Suppression of Penaeus merguiensis densovirus following oral delivery of live bacteria expressing dsRNA in the house cricket (Acheta domesticus) model

Efficient RNA interference method by feeding in Brachionus plicatilis (Rotifera)

Rotifers are small, ubiquitous invertebrate animals found throughout the world and have emerged as a promising model system for studying molecular mechanisms in the fields of experimental ecology, aquatic toxicology, and geroscience. However, the lack of efficient gene expression manipulation techniques has hindered the study of rotifers. In this study, we used the L4440 plasmid with two reverse-oriented T7 promoters, along with RNase-deficient E. coli HT115, to efficiently produce dsRNA and thereby present an efficient feeding-based RNAi method in Brachionus plicatilis. We targeted Bp-Ku70 & Ku80, key proteins in the DNA double-strand breaks repair pathway, and then subjected rotifers to UV radiation. We found that the mRNA expression, fecundity, as well as survival rate diminished significantly as a result of RNAi. Overall, our results demonstrate that the feeding-based RNAi method is a simple and efficient tool for gene knockdown in B. plicatilis, advancing their use as a model organism for biological research.

Bugs in Bugs: The Role of Probiotics and Prebiotics in Maintenance of Health in Mass-Reared Insects

Interactions between insects and their microbiota affect insect behaviour and evolution. When specific microorganisms are provided as a dietary supplement, insect reproduction, food conversion and growth are enhanced and health is improved in cases of nutritional deficiency or pathogen infection. The purpose of this review is to provide an overview of insect-microbiota interactions, to review the role of probiotics, their general use in insects reared for food and feed, and their interactions with the host microbiota. We review how bacterial strains have been selected for insect species reared for food and feed and discuss methods used to isolate and measure the effectiveness of a probiotic. We outline future perspectives on probiotic applications in mass-reared insects.

Expression and functional analysis of the Akt gene from Daphnia pulex

Daphnia pulex is a nutrient-rich freshwater crustacean with two different reproduction methods. Akt is a serine/threonine protein kinase that plays an important role in cell growth, survival, and lifespan regulation. To explore the function of Akt in the growth and aging process of Daphnia pulex, we cloned the cDNA sequence of the open reading frame (ORF) of the akt gene based on the bioinformatic analysis of the transcriptome data of D. pulex, and analyzed the structural features of the Akt protein. Gene silencing was performed using RNA interference (RNAi), and the expression of the Akt gene and protein before and after interference were analyzed using qPCR and western blotting. The results showed that the expression of akt in D. pulex at different ages showed a "W" pattern, being significantly higher at 20 days than at 10 days and 15 days (P < .05). The expression trend of Akt protein and mRNA were similar, with lower expression at a younger age (1-5 day), after which expression gradually increased from 10 days age, and showed no significant change after 25 days, which might be caused by a lag of protein translation. RNAi reduced the expression of the Akt gene and protein by at least 76%, and the survival rate and reproductive capacity of D. pulex were significantly lower in the RNAi group compared with those in the control group. This study provides a better understanding of the function of the akt gene in D. pulex.

Knockdown of Mythimna separata chitinase genes via bacterial expression and oral delivery of RNAi effectors

Background

RNAi (RNA interference) is a technology for silencing of target genes via sequence-specific manner. RNAi technology has been used for development of anti-pathogenic crops. In 2007, development of transgenic plants resistant to insect herbivore using RNAi technology was first reported, leading to a burst of efforts aimed at exploitation of RNAi mechanism and control strategy against variety of insect species based on this technique. Mythimna separata belongs to noctuidae family of lepidoptera and is posing threat to crops of economic importance. Recently, outbreaks of M. separata severely threatens corn production in Northern China, calling for new control approaches.

Results

Chitinase genes were chosen as the target genes as they were expressed predominantly in the gut tissue and were reported to be ideal silencing targets in several insect species. Interfering sequences against the target genes were cloned into the L4440 vector to produce sequence specific dsRNAs (double-stranded RNAs). Recombinant L4440 vectors were transformed into Escherichia coli strain HT115 (DE3) which was defective in dsRNA degradation activity, so preserving the dsRNA from degradation by cellular machinery. The bacteria were mixed with artificial diet and were fed to M. separata. We showed that oral delivery of bacterially expressed dsRNA would lead to RNAi effects in the recipient insect. Quantitative real-time PCR results showed that expression level of target MseChi1 and MseChi2 genes in gut tissue of M. separata were down-regulated after oral delivery of engineered bacteria expressing the corresponding dsRNA. Sequence-specific siRNA (small interfering RNA) was detected in recipient insects, supporting the existence of siRNA-mediated silencing effects in M. separata. Furthermore, knockdown of MseChi1 and MseChi2 resulted in increased mortality and reduced body weight of the feeding larvae.

Conclusion

We reported a simple and low cost experimental procedure to silence M. separata endogenous gene expression. Our research provides both an experimental foundation for using RNAi technology to control M. separata and also a useful research tool for loss-of-function study of important developmental and regulatory genes in this insect species.

Electronic supplementary material

The online version of this article (doi:10.1186/s12896-017-0328-7) contains supplementary material, which is available to authorized users.

