DOCSLIB.ORG

Title Analysis of the Genome Architecture of The

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Title Analysis of the Genome Architecture of The Analysis of the genome architecture of the hyperthermopholic Title archaeon Thermococcus kodakarensis( Dissertation_全文 ) Author(s) Maruyama, Hugo Citation 京都大学 Issue Date 2011-03-23 URL https://doi.org/10.14989/doctor.k16233 Right Type Thesis or Dissertation Textversion author Kyoto University Analysis of the genome architecture of the hyperthermophilic archaeon Thermococcus kodakarensis Hugo Maruyama 要旨 ゲノム DNA は細胞内で高度に折りたたまれ、この染色体高次構造は転写・複製・染色体分 配といった機構と密接に結びついている。染色体の主要な構成タンパク質は真核生物では ヒストン、バクテリアでは HU と全く異なるが、一様な基本構造を基にゲノム DNA が階層 的に折りたたまれている点で両者の染色体構造は共通している。アーキアは真核生物・バ クテリアと並ぶ生命の第三のドメインであり、遺伝情報の発現(複製・転写・翻訳)の機 構は真核生物に、代謝経路はバクテリアに近い。アーキアには染色体を構成するタンパク 質として真核生物のヒストンに相同なもの、バクテリアの HU に相同なもの、アーキア特有 の Alba と呼ばれるタンパク質などが存在し、種によってゲノムがコードするタンパク質の 組合せが異なる。様々なアーキアのゲノムがどのような高次構造を形成しているかを明ら かにすることで、三つのドメインにわたるゲノム構造の共通性あるいは多様性を明らかに できる。本研究ではその第一歩としてヒストンを持つ超好熱性アーキア Thermococcus kodakarensis の染色体構造を解析した。 T. kodakarensis の染色体に含まれるタンパク質を質量分析により同定した結果、ヒ ストン、Alba、TK0471(TrmBL2)、 RNA ポリメラーゼ等の DNA 結合タンパク質が含まれ ることが分かった。TK0471 は転写因子 TrmB と相同な機能未知の DNA 結合タンパク質で あった。次に、染色体をミクロコッカルヌクレアーゼで部分消化した後、5%-20%のショ糖 密度勾配遠心により構成タンパク質の異なる染色体断片が分離された。原子間力顕微鏡に よる解析から、ヒストンは DNA 上に beads-on-a-string 構造を、TK0471 は線維状の構造を形 成することが示された。また大腸菌で発現させた組換えタンパク質(ヒストンおよび TK0471)を用いて同様の構造が DNA 上に再構成された。ショ糖密度勾配で分離されたそ れぞれの染色体断片に含まれる DNA 配列を超並列シークエンサーで同定した結果、ヒスト ンおよび TK0471 はゲノム上のプロモーター領域にもコーディング領域にも偏りなく存在 するが、両者の存在する領域は重複しない傾向があった。以上の結果から、T. kodakarensis の染色体上には、構成タンパク質および構造の異なる領域が存在することが明らかとなっ た。相同組換えにより TK0471 遺伝子を破壊すると染色体の DNA 消化酵素に対する感受性 が高まった。また、約 100 個の遺伝子の転写産物量が増加した。TK0471 破壊株における各 遺伝子の転写量の上昇と TK0471 タンパク質のプロモーター上の局在とには有意な相関が あった。このことから、TK0471 は染色体に多量に存在してゲノム構造を維持すると同時に、 プロモーターに結合した場合には転写抑制因子として働くと考えられる。TK0471(TrmBL2) は一部のアーキアとバクテリアの種で保存された新しいタイプの染色体構成タンパク質で ある。他の種での機能解析によりその機能がより詳細に明らかになることが期待される。 ii Abstract Genomic DNA is highly organized and compacted inside the cell. The higher-order chromosome architecture is coupled to cellular processes such as DNA replication, transcription, and chromosome segregation. Although the fundamental architectural protein of the chromosome is different for eukaryotes and bacteria (i.e., histone in eukaryotes and HU in bacteria), eukaryotic chromosomes and bacterial nucleoids both exhibit hierarchical architecture. Archaea is the third domain of life, distinct from eukaryotes or bacteria. The information processing machineries (DNA replication, transcription, and translation) of archaea are more similar to those of eukaryotes and the metabolic pathways are more similar to those of bacteria. Interestingly, archaeal species encode diverse chromosome architectural proteins such as eukaryotic histone, bacterial HU, as well as archaea-specific Alba. Each archaeal species encodes different combinations of these proteins. Clarification of the chromosome architecture in archaea will lead to the understanding of the general chromosome folding principle in all three domains. As a first step toward this goal, the chromosome architecture of the hyperthermophilic archaeon Thermococcus kodakarensis was analyzed in this study. Histone, Alba, TK0471, and RNA polymerase subunits were identified through mass spectrometry as the major DNA-binding proteins of the T. kodakarensis chromosome. TK0471 is a protein previously named TrmB-like 2 (TrmBL2) based on its homology to transcription factors TrmB or Tgr/TrmB-like 1 (TrmBL1), but its specific role has been difficult to identify. Sucrose density gradient sedimentation of a partially digested T. kodakarensis chromosome resulted in the separation of chromosome fragments with different protein compositions. Atomic force microscopy revealed that histone forms a “beads-on-a-string” structure, while TK0471 forms a thick fibrous structure on the DNA. High-throughput sequencing of the DNA concentrated with histone or TK0471 showed that these proteins