Your search keyword '"Aravind, L."' showing total 27 results

1. Novel eukaryotic enzymes modifying cell-surface biopolymers.

Author

Anantharaman V and Aravind L

Subjects

Acyltransferases chemistry, Adenosine Triphosphate metabolism, Amino Acid Sequence, Animals, Esterases chemistry, Esterases classification, Fungal Proteins chemistry, Molecular Sequence Data, Protein Structure, Tertiary, Sequence Alignment, Acyltransferases metabolism, Biopolymers metabolism, Cell Membrane metabolism, Esterases metabolism, Eukaryotic Cells enzymology

Abstract

Background: Eukaryotic extracellular matrices such as proteoglycans, sclerotinized structures, mucus, external tests, capsules, cell walls and waxes contain highly modified proteins, glycans and other composite biopolymers. Using comparative genomics and sequence profile analysis we identify several novel enzymes that could be potentially involved in the modification of cell-surface glycans or glycoproteins., Results: Using sequence analysis and conservation we define the acyltransferase domain prototyped by the fungal Cas1p proteins, identify its active site residues and unify them to the superfamily of classical 10TM acyltransferases (e.g. oatA). We also identify a novel family of esterases (prototyped by the previously uncharacterized N-terminal domain of Cas1p) that have a similar fold as the SGNH/GDSL esterases but differ from them in their conservation pattern., Conclusions: We posit that the combined action of the acyltransferase and esterase domain plays an important role in controlling the acylation levels of glycans and thereby regulates their physico-chemical properties such as hygroscopicity, resistance to enzymatic hydrolysis and physical strength. We present evidence that the action of these novel enzymes on glycans might play an important role in host-pathogen interaction of plants, fungi and metazoans. We present evidence that in plants (e.g. PMR5 and ESK1) the regulation of carbohydrate acylation by these acylesterases might also play an important role in regulation of transpiration and stress resistance. We also identify a subfamily of these esterases in metazoans (e.g. C7orf58), which are fused to an ATP-grasp amino acid ligase domain that is predicted to catalyze, in certain animals, modification of cell surface polymers by amino acid or peptides., Reviewers: This article was reviewed by Gaspar Jekely and Frank Eisenhaber.

Published

2010

2. HPC2 and ubinuclein define a novel family of histone chaperones conserved throughout eukaryotes.

Author

Balaji S, Iyer LM, and Aravind L

Subjects

Amino Acid Sequence, Animals, Evolution, Molecular, Molecular Sequence Data, Neoplasm Proteins chemistry, Phylogeny, Plasmodium genetics, Protein Structure, Tertiary, Sequence Alignment, Conserved Sequence, Eukaryotic Cells metabolism, Histones metabolism, Molecular Chaperones metabolism, Neoplasm Proteins metabolism, Nuclear Proteins metabolism

Abstract

While histone chaperones have been intensely studied, the roles of components of the Hir-Asf1 histone chaperone complex such as Hir3p and Hpc2p are poorly understood. Using sensitive protein sequence profile analyses we investigated the evolution of these proteins and showed that Hir3p and Hpc2p have a much wider phyletic pattern than was previously known. We established the animal histone-deacetylase-complex-interacting proteins, CAIN/CABIN, to be orthologs of Hir3p. They contain a conserved core of around 30 TPR-like bi-helical repeats that are likely to form a super-helical scaffold. We identified a conserved domain, the HUN domain, in all Hpc2p homologs, including animal ubinuclein/yemanuclein and the recently discovered vertebrate cell-cycle regulator FLJ25778. The HUN domain has a characteristic pattern of conserved acidic residues based on which we predict that it is a previously unrecognized histone-tail-binding chaperone. By analyzing various high-throughput data sets, such as RNAi knock-downs, genetic and protein interaction maps and cell-cycle-specific gene expression data, we present evidence that Hpc2p homologs might be deployed in specific processes of chromatin dynamics relating to cell-cycle progression in vertebrates and schizogony in Plasmodium. Beyond the conserved HUN domain these proteins show extensive divergence patterns in different eukaryotic lineages. Hence, we propose that Hpc2p homologs are probably involved in recruitment of the ancient conserved histone-loading Hir-Asf1 complex to different lineage-specific chromatin reorganization processes.

Published

2009

3. MutL homologs in restriction-modification systems and the origin of eukaryotic MORC ATPases.

Author

Iyer LM, Abhiman S, and Aravind L

Subjects

Adenosine Triphosphatases genetics, Adenosine Triphosphatases physiology, Adenosine Triphosphatases supply & distribution, Amino Acid Sequence, Bacterial Proteins chemistry, Bacterial Proteins genetics, DNA Restriction-Modification Enzymes genetics, DNA Restriction-Modification Enzymes physiology, Escherichia coli Proteins genetics, Escherichia coli Proteins physiology, Humans, Molecular Sequence Data, MutL Proteins, Nuclear Proteins genetics, Nuclear Proteins physiology, Adenosine Triphosphatases chemistry, DNA Restriction-Modification Enzymes chemistry, Escherichia coli Proteins chemistry, Eukaryotic Cells enzymology, Evolution, Molecular, Nuclear Proteins chemistry

Abstract

The provenance and biochemical roles of eukaryotic MORC proteins have remained poorly understood since the discovery of their prototype MORC1, which is required for meiotic nuclear division in animals. The MORC family contains a combination of a gyrase, histidine kinase, and MutL (GHKL) and S5 domains that together constitute a catalytically active ATPase module. We identify the prokaryotic MORCs and establish that the MORC family belongs to a larger radiation of several families of GHKL proteins (paraMORCs) in prokaryotes. Using contextual information from conserved gene neighborhoods we show that these proteins primarily function in restriction-modification systems, in conjunction with diverse superfamily II DNA helicases and endonucleases. The common ancestor of these GHKL proteins, MutL and topoisomerase ATPase modules appears to have catalyzed structural reorganization of protein complexes and concomitant DNA-superstructure manipulations along with fused or standalone nuclease domains. Furthermore, contextual associations of the prokaryotic MORCs and their relatives suggest that their eukaryotic counterparts are likely to carry out chromatin remodeling by DNA superstructure manipulation in response to epigenetic signals such as histone and DNA methylation.

