Your search keyword '"Faculty of Biology, Technion"' showing total 25 results

1. Identification of Shemin pathway genes for tetrapyrrole biosynthesis in bacteriophage sequences from aquatic environments.

Author

Wegner H, Roitman S, Kupczok A, Braun V, Woodhouse JN, Grossart HP, Zehner S, Béjà O, and Frankenberg-Dinkel N

Subjects

Escherichia coli genetics, Escherichia coli virology, Escherichia coli metabolism, 5-Aminolevulinate Synthetase genetics, 5-Aminolevulinate Synthetase metabolism, Amino Acid Sequence, Heme metabolism, Heme biosynthesis, Aminolevulinic Acid metabolism, Phylogeny, Fresh Water virology, Biosynthetic Pathways genetics, Tetrapyrroles biosynthesis, Tetrapyrroles metabolism, Bacteriophages genetics, Bacteriophages metabolism

Abstract

Tetrapyrroles such as heme, chlorophyll, and vitamin B 12 are essential for various metabolic pathways. They derive from 5-aminolevulinic acid (5-ALA), which can be synthesized by a single enzyme (5-ALA synthase or AlaS, Shemin pathway) or by a two-enzyme pathway. The genomes of some bacteriophages from aquatic environments carry various tetrapyrrole biosynthesis genes. Here, we analyze available metagenomic datasets and identify alaS homologs (viral alaS, or valaS) in sequences corresponding to marine and freshwater phages. The genes are found individually or as part of complete or truncated three-gene loci encoding heme-catabolizing enzymes. Amino-acid sequence alignments and three-dimensional structure prediction support that the valaS sequences likely encode functional enzymes. Indeed, we demonstrate that is the case for a freshwater phage valaS sequence, as it can complement an Escherichia coli 5-ALA auxotroph, and an E. coli strain overexpressing the gene converts the typical AlaS substrates glycine and succinyl-CoA into 5-ALA. Thus, our work identifies valaS as an auxiliary metabolic gene in phage sequences from aquatic environments, further supporting the importance of tetrapyrrole metabolism in bacteriophage biology., (© 2024. The Author(s).)

Published

2024

2. Multistep diversification in spatiotemporal bacterial-phage coevolution.

Author

Shaer Tamar E and Kishony R

Subjects

Escherichia coli genetics, Bacteriophage T7, Biological Evolution, Bacteria genetics, Bacteriophages genetics

Abstract

The evolutionary arms race between phages and bacteria, where bacteria evolve resistance to phages and phages retaliate with resistance-countering mutations, is a major driving force of molecular innovation and genetic diversification. Yet attempting to reproduce such ongoing retaliation dynamics in the lab has been challenging; laboratory coevolution experiments of phage and bacteria are typically performed in well-mixed environments and often lead to rapid stagnation with little genetic variability. Here, co-culturing motile E. coli with the lytic bacteriophage T7 on swimming plates, we observe complex spatiotemporal dynamics with multiple genetically diversifying adaptive cycles. Systematically quantifying over 10,000 resistance-infectivity phenotypes between evolved bacteria and phage isolates, we observe diversification into multiple coexisting ecotypes showing a complex interaction network with both host-range expansion and host-switch tradeoffs. Whole-genome sequencing of these evolved phage and bacterial isolates revealed a rich set of adaptive mutations in multiple genetic pathways including in genes not previously linked with phage-bacteria interactions. Synthetically reconstructing these new mutations, we discover phage-general and phage-specific resistance phenotypes as well as a strong synergy with the more classically known phage-resistance mutations. These results highlight the importance of spatial structure and migration for driving phage-bacteria coevolution, providing a concrete system for revealing new molecular mechanisms across diverse phage-bacterial systems., (© 2022. The Author(s).)

Published

2022

3. Cyanophages from a less virulent clade dominate over their sister clade in global oceans.

Author

Maidanik I, Kirzner S, Pekarski I, Arsenieff L, Tahan R, Carlson MCG, Shitrit D, Baran N, Goldin S, Weitz JS, and Lindell D

Subjects

Indian Ocean, Phylogeny, Seawater, Bacteriophages genetics, Prochlorococcus genetics, Synechococcus genetics

Abstract

Environmental virus communities are highly diverse. However, the infection physiology underlying the evolution of diverse phage lineages and their ecological consequences are largely unknown. T7-like cyanophages are abundant in nature and infect the marine unicellular cyanobacteria, Synechococcus and Prochlorococcus, important primary producers in the oceans. Viruses belonging to this genus are divided into two distinct phylogenetic clades: clade A and clade B. These viruses have narrow host-ranges with clade A phages primarily infecting Synechococcus genotypes, while clade B phages are more diverse and can infect either Synechococcus or Prochlorococcus genotypes. Here we investigated infection properties (life history traits) and environmental abundances of these two clades of T7-like cyanophages. We show that clade A cyanophages have more rapid infection dynamics, larger burst sizes and greater virulence than clade B cyanophages. However, clade B cyanophages were at least 10-fold more abundant in all seasons, and infected more cyanobacteria, than clade A cyanophages in the Red Sea. Models predicted that steady-state cyanophage abundances, infection frequency, and virus-induced mortality, peak at intermediate virulence values. Our findings indicate that differences in infection properties are reflected in virus phylogeny at the clade level. They further indicate that infection properties, together with differences in subclade diversity and host repertoire, have important ecological consequences with the less aggressive, more diverse virus clade having greater ecological impacts., (© 2022. The Author(s).)

