The effect of epsilon-aminocaproic acid on biochemical changes in the development of the cellular slime mould Dictyostelium discoideum.

epsilon-Aminocaproic acid (EACA) inhibited the development of Dictyostelium discoideum strain AX2 after the aggregation stage. Biochemical changes that occurred early in development (loss of cellular protein, RNA and carbohydrate; increase in the specific activity of N-acetylglucosaminidase, alpha-mannosidase, threonine deaminase and leucine aminopeptidase) were not affected by concentrations of EACA which blocked development; but biochemical changes that occurred later (synthesis of carbohydrate, increase in the specific activity of UDP-glucose pyrophosphorylase) were inhibited. Spores from fruiting bodies formed in the presence of low concentrations of EACA were larger, more spherical and less able to survive heat treatment than spores from fruiting bodies of control (no EACA) cells.     

Fruiting of Agaricus bisporus

Several enzymes were assayed in extracts from mycelium-colonised compost during growth and fruiting of Agaricus bisporus (Lange) Imbach. Comparison of changes of enzyme levels in axenic and nonaxenic cultures and in cultures of non-fruiting strains indicated that they were associated directly with the fungal mycelium. Large changes were found in the amounts of laccase and cellulase which were correlated with fruit body development. Laccase concentration increased during mycelial growth and then declined rapidly at the start of fruiting. Cellulase activity could be detected throughout growth but increased at fruiting. No such changes were observed in xylanase, alkaline protease, laminarinase and acid and alkaline phosphatases. Activities of laccase and cellulase were measured in axenic cultures arrested at various stages of fruiting development. Such cultures showed that the changes in concentration of laccase and cellulase were associated with the enlargement of fruit bodies.     

The Possible Involvement of Cyclic AMP and Volatile Substance (s) in the Development of a Macrocyst-Forming Strain of Dictyostelium mucoroides

A mutant MF1 previously isolated from Dictyostelium mucoroides -7 (Dm7) formed macrocysts with or without light when plated on agar at high cell dinsities. At lower cell densities, however, the MF1 cells formed only fruiting bodies. This failure to form macrocysts was shown to be due to the subthreshfold concentration of a volatile substance(s) required for macrocyst formation. Although ammonia is a volatile substance produced by both the Dm7 and MF1 cells, no evidence of its involvement in macrocyst formation was obtained. Mixing the Dm7 and MF1 in a one-to-one ratio resulted only in fruiting body formation suggesting that the Dm7 cells produced a factor which allowed MF1 cells to form fruiting bodies. This factor may be cyclic AMP (cAMP) since addition of cAMP to the medium directed development of MF1 cells to fruiting body formation. The effect of cAMP was exhibited most conspicuously when MF1 cells were exposed at the aggregation stage. Based on these results it is suggested that developmental pathway of the D. mucoroides macrocystforming strain Dm7 and its mutant MF1 may be determined by the relative concentrations of the volatile, macrocyst-inducing substance(s) and cAMP at the aggregation stage.     

Nutritional induction and suppression of fruiting in Myxococcus xanthus FBa

A defined agar medium (A agar) containing 15 amino acids in concentrations between 0.5 and 2 mm was developed for studying the fruiting cycle of Myxococcus xanthus FBa. Cells grew only vegetatively in this medium unless the initial concentration of one of nine required or stimulatory amino acids was lowered about 50-fold. In the latter circumstance, fruiting bodies developed after several days of vegetative growth. The conclusion was that fruiting occurred when any amino acid required for normal growth became limiting in the environment. High concentrations (10 mm) of phenylalanine, tryptophan, or methionine prevented fruiting without affecting growth. Mutants requiring arginine, thymidine, or adenine could not be induced to fruit by limiting their unique requirement although they responded to the same deprivations which brought about fruiting of the wild type. A histidine auxotroph formed fruiting bodies when histidine was lowered to growth-limiting concentrations, provided that the medium was supplemented with purines. A uracil auxotroph was isolated that, perhaps secondarily, had lost some of the mechanisms which control the formation of fruiting bodies; if uracil was present, it formed fruits even when no amino acid was limiting. No concentration of uracil was sufficient to prevent fruiting. Fruiting bodies were formed when mixtures of the uracil auxotroph and wild-type cells were inoculated on A agar plus uracil, even when 75% of the cells were wild type. Microcysts of both strains were present in the fruiting bodies.     

