Leaf structure and histochemistry of Ecballium elaterium (L.) A. Rich. (squirting cucumber)

Light, scanning and transmission electron microscopy as well as histochemical reactions were employed to study the leaf structure and secretory activity of Ecballium elaterium, a hairy pharmaceutical perennial common in the Mediterranean region. The amphistomatic leaf has a peculiar structure due to special cells supporting the conductive bundles, a remarkable shortage of mechanical tissue, and the existence of pectin strands between mesophyll cells. The secreting activity is limited mostly to secretary hairs. These attributes of the Ecballium leaf fine structures do not resemble the common structure of leaves from Mediterranean plants and point to a peculiar strategy of this species coping with stress conditions of its habitat.     

Numerical analysis of electrophoretic protein patterns of Group EF-4 bacteria, predominantly from dog-bite wounds of humans

Thirty-seven strains of Group EF-4 bacteria (from various countries) were characterized by one-dimensional SDS-PAGE of cellular proteins. They comprised 21 from dog-bite wounds of humans, three from cat-bite wounds of humans and five from human limb wounds which may have been inflicted by dogs or cats; there was also one each from a pet monkey, a tiger lung (fatal), a dog tonsil, a mouse, a cat liver, a wallaby mandible, a human vagina and one from a human limb wound which was apparently not inflicted by an animal. The protein patterns, which contained 45 to 50 discrete bands, were highly reproducible and were used as the basis for three numerical analyses. In the first, in which the principal protein bands (in the 34.8 to 41.3 kD range) were excluded, the 37 Group EF-4 strains formed, at the 62% S level, two major clusters corresponding to strains producing a dihydrolase for arginine and those not doing so. In the second analysis, which included all the protein bands and which was performed only on the 22 arginine-positive strains, two phenons formed (one of which could be further divided into two sub-phenons) at the 56% S level. The third analysis, also based on all the protein bands, divided the 15 arginine-negative strains into three clusters at the 56% S level. We conclude that high resolution PAGE combined with computerised analysis of protein patterns correlates exactly with the separation of Group EF-4 into two biovars (also with the distinction of the biovars on the basis of G+C content). Reference strains of each of the PAGE types identified are available from the NCTC for inclusion in future studies.     

The influence of the slowing of Earth's rotation: A hypothesis to explain cell division synchrony under different day duration in earlier and later evolved unicellular algae

Every year the Earth's rotation period is reduced, mainly due to the tidal drag of the moon. The length of day increases continuously by about 1 h every 200 million years. The period of rotation around the Sun remains constant; hence, the length of the year remains constant, so years acquire progressively fewer days. Many unicellular algae show rhythmicity in their cell division cycle. If primitive algae evolved under a shorter day duration, then it is possible that the early-evolved algae had to synchronize their cell division cycle to shorter lengths of day than did later-evolved algae. We tested this hypothesis by growing Cyanobacteria, Dinophyceae, Prasinophyceae, Bacillariophyceae and Conjugatophyceae (evolutionary appearance probably in this order) at 8∶8 h light-dark cycles (LD), 10∶10 LD, and 12∶12 LD, at 20 or 27°C. Cyanobacteria synchronized their cell division cycles optimally at 8∶8 h LD, Dinophyceae and Prasinophyceae at 10∶10 h LD, and Conjugatophyceae and Bacillariophyceae at 12∶12 h LD. The synchrony of cell division was scarcely affected by temperature. Results suggested that the early evolved unicellular autotrophic organisms such as the Cyanobacteria synchronized their cell division cycle under a shorter day duration than later-evolved unicellular algae, and these traits may have been conserved by quiescent genes up to the present day.