Published

2022

4. Genetic engineering of marine cyanophages reveals integration but not lysogeny in T7-like cyanophages.

Author

Shitrit D, Hackl T, Laurenceau R, Raho N, Carlson MCG, Sabehi G, Schwartz DA, Chisholm SW, and Lindell D

Subjects

Genetic Engineering, Humans, Lysogeny, Bacteriophages genetics, Prochlorococcus genetics, Synechococcus genetics

Abstract

Marine cyanobacteria of the genera Synechococcus and Prochlorococcus are the most abundant photosynthetic organisms on earth, spanning vast regions of the oceans and contributing significantly to global primary production. Their viruses (cyanophages) greatly influence cyanobacterial ecology and evolution. Although many cyanophage genomes have been sequenced, insight into the functional role of cyanophage genes is limited by the lack of a cyanophage genetic engineering system. Here, we describe a simple, generalizable method for genetic engineering of cyanophages from multiple families, that we named REEP for REcombination, Enrichment and PCR screening. This method enables direct investigation of key cyanophage genes, and its simplicity makes it adaptable to other ecologically relevant host-virus systems. T7-like cyanophages often carry integrase genes and attachment sites, yet exhibit lytic infection dynamics. Here, using REEP, we investigated their ability to integrate and maintain a lysogenic life cycle. We found that these cyanophages integrate into the host genome and that the integrase and attachment site are required for integration. However, stable lysogens did not form. The frequency of integration was found to be low in both lab cultures and the oceans. These findings suggest that T7-like cyanophage integration is transient and is not part of a classical lysogenic cycle., (© 2021. The Author(s).)

Published

2022

5. Adaptation of the polony technique to quantify Gokushovirinae, a diverse group of single-stranded DNA phage.

Author

Sawaya NA, Baran N, Mahank S, Varsani A, Lindell D, and Breitbart M

Subjects

DNA, Single-Stranded genetics, DNA, Viral genetics, Ecosystem, Indian Ocean, Phylogeny, Bacteriophages genetics, Microviridae genetics

Abstract

Advances in metagenomics have revealed the ubiquity of single-stranded DNA (ssDNA) phage belonging to the subfamily Gokushovirinae in the oceans; however, the abundance and ecological roles of this group are unknown. Here, we quantify gokushoviruses through adaptation of the polony method, in which viral template DNA is immobilized in a gel, amplified by PCR, and subsequently detected by hybridization. Primers and probes for this assay were designed based on PCR amplicon diversity of gokushovirus major capsid protein gene sequences from a depth profile in the Gulf of Aqaba, Red Sea sampled in September 2015. At ≥95% identity, these 87 gokushovirus sequences formed 14 discrete clusters with the largest clades showing distinct depth distributions. The application of the polony method enabled the first quantification of gokushoviruses in any environment. The gokushoviruses were most abundant in the upper 40 m of the stratified water column, with a subsurface peak in abundance of 1.26 × 10 5 viruses ml -1 . These findings suggest that discrete gokushovirus genotypes infect bacterial hosts that differentially partition in the water column. Since the designed primers and probe are conserved across marine ecosystems, this polony method can be applied broadly for the quantification of gokushoviruses throughout the global oceans., (© 2021 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2021

6. Phage biology: Stuck with dU.

Author

Arava YS and Béjà O

Subjects

Biology, Genome, Viral, Bacteriophages genetics

Abstract

A new environmental study has discovered marine phages containing deoxyuridine instead of deoxythymidine in their DNA. The newly isolated viruses are phylogenetically distinct from any currently known double-stranded DNA phages., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

7. A single-cell polony method reveals low levels of infected Prochlorococcus in oligotrophic waters despite high cyanophage abundances.

Author

Mruwat N, Carlson MCG, Goldin S, Ribalet F, Kirzner S, Hulata Y, Beckett SJ, Shitrit D, Weitz JS, Armbrust EV, and Lindell D

Subjects

DNA Viruses, Ecosystem, Oceans and Seas, Seawater, Bacteriophages genetics, Prochlorococcus genetics

Abstract

Long-term stability of picocyanobacteria in the open oceans is maintained by a balance between synchronous division and death on daily timescales. Viruses are considered a major source of microbial mortality, however, current methods to measure infection have significant methodological limitations. Here we describe a method that pairs flow-cytometric sorting with a PCR-based polony technique to simultaneously screen thousands of taxonomically resolved individual cells for intracellular virus DNA, enabling sensitive, high-throughput, and direct quantification of infection by different virus lineages. Under controlled conditions with picocyanobacteria-cyanophage models, the method detected infection throughout the lytic cycle and discriminated between varying infection levels. In North Pacific subtropical surface waters, the method revealed that only a small percentage of Prochlorococcus (0.35-1.6%) were infected, predominantly by T4-like cyanophages, and that infection oscillated 2-fold in phase with the diel cycle. This corresponds to 0.35-4.8% of Prochlorococcus mortality daily. Cyanophages were 2-4-fold more abundant than Prochlorococcus, indicating that most encounters did not result in infection and suggesting infection is mitigated via host resistance, reduced phage infectivity and inefficient adsorption. This method will enable quantification of infection for key microbial taxa across oceanic regimes and will help determine the extent that viruses shape microbial communities and ecosystem level processes.