The developmental capacity of various stages of a macrocyst-forming strain of the cellular slime mold, Dictyostelium mucoroides.

Vegetative cells of certain strains of Dictyostelium mucoroides form fruiting bodies on an agar surface and macrocysts when placed under saline. This study sought to determine whether the aggregation and pseudoplasmodial stages of fruiting body formation could be induced to form macrocysts when placed under saline. Likewise, different stages in macrocyst formation were put on an agar surface to determine their potential to switch to fruiting body formation. It was found that 78% of the aggregates and 21% of the pseudoplasmodia placed under saline formed macrocysts indicating that as fruiting body development proceeds, there is a restriction of the capability of cells to respond to environmental conditions favoring macrocyst formation. Stages in macrocyst development prior to the formation of precysts always formed fruiting bodies when put on agar. Once precysts had formed, surrounded by their acellular sheath, they always developed as macrocysts on agar. Peripheral cells isolated from precysts and put on agar quickly aggregated; the aggregates became surounded by a sheath and developed as macrocysts. If isolated peripheral cells were allowed to proliferate on the agar surface, the resulting cells aggregated and formed fruiting bodies.     

The cyclin-dependent kinase inhibitor roscovitine inhibits kinase activity, cell proliferation, multicellular development, and Cdk5 nuclear translocation in Dictyostelium discoideum

Roscovitine, a cyclin-dependent kinase (Cdk) inhibitor, inhibited kinase activity and the axenic growth of Dictyostelium discoideum at micromolar concentrations. Growth was almost fully rescued in 50 μM and ≈ 50% rescued in 100 μM roscovitine-treated cultures by the over-expression of Cdk5-GFP. This supports the importance of Cdk5 function during cell proliferation in Dictyostelium and indicates that Cdk5 is a primary target of the drug. Roscovitine did not affect the expression of Cdk5 protein during axenic growth but did inhibit its nuclear translocation. This novel result suggests that the effects of roscovitine could be due in part to altering Cdk5 translocation in other systems as well. Kinase activity was inhibited by roscovitine in assays using AX3 whole cell lysates, but not in assays using lysates from Cdk5-GFP over-expressing cells. At higher concentrations, roscovitine impaired slug and fruiting body formation. Fruiting bodies that did form were small and produced relatively fewer spores many of which were round. However, roscovitine did not affect stalk cell differentiation. Together with previous findings, these data reveal that roscovitine inhibits Cdk5 during growth and as yet undefined Cdks during mid-late development.     

Role of cell cohesion in Myxococcus xanthus fruiting body formation.

Dsp mutants of Myxococcus xanthus have a complex phenotype with abnormal cell cohesion, social motility, and development. All three defects are the result of a single mutation in the dsp locus, a region of DNA about 14 kilobases long. Cohesion appears to play a central role in social motility, since nonsocial mutants exhibit weak agglutination or, in the case of Dsp cells, no agglutination (L. J. Shimkets, J. Bacteriol. 166:837-841, 1986). However, Dsp cells can be agglutinated by cohesive strains of M. xanthus. This provided the opportunity to examine the role of cohesion during development by comparing the developmental phenotype of Dsp cells with that of Dsp cells mixed with cohesive strains. Dsp mutants were unable to complete any of the developmental behaviors: aggregation, fruiting body formation, developmental autolysis, and sporulation. Contact with cohesive strains seemed to restore some developmental characteristics to the Dsp cells. When allowed to develop with wild-type cells, Dsp cells accumulated in fruiting bodies and underwent developmental autolysis, but did not form a significant portion of the spore population. Igl mutants, which may be similar to the previously described frizzy mutants, are cohesive strains that are unable to form fruiting bodies. Mixing Igl cells with Dsp cells under developmental conditions resulted in fruiting body formation, although the Dsp cells were unable to form significant levels of myxospores. In spite of their inability to sporulate under developmental conditions, Dsp mutants did not appear to be defective in the sporulation process. In fact, they formed normal levels of myxospores in response to the chemical inducer glycerol.     

