Food Selectivity and Diet Switch Can Explain the Slow Feeding of Herbivorous Coral-Reef Fishes during the Morning

Most herbivorous coral-reef fishes feed slower in the morning than in the afternoon. Given the typical scarcity of algae in coral reefs, this behavior seems maladaptive. Here we suggest that the fishes'' slow feeding during the morning is an outcome of highly selective feeding on scarcely found green algae. The rarity of the food requires longer search time and extended swimming tracks, resulting in lower bite rates. According to our findings by noon the fish seem to stop their search and switch to indiscriminative consumption of benthic algae, resulting in apparent higher feeding rates. The abundance of the rare preferable algae gradually declines from morning to noon and seems to reach its lowest levels around the switch time. Using in situ experiments we found that the feeding pattern is flexible, with the fish exhibiting fast feeding rates when presented with ample supply of preferable algae, regardless of the time of day. Analyses of the fish''s esophagus content corroborated our conclusion that their feeding was highly selective in the morning and non-selective in the afternoon. Modeling of the fishes'' behavior predicted that the fish should perform a diel diet shift when the preferred food is relatively rare, a situation common in most coral reefs found in a warm, oligotrophic ocean.     

Plants’ ability to sense and respond to airborne sound is likely to be adaptive: reply to comment by Pyke et al

Ecol. Lett. 22, 2019, 1483 demonstrated, for the first time, a rapid response of a plant to the airborne sounds of pollinators. Pyke et al. argue that this response is unlikely to be adaptive. Here we clarify some misunderstandings, and demonstrate the potential adaptive value using theoretical modelling and field observations.     

Impaired myocardial autophagy linked to energy metabolism disorders

Autophagy represents an evolutionarily conserved catabolic mechanism that promotes cell survival by releasing energy substrates via degradation of cellular constituents and by eliminating defective organelles under conditions of stress, such as starvation and hypoxia. The link between enhanced autophagy and nutrient deprivation has been well established. For example, chronic myocardial ischemia, a condition of insufficient oxygen and nutrition, activates autophagy to degrade and recycle damaged cellular structures, thereby ameliorating cardiomyocyte injury.     

Regional decreases in renal oxygenation during graded acute renal arterial stenosis: a case for renal ischemia

Ischemic nephropathy describes progressive renal failure, defined by significantly reduced glomerular filtration rate, and may be due to renal artery stenosis (RAS), a narrowing of the renal artery. It is unclear whether ischemia is present during RAS since a decrease in renal blood flow (RBF), O(2) delivery, and O(2) consumption occurs. The present study tests the hypothesis that despite proportional changes in whole kidney O(2) delivery and consumption, acute progressive RAS leads to decreases in regional renal tissue O(2). Unilateral acute RAS was induced in eight pigs with an extravascular cuff. RBF was measured with an ultrasound flow probe. Cortical and medullary tissue oxygen (P(t(O(2)))) of the stenotic kidney was measured continuously with sensors during baseline, three sequentially graded decreases in RBF, and recovery. O(2) consumption decreased proportionally to O(2) delivery during the graded stenosis (19 +/- 10.8, 48.2 +/- 9.1, 58.9 +/- 4.7 vs. 15.1 +/- 5, 35.4 +/- 3.5, 57 +/- 2.3%, respectively) while arterial venous O(2) differences were unchanged. Acute RAS produced a sharp reduction in O(2) efficiency for sodium reabsorption (P < 0.01). Cortical (P(t(O(2)))) decreases are exceeded by medullary decreases during stenosis (34.8 +/- 1.3%). Decreases in tissue oxygenation, more pronounced in the medulla than the cortex, occur despite proportional reductions in O(2) delivery and consumption. This demonstrates for the first time that hypoxia is present in the early stages of RAS and suggests a role for hypoxia in the pathophysiology of this disease. Furthermore, the notion that arteriovenous shunting and increased stoichiometric energy requirements are potential contributors toward ensuing hypoxia with graded and progressive acute RAS cannot be excluded.     

Celebrating 100 years of Drosophila research

The seventeenth EMBO Conference on the Molecular and Developmental Biology of Drosophila took place in Kolymbari, Crete, between 20 and 26 June 2010. The conference covered a broad range of topics and much progress was made by combining two or more fields of study. Such combinations included quantitative approaches to cell and developmental biology, dissecting interrelations of physiology and development and integrated genomic analysis.