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DNA & Protein Synthesis. From Gene to Protein. Nucleic Acids and Protein Synthesis. All functions of a cell are directed from some central form of information (DNA). This "biological program" is called the Genetic Code . - PowerPoint PPT Presentation
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DNA & Protein DNA & Protein SynthesisSynthesis
From Gene to ProteinFrom Gene to Protein
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Nucleic Acids and Protein Nucleic Acids and Protein SynthesisSynthesis
• All functions of a cell are All functions of a cell are directed from some central directed from some central form of information form of information (DNA).(DNA).
• This "biological program" is This "biological program" is called the called the Genetic CodeGenetic Code..
• This is the way cells This is the way cells store store informationinformation regarding their regarding their structure and function.structure and function.
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History of DNAHistory of DNA
Composition and Composition and StructureStructure
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HistoryHistory• For years the source of heredity For years the source of heredity
was unknown. This was resolved was unknown. This was resolved after numerous studies and after numerous studies and experimental research by the experimental research by the following researchers:following researchers:
• Fredrick GriffithFredrick Griffith– He was studying effects of He was studying effects of 22
strains of an infectious bacteriastrains of an infectious bacteria, , the "the "smoothsmooth" strain was found to " strain was found to cause pneumonia & death in mice. cause pneumonia & death in mice. The " The "roughrough" strain did not. He " strain did not. He conducted the following conducted the following experimentexperiment
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Griffith ExperimentGriffith ExperimentBacteria Strain Bacteria Strain injected into injected into
mousemouse
ResultResult
Smooth StrainSmooth Strain Mouse Mouse diesdies
Rough strainRough strain Mouse Mouse LivesLives
Heat-Killed Smooth Heat-Killed Smooth strainstrain
Mouse Mouse liveslives
Rough Strain & Heat Rough Strain & Heat killed smooth strainkilled smooth strain
*MOUSE *MOUSE DIES*DIES*•The The last condition was
unusual, as he predicted as he predicted that the mouse should livethat the mouse should live•Concluded that some Concluded that some unknown substance was unknown substance was TransformingTransforming the rough the rough strain into the smooth onestrain into the smooth one
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Avery, McCarty & MacLeodAvery, McCarty & MacLeodWas it protein Was it protein or DNA?or DNA?
•They Degraded chromosomes with enzymes that destroyed proteins or DNA•The Samples with Proteins destroyed would still cause transformation in bacteria indicating genetic material was DNA
Tried to determine the nature of this transforming agent.
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Hershey-ChaseHershey-Chase • ONE virus was ONE virus was
radioactivelyradioactively "tagged" with "tagged" with 3232P on P on it's DNAit's DNA
• The OTHER was The OTHER was "tagged" "tagged" 3535S on it's S on it's protein coat.protein coat.
• Researchers found the Researchers found the radioactive P in the radioactive P in the bacteria, bacteria, indicating it indicating it is DNA, not protein is DNA, not protein being injected into being injected into bacteriabacteria. .
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Watson & CrickWatson & Crick• The constituents of DNA The constituents of DNA
had long been known. had long been known. Structure of DNA, Structure of DNA, however was nothowever was not..
• In In 1953, Watson & Crick1953, Watson & Crick published findings published findings based on based on X-ray analysis X-ray analysis (Rosalind Franklin(Rosalind Franklin) and ) and other data that DNA was other data that DNA was in the form of a "Double in the form of a "Double Helix". Helix".
• Their findings show us Their findings show us the basic structure of the basic structure of DNA which is as follows.DNA which is as follows.
