Melhoramento genético na apicultura comercial para produção da própolis

O melhoramento genético de abelhas Apis mellifera é uma ferramenta essencial e de caráter obrigatório para o sucesso e desenvolvimento da indústria apícola. Práticas de manejo, troca das rainhas e inseminação instrumental constituem os pilares fundamentais de um programa que vise o aumento de determinada característica quantitativamente. A diversidade de climas no Brasil, junto com a possibilidade de direcionar a produção de diferentes produtos, fazem deste um país com oportunidades no campo internacional da apicultura. Programas de melhoramento genético, em grande escala, precisam ser feitos a partir de populações em massa, ou seja, um programa de melhoramento deverá iniciar-se a partir de um grande número de colmeias para serem selecionadas, com a finalidade de desenvolver e estruturar um programa de melhoramento genético que tenha como objetivo incrementar os níveis de produção e assim aumentar as médias de produção por colmeia em geral. Algumas características podem ser utilizadas para selecionar as colmeias, como: produção de própolis; a qualidade da própolis coletada; comportamento higiênico; taxa de infestação de varroa e incidência de Nosema. Isso garante a seleção das melhores colmeias como base do programa de melhoramento genético. Adicionalmente, padronização de práticas de manejo, troca constante de rainhas, produção de zangões, avaliação contínua da produção e a inseminação instrumental são práticas constantes nos apiários do programa de melhoramento em própolis.

Funktionsaufklärung von Atmungsproteinen in Insekten

Globine sind kleine globuläre Proteine mit nahezu ubiquitärem Vorkommen in allen Tiergruppen. Sie weisen eine typische Sandwichstruktur auf, die in der Regel aus acht α-Helices mit einer zentralen prosthetischen Häm-Gruppe besteht und die Proteine zur Bindung gasförmiger Liganden befähigt. Die Funktionen der Globine reichen von O2-Transport und – Speicherung, über eine Beteiligung bei der Entgiftung reaktiver Sauerstoff- und Stickstoffspezies bis hin zu sensorischen physiologischen Aufgaben. Innerhalb der Klasse der Insekten schien das Vorhandensein von Globinen zunächst auf Insekten mit offensichtlich hypoxischen Habitaten beschränkt zu sein. Die Entdeckung des Globins glob1 in Drosophila melanogaster deutete jedoch eine sehr viel weitere Verbreitung der Globine in Insekten an, die sich durch die Identifizierung von Globingenen in einer Vielzahl von normoxisch lebenden Insekten, wie z.B. Apis mellifera oder Aedes aegypti bestätigte. D. melanogaster besitzt drei Globine, glob1, glob2 und glob3. Glob1 ist eng mit anderen intrazellulären Insektenglobinen verwandt, was zu der Annahme führte, dass es sich bei glob1 um das ursprüngliche und bei glob2 und glob3 um abgeleitete D. melanogaster Globine handelt. Glob1 wird in allen Entwicklungsstadien exprimiert, wobei die Hauptexpressionsorte der Fettkörper und das Tracheensystem sind. Die Transkription des glob1 startet von zwei alternativen Promotoren (Promotor I und II), wodurch in Kombination mit alternativem Splicing vier Transkriptvarianten (Isoform A-D) entstehen, deren Translation jedoch in einer Proteinvariante (glob1) resultiert. Hypoxische Bedingungen führen zu einer vermutlich HIF (=‚hypoxia-inducible factor‘) -vermittelten Abnahme der glob1 Genexpression, wohingegen Hyperoxie eine leichte Zunahme der glob1 mRNA Menge bewirkt. Der mithilfe des UAS/Gal4- Systems erzeugte, RNAi-vermittelte glob1 Knockdown führt zu einer schlechteren Überlebensrate adulter Fliegen unter hypoxischen Bedingungen, einer verkürzten Erholungszeit nach hypoxischem Stupor in Weibchen sowie zu einer erhöhten Resistenz gegenüber dem ROS (=‘reactive oxygen species‘) -generierenden Herbizid Paraquat in Larven und adulten Weibchen. Diese Beobachtungen sprechen für eine Funktion des Drosophila glob1 innerhalb der O2-Versorgung. Unter hyperoxischen Bedingungen hingegen wurde kein Unterschied zwischen Fliegen mit wildtypischer und manipulierter glob1-Expression festgestellt, wodurch eine Beteiligung des glob1 bei der Entgiftung reaktiver Sauerstoffspezies als mögliche Funktion vorerst ausscheidet. Bei glob2 und glob3 handelt es sich um duplizierte Gene. Auf phylogenetischen Rekonstruktionen basierend konnte die Entstehung der Globin-Duplikate auf ein Duplikationsereignis vor der Radiation des Subgenus Sophophora vor mindestens 40 Millionen Jahren zurückgeführt werden. Die durchgeführten Analysen zur molekularen Sequenzevolution der Globin-Duplikate deuten darauf hin, dass glob2 und glob3 nach der Duplikation eine Kombination aus Sub- und Neo-Funktionalisierungsprozessen durchlaufen haben. Glob2 und glob3 zeigen eine deckungsgleiche mRNA Expression, die auf die männliche Keimbahn beschränkt ist. Aufgrund des hohen Konservierungsgrads der für die Häm- und O2-Bindung essentiellen Aminosäuren kann von der Funktionalität beider Proteine ausgegangen werden. Die streng auf die männliche Keimbahn begrenzte Expression von glob2 und glob3 deutet auf eine Rolle der Globin-Duplikate innerhalb der Spermatogenese hin, die möglicherweise in einem Schutz der Spermatogenese vor oxidativem Stress besteht. Auch eine Beteiligung beim korrekten Ablauf der Spermien-Individualisierung, beispielsweise durch Regulation von Apoptoseprozessen wäre denkbar.