localize to both coding and intergenic regions, but that these areas of localization tend not to overlap. Deletion of the TK0471 gene by homologous recombination results in an alteration of the chromosome into a more nuclease-sensitive state and an increase in the transcript level of approximately 100 genes. The elevation of the transcript level has a significant correlation with the localization of TK0471 to the promoter region of the gene. These results suggest that TK0471 (TrmBL2) is an abundant chromosomal protein that plays dual roles in chromosome architecture and transcriptional regulation. Further analysis in other species may lead to greater understanding of this protein‟s function. iii Acknowledgements First and foremost I offer my sincerest gratitude to my supervisor, Dr. Kunio Takeyasu, who has supported me throughout my study with his patience and knowledge whilst allowing me the room to work in my own way. This thesis would not have been completed without his support. He has always emphasized the importance of keeping the big picture in mind, and to study something fundamentally novel. These are important attitudes that I will remember throughout my life. I also appreciate the opportunities he provided me with, like to study abroad as an exchange student, and to attend international conferences. These experiences have broadened my vision towards science. Next, I would like to express my gratitude to Dr. Shige H. Yoshimura, who was my first direct supervisor when I started my research in the laboratory as an undergraduate student and has been a great advisor since then. I remember the first experiment I conducted with him was to amplify DNA using PCR. He has given me a lot of helpful suggestions, especially when I was writing the manuscript for my research publication. Working with him, I learned the importance of having solid logic in my study. I sincerely thank all of the current and former members of Takeyasu laboratory for their help and friendship over the years I spent there. The study described in this thesis is based on Dr. Ryosuke L. Ohniwa‟s study and could not have reached this point without him. He has encouraged me throughout my research with his positive attitude toward science. Drs. Chieko Wada, Kohji Hizeme and Masatoshi Yokokawa encouraged me to publish my research, even when it was not going well and seemed as if it would never end. They have been a pillar of support that has encouraged me to complete my study. I learned a lot about computational analysis and programming from Mr. Toshiyuki Oda. Dr. Minsang Shin has given me many insightful discussions about prokaryotic gene regulation. I thank Ms. Abeer Hasan for English proofreading of my manuscript. I would like to thank Drs. Rie Matsumi, Haruyuki Atomi, Tadayuki Imanaka and the members in their laboratory for insightful suggestions and discussions about the study of the archaeal species. This collaborative study would not have been possible without them. I also thank Dr. Katsuhiko Shirahige and Dr. Takehiko Itoh for their support and helpeful suggestions about DNA sequencing, which constitutes an important part of this thesis. Next, I would also like to thank the people I worked with at the Salk Institute for Biological Studies in La Jolla, USA. Professor Takeyasu provided me with the opportunity to study there as an exchange student. There I worked mainly with the iv postdoctoral researcher Dr. Marcela Raices under the supervision of Dr. Andrew Dillin and Dr. Jan Karlseder. I learned to be aware of the biological and/or medical relevance of my own study, and to always think about how I can contribute to move the research field forward. I would like to thank the Graduate School of Biostudies and the “Life Science English Communication Program” for their support to send me to the Gordon Research Conference on Archaea in 2009. I would also like to thank the Ministry of Education, Culture, Sports, Science and Technology of Japan and the “Academic Frontiers Student Exchange Promotion Program” for their support for me to study abroad as an exchange student. Last but not least, I thank my parents, who have educated, supported and encouraged me to pursue my interests. Without their continuous support, it was not possible to complete my work. I also thank all my friends. Without the time I spent with them outside the laboratory, I could not have maintained a healthy mind to concentrate on science. Kyoto, Hugo Maruyama 2011 v Curriculum Vitae Hugo Maruyama Graduate School of Biostudies, Kyoto University, Sakyo-ku, Kyoto 606-8501 Tel. & Fax (075) 753-7906 e-mail: [email protected], [email protected] Born July 31, 1978 in Osaka, Japan Education 4/1994 – 3/1997 Takatsuki High School 4/1998 – 3/2002 Kyoto University, Faculty of Integrated Human Studies 5/2003 – 3/2007 The Salk Institute for biological studies (As an exchange student) 4/2002 – 3/2010 Kyoto University, Graduate School of Biostudies 4/2010 – present Researcher at Kyoto University, Graduate School of Biostudies Fellowship 4/2002 – 3/2007 Fellowship for Graduate Students, The Japan Scholarship Foundation 4/2003 – 3/2004 Exchange student, Academic Frontiers Student Exchange Promotion Program 2003-2004 (Ministry of Education, Culture, Sports, Science and Technology, Japan) Awards Poster Award at The 3rd NTU-Kyoto U student mini-Symposium on molecular and cell biology (2008/5) Second Place Poster Award at Gordon Research Conference, Archaea: Ecology, Metabolism & Molecular Biology (2009/7) Teaching Experience 4/2008 – 3/2010 Teaching assistant at Graduate School of Biostudies, Kyoto University 4/2009 – 3/2010 Part-time lecturer at Shin-Osaka Dental Hygienist College (Biology) Publications (1) Peer-Reviewed Research Articles
Load more

Recommended publications
  • The Genome of Nanoarchaeum Equitans: Insights Into Early Archaeal Evolution and Derived Parasitism
    The genome of Nanoarchaeum equitans: Insights into early archaeal evolution and derived parasitism Elizabeth Waters†‡, Michael J. Hohn§, Ivan Ahel¶, David E. Graham††, Mark D. Adams‡‡, Mary Barnstead‡‡, Karen Y. Beeson‡‡, Lisa Bibbs†, Randall Bolanos‡‡, Martin Keller†, Keith Kretz†, Xiaoying Lin‡‡, Eric Mathur†, Jingwei Ni‡‡, Mircea Podar†, Toby Richardson†, Granger G. Sutton‡‡, Melvin Simon†, Dieter So¨ ll¶§§¶¶, Karl O. Stetter†§¶¶, Jay M. Short†, and Michiel Noordewier†¶¶ †Diversa Corporation, 4955 Directors Place, San Diego, CA 92121; ‡Department of Biology, San Diego State University, 5500 Campanile Drive, San Diego, CA 92182; §Lehrstuhl fu¨r Mikrobiologie und Archaeenzentrum, Universita¨t Regensburg, Universita¨tsstrasse 31, D-93053 Regensburg, Germany; ‡‡Celera Genomics Rockville, 45 West Gude Drive, Rockville, MD 20850; Departments of ¶Molecular Biophysics and Biochemistry and §§Chemistry, Yale University, New Haven, CT 06520-8114; and ʈDepartment of Biochemistry, Virginia Polytechnic Institute and State University, Blacksburg, VA 24061 Communicated by Carl R. Woese, University of Illinois at Urbana–Champaign, Urbana, IL, August 21, 2003 (received for review July 22, 2003) The hyperthermophile Nanoarchaeum equitans is an obligate sym- (6–8). Genomic DNA was either digested with restriction en- biont growing in coculture with the crenarchaeon Ignicoccus. zymes or sheared to provide clonable fragments. Two plasmid Ribosomal protein and rRNA-based phylogenies place its branching libraries were made by subcloning randomly sheared fragments point early in the archaeal lineage, representing the new archaeal of this DNA into a high-copy number vector (Ϸ2.8 kbp library) kingdom Nanoarchaeota. The N. equitans genome (490,885 base or low-copy number vector (Ϸ6.3 kbp library). DNA sequence pairs) encodes the machinery for information processing and was obtained from both ends of plasmid inserts to create repair, but lacks genes for lipid, cofactor, amino acid, or nucleotide ‘‘mate-pairs,’’ pairs of reads from single clones that should be biosyntheses.
