RESUMEN
Circulating extra-cellular microRNAs (miRNAs) have emerged as promising minimally invasive markers in human medicine. We evaluated miRNAs isolated from total plasma as biomarker candidates of a response to an abiotic stress (feed deprivation) in a livestock species. Two chicken lines selected for high (R+) and low (R-) residual feed intake were chosen as an experimental model because of their extreme divergence in feed intake and energy metabolism. Adult R+ and R- cocks were sampled after 16 hours of feed deprivation and again four hours after re-feeding. More than 292 million sequence reads were generated by small RNA-seq of total plasma RNA. A total of 649 mature miRNAs were identified; after quality filtering, 148 miRNAs were retained for further analyses. We identified 23 and 19 differentially abundant miRNAs between feeding conditions and between lines respectively, with only two miRNAs identified in both comparisons. We validated a panel of six differentially abundant miRNAs by RT-qPCR on a larger number of plasma samples and checked their response to feed deprivation in liver. Finally, we evaluated the conservation and tissue distribution of differentially abundant miRNAs in plasma across a variety of red jungle fowl tissues. We show that the chicken plasma miRNome reacts promptly to the alteration of the animal physiological condition driven by a feed deprivation stress. The plasma content of stress-responsive miRNAs is strongly influenced by the genetic background, with differences reflecting the phenotypic divergence acquired through long-term selection, as evidenced by the profiles of conserved miRNAs with a regulatory role in energy metabolism (gga-miR-204, gga-miR-let-7f-5p and gga-miR-122-5p). These results reinforce the emerging view in human medicine that even small genetic differences can have a considerable impact on the resolution of biomarker studies, and provide support for the emerging interest in miRNAs as potential novel and minimally invasive biomarkers for livestock species.
Asunto(s)
Pollos/genética , MicroARNs/sangre , Estrés Fisiológico , Transcriptoma , Animales , Análisis por Conglomerados , Ontología de Genes , MicroARNs/genética , Anotación de Secuencia Molecular , Interferencia de ARNRESUMEN
We are currently facing a global threat caused by a highly pathogenic avian H5N1 influenza virus (hpH5N1). Death occurs in 48 h in infected chickens, suggesting that they fail to eliminate the virus. Little is known about the immune response in chickens after hpH5N1 infection, or how the virus is evolving to modify and evade host protective responses. Therefore, to better understand the chicken immune response following hpH5N1 infection, we set up an experimental infection of chickens with an hpH5N1 strain, and quantified the mRNA expression of several cytokines and antiviral proteins at different time points post-infection. We show here that a weak host immune response is observed in vivo, in spite of the induction of IL-6, myxovirus resistance protein (Mx), and protein kinase R (PKR). This weak immune response, probably due in part to the absence of type I interferon, was not sufficient to counteract the hpH5N1 virus and protect the chicken from death.
Asunto(s)
Pollos/inmunología , Proteínas de Unión al GTP/fisiología , Evasión Inmune , Subtipo H5N1 del Virus de la Influenza A/patogenicidad , Gripe Aviar/inmunología , Proteínas Quinasas/fisiología , Animales , Pollos/virología , Citocinas/biosíntesis , Citocinas/genética , Femenino , Proteínas de Unión al GTP/biosíntesis , Proteínas de Unión al GTP/genética , Regulación de la Expresión Génica , Inmunidad Innata/inmunología , Subtipo H5N1 del Virus de la Influenza A/inmunología , Gripe Aviar/prevención & control , Intestinos/virología , Pulmón/virología , Proteínas de Resistencia a Mixovirus , Especificidad de Órganos , Proteínas Quinasas/biosíntesis , Proteínas Quinasas/genética , ARN Mensajero/biosíntesis , ARN Mensajero/genética , ARN Viral/análisis , Bazo/virología , VirulenciaRESUMEN
Recent large-scale cDNA cloning studies have shown that a significant proportion of the transcripts expressed from vertebrate genomes do not appear to encode protein. Moreover, it was reported in mammals (human and mice) that these non-coding transcripts are expressed and regulated by mechanisms similar to those involved in the control of protein-coding genes. We have produced a collection of cDNA sequences from immunologically active tissues with the aim of discovering chicken genes involved in immune mechanisms, and we decided to explore the non-coding component of these immune-related libraries. After finding known non-coding RNAs (miRNA, snRNA, snoRNA), we identified new putative mRNA-like non-coding RNAs. We characterised their expression profiles in immune-related samples. Some of them showed changes in expression following viral infections. As they exhibit patterns of expression that parallel the behaviour of protein-coding RNAs in immune tissues, our study suggests that they could play an active role in the immune response.