Control of CO(2) Fixation by Cell-free Extracts of Chlamydomonas reinhardtii

Contrary to earlier reports, CO₂ fixation by extracts of Chlamydomonas is inhibited by glutamate and aspartate. These amino acids and some organic acids are shown to be inhibitors of phosphoenolpyruvate carboxylase. Inorganic phosphate is shown to activate CO₂ fixation, but there is a time lag before inorganic phosphate exerts its full activating effect.     

Dark Anaerobic Inactivation of Photosynthetic Oxygen Evolution by Chlamydomonas reinhardtii

When intact cells of Chlamydomonas reinhardtii were anaerobicallyincubated in the dark, rapid inactivation of oxygen evolutionwith benzoquinone as the Hill oxidant occurred. Measurementsof electron transport using thylakoids isolated after anaerobictreatment showed that the inactivation occurred at, or before,the secondary electron acceptor of PS II, whereas PS I activitywas largely unaffected. In addition, after anaerobic treatmentfluorescence transients measured with no addition or with dibromomethylisopropylbenzoquinonepresent were virtually the same as those obtained with DCMUpresent. When 10 mM NaHCO₃ was added to inactivated cells, partof the oxygen evolution capacity was restored rapidly. However,almost complete recovery (within 20 to 25 min) required theaddition of oxygen as well. This recovery was not light-dependentand was faster in the presence of 1 mM KCN. We suggest thatthe in activation of benzoquinone-dependent oxygen evolutionwas due to both bicarbonate depletion and reduction of the plastoquinonepool. ¹Present address: Institute of Molecular Biophysics, FloridaState University, Tallahassee, Florida 32306, U.S.A. (Received January 17, 1984; Accepted February 25, 1984)     

Colchicine-resistant mutants of Chlamydomonas reinhardi

Five colchicine-resistant mutant strains of Chlamydomonas reinhardi have been isolated. In colchicine-free medium they all have abnormally long cell doubling times and tend to occur within palmella envelopes, rather than as free-swimming cells. Zygote germination of all the mutants is abnormal, but crosses with wild type suggest that resistance is in each case due to a Mendelian mutation. It is suggested, though not proved, that the mutations may affect microtubular structures.     

Amide metabolism of Chlamydomonas reinhardi

Chlamydomonas reinhardi can utilise the lower aliphatic amides (C₁–C₄) as nitrogen sources. Of these only acetamide can serve as a sole carbon source. The acetamide analogue F-acetamide kills cells after conversion to F-acetate and F-citrate. This conversion is controlled by exogenous ammonia and, in part, acetate levels. Only one enzyme and one active site are involved in acetamidase function. Enzymatic analysis indicates an increased substrate range as compared to the growth — supported range, indicating uptake, toxicity or metabolic control restrictions.Abbreviations TCA trichloroacetic acid - TAP tris-acetate-phosphate medium - MIC mimmum inhibitory concentration - BSA bovine serum albumin     

Effect of Dihydrostreptomycin on Protein Synthesis in Whole Cells and in Cell-free Extracts of a Streptomycin-dependent Strain of Escherichia coli B

The effect of dihydrostreptomycin on the incorporation of amino acids into protein in antibiotic-deprived cells of a streptomycin-dependent strain of Escherichia coli B has been compared with its effect on protein synthesis in extracts from cells of the same strain. Stimulation of phenylalanine incorporation into protein in whole cells occurred within 5 min of addition of dihydrostreptomycin to a deprived culture and was maximal at an antibiotic concentration of 20 mug/ml. Stimulation of protein synthesis in cell-free extracts from antibiotic-deprived cells was maximal at a dihydrostreptomycin concentration of 10 mug/ml in systems programmed with f2-ribonucleic acid and poly AGU, whereas extracts from cells grown on nonlimiting concentrations of dihydrostreptomycin were unaffected by the addition of antibiotic. These results indicate that protein synthesis is an antibiotic-requiring process in streptomycin-dependent E. coli B.     

