The impact of pH on interactions among phytoplankton algae, zooplankton and perch (Perca fluviatilis) in a shallow, fertile lake

1. The combined effects of increasing pH (< 9–11) and increasing densities of perch (0, two, four per enclosure) have been investigated in polyethylene enclosures of volume about 1100 1 in a shallow, fertile lake in Cheshire. 2. Increasing pH decreased carbon dioxide concentrations, chlorophyll a concentrations and diatom biomass. It led to increases in the proportions of Cryptophyta (to pH 10) and Chlorophyta (to pH 11). Although ample inocula were present, significant growths of cyanophytes were not recorded, contrary to expectation. 3. Increasing pH led to increases in numbers of Daphnia hyalina particularly at pH 10 but collapse at pH 11. This persistence at pH 10, independent of perch number, is attributed to reduced feeding of the fish, which survived at this pH. Other zooplankters (Ceriodaphnia spp., Bosmina longirostris, Polyphemus pediculus, Cyclops spp.) all declined with increasing pH. 4. Increasing fish density resulted in an increase in chlorophyll a concentration and in the biomass of Chlorophyta but had no effect on cyanophyte or cryptophyte biomass. 5. Increasing fish density led to declines in Daphnia in the untreated lake-water controls (pH < 9) and at pH 9, but had no effect at pH 10 where Daphnia hyalina was very abundant. Numbers of Ceriodaphnia spp. and Bosmina longirostris increased with increasing fish density, whilst numbers of Polyphemus pediculus and Cyclops spp. were independent of it. 6. The results are discussed in the light of contemporary knowledge of the factors resulting in large cyanophyte growths and of the factors controlling the stability of macrophyte-dominated and phytoplankton-dominated states in shallow lakes. The interaction between pH and fish density and consequent non-linear response of Daphnia hyalina is particularly notable because of the significance of zooplankton grazing in shallow lakes.     

Microfilaments, Cell Shape Changes, and Morphogenesis of Salivary Epithelium

The evidence supporting the idea that microfilament-mediatedcell shape changes produce morphogenetic movements of the salivaryepithelium is reviewed. The correlations between microfilamentsand morphogenesis and microtubules and morphogenesis, as revealedby experiments with cytochalasin B and colchicine respectively,are compared and contrasted. On the basis of a correlation betweenmicrofilament integrity and epithelial morphogenesis, and anactin-like nature of microfilaments to bind heavy meromyosin,it is proposed that microfilament contraction is required forcleft formation in the epithelium. Several ways in which microfilamentactivity might be regulated during morphogenesis are discussedin the framework of experiments that may comment on such regulation.