Your search keyword '"Alessandro Vannini"' showing total 57 results

1. Structural basis of Ty3 retrotransposon integration at RNA Polymerase III-transcribed genes

Author

Guillermo Abascal-Palacios, Laura Jochem, Carlos Pla-Prats, Fabienne Beuron, and Alessandro Vannini

Subjects

Science

Abstract

Ty3 retrotransposon integrates with an exquisite specificity upstream of RNA Polymerase III-transcribed genes, such as transfer RNAs. Here the authors resolve a cryo-EM structure of an active Ty3 intasome in complex with a TFIIIB-bound tRNA promoter, shedding light into the molecular determinants of harmless retrotransposition.

Published

2021

2. Structure of human RNA polymerase III

Author

Ewan Phillip Ramsay, Guillermo Abascal-Palacios, Julia L. Daiß, Helen King, Jerome Gouge, Michael Pilsl, Fabienne Beuron, Edward Morris, Philip Gunkel, Christoph Engel, and Alessandro Vannini

Subjects

Science

Abstract

The eukaryotic RNA Polymerase III transcribes tRNAs, some ribosomal and spliceosomal RNAs. Here, the authors resolve a cryo-EM structure of human RNA Polymerase III in its apo form and complemented it with crystal structures and SAXS analysis of RPC5, revealing insights into the molecular mechanisms of Pol III transcription.

Published

2020

3. DNA origami-based single-molecule force spectroscopy elucidates RNA Polymerase III pre-initiation complex stability

Author

Kevin Kramm, Tim Schröder, Jerome Gouge, Andrés Manuel Vera, Kapil Gupta, Florian B. Heiss, Tim Liedl, Christoph Engel, Imre Berger, Alessandro Vannini, Philip Tinnefeld, and Dina Grohmann

Subjects

Science

Abstract

TATA-binding protein (TBP) and a transcription factor (TF) IIB-like factor are important constituents of all eukaryotic initiation complexes. Here, the authors use a DNA origami-based force clamp to investigate the assembly dynamics of human initiation complexes in the RNAP II and RNAP III systems at the single-molecule level under pico newton forces.

Published

2020

4. MCPH1 inhibits Condensin II during interphase by regulating its SMC2-Kleisin interface

Author

Martin Houlard, Erin E Cutts, Muhammad S Shamim, Jonathan Godwin, David Weisz, Aviva Presser Aiden, Erez Lieberman Aiden, Lothar Schermelleh, Alessandro Vannini, and Kim Nasmyth

Subjects

condensin, chromosome, microcephalin, condensation, cell cycle, cohesin, Medicine, Science, Biology (General), QH301-705.5

Abstract

Dramatic change in chromosomal DNA morphology between interphase and mitosis is a defining features of the eukaryotic cell cycle. Two types of enzymes, namely cohesin and condensin confer the topology of chromosomal DNA by extruding DNA loops. While condensin normally configures chromosomes exclusively during mitosis, cohesin does so during interphase. The processivity of cohesin’s loop extrusion during interphase is limited by a regulatory factor called WAPL, which induces cohesin to dissociate from chromosomes via a mechanism that requires dissociation of its kleisin from the neck of SMC3. We show here that a related mechanism may be responsible for blocking condensin II from acting during interphase. Cells derived from patients affected by microcephaly caused by mutations in the MCPH1 gene undergo premature chromosome condensation. We show that deletion of Mcph1 in mouse embryonic stem cells unleashes an activity of condensin II that triggers formation of compact chromosomes in G1 and G2 phases, accompanied by enhanced mixing of A and B chromatin compartments, and this occurs even in the absence of CDK1 activity. Crucially, inhibition of condensin II by MCPH1 depends on the binding of a short linear motif within MCPH1 to condensin II’s NCAPG2 subunit. MCPH1’s ability to block condensin II’s association with chromatin is abrogated by the fusion of SMC2 with NCAPH2, hence may work by a mechanism similar to cohesin. Remarkably, in the absence of both WAPL and MCPH1, cohesin and condensin II transform chromosomal DNAs of G2 cells into chromosomes with a solenoidal axis.

Published

2021

5. Linker histone H1.8 inhibits chromatin binding of condensins and DNA topoisomerase II to tune chromosome length and individualization

Author

Pavan Choppakatla, Bastiaan Dekker, Erin E Cutts, Alessandro Vannini, Job Dekker, and Hironori Funabiki

Subjects

chromosome compaction, mitosis, linker histone, nucleosome, Hi-C, chromatin, Medicine, Science, Biology (General), QH301-705.5

Abstract

DNA loop extrusion by condensins and decatenation by DNA topoisomerase II (topo II) are thought to drive mitotic chromosome compaction and individualization. Here, we reveal that the linker histone H1.8 antagonizes condensins and topo II to shape mitotic chromosome organization. In vitro chromatin reconstitution experiments demonstrate that H1.8 inhibits binding of condensins and topo II to nucleosome arrays. Accordingly, H1.8 depletion in Xenopus egg extracts increased condensins and topo II levels on mitotic chromatin. Chromosome morphology and Hi-C analyses suggest that H1.8 depletion makes chromosomes thinner and longer through shortening the average loop size and reducing the DNA amount in each layer of mitotic loops. Furthermore, excess loading of condensins and topo II to chromosomes by H1.8 depletion causes hyper-chromosome individualization and dispersion. We propose that condensins and topo II are essential for chromosome individualization, but their functions are tuned by the linker histone to keep chromosomes together until anaphase.

Published

2021

6. A commercial antibody to the human condensin II subunit NCAPH2 cross-reacts with a SWI/SNF complex component [version 1; peer review: 2 approved]

Author

Erin E. Cutts, Gillian C. Taylor, Mercedes Pardo, Lu Yu, Jimi C. Wills, Jyoti S. Choudhary, Alessandro Vannini, and Andrew J. Wood

Subjects

Medicine, Science

Abstract

Condensin complexes compact and disentangle chromosomes in preparation for cell division. Commercially available antibodies raised against condensin subunits have been widely used to characterise their cellular interactome. Here we have assessed the specificity of a polyclonal antibody (Bethyl A302-276A) that is commonly used as a probe for NCAPH2, the kleisin subunit of condensin II, in mammalian cells. We find that, in addition to its intended target, this antibody cross-reacts with one or more components of the SWI/SNF family of chromatin remodelling complexes in an NCAPH2-independent manner. This cross-reactivity, with an abundant chromatin-associated factor, is likely to affect the interpretation of protein and chromatin immunoprecipitation experiments that make use of this antibody probe.

Published

2021

7. Molecular mechanisms of Bdp1 in TFIIIB assembly and RNA polymerase III transcription initiation

Author

Jerome Gouge, Nicolas Guthertz, Kevin Kramm, Oleksandr Dergai, Guillermo Abascal-Palacios, Karishma Satia, Pascal Cousin, Nouria Hernandez, Dina Grohmann, and Alessandro Vannini

Subjects

Science

Abstract

Transcription initiation by RNA polymerase III requires TFIIIB, a complex formed by Brf1/Brf2, TBP and Bdp1. Here, the authors describe the crystal structure of a Brf2-TBP-Bdp1 complex bound to a DNA promoter and characterize the role of Bdp1 in TFIIIB assembly and pre-initiation complex formation.

Published

2017

8. Structural basis of SNAPc-dependent snRNA transcription initiation by RNA polymerase II

Author

Srinivasan Rengachari, Sandra Schilbach, Thangavelu Kaliyappan, Jerome Gouge, Kristina Zumer, Juliane Schwarz, Henning Urlaub, Christian Dienemann, Alessandro Vannini, and Patrick Cramer

Subjects

Structural Biology, Molecular Biology

Abstract

RNA polymerase II (Pol II) carries out transcription of both protein-coding and non-coding genes. Whereas Pol II initiation at protein-coding genes has been studied in detail, Pol II initiation at non-coding genes, such as small nuclear RNA (snRNA) genes, is less well understood at the structural level. Here, we study Pol II initiation at snRNA gene promoters and show that the snRNA-activating protein complex (SNAPc) enables DNA opening and transcription initiation independent of TFIIE and TFIIH in vitro. We then resolve cryo-EM structures of the SNAPc-containing Pol IIpre-initiation complex (PIC) assembled on U1 and U5 snRNA promoters. The core of SNAPc binds two turns of DNA and recognizes the snRNA promoter-specific proximal sequence element (PSE), located upstream of the TATA box-binding protein TBP. Two extensions of SNAPc, called wing-1 and wing-2, bind TFIIA and TFIIB, respectively, explaining how SNAPc directs Pol II to snRNA promoters. Comparison of structures of closed and open promoter complexes elucidates TFIIH-independent DNA opening. These results provide the structural basis of Pol II initiation at non-coding RNA gene promoters.

Published

2022

9. Structural basis of Ty3 retrotransposon integration at RNA Polymerase III-transcribed genes

Author

Alessandro Vannini, Laura Jochem, G. Abascal-Palacios, Fabienne Beuron, and Carlos Pla-Prats

Subjects

Saccharomyces cerevisiae Proteins, Retroelements, Science, Genes, Fungal, General Physics and Astronomy, Retrotransposon, Saccharomyces cerevisiae, Computational biology, Biology, General Biochemistry, Genetics and Molecular Biology, Article, RNA polymerase III, Chromodomain, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Retrovirus, RNA, Transfer, Transcription Factor TFIIIB, Cryoelectron microscopy, RNA polymerase, Transposition, Transcription factor, Gene, 030304 developmental biology, Genetics, 0303 health sciences, Multidisciplinary, General transcription factor, 030302 biochemistry & molecular biology, RNA Polymerase III, RNA, food and beverages, RNA-Directed DNA Polymerase, General Chemistry, DNA, biology.organism_classification, chemistry, Transfer RNA, RNA Polymerase II, Transcription, 030217 neurology & neurosurgery

Abstract

Retrotransposons are endogenous elements that have the ability to mobilise their DNA between different locations in the host genome. The Ty3 retrotransposon integrates with an exquisite specificity in a narrow window upstream of RNA Polymerase (Pol) III-transcribed genes, representing a paradigm for harmless targeted integration. Here we present the cryo-EM reconstruction at 4.0 Å of an active Ty3 strand transfer complex bound to TFIIIB transcription factor and a tRNA gene. The structure unravels the molecular mechanisms underlying Ty3 targeting specificity at Pol III-transcribed genes and sheds light into the architecture of retrotransposon machinery during integration. Ty3 intasome contacts a region of TBP, a subunit of TFIIIB, which is blocked by NC2 transcription regulator in RNA Pol II-transcribed genes. A newly-identified chromodomain on Ty3 integrase interacts with TFIIIB and the tRNA gene, defining with extreme precision the integration site position., Ty3 retrotransposon integrates with an exquisite specificity upstream of RNA Polymerase III-transcribed genes, such as transfer RNAs. Here the authors resolve a cryo-EM structure of an active Ty3 intasome in complex with a TFIIIB-bound tRNA promoter, shedding light into the molecular determinants of harmless retrotransposition.

