Effect of polymyxins on Bacillus polymyxa sporogenesis

Bacillus polymyxa var. Ross. producing polymyxin M and Bacillus polymyxa 153 producing polymyxin B form spores during submerged cultivation when the rate of biosynthesis of antibiotic peptides is low and when the production of antibiotics is over. However, sporogenesis is stimulated if polymyxins are added at the early stage of cultural growth. Inhibition of the synthesis of antibiotics suppresses the formation of spores. Substances other than polymyxins do not exhibit such a specific effect on sporogenesis. The fact that the culture requires endogenous polymyxins which are most effective in the period prior to the appearance of spores in the culture suggests the regulatory action of these peptides at the stage between vegetative growth and spore formation in Bacillus polymyxa.     

苔藓植物孢子发生的研究进展

苔藓植物孢子发生的过程是一个复杂的形态建成的过程,在此过程中,孢子母细胞经过减数分裂的两次精确的核分裂以及细胞质分裂,形成单倍体的四分孢子,再经孢子壁的发育过程,形成成熟的孢子。本文重点介绍了苔藓植物孢子发生过程中细胞质裂片、质体及核的变化、微管系统及纺锤体、胞质分裂和孢子壁形成过程的特点及其研究进展。     

苔藓植物孢子发生的研究进展

苔藓植物孢子发生的过程是一个复杂的形态建成的过程,在此过程中,孢子母细胞经过减数分裂的两次精确的核分裂以及细胞质分裂,形成单倍体的四分孢子,再经孢子壁的发育过程,形成成熟的孢子。本文重要介绍了苔藓植物孢子发生过程中细胞质裂片、质体及核的变化、微管系统及纺锤体、胞质分裂和孢子壁形成过程的特点及其研究进展。     

Spores of microorganisms

Preexisting¹⁴C-DAP in vegetative cells ofBacillus cereus is not incorporated into the spores, but is released into the medium after sporogenesis is complete. Exogenous¹⁴C-DAP added to the medium before sporulation is incorporated intensively into the sporangia and practically all of it is taken up by the spores. During sporogenesis, two periods of increased incorporation of¹⁴C into hot TCA-precipitate of cells are found after adding¹⁴C-DAP— one before formation of the spores, when¹⁴C-lysine formed by decarboxylation is incorporated together with¹⁴C-DAP, and one during the “whitening” phase, when any¹⁴C-lysine is no longer incorporated. The incorporation of exogenous¹⁴C-lysine into the sporangial proteins is also markedly elevated during the presporulation phase and at the outset of sporogenesis.     

Mutual relationship between antibiotics and resting spores of Bacillus subtilis: morphological changes and macromolecular synthesis after germination of spores treated with cyclic polypeptide and aminoglycoside antibiotics

Morphological changes and synthesis of DNA, RNA, protein, and cell wall were investigated during germination of resting spores of Bacillus subtilis exposed transiently to the cyclic polypeptide antibiotics, polymyxin B and gramicidin S, and the aminoglycoside antibiotics, streptomycin, kanamycin, and gentamicin. Normal germinated spores showed breaks of the spore coat, a diminution in size and a fibrillar appearance of the cortex, a swelling core, a cell wall as thick as that of vegetable cells, some mesosomes and DNA fibrils. On the other hand, no breaks of the spore coat, a spore core with a slight swelling and irregular form, a thin cell wall, no demonstration of the nuclear material and no granularity in the cytoplasm were characteristic of the germinated spores derived from polymyxin B- and gramicidin S-treated resting spores. With gramicidin S-treated germinated spores a few vacuoles were formed in the cytoplasm. Both polymyxin B- and gramicidin S-treated germinated spores showed little or no synthesis of DNA, RNA, and protein. The vegetative cells derived from streptomycin-treated resting spores demonstrated several finely granular regions in the cytoplasm and a disorder of the fibrillar nucleoid, and their autolysis occurred early. Their DNA and RNA synthesis was normal, whereas protein synthesis was low. In spite of no occurrence of cell division and very low protein synthesis, the most striking characteristics of the outgrowing cells derived from kanamycin-treated resting spores were a markedly thickened cell wall and a continuous incorporation of labeled D-alanine suggesting cell wall synthesis; RNA synthesis was slightly lower and DNA synthesis was almost normal. The outgrowing cells from gentamicin-treated resting spores also revealed relatively thick cell walls and a very slight incorporation of labeled D-alanine. Their DNA and RNA synthesis was fairly low and protein synthesis was almost completely inhibited. These results coincide with the growth curves of individual antibiotic-treated resting spores.     

