Bimalendu B. Nath

Insect trehalase: Physiological significance and potential applications

Trehalose, a non-reducing disaccharide, is widespread throughout the biological world. It is the major blood sugar in insects playing a crucial role as an instant source of energy and in dealing with abiotic stresses. The hydrolysis of trehalose is under the enzymatic control of trehalase. The enzyme trehalase is gaining interest in insect physiology as it regulates energy metabolism and glucose generation via trehalose catabolism. The two forms of insect trehalase namely, Tre-1 and Tre-2, are important in energy supply, growth, metamorphosis, stress recovery, chitin synthesis and insect flight. Insect trehalase has not been reviewed in depth and the information available is quite scattered. The present mini review discusses our recent understanding of the regulation, mechanism and biochemical characterization of insect trehalase with respect to its physiological role in vital life functions. We also highlight the molecular and biochemical properties of insect trehalase that makes it amenable to competitive inhibition by most glycosidase inhibitors. Due to its crucial role in carbon metabolism in insects, application of inhibitors against trehalose can form a promising area towards formulating strategies for insect pest control.

Increased level of superoxide dismutase (SOD) activity in larvae of Chironomus ramosus (Diptera: Chironomidae) subjected to ionizing radiation

A battery of enzymes from the eukaryotic antioxidant defense system was measured in salivary gland and in whole body extract of fourth instar larvae of Chironomus ramosus with an objective of finding any clue for the dipteran insects capacity to tolerate heavy doses of ionizing radiation. Levels of activity of antioxidant enzymes, superoxide dismutase (SOD), catalase (CAT), glutathione reductase (GR), and glutathione peroxidase (GSH-Px) were quantified in 30 days old larvae exposed to LD(20) dose of gamma radiation. Compared to controls, activity of Cu,Zn-SOD increased 3 to 4 fold and catalase 2 fold in response to ionizing radiation stress, while activities of GR and GSH-Px enzymes were decreased. Among the other SOD isoenzymes, our results showed comparable levels of Mn-SOD and Cu,Zn-SOD activity in control and irradiated groups of larvae. The increase in levels of the Cu,Zn-SOD isoenzyme was also confirmed by Western blot and zymography supported by densitometric quantification. No evidence of Fe-SOD was found in C. ramosus larvae. These findings could help to explain the persistence of natural populations of Chironomus in radioactively contaminated regions.

Trehalose as an indicator of desiccation stress in Drosophila melanogaster larvae: A potential marker of anhydrobiosis

In the current scenario of global climate change, desiccation is considered as one of the major environmental stressors for the biota exposed to altered levels of ambient temperature and humidity. Drosophila melanogaster, a cosmopolitan terrestrial insect has been chosen as a humidity-sensitive bioindicator model for the present study since its habitat undergoes frequent stochastic and/or seasonally aggravated dehydration regimes. We report here for the first time the occurrence of anhydrobiosis in D. melanogaster larvae by subjecting them to desiccation stress under laboratory conditions. Larvae desiccated for ten hours at <5% relative humidity could enter anhydrobiosis and could revive upon rehydration followed by resumption of active metabolism. As revealed by FTIR and HPLC analyzes, our findings strongly indicated the synthesis and accumulation of trehalose in the desiccating larvae. Biochemical measurements pointed out the desiccation-responsive trehalose metabolic pathway that was found to be coordinated in concert with the enzymes trehalose 6-phosphate synthase and trehalase. Further, an inhibitor-based experimental approach using deoxynojirimycin, a specific trehalase inhibitor, demonstrated the pivotal role of trehalose in larval anhydrobiosis of D. melanogaster. We therefore propose trehalose as a potential marker for the assessment of anhydrobiosis in Drosophila. The present findings thus add to the growing list of novel biochemical markers in specific bioindicator organisms for fulfilling the urgent need of environmental biomonitoring of climate change.