Published

2021

10. Condensin complexes: understanding loop extrusion one conformational change at a time

Author

Alessandro Vannini and Erin E. Cutts

Subjects

chromosomes, Conformational change, Saccharomyces cerevisiae Proteins, Chromosomal Proteins, Non-Histone, Protein Conformation, Condensin, Cell Cycle Proteins, Saccharomyces cerevisiae, macromolecular substances, Chaetomium, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Condensin complex, Adenosine Triphosphate, 0302 clinical medicine, Protein structure, Protein Domains, Structural Biology, Gene Expression Regulation, Fungal, Humans, Protein Isoforms, DNA binding, DNA, Chromosomes & Chromosomal Structure, Review Articles, 030304 developmental biology, Adenosine Triphosphatases, 0303 health sciences, biology, Cohesin, SMC, condensin, Cryoelectron Microscopy, Nuclear Proteins, DNA, Chromatin, Cell biology, DNA-Binding Proteins, chemistry, Structural biology, Multiprotein Complexes, Mutation, biology.protein, single-molecule, biological phenomena, cell phenomena, and immunity, Dimerization, 030217 neurology & neurosurgery, Protein Binding

Abstract

Condensin and cohesin, both members of the structural maintenance of chromosome (SMC) family, contribute to the regulation and structure of chromatin. Recent work has shown both condensin and cohesin extrude DNA loops and most likely work via a conserved mechanism. This review focuses on condensin complexes, highlighting recent in vitro work characterising DNA loop formation and protein structure. We discuss similarities between condensin and cohesin complexes to derive a possible mechanistic model, as well as discuss differences that exist between the different condensin isoforms found in higher eukaryotes.

Published

2020

11. The human RNA polymerase I structure reveals an HMG-like transcription factor docking domain specific to metazoans

Author

Julia L. Daiß, Michael Pilsl, Kristina Straub, Andrea Bleckmann, Mona Höcherl, Florian B. Heiss, Guillermo Abascal-Palacios, Ewan Ramsay, Katarina Tlučková, Jean-Clement Mars, Astrid Bruckmann, Carrie Bernecky, Valérie Lamour, Konstantin Panov, Alessandro Vannini, Tom Moss, and Christoph Engel

Abstract

Transcription of the ribosomal RNA precursor by RNA polymerase (Pol) I is a major determinant of cellular growth and dysregulation is observed in many cancer types. Here, we present the purification of human Pol I from cells carrying a genomic GFP-fusion on the largest subunit allowing the structural and functional analysis of the enzyme across species. In contrast to yeast, human Pol I carries a single-subunit stalk and in vitro transcription indicates a reduced proofreading activity. Determination of the human Pol I cryo-EM reconstruction in a close-to-native state rationalizes the effects of disease-associated mutations and uncovers an additional domain that is built into the sequence of Pol I subunit RPA1. This ‘dock II’ domain resembles a truncated HMG-box incapable of DNA-binding which may serve as a downstream-transcription factor binding platform in metazoans. Biochemical analysis and ChIP data indicate that Topoisomerase 2a can be recruited to Pol I via the domain and cooperates with the HMG-box domain containing factor UBF. These adaptations of the metazoan Pol I transcription system may allow efficient release of positive DNA supercoils accumulating downstream of the transcription bubble.

Published

2021

12. MCPH1 inhibits Condensin II during interphase by regulating its SMC2-Kleisin interface

Author

Aviva Presser Aiden, Erez Lieberman Aiden, Alessandro Vannini, Martin Houlard, Lothar Schermelleh, Muhammad S. Shamim, Erin E. Cutts, Kim Nasmyth, David Weisz, and Jonathan Godwin

Subjects

Mouse, QH301-705.5, Science, Condensin, cohesin, Cell Cycle Proteins, macromolecular substances, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Mice, Biochemistry and Chemical Biology, Animals, chromosome, Biology (General), Mitosis, Interphase, Embryonic Stem Cells, 030304 developmental biology, 0303 health sciences, General Immunology and Microbiology, Cohesin, biology, microcephalin, Chemistry, General Neuroscience, condensin, 030302 biochemistry & molecular biology, General Medicine, Cell Biology, Cell cycle, Cell biology, Chromatin, condensation, Cytoskeletal Proteins, Gene Expression Regulation, Premature chromosome condensation, biology.protein, Medicine, Chromatid, cell cycle, biological phenomena, cell phenomena, and immunity, Metabolic Networks and Pathways, Research Article, Human

Abstract

The dramatic change in morphology of chromosomal DNAs between interphase and mitosis is one of the defining features of the eukaryotic cell cycle. Two types of enzymes, namely cohesin and condensin confer the topology of chromosomal DNA by extruding DNA loops. While condensin normally configures chromosomes exclusively during mitosis, cohesin does so during interphase. The processivity of cohesin's loop extrusion during interphase is limited by a regulatory factor called WAPL, which induces cohesin to dissociate from chromosomes via a mechanism that requires dissociation of its kleisin from the neck of SMC3. We show here that a related mechanism may be responsible for blocking condensin II from acting during interphase. Cells derived from patients affected by microcephaly caused by mutations in the MCPH1 gene undergo premature chromosome condensation but it has never been established for certain whether MCPH1 regulates condensin II directly. We show that deletion of Mcph1 in mouse embryonic stem cells unleashes an activity of condensin II that triggers formation of compact chromosomes in G1 and G2 phases, which is accompanied by enhanced mixing of A and B chromatin compartments, and that this occurs even in the absence of CDK1 activity. Crucially, inhibition of condensin II by MCPH1 depends on the binding of a short linear motif within MCPH1 to condensin II's NCAPG2 subunit. We show that the activities of both Cohesin and Condensin II may be restricted during interphase by similar types of mechanisms as MCPH1's ability to block condensin II's association with chromatin is abrogated by the fusion of SMC2 with NCAPH2. Remarkably, in the absence of both WAPL and MCPH1, cohesin and condensin II transform chromosomal DNAs of G2 cells into chromosomes with a solenoidal axis showing that both cohesin and condensin must be tightly regulated to adjust the structure of chromatids for their successful segregation.

Published

2021

13. Author response: MCPH1 inhibits Condensin II during interphase by regulating its SMC2-Kleisin interface

Author

Erin E Cutts, Martin Houlard, Muhammad S Shamim, Jonathan Godwin, David Weisz, Aviva Presser Aiden, Erez Lieberman Aiden, Lothar Schermelleh, Alessandro Vannini, and Kim Nasmyth

Published

2021

14. A small nucleosome from a weird virus with a fat genome

Author

Alessandro Vannini and Ivan Marazzi

Subjects

viruses, nucleosome-like-particle, Biology, Genome, acidic patch, Virus, Article, viral factory, viral nucleosome, Nucleosome, histone tail, Giant Virus, KO fitness impact, Analytical Ultracentrifugation, Molecular Biology, giant virus, Genetics, Melbournevirus genetics, Cell Biology, doublet histone, Nucleosomes, Giant Viruses, Viruses, NCLDV, cryo-EM, non-eukaryotic nucleosome

Abstract

Summary The organization of genomic DNA into defined nucleosomes has long been viewed as a hallmark of eukaryotes. This paradigm has been challenged by the identification of “minimalist” histones in archaea and more recently by the discovery of genes that encode fused remote homologs of the four eukaryotic histones in Marseilleviridae, a subfamily of giant viruses that infect amoebae. We demonstrate that viral doublet histones are essential for viral infectivity, localize to cytoplasmic viral factories after virus infection, and ultimately are found in the mature virions. Cryogenic electron microscopy (cryo-EM) structures of viral nucleosome-like particles show strong similarities to eukaryotic nucleosomes despite the limited sequence identify. The unique connectors that link the histone chains contribute to the observed instability of viral nucleosomes, and some histone tails assume structural roles. Our results further expand the range of “organisms” that require nucleosomes and suggest a specialized function of histones in the biology of these unusual viruses., Graphical abstract, Highlights • Marseilleviridae encode proteins that resemble fused histones H4-H3 and H2B-H2A • These histone doublets assemble into unstable nucleosome-like particles in vitro • Histone doublets localize to the viral factory and are highly abundant in the virus • They are essential for viral fitness and infectivity, a first for any virus, Some viruses can package DNA into particles that resemble eukaryotic nucleosomes, with noteworthy similarities and differences.