Viruses of insects reared for food and feed

The use of insects as food for humans or as feed for animals is an alternative for the increasing high demand for meat and has various environmental and social advantages over the traditional intensive production of livestock. Mass rearing of insects, under insect farming conditions or even in industrial settings, can be the key for a change in the way natural resources are utilized in order to produce meat, animal protein and a list of other valuable animal products. However, because insect mass rearing technology is relatively new, little is known about the different factors that determine the quality and yield of the production process. Obtaining such knowledge is crucial for the success of insect-based product development. One of the issues that is likely to compromise the success of insect rearing is the outbreak of insect diseases. In particular, viral diseases can be devastating for the productivity and the quality of mass rearing systems. Prevention and management of viral diseases imply the understanding of the different factors that interact in insect mass rearing. This publication provides an overview of the known viruses in insects most commonly reared for food and feed. Nowadays with large-scale sequencing techniques, new viruses are rapidly being discovered. We discuss factors affecting the emergence of viruses in mass rearing systems, along with virus transmission routes. Finally we provide an overview of the wide range of measures available to prevent and manage virus outbreaks in mass rearing systems, ranging from simple sanitation methods to highly sophisticated methods including RNAi and transgenics.

Development of an efficient RNA interference method by feeding for the microcrustacean Daphnia

Background

RNA interference (RNAi) is an important molecular tool for analysis of gene function in vivo. Daphnia, a freshwater microcrustacean, is an emerging model organism for studying cellular and molecular processes involved in aging, development, and ecotoxicology especially in the context of environmental variation. However, in spite of the availability of a fully sequenced genome of Daphnia pulex, meaningful mechanistic studies have been hampered by a lack of molecular techniques to alter gene expression. A microinjection method for gene knockdown by RNAi has been described but the need for highly specialized equipment as well as technical expertise limits the wider application of this technique. In addition to being expensive and technically challenging, microinjections can only target genes expressed during embryonic stages, thus making it difficult to achieve effective RNAi in adult organisms.

Results

In our present study we present a bacterial feeding method for RNAi in Daphnia. We used a melanic Daphnia species (Daphnia melanica) that exhibits dark pigmentation to target phenoloxidase, a key enzyme in the biosynthesis of melanin. We demonstrate that our RNAi method results in a striking phenotype and that the phenoloxidase mRNA expression and melanin content, as well as survival following UV insults, are diminished as a result of RNAi.

Conclusions

Overall, our results establish a new method for RNAi in Daphnia that significantly advances further use of Daphnia as a model organism for functional genomics studies. The method we describe is relatively simple and widely applicable for knockdown of a variety of genes in adult organisms.

Emerging strategies for RNA interference (RNAi) applications in insects

RNA interference (RNAi) in insects is a gene regulatory process that also plays a vital role in the maintenance and in the regulation of host defenses against invading viruses. Small RNAs determine the specificity of the RNAi through precise recognition of their targets. These small RNAs in insects comprise small interfering RNAs (siRNAs), micro RNAs (miRNAs) and Piwi interacting RNAs (piRNAs) of various lengths. In this review, we have explored different forms of the RNAi inducers that are presently in use, and their applications for an effective and efficient fundamental and practical RNAi research with insects. Further, we reviewed trends in next generation sequencing (NGS) technologies and their importance for insect RNAi, including the identification of novel insect targets as well as insect viruses. Here we also describe a rapidly emerging trend of using plant viruses to deliver the RNAi inducer molecules into insects for an efficient RNAi response.

Systemic RNA interference in locusts: reverse genetics and possibilities for locust pest control

RNA interference (RNAi) is a biological process triggered by double stranded (ds)RNA that results in sequence-dependent mRNA degradation. Because of its high specificity, this post-transcriptional gene silencing mechanism is a widely used tool for reverse genetics in several insect species. In particular, locusts possess a very robust and sensitive RNAi response that has already been exploited to investigate a diverse range of important physiological processes. These orthopteran insects constitute important model organisms in several areas of entomology, but they can also become voracious swarming pests that threaten the agricultural production in large parts of the world. In comparison to the widely applied chemical insecticides, the RNAi-technology could contribute to the development of a novel generation of insecticides, with high species-specificity. In this article, we discuss the potential of the RNAi-technology in loss of function studies in locusts, as well as to control locust populations.

Protection of Macrobrachium rosenbergii against white tail disease by oral administration of bacterial expressed and encapsulated double-stranded RNA

White tail disease (WTD) of cultured Macrobrachium rosenbergii is caused by M. rosenbergii nodavirus (MrNV) and an extra small virus (XSV), both present together, and the mortality rate can be as high as 100% within 2 or 3 days of infection. Possible protection of M. rosenbergii against WTD by oral administration of bacterial expressed and encapsulated double-stranded RNA (dsRNA) was studied. Juvenile M. rosenbergii were fed with the feed coated with inactivated bacteria encapsulated dsRNA of MrNV and XSV genes individually and in combination for 7 days followed by challenge with WTD causing agents at 24 h and 72 h post-feeding. Test animals fed with a combination of dsRNA of MrNV and XSV capsid genes showed the highest relative percent survival (RPS) when compared to other treatments with RPS of 80% and 75% at 24 and 72 h respectively. One hundred percent mortality was observed in test animals fed with control dsRNA coated feed. Although in the literature, injection is the most common method used to deliver dsRNA, this study shows that oral administration is effective, feasible and economical.