Regulating transcription Telling RNA pol to copy a DNA sequence Transcription factors bind promoters...

Regulating transcriptionTelling RNA pol to copy a DNA sequenceTranscription factors bind promoters & control initiation of transcription

1/signal gene senses1 binding site/signal gene senses

Transcription factorsBind surface -> base-pairs form unique patterns in major & minor grooves

Transcription factorsBind surface -> base-pairs form unique patterns in major & minor groovesScan DNA for correct patternneed 15 - 20 H-bonds = 5-8 base-pairs

Transcription

Prokaryotes have one RNA polymerase

makes all RNA

core polymerase = complex of 5 subunits (’)

not absolutely needed, but cells lacking are very sick

Initiating transcription in Prokaryotes1) Core RNA polymerase is promiscuous

Initiating transcription in Prokaryotes1) Core RNA polymerase is promiscuous2) sigma factors provide specificity• Bind promoters

Initiating transcription in Prokaryotes1) Core RNA polymerase is promiscuous2) sigma factors provide specificity• Bind promoters• Different sigmas bind different promoters

Initiating transcription in Prokaryotes1) Core RNA polymerase is promiscuous2) sigma factors provide specificity• Bind promoters3) Once bound, RNA polymerase “melts” the DNA

Initiating transcription in Prokaryotes3) Once bound, RNA polymerase “melts” the DNA4) rNTPs bind template

Initiating transcription in Prokaryotes3) Once bound, RNA polymerase “melts” the DNA4) rNTPs bind template5) RNA polymerase catalyzes phosphodiester

bonds, melts and unwinds template

Initiating transcription in Prokaryotes3) Once bound, RNA polymerase “melts” the DNA4) rNTPs bind template5) RNA polymerase catalyzes phosphodiester

bonds, melts and unwinds template6) sigma falls off after ~10 bases are added

Structure of Prokaryotic promotersThree DNA sequences (core regions)

1) Pribnow box at -10 (10 bp 5’ to transcription start)5’-TATAAT-3’ determines exact start site: bound by factor

2)” -35 region” : 5’-TTGACA-3’ : bound by factor

2)” -35 region” : 5’-TTGACA-3’ : bound by factor3) UP element : -57: bound by factor

2)” -35 region” : 5’-TTGACA-3’ : bound by factor3) UP element : -57: bound by factorOther sequences also often influence transcription! Eg Trp operator

Prok gene regulation5 genes (trp operon) encode trp enzymes

Prok gene regulationCopy genes when no trpRepressor stops operon if [trp]

Prok gene regulationRepressor stops operon if [trp] trp allosterically regulates repressor can't bind operator until 2 trp bind

lac operonSome operons use combined “on” & “off” switches E.g. E. coli lac operon Encodes enzymes to use lactose

lac Z = -galactosidaselac Y= lactose permeaselac A = transacetylase

lac operon

Make these enzymes only if:

1) - glucose

lac operon

Make these enzymes only if:

1) - glucose

2) + lactose

lac operon

Regulated by 2 proteins

1) CAP protein : senses [glucose]

lac operonRegulated by 2 proteins1) CAP protein : senses [glucose]2) lac repressor: senses [lactose]

encoded by lac i geneAlways on

lac operon2 proteins = 2 binding sites1) CAP site: promoter isn’t active until CAP binds

lac operon2 proteins = 2 binding sites1) CAP site: promoter isn’t active until CAP binds2) Operator: repressor blocks transcription

lac operonRegulated by 2 proteins1) CAP only binds if no glucose -> no activation

lac operonRegulated by 2 proteins1) CAP only binds if no glucose -> no activation2) Repressor blocks transcription if no lactose

lac operonRegulated by 2 proteins1) CAP only binds if no glucose 2) Repressor blocks transcription if no lactose3) Result: only make enzymes for using lactose if lactose is present and glucose is not

Result[-galactosidase]rapidly rises if noglucose & lactoseis presentW/in 10 minutes is 6% of total protein!

Structure of Prokaryotic promotersOther sequences also often influence transcription! Bio502 plasmid contains the nickel promoter.

Structure of Prokaryotic promotersOther sequences also often influence transcription! Bio502 plasmid contains the nickel promoter.nrsBACD encode nickel transporters

Structure of Prokaryotic promotersOther sequences also often influence transcription! Bio502 plasmid contains the nickel promoter.nrsBACD encode nickel transportersnrsRS encode “two component” signal transducers•nrsS encodes a his kinase•nrsR encodes a response regulator

Structure of Prokaryotic promotersnrsRS 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 promotersnrsRS 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 activatestranscription of both operons

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) rrnB first forms an RNA hairpin, followed by an 8 base sequence TATCTGTT that halts transcription

Transcription in Eukaryotes3 RNA polymerasesall are multi-subunit complexes 5 in common 3 very similar variable # unique onesNow have Pols IV & V in plantsMake siRNA