Published

2021

15. Decision letter: Molecular architecture of the human tRNA ligase complex

Author

Alessandro Vannini and Oliver Weichenrieder

Published

2021

16. Linker histone H1.8 inhibits chromatin binding of condensins and DNA topoisomerase II to tune chromosome length and individualization

Author

Alessandro Vannini, Hironori Funabiki, Pavan Choppakatla, Bastiaan Dekker, Job Dekker, and Erin E. Cutts

Subjects

Cell Extracts, Xenopus, Condensin, Histones, Xenopus laevis, 0302 clinical medicine, Hi-C, Biology (General), Anaphase, Adenosine Triphosphatases, 0303 health sciences, biology, Chemistry, General Neuroscience, Chromatin binding, General Medicine, Chromosomes and Gene Expression, Chromatin, Cell biology, DNA-Binding Proteins, linker histone, Histone, Medicine, Female, Research Article, QH301-705.5, Science, chromosome compaction, Spindle Apparatus, macromolecular substances, Models, Biological, Chromosomes, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Histone H1, Animals, Nucleosome, Mitosis, 030304 developmental biology, mitosis, General Immunology and Microbiology, nucleosome, DNA Topoisomerases, Type II, Multiprotein Complexes, Oocytes, biology.protein, chromatin, 030217 neurology & neurosurgery

Abstract

DNA loop extrusion by condensins and decatenation by DNA topoisomerase II (topo II) are thought to drive mitotic chromosome compaction and individualization. Here, we reveal that the linker histone H1.8 antagonizes condensins and topo II to shape mitotic chromosome organization. In vitro chromatin reconstitution experiments demonstrate that H1.8 inhibits binding of condensins and topo II to nucleosome arrays. Accordingly, H1.8 depletion in Xenopus egg extracts increased condensins and topo II levels on mitotic chromatin. Chromosome morphology and Hi-C analyses suggest that H1.8 depletion makes chromosomes thinner and longer through shortening the average loop size and reducing the DNA amount in each layer of mitotic loops. Furthermore, excess loading of condensins and topo II to chromosomes by H1.8 depletion causes hyper-chromosome individualization and dispersion. We propose that condensins and topo II are essential for chromosome individualization, but their functions are tuned by the linker histone to keep chromosomes together until anaphase.

Published

2021

17. MCPH1 inhibits condensin II during interphase by regulating its SMC2-kleisin interface

Author

Alessandro Vannini, David Weisz, Martin Houlard, Erez Lieberman Aiden, Muhammad S. Shamim, Kim Nasmyth, Jonathan Godwin, Erin E. Cutts, Aviva Presser Aiden, and Lothar Schermelleh

Subjects

biology, Cohesin, Chemistry, Condensin, Premature chromosome condensation, biology.protein, Interphase, macromolecular substances, Processivity, Cell cycle, Mitosis, Chromatin, Cell biology

Abstract

The dramatic change in morphology of chromosomal DNAs between interphase and mitosis is one of the defining features of the eukaryotic cell cycle. Two types of enzymes, namely cohesin and condensin confer the topology of chromosomal DNA by extruding DNA loops. While condensin normally configures chromosomes exclusively during mitosis, cohesin does so during interphase. The processivity of cohesin’s LE during interphase is limited by a regulatory factor called WAPL, which induces cohesin to dissociate from chromosomes via a mechanism that requires dissociation of its kleisin from the neck of SMC3. We show here that a related mechanism may be responsible for blocking condensin II from acting during interphase. Cells from patients carrying mutations in the Mcph1 gene undergo premature chromosome condensation but it has never been established for certain whether MCPH1 regulates condensin II directly. We show that deletion of Mcph1 in mouse embryonic stem cells unleashes an activity of condensin II that triggers formation of compact chromosomes in G1 and G2 phases, which is accompanied by enhanced mixing of A and B chromatin compartments, and that this occurs even in the absence of CDK1 activity. Crucially, inhibition of condensin II by MCPH1 depends on the binding of a short linear motif within MCPH1 to condensin II’s NCAPG2 subunit. We show that the activities of both Cohesin and Condensin II may be restricted during interphase by similar types of mechanisms as MCPH1’s ability to block condensin II’s association with chromatin is abrogated by the fusion of SMC2 with NCAPH2. Remarkably, in the absence of both WAPL and MCPH1, cohesin and condensin II transform chromosomal DNAs of G2 cells into chromosomes with a solenoidal axis showing that both SMC complexes must be tightly regulated to adjust both the chromatid’s structure and their segregation.

Published

2021

18. Author response: Linker histone H1.8 inhibits chromatin binding of condensins and DNA topoisomerase II to tune chromosome length and individualization

Author

Erin E. Cutts, Hironori Funabiki, Job Dekker, Bastiaan Dekker, Alessandro Vannini, and Pavan Choppakatla

Subjects

DNA Topoisomerase II, biology, Histone H1, Chemistry, Condensin, Chromatin binding, biology.protein, Chromosome, Linker, Cell biology

Published

2021

19. Linker histone H1.8 inhibits chromatin-binding of condensins and DNA topoisomerase II to tune chromosome length and individualization

Author

Alessandro Vannini, Pavan Choppakatla, Bastiaan Dekker, Erin E. Cutts, Job Dekker, and Hironori Funabiki

Subjects

biology, Condensin, Chromatin binding, macromolecular substances, Chromatin, Cell biology, chemistry.chemical_compound, Histone, Histone H1, chemistry, biology.protein, Nucleosome, Mitosis, DNA

Abstract

SummaryDNA loop extrusion by condensins and decatenation by DNA topoisomerase II (topo II) are thought to drive mitotic chromosome compaction and individualization. Here, we reveal that the linker histone H1.8 antagonizes condensins and topo II to shape mitotic chromosome organization. In vitro chromatin reconstitution experiments demonstrate that H1.8 inhibits binding of condensins and topo II to nucleosome arrays. Accordingly, H1.8 depletion in Xenopus egg extracts increased condensins and topo II levels on mitotic chromatin. Chromosome morphology and Hi-C analyses suggest that H1.8 depletion makes chromosomes thinner and longer through shortening the average loop size and reducing the DNA amount in each layer of mitotic loops. Furthermore, excess loading of condensins and topo II to chromosomes by H1.8 depletion causes hyper-chromosome individualization and dispersion. We propose that condensins and topo II are essential for chromosome individualization, but their functions are tuned by the linker histone to keep chromosomes together until anaphase.

Published

2020

20. Structure of human RNA polymerase III

Author

Philip Gunkel, E.P. Ramsay, Christoph Engel, Edward P. Morris, Michael Pilsl, Jerome Gouge, Alessandro Vannini, Julia L. Daiß, Fabienne Beuron, Helen King, and G. Abascal-Palacios

Subjects

CRISPR-Cas9 genome editing, Models, Molecular, 0301 basic medicine, Protein Conformation, viruses, General Physics and Astronomy, chemistry.chemical_compound, 0302 clinical medicine, X-Ray Diffraction, Genome editing, Transcription (biology), RNA polymerase, Enzyme Stability, Genetics, chemistry.chemical_classification, 0303 health sciences, Multidisciplinary, SAXS, DNA-Directed RNA Polymerases, 3. Good health, Cell biology, Eukaryote, Transcription, Protein subunit, Science, Biology, bcs, Article, General Biochemistry, Genetics and Molecular Biology, RNA polymerase III, 03 medical and health sciences, Downregulation and upregulation, Scattering, Small Angle, Humans, X-ray crystallography, 030304 developmental biology, Cryoelectron Microscopy, RNA Polymerase III, General Chemistry, Ribosomal RNA, biology.organism_classification, Protein Subunits, 030104 developmental biology, Enzyme, chemistry, Mutation, 030217 neurology & neurosurgery, DNA, Biogenesis, HeLa Cells

Abstract

In eukaryotes, RNA Polymerase (Pol) III is specialized for the transcription of tRNAs and other short, untranslated RNAs. Pol III is a determinant of cellular growth and lifespan across eukaryotes. Upregulation of Pol III transcription is observed in cancer and causative Pol III mutations have been described in neurodevelopmental disorders and hypersensitivity to viral infection. Here, we report a cryo-EM reconstruction at 4.0 Å of human Pol III, allowing mapping and rationalization of reported genetic mutations. Mutations causing neurodevelopmental defects cluster in hotspots affecting Pol III stability and/or biogenesis, whereas mutations affecting viral sensing are located in proximity to DNA binding regions, suggesting an impairment of Pol III cytosolic viral DNA-sensing. Integrating x-ray crystallography and SAXS, we also describe the structure of the higher eukaryote specific RPC5 C-terminal extension. Surprisingly, experiments in living cells highlight a role for this module in the assembly and stability of human Pol III., The eukaryotic RNA Polymerase III transcribes tRNAs, some ribosomal and spliceosomal RNAs. Here, the authors resolve a cryo-EM structure of human RNA Polymerase III in its apo form and complemented it with crystal structures and SAXS analysis of RPC5, revealing insights into the molecular mechanisms of Pol III transcription.

Published

2020

21. A micronutrient with major effects on cancer cell viability

Author

Anastasia, Kapara, Alessandro, Vannini, and Barrie, Peck

Published

2020

22. Hybrid Gene Origination Creates Human-Virus Chimeric Proteins during Infection

Author

Jiajie Wei, Paul Digard, Robert J. Gifford, Nerea Irigoyen, Megan K. L. MacLeod, Alessandro Vannini, James P. Gibbs, Laura Campisi, Brad R. Rosenberg, Joshua D. Jones, Max W. Chang, Cheng Huang, Quan Gu, Edward C. Hutchinson, Veronica V. Rezelj, Christopher Benner, Helen M. Wise, Jessica Sook Yuin Ho, Jeffrey R. Johnson, Guojun Wang, Matthew Angel, Yesai Fstkchyan, Slobodan Paessler, Robyn M. Kaake, Nan Zhao, Maria João Amorim, Marta Alenquer, Elizabeth Sloan, Sara Clohisey, Ingeborg van Knippenberg, Harm van Bakel, Simin Zheng, Nevan J. Krogan, Liliane Chung, Adam M. Dinan, Bo Wang, Benjamin Greenbaum, Léa Meyer, Natasha Moshkina, Ian Brierley, Zeyu Zhu, Zuleyma Peralta, Adolfo García-Sastre, Andrew E. Firth, Marta Łuksza, Emily R. Miraldi, Vladimir Roudko, Ivan Marazzi, Rong Shen, Carles Martínez-Romero, Yixuan Ma, Jonathan W. Yewdell, J Kenneth Baillie, Justine Noel, Dinan, Adam [0000-0003-2812-1616], Irigoyen, Nerea [0000-0001-6346-3369], Brierley, Ian [0000-0003-3965-4370], Firth, Andrew [0000-0002-7986-9520], and Apollo - University of Cambridge Repository

