Shivering,muscle tone,and uncoupling proteins in a developing marsupial,the Tasmanian bettong (Bettongia gaimardi)

This study examined the development of several physiological parameters that enable the development of endothermy during pouch life of the Tasmanian bettong (Bettongia gaimardi). By using several key age groups, we investigated the electromyography response of pouch young under different thermal conditions (35 or 20 °C), with and without injection of the β-agonist norepinephrine. We also used molecular techniques to examine the possible expression of uncoupling proteins 1, 2, and 3 (UCP1, 2, and 3), and if they were expressed, any association these may have with the timing of endothermic development. AT 6 weeks of age, pouch young were unable to thermoregulate via shivering or non-shivering mean, maintain a constant metabolic rate, or show any response to the β-agonist injection. When the animals were exposed to a cold stress (20 °C), 8-week-old pouch young initially shivered for 2–3 min before tapering off completely, causing body temperature to sharply decline. During the 10th week, cold-exposed pouch young began shivering, with the bout lasting approximately 10 min before ceasing and body temperature beginning to decline. It was also at this age that the expression of UCP2 was initially expressed. By the 12th week, cold exposed pouch young initially employed classical shivering; however, after approximately 12 min, this was replaced with an increase in muscular tone. This increase in muscular tone was also recorded in response to β-agonist injection at thermoneutral this age and was associated with an increase in metabolic rate. Also by this age, total body fat increased by approximately 300% from the levels expressed at 6 weeks of age and UCP2 was significantly upregulated. Although pouch young B. gaimardi did not show UCP1 expression at any time, UCP3 was expressed at every age investigated from 6 weeks of age. This study proposes that pouch young B. gaimardi use a mechanism of increased muscle tone as a source of heat production, and shows that UCP2 has an association with the onset of thermogenesis.     

Chemical and Morphological Studies of Bacterial Spore Formation : II. Spore and Parasporal Protein Formation in Bacillus cereus var. Alesti

The development of both the spore and parasporal protein crystal of Bacillus cereus var. alesti was followed using chemical and cytological techniques. The changes which led to the formation of the fore-spore were similar to those already described for Bacillus cereus. However, adjacent to the developing fore-spore a small inclusion became discernible in phase contrast. This protein inclusion during its growth was differentiated from the chromatin and lipid-containing inclusions by sequential staining techniques. During spore and crystal formation no net synthesis of either nucleic acid was detected. Tracer studies with radioactive phosphorus confirmed that the spore chromatin was derived from that in the vegetative cell. These same studies also indicated that a turnover of ribonucleic acid occurred during the sporulation process. During their formation both the spore and crystal incorporated methionine-³⁵S from the medium and from cellular material into a bound form. Sequential extractions with alkali and with alkaline-thioglycollate reagent revealed that the solubility characteristics of the mature crystal were possibly related to the presence of intermolecular disulphide bonds which developed after the major synthesis of the crystal was complete. The synthetic nature of sporogenesis and crystal formation is discussed with reference to the concept of "endotrophic" sporulation.     

Role of YpeB in Cortex Hydrolysis during Germination of Bacillus anthracis Spores

The infectious agent of the disease anthrax is the spore of Bacillus anthracis. Bacterial spores are extremely resistant to environmental stresses, which greatly hinders spore decontamination efforts. The spore cortex, a thick layer of modified peptidoglycan, contributes to spore dormancy and resistance by maintaining the low water content of the spore core. The cortex is degraded by germination-specific lytic enzymes (GSLEs) during spore germination, rendering the cells vulnerable to common disinfection techniques. This study investigates the relationship between SleB, a GSLE in B. anthracis, and YpeB, a protein necessary for SleB stability and function. The results indicate that ΔsleB and ΔypeB spores exhibit similar germination phenotypes and that the two proteins have a strict codependency for their incorporation into the dormant spore. In the absence of its partner protein, SleB or YpeB is proteolytically degraded soon after expression during sporulation, rather than escaping the developing spore. The three PepSY domains of YpeB were examined for their roles in the interaction with SleB. YpeB truncation mutants illustrate the necessity of a region beyond the first PepSY domain for SleB stability. Furthermore, site-directed mutagenesis of highly conserved residues within the PepSY domains resulted in germination defects corresponding to reduced levels of both SleB and YpeB in the mutant spores. These results identify residues involved in the stability of both proteins and reiterate their codependent relationship. It is hoped that the study of GSLEs and interacting proteins will lead to the use of GSLEs as targets for efficient activation of spore germination and facilitation of spore cleanup.     

