Publications by authors named "Vincent Caval"

Article Synopsis
  • Usutu virus (USUV) and West Nile virus (WNV) are mosquito-borne flaviviruses that primarily affect wild birds but can cause serious neurological issues in humans.
  • These viruses are suppressed by type I interferon (IFN), which hinders their replication and spread, but USUV shows a unique resistance to the ISG20 gene, which is involved in this suppression.
  • The study reveals that the USUV genome's resistance to ISG20 is due to a specific sequence in its 3' untranslated region, suggesting that this feature could potentially be transferred to other flaviviruses to help them evade host defenses.
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Polioviruses (PVs) are positive strand RNA viruses responsible for poliomyelitis. Many PVs have been isolated and phenotypically characterized in the 1940s-50s for the purpose of identifying attenuated strains that could be used as vaccine strains. Among these historical PVs, only few are genetically characterized.

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Investigations of cellular responses to viral infection are commonly performed on mixed populations of infected and uninfected cells or using single-cell RNA sequencing, leading to inaccurate and low-resolution gene expression interpretations. Here, we performed deep polyA+ transcriptome analyses and novel RNA profiling of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infected lung epithelial cells, sorted based on the expression of the viral spike (S) protein. Infection caused a massive reduction in mRNAs and long non-coding RNAs (lncRNAs), including transcripts coding for antiviral factors, such as interferons (IFNs).

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The mechanisms utilized by different flaviviruses to evade antiviral functions of interferons are varied and incompletely understood. Using virological approaches, biochemical assays, and mass spectrometry analyses, we report here that the NS5 protein of tick-borne encephalitis virus (TBEV) and Louping Ill virus (LIV), two related tick-borne flaviviruses, antagonize JAK-STAT signaling through interactions with the tyrosine kinase 2 (TYK2). Co-immunoprecipitation (co-IP) experiments, yeast gap-repair assays, computational protein-protein docking and functional studies identify a stretch of 10 residues of the RNA dependent RNA polymerase domain of tick-borne flavivirus NS5, but not mosquito-borne NS5, that is critical for interactions with the TYK2 kinase domain.

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Viruses have evolved countless mechanisms to subvert and impair the host innate immune response. Measles virus (MeV), an enveloped, non-segmented, negative-strand RNA virus, alters the interferon response through different mechanisms, yet no viral protein has been described as directly targeting mitochondria. Among the crucial mitochondrial enzymes, 5'-aminolevulinate synthase (ALAS) is an enzyme that catalyzes the first step in heme biosynthesis, generating 5'-aminolevulinate from glycine and succinyl-CoA.

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Article Synopsis
  • A specific genetic variation in the APOBEC3C enzyme, affecting a single amino acid (serine to isoleucine at position 188), is found in around 10% of African populations and significantly boosts the enzyme's ability to fight off HIV-1 and SIV.
  • The study observed that this variant, APOBEC3CS188I, can edit the hepatitis B virus (HBV) both in lab cultures and in infected individuals.
  • Utilizing next-generation sequencing, researchers discovered that this edited variant enhances activity in a specific DNA editing context (5'TpCpA to 5'TpTpA), marking a new understanding of the enzyme's function and potential implications for HBV and nuclear DNA.
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Article Synopsis
  • Herpes simplex virus type 1 (HSV-1) disrupts the structure and function of mitochondria through the viral protein UL12.5, causing mitochondrial fragmentation and the release of mitochondrial DNA (mtDNA) into the cytosol.
  • The presence of cytosolic mtDNA triggers immune responses, leading to an increase in type I interferon and the enzyme APOBEC3A, which is responsible for inducing mutations in mtDNA.
  • The study highlights how HSV-1 infection not only damages mitochondrial networks but also utilizes released mtDNA as a danger signal to stimulate inflammation and immune reactions.
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  • The human APOBEC3A (A3A) enzyme is a significant contributor to mutations in tumor DNA but shows a mismatch between its mRNA levels and protein presence after interferon stimulation in myeloid cells.
  • Researchers identified two new alternative proteins, A3Alt-L and A3Alt-S, which are generated from the APOBEC3A gene and are targeted to mitochondria.
  • These A3Alt proteins induce membrane depolarization and apoptosis, illustrating that a single gene can produce multiple proteins with distinct functions—one affecting the genome and the other impacting mitochondrial health.
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  • APOBEC3 enzymes, particularly A3A and A3B, are significantly upregulated in patients with Systemic Lupus Erythematosus (SLE), especially during disease flares and with high levels of interferon-α (IFN-α).
  • This upregulation, observed in a study of 57 SLE patients, was found in 14.9% of patients with a specific genetic polymorphism that enhances A3A, and it correlates with cellular DNA damage and low lymphocyte counts.
  • The findings suggest that high levels of A3A and A3B may promote cell death and inflammation in SLE, indicating that targeting these enzymes might help alleviate symptoms and reduce the formation
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Background: APOBEC1 (A1) enzymes are cytidine deaminases involved in RNA editing. In addition to this activity, a few A1 enzymes have been shown to be active on single stranded DNA. As two human ssDNA cytidine deaminases APOBEC3A (A3A), APOBEC3B (A3B) and related enzymes across the spectrum of placental mammals have been shown to introduce somatic mutations into nuclear DNA of cancer genomes, we explored the mutagenic threat of A1 cytidine deaminases to chromosomal DNA.

