Unique genome replication mechanism of the archaeal virus AFV1

The exceptional genomic content and genome organization of the Acidianus filamentous virus 1 (AFV1) that infects the hyperthermophilic archaeon Acidianus hospitalis suggest that this virus might exploit an unusual mechanism of genome replication. An analysis of replicative intermediates of the viral genome by two‐dimensional (2D) agarose gel electrophoresis revealed that viral genome replication starts by the formation of a D‐loop and proceeds via strand displacement replication. Characterization of replicative intermediates using dark‐field electron microscopy, in combination with the 2D agarose gel electrophoresis data, suggests that recombination plays a key role in the termination of AFV1 genome replication through the formation of terminal loops. A terminal protein was found to be attached to the ends of the viral genome. The results allow us to postulate a model of genome replication that relies on recombination events for initiation and termination.     

A protein encoded by a new family of mobile elements from Euryarchaea exhibits three domains with novel folds

We present here the 2.6Å resolution crystal structure of the pT26‐6p protein, which is encoded by an ORF of the plasmid pT26‐2, recently isolated from the hyperthermophilic archaeon, Thermococcus sp. 26,2. This large protein is present in all members of a new family of mobile elements that, beside pT26‐2 include several virus‐like elements integrated in the genomes of several Thermococcales and Methanococcales (phylum Euryarchaeota). Phylogenetic analysis suggested that this protein, together with its nearest neighbor (organized as an operon) have coevolved for a long time with the cellular hosts of the encoding mobile element. As the sequences of the N and C‐terminal regions suggested a possible membrane association, a deletion construct (739 amino acids) was used for structural analysis. The structure consists of two very similar β‐sheet domains with a new topology and a five helical bundle C‐terminal domain. Each of these domains corresponds to a unique fold that has presently not been found in cellular proteins. This result supports the idea that proteins encoded by plasmid and viruses that have no cellular homologues could be a reservoir of new folds for structural genomic studies.     

The thermo‐ and acido‐stable ORF‐99 from the archaeal virus AFV1

Acidianus Filamentous Virus 1 (AFV1), isolated from acidic hot springs, is an enveloped lipid‐containing archaeal filamentous virus with a linear double‐stranded DNA genome. It infects Acidianus, which is a hyperthermostable archaea growing at 85°C and acidic pHs, below pH 3. AFV1‐99, a protein of 99 amino acids of unknown function, has homologues in the archaeal virus families Lipothrixviridae and Rudiviridae. We determined the crystal structure of AFV1‐99 at 2.05 Å resolution. AFV1‐99 has a new fold, is hyperthermostable (up to 95°C) and resists to extreme pH (between pH 0 and 11) and to the combination of high temperature (95°C) and low pH (pH 0). It possesses characteristics of hyperthermostable proteins, such as a high content of charged residues.     

Modified coat protein forms the flexible spindle‐shaped virion of haloarchaeal virus His1

Extremophiles are found in all three domains of cellular life. However, hyperthermic and hypersaline environments are typically dominated by archaeal cells which also hold the records for the highest growth temperature and are able to grow even at saturated salinity. Hypersaline environments are rich of virus‐like particles, and spindle‐shaped virions resembling lemons are one of the most abundant virus morphotypes. Spindle‐shaped viruses are archaea‐specific as all the about 15 such virus isolates infect either hyperthermophilic or halophilic archaea. In the present work, we studied spindle‐shaped virus His1 infecting an extremely halophilic euryarchaeon, Haloarcula hispanica. We demonstrate that His1 tolerates a variety of salinities, even lower than that of seawater. The detailed analysis of the structural constituents showed that the His1 virion is composed of only one major and a few minor structural proteins. There is no lipid bilayer in the His1 virion but the major structural protein VP21 is most likely lipid modified. VP21 forms the virion capsid, and the lipid modification probably enables hydrophobic interactions leading to the flexible nature of the virion. Furthermore, we propose that euryarchaeal virus His1 may be related to crenarchaeal fuselloviruses, and that the short‐tailed spindle‐shaped viruses could form a structure‐based viral lineage.     

