Gene, genetic code and regulation of the gene expression ......•Lactose & tryptophan metabolism...
Transcript of Gene, genetic code and regulation of the gene expression ......•Lactose & tryptophan metabolism...
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Gene, genetic code and regulation of the gene expression, Regulating the Metabolism, The Lac-
Operon system,Catabolic repression, The Trp Operon system: regulating the biosynthesis of the tryptophan.
Mitesh Shrestha
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The Gene
The gene; it is a segment within a very long strand of
DNA.
Genes are the basic units of hereditary.
Genes located on chromosome on its place or locus.
Allele; a variant of the DNA sequence at a given
locus. Each allele inherited from a different parent.
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The Gene
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Dominant and Recessive
• Dominant
The one pair of allele that masks the effect of the other when present in the same cell.
• Recessive
The one pair of allele that is masked by the other when present in the same cell and capable of producing its characteristics phenotype in the organism only when two alleles is present and identical.
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Dominant and Recessive
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From Genes to Proteins
DNA
mRNA
Protein
Gen
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Structure of prokaryotic genes 1
The prokaryotic genomes have a very high gene density: on average, the proteincoding genes occupy 85% of the genome In addition, the prokaryotic genes are not interrupted by introns and are sometimes organized in transcriptional polycistronic units (leading information related to several genes), called operons The high plasticity of prokaryotic genomes is reflected by the fact that the order of genes along the genome is poorly conserved among different species and taxonomic groups Therefore, groups of contiguous genes contained in a single operon in a certain genome can be dispersed in another
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The structure of prokaryotic genes is normally quite simple
Just as we rely on punctuation to decipher the information contained in a written text, proteins, responsible for gene expression, search for a recurring set of signals associated with each gene
Structure of prokaryotic genes 2
Operator: a DNA segment to which a transcription factor binds to regulate the gene expression
Promoter
Translation end site (UAA, UAG, UGA)
Transcription end site
Translation start site (AUG)
Transcription start site
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These genomic punctuation marks and their sometimes subtle changes, allow to
distinguish between genes that must be expressed identify the beginning and the end of the regions that must be copied into RNA demarcate the beginning and the end of the RNA regions that ribosomes must translate into proteins
Such signals are represented by short strings of nucleotides, which constitute only a small fraction of the hundreds/thousands of nucleotides necessary to encode the amino acid sequence of a protein
Structure of prokaryotic genes 3
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Prokaryotic gene density 1
The density of prokaryotic genes is very high The chromosomes of bacteria and archaea completely sequenced indicate that from 85% to 88% of the nucleotides are associated with coding regions
Example: E.coli contains a total of 4288 genes, with
coding sequences which are long, on average, 950 base pairs and separated, on average, from 118 bases
In addition, prokaryotic genes are not interrupted by introns and are organized in polycistronic transcriptional units (operons)
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The number of genes and the genome size reflect the bacterium style of life
The specialized parasites have about 500600 genes, while the generalist bacteria have a much greater number of genes, typically between 4000 and 5000 The Archea have a number of genes between 1700 and 2900
A rapid reproduction phase is important for the evolutionary success of bacteria
Maximize the coding efficiency of the chromosomes to minimize the time of DNA replication during cell division
Prokaryotic gene density 2
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Finding a gene in a prokaryotic genome is just a simple task
Simple promoter sequences (a small number of factors that support RNA polymerase in the recognition of the promoter sequences placed in 35 and 10) Transcription termination signals simply recognizable (inverted repeats followed by a sequence of uracils) Possible comparison with the nucleotide or amino acid sequences of other well known organisms
High probability that any randomly chosen nucleotide is associated with the coding sequence or with the promoter of an important gene The genome of prokaryotes contains no “wasted space”
Prokaryotic gene density 3
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Gene Structure
• Most of the genes consist of; short coding
sequences or exons are interrupted by a longer
intervening noncoding sequence or introns;
although a few genes in the human genome
have no introns.
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Gene Structure
Eukaryotic gene structure: Most eukaryotic genes in
contrast to typical bacterial genes, the coding
sequences (exons) are interrupted by noncoding DNA
(introns). The gene must have (Exon; start signals;
stop signals; regulatory control elements).
The average gene 7-10 exons spread over 10-16kb of
DNA.