Published

2021

8. An uncultured marine cyanophage encodes an active phycobilisome proteolysis adaptor protein NblA.

Author

Nadel O, Rozenberg A, Flores-Uribe J, Larom S, Schwarz R, and Béjà O

Subjects

Cyanobacteria genetics, Genetic Complementation Test, Metagenome, Phycobilisomes metabolism, Proteolysis, Seawater virology, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bacteriophages enzymology, Bacteriophages genetics, Cyanobacteria virology, Viral Proteins genetics

Abstract

Phycobilisomes (PBS) are large water-soluble membrane-associated complexes in cyanobacteria and some chloroplasts that serve as light-harvesting antennae for the photosynthetic apparatus. When deplete of nitrogen or sulphur, cyanobacteria readily degrade their phycobilisomes allowing the cell to replenish these vanishing nutrients. The key regulator in the degradation process is NblA, a small protein (∼6 kDa), which recruits proteases to the PBS. It was discovered previously that not only do cyanobacteria possess nblA genes but also that they are encoded by genomes of some freshwater cyanophages. A recent study, using assemblies from oceanic metagenomes, revealed genomes of a novel uncultured marine cyanophage lineage, representatives of which contain genes coding for the PBS degradation protein. Here, we examined the functionality of nblA-like genes from these marine cyanophages by testing them in a freshwater model cyanobacterial nblA knockout. One of the viral NblA variants could complement the non-bleaching phenotype and restore PBS degradation. Our findings reveal a functional NblA from a novel marine cyanophage lineage. Furthermore, we shed new light on the distribution of nblA genes in cyanobacteria and cyanophages., (© 2019 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2019

9. Cyanobacteria and cyanophage contributions to carbon and nitrogen cycling in an oligotrophic oxygen-deficient zone.

Author

Fuchsman CA, Palevsky HI, Widner B, Duffy M, Carlson MCG, Neibauer JA, Mulholland MR, Keil RG, Devol AH, and Rocap G

Subjects

Carbon metabolism, Chlorophyll A metabolism, Cyanobacteria classification, Metabolomics, Nitrogen Fixation, Oxygen metabolism, Pacific Ocean, Photosynthesis, Prochlorococcus metabolism, Prochlorococcus virology, Bacteriophages metabolism, Cyanobacteria metabolism, Cyanobacteria virology, Nitrogen Cycle, Seawater chemistry, Seawater microbiology

Abstract

Up to half of marine N losses occur in oxygen-deficient zones (ODZs). Organic matter flux from productive surface waters is considered a primary control on N 2 production. Here we investigate the offshore Eastern Tropical North Pacific (ETNP) where a secondary chlorophyll a maximum resides within the ODZ. Rates of primary production and carbon export from the mixed layer and productivity in the primary chlorophyll a maximum were consistent with oligotrophic waters. However, sediment trap carbon and nitrogen fluxes increased between 105 and 150 m, indicating organic matter production within the ODZ. Metagenomic and metaproteomic characterization indicated that the secondary chlorophyll a maximum was attributable to the cyanobacterium Prochlorococcus, and numerous photosynthesis and carbon fixation proteins were detected. The presence of chemoautotrophic ammonia-oxidizing archaea and the nitrite oxidizer Nitrospina and detection of nitrate oxidoreductase was consistent with cyanobacterial oxygen production within the ODZ. Cyanobacteria and cyanophage were also present on large (>30 μm) particles and in sediment trap material. Particle cyanophage-to-host ratio exceeded 50, suggesting that viruses help convert cyanobacteria into sinking organic matter. Nitrate reduction and anammox proteins were detected, congruent with previously reported N 2 production. We suggest that autochthonous organic matter production within the ODZ contributes to N 2 production in the offshore ETNP.

Published

2019

10. Resistance in marine cyanobacteria differs against specialist and generalist cyanophages.

Author

Zborowsky S and Lindell D

Subjects

Aquatic Organisms growth & development, Aquatic Organisms virology, Bacteriophages physiology, Models, Biological, Prochlorococcus growth & development, Prochlorococcus virology, Synechococcus growth & development, Synechococcus virology

Abstract

Long-term coexistence between unicellular cyanobacteria and their lytic viruses (cyanophages) in the oceans is thought to be due to the presence of sensitive cells in which cyanophages reproduce, ultimately killing the cell, while other cyanobacteria survive due to resistance to infection. Here, we investigated resistance in marine cyanobacteria from the genera Synechococcus and Prochlorococcus and compared modes of resistance against specialist and generalist cyanophages belonging to the T7-like and T4-like cyanophage families. Resistance was extracellular in most interactions against specialist cyanophages irrespective of the phage family, preventing entry into the cell. In contrast, resistance was intracellular in practically all interactions against generalist T4-like cyanophages. The stage of intracellular arrest was interaction-specific, halting at various stages of the infection cycle. Incomplete infection cycles proceeded to various degrees of phage genome transcription and translation as well as phage genome replication in numerous interactions. In a particularly intriguing case, intracellular capsid assembly was observed, but the phage genome was not packaged. The cyanobacteria survived the encounter despite late-stage infection and partial genome degradation. We hypothesize that this is tolerated due to genome polyploidy, which we found for certain strains of both Synechococcus and Prochlorococcus Our findings unveil a heavy cost of promiscuous entry of generalist phages into nonhost cells that is rarely paid by specialist phages and suggests the presence of unknown mechanisms of intracellular resistance in the marine unicellular cyanobacteria. Furthermore, these findings indicate that the range for virus-mediated horizontal gene transfer extends beyond hosts to nonhost cyanobacterial cells., Competing Interests: The authors declare no conflict of interest., (Copyright © 2019 the Author(s). Published by PNAS.)