    [Show full text]
  • The Mínimum Cell
    The minimum cell GENOMIC – ADVANCED GENETICS AUTHOR: I. ODEI BARREÑADA Overview The Concept Small genomes Minimal gene set Approache theories Minimal genome proyect Future insight The concept “MINIMUN CELL“ The smallest size (of genetic The smallest unit of life that can information) replicate autonomously = minimum genome Small genomes Circovirus (1.800 base pairs / 3 gens) Virus Carsonella ruddi (159 kb /182 genes) Symbiont Nanoarchaeum equitans (490 kb/ 553 genes) Parasite Mycoplasma genitalium (582 kb/ 521 genes ) Parasite Pelagibacter ubique (1,3 Mb/ 1,370 genes) Free-living Smallest genomes Circovirus (1.800 base pairs / 3 gens) Virus Carsonella ruddi (159 kb /182 genes) Symbiont Nanoarchaeum equitans (490 kb/ 553 genes) Parasite Mycoplasma genitalium (582 kb/ 521 genes ) Parasite Pelagibacter ubique (1,3 Mb/ 1,370 genes) Free-living (Giovannoni et al., 2005) “MINIMAL GENE SET” By genome comparison Ubiquitous genes: Translation Transcription Replication of DNA Variable genes: Depends of environment (Koonin, 2003) Theories for reach the minimum cell Two approaches Top – Down knock-down known organism Bottom-up --> build from synthetics DNA Minimal genome project J. Craig Venter Institute Search of essential genes Gene disruption by transposons Seq the survivors organisms Detect the disrupted gene Declare this genes as NON-ESENTIAL In M. genitalium only 382 of 521 genes are essential (Gibson et al., 2011) Build de novo M. genitalium genome Future insight - Cell design Create artificial cells for: Generation of hydrogen for fuel Capturing excess carbon dioxide in the atmosphere Drug delivery directly into the body As Enzyme therapy Artificial blood cells … And all you can think References Koonin E V.
    [Show full text]
  • The Mysterious Orphans of Mycoplasmataceae
    The mysterious orphans of Mycoplasmataceae Tatiana V. Tatarinova1,2*, Inna Lysnyansky3, Yuri V. Nikolsky4,5,6, and Alexander Bolshoy7* 1 Children’s Hospital Los Angeles, Keck School of Medicine, University of Southern California, Los Angeles, 90027, California, USA 2 Spatial Science Institute, University of Southern California, Los Angeles, 90089, California, USA 3 Mycoplasma Unit, Division of Avian and Aquatic Diseases, Kimron Veterinary Institute, POB 12, Beit Dagan, 50250, Israel 4 School of Systems Biology, George Mason University, 10900 University Blvd, MSN 5B3, Manassas, VA 20110, USA 5 Biomedical Cluster, Skolkovo Foundation, 4 Lugovaya str., Skolkovo Innovation Centre, Mozhajskij region, Moscow, 143026, Russian Federation 6 Vavilov Institute of General Genetics, Moscow, Russian Federation 7 Department of Evolutionary and Environmental Biology and Institute of Evolution, University of Haifa, Israel 1,2 [email protected] 3 [email protected] 4-6 [email protected] 7 [email protected] 1 Abstract Background: The length of a protein sequence is largely determined by its function, i.e. each functional group is associated with an optimal size. However, comparative genomics revealed that proteins’ length may be affected by additional factors. In 2002 it was shown that in bacterium Escherichia coli and the archaeon Archaeoglobus fulgidus, protein sequences with no homologs are, on average, shorter than those with homologs [1]. Most experts now agree that the length distributions are distinctly different between protein sequences with and without homologs in bacterial and archaeal genomes. In this study, we examine this postulate by a comprehensive analysis of all annotated prokaryotic genomes and focusing on certain exceptions.
    [Show full text]
  • Insights Into Archaeal Evolution and Symbiosis from the Genomes of a Nanoarchaeon and Its Inferred Crenarchaeal Host from Obsidian Pool, Yellowstone National Park
    University of Tennessee, Knoxville TRACE: Tennessee Research and Creative Exchange Microbiology Publications and Other Works Microbiology 4-22-2013 Insights into archaeal evolution and symbiosis from the genomes of a nanoarchaeon and its inferred crenarchaeal host from Obsidian Pool, Yellowstone National Park Mircea Podar University of Tennessee - Knoxville, [email protected] Kira S. Makarova National Institutes of Health David E. Graham University of Tennessee - Knoxville, [email protected] Yuri I. Wolf National Institutes of Health Eugene V. Koonin National Institutes of Health See next page for additional authors Follow this and additional works at: https://trace.tennessee.edu/utk_micrpubs Part of the Microbiology Commons Recommended Citation Biology Direct 2013, 8:9 doi:10.1186/1745-6150-8-9 This Article is brought to you for free and open access by the Microbiology at TRACE: Tennessee Research and Creative Exchange. It has been accepted for inclusion in Microbiology Publications and Other Works by an authorized administrator of TRACE: Tennessee Research and Creative Exchange. For more information, please contact [email protected]. Authors Mircea Podar, Kira S. Makarova, David E. Graham, Yuri I. Wolf, Eugene V. Koonin, and Anna-Louise Reysenbach This article is available at TRACE: Tennessee Research and Creative Exchange: https://trace.tennessee.edu/ utk_micrpubs/44 Podar et al. Biology Direct 2013, 8:9 http://www.biology-direct.com/content/8/1/9 RESEARCH Open Access Insights into archaeal evolution and symbiosis from the genomes of a nanoarchaeon and its inferred crenarchaeal host from Obsidian Pool, Yellowstone National Park Mircea Podar1,2*, Kira S Makarova3, David E Graham1,2, Yuri I Wolf3, Eugene V Koonin3 and Anna-Louise Reysenbach4 Abstract Background: A single cultured marine organism, Nanoarchaeum equitans, represents the Nanoarchaeota branch of symbiotic Archaea, with a highly reduced genome and unusual features such as multiple split genes.
