The Blueprint of Life, From DNA to Protein - PowerPoint PPT Presentation

1 / 49
About This Presentation
Title:

The Blueprint of Life, From DNA to Protein

Description:

Characteristics of each cell dictated by information contained on DNA ... All cell structures and processes ... Genet Expression. Specifics of transcription ... – PowerPoint PPT presentation

Number of Views:117
Avg rating:3.0/5.0
Slides: 50
Provided by: mell166
Category:
Tags: dna | blueprint | genet | life | protein

less

Transcript and Presenter's Notes

Title: The Blueprint of Life, From DNA to Protein


1
The Blueprint of Life,From DNA to Protein
  • Chapter 7

2
The Blueprint of Life
  • Characteristics of each cell dictated by
    information contained on DNA
  • DNA holds master blueprint
  • All cell structures and processes directed by DNA

3
Overview
  • Complete set of genetic information referred to
    as genome
  • Genome of all cells is composed of DNA
  • Some viruses have RNA genome
  • Functional unit of genome is the gene
  • Gene codes for gene product
  • Gene product is most commonly protein
  • Study of transfer of genes is genetics
  • Study of sequence of DNA is genomic

4
Overview
  • Living cells must accomplish two general tasks to
    multiply
  • DNA replication
  • DNA expression (gene expression)
  • Expression involves two process
  • Transcription
  • Copies information in DNA to RNA
  • Translation
  • Interpret RNA to synthesize protein
  • Flow of information from DNA to RNA to protein
  • Central dogma of molecular biology

5
Overview
  • Characteristics of DNA
  • Made up of deoxy-ribonucleotides
  • Nucleotides include
  • Phosphate group
  • 5 carbon sugar
  • Deoxyribose
  • Nucleotides bond covalently between the 5PO4 of
    one nucleotide and the 3OH of another
  • Joining of nucleotides creates an alternating
    sugar-phosphate backbone

6
Overview
  • Characteristics of DNA
  • Each sugar (deoxyribose) molecule is connected to
    a nitrogenous base
  • Nitrogenous bases
  • Adenine (A) - purine
  • Thymine (T) - pyrimidine
  • Guanine (G) - purine
  • Cytosine (C) pyrimidine

7
Overview
  • Characteristics of DNA
  • Chemical structure and joining of nucleotide
    subunits causes strands to differ at the ends
  • One strand has a phosphate attached at the number
    5 carbon of the sugar.
  • Termed the five prime (5) end
  • The other strand has a hydroxyl group attached to
    the number 3 carbon of the sugar.
  • Termed the three prime (3) end

8
Overview
  • Characteristics of DNA
  • DNA occurs as double-stranded molecule
  • Strands are complementary to each other
  • Due to the specific base pairing of bases
  • AT
  • CG
  • Strands are held together with hydrogen bonds
  • Specific hydrogen bonding between bases
  • A is bound to T by two hydrogen bonds
  • G is bound to C by three hydrogen bond

9
Overview
  • Characteristics of DNA
  • DNA molecule is antiparallel
  • Strands are oriented in opposite directions
  • Strands differ at the ends
  • One strand oriented in the 5 to 3 direction.
  • The other strand is oriented in the 3 to 5
    direction.

10
Overview
  • Characteristics of RNA
  • RNA is made up of nucleotides
  • Ribonucleotides
  • RNA contains nitrogenous bases
  • Adenine
  • Guanine
  • Cytosine
  • Uracil
  • Uracil replaces thymine in RNA
  • RNA usually exists as single stranded molecule

11
Overview
  • Characteristics of RNA
  • Portion of DNA acts of template for RNA synthesis
  • RNA molecule called transcript
  • Numerous transcripts can be produced from one
    chromosome
  • Either strand of DNA can act as template
  • Three different functional groups of RNA
  • Messenger RNA (mRNA)
  • Ribosomal RNA (rRNA)
  • Transfer RNA (tRNA)

12
Overview
  • Regulating the expression of genes
  • Nucleotide sequence codes for regulation
    mechanism for gene expression
  • Mechanisms determine duration of synthesis of
    gene products
  • Products are only made when required
  • Key mechanism is regulation of mRNA synthesis
    from DNA
  • Regulation of transcription

13
DNA Replication
  • DNA is replicated to create second copy of
    molecule
  • Molecule is identical to original
  • Replication is bidirectional
  • Replication begins at specific starting point
  • Proceeds in opposite directions
  • Allows replication to proceed more quickly

14
DNA Replication
  • DNA replication
  • The two strands are unwound and separated
  • Free, unbound nucleotides match up to the newly
    separated nitrogenous bases of the parent strand
  • The parent strand is also called the template
    strand

15
DNA Replication
  • DNA replication
  • Base pairing is specific in DNA replication
  • Where adenine is present only thymine binds in
    the new strand and vice versa
  • Where guanine is present only cytosine binds in
    the new strand and vice versa
  • Bases that are improperly inserted are removed
    and replaced with the correct base
  • Newly added bases are added by the enzyme DNA
    polymerase

