Stop codon recoding is widespread in diverse phage lineages and has the potential to regulate translation of late stage and lytic genes

The genetic code is a highly conserved feature of life. However, some alternative genetic codes use reassigned stop codons to code for amino acids. Here, we survey stop codon recoding across bacteriophages (phages) in human and animal gut microbiomes. We find that stop codon recoding has evolved in diverse clades of phages predicted to infect hosts that use the standard code. We provide evidence for an evolutionary path towards recoding involving reduction in the frequency of TGA and TAG stop codons due to low GC content, followed by acquisition of suppressor tRNAs and the emergence of recoded stop codons in structural and lysis genes. In analyses of two distinct lineages of recoded virulent phages, we find that lysis-related genes are uniquely biased towards use of recoded stop codons. This convergence supports the inference that stop codon recoding is a strategy to regulate the expression of late stage genes and control lysis timing. Interestingly, we identified prophages with recoded stop codons integrated into genomes of bacteria that use standard code, and hypothesize that recoding may control the lytic-lysogenic switch. Alternative coding has evolved many times, often in closely related lineages, indicating that genetic code is plastic in bacteriophages and adaptive recoding can occur over very short evolutionary timescales.

De Novo Polycomb Recruitment: Lessons from Latent Herpesviruses

The Human Herpesviruses persist in the form of a latent infection in specialized cell types. During latency, the herpesvirus genomes associate with cellular histone proteins and the viral lytic genes assemble into transcriptionally repressive heterochromatin. Although there is divergence in the nature of heterochromatin on latent herpesvirus genomes, in general, the genomes assemble into forms of heterochromatin that can convert to euchromatin to permit gene expression and therefore reactivation. This reversible form of heterochromatin is known as facultative heterochromatin and is most commonly characterized by polycomb silencing. Polycomb silencing is prevalent on the cellular genome and plays a role in developmentally regulated and imprinted genes, as well as X chromosome inactivation. As herpesviruses initially enter the cell in an un-chromatinized state, they provide an optimal system to study how de novo facultative heterochromatin is targeted to regions of DNA and how it contributes to silencing. Here, we describe how polycomb-mediated silencing potentially assembles onto herpesvirus genomes, synergizing what is known about herpesvirus latency with facultative heterochromatin targeting to the cellular genome. A greater understanding of polycomb silencing of herpesviruses will inform on the mechanism of persistence and reactivation of these pathogenic human viruses and provide clues regarding how de novo facultative heterochromatin forms on the cellular genome.

The resident TP712 prophage of Lactococcus lactis MG1363 provides extra holin functions to the new P335 phage CAP for effective host lysis

Prophages are widely present in Lactococcus lactis , a lactic acid bacterium (LAB) that plays a key role in dairy fermentations. L. lactis MG1363 is a laboratory strain used worldwide as a model LAB. Initially regarded as plasmid- and prophage-free, MG1363 carries two complete prophages TP712 and MG-3. Only TP712 seems to be inducible but unable to lyse the host. Several so-called TP712 lysogens able to lyse upon prophage induction were reported in the past, but the reason for their lytic phenotype remained unknown. In this work, we describe CAP, a new P335 prophage detected in the “lytic TP712 lysogens”, which had remained unnoticed. CAP is able to excise after mitomycin C treatment, along with TP712, and able to infect L. lactis MG1363-like strains but not the lytic TP712 lysogens. Both phages cooperate for efficient host lysis. While the expression i n trans of the CAP lytic genes was sufficient to trigger cell lysis, this process was boosted when the resident TP712 prophage was concomitantly induced. Introduction of mutations into the TP712 lytic genes revealed that its holin but not its endolysin plays a major role. Accordingly, it is shown that the lytic activity of the recombinant CAP endolysin relies on membrane depolarization. Revisiting the seminal work to generate the extensively used L. lactis MG1363 strain led us to conclude that the CAP phage was originally present in its ancestor L. lactis NCDO712 and our results solved long-standing mysteries around the MG1363 resident prophage TP712 reported in the “pre-sequencing” era. Importance Prophages are bacterial viruses that integrate in the chromosome of bacteria until an environmental trigger induces their lytic cycle ending with lysis of the host. Prophages present in dairy starters can compromise milk fermentation and represent a serious threat in dairy plants. In this work, we have discovered that two temperate phages TP712 and CAP infecting the laboratory strain Lactococcus lactis MG1363 join forces to lyse the host. Based on the in vitro lytic activity of the LysCAP endolysin, in combination with mutated versions of TP712 lacking either its holin or endolysin, we conclude that this cooperation relies on the combined activity of the holins of both phages that boost the activity of LysCAP. The presence of an additional prophage explains the lytic phenotype of the formerly thought to be single TP712 lysogens that had remained a mystery for many years.