Winter Losses of Honeybee Colonies (Hymenoptera: Apidae): The Role of Infestations With Aethina tumida (Coleoptera: Nitidulidae) and Varroa destructor (Parasitiformes: Varroidae)

Multiple infections of managed honeybee, Apis mellifera, colonies are inevitable due to the ubiquitous ectoparasitic mite Varroa destructor and might be an underlying cause of winter losses. Here we investigated the role of adult small hive beetles, Aethina tumida, alone and in combination with V. destructor for winter losses and for infections with the microsporidian endoparasite Nosema ceranae. We found no significant influence of A. tumida and V destructor alone or in combination on the numbers of N. ceranae spores. Likewise, A. tumida alone had no significant effects on winter losses, which is most likely due to the observed high winter mortality of the adult beetles. Therefore, our data suggest that A. tumida is unlikely to contribute to losses of overwintering honeybee colonies. However, high losses occurred in all groups highly infested with V. destructor, supporting the central role of the mite for colony losses.

Clinical signs of deformed wing virus infection are predictive markers for honey bee colony losses.

The ectoparasitic mite Varroa destructor acting as a virus vector constitutes a central mechanism for losses of managed honey bee, Apis mellifera, colonies. This creates demand for an easy, accurate and cheap diagnostic tool to estimate the impact of viruliferous mites in the field. Here we evaluated whether the clinical signs of the ubiquitous and mite-transmitted deformed wing virus (DWV) can be predictive markers of winter losses. In fall and winter 2007/2008, A.m. carnica workers with apparent wing deformities were counted daily in traps installed on 29 queenright colonies. The data show that colonies which later died had a significantly higher proportion of workers with wing deformities than did those which survived. There was a significant positive correlation between V. destructor infestation levels and the number of workers displaying DWV clinical signs, further supporting the mite's impact on virus infections at the colony level. A logistic regression model suggests that colony size, the number of workers with wing deformities and V. destructor infestation levels constitute predictive markers for winter colony losses in this order of importance and ease of evaluation.

