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Title: Project

1
Project Studying Synechococcus elongatus for
biophotovoltaics
2

How to bioengineer a novel bio-photovoltaic
system?
Obtain a sequence by PCR, then clone it into a
suitable plasmid
Were adding DNA, but want Synechococcus to make
a protein!

In bacteria transcription and translation are
initially coupled

In Bacteria transcription and translation are
initially coupled
RNA polymerase quits if ribosomes lag too much

In Bacteria transcription and translation are
initially coupled
RNA polymerase quits if ribosomes lag too much
Recent studies show that ribosomes continue
translating once mRNA is complete i.e after
transcription is done

Bacteria have gt 1 protein/mRNA (polycistronic)
http//bmb-it-services.bmb.psu.edu/bryant/lab/Proj
ect/Hydrogen/index.htmlsection1
euk have 1 protein/mRNA

Bacteria have gt 1 protein/mRNA (polycistronic)
Mutations can have polar effects mutations in
upstream genes may affect expression of perfectly
good downstream genes!

8
Transcription Prokaryotes have one RNA
polymerase makes all RNA core polymerase
complex of 5 subunits (a1aIIbbw)
9
Transcription Prokaryotes have one RNA
polymerase makes all RNA core polymerase
complex of 5 subunits (a1aIIbbw) w not
absolutely needed, but cells lacking w are very
sick
10
Initiating transcription in Prokaryotes 1) Core
RNA polymerase is promiscuous
11

Initiating transcription in Prokaryotes
Core RNA polymerase is promiscuous
sigma factors provide specificity

Initiating transcription in Prokaryotes
Core RNA polymerase is promiscuous
sigma factors provide specificity
Bind promoters

Initiating transcription in Prokaryotes
Core RNA polymerase is promiscuous
sigma factors provide specificity
Bind promoters
Different sigmas bind different promoters

Initiating transcription in Prokaryotes
Core RNA polymerase is promiscuous
sigma factors provide specificity
Bind promoters
3) Once bound, RNA polymerase
melts the DNA

Initiating transcription in Prokaryotes
3) Once bound, RNA polymerase
melts the DNA
4) rNTPs bind template

Initiating transcription in Prokaryotes
3) Once bound, RNA polymerase
melts the DNA
4) rNTPs bind template
5) RNA polymerase catalyzes phosphodiester bonds,
melts and unwinds template

Initiating transcription in Prokaryotes
3) Once bound, RNA polymerase
melts the DNA
4) rNTPs bind template
5) RNA polymerase catalyzes phosphodiester bonds,
melts and unwinds template
6) sigma falls off after 10 bases are added

18
Structure of Prokaryotic promoters Three DNA
sequences (core regions) 1) Pribnow box at -10
(10 bp 5 to transcription start) 5-TATAAT-3
determines exact start site bound by s factor
19
Structure of Prokaryotic promoters Three DNA
sequences (core regions) 1) Pribnow box at -10
(10 bp 5 to transcription start) 5-TATAAT-3
determines exact start site bound by s
factor 2) -35 region 5-TTGACA-3 bound by
s factor
20
Structure of Prokaryotic promoters Three DNA
sequences (core regions) 1) Pribnow box at -10
(10 bp 5 to transcription start) 5-TATAAT-3
determines exact start site bound by s
factor 2) -35 region 5-TTGACA-3 bound by
s factor 3) UP element -57 bound by a factor
21
Structure of Prokaryotic promoters Three DNA
sequences (core regions) 1) Pribnow box at -10
(10 bp 5 to transcription start) 5-TATAAT-3
determines exact start site bound by s
factor 2) -35 region 5-TTGACA-3 bound by
s factor 3) UP element -57 bound by a factor
22
Structure of Prokaryotic promoters Three DNA
sequences (core regions) 1) Pribnow box at -10
(10 bp 5 to transcription start) 5-TATAAT-3
determines exact start site bound by s
factor 2) -35 region 5-TTGACA-3 bound by
s factor 3) UP element -57 bound by a
factor Other sequences also often influence
transcription! Eg CAP site in lac promoter
23
Structure of Prokaryotic promoters Other
sequences also often influence transcription! Our
plasmid contains the nickel promoter.
24
Structure of Prokaryotic promoters Other
sequences also often influence transcription! Our
plasmid contains the nickel promoter.
?
25
Structure of Prokaryotic promoters Other
sequences also often influence transcription! Our
plasmid contains the nickel promoter. nrsBACD
encode nickel transporters
26