16
DNA Replication
  • Specifics of DNA replication
  • As the strands of DNA unwind, it creates an area
    of replication called the replication fork
  • As nucleotides are added, the replication fork
    moves down the parental strand

17
DNA Replication
  • Specifics of DNA replication
  • DNA polymerase adds new nucleotides as they
    become available.
  • DNA polymerase can only add nucleotides to the
    free hydroxyl at the 3 end
  • DNA polymerase replicates in 5 to 3 direction
  • Enzymes READS DNA template in 3 to 5 direction
  • Because of the antiparallel nature of the strands
    of DNA, the two new strands will grow in opposite
    directions
  • One strand is the leading strand
  • One strand is the lagging strand

18
DNA Replication
  • Specifics of DNA replication
  • Leading strand
  • Is synthesized CONTINUOUSLY as the DNA polymerase
    moves towards the replication fork
  • Lagging strand
  • Is synthesized DISCONTINUOUSLY in pieces as DNA
    polymerase moves away from the replication fork

19
DNA Replication
  • Specifics of DNA replication
  • DNA polymerase must bind to an RNA primer to
    begin synthesis
  • A second DNA polymerase removes any RNA primers
  • An RNA primer is required at each newly
    synthesized section of the lagging strand
  • DNA ligase joins the fragments of the lagging
    strand

20
DNA Replication
  • Specifics of DNA replication
  • Replication is completed when the replication
    fork reaches the end of the parent strands
  • The original parent strand and the newly
    synthesized daughter strand rewind
  • Each new strand of DNA consists of one parent
    strand and one daughter strand
  • DNA replication is referred to as semiconservative

21
Gene Expression
  • Involves two separate but interrelated process
  • Transcription
  • Process of synthesizing RNA from DNA template
  • Translation
  • RNA is deciphered to synthesize protein

22
Gene Expression
  • Transcription
  • Transcription is the synthesis of a strand of
    mRNA from a DNA template
  • mRNA carries the coded information from DNA to
    the ribosome, which is the site of protein
    synthesis
  • mRNA also plays an important role in translation

23
Gene Expression
  • Transcription
  • During transcription the enzyme, RNA polymerase,
    synthesizes a complementary strand of mRNA from a
    portion of unwound DNA

24
Gene Expression
  • Specifics of Transcription
  • RNA polymerase binds to a region of the DNA
    called the promoter
  • Only one strand of DNA acts as a template
  • This is called the sense strand
  • The strand not transcribed is the nonsense strand

25
Genet Expression
  • Specifics of transcription
  • Nucleotides in RNA are the same as those in DNA
    with one exception
  • Thymine is replaced with uracil
  • Binding in RNA is
  • AU or UA
  • CG or GC

26
Gene Expression
  • Specifics of transcription
  • RNA polymerase continues down strand of DNA until
    it reaches a site on DNA called the terminator
  • At the terminator RNA polymerase and the new
    strand of mRNA are released from strand of DNA

27
Gene Expression
  • Translation
  • Translation is the decoding of information held
    in the mRNA to synthesize proteins
  • Two more RNA molecules become involved in
    translation
  • Ribosomal RNA (rRNA)
  • Transfer RNA (tRNA)

28
Gene Expression
  • rRNA forms part of the ribosomal machinery used
    in protein synthesis
  • rRNA builds the ribosomes
  • tRNA recognizes specific sequences of mRNA and
    transports the required amino acids to form a
    polypeptide chain

29
Gene Expression
  • Translation
  • The language of mRNA is in the form of codons
  • Codons are groups of three nucleotides situated
    next to each other on DNA
  • Codons are written in terms of their base
    sequence in mRNA
  • The sequence of codons determines the sequence of
    amino acids in the protein

30
Gene Expression
  • Translation
  • There are 64 codons that make up the alphabet
    of proteins
  • Of the 64 codons, 61 are sense codons
  • Each coding a specific amino acid
  • The remaining 3 are nonsense codons
  • These code for termination of the message
  • Codons contained in mRNA are read into proteins
    through translation
  • The site of translation is the ribosome

31
Gene Expression
  • In response to each codon, tRNA brings the
    appropriate amino acid to the site of translation
  • Each codon has an anticodon
  • The anticodon is complementary sequence to the
    codon

32
Gene Expression
  • Translation
  • Ribosomes
  • The 30s and the 50s ribosomal subunits join
    together around the mRNA
  • The ribosomes direct the binding of tRNA to the
    correct codon on the mRNA
  • tRNA binds to the P site and the A site of the
    50s ribosomal subunit
  • The ribosomes bind to the mRNA to be translated

33
Gene Expression
P site A site
  • Specifics of Translation
  • The first tRNA binds to a start codon in the P
    site of the ribosome
  • AUG is the start codon for EVERY protein
  • AUG codes for the amino acid methionine
  • When the second tRNA binds to the A site, the
    amino acid of the first tRNA forms a peptide bond
    with the amino acid of the second tRNA

