The evolution of opsin genes in five species of mirid bugs: duplication of long-wavelength opsins and loss of blue-sensitive opsins.

BACKGROUND: Color vision and phototactic behavior based on opsins are important for the fitness of insects because of their roles in foraging and mate choice. Related topics, including the duplication and loss of opsin genes, have been well investigated in insect orders such as Coleoptera, Lepidoptera, Hymenoptera, Odonata and Orthoptera, and the findings have been used to develop pest management strategies involving light trapping. Mirid bugs of Hemiptera, which are pests that cause heavy economic losses, show capacity for color discrimination and phototaxis. However, the opsins in mirid bugs remain uncharacterized. Herein, we examined five species to investigate the evolution of opsins in the family Miridae. RESULTS: Using RNA-seq, we identified several contigs showing high identity with opsins, including four contigs in Apolygus lucorum and three contigs each in Adelphocoris suturalis, Adelphocoris fasciaticollis, Adelphocoris lineolatus and Nesidiocoris tenuis. Phylogenetic analyses indicated that one of these genes clustered with ultraviolet-sensitive (UV) opsins and that the others clustered with long-wavelength (LW) opsins, suggesting that duplication of LW opsins and loss of blue light-sensitive (B) opsins occurred in mirid bugs. The existence of introns in the LW opsins of mirid bugs suggested that the duplication events were DNA based. Both LW1 and LW2 opsins of mirid bugs were found to be under strong purifying selection. The LW1 opsins were significantly more highly expressed than the LW2 and UV opsins. CONCLUSIONS: We identified the opsins of mirid bugs using five selected mirid species as a representative sample. Phylogenetic analyses clustered one of the genes with UV opsins and the others with LW opsins, suggesting the occurrence of LW opsin duplication and B opsin loss during the evolution of mirid bugs. Intron detection suggested that the identified duplication event was DNA based. The evidence of strong purifying selection and the relatively high expression levels suggested that these opsins exhibit fundamental functions in mirid bugs.

Osmolality as a Novel Mechanism Explaining Diet Effects on the Outcome of Infection with a Blood Parasite.

Recent research has suggested that the outcome of host-parasite interactions is dependent on the diet of the host, but most previous studies have focused on "top-down" mechanisms, i.e., how the host's diet improves the host immune response to drive down the parasite population and improve host fitness. In contrast, the direct impacts of host nutrition on parasite fitness and the mechanisms underpinning these effects are relatively unexplored. Here, using a model host-pathogen system (Spodoptera littoralis caterpillars and Xenorhabdus nematophila, an extracellular bacterial blood parasite), we explore the effects of host dietary macronutrient balance on pathogen growth rates both in vivo and in vitro, allowing us to compare pathogen growth rates both in the presence and absence of the host immune response. In vivo, high dietary protein resulted in lower rates of bacterial establishment, slower bacterial growth, higher host survival, and slower speed of host death; in contrast, the energy content and amount of carbohydrate in the diet explained little variation in any measure of pathogen or host fitness. In vitro, we show that these effects are largely driven by the impact of host dietary protein on host hemolymph (blood) osmolality (i.e., its concentration of solutes), with bacterial growth being slower in protein-rich, high-osmolality hemolymphs, highlighting a novel "bottom-up" mechanism by which host diet can impact both pathogen and host fitness.

Diet modulates the relationship between immune gene expression and functional immune responses.

Nutrition is vital to health and the availability of resources has long been acknowledged as a key factor in the ability to fight off parasites, as investing in the immune system is costly. Resources have typically been considered as something of a "black box", with the quantity of available food being used as a proxy for resource limitation. However, food is a complex mixture of macro- and micronutrients, the precise balance of which determines an animal's fitness. Here we use a state-space modelling approach, the Geometric Framework for Nutrition (GFN), to assess for the first time, how the balance and amount of nutrients affects an animal's ability to mount an immune response to a pathogenic infection. Spodoptera littoralis caterpillars were assigned to one of 20 diets that varied in the ratio of macronutrients (protein and carbohydrate) and their calorie content to cover a large region of nutrient space. Caterpillars were then handled or injected with either live or dead Xenorhabdus nematophila bacterial cells. The expression of nine genes (5 immune, 4 non-immune) was measured 20 h post immune challenge. For two of the immune genes (PPO and Lysozyme) we also measured the relevant functional immune response in the hemolymph. Gene expression and functional immune responses were then mapped against nutritional intake. The expression of all immune genes was up-regulated by injection with dead bacteria, but only those in the IMD pathway (Moricin and Relish) were substantially up-regulated by both dead and live bacterial challenge. Functional immune responses increased with the protein content of the diet but the expression of immune genes was much less predictable. Our results indicate that diet does play an important role in the ability of an animal to mount an adequate immune response, with the availability of protein being the most important predictor of the functional (physiological) immune response. Importantly, however, immune gene expression responds quite differently to functional immunity and we would caution against using gene expression as a proxy for immune investment, as it is unlikely to be reliable indicator of the immune response, except under specific dietary conditions.