Correlation of axenic linkage groups with the position of the microtubule-organizing center in aggregating Dictyostelium.

Positioning of the microtubule-organizing center (MTOC) in Dictyostelium discoideum was found to be genetically regulated. We examined the wild-type strain NC-4 cells independently maintained in different laboratories, freshly recovered cells from spores stocked for over 20 years, the temperature-sensitive growth mutant HU49 isolated from NC-4, as well as strain V-12 which is the opposite mating-type to NC-4. During aggregation on nonnutrient agar plates, all these strains showed similar cell polarity, as defined by the alignment of the nucleus ahead of the MTOC. By contrast, in Ax2 and Ax3, axenic strains carrying axenic mutations on linkage groups II and III, the MTOC was usually positioned ahead of the nucleus. Cells containing axenic linkage group II but not III positioned the MTOC ahead of the nucleus. Conversely cell polarity of strains including axenic linkage group III but not II was similar to that of wild-type cells. Thus axenic linkage group II, probably axeC or other linked gene(s) not yet identified, is responsible for the location of the MTOC anterior to the nucleus during aggregation. The anterior positioning of the MTOCs was prevented by growth on bacteria in cells carrying both axenic linkage groups, but not in those carrying only axenic linkage group II.     

Quantification of transformation efficiency using a new method for clonal growth and selection of axenic Dictyostelium cells

A new method for clonal growth of Dictyostelium axenic amoebae has been developed. Cells are plated in growth medium containing 1% ultra-low gelling temperature agarose. Cells grow normally in the agarose and form colonies up to several millimeters in diameter. When the colonies have grown to a sufficient size, they begin multicellular development. Pseudoplasmodia are formed, migrate to the surface of the agar, and then undergo fruiting body formation. Cells can be removed from the soft agarose colonies with a toothpick or by picking spores from the fruiting bodies. This method should be useful for drug, auxotrophic, and temperature selections where clonal maintenance of axenic colonies is important. This method has been used in combination with a selection for resistance to G418 to isolate independent colonies following DNA-mediated transformation. Several parameters in the calcium phosphate and electroporation transformation protocols have been optimized and the transformation frequency quantified. Independent transformed colonies are obtained at a frequency of 1 in 10(4) to 1 in 10(5) cells when integrating plasmids are introduced using calcium phosphate coprecipitation. The frequency is about tenfold higher when extrachromosomal shuttle vectors are introduced into cells.     

Ribonucleic acid synthesis during fruiting body formation in Myxococcus xanthus.

A method has been devised that allowed us, for the first time, to pulse-label M. xanthus cells with precursors for ribonucleic acid biosynthesis while they were undergoing fruiting body formation. Using this method, we examined patterns of ribonucleic acid (RNA) accumulation throughout the process of fruiting body formation. As development proceeded, the rate of RNA accumulation increased at two periods of the developmental cycle: once just before aggregation and once late in the cycle, when sporulation was essentially completed. In contrast to vegetatively growing cells, in which only stable RNA species are labeled during a 30-min pulse, the majority of radioactivity found in RNA from 30-min pulse-labeled developing cells was found in an unstable heterodisperse fraction that migrated to the 5S to 16S region of sucrose density gradients and sodium dodecyl sulfate-polyacrylamide gels. This pattern of incorporation could not be induced (i) by a shift down of vegetatively growing cells to a nutritionally poor medium, in which the generation time was increased to that of developing cells during the growth phase, or (ii) by plating of vegetative cells onto the same solid-surface environment as that of developing cells, but which surface supported vegetative growth rather than fruiting body formation. Thus, the RNA synthesis pattern observed appeared to be related to development per se rather than to nutritional depletion or growth on a solid surface alone. The radioactivity incorporated into the unstable 5S to 16S RNA fraction accumulated as the pulse length was increased from 10 to 30 min; in contrast, an analogous unstable fraction from vegetative cells decreased as pulse length was increased. This suggested that developmental 5S to 16S RNA was more stable than vegetative cell 5S to 16S RNA (presumptive messenger RNA). However, during a 45-min chase period, radioactivity in 30-min-pulse-labeled developmental 5S to 16S RNA decayed to an extent twice that of developmental RNA located in 16S and 23S regions of sucrose density gradients and was considerably less stable than the 5S, 16S, and 23S RNA species labeled during a 30-min pulse of vegetative cells.     