Transcription in EukaryotesRNA polymerase I: 13 subunits (5 + 3 + 5 unique) acts exclusively in nucleolus to make 45S-rRNA precursor

Transcription in EukaryotesPol I: acts exclusively in nucleolus to make 45S-rRNA precursor•accounts for 50% of total RNA synthesis

Transcription in EukaryotesPol I: acts exclusively in nucleolus to make 45S-rRNA precursor• accounts for 50% of total RNA synthesis• insensitive to -aminitin

Transcription in EukaryotesPol I: only makes 45S-rRNA precursor• 50 % of total RNA synthesis• insensitive to -aminitin•Mg2+ cofactor•Regulated @ initiation frequency

RNA polymerase Ipromoter is 5' to "coding sequence" 2 elements

1) essential core includes transcription start site

coding sequence

RNA polymerase Ipromoter is 5' to "coding sequence" 2 elements

1) essential core includes transcription start site2) UCE (Upstream Control Element) at ~ -100stimulates transcription 10-100x

coding sequence

Initiation of transcription by Pol IOrder of events was determined by in vitro reconstitution1) UBF (upstream binding factor) binds UCE and core element

UBF is a transcription factor: DNA-binding proteins which recruit polymerases and tell them where to begin

Initiation of transcription by Pol I1) UBF binds UCE and core element2) SL1 (selectivity factor 1) binds UBF (not DNA) SL1 is a coactivatorproteins which bind transcription factors and stimulate transcription

Initiation of transcription by Pol I1) UBF binds UCE and core element2) SL1 (selectivity factor 1) binds UBF (not DNA) SL1 is a complex of 4 proteins includingTBP (TATAA-binding protein)

Initiation of transcription by Pol I1) UBF binds UCE and core element2) SL1 (selectivity factor 1) binds UBF (not DNA) 3) complex recruits Pol I

Initiation of transcription by Pol I1) UBF binds UCE and core element2) SL1 (selectivity factor 1) binds UBF (not DNA) 3) complex recruits Pol I4) Pol I transcribes untilit hits a termination site

RNA Polymerase III

Reconstituted in vitro

makes ribosomal 5S and tRNA

(+ some snRNA & scRNA)

RNA Polymerase III makes ribosomal 5S and tRNA (+ some snRNA & scRNA)>100 different kinds of genes ~10% of all RNA synthesis

RNA Polymerase III makes ribosomal 5S and tRNA (+ some snRNA & scRNA)>100 different kinds of genes ~10% of all RNA synthesisCofactor = Mn2+ cf Mg2+

sensitive to high [-aminitin]

RNA Polymerase III makes ribosomal 5S and tRNA (also some snRNA and some scRNA)• Has the most subunits

RNA Polymerase III makes ribosomal 5S and tRNA (also some snRNA and some scRNA)• Has the most subunits•Regulated @initiation frequency

Initiation of transcription by Pol III

promoter is often w/in "coding" sequence!

promoter is w/in "coding" sequence!

5S & tRNA promoters differ

5S has single “C” box

1) TFIIIA binds C box in 5S

2) recruits TFIIIC

Initiation of transcription by Pol III1) TFIIIA binds C box2) recruits TFIIIC3) TFIIIB bindsTBP & 2 others

Initiation of Pol III transcription

1) TFIIIA binds C box

2) recruits TFIIIC

3) TFIIIB binds

4) Complex recruits Pol III

Initiation of Pol III transcription

1) TFIIIA binds C box

2) recruits TFIIIC

3) TFIIIB binds

4) Complex recruits Pol III

5) Pol III goes until

hits > 4 T's

promoter is w/in coding sequence!

5S & tRNA promoters differ

tRNA genes have “A” & “B” boxes

tRNA genes have “A” and “B” boxes

1) TFIIIC binds B box

tRNA genes have “A” and “B” boxes

1) TFIIIC binds B box

2) recruits TFIIIB

1) TFIIIC binds box B

2) recruits TFIIIB

3) complex recruits Pol III

1) TFIIIC binds box B

2) recruits TFIIIB

3) complex recruits Pol III

4) Pol III runs until

hits > 4 Ts

RNA Polymerase II

makes mRNA (actually hnRNA), some snRNA and scRNA

RNA Polymerase II

• >30,000 different genes

RNA Polymerase II

• >30,000 different genes

• 20-40% of total RNA synthesis

RNA Polymerase II

• ~ 30,000 different genes

• 20-40% of all RNA synthesis

• very sensitive to -aminitin

RNA Polymerase II

12 subunits in yeast,

unknown elsewhere

RNA Polymerase II

12 subunits in yeast,

unknown elsewhere

Largest subunit (L’) has

CarboxyTerminal

Domain (CTD)