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Eukaryotic gene structure 1
By definition, among the most difficult search problems, there is the classic “find a needle in a haystack” This old analogy is far from being sufficient to give an idea of the complexity of finding eukaryotic genes within the huge amounts of sequence data
Actually, finding a needle of 2 grams inside 6000 kilos of straw is thousand times easier than finding a gene in the eukaryotic genome, even assuming that such a gene is so different from the rest of the DNA as it is a needle from a piece of straw
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In fact… Eukaryotic genomes have a very low gene density: on average, the proteincoding genes occupy only 24% of the entire genome The peculiarities of prokaryotic ORFs, with their statistically significant lengths, are not found in eukaryotic genes, due to the abundant presence of introns (which in mammals can reach sizes around 2030 Kb) and repeated elements Eukaryotic promoters, like their prokaryotic counterparts, contain, in their sequence, some preserved characteristics, that can be used as reference points in gene search algorithms
However, such sequences tend to be much more dispersed and positioned at a great distance from the transcription start site
Eukaryotic gene structure 2
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Comparison among human, yeast, fruit fly, maize, and E.coli genomes
Eukaryotic gene structure 3 Man
Saccharomyces cerevisiae
Drosophila melanogaster
Maize
Escherichia coli
MAP LEGEND
Gene Intron tRNA gene Extended repetitions Human pseudo-gene
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1
10
100
1000
10000
100000
human mouse chicken xenopus zebrafish fugu c iona fly worm yeast
Gene number Genome s ize (Mb)
Number of genes in prokaryotes (up to 8000)
Genome size in prokaryotes (up to 9 Mb)
The absence of correlation between the number of genes and the genome size in eukaryotes
Eukaryotic gene structure 4
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The problem of recognizing eukaryotic genes in sequence data is therefore a great challenge, which promises to remain such for some future decades So far, the best attempts to solve the problem are based on the use of pattern recognition techniques (such as neural networks and Generalized Hidden Markov Models) and on dynamic programming
In Internet, free software is available, such as Grail EXP or GenScan (http://genes.mit.edu/GENSCAN.html), that, however, shows low performances
Eukaryotic gene structure 5
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All the algorithms for the recognition of genes scan the DNA sequence to search particular
nucleotide strings, having ad hoc orientations and
relative positions Any feature, in itself, could be detected at random, but the simultaneous presence of more “markers”, such as possible promoters, sequences that indicate the vicinity of introns and exons, and a putative ORF with codons not uniformly distributed, increases the probability that a given region corresponds to a gene
Eukaryotic gene structure 6
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Eukaryotic gene density 1
22
The Cvalue paradox made it clear that much of the
eukaryotic genome is unnecessary many decades before that molecular biologists have provided the complete nucleotide sequence of several genomes
The human genome project has largely confirmed the hypothesis underlying that paradox:
Out of the 3200Mb of the human genome, not more than 90Mb (less than 3%) corresponds to coding sequences and, approximately, 820Mb (26%) corresponds to sequences associated with them (introns, promoters, pseudogenes)
The remaining 2300Mb are divided into two kinds of “junk” (subject to any selective constraint): low copied or unique sequences (1680Mb, 52%) and repeated DNA (620MB, 19%)
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Eukaryotic gene density 2
23
Human genome 3200 MB
Genes and related sequences 900 MB 29%
Extragenic DNA 2300 MB 71%
Coding DNA 90 MB 3%
Non-coding DNA 810 MB 26%
Pseudogenes Introns Leaders, Trailers
Repetitive DNA 620 MB 19%
Low copy or unique DNA 1680 MB 52%
Tandemly repeated DNA Interspersed repeats
Satellite Microsatellite Minisatellite
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24
Genes are far from each other, even in those regions of complex eukariots that are particularly rich of coding information, as the H3 isochore of the human genome
The average distance between human genes is around 65,000 base pairs, approximately equal to 10% of the genome size of a simple prokaryotic organism
Moreover:
Mutational analyses have revealed that many genes encode proteins that perform multiple functions
Many genes are present in multiple, redundant copies
Simple eukaryotes tend to have a higher density of genes compared to more complex organisms, such as vertebrates
Eukaryotic gene density 3
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The Genetic Code
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The Genetic Code
The triplet sequence of mRNA that specify certain amino acid.
64 different combination of bases; 61 of them code for 20 amino acids (AA); the last three codon (UAG,UGA,UAA) don not code for amino acids; they are termination codons.
Degenerate
More than on triplet codon specify the same amino acid.
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The Genetic Code
Unambiguous
Each codon specifies a particular amino acid, the codon ACG codes for the amino acid threonine, and only threonine.
Non overlapping
This means that successive triplets are read in order. Each nucleotide is part of only one triplet codon.
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DNA Codon RNA Codon
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Gene Expression
The process by which a gene's information is converted
into the structures and functions of a cell by a process of
producing a biologically functional molecule of either
protein or RNA (gene product) is made.
Gene expression is assumed to be controlled at various
points in the sequence leading to protein synthesis.
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Gene Expression
Transcription
Synthesis of an RNA that is complementary to one of
the strands of DNA.
Translation
Ribosomes read a messenger RNA and make protein
according to its instruction.
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Control of Gene Expression
Transcriptional
Posttranscriptional
Translational
Posttranslational
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Control of Gene Expression
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Control of gene expression depends various factors including:
Chromosomal activation or deactivation.
Control of initiation of transcription.
Processing of RNA (e.g. splicing).
Control of RNA transport.
Control of mRNA degradation.
Control of initiation of translation (only in eukaryotes).
Post-translational modifications.
