Senescence of Hydrilla leaves in light and darkness

Senescence of isolated leaves of Hydrilla verticillata (L.f.) Royle was studied in both darkness and light (20 μmol m⁻² s⁻¹). Senescence in the dark followed a general pattern of deterioration, i.e., gradual loss of cellular macromolecules like chlorophyll, protein and RNA with a concomitant rise in α-amino nitrogen, protease activity and tissue permeability. In light, however, an accelerated loss of chlorophyll took place although protein loss and increase in protease activity were retarded. A higher level of α-amino nitrogen in leaves in the light than in darkness could be correlated with lower leaching of free amino acids in light. Light decreased tissue permeability, as evidenced by lower conductivity of the incubation medium. In the light, RNA increased over the initial level. Both soluble and insoluble carbohydrates declined in the dark. The decline of insoluble carbohydrate was retarded by light, whereas soluble carbohydrate showed an initial rise and then declined sharply in the light.     

Effects of Some Chemical Compounds on the Slow, Far-red Induced Afterglow from Leaves of Elodea and the Lack of Effect of N-methyl Phena zonium Methosulfate on Far-red induced Glucose Uptake in Chlorella

N-methyl phenozonium methosulfate,3–(3,4-dichlorophe-nyl)–l, l-dimethylurea and carbonylcyanide-m-chlorophenyl hydrazone have similar effects on the slow, far-red induced afterglow component in intact Elodea leaves as has previously been shown for Chlorella. The first compound increases the rate constant for emission. Contrary to the case with Chlorella, it also markedly increases the total amount of light emitted from 10 sec. to infinity (maximally by 50 percent). The second compound decreases the rate constant and the amount of light, and the third compound increases the rate constant and decreases the amount of light. Electron micrographs are compared with the hypothetical units that can be deduced from the afterglow experiments, and it is found that the small thylakoids (“grana thylakoids”) have a size of the same order of magnitude as that expected for the afterglow units. The afterglow from Elodea, in contrast to that from Chlorella, is not affected by desaspidin except at extremely high concentrations. Far-red induced glucose uptake in Chlorella is not affected by 10^–7M N-methyl phenazonium methosulfate, which was previously shown to have a large effect on afterglow kinetics in the same organism.     

Relationship between power law coefficients and major blood constituents affecting the whole blood viscosity

The present work concerns a quantitative analysis of parameters that affect apparent blood viscosity at different low shear rates, i.e, between 1 s⁻¹ and, 100 s⁻¹. Viscosity profile of a large number of blood samples from thromboembolic stroke cases and age and sex matched healthy controls were studied which confirmed non-Newtonian power law behaviour of blood. The power law coefficients,n andk, which are unique to each blood sample, were related with blood viscosity parameters in the form of a mathematical equation by performing non-linear regression analysis. It was possible to calculaten andk of power law model by supplying the values of major blood constituents in the equation obtained for stroke and controls. The calculation ofn andk of a blood sample using the equation obtained, provided a quick information on its apparent viscosity values at any given shear rate without viscometry. The calculated and the experimental viscosity were found in good agreement within a permissible error range. The relation obtained between power law coefficients and major blood constituents in the present investigation would give a quantification of different blood viscosity parameters contributing to the resistance to flow of blood. Such an analysis may be considered as a scientific basis for the study of blood fluidity in different disease conditions.