Efeito alelopático das folhas de Schinus terebinthifolius Raddi em espécies nativas da restinga de Massambaba

Schinus terebinthifolius Raddi (Anacardiaceae) é uma espécie nativa da América do Sul com grande distribuição geográfica e muito comum em áreas de restinga. Sua grande plasticidade ecológica e boa interação biótica a torna espécie-chave na restauração de ambientes, porém, sua dominância pode estar relacionada à liberação de compostos alelopáticos. O objetivo do estudo foi avaliar o potencial alelopático dos extratos aquosos e óleos essenciais de folhas de Schinus terebinthifolius nas diferentes estações do ano sobre espécies-alvo nativas da restinga (Cereus fernambucensis, Erythroxylum ovalofolium, Pilosocereus arrabidae), uma espécie agrícola (Lactuca sativa) e nela própria (autoalelopatia). Para isso, suas folhas foram coletadas sazonalmente na restinga de Massambaba para o preparo dos extratos aquosos e extração dos óleos essenciais. Os extratos aquosos foram obtidos através da secagem das folhas a 60 C, trituração em liquidificador, diluição em água destilada e filtração, obtendo as concentrações de 5, 10, 15 e 20%. As extrações dos óleos foram realizadas através da hidrodestilação de 300 g de folhas frescas. A análise da composição dos óleos essenciais foi realizada através de cromatografia gasosa utilizando fibra SPME. O efeito fitotóxico foi avaliado nas espécies-alvo através da porcentagem de germinação, velocidade de germinação, crescimento aéreo e radicular, condutividade elétrica e massa seca. O efeito alelopático dos extratos aquosos foi observado em todas as espécies-alvo, principalmente sobre as espécies nativas. Esse efeito variou nas estações do ano de forma dose-dependente e espécie-específica. Os óleos essenciais de S. terebinthifolius também foram capazes de inibir a germinação e crescimento das espécies-alvo, e, da mesma forma que os extratos aquosos, esses efeitos variaram nas estações do ano e para cada espécie. Sugere-se que essas diferenças estejam relacionadas às fenofases de S. terebinthifolius e condições ambientais da restinga. Esse efeito fitotóxico, se comprovado em campo, pode restringir a utilização de S. terebinthifolius na restauração de ambientes.

Genetic variation of rougheye rockfish (Sebastes aleutianus) and shortraker rockfish (S. borealis) inferred from allozymes

Rougheye rockfish (Sebastes aleutianus) and shortraker rockfish (Sebastes borealis) were collected from the Washington coast, the Gulf of Alaska, the southern Bering Sea, and the eastern Kamchatka coast of Russia (areas encompassing most of their geographic distribution) for population genetic analyses. Using starch gel electrophoresis, we analyzed 1027 rougheye rockfish and 615 shortraker rockfish for variation at 29 proteincoding loci. No genetic heterogeneity was found among shortraker rockfish throughout the sampled regions, although shortraker in the Aleutian Islands region, captured at deeper depths, were found to be significantly smaller in size than the shortraker caught in shallower waters from Southeast Alaska. Genetic analysis of the rougheye rockfish revealed two evolutionary lineages that exist in sympatry with little or no gene f low between them. When analyzed as two distinct species, neither lineage exhibited heterogeneity among regions. Sebastes aleutianus seems to inhabit waters throughout the Gulf of Alaska and more southern waters, whereas S. sp. cf. aleutianus inhabits waters throughout the Gulf of Alaska, Aleutian Islands, and Asia. The distribution of the two rougheye rockfish lineages may be related to depth where they are sympatric. The paler color morph, S. aleutianus, is found more abundantly in shallower waters and the darker color morph, Sebastes sp. cf. aleutianus, inhabits deeper waters. Sebastes sp. cf. aleutianus, also exhibited a significantly higher prevalence of two parasites, N. robusta and T. trituba, than did Sebastes aleutianus, in the 2001 samples, indicating a possible difference in habitat and (or) resource use between the two lineages.

Effects of current speed and turbidity on stationary light-trap catches of larval and juvenile fishes

Light traps are one of a number of different gears used to sample pelagic larval and juvenile fishes. In contrast to conventional towed nets, light traps primarily collect larger size classes, including settlement-size larvae (Choat et al., 1993; Hickford and Schiel, 1999 ; Hernandez and Shaw, 2003), and, therefore, have become important tools for discerning recruitment dynamics (Sponaugle and Cowen, 1996; Wilson, 2001). The relative ease with which multiple synoptic light trap samples can be taken means that larval distribution patterns can be mapped with greater spatial resolution (Doherty, 1987). Light traps are also useful for sampling shallow or structurally complex habitats where towed nets are ineffective or prohibited (Gregory and Powles, 1985; Brogan, 1994; Hernandez and Shaw, 2003).

Cross-shelf and seasonal variation in larval fish assemblages on the southeast United States continental shelf off the coast of Georgia

Seasonal and cross-shelf patterns were investigated in larval fish assemblages on the continental shelf off the coast of Georgia. The influence of environmental factors on larval distributions also was examined, and larval transport processes on the shelf were considered. Ichthyoplankton and environmental data were collected approximately every other month from spring 2000 to winter 2002. Ten stations were repeatedly sampled along a 110-km cross-shelf transect, including four stations in the vicinity of Gray’s Reef National Marine Sanctuary. Correspondence analysis (CA) on untransformed community data identified two seasonal (warm weather [spring, summer, and fall] and winter) and three cross-shelf larval assemblages (inner-, mid-, and outer-shelf ). Five environmental factors (temperature, salinity, density, depth of the water column, and stratification) were related to larval cross-shelf distribution. Specifically, increased water column stratification was associated with the outer-shelf assemblage in spring, summer, and fall. The inner shelf assemblage was associated with generally lower temperatures and lower salinities in the spring and summer and higher salinities in the winter. The three cross-shelf regions indicated by the three assemblages coincided with the location of three primary water masses on the shelf. However, taxa occurring together within an assemblage were transported to different parts of the shelf; thus, transport across the continental shelf off the coast of Georgia cannot be explained solely by twodimensional physical factors.