Anastomosing laticifer in the primary and secondary structures of Calotropis procera (Aiton) W.T.Aiton (Apocynaceae) stems

Protoplasma - An in-depth understanding of the development and distribution of laticifer (latex secretory structure) will be important for the production of both rubber and medicines and will...     

Rumen Bacterial Competition in Continuous Culture: Streptococcus bovis Versus Megasphaera elsdenii

Streptococcus bovis and Megasphaera elsdenii were grown in continuous culture with maltose as the limiting substrate at dilution rates of 0.36, 0.22, and 0.12 h. After each steady-state turnover, the pH was decreased by adding concentrated HCl to the medium reservoir. Relative counts of the two species at each dilution rate indicated that when the pH was high (6.6 to 6.0), higher dilution rates selected for a higher ratio of S. bovis to M. elsdenii. At intermediate pH (6.0 to 5.4), higher dilution rates once again selected for greater numbers of S. bovis in relation to M. elsdenii, but the increase in S. bovis numbers was much less at the 0.36-h dilution rate. Decreasing the pH below 5.4 caused the ratio of S. bovis to M. elsdenii to increase greatly, and no M. elsdenii cells were seen below pH 5.1. The ratio of the two species could be explained by their relative affinities for maltose if pH was greater than 6.0, but the lower relative numbers of S. bovis in the 0.36-h, intermediate-pH (6.0 to 5.4) incubations could not. Analysis of lactate production by S. bovis in pure culture showed that l-lactate was produced only if the pH was less than 5.2 at dilution rates of 0.22 and 0.12 h and less than 6.0 at a rate of 0.36 h. The lower numbers of S. bovis relative to M. elsdenii in the incubations with a dilution rate of 0.36 h and intermediate pH thus could be explained by utilization of l-lactate by M. elsdenii. The very high numbers of S. bovis at pH less than 5.4 were consistent with the greater tolerance of this organism to low pH.     

Phenylacetic and Phenylpropionic Acids Do Not Affect Xylan Degradation by Ruminococcus albus

Since the addition of either ruminal fluid or a combination of phenylacetic and phenylpropionic acids (PAA/PPA) has previously been shown to dramatically improve cellulose degradation and growth of Ruminococcus albus, it was of interest to determine the effects of these additives on xylan-grown cultures. Although cell-bound xylanase activity increased when either PAA/PPA or ruminal fluid was added to the growth medium, total xylanase did not change, and neither of these supplements affected the growth or xylan-degrading capacity of R. albus 8. Similarly, neither PAA/PPA nor ruminal fluid affected xylan degradation by multiple strains of R. albus when xylan prepared from oat spelts was used as a carbohydrate source. These results show that the xylanolytic potential of R. albus is not conditional on the availability of PAA/PPA or other components of ruminal fluid.     

Changes of bacterial communities in the rhizosphere of sugarcane under elevated concentration of atmospheric CO2

It is believed that climate change will influence most of interactions that sustain life on Earth. Among these, the recruitment exerted by plants in their roots vicinity can change, leading to differential assemblages of microbiomes in the rhizosphere. We approached this issue analyzing the variations in the composition of bacterial communities in the rhizosphere of sugarcane cultivated under two concentrations of atmospheric CO₂ (350 or 700 ppm). In addition to the analysis of bacterial community, the use of DNA‐SIP allowed the comparison of bacterial groups assimilating roots exudates (based on ¹³C‐labeled DNA) in both conditions, in a period of 8 days after the CO₂ pulse. The separation of ¹³C‐DNA indicated the low but increasing frequency of labeling in the rhizosphere, as averages of 0.6, 2.4 and 5.0% of total DNA were labeled after 2, 4, and 8 days after the ¹³CO₂ pulse, respectively. Based on large‐scale sequencing of the V6 region in the gene 16S rRNA, we found an increase in the bacterial diversity in the ¹³C‐DNA along the sampling period. We also describe the occurrence of distinct bacterial groups assimilating roots exudates from sugarcane cultivated under each CO₂ concentration. Bacilli, Gammaproteobacteria, and Clostridia showed high affinity for the C‐sources released by sugarcane under 350 ppm of CO₂, while under elevated concentration of CO₂, the assimilation of roots exudates was prevalently made by members of Bacilli and Betaproteobacteria. The communities became more similar along time (4 and 8 days after CO₂ pulse), in both concentrations of CO₂, electing Actinobacteria, Sphingobacteriia, and Alphaproteobacteria as the major cross‐feeders on sugarcane exudates. In summary, we described the bacterial groups with higher affinity to assimilate roots exudates in the rhizosphere of sugarcane, and also demonstrated that the rhizosphere community can be differentially assembled in a future scenario with increased contents of CO₂.     