Subjects

Transcription, Genetic, viruses, Mutant Chimeric Proteins, medicine.disease_cause, Virus Replication, gene origination, segmented negative-strand RNA viruses, viral evolution, Mice, 0302 clinical medicine, RNA Virus Infections, Cricetinae, RNA hybrid, Genetics, 0303 health sciences, 3. Good health, Influenza A virus, Viral evolution, RNA, Viral, influenza, RNA Caps, Recombinant Fusion Proteins, Biology, General Biochemistry, Genetics and Molecular Biology, Cap snatching, Cell Line, 03 medical and health sciences, Open Reading Frames, Viral Proteins, Dogs, chimeric proteins, Plant virus, upstream AUG, medicine, uORFs, Animals, Humans, RNA Viruses, RNA, Messenger, Gene, 030304 developmental biology, RNA, cap-snatching, RNA-Dependent RNA Polymerase, Fusion protein, viral RNA, Lassa virus, Cattle, Human Virus, 5' Untranslated Regions, 030217 neurology & neurosurgery

Abstract

RNA viruses are a major human health threat. The life cycles of many highly pathogenic RNA viruses like influenza A virus (IAV) and Lassa virus depends on host mRNA, as viral polymerases cleave 5’-m7G-capped host transcripts to primeviral mRNA synthesis (‘cap-snatching’). We hypothesized that start codons within cap-snatched host transcripts could generate chimeric human-viral mRNAs with coding potential. We report the existence of this mechanism of gene origination, that we named ‘start-snatching’. Depending on the reading frame, start-snatching allows the translation of host and viral “untranslated regions” (UTRs) to create Nterminallyextended viral proteins or entirely novel polypeptides by geneticoverprinting. We show that both types of chimeric proteins are made in IAVinfectedcells, generate T cell responses and contribute to virulence. Our resultsindicate that during infection with IAV, and likely a multitude of other human-,animal- and plant-viruses, a host-dependent mechanism allows the genesis ofhybrid genes.

Published

2020

23. Redox regulation at the heart of RNA Polymerase III gene transcription machinery

Author

Alessandro Vannini

Subjects

Physiology (medical), Biochemistry

Published

2021

24. A micronutrient with major effects on cancer cell viability

Author

Alessandro Vannini, Barrie Peck, and Anastasia Kapara

Subjects

chemistry.chemical_classification, Reactive oxygen species, Mechanism (biology), Endocrinology, Diabetes and Metabolism, chemistry.chemical_element, Cell Biology, Micronutrient, Cell biology, chemistry.chemical_compound, chemistry, Physiology (medical), Selenide, Cancer cell, Internal Medicine, Selenium, Function (biology)

Abstract

Selenium is a micronutrient essential for the generation of selenoproteins, which function predominantly by detoxifying cellular reactive oxygen species. In this issue, Carlisle et al. describe a novel mechanism whereby perturbing selenium utilization via inhibition of SEPHS2, a component of the selenocysteine-biosynthesis pathway, results in selenide poisoning and cancer cell death.

Published

2020

25. DNA origami-based single-molecule force spectroscopy unravels the molecular basis of RNA Polymerase III pre-initiation complex stability

Author

Andrés Manuel Vera, Philip Tinnefeld, Tim Schröder, Christoph Engel, Alessandro Vannini, Kevin Kramm, Dina Grohmann, Tim Liedl, Florian B. Heiss, and Jerome Gouge

Subjects

0303 health sciences, biology, Chemistry, BDP1, RNA polymerase II, RNA polymerase III, enzymes and coenzymes (carbohydrates), 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, RNA polymerase, biology.protein, Biophysics, Initiation factor, Transcription factor II B, 030217 neurology & neurosurgery, Polymerase, DNA, 030304 developmental biology

Abstract

The TATA-binding protein (TBP) and a transcription factor (TF) IIB-like factor compound the fundamental core of all eukaryotic initiation complexes. The reason for the emergence and strict requirement of the additional intiation factor Bdp1, which is unique to the RNA polymerase (RNAP) III sytem, however, remained elusive. A poorly studied aspect in this context is the effect of DNA strain, that arises from DNA compaction and transcriptional activity, on the efficiency of initiation complex formation. We made use of a new nanotechnological tool – a DNA origami-based force clamp - to follow the assembly of human initiation complexes in the Pol II and Pol III system at the single-molecule level under piconewton forces. We demonstrate that TBP-DNA complexes are force-sensitive and TFIIB is necessary and sufficient to stabilise TBP on a strained RNAP II promoter. In contrast, Bdp1 is the pivotal component that ensures stable anchoring of initiation factors, and thus the polymerase itself, in the RNAP III system. Thereby, we offer an explanation for the crucial role of Bdp1 for the high transcriptional output of Pol III genes for the first time.

Published

2019

26. Decision letter: The cryo-EM structure of a 12-subunit variant of RNA polymerase I reveals dissociation of the A49-A34.5 heterodimer and rearrangement of subunit A12.2

Author

Alessandro Vannini

Subjects

Cryo-electron microscopy, Chemistry, Protein subunit, RNA polymerase I, Biophysics, Dissociation (chemistry)

Published

2018

27. A commercial antibody to the human condensin II subunit NCAPH2 cross-reacts with a SWI/SNF complex component

Author

Andrew J. Wood, Gillian C.A. Taylor, Erin E. Cutts, Jimi Wills, Alessandro Vannini, Jyoti S. Choudhary, Lu Yu, and Mercedes Pardo

Subjects

Cell division, Condensin, Protein subunit, Medicine (miscellaneous), macromolecular substances, Interactome, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Condensin complex, 0302 clinical medicine, antibody, PBAF, BAF, 030304 developmental biology, 0303 health sciences, biology, SWI/SNF complex, Chemistry, condensin, Articles, SWI/SNF, Cell biology, Polyclonal antibodies, biology.protein, SMC complex, specificity, Chromatin immunoprecipitation, 030217 neurology & neurosurgery, Research Article

Abstract

SummaryCondensin complexes compact and disentangle chromosomes in preparation for cell division. Commercially available antibodies raised against condensin subunits have been widely used to characterise their cellular interactome. Here we have assessed the specificity of a polyclonal antibody (Bethyl A302-276A) that is commonly used as a probe for NCAPH2, the kleisin subunit of condensin II, in mammalian cells. We find that, in addition to its intended target, this antibody cross-reacts with one or more components of the SWI/SNF family of chromatin remodelling complexes in an NCAPH2-independent manner. This cross-reactivity with an abundant chromatin-associated factor is likely to affect the interpretation of protein and chromatin immunoprecipitation experiments that make use of this antibody probe.

Published

2021

28. RNA polymerase I, bending the rules?

Author

Laura Jochem, Alessandro Vannini, and E.P. Ramsay

Subjects

Models, Molecular, 0301 basic medicine, Saccharomyces cerevisiae Proteins, Transcription, Genetic, RNA polymerase II, Saccharomyces cerevisiae, Crystallography, X-Ray, General Biochemistry, Genetics and Molecular Biology, RNA polymerase III, 03 medical and health sciences, 0302 clinical medicine, RNA Polymerase I, Transcriptional regulation, News & Views, Promoter Regions, Genetic, Molecular Biology, RNA polymerase II holoenzyme, Transcription Initiation, Genetic, Genetics, General Immunology and Microbiology, biology, General transcription factor, General Neuroscience, Cryoelectron Microscopy, Processivity, 030104 developmental biology, Multiprotein Complexes, biology.protein, Transcription factor II F, Transcription factor II D, 030217 neurology & neurosurgery

Abstract

Transcription initiation at the ribosomal RNA promoter requires RNA polymerase (Pol) I and the initiation factors Rrn3 and core factor (CF). Here, we combine X-ray crystallography and cryo-electron microscopy (cryo-EM) to obtain a molecular model for basal Pol I initiation. The three-subunit CF binds upstream promoter DNA, docks to the Pol I-Rrn3 complex, and loads DNA into the expanded active center cleft of the polymerase. DNA unwinding between the Pol I protrusion and clamp domains enables cleft contraction, resulting in an active Pol I conformation and RNA synthesis. Comparison with the Pol II system suggests that promoter specificity relies on a distinct "bendability" and "meltability" of the promoter sequence that enables contacts between initiation factors, DNA, and polymerase.

Published

2017

29. Human Condensin I and II Drive Extensive ATP-Dependent Compaction of Nucleosome-Bound DNA

Author

Dongqing Pan, Muwen Kong, Edward P. Morris, Eric C. Greene, Andrea Musacchio, Fabienne Beuron, Alessandro Vannini, Erin E. Cutts, Thangavelu Kaliyappan, and Chaoyou Xue

Subjects

Models, Molecular, Protein Conformation, Condensin, DNA curtain, single molecule, macromolecular substances, Article, 03 medical and health sciences, Condensin complex, chemistry.chemical_compound, Adenosine Triphosphate, 0302 clinical medicine, Condensin II, Humans, Nucleosome, Motor activity, Molecular Biology, 030304 developmental biology, Genomic organization, Adenosine Triphosphatases, 0303 health sciences, loop extrusion, electron microscopy, biology, condensin, crosslinking mass spectroscopy, DNA, Cell Biology, SMC complexes, Single Molecule Imaging, chromosome organization, Nucleosomes, Cell biology, DNA-Binding Proteins, chemistry, Multiprotein Complexes, biology.protein, Condensin I, 030217 neurology & neurosurgery, Protein Binding

Abstract

Summary Structural maintenance of chromosomes (SMC) complexes are essential for genome organization from bacteria to humans, but their mechanisms of action remain poorly understood. Here, we characterize human SMC complexes condensin I and II and unveil the architecture of the human condensin II complex, revealing two putative DNA-entrapment sites. Using single-molecule imaging, we demonstrate that both condensin I and II exhibit ATP-dependent motor activity and promote extensive and reversible compaction of double-stranded DNA. Nucleosomes are incorporated into DNA loops during compaction without being displaced from the DNA, indicating that condensin complexes can readily act upon nucleosome-bound DNA molecules. These observations shed light on critical processes involved in genome organization in human cells., Graphical Abstract, Highlights • Architecture of ATPγS-bound human condensin II • Human condensin II possesses two putative DNA binding compartments • Human condensins drive robust ATP-dependent compaction of nucleosome-bound DNA • Loop extrusion by human condensins can be symmetric or asymmetric, Kong and Cutts et al. present the general architecture of ATPγS-bound human condensin I and II complexes. They demonstrate that both human condensins are ATP-dependent motors that drive robust compaction of nucleosome-bound DNA, in either a symmetric or asymmetric manner, supporting the loop extrusion model under physiological conditions in higher eukaryotes.

