Phytochrome-induced Germination, Endosperm Softening and Embryo Growth Potential in Datura ferox Seeds: Sensitivity to Low Water Potential and Time to Escape to FR Reversal

In Datura ferox seeds, the far-red absorbing form of phytochrome(Pfr) induces endosperm softening, larger embryo growthpotential,and germination. We investigated the effect of exposing theseeds to a range of water potentials in the presence of Pfronits induction of these responses. In addition, the escape timeto far-red-light (FR) reversal of the three responses wasdetermined. Low water potential inhibited Pfr action on endosperm softeningand germination in a similar way. In both cases, a 50% reductionin the response to a saturating red-light (R) irradiation wasobserved at a water potential of c. —0·5 MPa andtherewas very good correlation between the percentage numberof seeds with softened endosperm at 45 h after R and germinationat 72 h after R (R2=0·95). In contrast, the effect ofdecreasing the external water potential on Pfr induction ofa larger embryogrowth potential was more complex. Moderate decreasesin water potential (—0·3 to —0·5 MPa)enhanced Pfr action and thegrowth potential of the embryos waslarger (20—25%) than the water controls; water potentialsbelow —0·7 MPa inhibited the Pfr stimulus. The escape time to FR reversal of the R effect was shorter forthe increase in embryo growth potential than for endospermsoftening.Twenty-four h after R, the embryo response had escaped in morethan 80% of the population whereas endospermsoftening and germinationwere susceptible to FR inhibition in 100% of the seeds. These results indicate that in D. ferox seeds the increase inembryo growth potential is not sufficient for germination andthatendosperm softening is a necessary condition. Key words: Germination, dormancy, phytochrome, endosperm softening, water potential     

Specificity of Cellular Immune Reactivity to Virus-induced Tumours

SPECIFICITY is one of the chief hallmarks of immune reactions. In many cases, specificity has been defined by reactivity against some antigens and not against others, but the results of direct tests may be misleading. In many cases, in transplantation and tumour immunology, direct reactivity may be absent in spite of the presence of the antigen. With HL-A antigens, the CYNAP phenomenon (cytotoxicity negative, absorption positive) has been described¹. Virus-induced tumours may have relatively small amounts of tumour specific cell surface antigens which are detectable only by absorption tests^2,3. In addition, immune reactions may occur against a particular antigen on one material and against different antigens on another material. With antibody reactions, specificity can be confirmed by the appropriate absorption experiments^4,5. With cellular immune reactions, comparable demonstration of specificity has been very difficult.     

Floral anatomy and systematics of Bretschneidera (Bretschneideraceae)

External morphology and anatomy of the flower and pollen of Bretschneidera sinensis Hemsl. are described to clarify the position of the family Bretschneideraceae relative to the Sapindales and the glucosinolate-producing families. Anatomical and micromorphological characters are investigated and sections are used to understand the structure of the flower. Observation of buds and sections reveal that the flower is obliquely monosymmetric, with the symmetry line running from one petal to a sepal. The upper petal shields the stamens and pistil and becomes positioned apically by the partial resupination of the pedicel. The octomerous androecium is characterized by variable empty positions which are related to the variable insertion of the three carpels. The loss of stamens is linked with a displacement of the remaining stamens. Floral anatomy demonstrates the presence of a nectary extending on the hypanthium from the base of the filaments to the base of the gynoecium. Details of floral anatomy are compared with members of Sapindaceae, Hippocastanaceae, Moringaceae, Akaniaceae, Tropaeolaceae and Capparaceae. Comparison with other characters supports a close relationship with Akaniaceae and Tropaeolaceae in an order Tropaeolales, in concordance with macromolecular results, either at the base of the glucosinolate clade, or in remote connection with the Sapindales. A number of floral anatomical characters with a strong phylogenetic signal are highlighted. © 2002 The Linnean Society of London, Botanical Journal of the Linnean Society , 2002, 139 , 29–45.     

Distribution of plant‐dwelling spiders: Inflorescences versus vegetative branches

Abstract The influence of the architecture of vegetative branches on the distribution of plant‐dwelling spiders has been intensively studied, and the effects on the aggregation of individuals in several spider species on plants include variation in prey abundance, availability of predator‐free refuges and smoother microclimate conditions. The emergence of inflorescences at the reproductive time of the plants changes branch architecture, and could provide higher prey abundance for the spiders. The distribution of spiders between inflorescences and vegetative branches was compared on four widespread plant species in a Brazilian savannah‐like system. Inflorescences attracted more spiders than vegetative branches for all plant species sampled. The influence of branch type (inflorescence and vegetative) on spider distribution was also evaluated by monitoring branches of Baccharis dracunculifolia DC. in vegetative and flowering periods for 1 year, and through a field experiment carried out during the same period where artificial inflorescences were available for spider colonization. Artificial inflorescences attached to B. dracunculifolia branches attracted more spiders than non‐manipulated vegetative branches for most of the year. However, this pattern differed among spider guilds. Foliage‐runners and stalkers occurred preferentially on artificial inflorescences relative to control branches. The frequencies of ambushers and web‐builders were not significantly different between treatment and control branches. However, most ambush spiders (65%) occurred only during the flowering period of B. dracunculifolia, suggesting that this guild was influenced only by natural inflorescences. The experimental treatment also influenced the size distribution of spiders: larger spiders were more abundant on artificial inflorescences than on vegetative branches. The hypothesis that habitat architecture can influence the spider assemblage was supported. In addition, our observational and experimental data strongly suggest that inflorescences can be a higher quality microhabitat than non‐reproductive branches for most plant‐dwelling spiders.