid • Nonsense mutation – changes a normal codon into a stop codon • Silent mutation – alters a base but does not change the amino acid
Categories of Mutations • Back-mutation – when a mutated gene reverses to its original base composition • Frameshift mutation – when the reading frame of the mRNA is altered
Repair of Mutations • Since mutations can be potentially fatal, the cell has several enzymatic repair mechanisms in place to find and repair damaged DNA • DNA polymerase – proofreads nucleotides during DNA replication • Mismatch repair – locates and repairs mismatched nitrogen bases that were not repaired by DNA polymerase • Light repair – for UV light damage • Excision repair – locates and repairs incorrect sequence by removing a segment of the DNA and then adding the correct nucleotides