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DNA StructureDNA StructureThe Double HelixThe Double Helix
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DNA StructureDNA Structure
DNA is Formed of in a "DNA is Formed of in a "Double HelixDouble Helix" - like " - like a spiral staircase a spiral staircase
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NucleotidesNucleotides• DNA is formed DNA is formed
by by NucleotidesNucleotides• These are made These are made
from three from three components:components:1.1.5-Carbon or 5-Carbon or
pentose Sugarpentose Sugar2.2.Nitrogenous Nitrogenous basebase3.3. PhosphatePhosphate group group
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Types of NucleotidesTypes of Nucleotides• For DNA There are 4 different Nucleotides
categorized as either Purines (Double rings) or Pyrimidines (Single ring). These are usually represented by a letter. They Are:1. Adenine (A)2. Cytosine (C)3. Guanine (G)4. Thymine (T)
Guanine
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Base PairingBase Pairing• Each Each "Rung""Rung" of the DNA "staircase" is formed by the linking of 2 of the DNA "staircase" is formed by the linking of 2
Nucleotides through Nucleotides through Hydrogen BondsHydrogen Bonds..• These Hydrogen bonds form only between specific Nucleotides. This is These Hydrogen bonds form only between specific Nucleotides. This is
known as known as Base PairingBase Pairing. The rules are as follows:. The rules are as follows:– Adenine (A) will ONLY bond to Thymine (T) (by 2 hydrogen Adenine (A) will ONLY bond to Thymine (T) (by 2 hydrogen
bonds)bonds)– Cytosine (C) will ONLY bond to Guanine (G) (by 3 hydrogen Cytosine (C) will ONLY bond to Guanine (G) (by 3 hydrogen
bonds)bonds)
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Central Dogma of Central Dogma of GeneticsGenetics
DNA to Protein DNA to Protein SynthesisSynthesis
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Central Dogma of GeneticsCentral Dogma of Genetics• Central DogmaCentral Dogma holds that genetic information is expressed holds that genetic information is expressed
in a specific order. This order is as followsin a specific order. This order is as follows
There are some apparent exceptions to this.There are some apparent exceptions to this.Retroviruses (eg. HIV) are able to synthesize Retroviruses (eg. HIV) are able to synthesize
DNA from RNADNA from RNA
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DNA ReplicationDNA Replication• DNA has unique DNA has unique ability to ability to
make copies of itselfmake copies of itself• The process is called The process is called DNA DNA
Replication.Replication.• First, the enzyme First, the enzyme HelicaseHelicase
unwinds the parental DNAunwinds the parental DNA• DNA DNA "Unzips itself""Unzips itself" by by
breaking the weak hydrogen breaking the weak hydrogen bonds between base pairs bonds between base pairs forming two forming two TEMPLATE TEMPLATE strands strands with exposed Nucleotideswith exposed Nucleotides
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DNA ReplicationDNA Replication• The place where helicase The place where helicase
attaches and opens DNA is attaches and opens DNA is called the called the Replication ForkReplication Fork
REPLICATION FORKREPLICATION FORK
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DNA ReplicationDNA Replication• Helicase enzymes may Helicase enzymes may attach attach
to multiple sites on the DNA to multiple sites on the DNA strandstrand forming forming Replication Replication BubblesBubbles which makes which makes replication fasterreplication faster
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DNA ReplicationDNA Replication• Single-strand binding proteinsSingle-strand binding proteins
attach & STABILIZE the 2 attach & STABILIZE the 2 parental strandsparental strands
• DNA polymeraseDNA polymerase attaches to attaches to the 3’ end of the 5’ to 3’ the 3’ end of the 5’ to 3’ parental strandparental strand
• DNA polymerase attaches DNA polymerase attaches FREE FREE nucleotides to the nucleotides to the complementary nucleotidecomplementary nucleotide on on the parental DNA the parental DNA
• This new strand is synthesized This new strand is synthesized continuously 5’ to 3’ continuously 5’ to 3’ (LEADING)(LEADING)
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Replication BubbleReplication Bubble
Origin of Replication
Origin of Replication
DNA is synthesized from the Origin of Replication within a replication bubble
•Towards fork – continuous replication•Away from fork – discontinuous replication (fragments)
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DNA ReplicationDNA ReplicationSince Since DNA DNA
polymerase can polymerase can only add only add nucleotides to the nucleotides to the 3’3’ end of the end of the parental strand, parental strand, the parental 5’ to the parental 5’ to 3’ strand must be 3’ strand must be replicated in replicated in fragmentsfragments that that must later be must later be joined together joined together (LAGGING)(LAGGING)
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DNA ReplicationDNA Replication• Transcription proceeds Transcription proceeds
continuouslycontinuously along the 5' along the 5'3' 3' direction (This is called the direction (This is called the leading strand)leading strand)
• Proceeds in Proceeds in fragmentsfragments in the in the other direction (called the other direction (called the lagging strandlagging strand) in the ) in the following wayfollowing way
• RNA primer is attached to a RNA primer is attached to a segment of the strand by the segment of the strand by the enzyme enzyme primaseprimase..
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DNA ReplicationDNA Replication• Transcription now continues Transcription now continues
in the 5'in the 5'3' direction forming 3' direction forming an an okazakiokazaki fragmentfragment. Until it . Until it reaches the next fragment.reaches the next fragment.
• The two fragments are joined The two fragments are joined by the enzyme by the enzyme DNA ligaseDNA ligase
• Two, new, identical Two, new, identical DNA DNA strands are now formedstrands are now formed
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DNA ReplicationDNA Replication
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Protein SynthesisProtein SynthesisTranscription and Transcription and
TranslationTranslation
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RNA TranscriptionRNA Transcription• The The cell does not directly use cell does not directly use
DNA to control the function DNA to control the function of the cell.of the cell.