Structural and functional studies on an FtsH inhibitor from Bacillus subtilis

The small 3 kDa SpoVM protein is essential for development of the spore in Bacillus subtilis. Genetic and biochemical experiments have shown that the function of SpoVM is to inhibit the proteolytic activity of FtsH during sporulation. We have used a combination of genetic and biophysical techniques to characterise the role of this small polypeptide. SpoVM was found to be widespread in Bacillus as well as in two Clostridia species, suggesting that SpoVM provides a common mechanism for inactivating the FtsH protease during spore differentiation. Using site-specific mutagenesis, we have identified C-terminal residues of SpoVM essential for biological activity. Analysis of SpoVM’s structure showed that it is able to assume an α-helical conformation in the presence of a lipid interface which may be important in interacting with FtsH.     

Premature differentiation and aberrant movement of pituitary cells lacking both Hes1 and Prop1

In the pituitary, the transition from proliferating progenitor cell into differentiated hormone producing cell is carefully regulated in a time-dependent and spatially-restricted manner. We report that two targets of Notch signaling, Hes1 and Prop1, are needed to maintain progenitors within Rathke's pouch and for the restriction of differentiated cells to the ventral pituitary. We observed ACTH and αGSU producing cells that had prematurely differentiated within Rathke's pouch along with correlated ectopic expression of Mash1 only when both Prop1 and Hes1 were lost. We also discovered that downregulation of N-cadherin expression in cells as they transition from Rathke's pouch to the anterior lobe appears to be essential for their movement. In the Prop1 mutant, cells are trapped in Rathke's pouch and N-cadherin expression remains high. Also, Slug, a marker of epithelial-to-mesenchymal transition, is absent in the dorsal anterior lobe. When Hes1 is lost in the Prop1 mutant, N-cadherin is downregulated and cells are able to exit Rathke's pouch but have lost their migrational cues and form ectopic foci surrounding Rathke's pouch. Our data reveal important overlapping functions of Hes1 and Prop1 in cell differentiation and movement that are critical for pituitary organogenesis.     

Electron microscopy of the surfaces of bacillus spores

The surface structures of the spores of Bacillus cereus, Bacillus thuringiensis, and Brevibacillus laterosporus were studied by transmission and scanning electron microscopy. Platinum deposition and negative staining with uranyl acetate revealed appendages and exosporium in B. thuringiensis and B. cereus. The exosporium structure was visualized by negative staining and ultrathin sectioning. For staining the exosporium polysaccharide, Alcian blue was used during fixation. The results obtained show the differences in structural organization of appendages and exosporium in different strains. Canoe-shaped inclusions were revealed in all Br. laterosporus strains, while strain IGM16-92 had a fibrillar capsule as well. Electron microscopy using a dual beam scanning electron microscope Quanta 200 3D provided the information of the spore surface relief without sample treatment (fixation and dehydration). The spores of Br. laterosporus strains had folded surface, unlike the smooth surface of B. cereus and B. thuringiensis spores. The diversity of external spore structures was shown within a species, which may be used for detection of bacteria at the strain level. Optimized procedures for visualization of spore surface by different electron microscopic techniques were discussed.     