    [Show full text]
  • Symbiosis in Archaea: Functional and Phylogenetic Diversity of Marine and Terrestrial Nanoarchaeota and Their Hosts
    Portland State University PDXScholar Dissertations and Theses Dissertations and Theses Winter 3-13-2019 Symbiosis in Archaea: Functional and Phylogenetic Diversity of Marine and Terrestrial Nanoarchaeota and their Hosts Emily Joyce St. John Portland State University Follow this and additional works at: https://pdxscholar.library.pdx.edu/open_access_etds Part of the Bacteriology Commons, and the Biology Commons Let us know how access to this document benefits ou.y Recommended Citation St. John, Emily Joyce, "Symbiosis in Archaea: Functional and Phylogenetic Diversity of Marine and Terrestrial Nanoarchaeota and their Hosts" (2019). Dissertations and Theses. Paper 4939. https://doi.org/10.15760/etd.6815 This Thesis is brought to you for free and open access. It has been accepted for inclusion in Dissertations and Theses by an authorized administrator of PDXScholar. Please contact us if we can make this document more accessible: [email protected]. Symbiosis in Archaea: Functional and Phylogenetic Diversity of Marine and Terrestrial Nanoarchaeota and their Hosts by Emily Joyce St. John A thesis submitted in partial fulfillment of the requirements for the degree of Master of Science in Biology Thesis Committee: Anna-Louise Reysenbach, Chair Anne W. Thompson Rahul Raghavan Portland State University 2019 © 2019 Emily Joyce St. John i Abstract The Nanoarchaeota are an enigmatic lineage of Archaea found in deep-sea hydrothermal vents and geothermal springs across the globe. These small (~100-400 nm) hyperthermophiles live ectosymbiotically with diverse hosts from the Crenarchaeota. Despite their broad distribution in high-temperature environments, very few Nanoarchaeota have been successfully isolated in co-culture with their hosts and nanoarchaeote genomes are poorly represented in public databases.
    [Show full text]
  • Predicted Highly Expressed Genes in Archaeal Genomes
    Predicted highly expressed genes in archaeal genomes Samuel Karlin*†, Jan Mra´ zek*, Jiong Ma‡, and Luciano Brocchieri* Departments of *Mathematics and ‡Biological Sciences, Stanford University, Stanford, CA 94305-2125 Contributed by Samuel Karlin, March 25, 2005 Based primarily on 16S rRNA sequence comparisons, life has been Table 1. Archaeal genomes broadly divided into the three domains of Bacteria, Archaea, and Optimal No. of Eukarya. Archaea is further classified into Crenarchaea and Eur- Genome growth G ϩ C genes yarchaea. Archaea generally thrive in extreme environments as Name size, kb temp, °C content, % Ն80 aa assessed by temperature, pH, and salinity. For many prokaryotic organisms, ribosomal proteins (RP), transcription͞translation fac- Crenarchaea tors, and chaperone genes tend to be highly expressed. A gene is SULSO 2,992 80 36 2,869 predicted highly expressed (PHX) if its codon usage is rather similar SULTO 2,695 80 33 2,657 to the average codon usage of at least one of the RP, transcription͞ AERPE 1,670 90 56 1,783 translation factors, and chaperone gene classes and deviates PYRAE 2,222 100 51 2,290 strongly from the average gene of the genome. The thermosome Euryarchaea (Ths) chaperonin family represents the most salient PHX genes PYRAB 1,765 96 45 1,786 among Archaea. The chaperones Trigger factor and HSP70 have PYRFU 1,908 96 41 1,941 overlapping functions in the folding process, but both of these PYRHO 1,739 96 42 1,828 THEAC 1,565 59 46 1,415 proteins are lacking in most archaea where they may be substi- THEVO 1,585 60 40 1,415 tuted by the chaperone prefoldin.
