The development of sporulation competence in Physarum polycephalum.

Plasmodial cells of the slime mold Physarum polycephalum become “competent” for sporulation following a prolonged period of dark starvation in the presence of nicotinamide. Sporulation can then be induced by illumination. Plasmodia are found to release into the medium during starvation one or more cellular products that promote sporulation. These products exert their effect specifically during the dark starvation period, rather than during the final phase of fruiting body construction. The sporulation control factor(s) (SCF) is nondialyzable and can stimulate the development of sporulation competence in the absence of nicotinamide.     

Selective gene expression during sporulation of Physarum polycephalum.

The two-dimensional gel electrophoresis of polypeptides synthesized in vitro from poly(A)+ RNA showed that mRNA populations change during sporulation of Physarum polycephalum. The differential hybridization of a cDNA library prepared from poly(A)+ RNA isolated from sporulating cells revealed that of 846 clones, 64 corresponded to sporulation-specific mRNAs. Further analysis demonstrated that these clones contained seven different sequences: three abundant sequences composing 3.2, 1.8, and 1.2% of the library and four other less abundant sequences. It is probable that all the major mRNAs specifically expressed in early stages of sporulation were identified. The most abundant mRNA from this group coded for a hydrophobic protein that contained a signal peptide. This protein is 47% similar to another Physarum protein, which was encoded by the most abundant plasmodium-specific mRNA. The plasmodial mRNA was degraded during sporulation and was replaced by the sporulation mRNA. These two proteins are thus encoded by members of a gene family whose expression is developmentally regulated.     

Pigmentation and sporulation in selected Myxomycetes

Chemical, chromatographic and spectrometric methods are used to characterize plasmodial pigments and determine relationships between pigmentation and sporulation in selected Myxomycetes. In Physarum gyrosum (white) a single pigment is identified and characterized as a flavone. Physarum polycephalum (yellow) and Didymium iridis (brown) contain four and six components, respectively, in their plasmodial pigments which test negatively for flavones but show the presence of some type of phenolic compound. No detectable component is identified in the white plasmodium of Didymium squamulosum which proved to be independent of light for fruiting. The absorption spectra of all species that were light sensitive for fruiting showed common peaks in the 300–400-mμ region, among others. Pigment changes associated with light absorption are reported for some white, yellow and brown plasmodial types. In Physarum gyrosum a yellow pigment forms in light which did not show the characteristic flavones present in the white plasmodial stage. Changes in absorption spectra are reported for Physarum polycephalum, Didymium iridis and Didymium squamulosum as the plasmodial pigments change prior to fruiting. Results show a close relationship between the physiology of plasmodial pigmentation and sporulation in the Myxomycete species studied.     

Hybrids of Physarum myosin light chains and desensitized scallop myofibrils

The two light chains of Physarum myosin have been purified in a 1:1 ratio with a yield of 0.5-1 mg/100 g of plasmodium and a purity of 40- 70%; the major contaminant is a 42,000-dalton protein. The 17,700 Mr Physarum myosin light chain (PhLC1) binds to scallop myofibrils, providing the regulatory light chains (ScRLC) have been removed. The 16,500 Mr light (PhLC2) does not bind to scallop myofibrils. The calcium control of scallop myosin ATPase is lost by the removal of one of the two ScRLC's and restored equally well by the binding of either PhLC1 or rabbit skeletal myosin light chains. When both ScRLC's are removed, replacement by two plasmodial light chains does not restore calcium control as platelet or scallop light chains do. Purified plasmodial actomyosin does not bind calcium in 10(-6) M free calcium, 1 mM MgCl2. No tropomyosin was isolated from Physarum by standard methods. Because the Physarum myosin light chains can substitute only partially for light chains from myosin linked systems, because calcium does not bind to the actomyosin, and because tropomyosin is apparently absent, the regulation of plasmodial actomyosin by micromolar Ca++ may involve other mechanisms, possibly phosphorylation.     

Time-resolved detection of three intracellular signals controlling photomorphogenesis in Physarum polycephalum.

Incompetent plasmodia of Physarum polycephalum exposed to a light pulse sporulated after reaching the competent stage. Fusion of irradiated plasmodia with dark-incubated plasmodia and analysis of sporulation indicated the presence of a morphogenetic signal. It is concluded that a logic AND gate integrates the photoreceptor signal and the competence signal and controls the formation of the morphogenetic signal.     

