Characterization of akinete differentiation in the cyanobacterium Anabaena azollae

Differentiation of akinetes was investigated in the filamentous cyanobacterium Anabaena azollae Stras. In this organism all pre-existing vegetative cells are capable of developing into akinetes. Standard sporulation medium (SSM) was used to synchronously induce the formation of akinetes, while cultures in Allen and Arnon (AA/8) medium were used as controls.This paper describes the changes in photosynthetic pigments and total soluble proteins in these cultures over a 25-day period encompassing akinete differentiation. Heterocyst frequencies and nitrogenase activity were also monitored during the same period in both media. SDS-PAGE results indicated that specific proteins were synthesized in a manner correlated with akinete differentiation. The results demonstrate that in cultures undergoing akinete development, some of the photosynthetic pigments are maintained, nitrogen-fixation and heterocyst differentiation are suppressed, and the cells synthesize a variety of specific proteins.     

Note on study of the sporulation of fungi: endotrophic sporulation in the genusPenicillium

Conidiophore formation and sporulation can be induced inPenicillium sp. strain P 17 by an environmental factor—carbohydrate (carbon) starvation. Both surface and submerged mycelium, when transferred from synthetic medium to glucose-free salt solution, form conidiophores and sporulate, while in the control cultures on complete medium, vegetative growth continues. The time required for the formation of conidiophores, i.e. the induction interval, is 7–14 h and its length increases with the age of both surface and submerged mycelia. During the induction phase the mycelium undergoes autolysis, associated with degradation of energy motabolism involving the comsumption of reserve substances, a rapid drop in endogenous respiration and the endogenous reducing activity of the mycelium, a decrease in the labile phosphate concentration, proteolysis, an increase in the ammonia and orthopsphate concentration and exhaustion of readily oxidized amino acids from the pool. A transient increase in respiration occurs before differentiation of the conidiophores starts. During the second half of the induction phase, polyphenol substances and polyphenol oxidase appear in the mycelium.The enzyme is not induced by exogenous phenols. Its possible role in the sporulation of fungi is considered.     

Intracellular protease activity during the growth of Streptomyces coelicolor

Multiple intracellular proteases were produced by Streptomyces coelicolor throughout growth as surface cultures. Zymography revealed two constitutive, gelatinolytic proteases of approximate molecular masses 32.5 and 36.5 kDa. In addition, transient expression of a large (183.5 kDa) protease preceded aerial mycelium formation and following this, during sporulation, an additional protease of mass 27.5 kDa was produced.     

Sporulation ofStreptomyces roseosporus in submerged culture

Summary A soil isolate ofStreptomyces roseosporus was found to produce spores in stirred submerged culture. Both biological mass and respiratory activity increased during the sporulation process. Contrary to other reports, the differentiation process was not purposefully initiated by critical manipulation of either nutritional or environmental conditions.     

Alkaline protease production by Basidiobolus (N.C.L. 97.1.1): effect of 'darmform' morphogenesis and cultural conditions on enzyme production and preliminary enzyme characterization

A strain of Basidiobolus (N.C.L. 97.1.1) was isolated from plant detritus which secreted alkaline protease optimally active at pH 10.0. It is the first report of a protease from Basidiobolus, which is stable to and active under high alkaline conditions. When incubated under stationary conditions in broth cultures containing salts such as ammonium chloride, 'darmform' morphogenesis was readily induced through enlargement and internal division of the hyphal segments. Secretion of high activity alkaline protease was obtained in cultures initiated with darmform morphogenesis whereas cultures initiated from mycelial inocula grew as large pellets in submerged cultures, with little or no protease secretion. Cultural conditions favoring alkaline protease secretion have been optimized and a preliminary characterization of the enzyme is presented. Compatibility of the alkaline protease with commercial detergents as well as its potential application in recovering silver from spent photographic films have also been investigated.     

Changes in patterns of alkaline serine protease and bacilysin formation caused by common effectors of sporulation inBacillus subtilis 168

Bacilysin biosynthesis and alkaline serine protease production inBacillus subtilis 168 were monitored and compared in batch cultures when various effectors of sporulation were added at different stages of growth in a medium containing sucrose and glutamate. Depending on the time of addition, glucose affected sporulation and serine protease formation to the same extent, but had no effect on bacilysin production. Ammonium andl-alanine additions suppressed all three processes. Casamino acids severely interfered with bacilysin formation and sporulation, but not with protease formation. Decoyinine, a well-known inducer of sporulation, induced protease formation as well, but did not affect bacilysin biosynthesis. The extent of the observed effects depended largely on the time of metabolite additions. The results are discussed with reference to a possible coregulation of sporulation and the formation of bacilysin and alkaline serine protease inB. subtilis.     