Published

2019

11. A novel uncultured marine cyanophage lineage with lysogenic potential linked to a putative marine Synechococcus 'relic' prophage.

Author

Flores-Uribe J, Philosof A, Sharon I, Fridman S, Larom S, and Béjà O

Subjects

Bacteriophages classification, Bacteriophages isolation & purification, Base Sequence, Genome, Viral, Genomic Islands genetics, Metagenome, Oceans and Seas, Phylogeny, Prophages classification, Prophages isolation & purification, Synechococcus genetics, Viral Proteins genetics, Bacteriophages genetics, Lysogeny genetics, Prophages genetics, Seawater virology, Synechococcus virology

Abstract

Marine cyanobacteria are important contributors to primary production in the ocean and their viruses (cyanophages) affect the ocean microbial communities. Despite reports of lysogeny in marine cyanobacteria, a genome sequence of such temperate cyanophages remains unknown although genomic analysis indicate potential for lysogeny in certain marine cyanophages. Using assemblies from Red Sea and Tara Oceans metagenomes, we recovered genomes of a novel uncultured marine cyanophage lineage, which contain, in addition to common cyanophage genes, a phycobilisome degradation protein NblA, an integrase and a split DNA polymerase. The DNA polymerase forms a monophyletic clade with a DNA polymerase from a genomic island in Synechococcus WH8016. The island contains a relic prophage that does not resemble any previously reported cyanophage but shares several genes with the newly identified cyanophages reported here. Metagenomic recruitment indicates that the novel cyanophages are widespread, albeit at low abundance. Here, we describe a novel potentially lysogenic cyanophage family, their abundance and distribution in the marine environment., (© 2019 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2019

12. Cyanophage-encoded lipid desaturases: oceanic distribution, diversity and function.

Author

Roitman S, Hornung E, Flores-Uribe J, Sharon I, Feussner I, and Béjà O

Subjects

Amino Acid Motifs, Bacteriophages genetics, Chromosome Mapping, Computational Biology, Contig Mapping, DNA Replication, Genotype, Histidine, Phylogeny, Saccharomyces cerevisiae metabolism, Water Microbiology, Bacteriophages enzymology, Cyanobacteria virology, Fatty Acids chemistry, Lipids chemistry, Oceans and Seas, Photosynthesis, Viral Proteins genetics

Abstract

Cyanobacteria are among the most abundant photosynthetic organisms in the oceans; viruses infecting cyanobacteria (cyanophages) can alter cyanobacterial populations, and therefore affect the local food web and global biochemical cycles. These phages carry auxiliary metabolic genes (AMGs), which rewire various metabolic pathways in the infected host cell, resulting in increased phage fitness. Coping with stress resulting from photodamage appears to be a central necessity of cyanophages, yet the overall mechanism is poorly understood. Here we report a novel, widespread cyanophage AMG, encoding a fatty acid desaturase (FAD), found in two genotypes with distinct geographical distribution. FADs are capable of modulating the fluidity of the host's membrane, a fundamental stress response in living cells. We show that both viral FAD (vFAD) families are Δ9 lipid desaturases, catalyzing the desaturation at carbon 9 in C16 fatty acid chains. In addition, we present a comprehensive fatty acid profiling for marine cyanobacteria, which suggests a unique desaturation pathway of medium- to long-chain fatty acids no longer than C16, in accordance with the vFAD activity. Our findings suggest that cyanophages are capable of fiddling with the infected host's membranes, possibly leading to increased photoprotection and potentially enhancing viral-encoded photosynthetic proteins, resulting in a new viral metabolic network.

Published

2018

13. Quantification of diverse virus populations in the environment using the polony method.

Author

Baran N, Goldin S, Maidanik I, and Lindell D

Subjects

Bacteriophages genetics, DNA Viruses genetics, Ecosystem, Genes, Viral, Genome, Viral genetics, Indian Ocean, Sequence Analysis, DNA, Bacteriophages classification, Metagenomics methods, Phylogeny, Prochlorococcus virology, Seawater virology, Synechococcus virology

Abstract

Viruses are globally abundant and extremely diverse in their genetic make-up and in the hosts they infect. Although they influence the abundance, diversity and evolution of their hosts, current methods are inadequate for gaining a quantitative understanding of their impact on these processes. Here we report the adaptation of the solid-phase single-molecule PCR polony method for the quantification of taxonomically relevant groups of diverse viruses. Using T7-like cyanophages as our model, we found the polony method to be far superior to regular quantitative PCR methods and droplet digital PCR when degenerate primers were used to encompass the group's diversity. This method revealed that T7-like cyanophages were highly abundant in the Red Sea in spring 2013, reaching 770,000 phages ml -1 , and displaying a similar depth distribution pattern to cyanobacteria. Furthermore, the abundances of two major clades within the T7-like cyanophages differed dramatically throughout the water column: clade B phages that carry the psbA photosynthesis gene and infect either Synechococcus or Prochlorococcus were at least 20-fold more abundant than clade A phages that lack psbA and infect Synechococcus hosts. Such measurements are of paramount importance for understanding virus population dynamics and the impact of viruses on different microbial taxa and for modelling viral influence on ecosystem functioning on a global scale.