A Screen for Spore Wall Permeability Mutants Identifies a Secreted Protease Required for Proper Spore Wall Assembly

The ascospores of Saccharomyces cerevisiae are surrounded by a complex wall that protects the spores from environmental stresses. The outermost layer of the spore wall is composed of a polymer that contains the cross-linked amino acid dityrosine. This dityrosine layer is important for stress resistance of the spore. This work reports that the dityrosine layer acts as a barrier blocking the diffusion of soluble proteins out of the spore wall into the cytoplasm of the ascus. Diffusion of a fluorescent protein out of the spore wall was used as an assay to screen for mutants affecting spore wall permeability. One of the genes identified in this screen, OSW3 (RRT12/YCR045c), encodes a subtilisin-family protease localized to the spore wall. Mutation of the active site serine of Osw3 results in spores with permeable walls, indicating that the catalytic activity of Osw3 is necessary for proper construction of the dityrosine layer. These results indicate that dityrosine promotes stress resistance by acting as a protective shell around the spore. OSW3 and other OSW genes identified in this screen are strong candidates to encode enzymes involved in assembly of this protective dityrosine coat.     

Consequences of Sporangial Development for Nodule Function in Root Nodules of Comptonia peregrina and Myrica gale

Frankia sp., the actinomycetous endophyte in nitrogen-fixing actinorhizal nodules, may differentiate two forms from its hyphae: vesicles and sporangia. In root nodules of Comptonia peregrina (L.) Coult. and Myrica gale L., sporangia may be either absent or present. Nitrogenase activity and symbiotic efficiency were contrasted in spore(+) and spore(−) nodules of these two host genera. Seedlings of C. peregrina nodulated with the spore(+) inoculum showed only 60% of the nitrogenase activity and 50% of the net size of their spore(−) counterparts after 12 weeks of culture. Measurements of acetylene reduction (i.e., nitrogenase activity) were coordinated with samplings of nodules for structural studies. Significant differences in acetylene reduction rates were discernible between spore(+) and spore(−) nodules commencing 4 weeks after nodulation, concomitant with the maturation of sporangia in the nodule. Spore(+) nodules ultimately reached less than half of the rate of nitrogenase activity of spore(−) nodules. Both types of nodules evolved only small amounts of molecular hydrogen, suggesting that both were equally efficient in recycling electrons lost to the reduction of hydrogen ions by nitrogenase. Respiratory cost of nitrogen fixation, expressed as the quotient of micromole CO₂ to micromole ethylene evolved by excised nodules, was significantly greater in spore(+) than in spore(−) nodules. M. gale spore(−) nodules showed variable effectivity, though all had low CO₂ to ethylene evolution ratios. M. gale spore(+) nodules resembled C. peregrina spore(+), with low effectivity and high respiratory cost for nitrogen fixation.     

The fission yeast spore is coated by a proteinaceous surface layer comprising mainly Isp3

The spore is a dormant cell that is resistant to various environmental stresses. As compared with the vegetative cell wall, the spore wall has a more extensive structure that confers resistance on spores. In the fission yeast Schizosaccharomyces pombe, the polysaccharides glucan and chitosan are major components of the spore wall; however, the structure of the spore surface remains unknown. We identify the spore coat protein Isp3/Meu4. The isp3 disruptant is viable and executes meiotic nuclear divisions as efficiently as the wild type, but isp3∆ spores show decreased tolerance to heat, digestive enzymes, and ethanol. Electron microscopy shows that an electron-dense layer is formed at the outermost region of the wild-type spore wall. This layer is not observed in isp3∆ spores. Furthermore, Isp3 is abundantly detected in this layer by immunoelectron microscopy. Thus Isp3 constitutes the spore coat, thereby conferring resistance to various environmental stresses.     

