Ne system to fight against virus invasion. As demonstrated in the present study, the Ago1A and Ago1B isoforms containing Ago1 fragment 2 provide the molecular basis for the shrimp antiviral defense. To our knowledge, our study was the first report on the roles of Ago isoforms that might be generated by alternative splicing from a single gene in host immunity against virus infection in invertebrates. Invertebrates might have evolved alternative splicing strategies to generate functionally different isoforms to fine-tune the host antiviral responses. In our study, Ago1A and Ago1B were shown to be involved in host immune responses against WSSV. It was revealed that the knockdown of Ago1B by a low concentration of siRNA-Ago1B significantly increased viral loads after virus challenge, suggesting that Ago1B was involved in the host defense against virusinfection. However, the silencing of Ago1B by siRNA-Ago1B at the high concentration resulted in up-regulation of Ago1A and the simultaneous up-regulation of Ago1A could compensate for the loss of Ago1B in the shrimp defense against WSSV infection. Furthermore, knockdown of Ago1A by siRNA-Ago1A at the high concentration led to a significant increase in WSSV copies, although the Ago1B mRNA levels were also up-regulated, suggesting that the up-regulation of Ago1B could not compensate for the depletion of Ago1A in shrimp antiviral immunity. Therefore, it could be inferred that the Ago1 isoforms (Ago1A and Ago1B) might be involved in different pathways to control WSSV replication in shrimp. The mechanism for the compensatory regulation of different Ago isoforms in the host antiviral immunity warranted further investigation. Overall, our study described the presence of three isoforms of the Ago1 protein in shrimp (M. japonicus) and investigated the roles of the different isoforms in antiviral shrimp response upon WSSV challenge. Silencing Ago 1A or Ago 1B significantly increased virus load compared to control shrimp (WSSV challenged only), indicating that Ago1A and Ago1B might play important roles in the host defense against virus infection. In contrast, silencing Ago 1C did not affect virus load, indicating that this isoform has no significant antiviral role. This study provided new insights into understanding the role of Ago 1 protein in antiviral response in invertebrates.Supporting InformationTable S1 Primers, probes and siRNAs used in this study.(DOC)Author ContributionsConceived and designed the experiments: XZ. Performed the experiments: TH. Analyzed the data: XZ TH. Contributed reagents/materials/analysis tools: XZ. Wrote the paper: TH XZ.
Genomic imprinting is an epigenetic phenomenon observed in eutherian mammals. For the large majority of autosomal genes, the two parental copies are both either transcribed or silent. However, in a small group of genes one copy is turned off in a parent-of-origin 4EGI-1 specific manner thereby resulting in monoallelic expression. These genes are called `imprinted’ because the silenced copy of the gene is epigenetically marked or imprinted in either the egg or the sperm [1]. Imprinted genes play important roles in development and growth both pre- and postnatally by purchase 256373-96-3 acting in fetal and placental tissues [2]. Interestingly, there appears to exist a general pattern whereby maternally expressed genes tend to limit embryonic growth and paternally expressed genes tend to promote growth. A model case for this striking scenario is the antagonistic action of Igf2 and Igf2r i.Ne system to fight against virus invasion. As demonstrated in the present study, the Ago1A and Ago1B isoforms containing Ago1 fragment 2 provide the molecular basis for the shrimp antiviral defense. To our knowledge, our study was the first report on the roles of Ago isoforms that might be generated by alternative splicing from a single gene in host immunity against virus infection in invertebrates. Invertebrates might have evolved alternative splicing strategies to generate functionally different isoforms to fine-tune the host antiviral responses. In our study, Ago1A and Ago1B were shown to be involved in host immune responses against WSSV. It was revealed that the knockdown of Ago1B by a low concentration of siRNA-Ago1B significantly increased viral loads after virus challenge, suggesting that Ago1B was involved in the host defense against virusinfection. However, the silencing of Ago1B by siRNA-Ago1B at the high concentration resulted in up-regulation of Ago1A and the simultaneous up-regulation of Ago1A could compensate for the loss of Ago1B in the shrimp defense against WSSV infection. Furthermore, knockdown of Ago1A by siRNA-Ago1A at the high concentration led to a significant increase in WSSV copies, although the Ago1B mRNA levels were also up-regulated, suggesting that the up-regulation of Ago1B could not compensate for the depletion of Ago1A in shrimp antiviral immunity. Therefore, it could be inferred that the Ago1 isoforms (Ago1A and Ago1B) might be involved in different pathways to control WSSV replication in shrimp. The mechanism for the compensatory regulation of different Ago isoforms in the host antiviral immunity warranted further investigation. Overall, our study described the presence of three isoforms of the Ago1 protein in shrimp (M. japonicus) and investigated the roles of the different isoforms in antiviral shrimp response upon WSSV challenge. Silencing Ago 1A or Ago 1B significantly increased virus load compared to control shrimp (WSSV challenged only), indicating that Ago1A and Ago1B might play important roles in the host defense against virus infection. In contrast, silencing Ago 1C did not affect virus load, indicating that this isoform has no significant antiviral role. This study provided new insights into understanding the role of Ago 1 protein in antiviral response in invertebrates.Supporting InformationTable S1 Primers, probes and siRNAs used in this study.(DOC)Author ContributionsConceived and designed the experiments: XZ. Performed the experiments: TH. Analyzed the data: XZ TH. Contributed reagents/materials/analysis tools: XZ. Wrote the paper: TH XZ.
Genomic imprinting is an epigenetic phenomenon observed in eutherian mammals. For the large majority of autosomal genes, the two parental copies are both either transcribed or silent. However, in a small group of genes one copy is turned off in a parent-of-origin specific manner thereby resulting in monoallelic expression. These genes are called `imprinted’ because the silenced copy of the gene is epigenetically marked or imprinted in either the egg or the sperm [1]. Imprinted genes play important roles in development and growth both pre- and postnatally by acting in fetal and placental tissues [2]. Interestingly, there appears to exist a general pattern whereby maternally expressed genes tend to limit embryonic growth and paternally expressed genes tend to promote growth. A model case for this striking scenario is the antagonistic action of Igf2 and Igf2r i.