Hit-and-run trophallaxis of small hive beetles

Some parasites of social insects are able to exploit the exchange of food between nestmates via trophallaxis, because they are chemically disguised as nestmates. However, a few parasites succeed in trophallactic solicitation although they are attacked by workers. The underlying mechanisms are not well understood. The small hive beetle (=SHB), Aethina tumida, is such a parasite of honey bee, Apis mellifera, colonies and is able to induce trophallaxis. Here, we investigate whether SHB trophallactic solicitation is innate and affected by sex and experience. We quantified characteristics of the trophallactic solicitation in SHBs from laboratory-reared individuals that were either bee-naïve or had 5 days experience. The data clearly show that SHB trophallactic solicitation is innate and further suggest that it can be influenced by both experience and sex. Inexperienced SHB males begged more often than any of the other groups had longer breaks than their experienced counterparts and a longer soliciting duration than both experienced SHB males and females, suggesting that they start rather slowly and gain more from experience. Successful experienced females and males were not significantly different from each other in relation to successful trophallactic interactions, but had a significantly shorter soliciting duration compared to all other groups, except successful inexperienced females. Trophallactic solicitation success, feeding duration and begging duration were not significantly affected by either SHB sex or experience, supporting the notion that these behaviors are important for survival in host colonies. Overall, success seems to be governed by quality rather than quantity of interactions, thereby probably limiting both SHB energy investment and chance of injury (<1%). Trophallactic solicitation by SHBs is a singular example for an alternative strategy to exploit insect societies without requiring chemical disguise. Hit-and-run trophallaxis is an attractive test system to get an insight into trophallaxis in the social insects.

A Toolbox for Quantitative Gene Expression in Varroa destructor : RNA Degradation in Field Samples and Systematic Analysis of Reference Gene Stability

Funding: This project has received funding from the European Union’s Seventh Framework Programme for research, technological development and demonstration under grant agreement no. 613960 (SMARTBEES) (http://www.smartbees-fp7.eu/) and Veterinary Medicines Directorate, Department for Environment Food & Rural Affairs (Project # VM0517) (https://www.gov.uk/government/organisations/veterinary-medicines-directorate). CHM was supported by a Biosciences Knowledge Transfer Network Biotechnology and Biological Sciences Research Council (KTN-BBSRC CASE) Studentship (BB/L502467/1) (http://www.bbsrc.ac.uk/). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. Acknowledgments We gratefully acknowledge Mr Sebastian Bacz’s expert help and advice with beekeeping.

Análisis virológico y epidemiológico del síndrome de despoblamiento de las colmenas en España: estudio de causas y consecuencias

La abeja de la miel Apis mellifera es la principal especie polinizadora empleada por el hombre para aumentar la productividad de los cultivos, y además desempeña una importante función en el mantenimiento de la biodiversidad en todo el mundo. En las últimas décadas, se ha apreciado un incremento de la mortalidad de las colonias de abejas en numerosas regiones, lo que ha llevado a generar una gran alarma debido a sus potenciales repercusiones económicas y medioambientales. Este fenómeno, caracterizado por no tener una causa conocida, se ha clasificado principalemente en “Síndrome de Despoblamiento de las Colmenas” (SDC), cuando presenta una sintomatología concreta de despoblamiento de abejas adultas, o simplemente “mortalidad invernal”, cuando las colmenas no superan el invierno por causas no identificadas. Estas pérdidas se han observado también en España, el país con mayor censo de colmenas de la Unión Europea e importante productor de miel. Esta situación ha generado la necesidad de estudiar las causas de tales pérdidas. Actualmente se considera que no existe una causa única que explique esta mortalidad sino que, por el contrario, se trata de un fenómeno en el que la interacción de varios factores afecta a las colonias. Entre estos factores considerados ‘de riesgo’ destacan la mala nutrición y la escasez de recursos, la climatología adversa y el cambio climático, la exposición a pesticidas neonicotinoides empleados en los cultivos donde pecorean las abejas, la presencia de depredadores naturales y especies invasoras y la acción de los patógenos presentes en las colmenas. Entre los patógenos que pueden afectar a la abejas, destacan los virus porque a pesar de conocerse su amplia distribución y prevalencia en las colmenas y haber sido asociados con eventos de mortalidad de colonias de abejas, aún son muchos los interrogantes sobre su patogenia, cómo se ven afectados por otros factores y cómo son capaces de alterar el equilibrio con el hospedador produciendo estados patológicos...

