1 / 36

Architectural TFs

Architectural TFs. Overview. DNA-binding TFs General principles. Architectural factors. Recognition of response elements Activators vrs Architectural TFs. Ordinary activators with sequence specific DNA binding Key recruitment sites for assembly of transcription complexes

bandele
Download Presentation

Architectural TFs

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Architectural TFs

  2. Overview DNA-binding TFs General principles Architectural factors

  3. Recognition of response elementsActivators vrs Architectural TFs • Ordinary activators with sequence specific DNA binding • Key recruitment sites for assembly of transcription complexes • Architectural transcription factors playing a more structural role in the assembly of transcription complexes

  4. Architectural TFs - brief history • Transcription activation - focus on more and more dimentions • 70-ties: 1-Dimentional understanding • ≥ RNAPII: TFs binding specific cis-elements required for selective transcription • TFs mediate regulatory response • 80-ties: 2-Dimentional understanding • Promoters/enhancers: clusters of cis-elements • complex regulation - Several buttons have to be pushed simultaneouly • Ptashnes simplification - mixed order OK • 90-ties: 3-Dimentional understanding • Three-dimentional assembly of TFs required for correct biological response

  5. 3D protein-promoter complexes- factors dedicated architecture • some factors has a pure architectural function • designated architectural transcription factors • They lack a transactivation domain (TAD) • Do not function out of their natural context (in contrast to ordinary acitvators) • Their function is to confer a specific 3D structure on DNA

  6. Classical HMG-proteins • non-histone chromatin proteins - original defining criteria • high mobility in PAGE • soluble in 2-5% TCA • small < 30 kDa • High content of charged amino acids • abundant: 1 per. 10-15 nucleosomes

  7. Classical HMG-proteins • Three classes of HMG DNA-binding proteins • HMG-box family • Eks: HMG 1 and HMG 2 • Bends DNA substantially • Facilitators of nucleoprotein complexes • HMG-AT-hook family • Eks.: HMGI(Y) • Antagonizing intrinsic distortions in the conformation of AT-rich DNA • HMG-nucleosome binding family • Eks.: HMG14 and 17 • Mediates moderate destabilization of chromatin higher-order structure • Not present in yeast or fly HMGB HMGA HMGN

  8. HMGB-proteins

  9. HMG1 and 2 • 3 structural domains • A and B with high homology (80-90 aa) • acidic C-terminal • Interaction with DNA (and histones?) • A and B ≈ DNA • C-term ≈ histone H1 or unknown function + + + + + + + + - - - - A B N C Histon H1? DNA

  10. HMG-boxes in architectural proteins • One or two HMG-box domains 30 Asp/Glu acidic basic

  11. First eukaryotic architectural TF: LEF1 (Grosschedl 1992) • LEF1: a cell type-specific TF • LEF1 contains an HMG-related domain • LEF1: a sequence-specific TF that binds CCTTTGAAG • found in enhancer of TCR • LEF1 induces strong bending of DNA - about 130o • Induced bending brings nearly TFs in contact

  12. LEF1 3D

  13. LEF1 3D

  14. A whole family of architectural TFs with HMG-domains • UBF has repeated HMG-homologous repeats • 4-6 ex dimer ≈ 10 HMG-like domains • activator of rRNA gener • UBF-DNA complex  scaffold for SL-1 recruitment • Interaction with 180 bp that is packed into a distinct structure • DNA-motif in a series of TFs: • “HMG-box” designate the DNA-sequence-motif • “HMG-domain” designate the protein motif

  15. Two subclasses of HMG-domain proteins • Proteins with multiple HMG-domains • low sequence-specificity • Ubiquitous - found in all cell types • eks.: HMG1, HMG2, ABF-2, UBF • Proteins with single HMG-domain • (moderate) sequence-specificity • Cell type-specific • eks.: LEF-1, SRY, TCF-1, Sox, Mat-a1, Ste11, Rox1

  16. Characteristic DNA-binding • binds minor groove • induce bending of DNA • has high affinity for non-canonical DNA-structures such as : • cruciform DNA • 4-way junctions • cisplatin  kinked DNA +

  17. NMR-structures • Examples • HMG1 B-domain • LEF-1 • SRY • Yeast Nhp6p • Drosophila HMG-D • Common: 3 helix L-form • heliks II and III form an angle of about 80o • Conserved aromatic aa in kink • Basic concave side interact with DNA

  18. Similar structures of HMG domains

  19. Minor groove binding, intercalation and bending • Objective: shorten the distance between cis-elements facilitating interaction between bound factors • DNA <500bp relatively stiff  induced bending required • Mechanism for induced bending of DNA • Protein scaffold • HMG B-domain: L-shaped protein • TBP: sadle • Minor groove binding • DNA-binding face = hydrophobic surface that conforms to a wide, shallow minor groove • 4 residues inserted deep into the minor groove • Full or partial intercalation (“kile”)

  20. Intercalation in protein-induced DNA-bending • Partial intercalation in the DNA helix of a protein side chain introduces a kink in the DNA enhancing the bend • Large hydrophobic residues (N-term helix I) partially intercalates between two base pairs • The A-box HMG domain has only an Ala in the X position not large enough to intercalate, • Intercalation linked to bending also seen in other factors • Partial (TBP) • Inserted side chain unstacks two basepairs • side chain as stacking-partner • Full (ETS1) • side chain penetrates into the helix • side chain (Trp) as new stacking-partner • Result: helix axis direction altered

  21. Two points of intercalation, X and Y Basic tail Binds Major groove X only X and Y Y only X = major kink and intercalation site, Y=second kink due to partial intercalation