The first head-tailed virus,MFTV1, infecting hyperthermophilic methanogenic deep-sea archaea

Deep-sea hydrothermal vents are inhabited by complex communities of microbes and their viruses. Despite the importance of viruses in controlling the diversity, adaptation and evolution of their microbial hosts, to date, only eight bacterial and two archaeal viruses isolated from abyssal ecosystems have been described. Thus, our efforts focused on gaining new insights into viruses associated with deep-sea autotrophic archaea. Here, we provide the first evidence of an infection of hyperthermophilic methanogenic archaea by a head-tailed virus, Methanocaldococcus fervens tailed virus 1 (MFTV1). MFTV1 has an isometric head of 50 nm in diameter and a 150 nm-long non-contractile tail. Virions are released continuously without causing a sudden drop in host growth. MFTV1 infects Methanocaldococcus species and is the first hyperthermophilic head-tailed virus described thus far. The viral genome is a double-stranded linear DNA of 31 kb. Interestingly, our results suggest potential strategies adopted by the plasmid pMEFER01, carried by M. fervens, to spread horizontally in hyperthermophilic methanogens. The data presented here open a new window of understanding on how the abyssal mobilome interacts with hyperthermophilic marine archaea.     

Structure of human peptidyl‐prolyl cis–trans isomerase FKBP22 containing two EF‐hand motifs

The FK506‐binding protein (FKBP) family consists of proteins with a variety of protein–protein interaction domains and versatile cellular functions. It is assumed that all members are peptidyl‐prolyl cis–trans isomerases with the enzymatic function attributed to the FKBP domain. Six members of this family localize to the mammalian endoplasmic reticulum (ER). Four of them, FKBP22 (encoded by the FKBP14 gene), FKBP23 (FKBP7), FKBP60 (FKBP9), and FKBP65 (FKBP10), are unique among all FKBPs as they contain the EF‐hand motifs. Little is known about the biological roles of these proteins, but emerging genetics studies are attracting great interest to the ER resident FKBPs, as mutations in genes encoding FKBP10 and FKBP14 were shown to cause a variety of matrix disorders. Although the structural organization of the FKBP‐type domain as well as of the EF‐hand motif has been known for a while, it is difficult to conclude how these structures are combined and how it affects the protein functionality. We have determined a unique 1.9 Å resolution crystal structure for human FKBP22, which can serve as a prototype for other EF hand‐containing FKBPs. The EF‐hand motifs of two FKBP22 molecules form a dimeric complex with an elongated and predominantly hydrophobic cavity that can potentially be occupied by an aliphatic ligand. The FKBP‐type domains are separated by a cleft and their putative active sites can catalyze isomerazation of two bonds within a polypeptide chain in extended conformation. These structural results are of prime interest for understanding biological functions of ER resident FKBPs containing EF‐hand motifs.     

Beyond the Twilight Zone: Automated prediction of structural properties of proteins by recursive neural networks and remote homology information

The prediction of 1D structural properties of proteins is an important step toward the prediction of protein structure and function, not only in the ab initio case but also when homology information to known structures is available. Despite this the vast majority of 1D predictors do not incorporate homology information into the prediction process. We develop a novel structural alignment method, SAMD, which we use to build alignments of putative remote homologues that we compress into templates of structural frequency profiles. We use these templates as additional input to ensembles of recursive neural networks, which we specialise for the prediction of query sequences that show only remote homology to any Protein Data Bank structure. We predict four 1D structural properties – secondary structure, relative solvent accessibility, backbone structural motifs, and contact density. Secondary structure prediction accuracy, tested by five‐fold cross‐validation on a large set of proteins allowing less than 25% sequence identity between training and test set and query sequences and templates, exceeds 82%, outperforming its ab initio counterpart, other state‐of‐the‐art secondary structure predictors (Jpred 3 and PSIPRED) and two other systems based on PSI‐BLAST and COMPASS templates. We show that structural information from homologues improves prediction accuracy well beyond the Twilight Zone of sequence similarity, even below 5% sequence identity, for all four structural properties. Significant improvement over the extraction of structural information directly from PDB templates suggests that the combination of sequence and template information is more informative than templates alone. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

1H, 13C, 15N backbone and side chain NMR resonance assignments for E73 from Sulfolobus spindle-shaped virus ragged hills, a hyperthermophilic crenarchaeal virus from Yellowstone National Park

