Differences in larval nutritional requirements and female oviposition preference reflect the order of fruit colonization of Zaprionus indianus and Drosophila simulans

Species coexist using the same nutritional resource by partitioning it either in space or time, but few studies explore how species-specific nutritional requirements allow partitioning. Zaprionus indianus and Drosophila simulans co-exist in figs by invading the fruit at different stages; Z. indianus colonizes ripe figs, whereas D. simulans oviposits in decaying fruit. Larvae feed on yeast growing on the fruit, which serves as their primary protein source. Because yeast populations increase as fruit decays, we find that ripe fruit has lower protein content than rotting fruit. Therefore, we hypothesized that Z. indianus and D. simulans larvae differ in their dietary requirements for protein. We used nutritional geometry to assess the effects of protein and carbohydrate concentration in the larval diet on life history characters in both species. Survival, development time, and ovariole number respond differently to the composition of the larval diet, with Z. indianus generally performing better across a wider range of protein concentrations. Correspondingly, we found that Z. indianus females preferred to lay eggs on low protein foods, while D. simulans females chose higher protein foods for oviposition when competing with Z. indianus. We propose the different nutritional requirements and oviposition preference of these two species allows them to temporally partition their habitat.

Drosophila melanogaster larvae make nutritional choices that minimize developmental time

Organisms from slime moulds to humans carefully regulate their macronutrient intake to optimize a wide range of life history characters including survival, stress resistance, and reproductive success. However, life history characters often differ in their response to nutrition, forcing organisms to make foraging decisions while balancing the trade-offs between these effects. To date, we have a limited understanding of how the nutritional environment shapes the relationship between life history characters and foraging decisions. To gain insight into the problem, we used a geometric framework for nutrition to assess how the protein and carbohydrate content of the larval diet affected key life history traits in the fruit fly, Drosophila melanogaster. In no-choice assays, survival from egg to pupae, female and male body size, and ovariole number - a proxy for female fecundity - were maximized at the highest protein to carbohydrate (P:C) ratio (1.5:1). In contrast, development time was minimized at intermediate P:C ratios, around 1:2. Next, we subjected larvae to two-choice tests to determine how they regulated their protein and carbohydrate intake in relation to these life history traits. Our results show that larvae targeted their consumption to P:C ratios that minimized development time. Finally, we examined whether adult females also chose to lay their eggs in the P:C ratios that minimized developmental time. Using a three-choice assay, we found that adult females preferentially laid their eggs in food P:C ratios that were suboptimal for all larval life history traits. Our results demonstrate that D. melanogaster larvae make foraging decisions that trade-off developmental time with body size, ovariole number, and survival. In addition, adult females make oviposition decisions that do not appear to benefit the larvae. We propose that these decisions may reflect the living nature of the larval nutritional environment in rotting fruit. These studies illustrate the interaction between the nutritional environment, life history traits, and foraging choices in D. melanogaster, and lend insight into the ecology of their foraging decisions.

Role of dietary fibers in the nutritional management of hyperuricemia

Foods rich in adenine and hypoxanthine may contribute to the increase of uricemia. Hyperuricemia is associated with other pathological conditions pertaining to metabolic syndrome. Objective: the assessement of the impact of fiber rich diet on uricemia in patients with metabolic syndrome. Methods: the study involved 46 male patients with metabolic syndrome who claimed to have reduced mobility in fingers, hypertension, obesity, hyperglycemia and hyperuricemia. A validated questionnaire about dietary habits was applied at the beginning of the study and after 6 weeks of fiber-rich diet by eliminating from patients diet preparations of animal food and increased intake of vegetable foods. Blood presure, body mass index, blood glucose and uric acids were measured at the beginning of the study and after 6 weeks of fiber rich diet by daily consumption of 2 servings of added grains - 60g totally and vegetables 200g, fruits 300g respectively. Results: The study shows that at baseline all patients had an inadequate dietary intake of dietary fiber, 28.5 ± 2.2 g/day instead of 38 g per day.The increase in fiber intake of 10 ± 5 g/day was associated with a decrease of serum uric acid by 69.87% from 8.3  0.6 mg/dL to 5.8  0.5 mg/dL, p = 0.008, non-significant decrease of BMI (from 26.8  4.5 to 26.4  4.6 kg/m2, p<0.01), significant decrease of glycemia (from 130  0.8 to 105  4.2mg/dL, p <0.001) and significant decrease in blood pressure (from 150  10.6 to 130  8.4 mmHg, p <0.001). Conclusion: The fiber rich diet decreased blood uric acid, blood glucose levels an arterial pressure in patients with metabolic syndrome.

Solute losses from various shoot parts of field-grown wheat by leakage in the rain

Leakage from field-grown wheat was investigated during two seasons differing considerably in their rainfall patterns. For all solutes analyzed, these losses were low from non-senescing plant parts, increased after the onset of senescence and became maximal in fully senesced (dry, brown) organs. The cumulative losses of potassium by leakage in the rain were 65% of the content at anthesis for the flag leaf and 95% for the third leaf from the top, while these relative values were lower for magnesium (50 to 80%) and calcium (around 55%) and extremely low for sodium (<10%). The differences between potassium and sodium may be due to a different compartmentation on the tissue level or on the subcellular level. It became evident that for certain nutrients (e.g. potassium or magnesium) leakage in the rain may represent a major loss from senescing leaves and can be a relevant flux in maturing wheat.