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Regulation of Metabolism
• Multiple genes are expressed in a single gene expression
• trp operon
– Trytophan
– Synthesis
• Lac operon
– Lactose
– Degradation
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Regulation of Metabolism
• Lactose & tryptophan metabolism
• Adjustment by bacteria
• Regulates protein synthesis
• Response to environment
• Negative control of genes
• Operons turned off by active repressors
• Tryptophan repressible operon
• Lactose inducible operon
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lac Operon
• Lactose
• Sugar used for energy
• Enzymes needed to break it down
• Lactose present
• Enzymes are synthesized
• Induced
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lac Operon
• lac Operon
• Promoter
• Operator
• Genes to code for enzymes
• Metabolize (break down) lactose
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lac Operon
• Lactose is present
• Repressor released
• Genes expressed
• Lactose absent
• Repressor binds DNA
• Stops transcription
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lac Operon
• Allolactose:
• Binds repressor
• Repressor releases from DNA
• Inducer
• Transcription begins
• Lactose levels fall
• Allolactose released from repressor
• Repressor binds DNA blocks transcription
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Fig. 18-4a
(a) Lactose absent, repressor active, operon off
DNA
Protein Active repressor
RNA polymerase
Regulatory
gene
Promoter
Operator
mRNA 5
3
No RNA made
lacI lacZ
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(b) Lactose present, repressor inactive, operon on
mRNA
Protein
DNA
mRNA 5
Inactive repressor
Allolactose (inducer)
5
3
RNA polymerase
Permease Transacetylase
lac operon
-Galactosidase
lacY lacZ lacA lacI
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lac Operon
• Activators:
• Bind DNA
• Stimulate transcription
• Involved in glucose metabolism
• lac operon
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lac Operon
• Activator:
• Catabolite activator protein (CAP)
• Stimulates transcription of operons
• Code for enzymes to metabolize sugars
• cAMP helps CAP
• cAMP binds CAP to activate it
• CAP binds to DNA (lac Operon)
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lac Operon
• Glucose elevated cAMP low
• cAMP not available to bind CAP
• Does not stimulate transcription
• Bacteria use glucose
• Preferred sugar over others.
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lac Operon
• lac operon
• Regulated by positive & negative control
• Low lactose
• Repressor blocks transcription
• High lactose
• Allolactose binds repressor
• Transcription happens
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lac Operon
• lac operon
• Glucose also present
• CAP unable to bind
• Transcription will proceed slowly
• Glucose absent
• CAP binds promoter
• Transcription goes quickly
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Promoter
DNA Operator
Promoter DNA
CAP-binding site
cAMP
Active
CAP
Inactive
CAP
RNA
polymerase
binds and
transcribes
lac I
lac I
Allolactose
Inactive lac
repressor
(a) Lactose present, glucose scarce (cAMP level high):
abundant lac mRNA synthesized
lacZ
lacZ
CAP-binding site RNA
polymerase less
likely to bind
Operator
Inactive
CAP Inactive lac
repressor
(b) Lactose present, glucose present (cAMP level low):
little lac mRNA synthesized
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trp Operon
• trp Operon:
• Control system to make tryptophan
• Several genes that make tryptophan
• Regulatory region
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Polypeptide subunits that make up enzymes for tryptophan synthesis
mRNA 5 RNA polymerase
Promoter
trp operon
Genes of operon
Operator
Stop codon Start codon mRNA
trpA 5
trpE trpD trpC trpB
A B C D E
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trp Operon
• ⇧ tryptophan present
• Bacteria will not make tryptophan
• Genes are not transcribed
• Enzymes will not be made
• Repression
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trp Operon
• Repressors
• Proteins
• Bind regulatory sites (operator)
• Prevent RNA polymerase attaching to promoter
• Prevent or decrease the initiation of transcription
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trp Operon
• Repressors
• Allosteric proteins
• Changes shape
• Active or inactive
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trp Operon
• ⇧ tryptophan
• Tryptophan binds the trp repressor
• Repressor changes shape
• Active shape
• Repressor fits DNA better
• Stops transcription
• Tryptophan is a corepressor
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(b) Tryptophan present, repressor active, operon off
Tryptophan (corepressor)
No RNA made
Active repressor
mRNA
Protein
DNA
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trp Operon
• ⇩ tryptophan
• Nothing binds the repressor
• Inactive shape
• RNA polymerase can transcribe
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Polypeptide subunits that make up enzymes for tryptophan synthesis
(a) Tryptophan absent, repressor inactive, operon on
DNA
mRNA 5
Protein Inactive repressor
RNA polymerase
Regulatory gene
Promoter Promoter
trp operon
Genes of operon
Operator
Stop codon Start codon
mRNA
trpA
5
3
trpR trpE trpD trpC trpB
A B C D E
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Regulation of gene expression
trpE gene
trpD gene
trpC gene
trpB gene
trpA gene
(b) Regulation of enzyme production
(a) Regulation of enzyme activity
Enzyme 1
Enzyme 2
Enzyme 3
Tryptophan
Precursor
Feedback
inhibition