Published

2008

4. Comparative genomics of transcription factors and chromatin proteins in parasitic protists and other eukaryotes.

Author

Iyer LM, Anantharaman V, Wolf MY, and Aravind L

Subjects

Animals, Genomics, Host-Parasite Interactions, Nucleoproteins genetics, Phylogeny, Protein Structure, Tertiary, Chromatin genetics, Eukaryotic Cells metabolism, Evolution, Molecular, Parasites genetics, Transcription Factors genetics

Abstract

Comparative genomics of parasitic protists and their free-living relatives are profoundly impacting our understanding of the regulatory systems involved in transcription and chromatin dynamics. While some parts of these systems are highly conserved, other parts are rapidly evolving, thereby providing the molecular basis for the variety in the regulatory adaptations of eukaryotes. The gross number of specific transcription factors and chromatin proteins are positively correlated with proteome size in eukaryotes. However, the individual types of specific transcription factors show an enormous variety across different eukaryotic lineages. The dominant families of specific transcription factors even differ between sister lineages, and have been shaped by gene loss and lineage-specific expansions. Recognition of this principle has helped in identifying the hitherto unknown, major specific transcription factors of several parasites, such as apicomplexans, Entamoeba histolytica, Trichomonas vaginalis, Phytophthora and ciliates. Comparative analysis of predicted chromatin proteins from protists allows reconstruction of the early evolutionary history of histone and DNA modification, nucleosome assembly and chromatin-remodeling systems. Many key catalytic, peptide-binding and DNA-binding domains in these systems ultimately had bacterial precursors, but were put together into distinctive regulatory complexes that are unique to the eukaryotes. In the case of histone methylases, histone demethylases and SWI2/SNF2 ATPases, proliferation of paralogous families followed by acquisition of novel domain architectures, seem to have played a major role in producing a diverse set of enzymes that create and respond to an epigenetic code of modified histones. The diversification of histone acetylases and DNA methylases appears to have proceeded via repeated emergence of new versions, most probably via transfers from bacteria to different eukaryotic lineages, again resulting in lineage-specific diversity in epigenetic signals. Even though the key histone modifications are universal to eukaryotes, domain architectures of proteins binding post-translationally modified-histones vary considerably across eukaryotes. This indicates that the histone code might be "interpreted" differently from model organisms in parasitic protists and their relatives. The complexity of domain architectures of chromatin proteins appears to have increased during eukaryotic evolution. Thus, Trichomonas, Giardia, Naegleria and kinetoplastids have relatively simple domain architectures, whereas apicomplexans and oomycetes have more complex architectures. RNA-dependent post-transcriptional silencing systems, which interact with chromatin-level regulatory systems, show considerable variability across parasitic protists, with complete loss in many apicomplexans and partial loss in Trichomonas vaginalis. This evolutionary synthesis offers a robust scaffold for future investigation of transcription and chromatin structure in parasitic protists.

Published

2008

5. Comparative genomics of protists: new insights into the evolution of eukaryotic signal transduction and gene regulation.

Author

Anantharaman V, Iyer LM, and Aravind L

Subjects

Gene Silencing, Genetic Variation, Phosphorylation, Eukaryotic Cells physiology, Gene Expression Regulation, Genomics, Signal Transduction physiology

Abstract

Data from protist genomes suggest that eukaryotes show enormous variability in their gene complements, especially of genes coding regulatory proteins. Overall counts of eukaryotic signaling proteins show weak nonlinear scaling with proteome size, but individual superfamilies of signaling domains might show vast expansions in certain protists. Alteration of domain architectural complexity of signaling proteins and repeated lineage-specific reshaping of architectures might have played a major role in the emergence of new signaling interactions in different eukaryotes. Lateral transfer of various signaling domains from bacteria or from hosts, in parasites such as apicomplexans, appears to also have played a major role in the origin of new functional networks. Lineage-specific expansion of regulatory proteins, particularly of transcription factors, has played a critical role in the adaptive radiation of different protist lineages. Comparative genomics allows objective reconstruction of the ancestral conditions and subsequent diversification of several regulatory systems involved in phosphorylation, cyclic nucleotide signaling, Ubiquitin conjugation, chromatin remodeling, and posttranscriptional gene silencing.

Published

2007

6. Comparative genomics and structural biology of the molecular innovations of eukaryotes.

Author

Aravind L, Iyer LM, and Koonin EV

Subjects

Animals, Gene Duplication, Humans, Protein Folding, Protein Structure, Tertiary, Proteins chemistry, Proteins genetics, Computational Biology methods, Eukaryotic Cells physiology, Evolution, Molecular, Genomics methods

Abstract

Eukaryotes encode numerous proteins that either have no detectable homologs in prokaryotes or have only distant homologs. These molecular innovations of eukaryotes may be classified into three categories: proteins and domains inherited from prokaryotic precursors without drastic changes in biochemical function, but often recruited for novel roles in eukaryotes; new superfamilies or distinct biochemical functions emerging within pre-existing protein folds; and domains with genuinely new folds, apparently 'invented' at the outset of eukaryotic evolution. Most new folds emerging in eukaryotes are either alpha-helical or stabilized by metal chelation. Comparative genomics analyses point to an early phase of rapid evolution, and dramatic changes between the origin of the eukaryotic cell and the advent of the last common ancestor of extant eukaryotes. Extensive duplication of numerous genes, with subsequent functional diversification, is a distinctive feature of this turbulent era. Evolutionary analysis of ancient eukaryotic proteins is generally compatible with a two-symbiont scenario for eukaryotic origin, involving an alpha-proteobacterium (the ancestor of the mitochondria) and an archaeon, as well as key contributions from their selfish elements.

Published

2006

7. Comparative analysis of apicomplexa and genomic diversity in eukaryotes.

Author

Templeton TJ, Iyer LM, Anantharaman V, Enomoto S, Abrahante JE, Subramanian GM, Hoffman SL, Abrahamsen MS, and Aravind L

Subjects

Animals, Apicomplexa classification, Apicomplexa pathogenicity, Cell Adhesion, Chromatin, Cryptosporidium classification, Cryptosporidium pathogenicity, Evolution, Molecular, Genome, Glycosylation, Introns, Membrane Proteins genetics, Membrane Proteins metabolism, Phylogeny, Plasmodium classification, Plasmodium pathogenicity, Signal Transduction, Transcription, Genetic genetics, Apicomplexa genetics, Cryptosporidium genetics, Eukaryotic Cells physiology, Genes, Protozoan, Genetic Variation, Plasmodium genetics

Abstract

The apicomplexans Plasmodium and Cryptosporidium have developed distinctive adaptations via lineage-specific gene loss and gene innovation in the process of diverging from a common parasitic ancestor. The two lineages have acquired distinct but overlapping sets of surface protein adhesion domains typical of animal proteins, but in no case do they share multidomain architectures identical to animals. Cryptosporidium, but not Plasmodium, possesses an animal-type O-linked glycosylation pathway, along with >30 predicted surface proteins having mucin-like segments. The two parasites have notable qualitative differences in conserved protein architectures associated with chromatin dynamics and transcription. Cryptosporidium shows considerable reduction in the number of introns and a concomitant loss of spliceosomal machinery components. We also describe additional molecular characteristics distinguishing Apicomplexa from other eukaryotes for which complete genome sequences are available.

