Lipid and Protein Arrangement in Bacteriophage PM2

X-ray structure analysis shows that the lipid of bacteriophage PM2 is organized in a bilayer. These results provide a basis for interpreting electron micrographs of the virus in molecular terms.     

Some Effects of Amo-1618 on Growth, Peroxidase and α-Amylase Which Cannot Be Easily Explained by Inhibition of Gibberellin Biosynthesis

Growth and peroxidase activity of roots and stems of lentil seedlings were compared after treatment with Amo-1618, alone or in combination with gibberellic acid (GA) at varying concentrations. The peroxidase enhancement in Amo-1618 treated stems could not be attributed to a decrease in the gibberellin content since GA alone had no effect on this enzyme. In other experiments, AMO, at low concentrations, was able to induce α-amylase production in barley aleurone layers; the lag period needed for this induction, was longer than for GA. These facts seem to indicate that some growth retardants might act at least in some cases by mechanisms other than inhibition of gibberellin biosynthesis and reversal of GA action.     

Effect of Colchicine on Cell Membrane and on Biopterin Transport in Crithidia fasciculata*

SYNOPSIS. Incorporation of ¹⁴C-labeled biopterin into Crithidia fasciculata was inhibited by 1 mM colchicine or lumicolchicine. These substances do not penetrate the cell membrane, hence they cannot interact with the subpellicular microtubules. In view of this, interference of colchicine with biopterin transport must occur on the outer surface of the cell membrane. Binding of colchicine to Crithidia was not temperature-dependent and did not exhibit saturation kinetics. These facts exclude a binding as in the case of tubulin, or similar proteins which may be present in the membrane. The results suggest an inhibition reflecting steric hindrance of the biopterin carrier system.     

ATP-Driven Oscillation of Glycerol-Extracted Insect Fibrillar Muscle: Mechano-Chemical Coupling

Synchronous (fibrillar) insect flight muscle oscillates accordingto a myogenic rhythm. The oscillator is built into the contractilestructure, which can oscillate and perform work in a constantchemical environment with ATP as the only source of energy,when it has been isolated by glycerol-extraction. During oscillation,changes in tension follow changes in length with a delay, sincecontractile activity is switched on and off with a delay byelongation and shortening of the glycerol-extracted fibers (stretchactivates, and release of the fibers deactivates, the contractileATPase). Consequently, sinusoidal stretch and release induceoscillation (driven oscillation) associated with extra ATPaseactivity. The latter is proportional to the power-output, implyinga biochemical Fenn-effect. Power-output and ATPase activitycan be increased by raising the concentration of calcium or—atconstant chemical conditions—by increasing the frequencyorthe amplitude of driven oscillation, demonstrating a mechano-chemicalcoupling between mechanical performance(product of delayed tensionand speed of shortening) and enzymatic activity.     

Phakopsora pachyrhizi, the causal agent of Asian soybean rust

The plant pathogenic basidiomycete fungi Phakopsora pachyrhizi and Phakopsora meibomiae cause rust disease in soybean plants. Phakopsora pachyrhizi originated in Asia–Australia, whereas the less aggressive P. meibomiae originated in Latin America. In the New World, P. pachyrhizi was first reported in the 1990s to have spread to Hawaii and, since 2001, it has been found in South America. In 2004, the pathogen entered continental USA. This review provides detailed information on the taxonomy and molecular biology of the pathogen, and summarizes strategies to combat the threat of this devastating disease.
Taxonomy: Phakopsora pachyrhizi Syd. & P. Syd; uredial anamorph: Malupa sojae (syn. Uredo sojae ); Domain Eukaryota; Kingdom Fungi; Phylum Basidiomycota; Order Uredinales; Class Urediniomycetes; Family Phakopsoraceae; Genus Phakopsora ( http://www.indexfungorum.org ). The nomenclature of rust spores and spore-producing structures used within this review follows Agrios GN (2005) Plant Pathology , 5th edn. London: Elsevier/Academic Press.
Host range: In the field, P. pachyrhizi infects leaf tissue from a broad range (at least 31 species in 17 genera) of leguminous plants. Infection of an additional 60 species in other genera has been achieved under laboratory conditions.
Disease symptoms: At the beginning of the disease, small, tan-coloured lesions, restricted by leaf veins, can be observed on infected soybean leaves. Lesions enlarge and, 5–8 days after initial infection, rust pustules (uredia, syn. uredinia) become visible. Uredia develop more frequently in lesions on the lower surface of the leaf than on the upper surface. The uredia open with a round ostiole through which uredospores are released.