VAPEX: an interactive web server for the deep exploration of natural virus and phage genomes.

MOTIVATION: Studying the genetic makeup of viruses and phages through genome analysis is crucial for comprehending their function in causing diseases, progressing medicine, tracing their evolutionary history, monitoring the environment, and creating innovative biotechnologies. However, accessing the necessary data can be challenging due to a lack of dedicated comparative genomic tools and viral and phage databases, which are often outdated. Moreover, many wet bench experimentalists may not have the computational proficiency required to manipulate large amounts of genomic data. RESULTS: We have developed VAPEX (Virus And Phage EXplorer), a web server which is supported by a database and features a user-friendly web interface. This tool enables users to easily perform various genomic analysis queries on all natural viruses and phages that have been fully sequenced and are listed in the NCBI compendium. VAPEX therefore excels in producing visual depictions of fully resolved synteny maps, which is one of its key strengths. VAPEX has the ability to exhibit a vast array of orthologous gene classes simultaneously through the use of symbolic representation. Additionally, VAPEX can fully analyze user-submitted viral and phage genomes, including those that have not yet been annotated. AVAILABILITY AND IMPLEMENTATION: VAPEX can be accessed from all current web browsers such as Chrome, Firefox, Edge, Safari, and Opera. VAPEX is freely accessible at https://archaea.i2bc.paris-saclay.fr/vapex/.

Transcriptional Regulation of Congocidine (Netropsin) Biosynthesis and Resistance.

The production of specialized metabolites by Streptomyces bacteria is usually temporally regulated. This regulation is complex and frequently involves both global and pathway-specific mechanisms. Streptomyces ambofaciens ATCC23877 produces several specialized metabolites, including spiramycins, stambomycins, kinamycins and congocidine. The production of the first three molecules has been shown to be controlled by one or several cluster-situated transcriptional regulators. However, nothing is known regarding the regulation of congocidine biosynthesis. Congocidine (netropsin) belongs to the family of pyrrolamide metabolites, which also includes distamycin and anthelvencins. Most pyrrolamides bind into the minor groove of DNA, specifically in A/T-rich regions, which gives them numerous biological activities, such as antimicrobial and antitumoral activities. We previously reported the characterization of the pyrrolamide biosynthetic gene clusters of congocidine (cgc) in S. ambofaciens ATCC23877, distamycin (dst) in Streptomyces netropsis DSM40846, and anthelvencins (ant) in Streptomyces venezuelae ATCC14583. The three gene clusters contain a gene encoding a putative transcriptional regulator, cgc1, dst1, and ant1, respectively. Cgc1, Dst1, and Ant1 present a high percentage of amino acid sequence similarity. We demonstrate here that Cgc1, an atypical orphan response regulator, activates the transcription of all cgc genes in the stationary phase of S. ambofaciens growth. We also show that the cgc cluster is constituted of eight main transcriptional units. Finally, we show that congocidine induces the expression of the transcriptional regulator Cgc1 and of the operon containing the resistance genes (cgc20 and cgc21, coding for an ABC transporter), and propose a model for the transcriptional regulation of the cgc gene cluster. IMPORTANCE Understanding the mechanisms of regulation of specialized metabolite production can have important implications both at the level of specialized metabolism study (expression of silent gene clusters) and at the biotechnological level (increase of the production of a metabolite of interest). We report here a study on the regulation of the biosynthesis of a metabolite from the pyrrolamide family, congocidine. We show that congocidine biosynthesis and resistance are controlled by Cgc1, a cluster-situated regulator. As the gene clusters directing the biosynthesis of the pyrrolamides distamycin and anthelvencin encode a homolog of Cgc1, our findings may be relevant for the biosynthesis of other pyrrolamides. In addition, our results reveal a new type of feed-forward induction mechanism, in which congocidine induces its own biosynthesis through the induction of the transcription of cgc1.

BAGET 2.0: an updated web tool for the effortless retrieval of prokaryotic gene context and sequence.

MOTIVATION: The retrieval of a single gene sequence and context from completely sequenced bacterial and archaeal genomes constitutes an intimidating task for the wet bench biologist. Existing web-based genome browsers are either too complex for routine use or only provide a subset of the available prokaryotic genomes. RESULTS: We have developed BAGET 2.0 (Bacterial and Archaeal Gene Exploration Tool), an updated web service granting access in just three mouse clicks to the sequence and synteny of any gene from completely sequenced bacteria and archaea. User-provided annotated genomes can be processed as well. BAGET 2.0 relies on a local database updated on a daily basis. AVAILABILITY AND IMPLEMENTATION: BAGET 2.0 befits all current browsers such as Chrome, Firefox, Edge, Opera and Safari. Internet Explorer 11 is supported. BAGET 2.0 is freely accessible at https://archaea.i2bc.paris-saclay.fr/baget/.

Accurate characterization of Escherichia coli tRNA modifications with a simple method of deep-sequencing library preparation.