    [Show full text]
  • The Complete Set of Trna Species in Nanoarchaeum Equitans
    FEBS 29588 FEBS Letters 579 (2005) 2945–2947 The complete set of tRNA species in Nanoarchaeum equitans Lennart Randaua, Michael Pearsonb, Dieter So¨lla,c,* a Department of Molecular Biophysics and Biochemistry, Yale University, 266 Whitney Avenue, New Haven, CT 06520-8114, USA b Department of Molecular, Cellular and Developmental Biology, Sinsheimer Laboratories, UCSC, Santa Cruz, CA 95064, USA c Department of Chemistry, Yale University, 266 Whitney Avenue, New Haven, CT 06520-8114, USA Received 22 April 2005; accepted 25 April 2005 Available online 3 May 2005 Edited by Lev Kisselev led to the reannotation of three tRNA genes and provide N. Abstract The archaeal parasite Nanoarchaeum equitans was found to generate five tRNA species via a unique process requir- equitans with a complete set of tRNAs. ing the assembly of seperate 50 and 30 tRNA halves [Randau, L., Mu¨nch, R., Hohn, M.J., Jahn, D. and So¨ll, D. (2005) Nanoar- chaeum equitans creates functional tRNAs from separate genes 2. Materials and methods for their 50- and 30-halves. Nature 433, 537–541]. Biochemical evidence was missing for one of the computationally-predicted, 2.1. Cell cultivation and tRNA isolation joined tRNAs designated as tRNATrp. Our RT-PCR and N. equitans cells were grown in a 300 l fermenter in a simultaneous sequencing results identify this tRNA as tRNALys (CUU) joined culture with Ignicoccus sp. and purified by gradient centrifugation as at the alternative position between bases 30 and 31. We show described [3]. Total tRNA was prepared by SDS-lysis of the cell pellet, that the intron-containing tRNATrp was misidentified in the ini- phenol/chloroform extraction and MonoQ anion-exchange chroma- tial Nanoarchaeum equitans genome annotation [E.
    [Show full text]
  • Annotation of Protein Domains Reveals Remarkable Conservation in the Functional Make up of Proteomes Across Superkingdoms
    Genes 2011, 2, 869-911; doi:10.3390/genes2040869 OPEN ACCESS genes ISSN 2073-4425 www.mdpi.com/journal/genes Article Annotation of Protein Domains Reveals Remarkable Conservation in the Functional Make up of Proteomes Across Superkingdoms Arshan Nasir 1, Aisha Naeem 2, Muhammad Jawad Khan 2, Horacio D. Lopez-Nicora 3 and Gustavo Caetano-Anollés 1,* 1 Evolutionary Bioinformatics Laboratory, Department of Crop Sciences, University of Illinois, Urbana, IL 61801, USA; E-Mail: [email protected] 2 Mammalian NutriPhysioGenomics Laboratory, Department of Animal Sciences, University of Illinois, Urbana, IL 61801, USA; E-Mails: [email protected] (A.Na.); [email protected] (M.J.K.) 3 Plant Pathology Laboratory, Department of Crop Sciences, University of Illinois, Urbana, IL 61801, USA; E-Mail: [email protected] * Author to whom correspondence should be addressed; E-Mail: [email protected]; Tel.: +1-217-333-8172; Fax: +1-217-333-8046. Received: 16 September 2011; in revised form: 28 October 2011 / Accepted: 28 October 2011 / Published: 8 November 2011 Abstract: The functional repertoire of a cell is largely embodied in its proteome, the collection of proteins encoded in the genome of an organism. The molecular functions of proteins are the direct consequence of their structure and structure can be inferred from sequence using hidden Markov models of structural recognition. Here we analyze the functional annotation of protein domain structures in almost a thousand sequenced genomes, exploring the functional and structural diversity of proteomes. We find there is a remarkable conservation in the distribution of domains with respect to the molecular functions they perform in the three superkingdoms of life.