Extracellular proteases produced by the wood-degrading fungus Phanerochaete chrysosporium under ligninolytic and non-ligninolytic conditions

When subjected to nitrogen limitation, the wood-degrading fungus Phanerochaete chrysosporium produces two groups of secondary metabolic, extracellular isoenzymes that depolymerize lignin in wood: lignin peroxidases and manganese peroxidases. We have shown earlier the turnover in activity of the lignin peroxidases to be due in part to extracellular proteolytic activity. This paper reports the electrophoretic characterization of two sets of acidic extracellular proteases produced by submerged cultures of P. chrysosporium. The protease activity seen on day 2 of incubation, during primary growth when nitrogen levels are not known to be limiting, consisted of at least six proteolytic bands ranging in size from 82 to 22 kDa. The activity of this primary protease was strongly reduced in the presence of SDS. Following the day 2, when nitrogen levels are known to become limiting and cultures become ligninolytic, the main protease activity (secondary protease) consisted of a major proteolytic band of 76 kDa and a minor band of 25 kDa. The major and minor secondary protease activities were inhibited by phenylmethylsulfonyl fluoride and pepstatin A, respectively. When cultures were grown in the presence of excess nitrogen (non-ligninolytic condition), the primary protease remained the principal protease throughout the culture period. These results identify and characterize a specific proteolytic activity associated with conditions that promote lignin degradation.     

Exploration of fungal spores as a possible storehouse of proteolytic biocatalysts

Studies were carried out to define the relation between enzyme production and fungal sporulation, in solid-state cultivation conditions of the filamentous fungus Aspergillus oryzae NRRL 2217 to get information on possible links between metabolite synthesis and differentiation phenomena. The efforts taken to explore the possibility for the presence of a neutral protease inside the spores of this fungus was to increase the overall enzyme yield. Results showed that the production of enzyme (neutral protease) and biomass (total protein) were synchronised, both reaching their respective maximum levels at 48 h of fermentation, and decreasing thereafter. Neutral protease synthesis was not related to sporulation. The spores produced were subjected to various permeabilisation procedures, and the increase in the levels of neutral protease was monitored. Mechanical shear was the sole technique that was able to disrupt spores but even this failed to increase enzyme titres, confirming the absence of intra-spore proteases.     

Degradation of keratinous materials by the plant pathogenic fungus <Emphasis Type="Italic">Myrothecium verrucaria</Emphasis>

In this paper it is described for the first time the capability of Myrothecium verrucaria to grow in submerged and solid state cultures using poultry feathers as the only substrate. The fungus produced a protease with an unusual keratinolytic activity among plant pathogenic fungi. Its crude protease hydrolyzed keratinous substrates at pH 9.0 and 40 °C in the following order: poultry feather keratin > sheep wool keratin > human nail keratin > human hair keratin. Protease activity was highly sensitive to phenylmethyl sulphonyl fluoride (PMSF) indicating that the enzyme belonged to the serine protease family.     

Sporulation of Streptomyces griseus in submerged culture.

A wild-type strain of Streptomyces griseus forms spores both on solid media (aerial spores) and in liquid culture (submerged spores). Both spore types are highly resistant to sonication, but only aerial spores are resistant to lysozyme digestion. Electron micrographs suggest that lysozyme sensitivity may result from the thinner walls of the submerged spores. Studies of the life cycle indicate that neither streptomycin excretion nor extracellular protease activity is required for sporulation: the analysis of mutants, however, suggests that antibiotic production may be correlated with the ability to sporulate. A method was devised to induce the rapid sporulation of S. griseus in a submerged culture. This method, which depends on nutrient deprivation, was used to determine that either ammonia or phosphate starvation can trigger sporulation and that the enzyme glutamine synthetase may be useful as a sporulation marker after phosphate deprivation.     

Inhibition of sporulation in the water mold Blastocladiella emersonii by antipain

Blastocladiella emersonii express two different types of caseinolytic activities during the process of sporulation. They can be distinguished in vitro on the basis of their sensitivity to antipain. The alkaline protease activity is inhibited by antipain and PMSF, whereas the second enzyme, denoted here as the caseinolytic activity, is not inhibited by antipain but is sensitive to PMSF and concanavalin A. In vivo, antipain blocks sporulation when added to cultures during the first 60 min of sporulation, but if added 90 min after sporulation is induced, it is biologically ineffective. In both cases, antipain enters the cells and decreases the rate of total protein degradation by 60%. The antisporulation effect of antipain cannot be reversed by washing the cells. The ability of cells which have been pretreated with antipain to sporulate can be recovered, but only after a period of growth. These data provide evidence for the critical role of the alkaline protease for a limited period of time during the initial phases of sporulation in Blastocladiella. A hypothesis based on the processing of preformed proteins by the alkaline protease as a key control mechanism for sporulation is presented.     