In conventional RNA high-throughput sequencing, modified bases prevent a large fraction of tRNA transcripts to be converted into cDNA libraries. Recent proposals aiming at resolving this issue take advantage of the interference of base modifications with RT enzymes to detect and identify them by establishing signals from aborted cDNA transcripts. Because some modifications, such as methyl groups, do almost not allow RT bypassing, demethylation and highly processive RT enzymes have been used to overcome these obstacles. Working with Escherichia coli as a model system, we show that with a conventional (albeit still engineered) RT enzyme and key optimizations in library preparation, all RT-impairing modifications can be highlighted along the entire tRNA length without demethylation procedure. This is achieved by combining deep-sequencing samples, which allows to establish aborted transcription signal of higher accuracy and reproducibility, with the potential for differentiating tiny differences in the state of modification of all cellular tRNAs. In addition, our protocol provides estimates of the relative tRNA abundance.

Natural combinatorial biosynthesis involving two clusters for the synthesis of three pyrrolamides in Streptomyces netropsis.

The pyrrolamides constitute a small family of secondary metabolites that are known for their ability to bind noncovalently to the DNA minor groove with some sequence specificity. To date, only a single pyrrolamide biosynthetic gene cluster has been reported, directing the synthesis of congocidine (netropsin) in Streptomyces ambofaciens. In this study, we improve our understanding of pyrrolamide biosynthesis through the identification and characterization of the gene cluster responsible for the production of distamycin in Streptomyces netropsis DSM40846. We discover that the strain produces two other pyrrolamides, the well-characterized congocidine and a congocidine/distamycin hybrid that we named disgocidine. S. netropsis DSM40846 genome analysis led to the identification of two distinct pyrrolamide-like biosynthetic gene clusters. We show here that these two clusters are reciprocally dependent for the production of the three pyrrolamide molecules. Furthermore, based on detailed functional analysis of these clusters, we propose a biosynthetic route to congocidine and distamycin and an updated model for pyrrolamide assembly. The synthesis of disgocidine, the distamycin/congocidine hybrid, appears to constitute the first example of "natural combinatorial biosynthesis" between two related biosynthetic pathways. Finally, we analyze the genomic context of the two biosynthetic gene clusters and suggest that the presently interdependent clusters result from the coevolution of two ancestral independent pyrrolamide gene clusters.

Cold adaptation in DEAD-box proteins.

Spontaneous rearrangements of RNA structures are usually characterized by large activation energies and thus become very slow at low temperatures, yet RNA structure must remain dynamic even in cold-adapted (psychrophilic) organisms. DEAD-box proteins constitute a ubiquitous family of RNA-dependent ATPases that can often unwind short RNA duplexes in vitro (helicase activity), hence the belief that one of their major (though not exclusive) roles in vivo is to assist in RNA rearrangements. Here, we compare two Escherichia coli DEAD-box proteins and their orthologs from the psychrophilic bacteria Pseudoalteromonas haloplanktis and Colwellia psychrerythraea from the point of view of enzymatic properties. One of these proteins (SrmB) is involved in ribosome assembly, whereas the other (RhlE) presumably participates in both mRNA degradation and ribosome assembly; in vitro, RhlE is far more active as a helicase than SrmB. The activation energy associated with the ATPase activity of the psychrophilic SrmB is lower than for its mesophilic counterpart, making it more active at low temperatures. In contrast, in the case of psychrophilic RhlE, it is the RNA unwinding activity, not the ATPase activity, that has a reduced activation energy and is therefore cold-adapted. We argue that these different modes of cold adaptation reflect the likely function of these proteins in vivo: RNA helicase for RhlE and ATP-dependent RNA binding for SrmB. The cold adaptation of helicases like RhlE presumably facilitates RNA metabolism in psychrophilic bacteria.

The rolling-circle plasmid pTN1 from the hyperthermophilic archaeon Thermococcus nautilus.

The hyperthermophilic archaeon Thermococcus nautilus carries a plasmid, pTN1, which encodes a rolling-circle (RC) replication initiator protein of 74 kDa (Rep74) and an orphan protein of 24 kDa (p24). The Rep74 protein is homologous to the Rep75 protein encoded by the RC plasmid pGT5 from Pyrococcus abyssi. Comparative analysis of Rep74 and Rep75 sequences shows that these proteins correspond to a new family of RC initiators formed by the fusion of a Rep domain with an N-terminal domain of unknown function. Surprisingly, the Rep domain of Rep74/75 is more closely related to transposases encoded by IS elements than to Rep proteins of other RC plasmids. The p24 protein contains a hydrophobic segment, a highly charged region and a zinc finger motif. A recombinant p24 protein lacking the hydrophobic segment binds and condenses both single- and double-stranded DNA, and forms DNA aggregates with extreme compaction at high protein to DNA ratio. In addition to encoding proteins of significant interest, pTN1 is remarkable by being the only characterized plasmid isolated from a Thermococcus strain, thus being useful to develop genetic tools in Thermococcus kodakaraensis for which gene disruption methods became recently available.