Techniques for the In Vitro Production of Queens in Stingless Bees (Apidae, Meliponini)

Considering the ecological importance of stingless bees as caretakers and pollinators of a variety of native plants makes it necessary to improve techniques which increase of colonies' number in order to preserve these species and the biodiversity associated with them. Thus, our aim was to develop a methodology of in vitro production of stingless bee queens by offering a large quantity of food to the larvae. Our methodology consisted of determining the amount of larval food needed for the development of the queens, collecting and storing the larval food, and feeding the food to the larvae in acrylic plates. We found that the total average amount of larval food in a worker bee cell of E varia is approximately 26.70 +/- 3.55 mu L. We observed that after the consumption of extra amounts of food (25, 30, 35 and 40 mu L) the larvae differentiate into queens (n = 98). Therefore, the average total volume of food needed for the differentiation of a young larva of F. varia queen is approximately 61.70 +/- 5.00 mu L. In other words; the larvae destined to become queens eat 2.31 times more food than the ones destined to become workers. We used the species Frieseomelitta varia as a model, however the methodology can be reproduced for all species of stingless bees whose mechanism of caste differentiation depends on the amount of food ingested by the larvae. Our results demonstrate the effectiveness of the in vitro technique developed herein, pointing to the possibility of its use as a tool to assist the production of queens on a large scale. This would allow for the artificial splitting of colonies and contribute to conservation efforts in native bees.

Proteomic Analysis of Chloroplast-to-Chromoplast Transition in Tomato Reveals Metabolic Shifts Coupled with Disrupted Thylakoid Biogenesis Machinery and Elevated Energy-Production Components

A comparative proteomic approach was performed to identify differentially expressed proteins in plastids at three stages of tomato (Solanum lycopersicum) fruit ripening (mature-green, breaker, red). Stringent curation and processing of the data from three independent replicates identified 1,932 proteins among which 1,529 were quantified by spectral counting. The quantification procedures have been subsequently validated by immunoblot analysis of six proteins representative of distinct metabolic or regulatory pathways. Among the main features of the chloroplast-to-chromoplast transition revealed by the study, chromoplastogenesis appears to be associated with major metabolic shifts: (1) strong decrease in abundance of proteins of light reactions (photosynthesis, Calvin cycle, photorespiration) and carbohydrate metabolism (starch synthesis/degradation), mostly between breaker and red stages and (2) increase in terpenoid biosynthesis (including carotenoids) and stress-response proteins (ascorbate-glutathione cycle, abiotic stress, redox, heat shock). These metabolic shifts are preceded by the accumulation of plastid-encoded acetyl Coenzyme A carboxylase D proteins accounting for the generation of a storage matrix that will accumulate carotenoids. Of particular note is the high abundance of proteins involved in providing energy and in metabolites import. Structural differentiation of the chromoplast is characterized by a sharp and continuous decrease of thylakoid proteins whereas envelope and stroma proteins remain remarkably stable. This is coincident with the disruption of the machinery for thylakoids and photosystem biogenesis (vesicular trafficking, provision of material for thylakoid biosynthesis, photosystems assembly) and the loss of the plastid division machinery. Altogether, the data provide new insights on the chromoplast differentiation process while enriching our knowledge of the plant plastid proteome.

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.