Seasonality of vesicular-arbuscular mycorrhizae in sedges in a semi-arid tropical grassland

Vesicular-arbuscular mycorrhizal (VAM) colonization and spore numbers in the rhizosphere of Cyperus iria L. and C. rotundus L., growing in a semi-arid tropical grassland, was studied during the 1993 and 1994 monsoons. In addition, climatic and chemical properties of the soils were determined in order to investigate their influence on mycorrhizal variables. VAM fungal association in the sedges was confirmed by plant- and root-trap culture techniques. The soil nutrients exhibited seasonal variations, but were highly variable between years. Intercellular hyphae and vesicles with occasional intraradical spores characterized mycorrhizal association in sedges. Dark septate fungi also colonized roots of sedges. Temporal variations in mycorrhizal colonization and spore numbers occurred, indicating seasonality. However, the patterns of mycorrhizal colonization and spore numbers were different during both the years. The VAM fungal structures observed were intercellular hyphae and vesicles. Changes in the proportion of root length with VAM structures, total colonization levels and spore numbers were related to climatic and edaphic factors. However, the intensity of influence of climatic and soil factors on VAM tended to vary with sedge species.     

Spatial variation of arbuscular mycorrhizal fungi in two vegetation types in Gurbantonggut Desert

Geostatistical techniques were used to assess the spatial patterns of spores densities and biovolume of arbuscular mycorrhizal fungi (AMF) in soils from two contrasting vegetation communities: an Ephedra distachya-ephemeral plant vegetation community and an Eremurus anisopteris vegetation community. Also evaluated the relationship between the spatial distribution of spore densities and biovolume of AMF and soil properties. Spatial dependence of spore densities and biovolume of AMF were exhibited further by kriged maps. The results showed spore density and biovolume indicated strong spatial autocorrelation and a patchy distribution within both sites. However, the patch size of genera and biovolume of AMF differed between the two communities. The correlation between distribution of spore and biovolume of AMF and distribution of soil parameters was expressed by Spearman rank-correlations coefficients. These results suggest that spore or biovolume distribution of AMF was affected significantly by some soil properties.     

The effects of recent changes in air temperature on trends in airborne <Emphasis Type="Italic">Alternaria</Emphasis>, <Emphasis Type="Italic">Epicoccum</Emphasis> and <Emphasis Type="Italic">Stemphylium</Emphasis> spore seasons in Bratislava (Slovakia)

Over the period 2002–2014, air temperature significantly increased regionally for Bratislava. However, no significant shifts have been observed in other meteorological parameters examined. The aim of this study was to analyse the effect of significant temperature trends on timing, duration and intensity of Alternaria, Epicoccum and Stemphylium spore seasons. Aerobiological monitoring was conducted using a Burkard 7-day volumetric spore trap. Mann–Kendall tau test was used to determine trends in spore seasons characteristics, whereas Spearman’s correlation coefficients were calculated to establish the relationships between temperature and spore season time series. Spore seasons of analysed taxa changed throughout the years of study. Alternaria spore season now starts earlier, ends later and lasts longer. Start, end and peak dates as well as duration of Alternaria spore seasons were significantly correlated with recorded increases in winter temperatures. Despite significant lengthening of Alternaria spore seasons, the lack of rising trend in its spore season index has been registered. This phenomenon could be partly explained by the reduction in the source vegetation due to drop of agricultural land use areas in Bratislava. In contrast, the intensity of Stemphylium spore seasons significantly increased during the study period and was correlated with recorded increases in summer–autumn temperatures. Based on the results of this study, it could be concluded that changes in selected fungal spore season patterns in Bratislava (earlier start date, later end date and longer duration of Alternaria spore seasons and higher Stemphylium spore season indexes) might be caused by the recorded local change in air temperature.     

Life cycle and spore resistance of spore-forming Bacillus atrophaeus

Bacillus endospores have a wide variety of important medical and industrial applications. This is an overview of the fundamental aspects of the life cycle, spore structure and factors that influence the spore resistance of spore-forming Bacillus. Bacillus atrophaeus was used as reference microorganism for this review because their spores are widely used to study spore resistance and morphology. Understanding the mechanisms involved in the cell cycle and spore survival is important for developing strategies for spore killing; producing highly resistant spores for biodefense, food and pharmaceutical applications; and developing new bioactive molecules and methods for spore surface display.     