Beta-D-Allose inhibits fruiting body formation and sporulation in Myxococcus xanthus

Myxococcus xanthus, a gram-negative soil bacterium, responds to amino acid starvation by entering a process of multicellular development which culminates in the assembly of spore-filled fruiting bodies. Previous studies utilizing developmental inhibitors (such as methionine, lysine, or threonine) have revealed important clues about the mechanisms involved in fruiting body formation. We used Biolog phenotype microarrays to screen 384 chemicals for complete inhibition of fruiting body development in M. xanthus. Here, we report the identification of a novel inhibitor of fruiting body formation and sporulation, beta-d-allose. beta-d-Allose, a rare sugar, is a member of the aldohexose family and a C3 epimer of glucose. Our studies show that beta-d-allose does not affect cell growth, viability, agglutination, or motility. However, beta-galactosidase reporters demonstrate that genes activated between 4 and 14 h of development show significantly lower expression levels in the presence of beta-d-allose. Furthermore, inhibition of fruiting body formation occurs only when beta-d-allose is added to submerged cultures before 12 h of development. In competition studies, high concentrations of galactose and xylose antagonize the nonfruiting response to beta-d-allose, while glucose is capable of partial antagonism. Finally, a magellan-4 transposon mutagenesis screen identified glcK, a putative glucokinase gene, required for beta-d-allose-mediated inhibition of fruiting body formation. Subsequent glucokinase activity assays of the glcK mutant further supported the role of this protein in glucose phosphorylation.     

The sulphation inhibitor sodium selenate arrests the growth of Dictyostelium discoideum

Abstract Sulphate incorporation into glycopeptides appears to be a key event in the development of a number of organisms. An inhibitor of sulphation, sodium selenate, has been used in this study to examine the possibility that sulphation has a comparable role in the development of Dictyostelium discoideum . At concentrations of 0.1 mM and 1.0 mM, exogenously supplied selenate reversibly arrested the growth of bacterially grown amoebae of D. discoideum . In contrast, the effect of selenate on development was minimal. In the presence of 1.0 mM selenate, aggregation and tip formation were delayed 2–3 h and aggregates were slightly smaller; exogenous 0.1 mM selenate had no visible effect on development. However, the possibility that starved amoebae are impermeable to selenate was not excluded. The vegetative growth and development of an axenic strain in the presence of selenate closely resembled that of the bacterially grown strain. Since an inhibitory effect of 1.0 mM selenate on [³⁵S]sulphate incorporation into acetone precipitable protein was also demonstrated, these results suggest that sulphation is necessary for the growth of D. discoideum .     

Assay of human fibrinopeptides by high-performance liquid chromatography

Fibrinopeptides A, AP, and B, desarginine fibrinopeptide B, and a previously unknown peptide corresponding to B beta 3-14 were resolved within 10 min by an HPLC technique using an isocratic solvent system (22% acetonitrile in 0.1% trifluoroacetic acid) and a 0.46 X 10-cm Spherisorb ODS-2 (3-micron) octadecylsilane column. Fibrinopeptides A and AY eluted in the same peptide peak. The method was used to evaluate a carboxypeptidase which converts fibrinopeptide B into its desarginine form. Fifty percent inhibition of this activity occurred at 1.7 mM epsilon-aminocaproic acid (EACA). At saturating substrate concentrations the rates of total fibrinopeptides A and B release were unaffected by 125 mM EACA, a concentration at which the carboxypeptidase activity is completely inhibited.     