• DNA is too precious and must be DNA is too precious and must be kept protected within the kept protected within the nucleus.nucleus.
• The The Cell makes a working Cell makes a working "Photocopy" of itself"Photocopy" of itself to do the to do the actual work of making proteins.actual work of making proteins.
• This copy is called This copy is called Ribonucleic Ribonucleic Acid or RNAAcid or RNA..
• RNA differs from DNARNA differs from DNA in in several important ways.several important ways.1.1. It is much It is much smallersmaller2.2. It is It is single-strandedsingle-stranded3.3. It does NOT contain It does NOT contain
ThymineThymine, but rather a new , but rather a new nucleotide called nucleotide called UracilUracil which will bind to Adeninewhich will bind to Adenine
4.4. Contains Contains riboseribose, not , not deoxyribose sugardeoxyribose sugar
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RNA TranscriptionRNA Transcription• RNA is produced through a process called RNA is produced through a process called RNA RNA
TranscriptionTranscription..• Similar to DNA Replication.Similar to DNA Replication.• Small area of DNA "Unzips"Small area of DNA "Unzips" exposing Nucleotides exposing Nucleotides• This area is acted on by an enzyme called This area is acted on by an enzyme called RNA RNA
PolymerasePolymerase, which binds nucleotides (using uracil) to , which binds nucleotides (using uracil) to their complementary base pair.their complementary base pair.
• This releases a long strand of This releases a long strand of Messenger RNA (mRNAMessenger RNA (mRNA)) which is an important component ofwhich is an important component of protein synthesis.protein synthesis.
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RNA TranscriptionRNA Transcription
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Protein Synthesis & The Protein Synthesis & The Genetic CodeGenetic Code
• The The Sequence of nucleotides in an Sequence of nucleotides in an mRNAmRNA strand determine the strand determine the sequence of amino acids in a sequence of amino acids in a proteinprotein
• Process requires Process requires mRNA, tRNA & mRNA, tRNA & ribosomes ribosomes
• Polypeptide chainsPolypeptide chains are synthesized are synthesized by linking by linking amino acidsamino acids together with together with peptide bondspeptide bonds
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mRNAmRNA• Each three Each three Nucleotide Nucleotide sequence in an sequence in an mRNA strand is mRNA strand is called a "called a "CodonCodon““
• Each Codon Each Codon codes for a codes for a particular amino particular amino acid.acid.
• The codon The codon sequence codes sequence codes for an amino acid for an amino acid using specific using specific rules. These rules. These specific specific codon/amino acid codon/amino acid pairings is called pairings is called the the Genetic CodeGenetic Code. .
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tRNAtRNA•There is a special form There is a special form of RNA called of RNA called Transfer Transfer RNA or tRNA.RNA or tRNA.•Each tRNA has a 3 Each tRNA has a 3 Nucleotide sequence on Nucleotide sequence on one end which is known one end which is known as the "as the "AnitcodoAnitcodonn""•This Anticodon This Anticodon sequence sequence is is complimentary to the complimentary to the Codon sequence found Codon sequence found on theon the strand of mRNAstrand of mRNA•Each tRNA can bind Each tRNA can bind specifically with a specifically with a particular amino acid.particular amino acid.
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RibosomeRibosome• Consists of two Consists of two
subunits made of subunits made of protein & rRNAprotein & rRNA– Large subunitLarge subunit– Small subunitSmall subunit
• Serves as a Serves as a template or template or "work station""work station" where protein where protein synthesis can synthesis can occur.occur.
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Protein SynthesisProtein Synthesis• First, an First, an mRNA strand binds to the large & mRNA strand binds to the large &
small subunits of a ribosomesmall subunits of a ribosome in the cytosol of in the cytosol of the cellthe cell
• This occurs at the This occurs at the AUG (initiation) codonAUG (initiation) codon of of the strand.the strand.
• The ribosome has The ribosome has 3 binding sites3 binding sites for codons for codons --- --- EE (exit site), (exit site), PP, and , and AA (entry site for new (entry site for new tRNA)tRNA)
• The ribosome moves along the mRNA strandThe ribosome moves along the mRNA strand
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Protein SynthesisProtein Synthesis• An An anticodon on tRNA binds to a anticodon on tRNA binds to a
complementary codon on mRNA.complementary codon on mRNA.• The tRNA carrying an amino acid The tRNA carrying an amino acid enters the enters the
A site on the ribosomeA site on the ribosome• The ribosome moves down the mRNA so the The ribosome moves down the mRNA so the
tRNA is now in the P sitetRNA is now in the P site and another tRNA and another tRNA enters the A siteenters the A site
• A A peptide bondpeptide bond is formed between the amino is formed between the amino acids and the ribosome moves down againacids and the ribosome moves down again
• The The first tRNA is releasedfirst tRNA is released, and another tRNA , and another tRNA binds next to the second, another peptide binds next to the second, another peptide bond is formed.bond is formed.