De Novo Polycomb Recruitment: Lessons from Latent Herpesviruses

The Human Herpesviruses persist in the form of a latent infection in specialized cell types. During latency, the herpesvirus genomes associate with cellular histone proteins and the viral lytic genes assemble into transcriptionally repressive heterochromatin. Although there is divergence in the nature of heterochromatin on latent herpesvirus genomes, in general the genomes assemble into forms of heterochromatin that can convert to euchromatin to permit gene expression and therefore reactivation. This reversible form of heterochromatin is known as facultative heterochromatin and is most commonly characterized by polycomb silencing. Polycomb silencing is prevalent on the cellular genome and plays a role in developmentally regulated and imprinted genes, as well as X chromosome inactivation. As herpesviruses initially enter the cell in an un-chromatinized state, they provide an optimal system to study how de novo facultative heterochromatin is targeted to regions of DNA and how it contributes to silencing. Here, we describe how polycomb-mediated silencing potentially assembles onto herpesvirus genomes, synergizing what is known about herpesvirus latency with facultative heterochromatin targeting to the cellular genome. A greater understanding of polycomb silencing of herpesviruses will inform on the mechanism of persistence and reactivation of these pathogenic human viruses and provide clues regarding how de novo facultative heterochromatin forms on the cellular genome.

Bone Marrow Derived SH-SY5Y Neuroblastoma Cells Infected by Kaposi’s Sarcoma Herpes Virus (KSHV) Display Unique Infection Phenotypes and Growth Properties

The Kaposi’s sarcoma-associated herpesvirus (KSHV) is an important oncogenic virus previously shown to be neurotropic, but studies on neuronal cells infection and pathogenesis are still very limited. Here we characterized the effects of KSHV infection on neuronal SH-SY5Y cells by the recombinant virus rKSHV219, which expresses both GFP and RFP to reflect latent and lytic phases of infection. We demonstrated that infected cells have a faster growth rate and the KSHV infection can be sustained. Interestingly, the infected cells can transition spontaneously back and forth between lytic and latent phases of infections, producing progeny viruses but without any adverse effects on cell growth. In addition, transcriptome analysis of viral and cellular genes in latent and lytic cells showed that unlike other infected cell lines, the latently infected cells expressed both latent and most, but not all the lytic genes required for infectious virion production. The uniquely expressed viral genes by the lytic cells were mainly involved in the early steps of virus binding. Some of the cellular genes that were deregulated in both latent and lytically infected cells are involved in cell adhesion, in cell signal pathways and tumorigenesis. The downregulated cellular CCDN1, PAX5, NFASC and upregulated CTGF, BMP4, YAP1, LEF1 and HLA-DRB1 genes were found to be associated with the cell adhesion molecules (CAM), hippo signaling and cancer. These deregulated genes may be involved in creating an environment that are unique in the neuronal cells to sustain cell growth upon KSHV infection not observed in other infected cell types. IMPORTANCE Our study has provided evidence that the neuronal SH-SY5Y cells displayed unique cellular responses upon KSHV infection. Unlike other infected cells, this neuronal cell displayed a more rapid growth rate upon infection and can spontaneously transition back and forth between latent and lytic phases of infection. Unlike other latently infected cells, a number of lytic genes were also expressed in the latent phase of infection in addition to the established latent viral genes. They may play a role in deregulating a number of host genes that are involved in cell signaling and tumorigenesis in order to sustain the infection and growth advantages for the cells. Our study has provided novel insights on KSHV infection of neuronal cells and a potential new model for further studies to explore the underlying mechanism in viral and host interaction for neuronal cells, and the association of KSHV with neuronal diseases.