Structure of Prokaryotic promoters
Other sequences also often influence
transcription! Our plasmid contains the nickel
promoter.
nrsBACD encode nickel transporters
nrsRS encode two component signal transducers
nrsS encodes a his kinase
nrsR encodes a response regulator

Structure of Prokaryotic promoters
nrsRS encode two component signal transducers
nrsS encodes a his kinase
nrsR encodes a response regulator
When nrsS binds Ni it kinases nrsR

Structure of Prokaryotic promoters
nrsRS encode two component signal transducers
nrsS encodes a his kinase
nrsR encodes a response regulator
When nrsS binds Ni it kinases nrsR
nrsR binds Ni promoter and activates
transcription of both operons

29
Termination of transcription in prokaryotes 1)
Sometimes go until ribosomes fall too far behind
30
Termination of transcription in prokaryotes 1)
Sometimes go until ribosomes fall too far
behind 2) 50 of E.coli genes require a
termination factor called rho
31
Termination of transcription in prokaryotes 1)
Sometimes go until ribosomes fall too far
behind 2) 50 of E.coli genes require a
termination factor called rho 3) Our terminator
(rrnB) first forms an RNA hairpin, followed by an
8 base sequence TATCTGTT that halts transcription
32
Homologous recombination 1) DNA strands must be
capable of base-pairing
33

Homologous recombination
DNA strands must be capable of base-pairing
DNA must get cut

Homologous recombination
DNA strands must be capable of base-pairing
DNA must get cut
Ends are processed to form single-strand overhangs

Homologous recombination
DNA strands must be capable of base-pairing
DNA must get cut
Ends are processed to form single-strand
overhangs
Single strand invades homolog (with help of RecA
protein)

Homologous recombination
DNA strands must be capable of base-pairing
DNA must get cut
Ends are processed to form single-strand
overhangs
Single strand invades homolog (with help of RecA
protein)
Must be capable of forming hybrid molecule!

Homologous recombination
DNA strands must be capable of base-pairing
DNA must get cut
Ends are processed to form single-strand
overhangs
Single strand invades homolog (with help of RecA
protein)
Must be capable of forming hybrid molecule!
DNA polymerase adds on to end of invading molecule

Homologous recombination
DNA strands must be capable of base-pairing
DNA must get cut
Ends are processed to form single-strand
overhangs
Single strand invades homolog (with help of RecA
protein) forms Holliday junction
Branch migrates

Homologous recombination
DNA strands must be capable of base-pairing
DNA must get cut
Ends are processed to form single-strand
overhangs
Single strand invades homolog (with help of RecA
protein) forms Holliday junction
Branch migrates
Holliday jn is
cut DNA is ligated

Homologous recombination
DNA strands must be capable of base-pairing
DNA must get cut
Ends are processed to form single-strand
overhangs
Single strand invades homolog (with help of RecA
protein) forms Holliday junction
Branch migrates
Holliday jn is
cut DNA is ligated
7) Use mismatch repair
to fix mismatches

Homologous recombination
DNA strands must be capable of base-pairing
DNA must get cut
Ends are processed to form single-strand
overhangs
Single strand invades homolog (with help of RecA
protein) forms Holliday junction
Branch migrates
Holliday jn is
cut DNA is ligated
7) Use mismatch repair
to fix mismatches
Why add selectable
marker to new sequence