Published

2004

8. Novel conserved domains in proteins with predicted roles in eukaryotic cell-cycle regulation, decapping and RNA stability.

Author

Anantharaman V and Aravind L

Subjects

Amino Acid Sequence, Animals, Archaeal Proteins chemistry, Bacterial Proteins chemistry, Catalysis, Fungal Proteins chemistry, Fungal Proteins physiology, Models, Molecular, Molecular Sequence Data, Phylogeny, Plant Proteins chemistry, Plant Proteins physiology, Prokaryotic Cells metabolism, Protein Conformation, Protein Folding, Protein Structure, Tertiary, RNA-Binding Proteins chemistry, Sequence Alignment, Sequence Homology, Amino Acid, Structure-Activity Relationship, Cell Cycle physiology, Eukaryotic Cells metabolism, Evolution, Molecular, Multigene Family, RNA metabolism, RNA Caps metabolism, RNA-Binding Proteins metabolism

Abstract

Background: The emergence of eukaryotes was characterized by the expansion and diversification of several ancient RNA-binding domains and the apparent de novo innovation of new RNA-binding domains. The identification of these RNA-binding domains may throw light on the emergence of eukaryote-specific systems of RNA metabolism., Results: Using sensitive sequence profile searches, homology-based fold recognition and sequence-structure superpositions, we identified novel, divergent versions of the Sm domain in the Scd6p family of proteins. This family of Sm-related domains shares certain features of conventional Sm domains, which are required for binding RNA, in addition to possessing some unique conserved features. We also show that these proteins contain a second previously uncharacterized C-terminal domain, termed the FDF domain (after a conserved sequence motif in this domain). The FDF domain is also found in the fungal Dcp3p-like and the animal FLJ22128-like proteins, where it fused to a C-terminal domain of the YjeF-N domain family. In addition to the FDF domains, the FLJ22128-like proteins contain yet another divergent version of the Sm domain at their extreme N-terminus. We show that the YjeF-N domains represent a novel version of the Rossmann fold that has acquired a set of catalytic residues and structural features that distinguish them from the conventional dehydrogenases., Conclusions: Several lines of contextual information suggest that the Scd6p family and the Dcp3p-like proteins are conserved components of the eukaryotic RNA metabolism system. We propose that the novel domains reported here, namely the divergent versions of the Sm domain and the FDF domain may mediate specific RNA-protein and protein-protein interactions in cytoplasmic ribonucleoprotein complexes. More specifically, the protein complexes containing Sm-like domains of the Scd6p family are predicted to regulate the stability of mRNA encoding proteins involved in cell cycle progression and vesicular assembly. The Dcp3p and FLJ22128 proteins may localize to the cytoplasmic processing bodies and possibly catalyze a specific processing step in the decapping pathway. The explosive diversification of Sm domains appears to have played a role in the emergence of several uniquely eukaryotic ribonucleoprotein complexes, including those involved in decapping and mRNA stability.

Published

2004

9. Evolutionary connections between bacterial and eukaryotic signaling systems: a genomic perspective.

Author

Aravind L, Anantharaman V, and Iyer LM

Subjects

Bacterial Physiological Phenomena, Biological Evolution, Eukaryotic Cells physiology, Genomics, Signal Transduction genetics

Abstract

Recent advances in microbial genomics suggest that several protein domains are common to bacterial and eukaryotic regulatory proteins. In particular, developmentally and morphologically complex prokaryotes appear to share several signaling modules with eukaryotes. New experimental studies and information from domain architectures point to several similar mechanistic themes in bacterial and eukaryotic signaling proteins. Laterally transferred protein domains, originally of bacterial provenance, appear to have contributed to the evolution of sensory pathways related to light, redox and nitric oxide signaling, and developmental pathways, such as Notch, cytokine and cytokinin signaling in eukaryotes.

Published

2003

10. Evolutionary connection between the catalytic subunits of DNA-dependent RNA polymerases and eukaryotic RNA-dependent RNA polymerases and the origin of RNA polymerases.

Author

Iyer LM, Koonin EV, and Aravind L

Subjects

Amino Acid Sequence, Bacteria enzymology, Bacteria genetics, Bacteriophages enzymology, Binding Sites, Catalytic Domain, Conserved Sequence, DNA-Directed RNA Polymerases metabolism, Models, Molecular, Molecular Sequence Data, Protein Structure, Tertiary, Protein Subunits, RNA-Dependent RNA Polymerase metabolism, Sequence Alignment, DNA-Directed RNA Polymerases chemistry, DNA-Directed RNA Polymerases genetics, Eukaryotic Cells enzymology, Evolution, Molecular, RNA-Dependent RNA Polymerase chemistry, RNA-Dependent RNA Polymerase genetics