RNA and ribosomal protein patterns during aerial spore germination in Streptomyces granaticolor

Disruption of the external sheath of Streptomyces granaticolor aerial spores and subsequent cultivation in a rich medium result in a synchronous germination. This method was used to analyze RNA and protein patterns during the germination. The germination process took place through a sequence of time-ordered events. RNA and protein synthesis started during the first 5 min and net DNA synthesis at 60-70 min of germination. Within the first 10 min of germination, synthesis of RNA was not sensitive to the inhibitory effect of rifamycin. During this period rRNA and other species including 4-5-S RNA were synthesized. Dormant spores contained populations of ribosomes or ribosomal precursors that were structurally and functionally defective. The ribosomal particles bound a sporulation pigment(s) of the melanine type. The ribosomal proteins complexed to the pigments formed insoluble aggregates which were easily removed from the ribosomes by one wash with 1 M NH4Cl. During the first 10 min of germination, pigment(s) were liberated from the complexes with the ribosomes and protein extracts of the washed ribosomes had essentially the same pattern as the extracts of ribosomes of vegetative cells. These structural alterations were accompanied by enhancement of the ribosome activities in polypeptide synthesis in vivo and in vitro. When the spores were incubated with a 14C-labelled amino acid mixture in the presence of rifamycin, only three proteins (GS1, GL1 and GS9) were identified to be radiolabelled in the extracts from the washed ribosomes. These experiments indicate that liberation of the sporulation pigment(s) from the complexes with ribosomal proteins and assembly of de novo synthesized proteins and proteins from a preexisting pool in the spore are involved in the reactivation of the ribosomes of dormant spores of S. granaticolor.     

Protein and nucleic acid synthesis during germination of the asexual spores of the aquatic fungus, Aphanomyces astaci

Macromolecular synthesis of asexual spores of Aphanomyces astaci Schikora, strain is, was studied during the germination phase. Germination of the spores was completely inhibited by aclinomycin D (20 ug/ml) or cycloheximide (100 ug/ml) as was incorporation of labeled uridine and leucine, respectively. During spore germination protein synthesis was almost linear, whereas incorporation of [3Hl-uridine and [3H1-thymidine showed lag phases. Initial protein synthesis is therefore suggested to take place without concomitant RNA-synthesis in this species. Germlings were not developmentally competent to sporulate before 8 h of germination.     

Ultrastructural and Cytochemical Observations on Sporogenesis of Myxobolus sp. (Myxosporida: Myxobolidae) from the Common Shiner Notropis cornutus*

SYNOPSIS. The structure and cytochemistry of spores of Myxobolus sp. from plasmodia which occur in the gill filaments of the common shiner Notropis cornutus were studied by light microscopy and by scanning and transmission electron microscopy. The thin-walled valves of the pyriform spores are thickened in the lateral sutural and apical regions. Mucous material is associated predominantly with the posterior end of many spores. The plasmodium is surrounded by a syncytial wall bounded by 2 membranes. Pinocytotic channels are formed by the inner membrane and numerous dense vesicles are pinched off at the distal ends of the channels. Sporogenesis is initiated by the envelopment of one vegetative cell by another. The larger, enveloped cell divides to form a disporous pansporoblast, which contains 2 pairs of capsulogenic and valvogenic cells and 2 binucleate sporoplasm cells. Each capsular primordium and connecting external tubule gives rise to a polar capsule which houses a helically coiled polar tubule. The apical end of each polar capsule is plugged by a stopper. The valvogenic cells surround the capsulogenic and posteriorly situated sporoplasm cells to form the spore valves. Iodinophilic (glycogen) inclusions were not seen in spores stained with iodine or Best's carmine. A darkly stained band was observed around the posterior region of most spores stained with Best's carmine. In the electron microscope large aggregates of β glycogen particles were seen in the cytoplasm of sporoplasm cells in mature spores.     

Influence of cellular differentiation on ultraviolet induced DNA damage and its repair mechanisms in B. cereus

