[Studies on microbodies in spadix appendices of Arum maculatum L. and Sauromatum guttatum schott]

[Studies on the change of microbody function in cotyledons of Helianthus annuus L]

The enzyme patterns in sunflower cotyledons indicate that the glyoxysomal function of microbodies is replaced by the peroxisomal function of these organelles during the transition from fat degradation to photosynthesis. The separation of the microbody population into glyoxysomes and peroxisomes during this transition period is reported. The mean difference in density between the activity peaks of glyoxysomal and peroxisomal marker enzymes on a sucrose gradient was calculated to be 0.007±0.004 g/cm(3) and turned out to be significant (t=7.8>4.04=t 5;0.01). The activity peak of catalase coincides with that of isocitrate lyase in early stages of development, but shifts to the activity peak of peroxisomal marker enzymes during the transition period. No isozymes of the catalase could be detected by gel electrophoresis in the microbodies with the two different functions.During the rise of the peroxisomal marker enzymes no synthesis of the common microbody marker, catalase, could be demonstrated using the inhibitor allylisopropylacetamide. Using D2) for density labeling of newly-formed catalase, no difference is observed between the density of catalase from cotyledons grown on 99.8% D2O during the transition period and the density of enzyme from cotyledons grown on H2O. The activity of particulate glycolate oxidase is reduced 30-50% by allylisopropylacetamide, but is not affected by D2O. The chlorophyll formation in the cotyledons is strongly inhibited by both substances.

[Microbodies and diaminobenzidine reaction in the acetate flagellates Polytomella caeca and Chlorogonium elongatum]

In two forms of acetate flagellates, the colourless Volvocale Polytomella caeca and the green Volvocale Chlorogonium elongatum, cell organelles can be demonstrated which are ultrastructurally similar to microbodies of higher organisms. The organelles do not have a close association with the endoplasmic reticulum and are located in the peripheral cytoplasm between the elongated mitochondria. In Polytomella they exhibit more or less spherical profiles in section and have a maximum diameter of approximately 0.2-0.25 μ. In Chlorogonium the organelles occasionally have an elongated shape and are larger than in Polytomella. Employing the electron microscopic cytochemical reagent diaminobenzidine (DAB)/H2O2 to localize the microbodial marker enzyme catalase in these organelles, it was found that no accumulation of the electron-opaque product occurs in the microbodies either at alkaline or neutral pH or at room temperature or 37° C. Only the cristae of mitochondria are stained with the DAB reaction caused by cytochrome oxidase and possibly by a cytochrome peroxidase.Organelles of Polytomella caeca containing catalase or cytochrome oxidase can be separated by rate centrifugation of a crude particulate fraction on a sucrose gradient (Gerhardt, 1971). The particles isolated from the peak of catalase activity show the same fine structural characteristics as the microbodies in situ do. But again, there is no detectable staining of these organelles by the DAB/H2O2 reaction.The identity of the microbody-like particles in Polytomella caeca and Chlorogonium elongatum with microbodies in general is deduced despite the negative results in cytochemical localization of catalase in these organelles.