Monitorización de los principales patógenos de las abejas para la detección de alertas y riesgos sanitarios

Las abejas, principalmente la especie Apis mellifera, desarrollan una función biológica muy importante puesto que se encargan de polinizar diversos cultivos agrícolas y la flora silvestre de todo el mundo. No obstante, existen numerosos factores que influyen en el estado sanitario de las colonias de abejas y presentan además un alto grado de interacciones entre ellos. Algunos de los potenciales riesgos para la apicultura española ya han sido identificados, como por ejemplo las dos especies de microsporidios, Nosema apis y N. ceranae, que actúan como parásitos intracelulares obligados o los ectoparásitos Varroa destructor, Acarapis woodi o Braula coeca; así como numerosos virus capaces de infectar a Apis melífera, de los cuales los principales son el virus de las alas deformadas (DWV), el virus de las realeras negras (BQCV), el virus Kashmir (KBV), el virus de la parálisis aguda (ABPV) y su variante israelí (IAPV). Otras enfermedades que afectan fundamentalmente a la cría de abejas son la loque americana y la loque europea, ambas de origen bacteriano (Paenibacillus larvae y Melissococcus plutonius respectivamente), así como la ascosferosis causada por el hongo Ascosphaera apis. Otro riesgo potencial para las abejas es la posible entrada de agentes exóticos como el coleóptero Aethina tumida o el ácaro Tropilaelaps clareae cuya presencia en Europa debe ser declarada según la OIE (2015). Recientemente se ha incluido a los neogregarinos y tripanosomátidos como posibles agentes patógenos. Actualmente, N. ceranae junto con V. destructor son los principales agentes patógenos que producen problemas sanitarios de las colonias de abejas en Europa. Además, se considera que los patógenos podrían jugar un papel primordial en el incremento de mortalidad de las abejas detectado en distintos países durante los últimos años...

Transcriptome analysis of the synganglion from the honey bee mite, Varroa destructor and RNAi knockdown of neural peptide targets

Date of Acceptance: 20/12/2015 This work was funded by BBSRC-LINK grant # BB/J01009X/1 and Vita Europe Ltd. We are grateful to the Scottish Beekeepers Association, especially Mr Phil McAnespie in supporting this work at its inception. We acknowledge partial funding from a Genesis Faraday SPARK Award, part of a Scottish Government SEEKIT project for the early part of this work. We are grateful to Prof David Evans for his advice on Varroa destructor viruses.

Widespread exploitation of the honeybee by early Neolithic farmers

The pressures on honeybee (Apis mellifera) populations, resulting from threats by modern pesticides, parasites, predators and diseases, have raised awareness of the economic importance and critical role this insect plays in agricultural societies across the globe. However, the association of humans with A. mellifera predates post-industrial-revolution agriculture, as evidenced by the widespread presence of ancient Egyptian bee iconography dating to the Old Kingdom (approximately 2400 bc)1. There are also indications of Stone Age people harvesting bee products; for example, honey hunting is interpreted from rock art2 in a prehistoric Holocene context and a beeswax find in a pre-agriculturalist site3. However, when and where the regular association of A. mellifera with agriculturalists emerged is unknown4. One of the major products of A. mellifera is beeswax, which is composed of a complex suite of lipids including n-alkanes, n-alkanoic acids and fatty acyl wax esters. The composition is highly constant as it is determined genetically through the insect’s biochemistry. Thus, the chemical ‘fingerprint’ of beeswax provides a reliable basis for detecting this commodity in organic residues preserved at archaeological sites, which we now use to trace the exploitation by humans of A. mellifera temporally and spatially. Here we present secure identifications of beeswax in lipid residues preserved in pottery vessels of Neolithic Old World farmers. The geographical range of bee product exploitation is traced in Neolithic Europe, the Near East and North Africa, providing the palaeoecological range of honeybees during prehistory. Temporally, we demonstrate that bee products were exploited continuously, and probably extensively in some regions, at least from the seventh millennium cal bc, likely fulfilling a variety of technological and cultural functions. The close association of A. mellifera with Neolithic farming communities dates to the early onset of agriculture and may provide evidence for the beginnings of a domestication process.

Evaluación del uso de diferentes concentraciones de Acaricida Comercial en el control de Varroa (Varroa destructor), en apiario infestado