Crenarchaeal viruses are commonly found in hyperthermal acidic environments such as those of Yellowstone National Park. These remarkable viruses not only exhibit unusual morphologies, but also display extreme genetic diversity. However, little is known about crenarchaeal viral life cycles, virus–host interactions, and their adaptation to hyperthermophilic environments. In an effort to better understand the functions of crenarchaeal viruses and the proteins encoded by their genomes, we have undertaken detailed structural and functional studies of gene products encoded in the open reading frames of Sulfolobus spindle-shaped virus ragged hills. Herein, we report (¹⁵N, ¹³C, ¹H) resonance assignments of backbone and side chain atoms of a 19.1 kDa homodimeric E73 protein of SSVRH.     

Different effects of the TAR structure on HIV-1 and HIV-2 genomic RNA translation

The 5'-untranslated region (5'-UTR) of the genomic RNA of human immunodeficiency viruses type-1 (HIV-1) and type-2 (HIV-2) is composed of highly structured RNA motifs essential for viral replication that are expected to interfere with Gag and Gag-Pol translation. Here, we have analyzed and compared the properties by which the viral 5'-UTR drives translation from the genomic RNA of both human immunodeficiency viruses. Our results showed that translation from the HIV-2 gRNA was very poor compared to that of HIV-1. This was rather due to the intrinsic structural motifs in their respective 5'-UTR without involvement of any viral protein. Further investigation pointed to a different role of TAR RNA, which was much inhibitory for HIV-2 translation. Altogether, these data highlight important structural and functional differences between these two human pathogens.     

Efficient ER Exit and Vacuole Targeting of Yeast Sna2p Require Two Tyrosine‐Based Sorting Motifs

SNA (Sensitive to Na⁺) proteins form a membrane protein family, which, in the yeast Saccharomyces cerevisiae, is composed of four members: Sna1p/Pmp3p, Sna2p, Sna3p and Sna4p. In this study, we focused on the 79 residue Sna2p protein. We found that Sna2p is localized in the vacuolar membrane. Directed mutagenesis showed that two functional tyrosine motifs YXXØ are present in the C‐terminal region. Each of these is involved in a different Golgi‐to‐vacuole targeting pathway: the tyrosine 65 motif is involved in adaptor protein (AP‐1)‐dependent targeting, whereas the tyrosine 75 motif is involved in AP‐3‐dependent targeting. Moreover, our data suggest that these motifs also play a crucial role in the exit of Sna2p from the endoplasmic reticulum (ER). Directed mutagenesis of these tyrosines led to a partial redirection of Sna2p to lipid bodies, probably because of a decrease in ER exit efficiency. Sna2p is the first yeast protein in which two YXXØ motifs have been identified and both were shown to be functional at two different steps of the secretory pathway, ER exit and Golgi‐to‐vacuole transport.     

Crystallographic and mutational studies on the tRNA thiouridine synthetase TtuA

In thermophilic bacteria, specific 2‐thiolation occurs on the conserved ribothymidine at position 54 (T54) in tRNAs, which is necessary for survival at high temperatures. T54 2‐thiolation is achieved by the tRNA thiouridine synthetase TtuA and sulfur‐carrier proteins. TtuA has five conserved CXXC/H motifs and the signature PP motif, and belongs to the TtcA family of tRNA 2‐thiolation enzymes, for which there is currently no structural information. In this study, we determined the crystal structure of a TtuA homolog from the hyperthermophilic archeon Pyrococcus horikoshii at 2.1 Å resolution. The P. horikoshii TtuA forms a homodimer, and each subunit contains a catalytic domain and unique N‐ and C‐terminal zinc fingers. The catalytic domain has much higher structural similarity to that of another tRNA modification enzyme, TilS (tRNA^Ile₂ lysidine synthetase), than to the other type of tRNA 2‐thiolation enzyme, MnmA. Three conserved cysteine residues are clustered in the putative catalytic site, which is not present in TilS. An in vivo mutational analysis in the bacterium Thermus thermophilus demonstrated that the three conserved cysteine residues and the putative ATP‐binding residues in the catalytic domain are important for the TtuA activity. A positively charged surface that includes the catalytic site and the two zinc fingers is likely to provide the tRNA‐binding site. Proteins 2013; 81:1232–1244. © 2013 Wiley Periodicals, Inc.     