Utility of alkaline protease from marine shipworm bacterium in industrial cleansing applications

Summary An alkaline protease, previously isolated from a symbiotic bacterium found in the gland of Deshayes of marine shipworm, was evaluated as a cleansing additive. The protease nearly doubled the cleaning power of a standard phosphate detergent at temperatures up to 50°C as determined by fabric swatch assays. The enzyme was, however, ineffective at 70°C. In both fresh and seawater, it was also an efficient presoak. The cleaning power of a non-phosphate detergent was significantly improved by added protease, independent of the pH range 10 to 12. The enzyme degraded lysozyme, the major protein contaminant of contact lenses, more extensively than subtilisin and was effective in solutions containing hydrogen peroxide, often employed to sterilize lenses. The protease was unusually stable in sodium perborate, as well as hydrogen peroxide, and retained good activity in the presence of sodium hypochloride.     

Degradation and utilization of xylan by the ruminal bacteria Butyrivibrio fibrisolvens and Selenomonas ruminantium.

The cross-feeding of xyland hydrolysis products between the xylanolytic bacterium Butyrivibrio fibrisolvens H17c and the xylooligosaccharide-fermenting bacterium Selenomonas ruminantium GA192 was investigated. Cultures were grown anaerobically in complex medium containing oat spelt xylan, and the digestion of xylan and the generation and subsequent utilization of xylooligosaccharide intermediates were monitored over time. Monocultures of B. fibrisolvens rapidly degraded oat spelt xylan, and a pool of extracellular degradation intermediates composed of low-molecular-weight xylooligosaccharides (xylobiose through xylopentaose and larger, unidentified oligomers) accumulated in these cultures. The ability of S. ruminantium to utilize the products of xylanolysis by B. fibrisolvens was demonstrated by its ability to grow on xylan that had first been digested by the extracellular xylanolytic enzymes of B. fibrisolvens. Although enzymatic hydrolysis converted the xylan to soluble products, this alone was not sufficient to assure complete utilization by S. ruminantium, and considerable quantities of oligosaccharides remained following growth. Stable xylan-utilizing cocultures of S. ruminantium and B. fibrisolvens were established, and the utilization of xylan was monitored. Despite the presence of an oligosaccharide-fermenting organism, accumulations of acid-alcohol soluble products were still noted; however, the composition of carbohydrates present in these cultures differed from that seen when B. fibrisolvens was cultivated alone. Residual carbohydrates present at various times during growth were of higher average degree of polymerization in cocultures than in cultures of B. fibrisolvens alone. Structural characterization of these residual products may help define the limitations on the assimilation of xylooligosaccharides by ruminal bacteria.     

Proteolytic activity of the ruminal bacterium Butyrivibrio fibrisolvens.

The proteolytic activity of Butyrivibrio fibrisolvens, a ubiquitously distributed bacterial species in the gastrointestinal tracts of ruminants and other mammals, was characterized. The relative proteolytic activity (micrograms of azocasein degraded per hour per milligram of protein) varied greatly with the strain: 0 to 1 for strains D1, D16f, E21C, and X6C61; 7 to 15 for strains IL631, NOR37, S2, LM8/1B, and X10C34; and 90 to 590 for strains 12, 49 H17C, CF4c, CF3, CF1B, and R28. The activity levels of the last group of strains were equal to or greater than those found with Bacteroides amylophilus or Bacteroides ruminicola. With the exception of strain R28 activity, 90% or more of the proteolytic activity was associated with the culture fluid and not the cells. Strain 49 produced proteolytic activity constitutively, but the level of activity (units per milligram of protein) was modulated by growth parameters. With various carbohydrates added to the growth medium, the proteolytic activities of strain 49 were positively correlated with the growth rate. However, when the growth rate varied with the use of different nitrogen sources, a similar correlation was not found. The highest activity level was observed with Casamino Acids (1 g/liter), but this level was reduced by ca. 70% with Trypticase (BBL Microbiology Systems, Cockeysville, Md.) or casein (1 g/liter) and by 85% with ammonium chloride (10 mM) as the sole nitrogen source. The addition of ammonium chloride (1 to 10 mM) to media with low levels of Casamino Acids or Trypticase resulted in lower proteolytic activities but not as low as seen when the complex nitrogen sources were increased to high levels (20 g/liter).(ABSTRACT TRUNCATED AT 250 WORDS)     

