Selective light transmittance of translucent bracts in the Himalayan giant glasshouse plant Rheum nobile Hook. f. & Thomson (Polygonaceae)

Translucent bract transmittance of ultraviolet (UV) to infrared (IR) radiation (between 320 and 800 nm) and leaf anatomy were examined in a glasshouse plant, Rheum nobile Hook. f. & Thomson (Polygonaceae) to assess the function of avoiding injury by UV radiation while keeping the inflorescence warm by photosynthetically active (PA) and IR radiation. Although the translucent bracts and rosulate leaves transmitted little UV radiation, the former always transmit more PA and IR radiation. Additionally, the bracts transmit much more scattered solar radiation than direct radiation. The bracts are also anatomically different from the rosulate leaves. They have two or three layers of mesophyll cells with neither palisade nor spongy parenchymatous cells; in addition, the uppermost layer of mesophyll and the epidermis stain easily, and both are thought to play a role in attenuating UV radiation. The leaf epidermis of many land plants has UV absorbing pigments such as flavonoids, which absorb almost all UV radiation. Thus the role of the bracts of R. nobile is to protect the reproductive organs by absorbing UV radiation and to keep them warm by transmitting PA and IR radiation. The bracts are believed to have adapted function and form to the environment, in particular, to the weather conditions of the eastern Himalaya.     

Pollen development of Rheum nobile Hook.f. & Thomson (Polygonaceae), with reference to its sterility induced by bract removal

The Himalayan alpine herb, Rheum nobile , terminates in a stout conical compound raceme concealed by large translucent bracts. It bears many fruits even under hostile conditions such as low temperature or persistent cloudy weather. To clarify the role of the bracts, the structure and the development of the pollen grains were examined after removing the bracts to expose the flowers to the open air for 9 days. Half of the individuals with bracts removed showed 0 to 1 % of pollen stainability and the pollen grains were variable in shape and size. It was also observed that the bracts of Rheum nobile increased the temperature of inflorescence by about 10deg;C above ambient daytime temperatures. These results suggest that one of the causes for the inhibition of pollen development was low temperature. The remainder, however, indicated high stainability of 70–100%. It is suggested that the extreme difference of pollen stainability between two groups of Rheum nobile exposed to the surroundings may be related to the stage of microsporogenesis. Bracts of Rheum nobile might play an important role in normal reproduction under low temperature at high altitudes.     

Formation of Embryo Thromboblasts in Chick Blastoderm: Morphology, Site of Production and Time of Emergence in the Blood

Thrombocytes in the blood of chick embryos (termed embryo thrombocytes by L ucas and J amroz ) have PAS-positive granules in their cytoplasm. Electron microscopic observations reveal that the embryo thrombocytes contain glycogen granules present singly or in clumps. The presence of these inclusions and other morphological characteristics were used as specific markers to distinguish embryo thrombocytes from primitive erythroid cells. These markers also made it possible to determine the time at which the immature thromboblasts first emerge in blood vessels, and the period of their continued presence in the circulation. In this way we found that thromboblasts were detectable in embryos as early as stage 10⁺ of H amburger and H amilton (after 35 hr incubation) and that the thromboblasts were present in the circulation until day 4 of incubation (stage 23). In ovo and in vitro culture of de-embryonated blastoderm demonstrated that thromboblasts were formed in the area opeca vasculosa. The present observations suggest that embryo thromboblasts are formed at the same time and in the same area as the primitive cells of erythroid line.