Susceptibility to UV irradiation of B. cereus BIS-59 spores undergoing germination at various stages-dormant spores to vegetative cell stage and their ability to recover from radiation damage were studied. For a given dose of radiation, the number of spore photoproducts (SPP) formed in the DNA of dormant spores was about 5-times greater than that of thymine dimers (TT) formed in the DNA of vegetative cells. At intermediate stages of the germination cycle, there was a rapid decline in the UV radiation-induced SPP formed in DNA with a concomitant increase in the UV radiation-induced TT formed in DNA. Bacterial spores undergoing germination (up to 3 hr) in the low nutrient medium (0.3% yeast extract) displayed much higher resistance to UV radiation than those germinating in the rich nutrient medium, even though there was no discernible difference under the two incubation conditions in respect of the extent of germination and the time at which the outgrowth stage appeared (3 hr). This was due to the formation TT in the DNA of spores germinating in the low nutrient as compared to that of spores germinating in the rich-nutrient medium. In UV-irradiated dormant spores, SPP formed in the spore DNA did not disappear even after prolonged incubation in the non-germinating medium. However, when the UV-irradiated dormant spores were germinated in low or rich nutrient medium, a significant proportion of SPP in DNA was eliminated. The dormant spores incubated in either of the germinating media for 15 min and then UV-irradiated were capable of eliminating SPP (presumably by monomerization) even by incubation in a non-germinating medium and in the complete absence of protein synthesis (buffer holding recovery), thereby implying that spore-repair enzymes were activated in response to initial's germination. The acquisition of photo-reactivation ability appeared in spores subjected to germination only in the rich-nutrient medium at the outgrowth stage and required de novo synthesis of the required enzymes.     

Dielectric characterization of forespores isolated from Bacillus megaterium ATCC 19213

Isolated stage III forespores of Bacillus megaterium ATCC 19213 in aqueous suspensions were nearly as dehydrated as mature spores, as indicated by low dextran-impermeable volumes of ca. 3.0 ml per g (dry weight) of cells compared with values of ca. 2.6 for mature spores and 7.3 for vegetative cells. The forespores lacked dipicolinate, had only minimal levels of calcium, magnesium, manganese, potassium, and sodium, and were more heat sensitive than vegetative cells. The effective homogeneous conductivities and dielectric constants measured over a frequency range of 1 to 200 MHz indicated that the inherent conductivities of the forespores were unusually low, in keeping with their low mineral contents, but that the forespores could be invaded by environmental ions which could penetrate dielectrically effective membranes. Overall, our findings support the view that the dehydration of a forespore during stage III of sporogenesis may be the result of ion movements out of the forespore into the sporangium.     

Spores of microorganisms

The relationship of the synthesis of new cell wall in the postgerminative development ofBacillus cereus spores to protein and ribonucleic acid synthesis was studied through the incorporation of¹⁴C-diaminopimelic acid. The spores were not capable of synthesizing cell wall immediately after germination. A very short, period of protein synthesis was first needed, the messenger ribonucleic acid for these proteins being formed at the end of the depolymerization phase. On blocking cell wall synthesis with penicillin or cycloserine, swelling and the outset of elongation were normal. In the presence of penicillin, the cells afterwards disintegrated during the elongation phase, while with cycloserine, elongation of the cells was only arrested and later atypical division occurred. The findings are discussed from the aspect of the possibility of the participation of part of the preexisting diaminopimelic acid-containing spore material in the envelope system of the outgrowing cell.     

Differential organization of desmin and vimentin in muscle is due to differences in their head domains

In most myogenic systems, synthesis of the intermediate filament (IF) protein vimentin precedes the synthesis of the muscle-specific IF protein desmin. In the dorsal myotome of the Xenopus embryo, however, there is no preexisting vimentin filament system and desmin's initial organization is quite different from that seen in vimentin-containing myocytes (Cary and Klymkowsky, 1994. Differentiation. In press.). To determine whether the organization of IFs in the Xenopus myotome reflects features unique to Xenopus or is due to specific properties of desmin, we used the injection of plasmid DNA to drive the synthesis of vimentin or desmin in myotomal cells. At low levels of accumulation, exogenous vimentin and desmin both enter into the endogenous desmin system of the myotomal cell. At higher levels exogenous vimentin forms longitudinal IF systems similar to those seen in vimentin-expressing myogenic systems and massive IF bundles. Exogenous desmin, on the other hand, formed a reticular IF meshwork and non-filamentous aggregates. In embryonic epithelial cells, both vimentin and desmin formed extended IF networks. Vimentin and desmin differ most dramatically in their NH2- terminal "head" regions. To determine whether the head region was responsible for the differences in the behavior of these two proteins, we constructed plasmids encoding chimeric proteins in which the head of one was attached to the body of the other. In muscle, the vimentin head- desmin body (VDD) polypeptide formed longitudinal IFs and massive IF bundles like vimentin. The desmin head-vimentin body (DVV) polypeptide, on the other hand, formed IF meshworks and non-filamentous structures like desmin. In embryonic epithelial cells DVV formed a discrete filament network while VDD did not. Based on the behavior of these chimeric proteins, we conclude that the head domains of vimentin and desmin are structurally distinct and not interchangeable, and that the head domain of desmin is largely responsible for desmin's muscle- specific behaviors.     