Characterization of Spetex‐1, a new component of satellite fibrils associated with outer dense fibers in the middle piece of rodent sperm flagella

Spetex‐1, which has been isolated by differential display as a haploid spermatid‐specific gene, encodes a protein with two coiled‐coil motifs located in the middle piece of flagella in rodent spermatozoa. The middle piece of flagella is composed of axoneme and peri‐axonemal elements including outer dense fibers (ODFs) and satellite fibrils. Pre‐embedding immunoelectron microscopy clearly demonstrated that Spetex‐1 is located at satellite fibrils associated with ODFs in the middle piece of flagella of rat spermatozoa. Extraction of Spetex‐1 from spermatozoa by SDS or urea required dithiothreitol, suggesting crosslinking by disulfide bond is involved in the assembly of satellite fibrils containing Spetex‐1. We identified putative Spetex‐1 orthologs in many animal species, and both cysteine residues and coiled‐coil motifs were well conserved in mammalian orthologs of Spetex‐1. When Spetex‐1 was co‐transfected into COS‐7 cells with myc‐tagged Tektin4, another filamentous protein associated with ODFs, the two molecules were co‐localized in various sizes of aggregates in the cells. These data suggested that Spetex‐1, a new component of satellite fibrils, might be involved in the structural stability of the sperm flagellar middle piece and functions in co‐operation with Tektin4. Mol. Reprod. Dev. 77: 363–372, 2010. © 2010 Wiley‐Liss, Inc.     

The Fugu tyrp1 promoter directs specific GFP expression in zebrafish: tools to study the RPE and the neural crest‐derived melanophores

In vertebrates, pigment cells account for a small percentage of the total cell population and they intermingle with other cell types. This makes it difficult to isolate them for analyzes of their functions in the context of development. To alleviate such difficulty, we generated two stable transgenic zebrafish lines (pt101 and pt102) that express green fluorescent protein (GFP) in melanophores under the control of the 1 kb Fugu tyrp1 promoter. In pt101, GFP is expressed in both retinal pigment epithelium (RPE) cells and the neural crest‐derived melanophores (NCDM), whereas in pt102, GFP is predominately expressed in the NCDM. Our results indicate that the Fugu tyrp1 promoter can direct transgene expression in a cell‐type‐specific manner in zebrafish. In addition, our findings provide evidence supporting differential regulations of melanin‐synthesizing genes in RPE cells and the NCDM in zebrafish. Utilizing the varying GFP expression levels in these fish, we have isolated melanophores via flow cytometry and revealed the capability of sorting the NCDM from RPE cells as well. Thus, these transgenic lines are useful tools to study melanophores in zebrafish.     

A TUBULAR MASTIGONEME‐RELATED PROTEIN,OCM1, ISOLATED FROM THE FLAGELLUM OF A CHROMOPHYTE ALGA,OCHROMONAS DANICA1

The phylogenetic group stramenopiles refers to the systematic groups that possess tripartite tubular hairs (stramenopiles) on their flagella. There have been a number of studies describing the fine structure of these mastigonemes and a few studies isolating the component proteins; however, these proteins and their gene sequences have not yet been identified. In the present study, we identified a mastigoneme protein (Ocm1) of the chrysophycean alga Ochromonas danica Pringsh. (UTEX LB1298). Its corresponding gene, Ocm1, was identified by using degenerate primers that correspond to the partial amino acid sequences of a protein (85 kDa) obtained from a mastigoneme‐rich fraction of isolated flagella. The polypeptide encoded by Ocm1 has four cysteine‐rich, epithelial growth factor (EGF)–like motifs, potentially involved in protein–protein interactions. It lacks obvious hydrophobic regions characteristic of transmembrane domains, suggesting that this polypeptide is not likely a protein for anchoring the mastigoneme. In addition, a polyclonal antibody against Ocm1 labeled the area where the tubular shafts of the mastigonemes are located, but not the basal portion or the terminal filaments.     