Acceleration of fungal spore production by embedding a hydrophobic polymer net in a nutrient agar plate

A simple and novel procedure for the acceleration of fungal spore production was developed. A net of hydrophobic polymer such as polypropylene (PP) and polytetrafluoroethylene (PTFE) was embedded in a nutrient agar plate, and effect of the polymer net on spore production by 6 fungal strains, such as Aspergillus terreus, Penicillium multicolor, and Trichoderma virens were estimated. The effect of hydrophobic polymer net was insufficient in a liquid-surface immobilization (LSI) system with fungal cells immobilized on a ballooned microsphere layer formed on a liquid medium surface. On the other hand, the embedding of a PTFE net in an agar plate remarkably enhanced the spore production in all 6 strains tested to produce 2.0–8.5 × 10⁷ spores/cm²-agar plate surface. Especially, the spore production by A. terreus ATCC 20542 in the presence of a PTFE net was 7.7 times as much than that in no net. Positive correlations between the hydrophobicity of net and the spore production were observed in all 6 strains (R², 0.653–0.999).     

Role of the Spore Coat Layers in Bacillus subtilis Spore Resistance to Hydrogen Peroxide, Artificial UV-C, UV-B, and Solar UV Radiation

Spores of Bacillus subtilis possess a thick protein coat that consists of an electron-dense outer coat layer and a lamellalike inner coat layer. The spore coat has been shown to confer resistance to lysozyme and other sporicidal substances. In this study, spore coat-defective mutants of B. subtilis (containing the gerE36 and/or cotE::cat mutation) were used to study the relative contributions of spore coat layers to spore resistance to hydrogen peroxide (H₂O₂) and various artificial and solar UV treatments. Spores of strains carrying mutations in gerE and/or cotE were very sensitive to lysozyme and to 5% H₂O₂, as were chemically decoated spores of the wild-type parental strain. Spores of all coat-defective strains were as resistant to 254-nm UV-C radiation as wild-type spores were. Spores possessing the gerE36 mutation were significantly more sensitive to artificial UV-B and solar UV radiation than wild-type spores were. In contrast, spores of strains possessing the cotE::cat mutation were significantly more resistant to all of the UV treatments used than wild-type spores were. Spores of strains carrying both the gerE36 and cotE::cat mutations behaved like gerE36 mutant spores. Our results indicate that the spore coat, particularly the inner coat layer, plays a role in spore resistance to environmentally relevant UV wavelengths.     

SpoIVA and SipL Are Clostridium difficile Spore Morphogenetic Proteins

Clostridium difficile is a major nosocomial pathogen whose infections are difficult to treat because of their frequent recurrence. The spores of C. difficile are responsible for these clinical features, as they resist common disinfectants and antibiotic treatment. Although spores are the major transmissive form of C. difficile, little is known about their composition or morphogenesis. Spore morphogenesis has been well characterized for Bacillus sp., but Bacillus sp. spore coat proteins are poorly conserved in Clostridium sp. Of the known spore morphogenetic proteins in Bacillus subtilis, SpoIVA is one of the mostly highly conserved in the Bacilli and the Clostridia. Using genetic analyses, we demonstrate that SpoIVA is required for proper spore morphogenesis in C. difficile. In particular, a spoIVA mutant exhibits defects in spore coat localization but not cortex formation. Our study also identifies SipL, a previously uncharacterized protein found in proteomic studies of C. difficile spores, as another critical spore morphogenetic protein, since a sipL mutant phenocopies a spoIVA mutant. Biochemical analyses and mutational analyses indicate that SpoIVA and SipL directly interact. This interaction depends on the Walker A ATP binding motif of SpoIVA and the LysM domain of SipL. Collectively, these results provide the first insights into spore morphogenesis in C. difficile.     