Published

2020

30. TFIIIC binding to Alu elements controls gene expression via chromatin looping and histone acetylation

Author

Roberto Ferrari, Enrique Vidal, Susana de la Luna, Giorgio Dieci, Lara Isabel de Llobet Cucalon, Chiara Di Vona, Antonios Lioutas, Miguel Beato, Erin E. Cutts, Laura Jochem, Javier Quilez Oliete, Martin Teichmann, François Le Dilly, and Alessandro Vannini

Subjects

Transcription, Genetic, Alu element, Nerve Tissue Proteins, RNA polymerase II, serum starvation, Article, Cell Line, Epigenesis, Genetic, Cromatina, Histones, 03 medical and health sciences, Histone H3, breast cancer, 0302 clinical medicine, Alu Elements, Transcription Factors, TFIII, Pol II, Humans, ADPN, Epigenetics, Promoter Regions, Genetic, Molecular Biology, Transcription factor, TFIIIC, 030304 developmental biology, Homeodomain Proteins, 0303 health sciences, General transcription factor, biology, 3D genome structure, RNA Polymerase III, Acetylation, Promoter, Cell Biology, CTCF, Expressió gènica, Chromatin, Cell biology, H3K18ac, Histone, Gene Expression Regulation, biology.protein, cell cycle, Protein Processing, Post-Translational, 030217 neurology & neurosurgery

Abstract

Summary How repetitive elements, epigenetic modifications, and architectural proteins interact ensuring proper genome expression remains poorly understood. Here, we report regulatory mechanisms unveiling a central role of Alu elements (AEs) and RNA polymerase III transcription factor C (TFIIIC) in structurally and functionally modulating the genome via chromatin looping and histone acetylation. Upon serum deprivation, a subset of AEs pre-marked by the activity-dependent neuroprotector homeobox Protein (ADNP) and located near cell-cycle genes recruits TFIIIC, which alters their chromatin accessibility by direct acetylation of histone H3 lysine-18 (H3K18). This facilitates the contacts of AEs with distant CTCF sites near promoter of other cell-cycle genes, which also become hyperacetylated at H3K18. These changes ensure basal transcription of cell-cycle genes and are critical for their re-activation upon serum re-exposure. Our study reveals how direct manipulation of the epigenetic state of AEs by a general transcription factor regulates 3D genome folding and expression., Graphical Abstract, Highlights • Serum starvation recruits TFIIIC at ADNP-bound Alu Elements (AEs) near Pol II genes • TFIIIC-associated histone acetylase activity acetylates H3K18 over the bound AEs • TFIIIC-bound acetylated AEs loop to contact CTCF at distal cell-cycle genes’ promoters • CTCF-TFIIIC interaction ensures rapid cell-cycle genes’ reactivation on serum exposure, Repetitive elements shape genome structure and function. Ferrari et al. find that cells respond to serum deprivation by redirecting the general transcription factor TFIIIC to acetylate ADNP-bound Alu elements in order to rewire the 3D genome architecture via CTCF looping, ultimately sustaining steady-state levels of cell-cycle-regulated gene expression.

Published

2018

31. Troubleshooting biGBac: a practical guide v1

Author

Erin E. Cutts and Alessandro Vannini

Subjects

Computer science, business.industry, Troubleshooting, Software engineering, business

Abstract

The biGBac system presented by Weissmann et al. (Weissmann et al, 2016 and Weissmann et al, 2018) is a modular insect cell expression system designed for expression of multi-subunit complexes. The system is very powerful, allowing up to 25 genes to be assembled into one baculo-virus expression vector, but does require a reasonable amount of cloning experience in order to attain clones in the 6 day time frame stated in the paper. This guide was written to provide a detailed explanation how the system is designed, how it can be further exploited and provide in-depth practical information that even a novice cloner can follow.

Published

2018

32. Mechanism of selective recruitment of RNA polymerases II and III to snRNA gene promoters

Author

Oleksandr Dergai, Alessandro Vannini, Viviane Praz, Nouria Hernandez, Tracy Kuhlman, Jerome Gouge, Pascal Cousin, Philippe Lhote, and Karishma Satia

Subjects

0301 basic medicine, TATA box, viruses, RNA polymerase II, Biology, bcs, RNA polymerase III, HEK293 Cells, Humans, Mutation, Promoter Regions, Genetic, Protein Binding, Protein Domains, Protein Transport, RNA Polymerase II/metabolism, RNA Polymerase III/metabolism, RNA, Small Nuclear/genetics, RNA, Small Nuclear/metabolism, TATA Box/genetics, TATA-Box Binding Protein/metabolism, Transcription Factor TFIIB/metabolism, Transcription Factors/metabolism, BRF2, SNAPc, TBP, TFIIA, TFIIB, small nuclear RNA promoters, 03 medical and health sciences, RNA, Small Nuclear, Genetics, 030102 biochemistry & molecular biology, General transcription factor, TATA-Box Binding Protein, RNA Polymerase III, Promoter, TATA Box, Cell biology, enzymes and coenzymes (carbohydrates), 030104 developmental biology, biology.protein, Transcription Factor TFIIB, RNA Polymerase II, Transcription factor II B, Transcription factor II A, Developmental Biology, Research Paper, Transcription Factors

Abstract

RNA polymerase II (Pol II) small nuclear RNA (snRNA) promoters and type 3 Pol III promoters have highly similar structures; both contain an interchangeable enhancer and “proximal sequence element” (PSE), which recruits the SNAP complex (SNAPc). The main distinguishing feature is the presence, in the type 3 promoters only, of a TATA box, which determines Pol III specificity. To understand the mechanism by which the absence or presence of a TATA box results in specific Pol recruitment, we examined how SNAPc and general transcription factors required for Pol II or Pol III transcription of SNAPc-dependent genes (i.e., TATA-box-binding protein [TBP], TFIIB, and TFIIA for Pol II transcription and TBP and BRF2 for Pol III transcription) assemble to ensure specific Pol recruitment. TFIIB and BRF2 could each, in a mutually exclusive fashion, be recruited to SNAPc. In contrast, TBP–TFIIB and TBP–BRF2 complexes were not recruited unless a TATA box was present, which allowed selective and efficient recruitment of the TBP–BRF2 complex. Thus, TBP both prevented BRF2 recruitment to Pol II promoters and enhanced BRF2 recruitment to Pol III promoters. On Pol II promoters, TBP recruitment was separate from TFIIB recruitment and enhanced by TFIIA. Our results provide a model for specific Pol recruitment at SNAPc-dependent promoters.

Published

2018

33. Structural rearrangements of the RNA polymerase III machinery during tRNA transcription initiation

Author

E.P. Ramsay and Alessandro Vannini

Subjects

0301 basic medicine, Transcription Elongation, Genetic, Biophysics, RNA polymerase II, Biology, Biochemistry, RNA polymerase III, TRNA transcription, 03 medical and health sciences, 0302 clinical medicine, RNA, Transfer, Structural Biology, Genetics, RNA polymerase I, Animals, Humans, Promoter Regions, Genetic, Molecular Biology, RNA polymerase II holoenzyme, Polymerase, Transcription Initiation, Genetic, Models, Genetic, RNA Polymerase III, RNA, Transfer, Amino Acid-Specific, Cell biology, Protein Subunits, 030104 developmental biology, Eukaryotic Cells, RNA editing, Multiprotein Complexes, biology.protein, 030217 neurology & neurosurgery, Small nuclear RNA, Transcription Factors

Abstract

RNA polymerase III catalyses the synthesis of tRNAs in eukaryotic organisms. Through combined biochemical and structural characterisation, multiple auxiliary factors have been identified alongside RNA Polymerase III as critical in both facilitating and regulating transcription. Together, this machinery forms dynamic multi-protein complexes at tRNA genes which are required for polymerase recruitment, DNA opening and initiation and elongation of the tRNA transcripts. Central to the function of these complexes is their ability to undergo multiple conformational changes and rearrangements that regulate each step. Here, we discuss the available biochemical and structural data on the structural plasticity of multi-protein complexes involved in RNA Polymerase III transcriptional initiation and facilitated re-initiation during tRNA synthesis. Increasingly, structural information is becoming available for RNA polymerase III and its functional complexes, allowing for a deeper understanding of tRNA transcriptional initiation. This article is part of a Special Issue entitled: SI: Regulation of tRNA synthesis and modification in physiological conditions and disease edited by Dr. Boguta Magdalena.

Published

2017

34. New tricks for an old dog: Brf2-dependent RNA Polymerase III transcription in oxidative stress and cancer

Author

Jerome, Gouge and Alessandro, Vannini

Subjects

Oxidative Stress, RNA polymerase III, Transcription, Genetic, Transcription Factor TFIIIB, Brf2, Neoplasms, Humans, Point-of-View, transcription, redox stress, Nrf2

Abstract

Here, we discuss the role of Brf2, an RNA Polymerase III core transcription factor, as a master switch of the oxidative stress response. We highlight the interplay of Brf2 with the Nrf2/Keap1 pathway, as well as the role of Brf2 in cancer and other possible regulations.