Theory of time-resolved somatic complementation and its use to explore the sporulation control network in Physarum polycephalum

Mutants of Physarum polycephalum can be complemented by fusion of plasmodial cells followed by cytoplasmic mixing. Complementation between strains carrying different mutational defects in the sporulation control network may depend on the signaling state of the network components. We have previously suggested that time-resolved somatic complementation (TRSC) analysis with such mutants may be used to probe network architecture and dynamics. By computer simulation it is now shown how and under which conditions the regulatory hierarchy of genes can be determined experimentally. A kinetic model of the sporulation control network is developed, which is then used to demonstrate how the mechanisms of TRSC can be understood and simulated at the kinetic level. On the basis of theoretical considerations, experimental parameters that determine whether functional complementation of two mutations will occur are identified. It is also shown how gene dosage-effect relationships can be employed for network analysis. The theoretical framework provided may be used to systematically analyze network structure and dynamics through time-resolved somatic complementation studies. The conclusions drawn are of general relevance in that they do not depend on the validity of the model from which they were derived.     

On the importance of calcium and magnesium ions in yeast sporulation

Irrespective of the nutritional conditions, the sporulation frequency of wild and industrially used yeasts on agar or agarose plates has been found to vary from one experiment to another. An analysis of agar- and agarose-extracts by ion-exchange column chromatography proved that the amount of calcium and/or magnesium ions contained in the agar was a factor in the fluctuation of sporulation frequency. Furthermore, these two cations enhanced the formation of four-spored asci. When calcium or magnesium ions were added to a nutrition-deprived medium solidified with agarose containing no detectable calcium and magnesium ions, wild and industrially used sake yeasts efficiently sporulated with a frequency of 10–40%. A strictly controlled sporulation condition suitable for the analysis of meiosis and sporulation of yeast cells was constructed by using calcium and/or magnesium ions and highly purified agarose.     

SPORULATION OF THE YEAST, HANSENULA SATURNUS: I. EFFECT OF MAGNESIUM AND CALCIUM IONS

Sporulation in a strain of the wild yeast, Hansenula saturnus,was investigated. The yeast was found to form spores even indistilled water. The sporulation rate (percentage of ascus-bearingindividuals) in this case was found to be markedly affectedby the cell concentration adopted in the test. The addition of inorganic nutrients to the sporulation mediumstimulates sporulation. The yeast requires either magnesiumor calcium for growth and sporulation. Higher concentrationsof these ions are required for sporulation than for growth.In both cases magnesium is effective at more dilute concentrationsthan calcium. Under the conditions of the experiments, in which the yeastforms a pellicle, the sporulation rate in the pellicle far exceedsthat in the sediment. The effects of environmental factors on the sporulation wasconsidered in relation to growth. It was found that, under theconditions of poor growth in the sporulation culture, no exogenousmagnesium and calcium are required for sporulation. In suchcases, the yeast cells are inferred to have an endogenous stockof magnesium and calcium enough for the sporulation. ¹ Present address: Laboratory of Microbiology, Department ofAgriculture, Tôhoku University, Sendai. (Received May 4, 1961; )     

Day/Night Changes in the Sensitivity of Phosphoenolpyruvate Carboxylase to Malate during Crassulacean Acid Metabolism

Phosphoenolpyruvate carboxylase (PEPC) was extracted from Mesembryanthemum crystallinum L. performing Crassulacean acid metabolism, at frequent intervals during a 12-hour light/12-hour dark cycle. Inhibition of PEPC by malate was followed at pH 8.0 and 7.5, 1 minute after homogenization of leaves. PEPC was more sensitive to malate during the light than during the dark periods and inhibition by malate was more pronounced at pH 7.5 than 8.0. For example, PEPC was not or only slightly inhibited by 0.5 millimolar malate during the dark period at both pH values and the rates per milligram chlorophyll were about the same. During the light period, 0.5 millimolar malate resulted in a 20 to 30% reduction of PEPC activity at pH 8.0 and a 80 to 90% reduction at pH 7.5. These and other experiments, in which plants were kept in prolonged dark periods, indicate that the increase in sensitivity of PEPC to malate is correlated with the change from acidification to deacidification in the tissue. These interactions account for apparent changes in pH response of PEPC in crude extracts assayed at different times of the day/night cycle.     

Description and life cycle of a new Physarum (Myxomycetes) from the Atacama Desert in Chile

A new species of Physarum (Myxomycetes), Physarum atacamense is described in this paper, and details are provided on its life cycle as observed in spore-to-spore culture in agar. The new species was collected during studies of the Atacama Desert in Chile. It has been collected directly in the field and isolated in moist chamber cultures prepared with material from an endemic cactus. The combination of characters that make this species unique in the genus are its large fusiform nodes of the capillitium, its long, bicolored stalk and the very dark brown and densely warted angular spores. The morphology of specimens of this myxomycete was examined with scanning electron microscopy and light microscopy, and micrographs of relevant details and life cycle stages are included in this paper. The importance of resistant stages in the life cycle of this myxomycete is stressed, and the close association of this myxomycete with its plant substrates is discussed.     

