Single-cell RNA-seq landscape midbrain cell responses to red spotted grouper nervous necrosis virus infection.

Viral nervous necrosis (VNN) is an acute and serious fish disease caused by nervous necrosis virus (NNV) which has been reported massive mortality in more than fifty teleost species worldwide. VNN causes damage of necrosis and vacuolation to central nervous system (CNS) cells in fish. It is difficult to identify the specific type of cell targeted by NNV, and to decipher the host immune response because of the functional diversity and highly complex anatomical and cellular composition of the CNS. In this study, we found that the red spotted grouper NNV (RGNNV) mainly attacked the midbrain of orange-spotted grouper (Epinephelus coioides). We conducted single-cell RNA-seq analysis of the midbrain of healthy and RGNNV-infected fish and identified 35 transcriptionally distinct cell subtypes, including 28 neuronal and 7 non-neuronal cell types. An evaluation of the subpopulations of immune cells revealed that macrophages were enriched in RGNNV-infected fish, and the transcriptional profiles of macrophages indicated an acute cytokine and inflammatory response. Unsupervised pseudotime analysis of immune cells showed that microglia transformed into M1-type activated macrophages to produce cytokines to reduce the damage to nerve tissue caused by the virus. We also found that RGNNV targeted neuronal cell types was GLU1 and GLU3, and we found that the key genes and pathways by which causes cell cytoplasmic vacuoles and autophagy significant enrichment, this may be the major route viruses cause cell death. These data provided a comprehensive transcriptional perspective of the grouper midbrain and the basis for further research on how viruses infect the teleost CNS.

Differential immunogene expression profile of European sea bass (Dicentrarchus labrax, L.) in response to highly and low virulent NNV.

European sea bass is highly susceptible to the nervous necrosis virus, RGNNV genotype, whereas natural outbreaks caused by the SJNNV genotype have not been recorded. The onset and severity of an infectious disease depend on pathogen virulence factors and the host immune response. The importance of RGNNV capsid protein amino acids 247 and 270 as virulence factors has been previously demonstrated in European sea bass; however, sea bass immune response against nodaviruses with different levels of virulence has been poorly characterized. Knowing the differences between the immune response against both kinds of isolates may be key to get more insight into the host mechanisms responsible for NNV virulence. For this reason, this study analyses the transcription of immunogenes differentially expressed in European sea bass inoculated with nodaviruses with different virulence: a RGNNV virus obtained by reverse genetics (rDl956), highly virulent to sea bass, and a mutated virus (Mut247+270Dl956, RGNNV virus displaying SJNNV-type amino acids at positions 247 and 270 of the capsid protein), presenting lower virulence. This study has been performed in brain and head kidney, and the main differences between the immunogene responses triggered by both viruses have been observed in brain. The immunogene response in this organ is stronger after inoculation with the most virulent virus, and the main differences involved genes related with IFN I system, inflammatory response, cell-mediated response, and apoptosis. The lower virulence of Mut247+270Dl956 to European sea bass can be associated with a delayed IFN I response, as well as an early and transitory inflammation and cell-mediated responses, suggesting that those can be pivotal elements in controlling the viral infection, and therefore, their functional activity could be analysed in future studies. In addition, this study supports the role of capsid amino acids at positions 247 and 270 as important determinants of RGNNV virulence to European sea bass.

Vibrio vulnificus quorum-sensing molecule cyclo(Phe-Pro) inhibits RIG-I-mediated antiviral innate immunity.

The recognition of pathogen-derived ligands by pattern recognition receptors activates the innate immune response, but the potential interaction of quorum-sensing (QS) signaling molecules with host anti-viral defenses remains largely unknown. Here we show that the Vibrio vulnificus QS molecule cyclo(Phe-Pro) (cFP) inhibits interferon (IFN)-ß production by interfering with retinoic-acid-inducible gene-I (RIG-I) activation. Binding of cFP to the RIG-I 2CARD domain induces a conformational change in RIG-I, preventing the TRIM25-mediated ubiquitination to abrogate IFN production. cFP enhances susceptibility to hepatitis C virus (HCV), as well as Sendai and influenza viruses, each known to be sensed by RIG-I but did not affect the melanoma-differentiation-associated gene 5 (MDA5)-recognition of norovirus. Our results reveal an inter-kingdom network between bacteria, viruses and host that dysregulates host innate responses via a microbial quorum-sensing molecule modulating the response to viral infection.

Characterization of microRNAs in orange-spotted grouper (Epinephelus coioides) fin cells upon red-spotted grouper nervous necrosis virus infection.