Relationship between axenic growth of Dictyostelium discoideum strains and their track morphology on substrates coated with gold particles

Amoebae of Dictyostelium discoideum produce tracks with two distinct morphologies on gold-coated coverslips. The wild-type strain and other strains that feed only by phagocytosis produced indistinct, fuzzy tracks, whereas mutants capable of axenic growth produced clear, sharp tracks. The sharp track morphology was found to be a recessive phenotype that segregates with axenicity and probably requires a previously unidentified axenic mutation. Axenic and nonaxenic strains also differed in their ability to pinocytose. When the two types of cells were shifted from bacterial growth plates to nutrient media, within 24 h the axenic strain established a rapid rate of pinocytosis, approximately 100-fold higher than the low rate detectable for the nonaxenic strain. However, track formation did not appear to be directly related to endocytosis. Electron microscopic examination of cells during track formation showed that both axenic and nonaxenic strains accumulated gold particles on their surfaces, but neither strain internalized the gold to any significant degree. Observation of living cells revealed that axenic strains collected all particles that they contacted, whereas wild-type strains left many particles undisturbed. The size of the gold particle clusters discarded by the cells also contributed to track morphology.     

The pool of ADP and ATP regulates anaerobic product formation in resting cells of Lactococcus lactis

Lactococcus lactis grows homofermentatively on glucose, while its growth on maltose under anaerobic conditions results in mixed acid product formation in which formate, acetate, and ethanol are formed in addition to lactate. Maltose was used as a carbon source to study mixed acid product formation as a function of the growth rate. In batch and nitrogen-limited chemostat cultures mixed acid product formation was shown to be linked to the growth rate, and homolactic fermentation occurred only in resting cells. Two of the four lactococcal strains investigated with maltose, L. lactis 65.1 and MG1363, showed more pronounced mixed acid product formation during growth than L. lactis ATCC 19435 or IL-1403. In resting cell experiments all four strains exhibited homolactic fermentation. In resting cells the intracellular concentrations of ADP, ATP, and fructose 1,6-bisphosphate were increased and the concentration of P(i) was decreased compared with the concentrations in growing cells. Addition of an ionophore (monensin or valinomycin) to resting cultures of L. lactis 65.1 induced mixed acid product formation concomitant with decreases in the ADP, ATP, and fructose 1,6-bisphosphate concentrations. ADP and ATP were shown to inhibit glyceraldehyde-3-phosphate dehydrogenase, lactate dehydrogenase, and alcohol dehydrogenase in vitro. Alcohol dehydrogenase was the most sensitive enzyme and was totally inhibited at an adenine nucleotide concentration of 16 mM, which is close to the sum of the intracellular concentrations of ADP and ATP of resting cells. This inhibition of alcohol dehydrogenase might be partially responsible for the homolactic behavior of resting cells. A hypothesis regarding the level of the ATP-ADP pool as a regulating mechanism for the glycolytic flux and product formation in L. lactis is discussed.     

Monoxenic and axenic cultivation of carrier and patient strains of Entamoeba histolytica.

All of five strains of Entamoeba histolytica, isolated from symptomatic cases of amoebiasis, could be adapted to axenic growth on the TP-S-1 medium of Diamond (1968). Four axenic strains were started from amoeba-Crithidia cultures; one could be axenized directly after isolation from a case of cutaneous amoebiasis. Attempts to monoxenize, resp. axenize strains, isolated from Dutch, asymptomatic carriers, were less successful. Only three out of ten strains could be submitted to bacteria-free growth. These three strains, however, originated probably from a recent case of intestinal amoebiasis. The results, suggesting that highly virulent strains can be easier cultivated bacteria-free than those with low or no virulence, are further discussed. The yield of axenic amoebae per tube fluctuates largely depending on many factors such as the strain, the number of transfers (i.e. degree of establishment), the quality of Panmede liver digest and serum in the TP-S-1 medium, and the care of manipulating the cultures. For optimal growth, a more acid medium was required in an amoeba-Crithidia culture than in an axenic culture. Multinucleated, giant amoebae were frequently observed in axenic cultures.     