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Human cells are stressed by numerous mechanisms that can lead to leakage of mitochondrial DNA (mtDNA) to the cytoplasm and ultimately apoptosis. This agonist DNA constitutes a danger to the cell and is counteracted by cytoplasmic DNases and APOBEC3 cytidine deamination of DNA. To investigate APOBEC3 editing of leaked mtDNA to the cytoplasm, we performed a PCR analysis of APOBEC3 edited cytoplasmic mtDNA (cymtDNA) at the single cell level for primary CD4 T cells and the established P2 EBV blast cell line.

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The incidence of developing cancer should increase with the body mass, yet is not the case, a conundrum referred to as Peto's paradox. Elephants have a lower incidence of cancer suggesting that these animals have probably evolved different ways to protect themselves against the disease. The paradox is worth revisiting with the realization that most mammals encode an endogenous APOBEC3 cytidine deaminase capable of mutating single stranded DNA.

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APOBEC3 are cytidine deaminases that convert cytidine to uridine residues. APOBEC3A and APOBEC3B enzymes able to target genomic DNA are involved in oncogenesis of a sizeable proportion of human cancers. While the locus is conserved in mammals, it encodes from 1-7 genes.

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Foreign and self-cytoplasmic DNA are recognized by numerous DNA sensor molecules leading to the production of type I interferons. Such DNA agonists should be degraded otherwise cells would be chronically stressed. Most human APOBEC3 cytidine deaminases can initiate catabolism of cytoplasmic mitochondrial DNA.

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The APOBEC3 locus consists of seven genes (A3A-A3C, A3DE, A3F-A3H) that encode DNA cytidine deaminases. These enzymes deaminate single-stranded DNA, the result being DNA peppered with CG →TA mutations preferentially in the context of 5'TpC with the exception of APOBEC3G (A3G), which prefers 5'CpC dinucleotides. Hepatitis B virus (HBV) DNA is vulnerable to genetic editing by APOBEC3 cytidine deaminases, A3G being a major restriction factor.

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Article Synopsis
  • RNA delivery is a promising method for temporary gene expression in both research and therapies, but current methods need improved efficiency for primary cells and in vivo applications.
  • A new dimerization-independent MS2-driven RNA packaging system using MS2-Coat-retrovirus chimeras was developed to enhance retroviral RNA transfer and enable effective packaging of various RNAs.
  • This innovative approach successfully allowed for gene expression in mouse liver and editing in muscle cells, as well as activating bone-marrow stem cell differentiation, making these chimeric particles useful for multiple biological applications.
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The human APOBEC3A and APOBEC3B genes (A3A and A3B) encode DNA mutator enzymes that deaminate cytidine and 5-methylcytidine residues in single-stranded DNA (ssDNA). They are important sources of mutations in many cancer genomes which show a preponderance of CG->TA transitions. Although both enzymes can hypermutate chromosomal DNA in an experimental setting, only A3A can induce double strand DNA breaks, even though the catalytic domains of A3B and A3A differ by only 9% at the protein level.

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Human APOBEC3A (A3A) cytidine deaminase is a host enzyme that can introduce mutations into chromosomal DNA. As APOBEC3B (A3B) encodes a C-terminal catalytic domain ~91% identical to A3A, we examined its genotoxic potential as well as that of a highly prevalent chimaeric A3A-A3B deletion allele (ΔA3B), which is linked to a higher odds ratio of developing breast, ovarian and liver cancer. Interestingly, breast cancer genomes from ΔA3B(-/-) patients show a higher overall mutation burden.

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Article Synopsis
  • - The APOBEC3 gene cluster in humans produces enzymes that can mutate viral DNA, but recent studies show that APOBEC3A can also significantly alter nuclear DNA and cause breaks in the genome.
  • - APOBEC3A has a unique ability to deaminate a specific form of DNA called 5-methylcytidine in single-stranded DNA, making it distinct among these enzymes.
  • - Analysis of similar enzymes in various animal species (like monkeys, horses, and dogs) showed strong evolutionary conservation, indicating that their role in DNA modification is crucial and may have more benefits than risks, despite potential issues like cancer.
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The advent of infectious molecular clones of Hepatitis C virus (HCV) has unlocked the understanding of HCV life cycle. However, packaging of the genomic RNA, which is crucial to generate infectious viral particles, remains poorly understood. Molecular interactions of the domain 1 (D1) of HCV Core protein and HCV RNA have been described in vitro.

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