Food, feeding ecology and ecological segregation of seabirds at South Georgia

At the sub-Antarctic island of South Georgia 25 of the 29 breeding species are seabirds. Fifteen of these have recently been studied in some detail. By examining the timing of their breeding seasons and their diet and feeding ecology (especially feeding techniques and potential foraging ranges), the nature of their ecological isolating mechanisms, and in particular the way in which they partition the resources of the marine environment, are reviewed.
Although breeding season adaptations occur (winter breeding in Wandering Albatross and King Penguin; out of phase breeding in two species-pairs of small petrels) these are less important than dillerences in food and feeding ecology. There is a fundamental distinction between the niche of pursuit-diving species (mainly penguins) and the remainder which are basically surface-feeders. The two abundant krill-eating penguins show clear differences in feeding zones. Three albatrosses and a petrel feed mainly on squid and there are differences in both the species and size of the prey of each. The remaining seabirds chiefly take krill (although the giant petrels are extensive scavengers and some smaller petrels specialize on copepods) and utilize different feeding methods and areas to do so.
Various adaptations related to inshore and offshore feeding zones are discussed. Although most species possess a combination of ecological isolating mechanisms additional evidence for the particular importance of dietary differences is presented.     

Hox Genes and Segmental Patterning of the Vertebrate Hindbrain

SYNOPSIS. Pattern formation in the developing hindbrain andcranio-facial region has been studied in a range of vertebrateorganisms. The developing hindbrain is transiently segmentedinto units termed rhombomeres which correspond with domainsof gene expression, lineage restriction and neuronal organizationand serve to coordinate the migration of cranial neural crestinto the adjacent branchial arches. In this paper I review thecellular and molecular events underlying both hindbrain segmentationand the acquisition of segmental identity, consolidating recentresults from different model systems. Data suggesting that thevertebrate Hox genes play an important role in specifying positionalvalue to the rhombomeres and cranial neural crest are also examined.I compare expression patterns of the Hox genes between speciesand consider the mechanisms involved in controlling their appropriatespatial regulation. In addition I describe a recently characterizedzebraflsh hindbrain segmentation mutant, Valentino; morphological,cellular and gene expression data for this mutant are helpingto further our understanding of hindbrain patterning.     

Growth of Various Bacteria on Polycyclic Aromatic Hydrocarbons and N-2–Fluorenylacetamide

Several heterotrophic bacteria grew in nutrient broth medium containing high concentrations (10⁻⁵ M) of the potent carcinogenic compounds, benz[a]pyrene, 3-methylcholanthrene or N-2–fluorenylacetamide. They were capable of metabolizing the polycyclic aromatic hydrocarbons to smaller molecules and utilized these compounds as the sole source of carbon and energy. Identification of the metabolites formed from benz[a]pyrene revealed that the major metabolite (3-hydroxybenz[a]pyrene) of mammalian systems did not accumulate in any of these cultures when the standard fluorometric assay was used. Benz[a]pyrene metabolism profiles with high-pressure liquid chromatography also exhibited no accumulation of any metabolites (hydroxy, quinone and diol derivatives).     

Angiosperm phylogeny inferred from 18S rDNA, vbcL, and atpB sequences

A phylogenetic analysis of a combined data set for 560 angiosperms and seven outgroups based on three genes, 18S rDNA (1855 bp), rbcL (1428 bp), and atpB (1450 bp) representing a total of 4733 bp is presented. Parsimony analysis was expedited by use of a new computer program, the RATCHET. Parsimony jackknifing was performed to assess the support of clades. The combination of three data sets for numerous species has resulted in the most highly resolved and strongly supported topology yet obtained for angiosperms. In contrast to previous analyses based on single genes, much of the spine of the tree and most of the larger clades receive jackknife support 250%. Some of the noneudicots form a grade followed by a strongly supported eudicot clade. The early‐branching angiosperms are Amborellaceae, Nymphaeaceae, and a clade of Austrobaileyaceae, Illiciaceae, and Schi‐sandraceae. The remaining noneudicots, except Ceratophyllaceae, form a weakly supported core eumagnoliid clade comprising six well‐supported subclades: Chloranthaceae, monocots, WinteraceaeICanellaceae, Piperales, Laurales, and Magnoliales. Ceratophyllaceae are sister to the eudicots. Within the well‐supported eudicot clade, the early‐diverging eudicots (e.g. Proteales, Ranunculales, Trochodendraceae, Sabiaceae) form a grade, followed by the core eudicots, the monophyly of which is also strongly supported. The core eudicots comprise six well‐supported subclades: (1) Berberidopsidaceae/Aextoxicaceae; (2) Myrothamnaceae/ Gunneraceae; (3) Saxifragales, which are the sister to Vitaceae (including Leea) plus a strongly supported eurosid clade; (4) Santalales; (5) Caryophyllales, to which Dilleniaceae are sister; and (6) an asterid clade. The relationships among these six subclades of core eudicots do not receive strong support. This large data set has also helped place a number of enigmatic angiosperm families, including Podostemaceae, Aphloiaceae, and Ixerbaceae. This analysis further illustrates the tractability of large data sets and supports a recent, phylogenetically based, ordinal‐level reclassification of the angiosperms based largely, but not exclusively, on molecular (DNA sequence) data.