Hsp70 expression in Chironomus ramosus exposed to gamma radiation

Purpose: A tropical species of midge, Chironomus ramosus has been recently reported to be one of the radio-tolerant groups of organisms. The present study was undertaken to examine the protein profile and expression of Heat shock protein-70 (Hsp70) in gamma radiation stress, which has also been reported as a common biomarker for different type of stressors. Materials and methods: Metabolic labelling of salivary gland (SG) proteins with [35S]-methionine showed over-expression of a 70 kDa protein band up to 4 hours (h) of observation in the post exposure recovery period. For confirmation of the expression of Hsp70 in SG cells after gamma radiation exposure, semi-quantitative real-time-polymerase chain reaction (RT-PCR), Western blotting and immuno-fluorescence detection of Hsp70 were carried out. Results: Results showed elevated levels of Hsp70 mRNA and protein in SG cells of larvae immediately after gamma radiation exposure. The levels dropped to basal values by 48 h in the recovery period. Conclusions: The present study confirmed that radio-tolerant midge, C. ramosus expressed Hsp70 upon gamma radiation exposure and Hsp70 might be one of the gamma radiation-induced stress proteins required during the early stages of radiation stress management in aquatic midge larvae. This is the first report of its kind from the juvenile stage of any aquatic insect group.

The interaction of actinide and lanthanide ions with hemoglobin and its relevance to human and environmental toxicology

Due to increasing use of lanthanides/actinides in nuclear and civil applications, understanding the impact of these metal ions on human health and environment is a growing concern. Hemoglobin (Hb), which occurs in all the kingdom of living organism, is the most abundant protein in human blood. In present study, effect of lanthanides and actinides [thorium: Th(IV), uranium: U(VI), lanthanum: La(III), cerium: Ce(III) and (IV)] on the structure and function of Hb has been investigated. Results showed that these metal ions, except Ce(IV) interacted with carbonyl and amide groups of Hb, which resulted in the loss of its alpha-helix conformation. However, beyond 75μM, these ions affected heme moiety. Metal-heme interaction was found to affect oxygen-binding of Hb, which seems to be governed by their closeness with the charge-to-ionic-radius ratio of iron(III). Consistently, Ce(IV) being closest to iron(III), exhibited a greater effect on heme. Binding constant and binding stoichiometry of Th(IV) were higher than that of U(VI). Experiments using aquatic midge Chironomus (possessing human homologous Hb) and human blood, further validated metal-Hb interaction and associated toxicity. Thus, present study provides a biochemical basis to understand the actinide/lanthanide-induced interference in heme, which may have significant implications for the medical and environmental management of lanthanides/actinides toxicity.

Downregulation of dTps1 in Drosophila melanogaster larvae confirms involvement of trehalose in redox regulation following desiccation.

As a survival strategy to environmental water deficits, desiccation-tolerant organisms are commonly known for their ability to recruit stress-protective biomolecules such as trehalose. We have previously reported the pivotal role of trehalose in larval desiccation tolerance in Drosophila melanogaster. Trehalose has emerged as a versatile molecule, serving mainly as energy source in insects and also being a stress protectant. While several recent reports have revealed the unconventional role of trehalose in scavenging reactive oxygen species in yeast and plants, this aspect has not received much attention in animals. We examined the status of desiccation-induced generation of reactive oxygen species in D. melanogaster larvae and the possible involvement of trehalose in ameliorating the harmful consequences thereof. Insect trehalose synthesis is governed by the enzyme trehalose 6-phosphate synthase 1 (TPS1). Using the ubiquitous da-GAL4-driven expression of the dTps1-RNAi transgene, we generated dTps1-downregulated Drosophila larvae possessing depleted levels of dTps1 transcripts. This resulted in the inability of the larvae for trehalose synthesis, thereby allowing us to elucidate the significance of trehalose in the regulation of desiccation-responsive redox homeostasis. Furthermore, the results from molecular genetics studies, biochemical assays, electron spin resonance analyses and a simple, non-invasive method of whole larval live imaging suggested that trehalose in collaboration with superoxide dismutase (SOD) is involved in the maintenance of redox state in D. melanogaster.

Gamma radiation tolerance of a tropical species of midge, Chironomus ramosus Chaudhuri (Diptera: Chironomidae).

