Processing by RNase 1 forms tRNA halves and distinct Y RNA fragments in the extracellular environment.

Extracellular RNAs participate in intercellular communication, and are being studied as promising minimally invasive diagnostic markers. Several studies in recent years showed that tRNA halves and distinct Y RNA fragments are abundant in the extracellular space, including in biofluids. While their regulatory and diagnostic potential has gained a substantial amount of attention, the biogenesis of these extracellular RNA fragments remains largely unexplored. Here, we demonstrate that these fragments are produced by RNase 1, a highly active secreted nuclease. We use RNA sequencing to investigate the effect of a null mutation of RNase 1 on the levels of tRNA halves and Y RNA fragments in the extracellular environment of cultured human cells. We complement and extend our RNA sequencing results with northern blots, showing that tRNAs and Y RNAs in the non-vesicular extracellular compartment are released from cells as full-length precursors and are subsequently cleaved to distinct fragments. In support of these results, formation of tRNA halves is recapitulated by recombinant human RNase 1 in our in vitro assay. These findings assign a novel function for RNase 1, and position it as a strong candidate for generation of tRNA halves and Y RNA fragments in biofluids.

Cellular and Molecular Immune Response to Chikungunya Virus Infection.

Chikungunya virus (CHIKV) is a re-emergent arthropod-borne virus (arbovirus) that causes a disease characterized primarily by fever, rash and severe persistent polyarthralgia. In the last decade, CHIKV has become a serious public health problem causing several outbreaks around the world. Despite the fact that CHIKV has been around since 1952, our knowledge about immunopathology, innate and adaptive immune response involved in this infectious disease is incomplete. In this review, we provide an updated summary of the current knowledge about immune response to CHIKV and about soluble immunological markers associated with the morbidity, prognosis and chronicity of this arbovirus disease. In addition, we discuss the progress in the research of new vaccines for preventing CHIKV infection and the use of monoclonal antibodies as a promising therapeutic strategy.

Vulnerability of primitive human placental trophoblast to Zika virus.

Infection of pregnant women by Asian lineage strains of Zika virus (ZIKV) has been linked to brain abnormalities in their infants, yet it is uncertain when during pregnancy the human conceptus is most vulnerable to the virus. We have examined two models to study susceptibility of human placental trophoblast to ZIKV: cytotrophoblast and syncytiotrophoblast derived from placental villi at term and colonies of trophoblast differentiated from embryonic stem cells (ESC). The latter appear to be analogous to the primitive placenta formed during implantation. The cells from term placentas, which resist infection, do not express genes encoding most attachment factors implicated in ZIKV entry but do express many genes associated with antiviral defense. By contrast, the ESC-derived trophoblasts possess a wide range of attachment factors for ZIKV entry and lack components of a robust antiviral response system. These cells, particularly areas of syncytiotrophoblast within the colonies, quickly become infected, produce infectious virus and undergo lysis within 48 h after exposure to low titers (multiplicity of infection > 0.07) of an African lineage strain (MR766 Uganda: ZIKVU) considered to be benign with regards to effects on fetal development. Unexpectedly, lytic effects required significantly higher titers of the presumed more virulent FSS13025 Cambodia (ZIKVC). Our data suggest that the developing fetus might be most vulnerable to ZIKV early in the first trimester before a protective zone of mature villous trophoblast has been established. Additionally, MR766 is highly trophic toward primitive trophoblast, which may put the early conceptus of an infected mother at high risk for destruction.