Iron deficiency-induced tetracycline production in submerged cultures by Streptomyces aureofaciens

Streptomyces aureofaciens ATCC 10762 grown in rotary-shaken submerged cultures produced substantial amounts of tetracycline only when the defined medium was deprived of iron. The biosynthesis of tetracycline was inhibited either by free iron at concentrations above 1–2 μmol l⁻¹, or by chelated iron provided by the siderophores of this bacterial strain. Late static iron-containing cultures allowed cell differentiation and sporulation and led to tetracyclines synthesis. A nitrosoguanidine-induced mutant able to synthesize tetracycline in the presence of iron in shaken submerged cultures was isolated and compared to the wild-type strain. However, no constitutive siderophore-mediated iron transport occurred in the mutant. These results suggest the involvement of a putative iron-controlled repressor in the biosynthesis of these secondary metabolites during vegetative growth and primary metabolism of the bacterium.     

Effects of increased and deregulated expression of cell division genes on the morphology and on antibiotic production of streptomycetes

This paper describes the effects of increased expression of the cell division genes ftsZ, ftsQ, and ssgA on the development of both solid- and liquid-grown mycelium of Streptomyces coelicolor and Streptomyces lividans. Over-expression of ftsZ in S. coelicolor M145 inhibited aerial mycelium formation and blocked sporulation. Such deficient sporulation was also observed for the ftsZ mutant. Over-expression of ftsZ also inhibited morphological differentiation in S. lividans 1326, although aerial mycelium formation was less reduced. Furthermore, antibiotic production was increased in both strains, and in particular the otherwise dormant actinorhodin biosynthesis cluster of S. lividans was activated in liquid- and solid-grown cultures. No significant alterations were observed when the gene dosage of ftsQ was increased. Analysis by transmission electron microscopy of an S. coelicolor strain over-expressing ssgA showed that septum formation had strongly increased in comparison to wild-type S. coelicolor, showing that SsgA clearly influences Streptomyces cell division. The morphology of the hyphae was affected such that irregular septa were produced with a significantly wider diameter, thereby forming spore-like compartments. This suggests that ssgA can induce a process similar to submerged sporulation in Streptomyces strains that otherwise fail to do so. A working model is proposed for the regulation of septum formation and of submerged sporulation.     

Role of autocide AMI in development of Myxococcus xanthus.

A new developmental mutant of Myxococcus xanthus has been isolated by screening TnV insertion mutants for AMI-dependent development in submerged culture. This mutant (ER304) aggregated and sporulated on agar surfaces but required at least 3.8 micrograms of autocide AMI per ml for development in submerged cultures. Spore rescue of ER304 was obtained with the saturated, monounsaturated, and diunsaturated fatty acid fractions of AMI, with specific activities of 68, 115, and 700 U/mg, respectively. In addition, several model fatty acids were capable of rescuing sporulation of ER304; however, there was no correlation between specific lytic activity observed in vegetative cultures and specific rescue activity. Rescue of ER304 was effected during the first ca. 12 h after the initiation of starvation conditions; after this time, addition of AMI or model fatty acids killed the cells. Supernatant fluids of ER304 rescued development in dsg mutants (e.g., DK3260) in submerged cultures, but dsg mutant supernatant fluids were incapable of rescuing ER304 development. The data presented in this article support the idea that the primary mechanism of rescue by AMI is not via lysis, although developmental lysis may be an indirect result of the rescue event. A membrane permeability model is presented to explain the role of autocides in early developmental events in wild-type strains and in the aggregation and sporulation rescue of developmental mutants ER304 and DK3260.     