Published

2018

14. Evolution and molecular mechanism of four-electron reducing ferredoxin-dependent bilin reductases from oceanic phages.

Author

Ledermann B, Schwan M, Sommerkamp JA, Hofmann E, Béjà O, and Frankenberg-Dinkel N

Subjects

Asparagine metabolism, Catalysis, Crystallography, X-Ray, Methionine metabolism, Mutagenesis, Site-Directed, Oceans and Seas, Oxidoreductases chemistry, Phylogeny, Protein Conformation, Substrate Specificity, Bacteriophages enzymology, Bile Pigments metabolism, Evolution, Molecular, Ferredoxins metabolism, Oxidoreductases genetics, Oxidoreductases metabolism

Abstract

Ferredoxin-dependent bilin reductases (FDBRs) are a class of enzymes reducing the heme metabolite biliverdin IXα (BV) to form open-chain tetrapyrroles used for light-perception and light-harvesting in photosynthetic organisms. Thus far, seven FDBR families have been identified, each catalysing a distinct reaction and either transferring two or four electrons from ferredoxin onto the substrate. The newest addition to the family is PcyX, originally identified from metagenomics data derived from phage. Phylogenetically, PcyA is the closest relative catalysing the reduction of BV to phycocyanobilin. PcyX, however, converts the same substrate to phycoerythrobilin, resembling the reaction catalysed by cyanophage PebS. Within this study, we aimed at understanding the evolution of catalytic activities within FDBRs using PcyX as an example. Additional members of the PcyX clade and a remote member of the PcyA family were investigated to gain insights into catalysis. Biochemical data in combination with the PcyX crystal structure revealed that a conserved aspartate-histidine pair is critical for activity. Interestingly, the same residues are part of a catalytic Asp-His-Glu triad in PcyA, including an additional Glu. While this Glu residue is replaced by Asp in PcyX, it is not involved in catalysis. Substitution back to a Glu failed to convert PcyX to a PcyA. Therefore, the change in regiospecificity is not only caused by individual catalytic amino acid residues. Rather the combination of the architecture of the active site with the positioning of the substrate triggers specific proton transfer yielding the individual phycobilin products., Enzymes: Suggested EC number for PcyX: 1.3.7.6 DATABASES: The PcyX X-ray structure was deposited in the PDB with the accession code 5OWG., (© 2017 Federation of European Biochemical Societies.)

Published

2018

15. Genetic hurdles limit the arms race between Prochlorococcus and the T7-like podoviruses infecting them.

Author

Schwartz DA and Lindell D

Subjects

Host-Pathogen Interactions, Mutation, Bacteriophages genetics, Bacteriophages physiology, Prochlorococcus genetics, Prochlorococcus virology

Abstract

Phages and hosts coexist in nature with a high degree of population diversity. This is often explained through coevolutionary models, such as the arms race or density-dependent fluctuating selection, which differ in assumptions regarding the emergence of phage mutants that overcome host resistance. Previously, resistance in the abundant marine cyanobacterium, Prochlorococcus, was found to occur frequently. However, little is known about the ability of phages to overcome this resistance. Here we report that, in some cases, T7-like cyanophage mutants emerge to infect resistant Prochlorococcus strains. These resistance-breaking phages retained the ability to infect the wild-type host. However, fitness of the mutant phages differed on the two hosts. Furthermore, in one case, resistance-breaking was accompanied by costs of decreased fitness on the wild-type host and decreased adsorption specificity, relative to the wild-type phage. In two other cases, fitness on the wild-type host increased. Whole-genome sequencing revealed mutations in probable tail-related genes. These were highly diverse in isolates and natural populations of T7-like cyanophages, suggesting that antagonistic coevolution enhances phage genome diversity. Intriguingly, most interactions did not yield resistance-breaking phages. Thus, resistance mutations raise genetic barriers to continuous arms race cycles and are indicative of an inherent asymmetry in coevolutionary capacity, with hosts having the advantage. Nevertheless, phages coexist with hosts, which we propose relies on combined, parallel action of a limited arms race, fluctuating selection and passive host-switching within diverse communities. Together, these processes generate a constantly changing network of interactions, enabling stable coexistence between hosts and phages in nature.

Published

2017

16. Two Synechococcus genes, Two Different Effects on Cyanophage Infection.

Author

Fedida A and Lindell D

Subjects

Gene Knockout Techniques, Bacteriophages physiology, Genes, Bacterial, Host-Parasite Interactions, Synechococcus genetics, Synechococcus virology, Virus Replication

Abstract

Synechococcus is an abundant marine cyanobacterium that significantly contributes to primary production. Lytic phages are thought to have a major impact on cyanobacterial population dynamics and evolution. Previously, an investigation of the transcriptional response of three Synechococcus strains to infection by the T4-like cyanomyovirus, Syn9, revealed that while the transcript levels of the vast majority of host genes declined soon after infection, those for some genes increased or remained stable. In order to assess the role of two such host-response genes during infection, we inactivated them in Synechococcus sp. strain WH8102. One gene, SYNW1659, encodes a domain of unknown function (DUF3387) that is associated with restriction enzymes. The second gene, SYNW1946, encodes a PIN-PhoH protein, of which the PIN domain is common in bacterial toxin-antitoxin systems. Neither of the inactivation mutations impacted host growth or the length of the Syn9 lytic cycle. However, the DUF3387 mutant supported significantly lower phage DNA replication and yield of phage progeny than the wild-type, suggesting that the product of this host gene aids phage production. The PIN-PhoH mutant, on the other hand, allowed for significantly higher Syn9 genomic DNA replication and progeny production, suggesting that this host gene plays a role in restraining the infection process. Our findings indicate that host-response genes play a functional role during infection and suggest that some function in an attempt at defense against the phage, while others are exploited by the phage for improved infection.