34
Gene Expression
  • Specifics of translation
  • After the peptide bond is formed between the two
    amino acids, the tRNA P site leaves the ribosome
  • The ribosome moves distance of one codon
  • Amino acid in the A site moves to the P site
  • A new tRNA fills the now empty A site

35
Gene Expression
  • Specifics of translation
  • The ribosome continues down the strand of mRNA
  • Amino acids form peptide bonds along the way
  • Translation is terminated when the ribosomes come
    to a stop or nonsense codon
  • At this point the ribosomes separate
  • The new polypeptide chain is released
  • The ribosome and the mRNA are free to begin
    translation again

36
Gene Expression
  • Specifics of translation
  • As the ribosome moves down the strand of mRNA,
    the start codon is exposed
  • Once exposed, a new ribosome will attach and
    begin another polypeptide chain

37
Regulation of Gene Expression
  • Microorganisms posses mechanism to synthesize
    maximum amount of cell material from limited
    energy
  • Controls directed at metabolic pathways
  • Two general mechanism
  • Allosteric inhibition of enzymes
  • Controlling synthesis of enzymes
  • Directed at making only what is required

38
Regulation of Gene Expression
  • Principles of regulation
  • Not all genes subjected to regulation
  • Enzymes can be classified according to
    characteristics of regulation
  • Constitutive enzymes
  • Constantly synthesized
  • Enzymes of glycolysis
  • Inducible enzymes
  • Not regularly produced
  • turned on in certain conditions
  • ?-galactosidase
  • Repressible enzymes
  • Routinely synthesized
  • Generally involved in biosynthesis

39
Regulation of Gene Expression
  • Mechanisms controlling transcription
  • Often controlled by regulatory region near
    promoter
  • Protein binds to region and acts as on/off
    switch
  • Binding protein can act as repressor or activator
  • Repressor blocks transcription
  • Activator facilitates transcription
  • Set of genes controlled by protein is called an
    operon

40
Regulation of Gene Expression
  • Repressors
  • Control mechanism that inhibits gene expression
    and decreases the synthesis of enzymes
  • Repression is usually in response to the
    overabundance of an end product
  • Repression decreases the rate synthesis of
    enzymes leading to the formation of the
    particular end product
  • Regulatory proteins called repressors mediate
    repression
  • Repressors block the ability of RNA polymerase to
    bind and initiate protein synthesis

41
Regulation of Gene Expression
  • Activators
  • Control mechanism that turns on the transcription
    of a gene or set of genes
  • Inducers are substances that act to induce
    transcription
  • Enzymes synthesized in the presence of inducers
    are called inducible enzymes

42
Regulation of Gene Expression
  • Operon model of gene expression
  • An operon is a set of genes that includes an
    operator, promoter and structural genes
  • An operon is divided into two regions, the
    control region and the structural region
  • The control region include the operator and the
    promoter
  • This region controls transcription
  • The operator acts as the on-off switch
  • The structural region includes the structural
    genes
  • This region contains the genes being transcribed

43
Operon structure
Operator binding site for the repressor protein
for the regulation of gene expression
Promoter Binding site for RNA polymerase
Structural Genes DNA sequence for specific
proteins
44
Regulation of Gene Expression
  • Lac operon
  • Example of induction of gene expression
  • Near the operon on the DNA is a regulatory gene
    called the I gene
  • This codes for the repressor protein
  • When lactose is absent, the repressor protein
    binds to the operator gene
  • Binding of the repressor gene prevents RNA
    polymerase from transcribing the structural genes
  • No mRNA is made and no enzymes are synthesized

45
Regulation of Gene Expression
  • Lac operon
  • When lactose is present the repressor binds to
    lactose instead of the operator
  • With the repressor bound to lactose, RNA
    polymerase is able to bind to the promoter and
    transcribes the structural genes
  • Lactose acts as an inducer by keeping the
    repressor from binding to the operator
  • It induces the transcription of the structural
    genes

46
Lac Operon
1.
2.
3.
Lactose
47
Gene Expression and Environmental Fluctuations
  • Many organisms adapt to changing environments by
    altering level of gene expression
  • Mechanisms include
  • Signal transduction
  • Natural selection

48
Gene Expression and Environmental Fluctuations
  • Signal transduction
  • Process that transmits information from external
    environment to inside cell
  • Allows cell to respond to changes
  • Two-component regulatory systems
  • Relies on sensor and response regulator proteins
  • Sensors recognize change in environment
  • Response regulators activate or repress gene
    expression
  • Quorum sensing
  • Organisms sense density of population
  • Enables activation of genes beneficial to the mass

49
Gene Expression and Environmental Fluctuations
  • Natural selection
  • Mechanisms to enhance survivability
  • Antigenic variation
  • Alteration in characteristics of certain surface
    proteins
  • Example Neisseria gonorrhoeae hides from host
    immunity by changing numerous surface proteins
  • Phase variation
  • Routine switching on and off of certain genes
  • Altering expression allows portions of population
    to survive and multiply
Write a Comment
User Comments (0)
About PowerShow.com