Vulnerability of primitive human placental trophoblast to Zika virus

Infection of pregnant women by Asian lineage strains of Zika virus (ZIKV) has been linked to brain abnormalities in their infants, yet it is uncertain when during pregnancy the human conceptus is most vulnerable to the virus. We have examined two models to study susceptibility of human placental trophoblast to ZIKV: cytotrophoblast and syncytiotrophoblast derived from placental villi at term and colonies of trophoblast differentiated from embryonic stem cells (ESC). The latter appear to be analogous to the primitive placenta formed during implantation. The cells from term placentas, which resist infection, do not express genes encoding most attachment factors implicated in ZIKV entry but do express many genes associated with antiviral defense. By contrast, the ESC-derived trophoblasts possess a wide range of attachment factors for ZIKV entry and lack components of a robust antiviral response system. These cells, particularly areas of syncytiotrophoblast within the colonies, quickly become infected, produce infectious virus and undergo lysis within 48 h after exposure to lowtiters (multiplicity of infection > 0.07) of an African lineage strain (MR766 Uganda: ZIKV(U)) considered to be benignwith regards to effects on fetal development. Unexpectedly, lytic effects required significantly higher titers of the presumed more virulent FSS13025 Cambodia (ZIKV(C)). Our data suggest that the developing fetus might be most vulnerable to ZIKV early in the first trimester before a protective zone of mature villous trophoblast has been established. Additionally, MR766 is highly trophic toward primitive trophoblast, which may put the early conceptus of an infected mother at high risk for destruction.

HIPSTR and thousands of lncRNAs are heterogeneously expressed in human embryos, primordial germ cells and stable cell lines.

Eukaryotic genomes are transcribed into numerous regulatory long non-coding RNAs (lncRNAs). Compared to mRNAs, lncRNAs display higher developmental stage-, tissue-, and cell-subtype-specificity of expression, and are generally less abundant in a population of cells. Despite the progress in single-cell-focused research, the origins of low population-level expression of lncRNAs in homogeneous populations of cells are poorly understood. Here, we identify HIPSTR (Heterogeneously expressed from the Intronic Plus Strand of the TFAP2A-locus RNA), a novel lncRNA gene in the developmentally regulated TFAP2A locus. HIPSTR has evolutionarily conserved expression patterns, its promoter is most active in undifferentiated cells, and depletion of HIPSTR in HEK293 and in pluripotent H1BP cells predominantly affects the genes involved in early organismal development and cell differentiation. Most importantly, we find that HIPSTR is specifically induced and heterogeneously expressed in the 8-cell-stage human embryos during the major wave of embryonic genome activation. We systematically explore the phenomenon of cell-to-cell variation of gene expression and link it to low population-level expression of lncRNAs, showing that, similar to HIPSTR, the expression of thousands of lncRNAs is more highly heterogeneous than the expression of mRNAs in the individual, otherwise indistinguishable cells of totipotent human embryos, primordial germ cells, and stable cell lines.

Characterization of HIPSTR highlights the heterogeneous expression pattern of lncRNAs in human embryos and stable cell lines / Caracterização do HIPSTR destaca o padrão de expressão heterogênea de IncRNAs em embriões humanos e linhagens estáveis de células

There is a growing appreciation that eukaryotic genomes are transcribed into numerous, previously undetected - and thus uncharacterized regulatory long non-coding RNAs (lncRNAs). Recent studies are primarily focused on lncRNAs transcribed from intergenic regions and enhancers, leaving antisense lncRNAs the least studied group of lncRNAs. At the same time, antisense transcription occurs in up to 74 % of human gene loci, frequently - from the opposite strand of genes encoding proteins involved in regulation of transcription. Here, we identified HIPSTAR (Heterogeneously expressed from the Intronic Plus Strand of the TFAP2A-locus RNA), a novel conserved lncRNA that is transcribed antisense to the TFAP2A gene. Unlike previously reported antisense lncRNAs, HIPSTR expression does not correlate with the expression of its antisense counterpart. Although HIPSTAR and TFAP2A are co-expressed in in vitro derived neural crest and trophoblast cells, only HIPSTAR and not TFAP2A is specifically expressed in a subset of cells within 8-cell- and morula-stage human embryos. We show that, similar to HIPSTAR, in the individual cells of developing human embryos or of stable cell lines the expression of lncRNAs is more highly heterogeneous than the expression of mRNAs. Finally, we demonstrate that HIPSTAR depletion in HEK293 and H1BP, a human embryonic stem cell line, predominantly affects the expression levels of genes involved in early organismal development and cell differentiation. Together, we show that expression of HIPSTAR and hundreds other lncRNAs is highly heterogeneous in human embryos and cell lines. We use HIPSTAR to exemplify the functional relevance of lncRNAs with heterogeneous and developmental stage-specific expression patterns