Structure and evolution of ENTH and VHS/ENTH‐like domains in tepsin

Tepsin is currently the only accessory trafficking protein identified in adaptor‐related protein 4 (AP4)‐coated vesicles originating at the trans‐Golgi network (TGN). The molecular basis for interactions between AP4 subunits and motifs in the tepsin C‐terminus have been characterized, but the biological role of tepsin remains unknown. We determined X‐ray crystal structures of the tepsin epsin N‐terminal homology (ENTH) and VHS/ENTH‐like domains. Our data reveal unexpected structural features that suggest key functional differences between these and similar domains in other trafficking proteins. The tepsin ENTH domain lacks helix0, helix8 and a lipid binding pocket found in epsin1/2/3. These results explain why tepsin requires AP4 for its membrane recruitment and further suggest ENTH domains cannot be defined solely as lipid binding modules. The VHS domain lacks helix8 and thus contains fewer helices than other VHS domains. Structural data explain biochemical and biophysical evidence that tepsin VHS does not mediate known VHS functions, including recognition of dileucine‐based cargo motifs or ubiquitin. Structural comparisons indicate the domains are very similar to each other, and phylogenetic analysis reveals their evolutionary pattern within the domain superfamily. Phylogenetics and comparative genomics further show tepsin within a monophyletic clade that diverged away from epsins early in evolutionary history (~1500 million years ago). Together, these data provide the first detailed molecular view of tepsin and suggest tepsin structure and function diverged away from other epsins. More broadly, these data highlight the challenges inherent in classifying and understanding protein function based only on sequence and structure.      

First structural evidence of sequestration of mRNA cap structures by type 1 ribosome inactivating protein from Momordica balsamina

This is the first structural evidence of recognition of mRNA cap structures by a ribosome inactivating protein. It is well known that a unique cap structure is formed at the 5′ end of mRNA for carrying out various processes including mRNA maturation, translation initiation, and RNA turnover. The binding studies and crystal structure determinations of type 1 ribosome inactivating protein (RIP‐1) from Momordica balsamina (MbRIP‐1) were carried out with mRNA cap structures including (i) N7‐methyl guanine (m7G), (ii) N7‐methyl guanosine diphosphate (m7GDP), and (iii) N7‐methyl guanosine triphosphate (m7GTP). These compounds showed affinities to MbRIP‐1 at nanomolar concentrations. The structure determinations of the complexes of MbRIP‐1 with m7G, m7GDP, and m7GTP at 2.65, 1.77, and 1.75 Å resolutions revealed that all the three compounds bound to MbRIP‐1 in the substrate binding site at the positions which are slightly shifted towards Glu85 as compared to those of rRNA substrates. In this position, Glu85 forms several hydrogen bonds with guanine moiety while N‐7 methyl group forms van der Waals contacts. However, the guanine rings are poorly stacked in these complexes. Thus, the mode of binding by MbRIP‐1 to mRNA cap structures is different which results in the inhibition of depurination. Since some viruses are known to exploit the capping property of the host, this action of MbRIP‐1 may have implications for the antiviral activity of this protein in vivo. The understanding of the mode of binding of MbRIP‐1 to cap structures may also assist in the design of anti‐viral agents. Proteins 2012. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Crystal structure of Methanococcus jannaschii dihydroorotase

In this paper, we report the structural analysis of dihydroorotase (DHOase) from the hyperthermophilic and barophilic archaeon Methanococcus jannaschii. DHOase catalyzes the reversible cyclization of N-carbamoyl-l -aspartate to l -dihydroorotate in the third step of de novo pyrimidine biosynthesis. DHOases form a very diverse family of enzymes and have been classified into types and subtypes with structural similarities and differences among them. This is the first archaeal DHOase studied by x-ray diffraction. Its structure and comparison with known representatives of the other subtypes help define the structural features of the archaeal subtype. The M. jannaschii DHOase is found here to have traits from all subtypes. Contrary to expectations, it has a carboxylated lysine bridging the two Zn ions in the active site, and a long catalytic loop. It is a monomeric protein with a large β sandwich domain adjacent to the TIM barrel. Loop 5 is similar to bacterial type III and the C-terminal extension is long.