  22. Cooperation with TFs • A major role of non-seq.spec. architectural factors is to facilitate formation of complex nucleoprotein assemblies • Need interaction with sequence specific TF to be directed to precise locations • An introduced bend could facilitate binding of one factor, and this could subsequently assist a second factor • The seq.spec. architectural factors is known to participate in the formation of complex nucleoprotein assemblies like enhanceosomes • TCRa and Interferon b

  23. Are all TFs architectural? • A large number of publications “TFx bends DNA” • positive reports “TFx bends DNA” • negative reports “TFx does not bend DNA” • All TFs that bind on one side of DNA will induce bending due to one-sided neutralization of charge • Degree of bending will depend on ionic condition • Uncertain if biologically relevant • The term “Architectural TFs“ should be reserved for factors with a particularly developed bending mechanism

  24. The charge neutralization model

  25. 2. subgruppe: HMGA .. First described by Søren Laland, an almost forgotten discovery

  26. HMGA - proteins with AT-hook • The mammalian HMGI/Y (HMGA) proteins participate in a wide variety of cellular processes • including regulation of gene trx and induction of neoplastic transformation and promotion of metastatic progression. • All members have multiple copies of a DNA-binding motif called the `AT hook' • that binds to the narrow minor groove of stretches of AT-rich sequence. • The proteins have little secondary structure in solution but assume distinct conformations when bound to DNA or other proteins • Their flexibility allows the HMGI/Y proteins to induce both structural changes in chromatin substrates and the formation of stereospecific complexes called `enhanceosomes'. Reciprocal conformational changes occur in both the HMGI/Y proteins themselves and in their interacting substrates.

  27. Members • 4 known members • Alternatively splicing gives rise to two isoform proteins, HMGA1a (HMGI) and HMGA1b (HMGY). These two are identical in sequence except for a deletion of 11 residues between the the first and second AT hook in the latter. Alternative splicing also produces HMGA1c. • The related HMGA2 (HMGI-C) protein is coded for by a separate gene. • Conserved • Homologues of the mammalian HMGA proteins have been found in yeast, insects, plants and birds, as well as in all mammalian species examined.

  28. HMGA - AT-hook binding to DNA • Each HMGA protein possesses 3 similar, but independent, AT hooks • which have an invariant peptide core motif of Arg-Gly-Arg-Pro (”palindromic” consensus PRGRP) flanked on either side by other conserved positively charged residues. • The HMGA proteins bind, via the AT hooks, to the minor groove • of stretches of AT-rich DNA but recognize substrate structure, rather than nucleotide sequence.

  29. HMGA proteins heavily modified • The HMGA proteins are among the most highly phosphorylated proteins in the mammalian nucleus. • Cell cycle-dependent phosphorylation pga cdc2 activity in the G2/M phase of the cycle. • Sites: T53 and T78 situated at the N-terminal ends of the 2. and 3. AT-hook. Phosphorylation significantly reduces (>20-fold) DNA binding. • HMGA proteins are the downstream targets of a number of signal transduction pathways that lead to phosphorylation. • HMGA proteins are also acetylated • at Lys65 by CBP and at Lys71 by PCAF • …as well as methylated and poly-ADP ribosylated • Hypothesis: Modifications may alter DNA-binding specificity?

  30. Architectural effects • Architectural effects • Binding of full-length HMGA proteins can bend, straighten, unwind and induce loop formation in linear DNA molecules in vitro. • Multiple contact points with DNA may alter conformation of DNA • A single AT-hook preferentially binds to stretches of 4-6 bp of AT-rich sequence, and partially neutralizes the negatively charged backbone phosphates on only one face of the DNA helix. • The number and spacing of AT-rich binding sites in DNA influences the conformation of bound DNA and the biological effects elicited. • HMGA may also induce conformational change in proteins • HMGA forms protein-protein interactions with other transcription factors, which alters the 3D structure of the factors resulting in enhanced DNA binding and transcriptional activation.

  31. Maniatis: HMGI(Y) contributes to formation of enhanceosomes • virus-inducible enhancer in the IFN- gene (human interferon ) • cis-elements for NF-kB, IRF-1, ATF-2-c-Jun • Synthetic (multiple cis-elements) enhancer ≠ natural • Too high basal transcription • Less induction • Responds to several stimuli, while natural enhancer only responds to virus • Biological function depends of HMGI(Y) as architectural component • HMG I(Y) • First described by Lund and Laland • binds AT-rich DNA in minor groove (“AT-hook”)

  32. Recentverision

  33. Other functions of HMGA proteins • HMGA and cancer • HMGI/Y proteins are also involved in a diverse range of other cellular processes including pathologic processes such as neoplastic transformation and metastatic progression. • Chromosomal translocations in a long 3.intron • Intron 3 of the HMGA2 genes is extremely long (>25 kb in human and >60 kb in mouse) and separates the three exons that contain the AT hook motifs from the remainds of the 3´-untranslated tail region of the gene. • Translocation within the exceptionally long third intron are commonly observed in benign mesenchymal tumors.

  34. 3. subgruppe: HMGN

  35. HMGN proteins • Three functional domains of the HMGN proteins: • a bipartite nuclear localization signal (NLS), • a nucleosomal binding domain (NBD) • and a chromatin-unfolding domain (CHUD). The CHUD domain has a net negative charge. • Binding of HMGN proteins to nucleosomes decreases the compactness of chromatin, and facilitates trx

  36. HMGN: architectural elements reducing compactness of chromatin • Model of the binding of HMGN proteins to chromatin • HMGNs interact with both the DNA and the histone component of the nucleosome • The CHUD domain interacts with the amino terminus of histone H3. • May also affect H1 binding • Incorporation of HMGN proteins into chromatin is believed to reduce the compactness of the chromatin fiber.

More Related