Abstract

Background: The eukaryotic RNA-dependent RNA polymerase (RDRP) is involved in the amplification of regulatory microRNAs during post-transcriptional gene silencing. This enzyme is highly conserved in most eukaryotes but is missing in archaea and bacteria. No evolutionary relationship between RDRP and other polymerases has been reported so far, hence the origin of this eukaryote-specific polymerase remains a mystery., Results: Using extensive sequence profile searches, we identified bacteriophage homologs of the eukaryotic RDRP. The comparison of the eukaryotic RDRP and their homologs from bacteriophages led to the delineation of the conserved portion of these enzymes, which is predicted to harbor the catalytic site. Further, detailed sequence comparison, aided by examination of the crystal structure of the DNA-dependent RNA polymerase (DDRP), showed that the RDRP and the beta' subunit of DDRP (and its orthologs in archaea and eukaryotes) contain a conserved double-psi beta-barrel (DPBB) domain. This DPBB domain contains the signature motif DbDGD (b is a bulky residue), which is conserved in all RDRPs and DDRPs and contributes to catalysis via a coordinated divalent cation. Apart from the DPBB domain, no similarity was detected between RDRP and DDRP, which leaves open two scenarios for the origin of RDRP: i) RDRP evolved at the onset of the evolution of eukaryotes via a duplication of the DDRP beta' subunit followed by dramatic divergence that obliterated the sequence similarity outside the core catalytic domain and ii) the primordial RDRP, which consisted primarily of the DPBB domain, evolved from a common ancestor with the DDRP at a very early stage of evolution, during the RNA world era. The latter hypothesis implies that RDRP had been subsequently eliminated from cellular life forms and might have been reintroduced into the eukaryotic genomes through a bacteriophage. Sequence and structure analysis of the DDRP led to further insights into the evolution of RNA polymerases. In addition to the beta' subunit, beta subunit of DDRP also contains a DPBB domain, which is, however, distorted by large inserts and does not harbor a counterpart of the DbDGD motif. The DPBB domains of the two DDRP subunits together form the catalytic cleft, with the domain from the beta' subunit supplying the metal-coordinating DbDGD motif and the one from the beta subunit providing two lysine residues involved in catalysis. Given that the two DPBB domains of DDRP contribute completely different sets of active residues to the catalytic center, it is hypothesized that the ultimate ancestor of RNA polymerases functioned as a homodimer of a generic, RNA-binding DPBB domain. This ancestral protein probably did not have catalytic activity and served as a cofactor for a ribozyme RNA polymerase. Subsequent evolution of DDRP and RDRP involved accretion of distinct sets of additional domains. In the DDRPs, these included a RNA-binding Zn-ribbon, an AT-hook-like module and a sandwich-barrel hybrid motif (SBHM) domain. Further, lineage-specific accretion of SBHM domains and other, DDRP-specific domains is observed in bacterial DDRPs. In contrast, the orthologs of the beta' subunit in archaea and eukaryotes contains a four-stranded alpha + beta domain that is shared with the alpha-subunit of bacterial DDRP, eukaryotic DDRP subunit RBP11, translation factor eIF1 and type II topoisomerases. The additional domains of the RDRPs remain to be characterized., Conclusions: Eukaryotic RNA-dependent RNA polymerases share the catalytic double-psi beta-barrel domain, containing a signature metal-coordinating motif, with the universally conserved beta' subunit of DNA-dependent RNA polymerases. Beyond this core catalytic domain, the two classes of RNA polymerases do not have common domains, suggesting early divergence from a common ancestor, with subsequent independent domain accretion. The beta-subunit of DDRP contains another, highly diverged DPBB domain. The presence of two distinct DPBB domains in two subunits of DDRP is compatible with the hypothesis that the ith the hypothesis that the ultimate ancestor of RNA polymerases was a RNA-binding DPBB domain that had no catalytic activity but rather functioned as a homodimeric cofactor for a ribozyme polymerase.

Published

2003

11. The role of lineage-specific gene family expansion in the evolution of eukaryotes.

Author

Lespinet O, Wolf YI, Koonin EV, and Aravind L

Subjects

Animals, Arabidopsis genetics, Caenorhabditis elegans genetics, Cell Lineage genetics, Cell Lineage physiology, Computational Biology, Drosophila melanogaster genetics, Eukaryotic Cells chemistry, Eukaryotic Cells metabolism, Genes, Helminth genetics, Genes, Helminth physiology, Genes, Insect genetics, Genes, Insect physiology, Genome, Fungal, Genome, Plant, Multigene Family physiology, Phylogeny, Saccharomyces cerevisiae genetics, Schizosaccharomyces genetics, Species Specificity, Eukaryotic Cells physiology, Evolution, Molecular, Gene Duplication, Multigene Family genetics

Abstract

A computational procedure was developed for systematic detection of lineage-specific expansions (LSEs) of protein families in sequenced genomes and applied to obtain a census of LSEs in five eukaryotic species, the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe, the nematode Caenorhabditis elegans, the fruit fly Drosophila melanogaster, and the green plant Arabidopsis thaliana. A significant fraction of the proteins encoded in each of these genomes, up to 80% in A. thaliana, belong to LSEs. Many paralogous gene families in each of the analyzed species are almost entirely comprised of LSEs, indicating that their diversification occurred after the divergence of the major lineages of the eukaryotic crown group. The LSEs show readily discernible patterns of protein functions. The functional categories most prone to LSE are structural proteins, enzymes involved in an organism's response to pathogens and environmental stress, and various components of signaling pathways responsible for specificity, including ubiquitin ligase E3 subunits and transcription factors. The functions of several previously uncharacterized, vastly expanded protein families were predicted through in-depth protein sequence analysis, for example, small-molecule kinases and methylases that are expanded independently in the fly and in the nematode. The functions of several other major LSEs remain mysterious; these protein families are attractive targets for experimental discovery of novel, lineage-specific functions in eukaryotes. LSEs seem to be one of the principal means of adaptation and one of the most important sources of organizational and regulatory diversity in crown-group eukaryotes.

Published

2002

12. Origin and evolution of eukaryotic apoptosis: the bacterial connection.

Author

Koonin EV and Aravind L

Subjects

Animals, Apoptosis Inducing Factor, Bacteria growth & development, Biological Evolution, Caspases genetics, Caspases physiology, Eukaryotic Cells cytology, Flavoproteins physiology, Membrane Proteins physiology, Mitochondria genetics, Mitochondria physiology, Models, Genetic, Phylogeny, Sequence Homology, Serine Endopeptidases genetics, Signal Transduction, Apoptosis genetics, Bacteria genetics, Eukaryotic Cells physiology, Heat-Shock Proteins, Periplasmic Proteins

Abstract

The availability of numerous complete genome sequences of prokaryotes and several eukaryotic genome sequences provides for new insights into the origin of unique functional systems of the eukaryotes. Several key enzymes of the apoptotic machinery, including the paracaspase and metacaspase families of the caspase-like protease superfamily, apoptotic ATPases and NACHT family NTPases, and mitochondrial HtrA-like proteases, have diverse homologs in bacteria, but not in archaea. Phylogenetic analysis strongly suggests a mitochondrial origin for metacaspases and the HtrA-like proteases, whereas acquisition from Actinomycetes appears to be the most likely scenario for AP-ATPases. The homologs of apoptotic proteins are particularly abundant and diverse in bacteria that undergo complex development, such as Actinomycetes, Cyanobacteria and alpha-proteobacteria, the latter being progenitors of the mitochondria. In these bacteria, the apoptosis-related domains typically form multidomain proteins, which are known or inferred to participate in signal transduction and regulation of gene expression. Some of these bacterial multidomain proteins contain fusions between apoptosis-related domains, such as AP-ATPase fused with a metacaspase or a TIR domain. Thus, bacterial homologs of eukaryotic apoptotic machinery components might functionally and physically interact with each other as parts of signaling pathways that remain to be investigated. An emerging scenario of the origin of the eukaryotic apoptotic system involves acquisition of several central apoptotic effectors as a consequence of mitochondrial endosymbiosis and probably also as a result of subsequent, additional horizontal gene transfer events, which was followed by recruitment of newly emerging eukaryotic domains as adaptors.

