Produção de açafrão em função de acessos e do peso de rizomas-semente / Influence of the weight of seed-rhizomes in the production of turmeric

O açafrão-da-terra (Curcuma longa L.) é originário do sudeste asiático e subcontinente indiano. É uma herbácea de caule subterrâneo, alaranjado, com vários rizomas secundários aproveitados na indústria alimentícia e farmacêutica devido às características de cor, sabor, odor, produção de óleos essenciais, e corantes. Na escolha do melhor material propagativo deve-se levar em consideração o material genético, o peso, tamanho, idade, capacidade de reserva acumulada, sanidade, dentre outros fatores. O objetivo neste experimento foi avaliar a influencia de diferentes acessos e pesos de rizomas-sementes na produção de açafrão. Empregou-se o delineamento em blocos casualizados em parcelas subdivididas com quatro repetições, tendo como tratamento principal os acessos (C-06, C-36 e C-38) e como tratamento secundário as classes de rizomas-sementes (peso): pequeno, médio e grande, ±5, ±10 e ±15 g/rizoma, respectivamente. Após a colheita, os rizomas foram distribuídos sobre tela suspensa para secagem à sombra com ventilação natural, por 20 dias. Posteriormente, para avaliar a produção, os rizomas foram classificados em 4 classes: A (> 15g ), B (±10 g), C (±5 g) e D(<5g). A interação entre os acessos e o tamanho do rizoma-semente foi significativa para todas as variáveis, com exceção da Classe D. Com o uso de rizoma-semente grande os acessos C-38 e o C-06 apresentaram maior produtividade total, 0,834 e 0,812kg/planta, respectivamente. O descarte gerado foi menor no acesso C-38 do que no C-06, representando 7,8 e 12,8% da produção total, respectivamente. O uso de rizomas-semente maiores aumentou significativamente a produção total. No acesso C-06 a produção passou de 0,481 para 0,812 kg/planta, ou seja, um aumento de 70%. O ganho relativo na produção de rizoma (kg/planta) no acesso C-06 para o plantio de rizomas com ±15 g, foi de 28%.

Turmeric (Curcuma longa L) originated in Southeast Asia and the Indian subcontinent. It is an herbaceous plant with underground, orange stem with several secondary rhizomes used in the food and pharmaceutical industries, because of its characteristics of color, taste, smell, production of essential oils and dyes. In cultivation, the best choice of propagation material must take account the genetic material, weight, age, accumulated reserve capacity, sanity, among other factors. In this study, seed-rhizomes of three weight categories - small, medium and large -, ± 05, ± 10 and ± 15 g / rhizome, respectively, of three genetic materials - C-06, C-36 and C-38 - from the Germplasm Bank of the ESALQ / USP were cultured from December 2009 to August 2010, at a spacing of 0.5 mx 0.2 m. After harvest, they were distributed on canvas suspended for drying in the shade and natural ventilation for 20 days. Later, to evaluate the production, they were classified into four categories: A (> 15g), B (± 10 g), C (± 5 g) and D (<5g) .The interaction between accessions and size of seed-rhizomes was significant for all variables, except for category D. With the use of large seed-rhizomes, C-38 and C-06 had a higher total yield, with 0.834 and 0.812 kg/plant, respectively. The use of large seed-rhizomes increased significantly the total production. In C-06, the production increased from 0.481 to 0.812 kg/plant, i.e. an increase of 70%. Also in C-06, the relative gain in the production of rhizome (kg / plant) for the planting of seed-rhizomes with ± 15 g was 28%.

Estrutura genética populacional de Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae) utilizando marcadores microssatélites / Population genetic structure of Bemisia tabaci (Hemiptera: Aleyrodidae) utilizing microsatellite markers

We aimed to characterize the population genetic structure within and among five Bemisia tabaci (Gennadius) populations collected from different host plants and geographic regions by using microssatelites as a molecular marker. Each population was represented by 19 specimens. The host plants and geographic origins of these populations were described as follows: Pop 1: Squash Barreiras (BA); Pop 2: Cotton Barreiras (BA); Pop 3: Soybean Campinas (SP); Pop 4: Tomato Cruz das Almas (BA); and Pop 5: Soybean Rondonópolis (MT). Six polymorphic loci were observed, which discriminated 31 different alleles in the studied populations, with a mean number of alleles per population of 3.30 (2.67 - 4.00). Using Fisher's Exact test, it was observed that at least three populations were in Hardy-Weinberg equilibrium for most of the studied loci (six). The dendrogram (UPGMA) separated populations into groups mainly related to the geographic origin of the samples. Only population 5 differed from the others at a 0.15 distance (74.5 percent group consistency). The most similar populations were 1 and 2, with a 0.01 distance (65.3 percent). This is in agreement with their geographic origins and it was not consistent with host specificity. The results suggest considerable gene flow (7.3 percent) among all whitefly populations and indicate that a better understanding of the gene flow in populations of B. tabaci associated with different hosts is required for the management of this insect.