Purpose: The Chironomid midges are known to thrive well under adverse environmental conditions and are even found inhabiting in areas contaminated by radioactive wastes. Studies were therefore undertaken to find out the radiosensitivity of different developmental stages of the Indian tropical midge, Chironomus ramosus. Materials and methods: In order to determine the threshold levels of lethality, eggs, larvae, pupae and adults of C. ramosus were exposed to varying dosages of gamma radiation (60Co radiation source) ranging from 0–3500 Gray (Gy) at dose-rate of 5.5 Gy/minute. The post-irradiation studies were conducted at three different time points: (a) Immediately after the end of irradiation, (b) 24 hours (h), and (c) 48 h after the end of radiation treatments. Determination of the lethal dose required to kill 50% (LD50), 90% (LD90) and 100% population was carried out using the log-probit analysis. Results: Different developmental stages showed variable threshold levels of radiosensitivity. The radiation doses required to cause 100% mortality immediately after radiation exposure of egg, larva, pupa and adult stages were 1000 Gy, 3000 Gy, 3200 Gy and 3500 Gy, respectively, indicating eggs as the most sensitive stage. Detailed analysis of the LD50 values of different post-irradiation time points indicated that pupal stages were also sensitive at 48 h post-irradiation amongst all the post-embryonic stages as described in many other insects. Interestingly detailed analysis of data indicated that amongst the adult population, females were the most radioresistant, compared to the males as reported in many other insect groups in the literature. Conclusions: The Indian tropical midge C. ramosus was found to tolerate higher dose of gamma radiation as compared to other known dipteran insects. It is evident from the present findings that C. ramosus falls in the category of radiation-tolerant group of insects.

Chromosomal polymorphism is associated with nematode parasitism in a natural population of a tropical midge

Abstract. A natural population of a tropical midge, Chironomus ramosus (Diptera: Chironomidae), was found to be polymorphic for a paracentric inversion (IV: 18C–19D). Based on the characteristic banding pattern of the fourth chromosome in the larval salivary gland polytene nuclei, individuals were classified as either structural homozygotes or heterozygotes. Isofemale lines were obtained and subsequently standard (S/S) and inversion (I/I) homozygotes were characterised by careful progeny testing in the laboratory. While exploring various biotic and abiotic factors that might be responsible for the maintenance of inversion polymorphism, we detected nematode (Family: Mermithidae) infections among the larval population. A detailed study indicated that the inversion polymorphism in the natural population of C. ramosus was apparently being maintained as a result of the selective pressure exerted by the nematode parasite. The corresponding pattern of increase and decrease in genotype frequencies and the relative fitness values indicated a selective advantage of inversion heterozygotes (S/I) over both homozygous types (S/S and I/I). Both empirical and experimental data suggest the strong heterotic nature of adaptation in this C. ramosus population towards nematode infection. This is the first report of its kind where inversion polymorphism has been shown to be associated with nematode parasitism.

Effects of water hyacinth Eichhornia crassipes root extracts on midge Chironomus ramosus larvae: a preliminary note

The effects of crude root extracts of Eichhornia crassipes (Marts) Solms on Chironomus ramosus Chaudhuri eggs and larvae are studied under laboratory conditions. Egg masses of C. ramosus that are subjected to varying concentrations of exudates (final concentrations 0.25–2.5%) show 100% viability. However, larvae reared further at these concentrations reveal a dose–response relationship, with an LC50 value of 1.33% and an LC90 value of 2.05%. A striking feature is the occurrence of supernumerary salivary glands in larvae (three glands per larva) reared in the 1%, 1.25%, 1.5% and 1.75% extracts. This deviates from the normal two glands per larva and may be explained by altered growth as a result of the putative bioactive compounds present in the hyacinth extracts. In nature, hyacinth and midges co‐exist in many freshwater habitats, implying that hyacinth compounds present from natural leaching could be encountered by the larvae. These preliminary findings suggest that hyacinth can influence the larval development of midges, giving rise to long‐term ecological implications.

Extracellular electrical activity from the photoreceptors of midge

The ontogeny of photosensitivity has been studied in a holometabolous insect, the midgeChironomus ramosus. The life cycle of midges shifts from an aquatic environment to a non-aquatic environment. Extracellular electrical activity of photoreceptor organs was recorded at larval and adult stages. We found an increase in photosensitivity as the larva metamorphosed to the adult stage. This is the first report of changes in photosensitivity during the development of any insect described in an ecological context.