Chemical Cues Influence Pupation Behavior of Drosophila simulans and Drosophila buzzatii in Nature and in the Laboratory

In the wild, larvae of several species of Drosophila develop in heterogeneous and rapidly changing environments sharing resources as food and space. In this scenario, sensory systems contribute to detect, localize and recognize congeners and heterospecifics, and provide information about the availability of food and chemical features of environments where animals live. We investigated the behavior of D. simulans and D. buzzatii larvae to chemicals emitted by conspecific and heterospecific larvae. Our goal was to understand the role of these substances in the selection of pupation sites in the two species that cohabit within decaying prickly pear fruits (Opuntia ficus-indica). In these breeding sites, larvae of D. simulans and D. buzzatii detect larvae of the other species changing their pupation site preferences. Larvae of the two species pupated in the part of the fruit containing no or few heterospecifics, and spent a longer time in/on spots marked by conspecifics rather than heterospecifics. In contrast, larvae of the two species reared in isolation from conspecifics pupated randomly over the substrate and spent a similar amount of time on spots marked by conspecifics and by heterospecifics. Our results indicate that early chemically-based experience with conspecific larvae is critical for the selection of the pupation sites in D. simulans and D. buzzatii, and that pupation site preferences of Drosophila larvae depend on species-specific chemical cues. These preferences can be modulate by the presence of larvae of the same or another species

Rights to Land, Forests and Carbon in REDD+ : Insights from Mexico, Brazil and Costa Rica

Land tenure and carbon rights constitute critical issues to take into account in achieving emission reductions, ensuring transparent benefit sharing and determining non-permanence (or non-compliance) liabilities in the context of REDD+ strategies and projects. This is so because tenure systems influence who becomes involved in efforts to avoid deforestation and improve forest management, and that land tenure, carbon rights and liabilities may be linked or divorced with implications for rural development. This paper explores these issues by looking at tenure regimes and carbon rights issues in Mexico, Brazil and Costa Rica. It is effectively shown that complex bundles of rights over forest resources have distinct implications for REDD+ design and implementation, and that REDD+ strategies in selected countries have to date failed in procedurally addressing land-use conflicts and carbon rights entitlements and liabilities

Olfactory Jump Reflex Habituation in Drosophila and Effects of Classical Conditioning Mutations

Habituation is a nonassociative learning mechanism, in which an initial response toward repeated stimuli gradually wanes. This is amongst the simplest and most widespread forms of behavioral plasticity. So far, neither the underlying molecular mechanisms nor the precise neural networks of habituation are well understood. We have developed a novel paradigm to quantify habituation of the olfactory jump reflex in Drosophila. We present data demonstrating several behavioral properties of this phenomenon, generally observed in other species. We also show that the dunce and rutabaga memory mutants behave abnormally in this assay, suggesting that this assay might be used in behavioral screens for new mutants with defects in this simpler form of behavioral plasticity

The Ol1mpiad: concordance of behavioural faculties of stage 1 and stage 3 Drosophila larvae

This publication hasn't any creative commons license associated. This article has a Company of Biologists User Licence 1.1. The deposited article version contains attached the supplementary materials within the pdf.Mapping brain function to brain structure is a fundamental task for neuroscience. For such an endeavour, the Drosophila larva is simple enough to be tractable, yet complex enough to be interesting. It features about 10,000 neurons and is capable of various taxes, kineses and Pavlovian conditioning. All its neurons are currently being mapped into a light-microscopical atlas, and Gal4 strains are being generated to experimentally access neurons one at a time. In addition, an electron microscopic reconstruction of its nervous system seems within reach. Notably, this electron microscope-based connectome is being drafted for a stage 1 larva - because stage 1 larvae are much smaller than stage 3 larvae. However, most behaviour analyses have been performed for stage 3 larvae because their larger size makes them easier to handle and observe. It is therefore warranted to either redo the electron microscopic reconstruction for a stage 3 larva or to survey the behavioural faculties of stage 1 larvae. We provide the latter. In a community-based approach we called the Ol1mpiad, we probed stage 1 Drosophila larvae for free locomotion, feeding, responsiveness to substrate vibration, gentle and nociceptive touch, burrowing, olfactory preference and thermotaxis, light avoidance, gustatory choice of various tastants plus odour-taste associative learning, as well as light/dark-electric shock associative learning. Quantitatively, stage 1 larvae show lower scores in most tasks, arguably because of their smaller size and lower speed. Qualitatively, however, stage 1 larvae perform strikingly similar to stage 3 larvae in almost all cases. These results bolster confidence in mapping brain structure and behaviour across developmental stages.Fundação para a Ciência e a Tecnologia grants: (SFRH/BPD/75993/2011EXPL/BEX-BID/0497/2013); Cluster of Excellence Cells in Motion; CiM International Max Planck research school; Spanish Ministry of Economy and Competitiveness; ‘Centro de Excelencia Severo Ochoa 2013-2017’ grant: (SEV-2012-0208); CERCA Programme/Generalitat de Catalunya; the ‘la Caixa’ International PhD Programme; Spanish Ministry of Science and Innovation grant: (BFU2011-26208); Wissenschaftsgemeinschaft Gottfried Wilhelm Leibniz; State of Sachsen-Anhalt; Center for Behavioral Brain Sciences Magdeburg; Otto von Guericke Universität Magdeburg; Deutsche Forschungsgemeinschaft grants: (CRC 779 Motivated behaviour: B11; GE1091/4-1, SPP 1926, Next generation optogenetics, SO1337/2-1, CRC 779 Motivated behaviour: B15; YA272/2-1, PA 787/7-1, (TH1584/1-1, TH1584/3-1); European Commission grant: (FP7-ICT project Miniature Insect Model for Active Learning MINIMAL); Howard Hughes Medical Institute; European Research Council grant: (ERC-2012-StG 309832-PhotoNaviNet); Swiss National Science Foundation grant: (31003A_169993); Landesforschungsförderung Hamburg grant: (LFF-FV27); Wissenschaftsgemeinschaft Gottfried Wilhelm Leibniz; State of Sachsen-Anhalt; Center for Behavioral Brain Sciences Magdeburg; Cluster of Excellence ImmunoSensation; Baden-Württemberg Stiftung; Zukunftskolleg of the University of Konstanz.info:eu-repo/semantics/publishedVersio