Tem sido cada vez mais reconhecido que a transcrição dos genomas eucarióticos produz múltiplos transcritos novos, anteriormente não detectados e ainda não caracterizados, sendo que a maioria é constituida de RNAs não-codificantes longos (lncRNAs) regulatórios. Estudos recentes estão focados principalmente nos lncRNAs transcritos de regiões intergênicas e enhancers; assim, o grupo dos lncRNAs antisenso permanece o menos estudado de todos. Ao mesmo tempo, a transcrição antisenso ocorre em até 74% dos loci de genes humanos, frequentemente - a partir da fita oposta de genes que codificam proteínas envolvidas na regulação da transcrição. No presente trabalho, nós identificamos HIPSTR (Heterogeneously expressed from the Intronic Plus Strand of the TFAP2A-locus RNA), um lncRNA novo conservado que é transcrito a partir da fita antisenso do gene TFAP2A. Ao contrário do anteriormente relatado para os lncRNAs antisenso, a expressão de HIPSTR não está correlacionada com a expressão do gene da fita oposta. HIPSTR e TFAP2A são co-expressos em células da crista neural e em trofoblastos derivadas in vitro, mas somente HIPSTR e não TFAP2A está especificamente expresso num subconjunto de células de embriões humanos nos estágios de 8-células e mórula. Mostramos que, semelhante a HIPSTR, a expressão de lncRNAs é mais altamente heterogênea que a expressão de mRNAs em células individuais de embriões humanos em desenvolvimento ou em linhagens estáveis de células. Finalmente, nós demonstramos que a depleção de HIPSTAR em células HEK293 e H1BP, uma linhagem de células tronco embrionárias humanas, afeta predominantemente os níveis de genes envolvidos no início do desenvolvimento do organismo e na diferenciação de células. No conjunto, nós mostramos que a expressão de HIPSTR e de centenas de outros lncRNAs é altamente heterogênea em embriões humanos e linhagens celulares. Usamos HIPSTR para exemplificar a relevância funcional de lncRNAs com padrões de expressão heterogêneos e estágio-de-desenvolvimento específicos

HIPSTR and thousands of lncRNAs are heterogeneously expressed in human embryos, primordial germ cells and stable cell lines

Eukaryotic genomes are transcribed into numerous regulatory long non-coding RNAs (lncRNAs). Compared to mRNAs, lncRNAs display higher developmental stage-, tissue-, and cell-subtype-specificity of expression, and are generally less abundant in a population of cells. Despite the progress in single-cell-focused research, the origins of low population-level expression of lncRNAs in homogeneous populations of cells are poorly understood. Here, we identify HIPSTR (Heterogeneously expressed from the Intronic Plus Strand of the TFAP2A-locus RNA), a novel lncRNA gene in the developmentally regulated TFAP2A locus. HIPSTR has evolutionarily conserved expression patterns, its promoter is most active in undifferentiated cells, and depletion of HIPSTR in HEK293 and in pluripotent H1BP cells predominantly affects the genes involved in early organismal development and cell differentiation. Most importantly, we find that HIPSTR is specifically induced and heterogeneously expressed in the 8-cell-stage human embryos during the major wave of embryonic genome activation. We systematically explore the phenomenon of cell-to-cell variation of gene expression and link it to low population-level expression of lncRNAs, showing that, similar to HIPSTR, the expression of thousands of lncRNAs is more highly heterogeneous than the expression of mRNAs in the individual, otherwise indistinguishable cells of totipotent human embryos, primordial germ cells, and stable cell lines