Thermodynamics of Malate Transport across the Tonoplast of Leaf Cells of CAM Plants

The electrochemical potential difference for each dissociationstate of malic acid across the tonoplast of leaf cells was examinedin two CAM plants, Graptopetalum paraguayense and Kalanchoëdaigremontiana. The concentration of malic acid in each dissociationstate was estimated from an analysis of pH and concentrationsof ionic species that included calcium, malate and isocitrate.The vacuoles contained 30–40 mM isocitrate and 50–70mM calcium in G. paraguayense, and 20–30 mM isocitrateand 70–100 mM calcium in K. daigremontiana. For the calculationof the pattern of dissociation of malic acid, the formationof chelates of calcium with malate and isocitrate, which havedifferent stability constants depending on the dissociationof the acids, were also taken into consideration. The vacuolarconcentrations of the divalently dissociated form of malic acid(mal^2– were 4–7 mM and 1-3 mM in G. paraguayenseand in K. daigremontiana, respectively. To obtain informationabout the cytoplasmic concentration of malate, the apparentinhibition constant for malate of phosphoenolpyruvate carboxylasewas measured. It was about 330 µM in the dark period and60 µM in the light period. Considering an inside-positivemembrane potential, we conclude that mal^2– can be takenup passively into the vacuole during the dark period and canbe released passively from the vacuole during the light period.Two types of channel (the "SV-type" channel and a novel "MU-type"channel) which we found recently in G. paraguayense [Iwasakiet al. (1992) Plant Physiol. 98: 1494] are probably involvedin the uptake and the release of malate in the diurnal CAM rhythm.The existence of a large pH-buffering capacity due to isocitricacid in the vacuole allows the accumulation of a large amountof malic acid during the diurnal CAM rhythm. (Received February 12, 1992; Accepted July 10, 1992)     

Light modulation of maize leaf phosphoenolpyruvate carboxylase

Phosphoenolpyruvate carboxylase (PEPC) was extracted from maize (Zea mays L. cv Golden Cross Bantam T51) leaves harvested in the dark or light and was partially purified by (NH₄)₂SO₄ fractionation and gel filtration to yield preparations that were 80% homogeneous. Malate sensitivity, PEPC activity, and PEPC protein (measured immunochemically) were monitored during purification. As reported previously, PEPC from dark leaves was more sensitive to malate inhibition compared to enzyme extracted from light leaves. Extraction and purification in the presence of malate stabilized the characteristics of the two forms. During gel filtration on Sephacryl S-300, all of the PEPC activity and PEPC protein emerged in a single high molecular weight peak, indicating that no inactive dissociated forms (dimers, monomers) were present. However, there was a slight difference between the light and dark enzymes in elution volume during gel filtration. In addition, specific activity (units at pH 7/milligram PEPC protein) decreased through the peak for both enzyme samples; because the dark enzyme emerged at a slightly higher elution volume, it contained enzyme with a relatively lower specific activity. The variation in specific activity of the dark enzyme corresponded with changes in malate sensitivity. Immunoblotting of samples with different specific activity and malate sensitivity, obtained from gel filtration, revealed only a single polypeptide with a relative molecular mass of 100,000. When the enzyme was extracted and purified in the absence of malate, characteristic differences of the light and dark enzymes were lost, the enzymes eluted at the same volume during gel filtration, and specific activity was constant through the peak. We conclude that maize leaf PEPC exists in situ as a tetramer of a single polypeptide and that subtle conformation changes can affect both enzymic activity and sensitivity to malate inhibition.     

NADP regulates the light activation of NADP-dependent malate dehydrogenase

The chloroplastic NADP-dependent malate-dehydrogenase (EC 1.1.1.82) activity is modulated by light and dark. The enzyme is activated upon illumination of intact or broken chloroplasts or by incubation with dithiothreitol, whereas dark has the opposite effect. The present communication shows an additional regulation of the light modulation: in isolated intact pea chloroplasts, light activation was inhibited in the presence of electron acceptors such as sodium bicarbonate, 3-phosphoglycerate or oxaloacetate, which consume NADPH₂ and produce NADP. With broken chloroplasts, addition of NADP resulted in a pronounced lag phase of NADP-dependent malate dehydrogenase light activation, while NADPH₂ was without any effect. The extent of the lag phase was correlated to the amount of NADP added. When light was replaced by dithiotreitol, the inhibition effect was even more pronounced. It was assumed that NADP inhibits the modulation reaction directly: reduced thioredoxin, a potent mediator of activation by light, or dithiotreitol appear to counteract NADP in a competitive manner. The results indicate a physiological role of NADP in the regulation of chloroplastic NADP-dependent malate dehydrogenase which is capable of removing electrons from the chloroplast, via oxaloacetate reduction and malate export. Thus an NADP concentration sufficient for continuous photosynthetic electron flow may be achieved.     