Published

2017

35. Unveiling (class III) transcription through integrative structural biology

Author

Alessandro Vannini

Subjects

Inorganic Chemistry, Structural biology, Structural Biology, Transcription (biology), General Materials Science, Computational biology, Class iii, Physical and Theoretical Chemistry, Biology, Condensed Matter Physics, Biochemistry

Published

2018

36. The archaeo-eukaryotic primase of plasmid pRN1 requires a helix bundle domain for faithful primer synthesis

Author

Patrick Cramer, Kirsten Beck, Alessandro Vannini, and Georg Lipps

Subjects

Models, Molecular, Protein Folding, HMG-box, DNA polymerase, Stereochemistry, Molecular Sequence Data, DNA Primase, Protein Structure, Secondary, Structural Biology, Genetics, Point Mutation, Amino Acid Sequence, DNA Primers, Helix bundle, biology, Templates, Genetic, Protein Structure, Tertiary, Biochemistry, Amino Acid Substitution, Helix, biology.protein, Protein folding, Primase, Primer (molecular biology), Sequence Alignment, Alpha helix, Plasmids

Abstract

The plasmid pRN1 encodes for a multifunctional replication protein with primase, DNA polymerase and helicase activity. The minimal region required for primase activity encompasses amino-acid residues 40-370. While the N-terminal part of that minimal region (residues 47-247) folds into the prim/pol domain and bears the active site, the structure and function of the C-terminal part (residues 248-370) is unknown. Here we show that the C-terminal part of the minimal region folds into a compact domain with six helices and is stabilized by a disulfide bond. Three helices superimpose well with the C-terminal domain of the primase of the bacterial broad host range plasmid RSF1010. Structure-based site-directed mutagenesis shows that the C-terminal helix of the helix bundle domain is required for primase activity although it is distant to the active site in the crystallized conformation. Furthermore, we identified mutants of the C-terminal domain, which are defective in template binding, dinucleotide formation and conformation change prior to DNA extension.

Published

2010

37. Structure of Eukaryotic RNA Polymerases

Author

Sonja Baumli, Karim-Jean Armache, Patrick Cramer, Alessandro Vannini, Claudia Buchen, Kristin Leike, Anja J. Jasiak, Sebastian R. Geiger, Hubert Kettenberger, Florian Brueckner, Elisabeth Lehmann, Claus-D. Kuhn, Gerke E. Damsma, Stefan Jennebach, Tomislav Kamenski, Stefan Benkert, Jasmin F. Sydow, Anass Jawhari, and Stefan Dengl

Subjects

Models, Molecular, Transcription, Genetic, DNA polymerase, viruses, Biophysics, Bioengineering, RNA polymerase II, Biochemistry, RNA polymerase III, Structural Biology, Transcriptional regulation, Animals, Humans, RNA polymerase II holoenzyme, Genetics, Models, Genetic, biology, DNA-Directed RNA Polymerases, Cell Biology, Processivity, Enzyme Activation, Models, Chemical, biology.protein, RNA, Transcription factor II D, Small nuclear RNA

Abstract

The eukaryotic RNA polymerases Pol I, Pol II, and Pol III are the central multiprotein machines that synthesize ribosomal, messenger, and transfer RNA, respectively. Here we provide a catalog of available structural information for these three enzymes. Most structural data have been accumulated for Pol II and its functional complexes. These studies have provided insights into many aspects of the transcription mechanism, including initiation at promoter DNA, elongation of the mRNA chain, tunability of the polymerase active site, which supports RNA synthesis and cleavage, and the response of Pol II to DNA lesions. Detailed structural studies of Pol I and Pol III were reported recently and showed that the active center region and core enzymes are similar to Pol II and that strong structural differences on the surfaces account for gene class-specific functions.

Published

2008

38. Structural Biology of RNA Polymerase III: Mass Spectrometry Elucidates Subcomplex Architecture

Author

Kristina Lorenzen, Patrick Cramer, Alessandro Vannini, Albert J. R. Heck, Biomoleculaire Massaspectrometrie, Massaspectrometrie, Dep Scheikunde, and Dep Farmaceutische wetenschappen

Subjects

biology, Protein subunit, viruses, Farmacie(FARM), RNA, RNA Polymerase III, RNA polymerase II, Processivity, Tandem mass spectrometry, Molecular biology, Models, Biological, RNA polymerase III, Farmacie/Biofarmaceutische wetenschappen (FARM), Protein Subunits, Structure-Activity Relationship, Structural biology, Tandem Mass Spectrometry, Structural Biology, biology.protein, RNA Polymerase II, Dimerization, Molecular Biology, Polymerase

Abstract

SummaryRNA polymerases (Pol) II and III synthesize eukaryotic mRNAs and tRNAs, respectively. The crystal structure of the 12 subunit Pol II is known, but only limited structural information is available for the 17 subunit Pol III. Using mass spectrometry (MS), we correlated masses of Pol II complexes with the Pol II structure. Analysis of Pol III showed that the complete enzyme contains a single copy of each subunit and revealed a 15 subunit form lacking the Pol III-specific subcomplex C53/37. DMSO treatment dissociated the C17/25 heterodimer of Pol III, confirming a peripheral location as its counterpart in Pol II. Tandem MS revealed the Pol III-specific subunits C82 and C34 dissociating as a heterodimer. C11 was retained, arguing against a stable trimeric subcomplex, C53/37/11. These data suggest that Pol III consists of a 10 subunit Pol II-like core; the peripheral heterodimers C17/25, C53/37, and C82/34; and subunit C31, which bridges between C82/34, C17/25, and the core.

Published

2007

39. Substrate binding to histone deacetylases as shown by the crystal structure of the HDAC8–substrate complex

Author

Philip Jones, Raffaele De Francesco, Stefania Di Marco, Andrea Carfi, Alessandro Vannini, Paola Gallinari, Marco Mattu, Christian Steinkühler, and Cinzia Volpari

Subjects

Models, Molecular, Aspartic Acid, biology, Scientific Report, Mutant, Mutagenesis, Repressor, Substrate (chemistry), HDAC8, Crystallography, X-Ray, Biochemistry, Histone Deacetylases, Protein Structure, Secondary, Substrate Specificity, Repressor Proteins, Structure-Activity Relationship, Histone, Acetylation, Genetics, biology.protein, Humans, Structure–activity relationship, Enzyme Inhibitors, Molecular Biology

Abstract

Histone deacetylases (HDACs)—an enzyme family that deacetylates histones and non-histone proteins—are implicated in human diseases such as cancer, and the first-generation of HDAC inhibitors are now in clinical trials. Here, we report the 2.0 Å resolution crystal structure of a catalytically inactive HDAC8 active-site mutant, Tyr306Phe, bound to an acetylated peptidic substrate. The structure clarifies the role of active-site residues in the deacetylation reaction and substrate recognition. Notably, the structure shows the unexpected role of a conserved residue at the active-site rim, Asp 101, in positioning the substrate by directly interacting with the peptidic backbone and imposing a constrained cis-conformation. A similar interaction is observed in a new hydroxamate inhibitor–HDAC8 structure that we also solved. The crucial role of Asp 101 in substrate and inhibitor recognition was confirmed by activity and binding assays of wild-type HDAC8 and Asp101Ala, Tyr306Phe and Asp101Ala/Tyr306Phe mutants.

Published

2007

40. Mechanism of Activation of Human Heparanase Investigated by Protein Engineering

Author

Caterina Nardella, Christian Steinkühler, Michele Pallaoro, Armin Lahm, Mirko Brunetti, and and Alessandro Vannini

Subjects

Signal peptide, Protein Folding, Protein subunit, Blotting, Western, Genetic Vectors, Molecular Sequence Data, Potyvirus, Spodoptera, Transfection, Biochemistry, Protein Structure, Secondary, chemistry.chemical_compound, Chlorocebus aethiops, Consensus Sequence, Endopeptidases, TIM barrel, Animals, Humans, Heparanase, Amino Acid Sequence, Cloning, Molecular, Peptide sequence, Glucuronidase, chemistry.chemical_classification, Sequence Homology, Amino Acid, biology, Hydrolysis, Active site, Heparan sulfate, Molecular biology, Enzyme Activation, Enzyme, chemistry, COS Cells, Mutagenesis, Site-Directed, biology.protein, Triose-Phosphate Isomerase

Abstract

The aim of this study was to investigate the mechanism of activation of human heparanase, a key player in heparan sulfate degradation, thought to be involved in normal and pathologic cell migration processes. Active heparanase arises as a product of a series of proteolytic processing events. Upon removal of the signal peptide, the resulting, poorly active 65 kDa species undergoes the excision of an intervening 6 kDa fragment generating an 8 kDa polypeptide and a 50 kDa polypeptide, forming the fully active heterodimer. By engineering of tobacco etch virus protease cleavage sites at the N- and C-terminal junctions of the 6 kDa fragment, we were able to reproduce the proteolytic activation of heparanase in vitro using purified components, showing that cleavage at both sites leads to activation in the absence of additional factors. On the basis of multiple-sequence alignment of the N-terminal fragment, we conclude that the first beta/alpha/beta element of the postulated TIM barrel fold is contributed by the 8 kDa subunit and that the excised 6 kDa fragment connects the second beta-strand and the second alpha-helix of the barrel. Substituting the 6 kDa fragment with the topologically equivalent loop from Hirudinaria manillensis hyaluronidase or connecting the 8 and 50 kDa fragments with a spacer of three glycine-serine pairs resulted in constitutively active, single-chain heparanases which were comparable to the processed, heterodimeric enzyme with regard to specific activity, chromatographic profile of hydrolysis products, complete inhibition at NaCl concentrations above 600 mM, a pH optimum of pH approximately 5, and inhibition by heparin with IC(50)s of 0.9-1.5 ng/microL. We conclude that (1) the heparanase heterodimer (alpha/beta)(8)-TIM barrel fold is contributed by both 8 and 50 kDa subunits with the 6 kDa connecting fragment leading to inhibition of heparanase by possibly obstructing access to the active site, (2) proteolytic excision of the 6 kDa fragment is necessary and sufficient for heparanase activation, and (3) our findings open the way to the production of recombinant, constitutively active single-chain heparanase for structural studies and for the identification of inhibitors.