• This process continues until a stop codon This process continues until a stop codon (UAG…) is reached.(UAG…) is reached.
• The completed polypeptide is thenThe completed polypeptide is then released.released.
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Protein SynthesisProtein Synthesis
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Replication ProblemReplication Problem• Given a DNA strand with the Given a DNA strand with the
following nucleotide sequence, following nucleotide sequence, what is the sequence of its what is the sequence of its complimentary strand?complimentary strand?
• 3’- TACCACGTGGACTGAGGACTCCTCTTCAGA -3’- TACCACGTGGACTGAGGACTCCTCTTCAGA -5’5’
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AnswerAnswer• Given a DNA strand with the Given a DNA strand with the
following nucleotide sequence, following nucleotide sequence, what is the sequence of its what is the sequence of its complimentary strand?complimentary strand?
• 3’- TACCACGTGGACTGAGGACTCCTCTTCAGA -3’- TACCACGTGGACTGAGGACTCCTCTTCAGA -5’5’
• 5’- ATGGTGCACCTGACTCCTGAGGAGAAGTCT 5’- ATGGTGCACCTGACTCCTGAGGAGAAGTCT -3’-3’
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RNA Transcription ProblemRNA Transcription Problem• Given a DNA strand with the Given a DNA strand with the
following nucleotide sequence, following nucleotide sequence, what is the sequence of its what is the sequence of its complimentary mRNA strand?complimentary mRNA strand?
• 3’- TACCACGTGGACTGAGGACTCCTCTTCAGA -3’- TACCACGTGGACTGAGGACTCCTCTTCAGA -5’5’
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ANSWERANSWER• Given a DNA strand with the Given a DNA strand with the
following nucleotide sequence, following nucleotide sequence, what is the sequence of its what is the sequence of its complimentary mRNA strand?complimentary mRNA strand?
• 3’- TACCACGTGGACTGAGGACTCCTCTTCAGA -5’3’- TACCACGTGGACTGAGGACTCCTCTTCAGA -5’• 3’- AUGGUGCACCUGACUCCUGAGGAGAAGUCU -5’3’- AUGGUGCACCUGACUCCUGAGGAGAAGUCU -5’
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Codon / AnticodonCodon / Anticodon• Given a mRNa strand with the Given a mRNa strand with the
following nucleotide sequence, what following nucleotide sequence, what are the sequence (anticodons) of its are the sequence (anticodons) of its complimentary tRNA strands?complimentary tRNA strands?
• 3’- 3’- AUGGUGCACCUGACUCCUGAGGAGAAGUCU -AUGGUGCACCUGACUCCUGAGGAGAAGUCU -5’5’
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AnswerAnswerGiven a mRNA strand with the following Given a mRNA strand with the following
nucleotide sequence, what are the sequence nucleotide sequence, what are the sequence (anticodons) of its complimentary tRNA strands?(anticodons) of its complimentary tRNA strands?
• 3’- AUGGUGCACCUGACUCCUGAGGAGAAGUCU -5’3’- AUGGUGCACCUGACUCCUGAGGAGAAGUCU -5’• 3’ – UACCACGUGGAUGAGGACUCCUCUUCAGA -5’3’ – UACCACGUGGAUGAGGACUCCUCUUCAGA -5’
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Protein TranslationProtein Translation• Given the Given the
following following sequence of sequence of mRNA, what is mRNA, what is the amino acid the amino acid sequence of the sequence of the resultant resultant polypeptide?polypeptide?
• AUGGUGCACCUGAUGGUGCACCUGACUCCUGAGGAGACUCCUGAGGAGAAGUCUAAGUCU
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Protein Translation / AnswerProtein Translation / Answer• Given the Given the
following following sequence of sequence of mRNA, what is mRNA, what is the amino acid the amino acid sequence of the sequence of the resultant resultant polypeptide?polypeptide?
• AUGGUGCACCUGAUGGUGCACCUGACUCCUGAGGAGACUCCUGAGGAGAAGUCUAAGUCU
Met-val-his-leu-thr-pro-glu-glu-lys-serMet-val-his-leu-thr-pro-glu-glu-lys-ser
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