Published

2017

17. Transcriptome dynamics of a broad host-range cyanophage and its hosts.

Author

Doron S, Fedida A, Hernández-Prieto MA, Sabehi G, Karunker I, Stazic D, Feingersch R, Steglich C, Futschik M, Lindell D, and Sorek R

Subjects

Bacteriophages physiology, Gene Expression Profiling, Oceans and Seas, Oligonucleotide Array Sequence Analysis, Phylogeny, Prochlorococcus genetics, Sequence Alignment, Sequence Analysis, RNA, Synechococcus genetics, Bacteriophages genetics, Host Specificity, Metagenomics, Prochlorococcus virology, Synechococcus virology, Transcriptome

Abstract

Cyanobacteria are highly abundant in the oceans and are constantly exposed to lytic viruses. The T4-like cyanomyoviruses are abundant in the marine environment and have broad host-ranges relative to other cyanophages. It is currently unknown whether broad host-range phages specifically tailor their infection program for each host, or employ the same program irrespective of the host infected. Also unknown is how different hosts respond to infection by the same phage. Here we used microarray and RNA-seq analyses to investigate the interaction between the Syn9 T4-like cyanophage and three phylogenetically, ecologically and genomically distinct marine Synechococcus strains: WH7803, WH8102 and WH8109. Strikingly, Syn9 led a nearly identical infection and transcriptional program in all three hosts. Different to previous assumptions for T4-like cyanophages, three temporally regulated gene expression classes were observed. Furthermore, a novel regulatory element controlled early-gene transcription, and host-like promoters drove middle gene transcription, different to the regulatory paradigm for T4. Similar results were found for the P-TIM40 phage during infection of Prochlorococcus NATL2A. Moreover, genomic and metagenomic analyses indicate that these regulatory elements are abundant and conserved among T4-like cyanophages. In contrast to the near-identical transcriptional program employed by Syn9, host responses to infection involved host-specific genes primarily located in hypervariable genomic islands, substantiating islands as a major axis of phage-cyanobacteria interactions. Our findings suggest that the ability of broad host-range phages to infect multiple hosts is more likely dependent on the effectiveness of host defense strategies than on differential tailoring of the infection process by the phage.

Published

2016

18. Closing the gaps on the viral photosystem-I psaDCAB gene organization.

Author

Roitman S, Flores-Uribe J, Philosof A, Knowles B, Rohwer F, Ignacio-Espinoza JC, Sullivan MB, Cornejo-Castillo FM, Sánchez P, Acinas SG, Dupont CL, and Béjà O

Subjects

Amino Acid Sequence, Aquatic Organisms genetics, Aquatic Organisms metabolism, Atlantic Ocean, Biological Evolution, Gene Order, Genes, Viral genetics, Indian Ocean, Metagenomics, Pacific Ocean, Photosystem II Protein Complex genetics, Prochlorococcus metabolism, Prochlorococcus virology, Synechococcus metabolism, Synechococcus virology, Bacteriophages genetics, Photosynthesis genetics, Photosystem I Protein Complex genetics, Prochlorococcus genetics, Synechococcus genetics

Abstract

Marine photosynthesis is largely driven by cyanobacteria, namely Synechococcus and Prochlorococcus. Genes encoding for photosystem (PS) I and II reaction centre proteins are found in cyanophages and are believed to increase their fitness. Two viral PSI gene arrangements are known, psaJF→C→A→B→K→E→D and psaD→C→A→B. The shared genes between these gene cassettes and their encoded proteins are distinguished by %G + C and protein sequence respectively. The data on the psaD→C→A→B gene organization were reported from only two partial gene cassettes coming from Global Ocean Sampling stations in the Pacific and Indian oceans. Now we have extended our search to 370 marine stations from six metagenomic projects. Genes corresponding to both PSI gene arrangements were detected in the Pacific, Indian and Atlantic oceans, confined to a strip along the equator (30°N and 30°S). In addition, we found that the predicted structure of the viral PsaA protein from the psaD→C→A→B organization contains a lumenal loop conserved in PsaA proteins from Synechococcus, but is completely absent in viral PsaA proteins from the psaJF→C→A→B→K→E→D gene organization and most Prochlorococcus strains. This may indicate a co-evolutionary scenario where cyanophages containing either of these gene organizations infect cyanobacterial ecotypes biogeographically restricted to the 30°N and 30°S equatorial strip., (© 2015 The Authors. Environmental Microbiology published by Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2015

19. Convergent evolution toward an improved growth rate and a reduced resistance range in Prochlorococcus strains resistant to phage.