Detection technologies for Bacillus anthracis: Prospects and challenges

Bacillus anthracis is a Gram-positive, spore-forming bacterium representing the etiological agent of acute infectious disease anthrax, a lethal but rare disease of animals and humans in nature. With recent use of anthrax as a bioweapon, a number of techniques have been recently developed and evaluated to facilitate its rapid detection of B. anthracis in the environment as well as in point-of-care settings for humans suspected of exposure to the pathogen. Complex laboratory methods for B. anthracis identification are required since B. anthracis has similarities with other Bacillus species and its existence in both spore and vegetative forms. This review discusses current challenges and various improvements associated with anthrax agent detection.     

The Role of Aquaporins in pH-Dependent Germination of Rhizopus delemar Spores

Rhizopus delemar and associated species attack a wide range of fruit and vegetables after harvest. Host nutrients and acidic pH are required for optimal germination of R. delemar, and we studied how this process is triggered. Glucose induced spore swelling in an acidic environment, expressed by an up to 3-fold increase in spore diameter, whereas spore diameter was smaller in a neutral environment. When suspended in an acidic environment, the spores started to float, indicating a change in their density. Treatment of the spores with HgCl₂, an aquaporin blocker, prevented floating and inhibited spore swelling and germ-tube emergence, indicating the importance of water uptake at the early stages of germination. Two putative candidate aquaporin-encoding genes—RdAQP1 and RdAQP2—were identified in the R. delemar genome. Both presented the conserved NPA motif and six-transmembrane domain topology. Expressing RdAQP1 and RdAQP2 in Arabidopsis protoplasts increased the cells'' osmotic water permeability coefficient (P_f) compared to controls, indicating their role as water channels. A decrease in R. delemar aquaporin activity with increasing external pH suggested pH regulation of these proteins. Substitution of two histidine (His) residues, positioned on two loops facing the outer side of the cell, with alanine eliminated the pH sensing resulting in similar P_f values under acidic and basic conditions. Since hydration is critical for spore switching from the resting to activate state, we suggest that pH regulation of the aquaporins can regulate the initial phase of R. delemar spore germination, followed by germ-tube elongation and host-tissue infection.     

Gastric dysfunction in sheep infected with Trichostrongylus colubriformis, a nematode inhabiting the small intestine

Barker I. K. and Titchen D. A. 1982. Gastric dysfunction in sheep infected with Trichostrongylus colubriformis, a nematode inhabiting the small intestine. International Journal for Parasitology12: 345–356. Six of 12 lambs infected with Trichostrongylus colubriformis had reduced abomasal acidification (pH 4.0–8.1) in comparison with uninfected pair-fed and replete controls (pH <3.5), though less than 0.8% of the worm burden was in the abomasum. Loss of prominence of parietal cells and encroachment of mucous cells deep into fundic glands was seen by light microscopy. Under the electron microscope, parietal cells had little canalicular or tubulovesicular development, had large vacuoles, many polyribosomes and few mitochondria in comparison with those in controls. In a further 8 sheep prepared with abomasal fistulae and separated fundic pouches and inoculated orally with T. colubriformis, the volume of fundic pouch secretion declined as feed intake dropped and in 7 out of 8 animals H⁺ concentration in fundic pouch secretion also fell. Infection generally reduced volume and acidity of pouch secretion more than did a pre-inoculation fast. In 5 sheep, abomasal content exceeded pH 4. Inoculation of T. colubriformis by enterotomy and Ostertagia circumcincta per os, in a lamb with a separated fundic pouch, caused depression of volume and acidity of pouch secretion characteristic of T. colubriformis infection, rather than the hypersecretion typical of abomasal infection with Ostertagia. Factors inhibitory to parietal cell differentiation and gastric acid secretion may be released from the small intestine of some sheep in response to changes in the gut induced by the presence of T. colubriformis. Abomasal dysfunction is a manifestation of severe intestinal trichostrongylosis.