    [Show full text]
  • Genome Watchhoney, I Shrunk the Mimiviral Genome
    NEWS & ANALYSIS GENOME WATCH Honey, I shrunk the mimiviral genome Isheng J. Tsai This month’s Genome Watch describes how does contain the genes for components that gel electrophoresis). The team isolated the bald the large size of the mimiviral genome is a allow translation competence, such as genes form of the virus and sequenced its genome, result of the sympatric lifestyle of mimivirus encoding four aminoacyl-tRNA synthetases. finding that it had lost 17% of the wild-type in host amoebae. The genome also contains genes (for exam­ mimiviral genome, corresponding to 155 ple, those encoding topoisomerase IA, IB and genes, through deletions. It was revealed that Viruses are typically small in physical size IIA) that are suggestive of alternative mecha­ more than one-third of the total genes involved as well as genome size (ranging from a few nisms of DNA repair which are not seen in in intracellular host–virus interactions were kilobases to a few hundred kilobases), mak­ other viruses. Thus, mimivirus exhibits greater lost. By comparing the proteomes of the wild- ing the discovery of the mimivirus, a nucleo­ genetic complexity than many intracellular type mimivirus and the bald form, the com­ cytoplasmic large DNA virus (NCLDV) bacterial parasites, leading many to rethink the plete lack of fibre was attributed to the loss found replicating in amoebae, something of traditional assumptions that are made when of two (L829 and R135) of the three proteins a shock to virologists and evolutionary biolo­ defining a virus. that form the fibres. Interestingly, the loss of gists. Mimivirus (so named for its mimicry of a Mimivirus has a sympatric lifestyle, shar­ fibres makes mimivirus more resistant to the microorganism) is currently the largest known ing its amoebal niche with many other spe­ virophage Sputnik, which was thought to attach virus both in terms of its particle size (750 nm cies of microorganism.
    [Show full text]
  • Insights Into the Metabolism, Lifestyle and Putative Evolutionary History of the Novel Archaeal Phylum ‘Diapherotrites’
    The ISME Journal (2015) 9, 447–460 & 2015 International Society for Microbial Ecology All rights reserved 1751-7362/15 www.nature.com/ismej ORIGINAL ARTICLE Insights into the metabolism, lifestyle and putative evolutionary history of the novel archaeal phylum ‘Diapherotrites’ Noha H Youssef1, Christian Rinke2, Ramunas Stepanauskas3, Ibrahim Farag1, Tanja Woyke2 and Mostafa S Elshahed1 1Department of Microbiology and Molecular Genetics, Oklahoma State University, Stillwater, OK, USA; 2DOE Joint Genome Institute, Walnut Creek, CA, USA and 3Bigelow Laboratory for Ocean Sciences, East Boothbay, ME, USA The archaeal phylum ‘Diapherotrites’ was recently proposed based on phylogenomic analysis of genomes recovered from an underground water seep in an abandoned gold mine (Homestake mine in Lead, SD, USA). Here we present a detailed analysis of the metabolic capabilities and genomic features of three single amplified genomes (SAGs) belonging to the ‘Diapherotrites’. The most complete of the SAGs, Candidatus ‘Iainarchaeum andersonii’ (Cand. IA), had a small genome (B1.24 Mb), short average gene length (822 bp), one ribosomal RNA operon, high coding density (B90.4%), high percentage of overlapping genes (27.6%) and low incidence of gene duplication (2.16%). Cand. IA genome possesses limited catabolic capacities that, nevertheless, could theoretically support a free-living lifestyle by channeling a narrow range of substrates such as ribose, polyhydroxybutyrate and several amino acids to acetyl-coenzyme A. On the other hand, Cand. IA possesses relatively well-developed anabolic capabilities, although it remains auxotrophic for several amino acids and cofactors. Phylogenetic analysis suggests that the majority of Cand. IA anabolic genes were acquired from bacterial donors via horizontal gene transfer.