Role of intracellular calcium and sodium in light adaptation in the retina of the honey bee drone (Apis mellifera, L)

In the honey bee drone, the decrease in sensitivity to light of a retinula cell exposed to background illumination was found to be accurately reflected by the difference in amplitude between the initial transient depolarization and the lowest steady depolarization evoked by the background light. It is shown that both the decrease in sensitivity to light and the accompanying drop in potential from the transient to the plateau can be prevented by injecting EGTA intracellularly. A decrease in duration and amplitude of responses to short test flashes such as observed immediately after illumination was found to occur too when Ca or Na, but not K, Li, or Mg injected into dark-adapted retinula cells. Injection of EGTA into a retinula cell maintained a steady state of light adaptation, was found to cause an increase in amplitude and duration of the response to a short test flash, thus producing the effects of dark adaptation. It is suggested that, in the retina of the honey bee drone, an increase in intracellular calcium concentration plays a central role in light adaptation and that an increase in intracellular sodium concentration, resulting from the influx of sodium ions during the responses to light, could lead to this increase in intracellular free calcium.     

Properties of phosphoenolpyruvate carboxylase in rapidly prepared,desalted leaf extracts of the Crassulacean acid metabolism plant Mesembryanthemum crystallinum L.

Properties of phosphoenolpyruvate (PEP) carboxylase, obtained from leaves of Mesembryanthemum crystallinum L. performing Crassulacean acid metabolism (CAM), were determined at frequent time points during a 12-h light/12-h dark cycle. Leaf extracts were rapidly desalted and PEP carboxylase activity as a function of PEP concentration, malate concentration, and pH was measured within 2 min after homogenization of the tissue. Maximum velocity of PEP carboxylase was similar in the light and dark at pH 7.5 and pH 8.0. However, PEP carboxylase had as much as a 12-fold lower K _m for PEP and as much as a 20-fold higher K _i for malate during the dark than during the light periods, the magnitude of these differences being dependent on the assay pH. Assuming that enzyme properties immediately after isolation reflect the approximate state of the enzyme in vivo, these differences in enzyme properties reduce the potential for CO₂ fixation via PEP carboxylase in the light. A small decrease in cytoplasmic pH in the light would greatly magnify the above differences in day/night properties of PEP carboxylase, because the sensitivity of PEP carboxylase to inhibition by malate increased with decreasing pH. Properties of PEP carboxylase were also studied in plants exposed to short-term perturbations of the normal 12-h light/12-h dark cycle (e.g., prolonged light period, prolonged dark period). Under all light/dark regimes, there was a close correlation between change in properties of PEP carboxylase and changes of the tissue from acidification to deacidification, and vice versa. Changes in properties of PEP carboxylase were not merely light/dark phenomena because they were also observed in plants exposed to continuous light or dark. the data indicate that, during CAM, PEP carboxylase exists in two stages which differ in their capacity for net malate synthesis. The physiologically-active state is distinguished by a low K _m for PEP and a high K _i for malate and favors malate synthesis. The physiologically-inactive state has a high K _m for PEP and a low K _i for malate and exists during periods of deacidification and other periods lacking synthesis of malic acid.Abbreviations CAM Crassulacean acid metabolism - PEP phosphoenolpyruvate - PEPC PEP carboxylase - RuBP ribulose 1,5-bisphosphate - RH relative humidity     

Calcium sensitivity of hybrid complexes of muscle myosin and Physarum proteins.