Published

2002

13. Eukaryote-specific domains in translation initiation factors: implications for translation regulation and evolution of the translation system.

Author

Aravind L and Koonin EV

Subjects

Adaptor Proteins, Signal Transducing, Amino Acid Sequence, Animals, Conserved Sequence, Databases, Factual, Fungal Proteins chemistry, Fungal Proteins genetics, Humans, Molecular Sequence Data, Peptide Initiation Factors genetics, Phylogeny, Protein Structure, Tertiary, Trans-Activators chemistry, Trans-Activators genetics, Eukaryotic Cells chemistry, Eukaryotic Cells physiology, Evolution, Molecular, Peptide Initiation Factors chemistry, Protein Biosynthesis, Saccharomyces cerevisiae Proteins

Abstract

Computational analysis of sequences of proteins involved in translation initiation in eukaryotes reveals a number of specific domains that are not represented in bacteria or archaea. Most of these eukaryote-specific domains are known or predicted to possess an alpha-helical structure, which suggests that such domains are easier to invent in the course of evolution than are domains of other structural classes. A previously undetected, conserved region predicted to form an alpha-helical domain is delineated in the initiation factor eIF4G, in Nonsense-mediated mRNA decay 2 protein (NMD2/UPF2), in the nuclear cap-binding CBP80, and in other, poorly characterized proteins, which is named the NIC (NMD2, eIF4G, CBP80) domain. Biochemical and mutagenesis data on NIC-containing proteins indicate that this predicted domain is one of the central adapters in the regulation of mRNA processing, translation, and degradation. It is demonstrated that, in the course of eukaryotic evolution, initiation factor eIF4G, of which NIC is the core, conserved portion, has accreted several additional, distinct predicted domains such as MI (MA-3 and eIF4G ) and W2, which probably was accompanied by acquisition of new regulatory interactions.

Published

2000

14. Origin of multicellular eukaryotes - insights from proteome comparisons.

Author

Aravind L and Subramanian G

Subjects

Animals, Arabidopsis chemistry, Caenorhabditis elegans chemistry, Cell Differentiation, Proteins chemistry, Proteins metabolism, Saccharomyces cerevisiae chemistry, Eukaryotic Cells cytology, Eukaryotic Cells metabolism, Evolution, Molecular, Phylogeny, Proteome

Abstract

The complete genomes of the yeast Saccharomyces cerevisiae and the nematode worm Caenorhabditis elegans have recently become available allowing the comparison of the complete protein sets of a unicellular and multicellular eukaryote for the first time. These comparisons reveal some striking trends in terms of expansions or extensive shuffling of specific domains that are involved in regulatory functions and signaling. Similar comparisons with the available sequence data from the plant Arabidopsis thaliana produce consistent results. These observations have provided useful insights regarding the origin of multicellular organisms.

Published

1999

15. G-patch: a new conserved domain in eukaryotic RNA-processing proteins and type D retroviral polyproteins.

Author

Aravind L and Koonin EV

Subjects

Amino Acid Sequence, Conserved Sequence, Glycine chemistry, Molecular Sequence Data, RNA Processing, Post-Transcriptional, RNA Splicing Factors, RNA-Binding Proteins metabolism, Ribonucleoproteins metabolism, Sequence Homology, Amino Acid, Spliceosomes metabolism, Eukaryotic Cells physiology, RNA-Binding Proteins chemistry, Retroviridae chemistry, Ribonucleoproteins chemistry, Spliceosomes chemistry, Viral Proteins chemistry

Published

1999

16. Novel families of putative protein kinases in bacteria and archaea: evolution of the "eukaryotic" protein kinase superfamily.

Author

Leonard CJ, Aravind L, and Koonin EV

Subjects

Amino Acid Sequence, Animals, Archaea genetics, Bacteria genetics, Conserved Sequence, Humans, Molecular Sequence Data, Multigene Family, Phylogeny, Protein Kinases chemistry, Protein Kinases genetics, Protein Serine-Threonine Kinases chemistry, Protein Serine-Threonine Kinases genetics, Protein Serine-Threonine Kinases physiology, Protein-Tyrosine Kinases chemistry, Protein-Tyrosine Kinases genetics, Protein-Tyrosine Kinases physiology, Archaea enzymology, Bacteria enzymology, Eukaryotic Cells enzymology, Evolution, Molecular, Protein Kinases physiology

Abstract

The central role of serine/threonine and tyrosine protein kinases in signal transduction and cellular regulation in eukaryotes is well established and widely documented. Considerably less is known about the prevalence and role of these protein kinases in bacteria and archaea. In order to examine the evolutionary origins of the eukaryotic-type protein kinase (ePK) superfamily, we conducted an extensive analysis of the proteins encoded by the completely sequenced bacterial and archaeal genomes. We detected five distinct families of known and predicted putative protein kinases with representatives in bacteria and archaea that share a common ancestry with the eukaryotic protein kinases. Four of these protein families have not been identified previously as protein kinases. From the phylogenetic distribution of these families, we infer the existence of an ancestral protein kinase(s) prior to the divergence of eukaryotes, bacteria, and archaea.

Published

1998

17. Lineage-Specific Loss and Divergence of Functionally Linked Genes in Eukaryotes

Author

Aravind, L., Watanabe, Hidemi, Lipman, David J., and Koonin, Eugene V.

Published

2000

18. Molecular Cloning, Expression, and Structural Prediction of Deoxyhypusine Hydroxylase: A HEAT-Repeat-Containing Metalloenzyme

Author

Park, Jong-Hwan, Aravind, L., Wolff, Edith C., Kaevel, Jörn, Kim, Yeon Sook, and Park, Myung Hee

Published

2006

19. The eukaryotic translation initiation regulator CDC123 defines a divergent clade of ATP-grasp enzymes with a predicted role in novel protein modifications.

Author

Maxwell Burroughs, A., Zhang, Dapeng, and Aravind, L.