Sporogenesis in Streptomyces melanochromogenes

The mode of spore differentiation in a strain of Streptomyces melanochromogenes was followed by analysis of ultrathin sections of sporulating aerial hyphae at various stages of sporogenesis. A special accent was laid on the formation of the sporulation septum and its alterations in the course of spore delimitation and separation. Distinct differences in formation and substructure have been observed between the cross walls of vegetative hyphae and the sporulation septa.Cross walls of vegetative hyphae are formed in a way typical for Gram-positive bacteria by a centripetal annular ingrowth of cytoplasmic membrane, on which wall material immediately is deposited. The development of the sporulation septa is characterized by the accumulation of amorphous material in addition to the newly synthesized wall layer inside the invaginating cytoplasmic membrane. This amorphous septal material will later be decomposed presumably by two lytic systems which cause the separation of the spores. The central region of the finished sporulation septum is perforated by microplasmodesmata. Spores are released by a break down of the surface sheath. The complete spores are enveloped by a twolayered cell wall and the spiny surface sheath.     

Homothallic life cycle in the diploid red yeast Xanthophyllomyces dendrorhous (Phaffia rhodozyma)

Sexual activity was induced in the basidiomyceteous Phaffia rhodozyma (Xanthophyllomyces dendrorhous) by depletion of nitrogen from the culture medium. This activity involved both mating between two yeast cells and the formation of basidiospores. Mating is possibly started by a G1 phase arrest of the cell cycle, as in other yeasts. The life cycle exhibited homothallic features. Crosses between genetically marked strains, and pulse-field gel electrophoresis of the chromosomal DNA of cells derived from individual spores revealed evidence of karyogamy, meiosis and even recombination. The segregation ratio in tetrads pointed to diploid vegetative cells, which formed tetraploid zygotes and the immediate meiosis then gave rise to diploid progenies again. Apart from the type strain Phaffia rhodozyma CBS 5905, all the examined strains were able to sporulate.     

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.     

An Ultrastructural Study of the Myxosporeans,Sphaerospoa angulata and Sphaerospora carassii,in the Common Carp,Cyprinus carpio L.1

Sporogenesis of Sphaerospora angulata occurs in the lumen of renal tubules, and of Sphaerospora carassii sporogenesis occurs in the gill epithelium of carp (Cyprinus carpio) from Hungarian pond farms. In infected fish, the lumen of the renal tubules is filled with disporous pansporoblasts of S. angulata. Spores are formed through the participation of paired valvogenic and capsulogenic cells, and a dikaryotic sporoplasm, all of which lie in the cytoplasm of an envelope cell. The polar filament is formed through the apparent invagination of components of the elongate external tubule into the capsular primordium, coupled with the incorporation of dense material from the lumen of the primordium and external tubule. The cytological events leading to spore formation in monosporous pansporoblasts of S. carassii are similar to those of S. angulata and most other species of Myxosporea thus far. While neither parasite appears to induce severe pathogenesis, they may contribute to morbidity in concurrent infections with other microorganisms. Since spores of S. angulata and S. carassii are not formed in plasmodia and the earliest stage observed in this study was 2-celled, earlier stages of these parasites must occur elsewhere in the carp host.     

MreB of Streptomyces coelicolor is not essential for vegetative growth but is required for the integrity of aerial hyphae and spores

MreB forms a cytoskeleton in many rod-shaped bacteria which is involved in cell shape determination and chromosome segregation. PCR-based and Southern analysis of various actinomycetes, supported by analysis of genome sequences, revealed mreB homologues only in genera that form an aerial mycelium and sporulate. We analysed MreB in one such organism, Streptomyces coelicolor. Ectopic overexpression of mreB impaired growth, and caused swellings and lysis of hyphae. A null mutant with apparently normal vegetative growth was generated. However, aerial hyphae of this mutant were swelling and lysing; spores doubled their volume and lost their characteristic resistance to stress conditions. Loss of cell wall consistency was observed in MreB-depleted spores by transmission electron microscopy. An MreB-EGFP fusion was constructed to localize MreB in the mycelium. No clearly localized signal was seen in vegetative mycelium. However, strong fluorescence was observed at the septa of sporulating aerial hyphae, then as bipolar foci in young spores, and finally in a ring- or shell-like pattern inside the spores. Immunogold electron microscopy using MreB-specific antibodies revealed that MreB is located immediately underneath the internal spore wall. Thus, MreB is not essential for vegetative growth of S. coelicolor, but exerts its function in the formation of environmentally stable spores, and appears to primarily influence the assembly of the spore cell wall.     