Published

2004

41. Effect of ibuprofen and warfarin on the allosteric properties of haem-human serum albumin

Author

Mauro Fasano, Alessandro Vannini, Rita Cipollone, Silvio Aime, Paolo Ascenzi, Simona Baroni, Marco Mattu, Baroni, S, Mattu, M, Vannini, A, Cipollone, R, Aime, S, Ascenzi, Paolo, and Fasano, M.

Subjects

Models, Molecular, Magnetic Resonance Spectroscopy, Macromolecular Substances, Protein Conformation, Stereochemistry, Allosteric regulation, Serum albumin, Ibuprofen, Heme, Plasma protein binding, In Vitro Techniques, Biochemistry, Ferrous, polycyclic compounds, medicine, Humans, Binding site, Serum Albumin, Binding Sites, biology, Chemistry, digestive, oral, and skin physiology, Electron Spin Resonance Spectroscopy, Human serum albumin, body regions, Kinetics, Spectrophotometry, embryonic structures, biology.protein, Ferric, Warfarin, Allosteric Site, Protein Binding, medicine.drug

Abstract

Haem binding to human serum albumin (HSA) endows the protein with peculiar spectroscopic properties. Here, the effect of ibuprofen and warfarin on the spectroscopic properties of ferric haem-human serum albumin (ferric HSA-haem) and of ferrous nitrosylated haem-human serum albumin (ferrous HSA-haem-NO) is reported. Ferric HSA-haem is hexa-coordinated, the haem-iron atom being bonded to His105 and Tyr148. Upon drug binding to the warfarin primary site, the displacement of water molecules--buried in close proximity to the haem binding pocket--induces perturbation of the electronic absorbance properties of the chromophore without affecting the coordination number or the spin state of the haem-iron, and the quenching of the 1H-NMR relaxivity. Values of Kd for ibuprofen and warfarin binding to the warfarin primary site of ferric HSA-haem, corresponding to the ibuprofen secondary cleft, are 5.4 +/- 1.1 x 10(-4) m and 2.1 +/- 0.4 x 10(-5) m, respectively. The affinity of ibuprofen and warfarin for the warfarin primary cleft of ferric HSA-haem is lower than that reported for drug binding to haem-free HSA. Accordingly, the Kd value for haem binding to HSA increases from 1.3 +/- 0.2 x 10(-8) m in the absence of drugs to 1.5 +/- 0.2 x 10(-7) m in the presence of ibuprofen and warfarin. Ferrous HSA-haem-NO is a five-coordinated haem-iron system. Drug binding to the warfarin primary site of ferrous HSA-haem-NO induces the transition towards the six-coordinated haem-iron species, the haem-iron atom being bonded to His105. Remarkably, the ibuprofen primary cleft appears to be functionally and spectroscopically uncoupled from the haem site of HSA. Present results represent a clear-cut evidence for the drug-induced shift of allosteric equilibrium(a) of HSA.

Published

2001

42. Crystallization and preliminary X-ray diffraction studies of the quorum-sensing regulator TraM fromAgrobacterium tumefaciens

Author

Stefania Di Marco, Alessandro Vannini, and Cinzia Volpari

Subjects

DNA, Bacterial, Light, Molecular Sequence Data, Regulator, Crystallography, X-Ray, medicine.disease_cause, law.invention, Ti plasmid, Plasmid, Bacterial Proteins, Structural Biology, law, Escherichia coli, medicine, Scattering, Radiation, Amino Acid Sequence, Cloning, Molecular, Crystallization, Selenomethionine, biology, General Medicine, Agrobacterium tumefaciens, biology.organism_classification, Molecular Weight, Quorum sensing, Crystallography, Chromatography, Gel, Mutagenesis, Site-Directed, Recombinant DNA, Sequence Alignment

Abstract

TraM is a 11.4 kDa protein involved in the control of the conjugal transfer of Agrobacterium tumefaciens Ti plasmids by quorum-sensing. TraM was overexpressed and purified from Escherichia coli. This protein binds to the transcriptional regulator TraR, abolishing its function. Size-exclusion chromatography and dynamic light scattering show that the recombinant protein has an apparent molecular weight of 30 kDa in solution. Crystals have been obtained of both native and selenomethionine-substituted TraM by the vapour-diffusion method. Crystals diffract to 1.67 A and belong to the space group P2(1)2(1)2, with unit-cell parameters a = 76.43, b = 47.09, c = 47.46 A and two molecules in the asymmetric unit. A two-wavelength MAD data set for the selenomethionine-substituted form has been collected to a resolution of 2.0 A. The selenium substructure (five out of six possible sites) has been solved using direct methods.

Published

2003

43. A structural perspective on RNA polymerase I and RNA polymerase III transcription machineries

Author

Alessandro Vannini

Subjects

Transcription factories, Genetics, General transcription factor, Transcription, Genetic, Biophysics, RNA-dependent RNA polymerase, RNA Polymerase III, RNA polymerase II, Computational biology, Biology, Biochemistry, RNA polymerase III, Repressor Proteins, Structural Biology, RNA Polymerase I, RNA polymerase I, biology.protein, Animals, Humans, Transcription factor II D, Molecular Biology, Polymerase, Transcription Factors

Abstract

RNA polymerase I and III are responsible for the bulk of nuclear transcription in actively growing cells and their activity impacts the cellular biosynthetic capacity. As a consequence, RNA polymerase I and III deregulation has been directly linked to cancer development. The complexity of RNA polymerase I and III transcription apparatuses has hampered their structural characterization. However, in the last decade tremendous progresses have been made, providing insights into the molecular and functional architecture of these multi-subunit transcriptional machineries. Here we summarize the available structural data on RNA polymerase I and III, including specific transcription factors and global regulators. Despite the overall scarcity of detailed structural data, the recent advances in the structural biology of RNA polymerase I and III represent the first step towards a comprehensive understanding of the molecular mechanism underlying RNA polymerase I and III transcription. This article is part of a Special Issue entitled: Transcription by Odd Pols.

Published

2012

44. Crystallization and preliminary X-ray diffraction studies of the transcriptional regulator TraR bound to its cofactor and to a specific DNA sequence

Author

Alessandro Vannini, Raffaele De Francesco, Cesare Gargioli, Petra Neddermann, Cinzia Volpari, Stefania Di Marco, and Ester Muraglia

Subjects

Macromolecular Substances, Sequence (biology), Crystallography, X-Ray, medicine.disease_cause, DNA-binding protein, Cofactor, Selenium, Bacterial Proteins, Structural Biology, Homoserine, Transcriptional regulation, medicine, Escherichia coli, Ternary complex, Binding Sites, Base Sequence, biology, Promoter, DNA, General Medicine, Agrobacterium tumefaciens, biology.organism_classification, Recombinant Proteins, Crystallography, biology.protein, Crystallization

Abstract

TraR is an Agrobacterium tumefaciens transcriptional regulator which binds the pheromone N-3-oxooctanoyl-L-homoserine lactone (AAI) in response to the bacterial population density. The TraR-AAI complex dimerizes and interacts with a specific 18-base-pair DNA sequence (TraBox), activating promoters containing this site. TraR was overexpressed and purified from Escherichia coli. Crystals of the ternary complex, in which dimeric TraR-AAI is bound to the TraBox sequence, have been obtained by the vapour-diffusion method. The crystals belong to space group P2(1)2(1)2(1), with unit-cell parameters a = 66.99, b = 94.67, c = 209.66 A, with two (TraR-AAI)(2)-TraBox complexes in the asymmetric unit. A three-wavelength MAD data set for the seleno-L-methionine-substituted form has been collected to a resolution of 3 A. 20 of the 24 crystallographically independent selenium sites were located as part of the MAD-phasing process.

Published

2002

45. Conservation between the RNA polymerase I, II, and III transcription initiation machineries

Author

Patrick Cramer and Alessandro Vannini

Subjects

Genetics, Models, Molecular, Transcription, Genetic, Eukaryotic transcription, RNA Polymerase III, RNA polymerase II, Cell Biology, Biology, TATA-Box Binding Protein, Protein Structure, Tertiary, Transcription Factors, TFII, RNA Polymerase I, biology.protein, Transcription Factor TFIIB, Transcription factor II F, Transcription factor II E, RNA Polymerase II, Transcription factor II D, Protein Structure, Quaternary, Molecular Biology, RNA polymerase II holoenzyme, Transcription factor II B, Transcription factor II A, Conserved Sequence

Abstract

Recent studies of the three eukaryotic transcription machineries revealed that all initiation complexes share a conserved core. This core consists of the RNA polymerase (I, II, or III), the TATA box-binding protein (TBP), and transcription factors TFIIB, TFIIE, and TFIIF (for Pol II) or proteins structurally and functionally related to parts of these factors (for Pol I and Pol III). The conserved core initiation complex stabilizes the open DNA promoter complex and directs initial RNA synthesis. The periphery of the core initiation complex is decorated by additional polymerase-specific factors that account for functional differences in promoter recognition and opening, and gene class-specific regulation. This review outlines the similarities and differences between these important molecular machines.