Subjects

EUKARYOTIC cells, EUKARYOTIC genomes, RADIOENZYMATIC assays, BIOCATALYSIS, ENZYMES

Abstract

Deciphering the origin of uniquely eukaryotic features of sub-cellular systems, such as the translation apparatus, is critical in reconstructing eukaryogenesis. One such feature is the highly conserved, but poorly understood, eukaryotic protein CDC123, which regulates the abundance of the eukaryotic translation initiation eIF2 complex and binds one of its components eIF2γ. We show that the eukaryotic protein CDC123 defines a novel clade of ATP-grasp enzymes distinguished from all other members of the superfamily by a RAGNYA domain with two conserved lysines (henceforth the R2K clade). Combining the available biochemical and genetic data on CDC123 with the inferred enzymatic function, we propose that the eukaryotic CDC123 proteins are likely to function as ATP-dependent protein-peptide ligases which modify proteins by ribosome-independent addition of an oligopeptide tag. We also show that the CDC123 family emerged first in bacteria where it appears to have diversified along with the two other families of the R2K clade. The bacterial CDC123 family members are of two distinct types, one found as part of type VI secretion systems which deliver polymorphic toxins and the other functioning as potential effectors delivered to amoeboid eukaryotic hosts. Representatives of the latter type have also been independently transferred to phylogenetically unrelated amoeboid eukaryotes and their nucleo-cytoplasmic large DNA viruses. Similarly, the two other prokaryotic R2K clade families are also proposed to participate in biological conflicts between bacteriophages and their hosts. These findings add further evidence to the recently proposed hypothesis that the horizontal transfer of enzymatic effectors from the bacterial endosymbionts of the stem eukaryotes played a fundamental role in the emergence of the characteristically eukaryotic regulatory systems and sub-cellular structures. Reviewers: This article was reviewed by Michael Galperin and Sandor Pongor. [ABSTRACT FROM AUTHOR]

Published

2015

20. Evolutionary connection between the catalytic subunits of DNA-dependent RNA polymerases and eukaryotic RNA-dependent RNA polymerases and the origin of RNA polymerases

Author

Aravind L, Koonin Eugene V, and Iyer Lakshminarayan M

Subjects

Models, Molecular, Binding Sites, Bacteria, Molecular Sequence Data, DNA-Directed RNA Polymerases, RNA-Dependent RNA Polymerase, Protein Structure, Tertiary, Evolution, Molecular, Protein Subunits, Eukaryotic Cells, lcsh:Biology (General), Catalytic Domain, Bacteriophages, Amino Acid Sequence, lcsh:QH301-705.5, Sequence Alignment, Conserved Sequence, Research Article

Abstract

Background The eukaryotic RNA-dependent RNA polymerase (RDRP) is involved in the amplification of regulatory microRNAs during post-transcriptional gene silencing. This enzyme is highly conserved in most eukaryotes but is missing in archaea and bacteria. No evolutionary relationship between RDRP and other polymerases has been reported so far, hence the origin of this eukaryote-specific polymerase remains a mystery. Results Using extensive sequence profile searches, we identified bacteriophage homologs of the eukaryotic RDRP. The comparison of the eukaryotic RDRP and their homologs from bacteriophages led to the delineation of the conserved portion of these enzymes, which is predicted to harbor the catalytic site. Further, detailed sequence comparison, aided by examination of the crystal structure of the DNA-dependent RNA polymerase (DDRP), showed that the RDRP and the β' subunit of DDRP (and its orthologs in archaea and eukaryotes) contain a conserved double-psi β-barrel (DPBB) domain. This DPBB domain contains the signature motif DbDGD (b is a bulky residue), which is conserved in all RDRPs and DDRPs and contributes to catalysis via a coordinated divalent cation. Apart from the DPBB domain, no similarity was detected between RDRP and DDRP, which leaves open two scenarios for the origin of RDRP: i) RDRP evolved at the onset of the evolution of eukaryotes via a duplication of the DDRP β' subunit followed by dramatic divergence that obliterated the sequence similarity outside the core catalytic domain and ii) the primordial RDRP, which consisted primarily of the DPBB domain, evolved from a common ancestor with the DDRP at a very early stage of evolution, during the RNA world era. The latter hypothesis implies that RDRP had been subsequently eliminated from cellular life forms and might have been reintroduced into the eukaryotic genomes through a bacteriophage. Sequence and structure analysis of the DDRP led to further insights into the evolution of RNA polymerases. In addition to the β' subunit, β subunit of DDRP also contains a DPBB domain, which is, however, distorted by large inserts and does not harbor a counterpart of the DbDGD motif. The DPBB domains of the two DDRP subunits together form the catalytic cleft, with the domain from the β' subunit supplying the metal-coordinating DbDGD motif and the one from the β subunit providing two lysine residues involved in catalysis. Given that the two DPBB domains of DDRP contribute completely different sets of active residues to the catalytic center, it is hypothesized that the ultimate ancestor of RNA polymerases functioned as a homodimer of a generic, RNA-binding DPBB domain. This ancestral protein probably did not have catalytic activity and served as a cofactor for a ribozyme RNA polymerase. Subsequent evolution of DDRP and RDRP involved accretion of distinct sets of additional domains. In the DDRPs, these included a RNA-binding Zn-ribbon, an AT-hook-like module and a sandwich-barrel hybrid motif (SBHM) domain. Further, lineage-specific accretion of SBHM domains and other, DDRP-specific domains is observed in bacterial DDRPs. In contrast, the orthologs of the β' subunit in archaea and eukaryotes contains a four-stranded α + β domain that is shared with the α-subunit of bacterial DDRP, eukaryotic DDRP subunit RBP11, translation factor eIF1 and type II topoisomerases. The additional domains of the RDRPs remain to be characterized. Conclusions Eukaryotic RNA-dependent RNA polymerases share the catalytic double-psi β-barrel domain, containing a signature metal-coordinating motif, with the universally conserved β' subunit of DNA-dependent RNA polymerases. Beyond this core catalytic domain, the two classes of RNA polymerases do not have common domains, suggesting early divergence from a common ancestor, with subsequent independent domain accretion. The β-subunit of DDRP contains another, highly diverged DPBB domain. The presence of two distinct DPBB domains in two subunits of DDRP is compatible with the hypothesis that the ultimate ancestor of RNA polymerases was a RNA-binding DPBB domain that had no catalytic activity but rather functioned as a homodimeric cofactor for a ribozyme polymerase.

Published

2003

21. CYSTM, a novel cysteine-rich transmembrane module with a role in stress tolerance across eukaryotes.

Author

Venancio, Thiago M. and Aravind, L.