Author

Avrani S and Lindell D

Subjects

Prochlorococcus virology, Bacteriophages, Evolution, Molecular, Genes, Bacterial, Mutation, Prochlorococcus genetics

Abstract

Prochlorococcus is an abundant marine cyanobacterium that grows rapidly in the environment and contributes significantly to global primary production. This cyanobacterium coexists with many cyanophages in the oceans, likely aided by resistance to numerous co-occurring phages. Spontaneous resistance occurs frequently in Prochlorococcus and is often accompanied by a pleiotropic fitness cost manifested as either a reduced growth rate or enhanced infection by other phages. Here, we assessed the fate of a number of phage-resistant Prochlorococcus strains, focusing on those with a high fitness cost. We found that phage-resistant strains continued evolving toward an improved growth rate and a narrower resistance range, resulting in lineages with phenotypes intermediate between those of ancestral susceptible wild-type and initial resistant substrains. Changes in growth rate and resistance range often occurred in independent events, leading to a decoupling of the selection pressures acting on these phenotypes. These changes were largely the result of additional, compensatory mutations in noncore genes located in genomic islands, although genetic reversions were also observed. Additionally, a mutator strain was identified. The similarity of the evolutionary pathway followed by multiple independent resistant cultures and clones suggests they undergo a predictable evolutionary pathway. This process serves to increase both genetic diversity and infection permutations in Prochlorococcus populations, further augmenting the complexity of the interaction network between Prochlorococcus and its phages in nature. Last, our findings provide an explanation for the apparent paradox of a multitude of resistant Prochlorococcus cells in nature that are growing close to their maximal intrinsic growth rates.

Published

2015

20. Comparative metagenomics of microbial traits within oceanic viral communities.

Author

Sharon I, Battchikova N, Aro EM, Giglione C, Meinnel T, Glaser F, Pinter RY, Breitbart M, Rohwer F, and Béjà O

Subjects

Cluster Analysis, Genome, Viral, Oceans and Seas, Phylogeny, Seawater virology, Sequence Analysis, DNA, Water Microbiology, Bacteriophages genetics, Genes, Viral, Metagenome, Metagenomics

Abstract

Viral genomes often contain genes recently acquired from microbes. In some cases (for example, psbA) the proteins encoded by these genes have been shown to be important for viral replication. In this study, using a unique search strategy on the Global Ocean Survey (GOS) metagenomes in combination with marine virome and microbiome pyrosequencing-based datasets, we characterize previously undetected microbial metabolic capabilities concealed within the genomes of uncultured marine viral communities. A total of 34 microbial gene families were detected on 452 viral GOS scaffolds. The majority of auxiliary metabolic genes found on these scaffolds have never been reported in phages. Host genes detected in viruses were mainly divided between genes encoding for different energy metabolism pathways, such as electron transport and newly identified photosystem genes, or translation and post-translation mechanism related. Our findings suggest previously undetected ways, in which marine phages adapt to their hosts and improve their fitness, including translation and post-translation level control over the host rather than the already known transcription level control.

Published

2011

21. Photosystem I gene cassettes are present in marine virus genomes.

Author

Sharon I, Alperovitch A, Rohwer F, Haynes M, Glaser F, Atamna-Ismaeel N, Pinter RY, Partensky F, Koonin EV, Wolf YI, Nelson N, and Béjà O

Subjects

Adhesins, Bacterial chemistry, Adhesins, Bacterial genetics, Amino Acid Sequence, Bacteriophages metabolism, Biodiversity, Genes, Bacterial genetics, Genome, Bacterial genetics, Geography, Lipoproteins chemistry, Lipoproteins genetics, Models, Molecular, Molecular Sequence Data, Oceans and Seas, Open Reading Frames genetics, Oxidation-Reduction, Photosynthesis genetics, Photosystem I Protein Complex chemistry, Phylogeny, Polymerase Chain Reaction, Protein Conformation, Viral Proteins chemistry, Viral Proteins genetics, Viral Proteins metabolism, Water Microbiology, Bacteriophages genetics, Genes, Viral genetics, Genome, Viral genetics, Photosystem I Protein Complex genetics, Prochlorococcus virology, Seawater microbiology, Synechococcus virology

Abstract

Cyanobacteria of the Synechococcus and Prochlorococcus genera are important contributors to photosynthetic productivity in the open oceans. Recently, core photosystem II (PSII) genes were identified in cyanophages and proposed to function in photosynthesis and in increasing viral fitness by supplementing the host production of these proteins. Here we show evidence for the presence of photosystem I (PSI) genes in the genomes of viruses that infect these marine cyanobacteria, using pre-existing metagenomic data from the global ocean sampling expedition as well as from viral biomes. The seven cyanobacterial core PSI genes identified in this study, psaA, B, C, D, E, K and a unique J and F fusion, form a cluster in cyanophage genomes, suggestive of selection for a distinct function in the virus life cycle. The existence of this PSI cluster was confirmed with overlapping and long polymerase chain reaction on environmental DNA from the Northern Line Islands. Potentially, the seven proteins encoded by the viral genes are sufficient to form an intact monomeric PSI complex. Projection of viral predicted peptides on the cyanobacterial PSI crystal structure suggested that the viral-PSI components might provide a unique way of funnelling reducing power from respiratory and other electron transfer chains to the PSI.

Published

2009

22. A supervised learning approach for taxonomic classification of core-photosystem-II genes and transcripts in the marine environment.