Two Distinct Modes of Lysis Regulation in Campylobacter Fletchervirus and Firehammervirus Phages

Campylobacter phages are divided into two genera; Fletchervirus and Firehammervirus, showing only limited intergenus homology. Here, we aim to identify the lytic genes of both genera using two representative phages (F352 and F379) from our collection. We performed a detailed in silico analysis searching for conserved protein domains and found that the predicted lytic genes are not organized into lysis cassettes but are conserved within each genus. To verify the function of selected lytic genes, the proteins were expressed in E. coli, followed by lytic assays. Our results show that Fletchervirus phages encode a typical signal peptide (SP) endolysin dependent on the Sec-pathway for translocation and a holin for activation. In contrast, Firehammervirus phages encode a novel endolysin that does not belong to currently described endolysin groups. This endolysin also uses the Sec-pathway for translocation but induces lysis of E. coli after overexpression. Interestingly, co-expression of this endolysin with an overlapping gene delayed and limited cell lysis, suggesting that this gene functions as a lysis inhibitor. These results indicate that Firehammervirus phages regulate lysis timing by a yet undescribed mechanism. In conclusion, we found that the two Campylobacter phage genera control lysis by two distinct mechanisms.

IFI16, a nuclear innate immune DNA sensor, mediates epigenetic silencing of herpesvirus genomes by its association with H3K9 methyltransferases SUV39H1 and GLP

IFI16, an innate immune DNA sensor, recognizes the nuclear episomal herpes viral genomes and induces the inflammasome and interferon-β responses. IFI16 also regulates cellular transcription and act as a DNA virus restriction factor. IFI16 knockdown disrupted the latency of Kaposi’s sarcoma associated herpesvirus (KSHV) and induced lytic transcripts. However, the mechanism of IFI16’s transcription regulation is unknown. Here, we show that IFI16 is in complex with the H3K9 methyltransferase SUV39H1 and GLP and recruits them to the KSHV genome during de novo infection and latency. The resulting depositions of H3K9me2/me3 serve as a docking site for the heterochromatin-inducing HP1α protein leading into the IFI16-dependent epigenetic modifications and silencing of KSHV lytic genes. These studies suggest that IFI16’s interaction with H3K9MTases is one of the potential mechanisms by which IFI16 regulates transcription and establish an important paradigm of an innate immune sensor’s involvement in epigenetic silencing of foreign DNA.

The Transcriptome of Latent Human Cytomegalovirus

ABSTRACTThe latent human cytomegalovirus (HCMV) transcriptome has been extremely difficult to define due to the scarcity of naturally latent cells and the complexity of available models. The genomic era offers many approaches to transcriptome profiling that hold great potential for elucidating this challenging issue. The results from two recent studies applying different transcriptomic methodologies and analyses of both experimental and natural samples challenge the dogma of a restricted latency-associated transcription program. Instead, they portray the hallmark of HCMV latent infection as low-level expression of a broad spectrum of canonical viral lytic genes.

Tumor Necrosis Factor Alpha Induces Reactivation of Human Cytomegalovirus Independently of Myeloid Cell Differentiation following Posttranscriptional Establishment of Latency

ABSTRACTWe used the Kasumi-3 model to study human cytomegalovirus (HCMV) latency and reactivation in myeloid progenitor cells. Kasumi-3 cells were infected with HCMV strain TB40/Ewt-GFP, flow sorted for green fluorescent protein-positive (GFP+) cells, and cultured for various times to monitor establishment of latency, as judged by repression of viral gene expression (RNA/DNA ratio) and loss of virus production. We found that, in the vast majority of cells, latency was established posttranscriptionally in the GFP+infected cells: transcription was initially turned on and then turned off. We also found that some of the GFP−cells were infected, suggesting that latency might be established in these cells at the outset of infection. We were not able to test this hypothesis because some GFP−cells expressed lytic genes and thus it was not possible to separate them from GFP−quiescent cells. In addition, we found that the pattern of expression of lytic genes that have been associated with latency, including UL138, US28, and RNA2.7, was the same as that of other lytic genes, indicating that there was no preferential expression of these genes once latency was established. We confirmed previous studies showing that tumor necrosis factor alpha (TNF-α) induced reactivation of infectious virus, and by analyzing expression of the progenitor cell marker CD34 as well as myeloid cell differentiation markers in IE+cells after treatment with TNF-α, we showed that TNF-α induced transcriptional reactivation of IE gene expression independently of differentiation. TNF-α-mediated reactivation in Kasumi-3 cells was correlated with activation of NF-κB, KAP-1, and ATM.IMPORTANCEHCMV is an important human pathogen that establishes lifelong latent infection in myeloid progenitor cells and reactivates frequently to cause significant disease in immunocompromised people. Our observation that viral gene expression is first turned on and then turned off to establish latency suggests that there is a host defense, which may be myeloid cell specific, responsible for transcriptional silencing of viral gene expression. Our observation that TNF-α induces reactivation independently of differentiation provides insight into molecular mechanisms that control reactivation.