Published

2011

46. Crystal structure of a eukaryotic zinc-dependent histone deacetylase, human HDAC8, complexed with a hydroxamic acid inhibitor

Author

Mirko Brunetti, Raffaele De Francesco, Elena Caroli Casavola, Gessica Filocamo, Prasun K. Chakravarty, Alessandro Vannini, Paola Gallinari, Debora Renzoni, Cinzia Volpari, Christian Steinkühler, Chantal Paolini, and Stefania Di Marco

Subjects

Models, Molecular, DNA repair, Protein Conformation, Molecular Sequence Data, Antineoplastic Agents, In Vitro Techniques, Crystallography, X-Ray, Hydroxamic Acids, Histone Deacetylases, chemistry.chemical_compound, Protein structure, RNA interference, Catalytic Domain, Cell Line, Tumor, Humans, Amino Acid Sequence, Enzyme Inhibitors, Regulation of gene expression, Multidisciplinary, Hydroxamic acid, biology, Sequence Homology, Amino Acid, Circular Dichroism, HDAC8, Biological Sciences, Recombinant Proteins, Histone Deacetylase Inhibitors, Repressor Proteins, Zinc, Histone, chemistry, Biochemistry, Drug Design, biology.protein, Potassium, RNA Interference, Histone deacetylase

Abstract

Histone deacetylases (HDACs) are a family of enzymes involved in the regulation of gene expression, DNA repair, and stress response. These processes often are altered in tumors, and HDAC inhibitors have had pronounced antitumor activity with promising results in clinical trials. Here, we report the crystal structure of human HDAC8 in complex with a hydroxamic acid inhibitor. Such a structure of a eukaryotic zinc-dependent HDAC has not be described previously. Similar to bacterial HDAC-like protein, HDAC8 folds in a single α/β domain. The inhibitor and the zinc-binding sites are similar in both proteins. However, significant differences are observed in the length and structure of the loops surrounding the active site, including the presence of two potassium ions in HDAC8 structure, one of which interacts with key catalytic residues. CD data suggest a direct role of potassium in the fold stabilization of HDAC8. Knockdown of HDAC8 by RNA interference inhibits growth of human lung, colon, and cervical cancer cell lines, highlighting the importance of this HDAC subtype for tumor cell proliferation. Our findings open the way for the design and development of selective inhibitors of HDAC8 as possible antitumor agents.

Published

2004

47. Crystal structure of the quorum-sensing protein TraM and its interaction with the transcriptional regulator TraR

Author

Stefania Di Marco, Cinzia Volpari, and Alessandro Vannini

Subjects

Models, Molecular, Light, Dimer, Electrons, Biology, Antiparallel (biochemistry), Crystallography, X-Ray, Biochemistry, Protein Structure, Secondary, chemistry.chemical_compound, Bacterial Proteins, Transcriptional regulation, Scattering, Radiation, Molecular Biology, Chromatography, Molecular mass, Cell Biology, Agrobacterium tumefaciens, biology.organism_classification, Quorum sensing, Kinetics, chemistry, Mutation, Biophysics, Autoinducer, Dimerization, DNA, Protein Binding

Abstract

Transfer of the tumor-inducing plasmid in Agrobacterium tumefaciens is controlled by a quorum-sensing system whose main components are the transcriptional regulator TraR and its autoinducer. This system allows bacteria to synchronize infection of the host plant when a “quorum” of cells has been reached. TraM is an A. tumefaciens protein involved in the regulation of this system because it binds to TraR and prevents it from binding DNA. As a first step to understanding the molecular basis for the regulation of TraR by TraM, we have determined the crystal structure of TraM at 1.65 A resolution. This protein is packed as a dimer, with each monomer consisting mainly of two antiparallel α helices. Monomers are tightly associated, with a large hydrophobic area buried upon dimerization. Secondly, we characterized the TraR-TraM complex in vitro. TraM (11.4 kDa, monomer molecular mass) binds tightly TraR (27 kDa, monomer molecular mass) forming a stable oligomeric complex that likely accounts for two TraR and two TraM dimers.

Published

2004

48. Determination of the stoichiometry of noncovalent complexes using reverse-phase high-performance liquid chromatography coupled with electrospray ion trap mass spectrometry

Author

Fabio Bonelli, Petra Neddermann, Alessandro Vannini, Laura Orsatti, Cinzia Volpari, and Stefania Di Marco

Subjects

Electrospray, Spectrometry, Mass, Electrospray Ionization, Molar concentration, viruses, Molecular Sequence Data, Biophysics, Hepacivirus, Viral Nonstructural Proteins, Mass spectrometry, Biochemistry, High-performance liquid chromatography, Cofactor, Viral Proteins, Homoserine, Amino Acid Sequence, Molecular Biology, Chromatography, High Pressure Liquid, Chromatography, biology, Chemistry, Escherichia coli Proteins, Selected reaction monitoring, Intracellular Signaling Peptides and Proteins, Cell Biology, Agrobacterium tumefaciens, Calibration, biology.protein, Ion trap, Carrier Proteins, Hydrophobic and Hydrophilic Interactions, Stoichiometry, Bacterial Outer Membrane Proteins

Abstract

An electrospray mass spectrometry-based methodology has been developed to have a fast and sensitive method for protein–cofactor stoichiometry determination. As model systems, we used two proteins which require the presence of cofactors for activity: TraR, a member of the LuxR family of quorum-sensing transcriptional regulators, which requires an acyl–homoserine lactone molecule called Agrobacterium autoinducer (AAI) as coinducer and the NS3 protease of hepatitis C virus which complexes with a NS4A cofactor peptide. Both TraR/AAI and NS3/NS4A are noncovalent complexes. Our method requires only nanomolar concentration of sample. A calibration curve of the cofactor is determined by high-performance liquid chromatography (HPLC) coupled on-line with an ion trap mass spectrometer operated in selected reaction monitoring mode. Subsequently, the complex is analyzed using the same experimental setup. During the HPLC run, the complex dissociates, and cofactor and protein elute at different retention times. The peak area of the cofactor is integrated and the molar concentration of cofactor in the complex is extrapolated from the calibration curve. The stoichiometry is consequently calculated by dividing the molar concentration of protein injected by that of cofactor measured. Both TraR/AAI and NS3/NS4A complexes have 1:1 stoichiometries, in line with those already reported in the literature.

Published

2002

49. The crystal structure of the quorum sensing protein TraR bound to its autoinducer and target DNA

Author

Petra Neddermann, Cesare Gargioli, Ester Muraglia, Riccardo Cortese, Stefania Di Marco, Alessandro Vannini, Raffaele De Francesco, and Cinzia Volpari

Subjects

Models, Molecular, TraR, DNA binding protein, GAF-PAS domains, homoserine lactone, quorum sensing, Agrobacterium tumefaciens, Amino Acid Motifs, Amino Acid Sequence, Bacterial Proteins, Binding Sites, Conjugation, Genetic, Crystallography, X-Ray, DNA, Bacterial, Dimerization, Evolution, Molecular, Homoserine, Ligands, Molecular Sequence Data, Multigene Family, Protein Binding, Protein Conformation, Protein Structure, Tertiary, Repressor Proteins, Sequence Alignment, Sequence Homology, Amino Acid, Trans-Activators, Transcription Factors, Protein Data Bank (RCSB PDB), Sequence Homology, Protein structure, PAS domain, Models, Crystallography, General Neuroscience, Bacterial, Cell biology, Amino Acid, Biochemistry, Autoinducer, Protein Structure, Evolution, Repressor, Biology, General Biochemistry, Genetics and Molecular Biology, Article, Genetic, Binding site, Settore BIO/10, Molecular Biology, General Immunology and Microbiology, Conjugation, Molecular, DNA, biology.organism_classification, Quorum sensing, X-Ray, Tertiary

Abstract

The quorum sensing system allows bacteria to sense their cell density and initiate an altered pattern of gene expression after a sufficient quorum of cells has accumulated. In Agrobacterium tumefaciens, quorum sensing controls conjugal transfer of the tumour- inducing plasmid, responsible for plant crown gall disease. The core components of this system are the transcriptional regulator TraR and its inducing ligand N-(3-oxo-octanoyl)-l-homoserine lactone. This complex binds DNA and activates gene expression. We have determined the crystal structure of TraR in complex with its autoinducer and target DNA (PDB code 1h0m). The protein is dimeric, with each monomer composed of an N-terminal domain, which binds the ligand in an enclosed cavity far from the dimerization region, and a C-terminal domain, which binds DNA via a helix–turn–helix motif. The structure reveals an asymmetric homodimer, with one monomer longer than the other. The N-terminal domain resembles GAF/PAS domains, normally fused to catalytic signalling domains. In TraR, the gene fusion is between a GAF/PAS domain and a DNA-binding domain, resulting in a specific transcriptional regulator involved in quorum sensing.

Published

2002

50. Relaxometric characterization of human hemalbumin

Author

Paolo Ascenzi, Mauro Fasano, Alessandro Vannini, Simona Baroni, Silvio Aime, Fasano, M, Baroni, S, Vannini, A, Ascenzi, Paolo, and Aime, S.

Subjects

Manganese, Aqueous solution, Coordination sphere, Binding Sites, Magnetic Resonance Spectroscopy, Chemistry, Ligand, Protein Conformation, Iron, Inorganic chemistry, Relaxation (NMR), Protoporphyrins, Heme, Ligands, Biochemistry, Inorganic Chemistry, chemistry.chemical_compound, Crystallography, Molecule, Humans, Azide, Fluoride, Serum Albumin

Abstract

Hemalbumin [i.e., Fe(III)-protoporphyrin IX-human serum albumin; Fe(III)heme-HSA] is an important intermediate in the recovery of heme iron following hemolysis. Relaxometric data are consistent with the occurrence of a hexacoordinated high-spin Fe(III) center with no water in the inner coordination sphere. The relatively high relaxation enhancement observed for an aqueous solution of Fe(III)heme-HSA (r1p=4.8 mM(-1)s(-1) at 20 MHz, pH 7, and 25 C) is ascribed to the occurrence of a strong contribution from water molecules in the second coordination sphere. Structural analysis of the putative binding region has been performed by a Monte Carlo simulated annealing procedure, which allowed us to identify His105 and Tyr148 as axial ligands. The role of a tyrosinate as the sixth Fe(III)heme ligand is supported by the pH-dependent analysis. Interestingly, when Fe(III) is replaced by Mn(III), the occurrence of a fast exchanging water molecule at pH values close to neutrality is detected. As the pH is increased, the Mn(III) containing system behaves analogously to Fe(III)heme-HSA. At higher pH, the phenolate ligand is eventually displaced by OH- from both Fe(III) and Mn(III) centers. Support for the proposed bonding scheme has been gained also from competitive binding assays for the sixth coordination site by fluoride, azide, and imidazole ligands.

Published

2001