Serial culturing of human bronchial epithelial cells derived from biopsies

Summary In the present study we describe the establishment of serial cultures of human bronchial epithelial cells derived from biopsies obtained by fiberoptic bronchoscopy. The cell cultures were initiated from small amounts of material (2 mm forceps biopsies) using either explants or epithelial cell suspensions in combination with a feeder-layer technique. The rate of cell proliferation and the number of passages (up to 8 passages) achieved were similar, irrespective of whether the explants or dissociated cells were used. To modulate the extent of differentiation, the bronchial epithelial cells were cultured either under submerged, low calcium (0.06 mM) (proliferating), normal calcium (1.6 mM) (differentiation enhancing) conditions, or at the air-liquid interface. Characterization of the bronchial epithelial cell cultures was assessed on the basis of cell morphology, cytokeratin expression, and ciliary activity. The cells cultured under submerged conditions formed a multilayer consisting of maximally three layers of polygonal-shaped, small cuboidal cells, an appearance resembling the basal cells in vivo. In the air-exposed cultures, the formed multilayer consisted of three to six layers exhibiting squamous metaplasia. The cytokeratin profile in cultured bronchial epithelial cells was similar in submerged and air-exposed cultures and comparable with the profile found in vivo. In addition to cytokeratins, vimentin was co-expressed in a fraction of the subcultured cells. The ciliary activity was observed in primary culture, irrespective of whether the culture had been established from explants or from dissociated cells. This activity was lost upon subculturing and it was not regained by prolongation of the culture period. In contrast to submerged cultures and despite the squamous metaplasia appearance, the cells showed a reappearance of cilia when cultured at the air-liquid interface. Human bronchial epithelial cell cultures can be a representative model for controlling the mechanisms of regulation of bronchial epithelial cell function.     

Protein degradation and protease activity during the late cycle of Blastocladiella emersonii

Analysis of protein degradation during the life cycle of Blastocladiella emersonii showed that (i) protein degradation is especially high during two phases of differentiation (sporulation, 12%/h and germination, 5%/h) in contrast with a much smaller degradation rate in the other phases (growth and zoospores, less than 1%/hr); (ii) protein degradation during germination in growth medium, as well as most of the germination process, is quantitatively unaffected by cycloheximide; (iii) a caseinolytic protease (pH optimum 5.5, apparent molecular weight 55,000 to 60,000) is present in extracts of zoospores and germinating cells; (iv) this protease activity is very low (perhaps absent) in extracts of late growth phase cells, but reappears during induced sporulation; (v) a different class of caseinolytic protease activity (pH optima 7 and 10; apparent molecular weight 25,000 to 30,000) is found in cellular extracts of late growth phase and early phases of sporulation; (vi) the latter class of enzyme activity is released into the medium during later phases of sporulation and is replaced in the cells by the former class. Speculations as to the roles of protein degradation in cell differentiation are discussed.     

An alkali-thermotolerant extracellular protease from a newly isolated Streptomyces sp. DP2

Of six alkalitolerant, extracellular protease producing bacterial strains isolated, DP2 displayed maximum activity. This organism was designated as Streptomyces sp. DP2 and identified as Streptomyces ambofaciens. Maximum protease yield was observed after 48 hours of submerged fermentation using various carbon and nitrogen sources. Fructose was found to be the best substrate for protease production, followed by maltose, lactose and wheat bran. Mustard cake is reported for the first time as the most ideal nitrogen source although soybean meal also gave comparable yield. The protease produced by Streptomyces sp. DP2 exhibited extensive activity over a broad pH range (4–12) with maximum activity at pH 8, and was active over a broad range of elevated temperatures (50–100°C), and possessed thermostability at 60–90°C for up to 1 hour. Enzyme activity was reduced by EDTA (25%), SDS (16%), and PMSF (6%). This novel alkaline protease has both alkali- and thermostability that may have industrial significance.     

Characteristics of a sporulation stimulating factor from Clostridium perfringens type A

A product in the culture supernatant fluid of Clostridium perfringens NCTC 8239 stimulated the sporulation of a test strain, NCTC 8679, of the same organism. The responsible factor, termed sporulation factor (SF), was present in seven cultures of Cl. perfringens grown in either a defined or complex medium. The SF reversed glucose-mediated catabolite repression of sporulation by this organism. Preliminary characterization of the SF demonstrated a resistance to elevated temperatures and proteases and a molecular weight of less than 500 Da. The known association of Cl. perfringens enterotoxin with sporulation highlights the importance of interactions between strains of this organism as may occur in the human intestine during foodborne illness.     

The effects of serine protease inhibitors on morphological differentiation of murine neuroblastoma cells (NB 15)

Morphological differentiation of neuroblastoma cells (NB15) was induced by cAMP effectors in the presence and absence of serine protease inhibitors. In all conditions tested, the percent differentiation was inhibited by protease inhibitors antipain, diisopropylfluorophosphate (DFP), leupeptin, and soybean trypsin inhibitor (SBTI). The level of morphological differentiation obtained in medium containing fetal calf serum was significantly less than the percent differentiation obtained with serum-free medium alone, so serum-free medium was the principal method of induction and comparisons were made to control uninduced cultures or cultures induced with the phospho-diesterase inhibitor R020–1724. Secreted or cell surface caseinolytic protease activity was higher in differentiating cells than in control cultures and was inhibited by the serine protease inhibitors. The effects of the protease inhibitors on growth and differentiation are discussed.