Subjects

*NUCLEOTIDE sequence, *CYSTEINE proteinases, *MEMBRANE proteins, *EUKARYOTIC cells, *SACCHAROMYCES, *SCHIZOSACCHAROMYCES

Abstract

Using sensitive sequence profile analysis, we identify a hitherto uncharacterized cysteine-rich, transmembrane (TM) module, CYSTM, found in a wide range of tail-anchored membrane proteins across eukaryotes. This superfamily includes Schizosaccharomyces Uvi15, Arabidopsis PCC1, Digtaria CDT1 and Saccharomyces proteins YDL012C and YDR210W, which have all been implicated in resistance/response to stress or pathogens. Based on the pattern of conserved cysteines and data from different chemical genetics studies, we suggest that CYSTM proteins might have critical role in responding to deleterious compounds at the plasma membrane via chelation or redox-based mechanisms. Thus, CYSTM proteins are likely to be part of a novel cellular protective mechanism that is widely active in eukaryotes, including humans. [ABSTRACT FROM PUBLISHER]

Published

2010

22. OST-HTH: a novel predicted RNA-binding domain.

Author

Anantharaman, Vivek, Dapeng Zhang, and Aravind, L.

Subjects

RNA, CARRIER proteins, NUCLEOPROTEINS, EUKARYOTIC cells, BACTERIA

Abstract

Background: The mechanism by which the arthropod Oskar and vertebrate TDRD5/TDRD7 proteins nucleate or organize structurally related ribonucleoprotein (RNP) complexes, the polar granule and nuage, is poorly understood. Using sequence profile searches we identify a novel domain in these proteins that is widely conserved across eukaryotes and bacteria. Results: Using contextual information from domain architectures, sequence-structure superpositions and available functional information we predict that this domain is likely to adopt the winged helix-turn-helix fold and bind RNA with a potential specificity for dsRNA. We show that in eukaryotes this domain is often combined in the same polypeptide with protein-protein- or lipid- interaction domains that might play a role in anchoring these proteins to specific cytoskeletal structures. Conclusions: Thus, proteins with this domain might have a key role in the recognition and localization of dsRNA, including miRNAs, rasiRNAs and piRNAs hybridized to their targets. In other cases, this domain is fused to ubiquitin-binding, E3 ligase and ubiquitin-like domains indicating a previously under-appreciated role for ubiquitination in regulating the assembly and stability of nuage-like RNP complexes. Both bacteria and eukaryotes encode a conserved family of proteins that combines this predicted RNA-binding domain with a previously uncharacterized domain (DUF88). We present evidence that it is an RNAse belonging to the superfamily that includes the 5'->3' nucleases, PIN and NYN domains and might be recruited to degrade certain RNAs. Reviewers: This article was reviewed by Sandor Pongor and Arcady Mushegian. [ABSTRACT FROM AUTHOR]

Published

2010

23. HORIZONTAL GENE TRANSFER IN PROKARYOTES: Quantification and Classification.

Author

Koonin, Eugene V., Makarova, Kira S., and Aravind, L.

Subjects

GENETIC transformation, PROKARYOTES, EUKARYOTIC cells, GENETICS

Abstract

Comparative analysis of bacterial, archaeal, and eukaryotic genomes indicates that a significant fraction of the genes in the prokaryotic genomes have been subject to horizontal transfer. In some cases, the amount and source of horizontal gene transfer can be linked to an organism's lifestyle. For example, bacterial hyperthermophiles seem to have exchanged genes with archaea to a greater extent than other bacteria, whereas transfer of certain classes of eukaryotic genes is most common in parasitic and symbiotic bacteria. Horizontal transfer events can be classified into distinct categories of acquisition of new genes, acquisition of paralogs of existing genes, and xenologous gene displacement whereby a gene is displaced by a horizontally transferred ortholog from another lineage (xenolog). Each of these types of horizontal gene transfer is common among prokaryotes, but their relative contributions differ in different lineages. The fixation and long-term persistence of horizontally transferred genes suggests that they confer a selective advantage on the recipient organism. In most cases, the nature of this advantage remains unclear, but detailed examination of several cases of acquisition of eukaryotic genes by bacteria seems to reveal the evolutionary forces involved. Examples include isoleucyl-tRNA synthetases whose acquisition from eukaryotes by several bacteria is linked to antibiotic resistance, ATP/ADP translocases acquired by intracellular parasitic bacteria, Chlamydia and Rickettsia, apparently from plants, and proteases that may be implicated in chlamydial pathogenesis. [ABSTRACT FROM AUTHOR]

Published

2001

24. Comparative genomics of the Archaea (Euryarchaeota): evolution of conserved protein families, the stable core, and the variable shell

Author

Ks, Makarova, Aravind L, Michael Galperin, Nv, Grishin, Rl, Tatusov, Yi, Wolf, and Ev, Koonin

Subjects

Evolution, Molecular, Eukaryotic Cells, Genome, Bacterial Proteins, Sequence Homology, Amino Acid, Archaeal Proteins, Genetic Variation, Amino Acid Sequence, Euryarchaeota, Sequence Alignment, Conserved Sequence, Phylogeny, Genes, Archaeal

Abstract

Comparative analysis of the protein sequences encoded in the four euryarchaeal species whose genomes have been sequenced completely (Methanococcus jannaschii, Methanobacterium thermoautotrophicum, Archaeoglobus fulgidus, and Pyrococcus horikoshii) revealed 1326 orthologous sets, of which 543 are represented in all four species. The proteins that belong to these conserved euryarchaeal families comprise 31%-35% of the gene complement and may be considered the evolutionarily stable core of the archaeal genomes. The core gene set includes the great majority of genes coding for proteins involved in genome replication and expression, but only a relatively small subset of metabolic functions. For many gene families that are conserved in all euryarchaea, previously undetected orthologs in bacteria and eukaryotes were identified. A number of euryarchaeal synapomorphies (unique shared characters) were identified; these are protein families that possess sequence signatures or domain architectures that are conserved in all euryarchaea but are not found in bacteria or eukaryotes. In addition, euryarchaea-specific expansions of several protein and domain families were detected. In terms of their apparent phylogenetic affinities, the archaeal protein families split into bacterial and eukaryotic families. The majority of the proteins that have only eukaryotic orthologs or show the greatest similarity to their eukaryotic counterparts belong to the core set. The families of euryarchaeal genes that are conserved in only two or three species constitute a relatively mobile component of the genomes whose evolution should have involved multiple events of lineage-specific gene loss and horizontal gene transfer. Frequently these proteins have detectable orthologs only in bacteria or show the greatest similarity to the bacterial homologs, which might suggest a significant role of horizontal gene transfer from bacteria in the evolution of the euryarchaeota.

25. The GOLD domain, a novel protein module involved in Golgi function and secretion

Author

Vivek Anantharaman and Aravind, L.

