Active aspartic proteinase is isolated from Brassica napus seeds and the peptide sequence is used to generate primers for PCR. We present here cDNA and genomic clones for aspartic proteinases from the closely related Brassicaceae Arabidopsis thaliana and Brassica napus. The Arabidopsis cDNA represents a single gene, while Brassica has at least 4 genes. Like other plant aspartic proteases, the two Brassicaceae enzymes contain an extra protein domain of about 100 amino acids relative to the mammalian forms. The intron/exon arrangement in the Brassica genomic clone is significantly different from that in mammalian genes. As the proteinase is isolated from seeds, the same tissue where 2S albumins are processed, this implies expression of one of the aspartic proteinase genes there.

The butterflies Pieris napi and Pieris bryoniae hybridize in a narrow zone at approximately 1200 m in the Alps and Carpathians of Europe. They feed as larvae on a variety of hosts in the Brassicaceae, and few host species occur on both sides of the hybrid zone. Females were captured on either side of the hybrid zone at Pont de Nant, Switzerland, eggs obtained, and larvae were offered plants from nineteen species of Brassicaceae and Reseda lutea (Resedaceae). Nine of the hosts were found to have eggs or larvae already on them. Only Capsella bursa-pastoris and R. lutea were unsuitable. Significant survivorship differences among suitable hosts were found. There was no interaction between butterfly species and host plant, which would indicate adaptation by these taxa to their respective suites of hosts. Among suitable hosts, larvae of both taxa had higher mortality on plants with hairy leaves and on older plants beginning to senesce. Differential selection on host use, if it occurs at all, is likely to be a very minor factor in the dynamics of the Pieris napi/bryoniae hybrid zone.

While phenotypic plasticity has been the focus of much research and debate in the recent ecological and evolutionary literature, the developmental nature of the phenomenon has been mostly overlooked. A developmental perspective must ultimately be an integral part of our understanding of how organisms cope with heterogeneous environments. In this paper I use the rapid cycling Arabidopsis thaliana to address the following questions concerning developmental plasticity. (1) Are there genetic and/or environmental differences in parameters describing ontogenetic trajectories? (2) Is ontogenetic variation produced by differences in genotypes and/or environments for two crucial traits of the reproductive phase of the life cycle, stem elongation and flower production? (3) Is there ontogenetic variability for the correlation between the two characters? I found genetic variation, plasticity, and variation for plasticity affecting at least some of the growth parameters, indicating potential for evolution via heterochronic shifts in ontogenetic trajectories. Within-population differences among families are determined before the onset of the reproductive phase, while among-population variation is the result of divergence during the reproductive phase of the ontogeny. Finally, the ontogenetic profiles of character correlations are very distinct between the ecologically meaningful categories of early- and late-flowering "ecotypes" in this species, and show susceptibility to environmental change.

The identity of a Puccinia species occurring on the introduced weed dyer's woad (Isatis tinctoria) was studied using sequences from the internal transcribed spacer of the nuclear ribosomal DNA. The relationship of this fungus to other Puccinia species occurring on the family Brassicaceae in Europe and North America was examined, and we tested the hypothesis that P. thlaspeos and P. monoica are correlated species. The data suggest that the Puccinia species from dyer's woad is closely related to the North American species P. consimilis and may be derived from an indigenous strain of P. consimilis that switched hosts. Thus, the Puccinia species from dyer's woad is probably native to North America and is unlikely to cause disease epidemics on indigenous plants if used as a biological control agent against dyer's woad. P. thlaspeos appears to be polyphyletic and, therefore, P. thlaspeos and P. monoica do not appear to be correlated species. Additional DNA sequence data will be needed to clarify further the phylogeny of Puccinia species on the family Brassicaceae.

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Members of the genus Lesquerella produce seed oil that contains a high proportion of hydroxy fatty acids (HFAs). There are three groups of Lesquerella species that are distinguished by their most abundant seed oil fatty acid: lesquerolic acid (20:1OH; e.g. Lesquerella fendleri), densipolic acid (18:2OH; e.g. Lesquerella kathryn), and auricolic acid (20:2OH; e.g. Lesquerella auriculata). To investigate the biochemistry of HFA production in Lesquerella species, the conversion of putative radiolabeled intermediates of HFA biosynthesis, including 18:1, 20:1, 18:1OH, 18:2OH, and 20:1OH, was examined in developing embryos of L. fendleri, L. kathryn, and L. auriculata. The results are consistent with (a) 18:1OH formation by hydroxylation of 18:1, (b) elongation and desaturation of 18:1OH to produce 20:1OH and 18:2OH, respectively, and (c) desaturation of 20:1OH to produce 20:2OH. The desaturation of 20:1OH was also found to occur in developing embryos of high, but not low, linolenic acid flax. This suggests that the desaturation is catalyzed by the extraplastidial linoleate desaturase. Confirming this suggestion, it was notable that 18:1OH and 18:2OH were found in low and high linolenic flax (Linum usitatissimum) seeds, respectively, at levels of 0.2 to 1%.