important role in

regulating pol II

Initiation of transcription by Pol II

Needs > 30 other factors to initiate transcription

final complex is called a transcriptosome

contains > 50 proteins

Separate basal and activated transcription

basal transcription is not regulated

driven by minimal promoter

basal transcription is not regulated

driven by minimal promoter

TATAA box at -30

coding sequence

activated transcription is regulated by proteins bound to promoter elements called enhancers and silencers

usually 5’ to TATAA box

coding sequenceUCE

activated transcription is regulated by proteins bound to promoter elements called enhancers and silencers

usually 5’ to TATAA box

Requires nucleosome repositioning

coding sequenceUCE

Basal transcription

1) TFIID (includingTBP) binds TATAA box

Initiation of transcription

by Pol II

Basal transcription

1) TFIID binds to

TATAA box

2) Distorts DNA

Initiation of transcription by Pol IIBasal transcription1) TFIID binds TATAA box2) TFIIA and TFIIB bind TFIID/DNA

Basal transcription

1) TFIID binds TATAA box

2) TFIIA and TFIIB bind

TFIID/DNA

3) Complex recruits Pol II

Basal transcription

1) TFIID binds TATAA box

2) TFIIA and TFIIB bind to

TFIID/DNA

3) Complex recruits Pol II

4) Still must recruit

TFIIE & TFIIH to

form initiation complex

Initiation of transcription by Pol IIBasal transcription1) Once assemble initiation complex must start Pol II2) TFIIH kinases CTD

negative charge gets it started

3) Exchange initiation for elongation factors

Regulating transcription Telling RNA pol to copy a DNA sequence Transcription factors bind promoters...

Documents

3. Basic Genetics Plant Molecular Biologycontents.kocw.or.kr/document/Week5_Transcription.pdf · RNA polymerases initiate transcription at specific nucleotide sequences called promoters

DNA, RNA, and Protein - booksite.elsevier.com · Additionally, a component of RNA polymerase, called a sigma factor, enables the enzyme to bind to different promoters. There are numerous

1 Transcription in eukaryotes RNA Polymerases Promoters General Transcription Factors

Isolating Transcription Factors that Bind to the CD4 Promoter Matthew C. Surdel and Sophia D. Sarafova Davidson College Biology Department I. Background

Mammalian Period represses and de-represses …Mammalian Period represses and de-represses transcription by displacing CLOCK–BMAL1 from promoters in a Cryptochrome-dependent manner

Global regulatory transitions at core promoters demarcate the … · 2020. 10. 30. · Functional diversification of general transcription factors (GTFs), which bind to the core promoter,

Illegitimate transcription: anygene in anycell · PDF fileIllegitimate transcription: ... The abundance ofthese "illegitimate" transcripts is ... controlled by these promoters define

Transcriptional repression by FACT is linked to regulation ...€¦ · At these so-called bidirectional promoters, RNA Pol II initiates transcription and undergoes promoter-proximal

Transcription: RNA synthesis, RNA processing, “Algorithms ... · Transcription: RNA synthesis, RNA processing, Intron-exon structure Promoters: Regulation, Chromatin structure,

Identifying conserved promoter motifs and transcription factor binding sites in plant promoters Endre Sebestyén, ARI-HAS, Martonvásár, Hungary 26th, November,

Promoters of the Broad Host Range Plasmid RK2: Analysis of ... · Promoters of the Broad Host Range Plasmid RK2: Analysis of Transcription (Initiation) ... University of Calgornia

To Bind Or Not To Bind – Let Bind Manager Decide

Modeling transcription factor combinatorics in promoters ... · Modeling transcription factor combinatorics in promoters and enhancers Jimmy Vandel, Océane Cassan, ... predicting

Genomics of Gene Regulation - Pennsylvania State University · General features of promoters • A promoter is the DNA sequence required for correct initiation of transcription •

Cell cycle-dependent transcription in yeast: promoters, transcription factors, and transcriptomes

CHE.167 Genetics - ftp.tugraz.atftp.tugraz.at/pub/Molekulare_Biotechnologie/CHE_167 Genetik/WS_201… · Gene expression Transcription: promoters, termination, mRNA processing, mRNA

Synthetic Control of Transcription: From Hybrid Promoters

Models of cellular regulation A genetic switch Lambda lysogeny/lysis –Three operator sites controlling two promoters P RM and P R –Cro and CI dimers bind

Transcription Factor Binding and Nucleosome Positioning Are ...iwbbio.ugr.es/2014/papers/IWBBIO_2014_paper_77.pdfTranscription Start Site Selection in Eukaryotic Promoters 3 vivo nucleosome

Supplementary Data: Extensive and coordinated …...Supplementary Data: Extensive and coordinated transcription of noncoding RNAs within cell cycle promoters Tiffany Hung1,2, Yulei