Assembly of amino-terminally deleted desmin in vimentin-free cells

To study the role of the amino-terminal domain of the desmin subunit in intermediate filament (IF) formation, several deletions in the sequence encoding this domain were made. The deleted hamster desmin genes were fused to the RSV promoter. Expression of such constructs in vimentin- free MCF-7 cells as well as in vimentin-containing HeLa cells, resulted in the synthesis of mutant proteins of the expected size. Single- and double-label immunofluorescence assays of transfected cells showed that in the absence of vimentin, desmin subunits missing amino acids 4-13 are still capable of filament formation, although in addition to filaments large numbers of desmin dots are present. Mutant desmin subunits missing larger portions of their amino terminus cannot form filaments on their own. It may be concluded that the amino-terminal region comprising amino acids 7-17 contains residues indispensable for desmin filament formation in vivo. Furthermore it was shown that the endogenous vimentin IF network in HeLa cells masks the effects of mutant desmin on IF assembly. Intact and mutant desmin colocalized completely with endogenous vimentin in HeLa cells. Surprisingly, in these cells endogenous keratin also seemed to colocalize with endogenous vimentin, even if the endogenous vimentin filaments were disturbed after expression of some of the mutant desmin proteins. In MCF-7 cells some overlap between endogenous keratin and intact exogenous desmin filaments was also observed, but mutant desmin proteins did not affect the keratin IF structures. In the absence of vimentin networks (MCF-7 cells), the initiation of desmin filament formation seems to start on the preexisting keratin filaments. However, in the presence of vimentin (HeLa cells) a gradual integration of desmin in the preexisting vimentin filaments apparently takes place.     

An improved system for the surface immobilisation of proteins on Bacillus thuringiensis vegetative cells and spores through a new spore cortex-lytic enzyme anchor

An improved surface-immobilisation system was engineered to target heterologous proteins onto vegetative cells and spores of Bacillus thuringiensis plasmid-free recipient strain BMB171. The sporulation-dependent spore cortex-lytic enzyme from B. thuringiensis YBT-1520, SceA, was expressed in vegetative cells and used as the surface anchoring motif. Green fluorescent protein (GFP) and a Bacillus endo-β-1,3-1,4-glucanase (BglS) were used as the fusion partners to test the binding efficiency and the functional activities of immobilised surface proteins. The surface localisation of the SceA-GFP fusion protein on vegetative cells and spores was confirmed by Western blot, immunofluorescence microscopy and flow cytometry. The GFP fluorescence intensity from both vegetative cells and spores was measured and compared to a previously characterised surface display system using a peptidoglycan hydrolase anchor (Mbg). Results demonstrated comparable efficiency of SceA- and Mbg-mediated immobilisation on vegetative cells but a more efficient immobilisation on spores using the SceA anchor, suggesting SceA has greater potential for spore-based applications. The SceA protein was then applied to target BglS onto vegetative cells and spores, and the surface immobilisation was verified by the substantial whole-cell enzymatic activity and enhanced whole-spore enzymatic activity compared to vegetative cells. A dually active B. thuringiensis vegetative cell and spore display system could prove especially valuable for the development of regenerable and heat-stable biocatalysts that function under adverse environmental conditions, for example, an effective feed additive for improved digestion and nutrient absorption by livestock.     

Repair of Radiation Damage to Deoxyribonucleic Acid in Germinating Spores of Bacillus subtilis

The repair of deoxyribonucleic acid (DNA) in germinating spores was studied in comparison with that in vegetative cells. Radiation-induced single-strand breaks in the DNA of spores and of vegetative cells of Bacillus subtilis were rejoined during postirradiation incubation. The molecular weight of single-stranded DNA was restored to the level of nonirradiated cells. The rate of the rejoining of DNA strand breaks in irradiated spores was essentially equal to that in irradiated vegetative cells. The rejoining in spores germinating in nutrient medium occurred in the absence of detectable DNA synthesis. In this state, normal DNA synthesis was not initiated. Very little DNA degradation occurred during the rejoining process. On the other hand, in vegetative cells the rejoining process was accompanied by a relatively large amount of DNA synthesis and DNA degradation in nutrient medium. The rejoining occurred in phosphate buffer in vegetative cells but not in spores in which germination was not induced. Chloramphenicol did not interfere with the rejoining process in either germinating spores or vegetative cells, indicating that the rejoining takes place in the absence of de novo synthesis of repair enzyme. In the radiation-sensitive strain uvs-80, the capacity for rejoining radiation-induced strand breaks was reduced both in spores and in vegetative cells, suggesting that the rejoining mechanism of germinating spores is not specific to the germination process.