Nervous necrosis virus (NNV), one of the most prevalent fish pathogens, has caused fatal disease of viral nervous necrosis (VNN) in many marine and freshwater fishes, and resulted in heavy economic losses in aquaculture industry worldwide. However, the molecular mechanisms underlying the pathogenicity of NNV remain elusive. In this study, the expression profiles of microRNA (miRNA) were investigated in grouper fin (GF-1) cells infected with red-spotted grouper nervous necrosis virus (RGNNV) via deep sequencing technique. The results showed that a total of 220 miRNAs were identified by aligning the small RNA sequences with the miRNA database of zebrafish, and 18 novel miRNAs were predicted using miRDeep2 software. Compared with the non-infected groups, 51 and 16 differentially expressed miRNAs (DE-miRNAs) were identified in the samples infected with RGNNV at 3 and 24 h, respectively. Six DE-miRNAs were randomly selected to validate their expressions using quantitative reverse transcription polymerase chain reaction (qRT-PCR), the results showed that their expression profiles were consistent with those obtained by deep sequencing. The target genes of the DE-miRNAs covered a wide range of functions, such as regulation of transcription, oxidation-reduction process, proteolysis, regulation of apoptotic process, and immune response. In addition, the effects of four DE-miRNAs including miR-1, miR-30b, miR-150, and miR-184 on RGNNV replication were evaluated, and the results showed that over-expression of each of the four miRNAs promoted the replication of RGNNV. These data provide insight into the molecular mechanism of RGNNV infection, and will benefit for the development of effective strategies to control RGNNV infection.

Genetic characterization and transcription analyses of the European sea bass (Dicentrarchus labrax) isg15 gene.

Fish interferons are cytokines involved in its resistance to viral infections by inducing the transcription of several interferon-induced genes, such as isg15. The aim of the present study was the genetic characterization of the European sea bass isg15 gene, describing the regulatory motifs found in its sequence. In addition, an in vivo analysis of transcription in response to betanodavirus (RGNNV genotype) and poly I:C has been performed. The analysis of the resulting sequences showed that sea bass isg15 gene is composed of two exons and a single 276-bp intron located at the 5'-UTR region. The full length cDNA is 1143-bp, including a 102-bp 5'-UTR region, a 474-bp ORF, and a 291-bp 3'-UTR region. Several mRNA-regulatory elements, including three unusual ATTTA instability motifs in the intron, and four ATTTA motifs along with a cytoplasmic polyadenylation element in the 3'-UTR region, have been found in this sequence. The in vivo analyses revealed a similar kinetics and level of transcription in fish brain and head kidney after poly I:C inoculation; however, the induction caused by RGNNV started earlier in brain, where the upregulation of isg15 gene transcription was high. The present study contributes to further characterize the European sea bass IFN I response against RGNNV infections.

Characterization and expression analysis of laboratory of genetics and physiology 2 gene in sea perch, Lateolabrax japonicus.

LGP2 (laboratory of genetics and physiology 2) as a key component of the retinoic acid-inducible gene I (RIG-I)-like receptors (RLRs), plays a predominant role in modulating RLRs-mediated cellular antiviral signaling during viral infection. In the present study, we cloned the LGP2 gene from the sea perch (Lateolabrax japonicus) (LjLGP2), an economically important farmed fish. The complete cDNA sequence of LjLGP2 was 2790 nt and encoded a polypeptide of 682 amino acids which contains four main structural domains: one DEAD/DEAH box helicase domain, one conserved restriction domain of bacterial type III restriction enzyme, one helicase superfamily c-terminal domain and one C-terminal domain of RIG-I, similar to most vertebrate LGP2. Subcellular localization analysis showed that LjLGP2 spanned the entire cytosol. The LjLGP2 mRNA was widespread expressed in the tested 10 tissues of healthy fish and significantly up-regulated post NNV infection. Furthermore, time course analysis showed that LjLGP2 transcripts significantly increased in the spleen, kidney and liver tissues after NNV infection. LjLGP2 mRNA expression was rapidly and significantly up-regulated in LJB cells after poly I:C stimulation and NNV infection. The present results suggest that LjLGP2 may be involved in recognization of NNV and play a role in antiviral innate immune against NNV in sea perch.

Influence of temperature on Mx gene expression profiles and the protection of sevenband grouper, Epinephelus septemfasciatus, against red-spotted grouper nervous necrosis virus (RGNNV) infection after poly (I:C) injection.

Influence of temperature on the susceptibility of fish against virus infection has been studied for a decade. Recent reports have been shown the effects of rearing temperatures on the fish immune system against virus infection. However, the roles of temperature in regulation of type I interferon (IFN) system has not yet been investigated. Thus, the effects of temperature on type I IFN response were investigated in this study using poly (I:C) injection in sevenband grouper and Mx gene was used as a marker for type I IFN expression. Quantitative real-time PCR (qPCR) result showed that Mx expression profiles were moderately different between temperatures. The highly up-regulated Mx transcripts at 3 h post injection (hpi) were observed in high temperatures (25 °C and 30 °C) but not in low temperatures (15 °C and 20 °C). Meanwhile, low temperatures (15 °C and 20 °C) could detect the highly up-regulated Mx transcripts at 24 hpi. Expression of Mx transcripts was also observed at 72 hpi at 15 °C. Poly (I:C)-injected fish were challenged with RGNNV after 72 and 168 hpi. At 72 hpi, 100% of fish survived at all temperatures, whereas 95% survival rate was observed at 168 hpi at 25 °C during 14 days of observation. To further verify the duration period of an antiviral state at different temperatures, qPCR and endpoint dilution assay were used to quantify the number of virus in fish challenged with RGNNV. The reduction of viral copy numbers and viral titers could be observed at 72 and 168 hpi. However, high viral copy numbers and viral titers could be detected at 168 hpi at 30 °C. These results demonstrate that temperatures influenced on the Mx expression profiles and the duration period of an antiviral state efficiently interfered with virus replication at different temperatures.

