Seeds redistribution in sand dunes: a basis for coexistence of two rodent species

Spatial and temporal heterogeneity is a major factor structuring communities and contributing to coexistence of the species they contain. In this study we examine a critical aspect of environmental heterogeneity that is assumed to promote coexistence in two gerbil species of the Western Negev Desert. Previous studies assumed that temporal partitioning, in activity time, is the result of daily redistribution of seeds that the dominant species is the first to utilize while the sub-ordinate and efficient species is being pushed to use the later and poorer part of the night. We tested the assumption that daily afternoon winds generating spatial and temporal heterogeneity in seed availability by the redistribution of sand and seeds. This was done by comparing plots experiencing normal wind condition with manipulated plots where wind action was diminished by a shade-cloth fence. Our results show that considerable amount of sand and seeds are redistributing regularly on a time scale of a single day. Our results also show that gerbil foraging behavior is strongly related to the pattern of the redistribution dynamics of the seeds. When we prevented redistribution of seeds, gerbil foraging activity was reduced considerably. However, both seed redistribution and gerbil activity did not change much on control plots. Furthermore, the two gerbil species responded differently to the reduction in seed redistribution. The larger Gerbillus pyramidum was shown to be more sensitive to the reduction than the smaller G. a. allenbyi . Daily variability in the availability of seed resources is probably the niche axis which, together with the trade-off in foraging efficiency of the species, forms the mechanism for the coexistence of the two gerbil species in the semi-stabilized sands.     

THE FINE STRUCTURE OF THE GRASS GUARD CELL

Brown, W. V., and Sr. C. Johnson. (U. Texas, Austin.) The fine structure of the grass guard cell. Amer. Jour, Bot. 49 (2): 110–115. Illus. 1962.—An electron microscopic study of 16 species of grasses classified in 10 tribes and 5 subfamilies has revealed some hitherto unknown facts about guard-cell structure. In species of 3 subfamilies, but not in the Festucoideae, there are membranes on the guard cells overarching the stoma. In the Festucoideae, the membrane is rudimentary or absent and is associated with a different cross-sectional shape of the guard cell. The central canal through the thick-walled region of the guard cell is structurally quite complex. The wall between the central canal and the subsidiary cell is thin and lacks plasmodesmata. There are plastids but no developed chloroplasts in grass guard cells. Mitochondria are abundant, but vacuoles are undetectable. At the ends of the guard-cell pair, the wall between them is incomplete and the protoplasts are confluent.     

FURTHER OBSERVATIONS ON THE MECHANISM OF PHAGE ACTION

1. The reaction between an antistaphlycoccal phage and the homologous bacterium has been studied, applying the following experimental technics not used in earlier work reported from this laboratory: (a) Both the activity assay and the plaque count were utilized for determining [phage]. (b) Sampling was done at short intervals; i.e., every 0.1 hour. (c) Extracellular phage was separated from the cell-bound fraction by a filtration procedure permitting passage of < 95 per cent of free phage. 2. Using these technics, the reaction was followed: (a) with pH maintained at 6.10 and temperature at 28°C. to slow the process; (b) with pH maintained at 7.2 and temperature at 36°C. 3. In addition separate experiments were performed on the sorption of phage by bacteria at 30°, 23°, and 0°C. 4. At pH 6.10 and 28°C. the phage-bacterium reaction proceeds in the following sequence: (a) There is an initial phase of rapid logarithmic sorption of phage to susceptible cells, during which the total phage activity and the plaque numbers in the mixtures remain constant. (b) When 90 per cent of the phage has been bound, there is a sudden very rapid increase in phage activity not paralleled by an increase in plaques; i.e., phage is formed intracellularly, but is retained within cellular confines. (c) After a further drop in the extracellular phage fraction there occurs a pronounced increase in the total phage plaque count not accompanied by any increase in total activity. This indicates a redistribution of phage formed intracellularly. At the same time there is a rise in the extracellular phage curves (both activity and plaque). (d) With the concentrations of phage and bacteria used in the experiment carried out at pH 6.1 and 28°C. there are two further increments in [phage]_act. before massive lysis begins. (e) During terminal lysis there are sharp rises in the curves for [total phage]_plaq., [extracellular phage]_act., and [extracellular phage]_plaq.. (f) Immediately after the completion of lysis there is a considerable disparity between measurements of total phage and extracellular phage, probably occasioned by the association of phage molecules with cellular debris, the latter being of sufficient size to be removed by the super-cel filters. 5. At pH 7.2 and 36°C. the steps in the phage production curve as determined by activity assay and plaque count are much less prominent than those observed at pH 6.1 and 28°C. However, the plateaus described by Ellis and Delbrück (10) for B. coli and coli phage can be detected also in the present case if frequent samples are taken. 6. The sorption experiments show a significant rise in the rate of phage uptake with increase in temperature, again supporting the view that the reaction involves more than a purely physical adsorption. 7. Delbrück''s objections to: (a) the use of the activity assay for determining [total phage] in mixtures of phage and susceptible cells, and (b), to the demonstration of phage precursor in "activated" bacteria have been analyzed. 8. The activity assay has been demonstrated to be an accurate procedure for determining either phage free in solution or phage bound to living susceptible cells, under the conditions of the experiments reported here and in earlier work. 9. The titration values obtained in the experiments designed to exhibit intracellular phage precursor are not the result of artifacts as Delbrück has inferred. The data can be interpreted in terms of the precursor theory, although other explanations are not ruled out.