Duplication and expression of horizontally transferred polygalacturonase genes is associated with host range expansion of mirid bugs.

BACKGROUD: Horizontal gene transfer and gene duplication are two major mechanisms contributing to the evolutionary adaptation of organisms. Previously, polygalacturonase genes (PGs) were independently horizontally transferred and underwent multiple duplications in insects (e.g., mirid bugs and beetles). Here, we chose three phytozoophagous mirid bugs (Adelphocoris suturalis, A. fasciaticollis, A. lineolatus) and one zoophytophagous mirid bug (Nesidiocoris tenuis) to detect whether the duplication, molecular evolution, and expression levels of PGs were related to host range expansion in mirid bugs. RESULTS: By RNA-seq, we reported 30, 20, 19 and 8 PGs in A. suturalis, A. fasciaticollis, A. lineolatus and N. tenuis, respectively. Interestingly, the number of PGs was significantly positive correlation to the number of host plants (P = 0.0339) in mirid bugs. Most PGs (> 17) were highly expressed in the three phytozoophagous mirid bugs, while only one PG was relatively highly expressed in the zoophytophagous mirid bug. Natural selection analysis clearly showed that a significant relaxation of selection pressure acted on the PGs in zoophytophagous mirid bugs (K = 0.546, P = 0.0158) rather than in phytozoophagous mirid bugs (K = 1, P = 0.92), suggesting a function constraint of PGs in phytozoophagous mirid bugs. CONCLUSION: Taken together with gene duplication, molecular evolution, and expression levels, our results suggest that PGs are more strictly required by phytozoophagous than by zoophytophagous mirid bugs and that the duplication of PGs is associated with the expansion of host plant ranges in mirid bugs.

Characterization of a novel RNA virus from Nesidiocoris tenuis related to members of the genus Iflavirus.

The complete genome of a novel virus from Nesidiocoris tenuis was determined by RNA-seq and rapid amplification of cDNA ends. This virus has a single-stranded RNA genome of 10633 nucleotides (nt) in length, not including the poly(A) tail, and contains two putative open reading frames (ORFs). ORF1 encodes a polypeptide of 1320 amino acids (aa) with a predicted molecular mass of 147.92 kDa and theoretical isoelectric point (pI) of 6.96. ORF2 encodes a polypeptide of 1728 aa with a predicted molecular mass of 197.09 kDa and pI of 6.73. Phylogenetic analysis with the deduced aa sequences of the conserved RNA dependent RNA polymerase domain as well as whole genome nt sequences indicated that the virus clusters with viruses classified within the genus Iflavirus, with a high bootstrap value in the maximum-likelihood and neighbor-joining trees. However, this virus has a distinct genome structure with two ORFs, iflaviruses normally having one, suggesting the virus might be a prototype of a new genus. We named the virus isolate Nesidiocoris tenuis virus 1 (NtV-1). The prevalence of NtV-1 infection in wild samples of N. tenuis was at a low level (7.32%, 6 positive in 82 samples), suggesting a possible harmful effect to its host.

Immune stimulation reduces sleep and memory ability in Drosophila melanogaster.

Psychoneuroimmunology studies the increasing number of connections between neurobiology, immunology and behaviour. We demonstrate the effects of the immune response on two fundamental behaviours: sleep and memory ability in Drosophila melanogaster. We used the Geneswitch system to upregulate peptidoglycan receptor protein (PGRP) expression, thereby stimulating the immune system in the absence of infection. Geneswitch was activated by feeding the steroid RU486, to the flies. We used an aversive classical conditioning paradigm to quantify memory and measures of activity to infer sleep. Immune stimulated flies exhibited reduced levels of sleep, which could not be explained by a generalised increase in waking activity. Immune stimulated flies also showed a reduction in memory abilities. These results lend support to Drosophila as a model for immune-neural interactions and provide a possible role for sleep in the interplay between the immune response and memory.