Viral coinfections in children with invasive pneumococcal disease.

BACKGROUND: Respiratory viruses contribute to the seasonal pattern of invasive pneumococcal disease (IPD), but the impact of viral coinfections on the clinical characteristics and outcomes of patients with IPD have not been well defined. OBJECTIVE: This study was designed to describe and compare the clinical presentations and outcomes of patients with IPD with or without viral coinfections. DESIGN/METHODS: Retrospective analyses of records of all children treated at Children's Medical Center Dallas (CMCD) for IPD from July 2005 to June 2008. Viral studies included viral direct fluorescent antibody staining and culture. For comparisons, patients were classified in 3 groups: with positive, negative, and no viral studies performed. RESULTS: A total of 129 patients were admitted to CMCD with IPD during the 3 year study; 57% were male. Ages ranged from 2 months to 18 years (median 25 months) and 48% were <2 years. Viral studies were performed in 82 (63%) patients, and 28 (34%) had positive results. The most common viruses isolated were influenza (7, 25%), rhinoviruses (6, 21%), adenoviruses (6, 21%), and RSV (5, 18%). Peaks of positive viral studies occurred in February and November which coincided with the peak numbers of patients admitted with IPD. Of 6 with adenovirus coinfection, 5 were admitted to Pediatric Intensive Care Unit (PICU). The most common pneumococcal serotypes were 19A (41, 32.5%), 7F (14, 11%), and 23A (13, 10.3%). Pneumonia (42%), bacteremia (22%), and meningitis (17%) were the most common clinical syndromes. There were no differences in duration of fever before admission, maximum temperatures during hospitalization and white blood cell counts, duration of fever and hospitalization between patients with positive and negative viral studies, but there was a trend for patient with positive viral studies to be admitted to PICU more frequently and to have longer PICU stay. Three of the 6 patients who died had documented viral coinfections (2 adenovirus, 1 parainfluenza 3), and all 3 had no underlying conditions. The other 3 patients who died had no viral studies performed. Duration of treatment ranged from 1 to -210 days (median 14), with no differences among the groups. CONCLUSIONS: Viral coinfections were common in children with IPD. Future prospective studies should include new PCR assays to characterize better the impact of viral coinfections in the occurrence and outcome of IPD.

Two-dimensional fractal growth properties of the filamentous fungus Cryphonectria parasitica: the effects of hypovirus infection.

Whole-colony two-dimensional fractal growth patterns produced by hypovirus-infected Cryphonectria parasitica (EP155/CHV1-EP713) were measured and compared with those produced by the isogenic virus-free strain (EP155) on solid medium. We have quantified statistically significant differences in the rates of expansion and spatial dynamics of colony growth between the two strains and concluded that fractal dimension is affected by the presence of the hypovirus. Therefore, fractal dimension measurement is an effective quantitative tool for testing the effects of mycovirus infection on fungal growth parameters.

Viral skin infections: diagnosis and treatment considerations.

Skin lesions are prominent features of many viral diseases. In some instances, characteristic skin lesions suggest a specific viral illness, the diagnosis of which can be quickly established by appropriate procedures. In addition to clinical manifestations, laboratory methods including virus isolation are used to diagnose viral infections. In viral diseases, prophylaxis has proved more successful than the specific treatment of established infection. However, recent progress in molecular biology has facilitated the development of new vaccines and new drugs to treat viral infections.

Viral hemorrhagic septicemia of rainbow trout: selection of a thermoresistant virus variant and comparison of polypeptide synthesis with the wild-type virus strain.

Serial passage of viral hemorrhagic septicemia virus at gradually increasing temperature selected for a variant virus that replicates at 25 degrees C and has a low pathogenicity for rainbow trout. Viral hemorrhagic septicemia virus-specific polypeptide synthesis was examined in epithelioma papulosum cyprini cells infected with either a wild-type strain or a thermoresistant variant. The wild-type N and M1 proteins were synthesized throughout the course of infection, whereas L, G, and M2 were more actively translated later in the replication cycle. The wild-type strain was more cytotoxic at 25 than at 14 degrees C despite the fact that no translation could be evidenced when the temperature was raised. When epithelioma papulosum cyprini cells were infected with the variant virus, the kinetic study was obstructed since protein synthesis was difficult to observe by the pulse method at a low multiplicity of infection and aborted when the multiplicity of infection was raised. The variant was less cytotoxic at 25 degrees C than wild-type virus.