En nuestro país la explotación de la abeja Apis mellifera, se ve afectada por un gran número de enfermedades y plagas. En la actualidad la enfermedad que mayormente afecta a los apicultores es el acaro varroa (Varroa destructor ), que es un parásito externo. Por lo que se hace necesario buscar métodos alternos para el control de esta; como la utilización de productos químicos y naturales. En esta investigación la principal finalidad es comprobar, la efectividad del producto químico acaricida Amitraz, en diferentes dosificaciones: 1cc de Amitraz por 750 ml de agua, 2cc de Amitraz por 750 ml de agua, 3 cc de Amitraz por 750 ml de agua; a excepción de un tratamiento que no poseía ninguna dosis. La investigación se realizó en un apiario ubicado en el cantón el Paraisal Jurisdicción del municipio de Jucuapa Departamento de Usulután. Propiedad del Sr. Hansy Gregorio Gómez Díaz, Se evaluaron cuatro tratamientos: T0 sin ninguna aplicación de Amitraz T1 1cc de Amitraz, T2 2cc de Amitraz, T3 3cc de Amitraz. Todas las dosificaciones fueron diluidas en 750 ml de agua; el diseño estadístico que se utilizó fue un bloque completamente al azar con 5 repeticiones por tratamiento las variables evaluadas fueron: Porcentaje de infestación y eficiencia del producto Amitraz (número de ácaros muertos)

Purification and characterization of the biological effects of phospholipase A(2) from sea anemone Bunodosoma caissarum

Sea anemones contain a variety of biologically active substances. Bunodosoma caissarum is a sea anemone from the Cnidaria phylum, found only in Brazilian coastal waters. The aim of the present work was to study the biological effects of PLA(2) isolated from the sea anemone B. caissarum on the isolated perfused kidney, the arteriolar mesenteric bed and on insulin secretion. Specimens of B. caissarum were collected from the Sao Vicente Channel on the southern coast of the State of São Paulo, Brazil. Reverse phase HPLC analysis of the crude extract of B. caissarum detected three PLA(2) proteins (named BcPLA(2)1, BCPLA(2)2 and BcPLA(2)3) found to be active in B. caissarum extracts. MALDI-TOF mass spectrometry of BcPLA(2)1 showed one main peak at 14.7 kDa. The N-terminal amino acid sequence of BcPLA(2)1 showed high amino acid sequence identity with PLA(2) group III protein isolated from the Mexican lizard (PA23 HELSU, HELSU, PA22 HELSU) and with the honey bee Apis mellifera (PLA(2) and 1POC_A). In addition, BcPLA(2)1 also showed significant overall homology to bee PLA(2). The enzymatic activity induced by native BCPLA(2)1 (20 mu g/well) was reduced by chemical treatment with p-bromophenacyl bromide (p-BPB) and with morin. BcPLA(2)1 strongly induced insulin secretion in presence of high glucose concentration. In isolated kidney, the PLA(2) from B. caissarum increased the perfusion pressure, renal vascular resistance, urinary flow, glomerular filtration rate, and sodium, potassium and chloride levels of excretion. BcPLA(2)1, however, did not increase the perfusion pressure on the mesenteric vascular bed. In conclusion, PLA(2), a group III phospholipase isolated from the sea anemone B. caissarum, exerted effects on renal function and induced insulin secretion in conditions of high glucose concentration. (C) 2009 Elsevier Ltd. All rights reserved.

Inhibition of Neurotoxic Secretory Phospholipases A(2) Enzymatic, Edematogenic, and Myotoxic Activities by Harpalycin 2, an Isoflavone Isolated from Harpalyce brasiliana Benth

Secretory phospholipases A(2) (sPLA(2)) exert proinflammatory actions through lipid mediators. These enzymes have been found to be elevated in many inflammatory disorders such as rheumatoid arthritis, sepsis, and atherosclerosis. The aim of this study was to evaluate the effect of harpalycin 2 (Har2), an isoflavone isolated from Harpalyce brasiliana Benth., in the enzymatic, edematogenic, and myotoxic activities of sPLA2 from Bothrops pirajai, Crotalus durissus terrificus, Apis mellifera, and Naja naja venoms. Har2 inhibits all sPLA(2) tested. PrTX-III (B. pirajai venom) was inhibited at about 58.7%, Cdt F15 (C. d. terrificus venom) at 78.8%, Apis (from bee venom) at 87.7%, and Naja (N. naja venom) at 88.1%. Edema induced by exogenous sPLA(2) administration performed in mice paws showed significant inhibition by Har2 at the initial step. In addition, Har2 also inhibited the myotoxic activity of these sPLA(2)s. In order to understand how Har2 interacts with these enzymes, docking calculations were made, indicating that the residues His48 and Asp49 in the active site of these enzymes interacted powerfully with Har2 through hydrogen bonds. These data pointed to a possible anti-inflammatory activity of Har2 through sPLA(2) inhibition.