    [Show full text]
  • Tailed Giant Tupanvirus Possesses the Most Complete Translational Apparatus of the Known Virosphere
    ARTICLE DOI: 10.1038/s41467-018-03168-1 OPEN Tailed giant Tupanvirus possesses the most complete translational apparatus of the known virosphere Jônatas Abrahão1,2, Lorena Silva1,2, Ludmila Santos Silva1,2, Jacques Yaacoub Bou Khalil3, Rodrigo Rodrigues2, Thalita Arantes2, Felipe Assis2, Paulo Boratto2, Miguel Andrade4, Erna Geessien Kroon2, Bergmann Ribeiro 4, Ivan Bergier 5, Herve Seligmann1, Eric Ghigo1, Philippe Colson1, Anthony Levasseur1, Guido Kroemer6,7,8,9,10,11,12, Didier Raoult1 & Bernard La Scola1 1234567890():,; Here we report the discovery of two Tupanvirus strains, the longest tailed Mimiviridae members isolated in amoebae. Their genomes are 1.44–1.51 Mb linear double-strand DNA coding for 1276–1425 predicted proteins. Tupanviruses share the same ancestors with mimivirus lineages and these giant viruses present the largest translational apparatus within the known virosphere, with up to 70 tRNA, 20 aaRS, 11 factors for all translation steps, and factors related to tRNA/mRNA maturation and ribosome protein modification. Moreover, two sequences with significant similarity to intronic regions of 18 S rRNA genes are encoded by the tupanviruses and highly expressed. In this translation-associated gene set, only the ribosome is lacking. At high multiplicity of infections, tupanvirus is also cytotoxic and causes a severe shutdown of ribosomal RNA and a progressive degradation of the nucleus in host and non-host cells. The analysis of tupanviruses constitutes a new step toward understanding the evolution of giant viruses. 1 MEPHI, APHM, IRD 198, Aix Marseille Univ, IHU-Méditerranee Infection, 19-21 Bd Jean Moulin, 13005 Marseille, France. 2 Laboratório de Vírus, Instituto de Ciências Biológicas, Departamento de Microbiologia, Universidade Federal de Minas Gerais, Belo Horizonte 31270-901, Brazil.
    [Show full text]
  • Title Analysis of the Genome Architecture of The
    Analysis of the genome architecture of the hyperthermopholic Title archaeon Thermococcus kodakarensis( Dissertation_全文 ) Author(s) Maruyama, Hugo Citation Kyoto University (京都大学) Issue Date 2011-03-23 URL http://dx.doi.org/10.14989/doctor.k16233 Right Type Thesis or Dissertation Textversion author Kyoto University Analysis of the genome architecture of the hyperthermophilic archaeon Thermococcus kodakarensis Hugo Maruyama 要旨 ゲノム DNA は細胞内で高度に折りたたまれ、この染色体高次構造は転写・複製・染色体分 配といった機構と密接に結びついている。染色体の主要な構成タンパク質は真核生物では ヒストン、バクテリアでは HU と全く異なるが、一様な基本構造を基にゲノム DNA が階層 的に折りたたまれている点で両者の染色体構造は共通している。アーキアは真核生物・バ クテリアと並ぶ生命の第三のドメインであり、遺伝情報の発現(複製・転写・翻訳)の機 構は真核生物に、代謝経路はバクテリアに近い。アーキアには染色体を構成するタンパク 質として真核生物のヒストンに相同なもの、バクテリアの HU に相同なもの、アーキア特有 の Alba と呼ばれるタンパク質などが存在し、種によってゲノムがコードするタンパク質の 組合せが異なる。様々なアーキアのゲノムがどのような高次構造を形成しているかを明ら かにすることで、三つのドメインにわたるゲノム構造の共通性あるいは多様性を明らかに できる。本研究ではその第一歩としてヒストンを持つ超好熱性アーキア Thermococcus kodakarensis の染色体構造を解析した。 T. kodakarensis の染色体に含まれるタンパク質を質量分析により同定した結果、ヒ ストン、Alba、TK0471(TrmBL2)、 RNA ポリメラーゼ等の DNA 結合タンパク質が含まれ ることが分かった。TK0471 は転写因子 TrmB と相同な機能未知の DNA 結合タンパク質で あった。次に、染色体をミクロコッカルヌクレアーゼで部分消化した後、5%-20%のショ糖 密度勾配遠心により構成タンパク質の異なる染色体断片が分離された。原子間力顕微鏡に よる解析から、ヒストンは DNA 上に beads-on-a-string 構造を、TK0471 は線維状の構造を形 成することが示された。また大腸菌で発現させた組換えタンパク質(ヒストンおよび TK0471)を用いて同様の構造が DNA 上に再構成された。ショ糖密度勾配で分離されたそ れぞれの染色体断片に含まれる DNA 配列を超並列シークエンサーで同定した結果、ヒスト ンおよび TK0471 はゲノム上のプロモーター領域にもコーディング領域にも偏りなく存在 するが、両者の存在する領域は重複しない傾向があった。以上の結果から、T. kodakarensis の染色体上には、構成タンパク質および構造の異なる領域が存在することが明らかとなっ た。相同組換えにより TK0471 遺伝子を破壊すると染色体の DNA 消化酵素に対する感受性 が高まった。また、約 100 個の遺伝子の転写産物量が増加した。TK0471
    [Show full text]