The enteroendocrine cell (EEC)-derived incretins play a pivotal role in regulating the secretion of glucagon and insulins in mammals. Although glucagon-like and insulin-like hormones have been found across animal phyla, incretin-like EEC-derived hormones have not yet been characterised in invertebrates. Here, we show that the midgut-derived hormone, neuropeptide F (NPF), acts as the sugar-responsive, incretin-like hormone in the fruit fly, Drosophila melanogaster. Secreted NPF is received by NPF receptor in the corpora cardiaca and in insulin-producing cells. NPF-NPFR signalling resulted in the suppression of the glucagon-like hormone production and the enhancement of the insulin-like peptide secretion, eventually promoting lipid anabolism. Similar to the loss of incretin function in mammals, loss of midgut NPF led to significant metabolic dysfunction, accompanied by lipodystrophy, hyperphagia, and hypoglycaemia. These results suggest that enteroendocrine hormones regulate sugar-dependent metabolism through glucagon-like and insulin-like hormones not only in mammals but also in insects.
Summary
Gut microbiota impacts the host metabolome and affects its health span. How bacterial species in the gut influence age-dependent metabolic alteration has not been elucidated. Here we show in
Drosophila melanogaster
that allantoin, an end product of purine metabolism, is increased during aging in a microbiota-dependent manner. Allantoin levels are low in young flies but are commonly elevated upon lifespan-shortening dietary manipulations such as high-purine, high-sugar, or high-yeast feeding. Removing
Acetobacter persici
in the
Drosophila
microbiome attenuated age-dependent allantoin increase. Mono-association with
A. persici
, but not with
Lactobacillus plantarum
, increased allantoin in aged flies.
A. persici
increased allantoin via activation of innate immune signaling IMD pathway in the renal tubules. On the other hand, analysis of bacteria-conditioned diets revealed that
L. plantarum
can decrease allantoin by reducing purines in the diet. These data together demonstrate species-specific regulations of host purine levels by the gut microbiome.
To achieve highly
selective ablation of lacZ-positive
cells in a biological milieu in vivo, we developed
an activatable photosensitizer, SPiDER-killer-βGal, targeted
to β-galactosidase encoded by the lacZ reporter
gene. Hydrolysis of SPiDER-killer-βGal by β-galactosidase
simultaneously activates both its photosensitizing ability and its
reactivity to nucleophiles, so that the phototoxic products generated
by light irradiation are trapped inside the lacZ-positive
cells. The combination of SPiDER-killer-βGal and light irradiation
specifically killed lacZ-positive cells in coculture
with cells without lacZ expression. Furthermore,
β-galactosidase-expressing cells in the posterior region of
cultured Drosophila wing discs and in pupal notum
of live Drosophila pupae were selectively killed
with single-cell resolution. This photosensitizer should be useful
for specific ablation of targeted cells in living organisms, for example,
to investigate cellular functions in complex networks.
Highlights d Necrotic cells in wings trigger a systemic immune response and shorten the lifespan d Eliminating microbiota diminishes necrosis-induced IMD activation d Gluconobacter sp. increases in the gut in response to wing necrosis d Gluconobacter sp. exacerbates pathologies in necrosisinduced flies
Non-apoptotic caspase activation involves multiple cellular events. However, the link between visible non-apoptotic caspase activation and its function in living organisms has not yet been revealed. Here, we visualized sub-lethal activation of apoptotic signaling with the combination of a sensitive indicator for caspase 3 activation and in vivo live-imaging analysis of Drosophila. During thorax closure in pupal development, caspase 3 activation was specifically observed at the leading edge cells, with no signs of apoptosis. Inhibition of caspase activation led to an increase in thorax closing speed, which suggests a role of non-apoptotic caspase activity in cell motility. Importantly, sub-lethal activation of caspase 3 was also observed during wound closure at the fusion sites at which thorax closure had previously taken place. Further genetic analysis revealed that the activation of the initiator caspase Dronc is coupled with the generation of reactive oxygen species. The activation of Dronc also regulates myosin levels and delays wound healing. Our findings suggest a possible function for non-apoptotic caspase activation in the fine-tuning of cell migratory behavior during epithelial closure.
The small biomolecule methionine (Met) is a fundamental amino acid required for a vast range of biological processes such as protein synthesis, cancer metabolism, and epigenetics. However, it is still difficult to visualize the subcellular distribution of small biomolecules including Met in a minimally invasive manner. Here, we demonstrate stimulated Raman scattering (SRS) imaging of cellular uptake of deuterated methionine (d 8 -Met) in live HeLa cells by way of comparison to the previously used alkyne-labeled Met analoguehomopropargylglycine (Hpg). We show that the solutions of d 8 -Met and Hpg have similar SRS signal intensities. Furthermore, by careful image analysis with background subtraction, we succeed in the SRS imaging of cellular uptake of d 8 -Met with a much greater signal intensity than Hpg, possibly reflecting the increased and minimally invasive uptake kinetics of d 8 -Met compared with Hpg. We anticipate that d 8 -Met and other deuterated biomolecules will be useful for investigating metabolic processes with subcellular resolution.
An early-life inflammatory response is associated with risks of age-related pathologies. How transient immune signalling activity during animal development influences life-long fitness is not well understood. Using Drosophila as a model, we find that activation of innate immune pathway Immune deficiency (Imd) signalling in the developing larvae increases adult starvation resistance, decreases food intake and shortens organismal lifespan. Interestingly, lifespan is shortened by Imd activation in the larval gut and fat body, whereas starvation resistance and food intake are altered by that in neurons. The adult flies that developed with Imd activation show sustained Imd activity in the gut, despite complete tissue renewal during metamorphosis. The larval Imd activation increases an immunostimulative bacterial species, Gluconobacter sp., in the gut microbiome, and this dysbiosis is persistent to adulthood. Removal of gut microbiota by antibiotics in the adult fly mitigates intestinal immune activation and rescues the shortened lifespan. This study demonstrates that early-life immune activation triggers long-term physiological changes, highlighted as an irreversible alteration in gut microbiota, prolonged inflammatory intestine and concomitant shortening of the organismal lifespan.
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