Subjects

Membrane Glycoproteins, Saccharomyces cerevisiae Proteins, Research, Vesicular Transport Proteins, Computational Biology, Golgi Apparatus, Membrane Proteins, Endoplasmic Reticulum, Protein Structure, Tertiary, Evolution, Molecular, Protein Transport, Eukaryotic Cells, Amino Acid Sequence, Carrier Proteins, Databases, Protein, Conserved Sequence

Abstract

Background Members of the p24 (p24/gp25L/emp24/Erp) family of proteins have been shown to be critical components of the coated vesicles that are involved in the transportation of cargo molecules from the endoplasmic reticulum to the Golgi complex. The p24 proteins form hetero-oligomeric complexes and are believed to function as receptors for specific secretory cargo. Results Using sensitive sequence-profile analysis methods, we identified a novel β-strand-rich domain, the GOLD (Golgi dynamics) domain, in the p24 proteins and several other proteins with roles in Golgi dynamics and secretion. This domain is predicted to mediate diverse protein-protein interactions. Other than in the p24 proteins, the GOLD domain is always found combined with lipid- or membrane-association domains such as the pleckstrin homology (PH), Sec14p and FYVE domains. Conclusions The identification of the GOLD domain could aid in directed investigation of the role of the p24 proteins in the secretion process. The newly detected group of GOLD-domain proteins, which might simultaneously bind membranes and other proteins, point to the existence of a novel class of adaptors that could have a role in the assembly of membrane-associated complexes or in regulating assembly of cargo into membranous vesicles.

26. Comparative genomics, evolution and origins of the nuclear envelope and nuclear pore complex

Author

Ben Mans, Anantharaman, V., Aravind, L., and Koonin, E. V.

Subjects

Cytoplasm, Nuclear Envelope, Molecular Sequence Data, Protozoan Proteins, Receptors, Cytoplasmic and Nuclear, Evolution, Molecular, Lectins, Yeasts, Animals, Humans, Amino Acid Sequence, Molecular Biology, Membrane Proteins, Nuclear Proteins, Genomics, Cell Biology, Lamins, DNA-Binding Proteins, Nuclear Pore Complex Proteins, Eukaryotic Cells, Prokaryotic Cells, Nuclear Pore, Discoidins, Ribosomes, Sequence Alignment, Developmental Biology

Abstract

The presence of a distinct nucleus, the compartment for confining the genome, transcription and RNA maturation, is a central (and eponymous) feature that distinguishes eukaryotes from prokaryotes. Structural integrity of the nucleus is maintained by the nuclear envelope (NE). A crucial element of this structure is the nuclear pore complex (NPC), a macromolecular machine with over 90 protein components, which mediates nucleo-cytoplasmic communication. We investigated the provenance of the conserved domains found in these perinuclear proteins and reconstructed a parsimonious scenario for NE and NPC evolution by means of comparative-genomic analysis of their components from the available sequences of 28 sequenced eukaryotic genomes. We show that the NE and NPC proteins were tinkered together from diverse domains, which evolved from prokaryotic precursors at different points in eukaryotic evolution, divergence from pre-existing eukaryotic paralogs performing other functions, and de novo. It is shown that several central components of the NPC, in particular, the RanGDP import factor NTF2, the HEH domain of Src1p-Man1, and, probably, also the key domains of karyopherins and nucleoporins, the HEAT/ARM and WD40 repeats, have a bacterial, most likely, endosymbiotic origin. The specialized immunoglobulin (Ig) domain in the globular tail of the animal lamins, and the Ig domains in the nuclear membrane protein GP210 are shown to be related to distinct prokaryotic families of Ig domains. This suggests that independent, late horizontal gene transfer events from bacterial sources might have contributed to the evolution of perinuclear proteins in some of the major eukaryotic lineages. Snurportin 1, one of the highly conserved karyopherins, contains a cap-binding domain which is shown to be an inactive paralog of the guanylyl transferase domain of the mRNA-capping enzyme, exemplifying recruitment of paralogs of pre-exsiting proteins for perinuclear functions. It is shown that several NPC proteins containing super-structure- forming alpha-helical and beta-propeller modules are most closely related to corresponding proteins in the cytoplasmic vesicle biogenesis and coating complexes. From these observations, we infer an autogenous scenario of nuclear evolution in which the nucleus emerged in the primitive eukaryotic ancestor (the "prekaryote") as part of cell compartmentalization triggered by archaeo-bacterial symbiosis. A pivotal event in this process was the radiation of Ras-superfamily GTPases yielding Ran, the key regulator of nuclear transport. A primitive NPC with approximately 20 proteins and a Src1p-Man1-like membrane protein with a DNA-tethering HEH domain are inferred to have been integral perinuclear components in the las common ancestor of modern eukaryotes.

27. Structure-function analysis of manganese exporter proteins across bacteria.

Author

Zeinert, Rilee, Martinez, Eli, Schmitz, Jennifer, Senn, Katherine, Usman, Bakhtawar, Anantharaman, Vivek, Aravind, L., and Waters, Lauren S.

Subjects

*BACTERIAL proteins, *EXPORTERS, *EUKARYOTIC cells, *REACTIVE oxygen species, *AMINO acids, *MANGANESE, *SUPEROXIDE dismutase

Abstract

Manganese (Mn) is an essential trace nutrient for organisms because of its role in cofactoring enzymes and providing protection against reactive oxygen species (ROS). Many bacteria require manganese to form pathogenic or symbiotic interactions with eukaryotic host cells. However, excess manganese is toxic, requiring cells to have manganese export mechanisms. Bacteria are currently known to possess two widely distributed classes of manganese export proteins, MntP and MntE, but other types of transporters likely exist. Moreover, the structure and function of MntP is not well understood. Here, we characterized the role of three structurally related proteins known or predicted to be involved in manganese transport in bacteria from the MntP, UPF0016, and TerC families. These studies used computational analysis to analyze phylogeny and structure, physiological assays to test sensitivity to high levels of manganese and ROS, and inductively coupled plasma-mass spectrometry (ICP-MS) to measure metal levels. We found that MntP alters cellular resistance to ROS. Moreover, we used extensive computational analyses and phenotypic assays to identify amino acids required for MntP activity. These negatively charged residues likely serve to directly bind manganese and transport it from the cytoplasm through the membrane. We further characterized two other potential manganese transporters associated with a Mn-sensing riboswitch and found that the UPF0016 family of proteins has manganese export activity. We provide here the first phenotypic and biochemical evidence for the role of Alx, a member of the TerC family, in manganese homeostasis. It does not appear to export manganese, but rather it intriguingly facilitates an increase in intracellular manganese concentration. These findings expand the available knowledge about the identity and mechanisms of manganese homeostasis proteins across bacteria and show that proximity to a Mn-responsive riboswitch can be used to identify new components of the manganese homeostasis machinery. [ABSTRACT FROM AUTHOR]

Published

2018