Dibucaine effects on structural and elastic properties of lipid bilayers

In this work we report the interaction effects of the local anesthetic dibucaine (DBC) with lipid patches in model membranes by Atomic Force Microscopy (AFM). Supported lipid bilayers (egg phosphatidylcholine, EPC and dimyristoylphosphatidylcholine, DMPC) were prepared by fusion of unilamellar vesicles on mica and imaged in aqueous media. The AFM images show irregularly distributed and sized EPC patches on mica. On the other hand DMPC formation presents extensive bilayer regions on top of which multibilayer patches are formed. In the presence of DBC we observed a progressive disruption of these patches, but for DMPC bilayers this process occurred more slowly than for EPC. In both cases, phase images show the formation of small structures on the bilayer surface suggesting an effect on the elastic properties of the bilayers when DBC is present. Dynamic surface tension and dilatational surface elasticity measurements of EPC and DMPC monolayers in the presence of DBC by the pendant drop technique were also performed, in order to elucidate these results. The curve of lipid monolayer elasticity versus DBC concentration, for both EPC and DMPC cases, shows a maximum for the surface elasticity modulus at the same concentration where we observed the disruption of the bilayer by AFM. Our results suggest that changes in the local curvature of the bilayer induced by DBC could explain the anesthetic action in membranes.     

Cyclic AMP in ruminal and other anaerobic bacteria

Abstract An examination of cAMP levels in predominant species of ruminal bacteria and other anaerobic bacteria was conducted. Cellular cAMP concentrations of glucose-grown cultures of Butyrivibrio fibrisolvens 49, Prevotella ruminicola D31d, Selenomonas ruminantium HD4 and D, Megasphaera elsdenii B159, Sreptococcus bovis JB1, Bacteroides thetaiotaomicron 5482, and Clostridium acetobutylicum ATCC 824 were determined at various times during growth by a competitive binding radioimmunoassay procedure. The results were compared to those for Escherichia coli NRRL B3704. The levels of cAMP ranged from undetectable for B. thetaiotaomicron to approximately 15 pmol/mg cell protein for P. ruminicola D31d. Varying the growth substrate in a manner previously shown to elicit regulatory response did not alter the level of cAMP in these organisms. In general, cAMP concentrations present in these organisms were much lower than the 6–25 pmol/mg cell protein observed for E. coli . The levels of cAMP in P. ruminicola were consistently higher than levels in other anaerobes, particularly during the early exponential and stationary phases of growth. Based on these data it seems unlikely that cAMP is involved in regulation of substrate catabolism in the anaerobic bacteria examined except in P. ruminicola where it may have an unknown regulatory function.     

Different Effects of Transgenic Maize and Nontransgenic Maize on Nitrogen-Transforming Archaea and Bacteria in Tropical Soils

The composition of the rhizosphere microbiome is a result of interactions between plant roots, soil, and environmental conditions. The impact of genetic variation in plant species on the composition of the root-associated microbiota remains poorly understood. This study assessed the abundances and structures of nitrogen-transforming (ammonia-oxidizing) archaea and bacteria as well as nitrogen-fixing bacteria driven by genetic modification of their maize host plants. The data show that significant changes in the abundances (revealed by quantitative PCR) of ammonia-oxidizing bacterial and archaeal communities occurred as a result of the maize host being genetically modified. In contrast, the structures of the total communities (determined by PCR-denaturing gradient gel electrophoresis) were mainly driven by factors such as soil type and season and not by plant genotype. Thus, the abundances of ammonia-oxidizing bacterial and archaeal communities but not structures of those communities were revealed to be responsive to changes in maize genotype, allowing the suggestion that community abundances should be explored as candidate bioindicators for monitoring the possible impacts of cultivation of genetically modified plants.