Author

Tzahor S, Man-Aharonovich D, Kirkup BC, Yogev T, Berman-Frank I, Polz MF, Béjà O, and Mandel-Gutfreund Y

Subjects

Bacteriophages classification, Cluster Analysis, Genes, Bacterial, Genes, Viral, Genome, Bacterial, Genome, Viral, Genomics methods, Mediterranean Sea, Photosystem II Protein Complex genetics, Principal Component Analysis, Prochlorococcus classification, Seawater microbiology, Sequence Analysis, DNA, Synechococcus classification, Bacteriophages genetics, Computational Biology methods, Photosystem II Protein Complex classification, Prochlorococcus genetics, Synechococcus genetics

Abstract

Background: Cyanobacteria of the genera Synechococcus and Prochlorococcus play a key role in marine photosynthesis, which contributes to the global carbon cycle and to the world oxygen supply. Recently, genes encoding the photosystem II reaction center (psbA and psbD) were found in cyanophage genomes. This phenomenon suggested that the horizontal transfer of these genes may be involved in increasing phage fitness. To date, a very small percentage of marine bacteria and phages has been cultured. Thus, mapping genomic data extracted directly from the environment to its taxonomic origin is necessary for a better understanding of phage-host relationships and dynamics., Results: To achieve an accurate and rapid taxonomic classification, we employed a computational approach combining a multi-class Support Vector Machine (SVM) with a codon usage position specific scoring matrix (cuPSSM). Our method has been applied successfully to classify core-photosystem-II gene fragments, including partial sequences coming directly from the ocean, to seven different taxonomic classes. Applying the method on a large set of DNA and RNA psbA clones from the Mediterranean Sea, we studied the distribution of cyanobacterial psbA genes and transcripts in their natural environment. Using our approach, we were able to simultaneously examine taxonomic and ecological distributions in the marine environment., Conclusion: The ability to accurately classify the origin of individual genes and transcripts coming directly from the environment is of great importance in studying marine ecology. The classification method presented in this paper could be applied further to classify other genes amplified from the environment, for which training data is available.

Published

2009

23. Viral photosynthetic reaction center genes and transcripts in the marine environment.

Author

Sharon I, Tzahor S, Williamson S, Shmoish M, Man-Aharonovich D, Rusch DB, Yooseph S, Zeidner G, Golden SS, Mackey SR, Adir N, Weingart U, Horn D, Venter JC, Mandel-Gutfreund Y, and Béjà O

Subjects

Amino Acid Sequence, Cluster Analysis, DNA, Viral chemistry, DNA, Viral genetics, Genomics, Molecular Sequence Data, Photosystem II Protein Complex genetics, Sequence Alignment, Sequence Analysis, DNA, Bacteriophages genetics, Photosynthetic Reaction Center Complex Proteins genetics, Prochlorococcus virology, Seawater microbiology, Synechococcus virology

Abstract

Cyanobacteria of the genera Synechococcus and Prochlorococcus are important contributors to photosynthetic productivity in the open ocean. The discovery of genes (psbA, psbD) that encode key photosystem II proteins (D1, D2) in the genomes of phages that infect these cyanobacteria suggests new paradigms for the regulation, function and evolution of photosynthesis in the vast pelagic ecosystem. Reports on the prevalence and expression of phage photosynthesis genes, and evolutionary data showing a potential recombination of phage and host genes, suggest a model in which phage photosynthesis genes help support photosynthetic activity in their hosts during the infection process. Here, using metagenomic data in natural ocean samples, we show that about 60% of the psbA genes in surface water along the global ocean sampling transect are of phage origin, and that the phage genes are undergoing an independent selection for distinct D1 proteins. Furthermore, we show that different viral psbA genes are expressed in the environment.

Published

2007

24. Single-domain VH antibody fragments from a phage display library.

Author

Binyamin L, Plaksin D, and Reiter Y

Subjects

Cloning, Molecular, DNA Primers chemistry, DNA, Recombinant, Immunoglobulin Heavy Chains isolation & purification, Immunoglobulin Heavy Chains metabolism, Bacteriophages genetics, Complementarity Determining Regions genetics, Immunoglobulin Heavy Chains genetics, Peptide Library, Polymerase Chain Reaction methods

Published

2003

25. An antibody single-domain phage display library of a native heavy chain variable region: isolation of functional single-domain VH molecules with a unique interface.

Author

Reiter Y, Schuck P, Boyd LF, and Plaksin D

Subjects

Amino Acid Sequence, Base Sequence, Cloning, Molecular, DNA, Recombinant, Immunoglobulin Heavy Chains metabolism, Immunoglobulin Variable Region metabolism, Molecular Sequence Data, Bacteriophages genetics, Immunoglobulin Heavy Chains genetics, Immunoglobulin Variable Region genetics

Abstract

To develop very small antibody-derived recognition units for experimental, medical, and drug design purposes, a heavy chain variable region (VH) single-domain phage-display library was designed and constructed. The scaffold that was used for library construction was a native sequence of a monoclonal antibody with a unique VH/VL interface. There was no need to modify any residues in the VL interface to avoid non-specific binding of VH domain. The library repertoire, consisting of 4x10(8)independent clones, was generated by the randomization of nine amino acid residues in complementary determining region 3. The library was screened by binding to protein antigens, and individual clones were isolated. The VH genes encoding for specific binding clones were rescued and large amounts of soluble and stable single-domain VH protein were made from insoluble inclusion bodies by in vitro refolding and purification. Biochemical and biophysical characterization of the VH protein revealed a highly specific, correctly folded, and stable monomeric molecule. Binding studies demonstrated an affinity of 20 nM. The properties of these molecules make them attractive for clinical, industrial, and research applications, as well as a step toward improvement in the design of small molecules that are based on the hypervariable loops of antibodies., (Copyright 1999 Academic Press.)

Published

1999