Smoking flies: testing the effect of tobacco cigarettes on heart function of Drosophila melanogaster.

Studies about the relationship between substances consumed by humans and their impact on health, in animal models, have been a challenge due to differences between species in the animal kingdom. However, the homology of certain genes has allowed extrapolation of certain knowledge obtained in animals. Drosophila melanogaster, studied for decades, has been widely used as model for human diseases as well as to study responses associated with the consumption of several substances. In the present work we explore the impact of tobacco consumption on a model of 'smoking flies'. Throughout these experiments, we aim to provide information about the effects of tobacco consumption on cardiac physiology. We assessed intracellular calcium handling, a phenomenon underlying cardiac contraction and relaxation. Flies chronically exposed to tobacco smoke exhibited an increased heart rate and alterations in the dynamics of the transient increase of intracellular calcium in myocardial cells. These effects were also evident under acute exposure to nicotine of the heart, in a semi-intact preparation. Moreover, the alpha 1 and 7 subunits of the nicotinic receptors are involved in the heart response to tobacco and nicotine under chronic (in the intact fly) as well as acute exposure (in the semi-intact preparation). The present data elucidate the implication of the intracellular cardiac pathways affected by nicotine on the heart tissue. Based on the probed genetic and physiological similarity between the fly and human heart, cardiac effects exerted by tobacco smoke in Drosophila advances our understanding of the impact of it in the human heart. Additionally, it may also provide information on how nicotine-like substances, e.g. neonicotinoids used as insecticides, affect cardiac function.This article has an associated First Person interview with the first author of the paper.

A low-cost Portable Device to Deliver Smoke, Volatile or Vaporized Substances to Drosophila melanogaster, Useful for Research and/or Educational Assays.

Drosophila melanogaster has been used to test drugs of abuse, substances with potential benefits for medical purposes, as well as contaminants and hazardous volatile compounds. This model has also been used for the characterization of behavioral changes, physiopathological consequences, and subcellular mechanisms of the use of cocaine, methamphetamines, ethanol, nicotine, cannabinoids, toluene, and other airborne volatile organic compounds. When testing these substances, routes of administration are important to define. Admixing the test compounds with water or food is one suitable option in many cases, but the inhalation route is especially suitable when the administration of one or more volatile compounds is desired. One advantage of the administration of substances via the inhalation route is its rapid exchange and distribution throughout the cuticle and the tracheal system. In addition, this route allows treating a large group of individuals simultaneously. Moreover, the inhalation route is frequently used to administer different drugs to humans. A good model system shares physiology and molecular pathways with humans, and D. melanogaster possesses almost 75% homologous genes associated with human diseases. Methodologies to deliver the abovementioned substances usually include customized devices. Herein, we focus on the development of a low-cost customized device useful to deliver smoke or vaporizable compounds to D. melanogaster. This approach might be applied for acute or chronic exposure to vaporized substances. In particular, our device was utilized for testing cigarette smoke and vaporized cannabis extract on cardiac performance of adult individuals during chronic treatment. We are describing how to set up this low-cost portable device, useful for research and/or educational assays, taking advantage of the amenability of D. melanogaster to test different compounds in relatively short periods, and especially including a large number of individuals at the same time. Graphic abstract: Custom-made device useful for inhalation pathway assays in Drosophila melanogaster.