1. A myosin-actin hybrid complex was used to study actin-associated calcium sensitivity of a "cytoplasmic" actomyosin. The approach should be generally applicable. 2. Low salt extracts of Physarum polycephalum contain actin which remains in solution after centrifugation at 46 000 times g or at 100 000 times g for 1 h. The actin was precipitated by the addition of muscle myosin to the supernatants and detected in the hybrid complex by electron microscopy, sodium dodecyl sulfate gel analysis, super-precipitation and activation of the myosin ATPase activity. Actin was also precipitable from high speed supernatants of brain tissue or platelets. 3. The hybrid complexes from Physarum possessed 1.5-5-fold calcium dependency which could be removed by washing. Reincubation of the washed complex with concentrated wash solution resulted in high calcium sensitivity. On sodium dodecyl sulfate gels, unwashed complexes from Physarum contained high molecular weight material in addition to bands of molecular weights less than actin. The bands in the size range of 39 000 to 18 000 were primarily lost from the Physarum complex concomitantly with loss of calcium dependence. 4. When the Physarum supernatants were made 40 mM in MgCl2, precipitates were formed containing actin which possessed calcium sensitivity which was also lost on washing with low ionic strength solutions. This calcium dependency was partially reversed by the addition of desensitized rabbit actin to the precipitate before assay. 5. Conclusion: calcium regulation of actomyosin in Physarum is mediated primarily by factors that are bound to the actin component. The regulatory factors are soluble in low salt buffers. The molecular weights of the polypeptide chains of several of these factors are similar to those of the troponin polypeptides of striated muscle. In Physarum but not in platelet or brain a prominent polypeptide chain of approx. 55 000 molecular weight also occurs which coprecipitates with the hybrid complex and which is not easily removed.     

Effect of far-red light on malate and potassium contents in cotton leaves: Relation to drought resistance

Long- or short-term far-red light given before a dark treatment modified the water status and the potassium and malate contents in cotton ( Gossypium hirsutum L. cv. Bou) leaves. Upon a long-term treatment, the leaf water content and the leaf water and osmotic potentials were lower whereas stomatal resistance was greater with a decrease in daily transpiration. There was a parallel increase in potassium and malate, but the calcium content was not significantly changed. This resulted in better water economy with an increase in drought resistance. Upon a short-term treatment, the accumulation of potassium and malate was reversible and the drought resistance was modified accordingly. There was a positive correlation between the ability of a plant to resist water stress and the content of potassium and malate.     

Repression of sporulation in Bacillus subtilis by L-malate.

L-Malate repressed sporulation in the wild-type strain of Bacillus subtilis. When 75 mM L-malate was added to the growth medium at the time of inoculation, the appearance of heat-resistant spores was delayed 6 to 8 h. The synthesis of extracellular serine protease, alkaline phosphatase, glucose dehydrogenase, and dipicolinic acid was similarly delayed. Sporulation was not repressed when malate was added to the culture at t4 or later. A mutant was selected for ability to sporulate in the presence of malate. This strain could also sporulate in the presence of glucose. The malate-resistant mutant grew poorly with malate as sole carbon source, although it possessed an intact citric acid cycle, and it showed increased levels of malic enzyme. This indicates a defect in the metabolism of malate in the mutant. A mutant lacking malate dehydrogenase activity was also able to sporulate in the presence of malate. A model for the regulation of sporulation by malate is presented and discussed. Citric acid cycle intermediates other than malate did not affect sporulation. In contrast to previous results, sporulation of certain citric acid cycle mutants could be greatly increased or completely restored by the addition of intermediates after the enzymatic block. The results indicate that the failure of citric acid cycle mutants to sporulate can be adequately explained by lack of energy and lack of glutamate.     

Energy sources for glutamate neurotransmission in the retina: absence of the aspartate/glutamate carrier produces reliance on glycolysis in glia

The mitochondrial transporter, the aspartate/glutamate carrier (AGC), is a necessary component of the malate/aspartate cycle, which promotes the transfer into mitochondria of reducing equivalents generated in the cytosol during glycolysis. Without transfer of cytosolic reducing equivalents into mitochondria, neither glucose nor lactate can be completely oxidized. In the present study, immunohistochemistry was used to demonstrate the absence of AGC from retinal glia (Müller cells), but its presence in neurons and photoreceptor cells. To determine the influence of the absence of AGC on sources of ATP for glutamate neurotransmission, neurotransmission was estimated in both light- and dark-adapted retinas by measuring flux through the glutamate/glutamine cycle and the effect of light on ATP-generating reactions. Neurotransmission was 80% faster in the dark as expected, because photoreceptors become depolarized in the dark and this depolarization induces release of excitatory glutamate neurotransmitter. Oxidation of [U-14C]glucose, [1-14C]lactate, and [1-14C]pyruvate in light- and dark-adapted excised retinas was estimated by collecting 14CO2. Neither glucose nor lactate oxidation that require participation of the malate/aspartate shuttle increased in the dark, but pyruvate oxidation that does not require the malate/aspartate shuttle increased to 36% in the dark. Aerobic glycolysis was estimated by measuring the rate of lactate appearance. Glycolysis was 37% faster in the dark. It appears that in the retina, ATP consumed during glutamatergic neurotransmission is replenished by ATP generated glycolytically within the retinal Müller cells and that oxidation of glucose within the Müller cells does not occur or occurs only slowly.