The Biological Clock in Chlamydomonas reinhardi

SYNOPSIS. Chlamydomonas reinhardi has a biological clock regulating phototaxis in dividing and non-dividing cultures; it also can exert some control on growth of continuous cultures. The period length is ∼ 24 hr; it is temperature-compensated and not dependent on the average growth rate. The rhythm can be entrained or phased by light-dark conditions. In dividing cultures a periodic fluctuation in cell number and total protein persists in continuous light.     

The Kok Effect in Chlamydomonas reinhardi

A Haxo-Blinks rate-measuring oxygen electrode together with a modulated light source gave an average current signal (change in net O₂ exchange) and a modulated current signal (photosynthetic O₂ evolution). Using this apparatus, net O₂ exchange and photosynthetic O₂ evolution at low intensities have been studied in the green alga, Chlamydomonas reinhardi. At both 645 nm and 695 nm, the curves of net O₂ exchange as a function of light intensity were steeper at lowest intensities than about compensation, indicative of the Kok effect. The effect was greater at 695 nm than at 645 nm. The corresponding curves of photosynthetic O₂ evolution, on the other hand, showed no Kok effect; here, the slope was lowest at lowest intensity. The absence of the Kok effect in O₂ evolution, together with its sensitivity to monofluoroacetic acid, show that it is due to an interaction of photosynthesis and respiration. The effect was exaggerated by 3-(3,4-dichlorophenyl)-1,1-dimethylurea. In the presence of concentrations of this inhibitor sufficient to inhibit O₂ evolution completely, a light-induced change in net O₂ exchange remained. This was interpreted as a system I dependent depression of respiratory O₂ uptake. The Kok effect remained undiminished in concentrations of carbonyl cyanide m-chlorophenylhydrazone and 2,4-dinitrophenol which partially uncoupled either oxidative phosphorylation alone or both oxidative and photosynthetic phosphorylations. The above results can be explained within a model of the Kok effect in which O₂ uptake is depressed by diversion of reductant away from respiratory electron transport and into photosystem I. The same photodepression of O₂ uptake also appears to account for a transient in net O₂ exchange seen in several algae upon turning off the light.     

Nutritional control of sexuality in Chlamydomonas reinhardi

1. Cells of Chlamydomonas reinhardi grown in the light or dark on standard medium require an additional exposure to light in the absence of a nitrogen source, in order to become sexually active. As the culture ages, the light requirement decreases. 2. This light requirement is a function of nitrogen depletion, as shown by the observation that cells from cultures grown to maturity on a low nitrogen medium in the light or in the dark, have no additional light requirement for zygote formation. The withholding of no other component of the medium has this effect. 3. In cells requiring light for zygote formation, the light can be supplied before the mating types are mixed, indicating that light is required, not for mating per se, but for the conversion of vegetative cells to gametes. 4. Gametes can be dedifferentiated to the vegetative state by any nitrogen compound which the cells can use for growth; and by further exposure to light in the absence of a nitrogen source, these vegetative cells can again become gametic. 5. Cells grown at different nitrogen levels become gametic at widely different cell concentrations of nitrogen and carbon and C/N ratios. 6. It is postulated that the role of light in gametic differentiation is indirect, providing by photosynthesis, energy for the mating process and carbohydrates to tie up excess nitrogenous reserves; and that the concentration of some particular nitrogen fraction or compound determines whether or not gametic differentiation is initiated.     

Effect of ethylmethanesulfonate on Chlamydomonas reinhardi

Summary Ethylmethane sulfonate (EMS) is known to cause a considerably high mutation rate in higher plants. In our experiments with Chlamydomonas reinhardi however, the mutagenic effect was unexpectedly low, whereas the toxic effect was quite remarkable. It is supposed that the reason for the low rate of mutants is the high toxicity, since non-toxic EMS concentrations induce no mutants. The toxic effect on Chlamydomonas cells is caused not only by the products of hydrolysis of the EMS, but also by the EMS itself. The damaged cells begin to bleach, furthermore they are not able to deliver their daughter cells. To a certain degree both effects are reversible. Finally it was found that the sensivity to EMS was higher in cells of the mating type — than it was in those of the+mating type.