荷叶离褶伞优良菌株筛选

以棉籽壳、木屑、玉米芯等为主料设计了10个栽培配方,研究不同配方下7株荷叶离褶伞的菌丝生长和出菇情况。结果表明,各菌株菌丝颜色以雪白色为主,在玉米芯为主料的配方上菌丝体生长优于以棉籽壳、木屑为主料的配方,但均无子实体形成;以棉籽壳为主料有利于子实体的形成,特别是棉子壳添加少量木屑、树叶、腐殖土、发酵料和小麦更利于子实体形成,菌株3001的出菇周期最短（108d）,产量最高（214.80g/袋）,各菌株出菇的顺序为3001、1035、1004和1013。因此,栽培料组分对荷叶离褶伞菌丝生长及子实体形成影响较大。     

Monokariotic fruiting body and clamp cell formation in Mycoleptodonoides aitchisonii (Bunaharitake)

The ability to produce monokaryotic fruiting bodies and clamp cells in culture was examined in monokaryotic strain isolated from several dikaryotic parental strains of the edible mushroom, Mycoleptodonoides aitchisonii (Bunaharitake). We describe a single dikaryotic M. aitchisonii strain, TUFC50005, and 20 monokaryons derived from it, which exhibited a wide spectrum of monokaryotic fruiting types. Most strains formed primordia, or young fruiting body-like structures, but only one of the monokaryons, strain TUFC50005-4, formed a fruiting body, even though it had only one nucleus and produced only two spores after meiosis. We demonstrated that dikariotization was not required for clamp cell formation, fruiting body formation, or meiosis, in this mushroom.     

蜜环菌对镁的耐性和富集特性

研究了镁对蜜环菌生长的影响, 蜜环菌对于镁的耐性和富集规律, 以及高浓度镁胁迫下蜜环菌的抗氧化酶的变化情况。3?15 g/L的Mg浓度对于蜜环菌菌体的生长有促进作用。Mg浓度19 g/L以上时, 蜜环菌菌体的生长受到抑制。蜜环菌的子实体形成和子实体生物量在Mg的浓度为11 g/L以下时不受影响, 超过11 g/L则子实体不能萌发。皮壳状菌丝和菌索中Mg的含量随培养基中Mg浓度的增大而增大, 培养基Mg浓度达到16 g/L后, 菌丝、菌索中Mg的含量都不再上升。子实体对Mg的富集量比菌丝体小的多, 在培养基Mg浓度在9、10 g/L时, 子实体中Mg的含量与对照组有显著差异。随着培养基中Mg浓度的提高, 菌丝和菌索POD、CAT、SOD活性都有增加, 而且菌丝与菌索之间抗氧化酶活力的差异随着培养基中Mg浓度的提高而增大。     

Adaptation of Salt-tolerant <Emphasis Type="Italic">Myxococcus</Emphasis> Strains and their Motility Systems to the Ocean Conditions

More and more studies have indicated that myxobacteria are able to live in seawater conditions, which, however, can decrease the fruiting body formation ability and also the adventurous (A) and social (S) motility systems of the myxobacteria. To learn the adaptation mechanism of the salt-tolerant myxobacteria to marine conditions, we analyzed 10 salt-tolerant Myxococcus strains of their fruiting body formation and motility. The isolates were from marine samples and possessed different levels of salt tolerance. They had the dual motility system and formed fruiting bodies in the presence of suitable seawater concentrations. Some high salt-tolerant strains even lost their fruiting abilities in the absence of seawater. In response to the presence of seawater, the S-motility was found to be increased in the high salt-tolerants but decreased in the low salt-tolerants. The A-motility, on the other hand, was observed in all the salt-tolerant Myxococcus strains, but increased or decreased in response to the presence of seawater. Perceived shifts of fruiting body formation abilities and motilities discovered in the salt-tolerant Myxococcus strains suggested an ecological adaptation of myxobacterial social behaviors to the marine environments.