Characterization of metabolically active developmental stage of Aspergillus niger cells immobilized in polyacrylamide gel

Summary The in-situ development of Aspergillus niger entrapped in polyacrylamide gel from spores and the gel surface characteristics were studied during the repeated shake flask batch citric acid fermentation. A marked increase in the rate of citric acid production was observed with the periodic replacement of culture with fresh media at an interval of 6 days reducing the fermentation time nearly to half. The metabolically active A. niger cells for citric acid production were characterized by the appearance of thick and bulbous hyphae scattered in and on the gel surface.     

Genetics of high level penicillin resistance in clinical isolates of Streptococcus pneumoniae

Abstract Mosaic penicillin-binding proteins (PBP) 1A, 2X and 2B genes were cloned from four clinical isolates of Streptococcus pneumoniae with levels of susceptibility to penicillin ranging from 1.5 to 16 μg benzylpenicillin ml⁻¹. In each instance it was possible to transform either the penicillin-sensitive laboratory strain R6 or a sensitive clinical isolate 110K/70 to the full level of penicillin resistance with these three penicillin-binding proteins alone. Until now it has not been possible to clearly determine whether alterations to PBP1A, 2X and 2B alone were sufficient to attain high level penicillin resistance.     

Detection by electron spin resonance of an exchange-coupled Cob(II)alamin...free radical pair species generated by anaerobic photolysis of polycrystalline adenosylcobalamin

Exposure to nitrous oxide (N₂O) $\text{in vivo}$ is accompanied by oxidation of cob[I]alamin to the inactive cob[III]alamin [1] and to loss of methionine synthetase activity [2]. There is a steady increase in thymidylate synthetase activity in marrow collected from rats exposed to N₂O and this returns to normal on restoring the animals to an air environment.     

Heterotopic Renal Autotransplantation in a Porcine Model: A Step-by-Step Protocol

Kidney transplantation is the treatment of choice for patients suffering from end-stage renal disease. It offers better life expectancy and higher quality of life when compared to dialysis. Although the last few decades have seen major improvements in patient outcomes following kidney transplantation, the increasing shortage of available organs represents a severe problem worldwide. To expand the donor pool, marginal kidney grafts recovered from extended criteria donors (ECD) or donated after circulatory death (DCD) are now accepted for transplantation. To further improve the postoperative outcome of these marginal grafts, research must focus on new therapeutic approaches such as alternative preservation techniques, immunomodulation, gene transfer, and stem cell administration.Experimental studies in animal models are the final step before newly developed techniques can be translated into clinical practice. Porcine kidney transplantation is an excellent model of human transplantation and allows investigation of novel approaches. The major advantage of the porcine model is its anatomical and physiological similarity to the human body, which facilitates the rapid translation of new findings to clinical trials. This article offers a surgical step-by-step protocol for an autotransplantation model and highlights key factors to ensure experimental success. Adequate pre- and postoperative housing, attentive anesthesia, and consistent surgical techniques result in favorable postoperative outcomes. Resection of the contralateral native kidney provides the opportunity to assess post-transplant graft function. The placement of venous and urinary catheters and the use of metabolic cages allow further detailed evaluation. For long-term follow-up studies and investigation of alternative graft preservation techniques, autotransplantation models are superior to allotransplantation models, as they avoid the confounding bias posed by rejection and immunosuppressive medication.     

Protein kinase D: activation for Golgi carrier formation

Protein kinase D regulates fission at the trans-Golgi network (TGN) of transport carriers that deliver cargo to the plasma membrane. PKD is first recruited to the TGN through interaction with diacylglycerol and is subsequently activated by phosphorylation to promote carrier fission. In a recent study, the relevant upstream kinase at the TGN was identified as the novel protein kinase C isoform PKCeta, which in turn is activated in response to heterotrimeric G-protein activation. These findings indicate the existence of a kinase signaling cascade at the TGN that regulates carrier fission and suggest a mechanism by which cargo might direct the formation of its transport carriers.     

Mango ripening--chemical and structural characterization of pectic and hemicellulosic polysaccharides

Ripening of mango is characterized by a gradual, but natural softening of the fruit, which is due to progressive depolymerization of pectic and hemicellulosic polysaccharides with significant loss of galactose, arabinose and mannose residues at the ripe stage. Structural characterization employing permethylation followed by GC-MS analysis, IR and ¹³C NMR measurements revealed the major CWS fractions of both unripe and ripe mangoes to be of variable molecular weights and having a 1,4-linked galactan/galacturonan backbone, which is occasionally involved in side chain branches consisting of single residues of galactose and arabinose or oligomeric 1,5-linked arabinofuranose residues linked through 1,3-linkages; whereas the major hemicellulosic fractions of unripe mango to be of xyloglucan-type having 1,4-linked glucan backbone with branching by non-reducing terminal arabinose and xylose residues.     

Mechanism of gamma-secretase cleavage activation: is gamma-secretase regulated through autoinhibition involving the presenilin-1 exon 9 loop?

Maturation of gamma-secretase requires an endoproteolytic cleavage in presenilin-1 (PS1) within a peptide loop encoded by exon 9 of the corresponding gene. Deletion of the loop has been demonstrated to cause familial Alzheimer's disease. A synthetic peptide corresponding to the loop sequence was found to inhibit gamma-secretase in a cell-free enzymatic assay with an IC(50) of 2.1 microM, a value similar to the K(m) (3.5 microM) for the substrate C100. Truncation at either end, single amino acid substitutions at certain residues, sequence reversal, or randomization reduced its potency. Similar results were also observed in a cell-based assay using HEK293 cells expressing APP. In contrast to small-molecule gamma-secretase inhibitors, kinetic inhibition studies demonstrated competitive inhibition of gamma-secretase by the exon 9 peptide. Consistent with this finding, inhibitor cross-competition kinetics indicated noncompetitive binding between the exon 9 peptide and L685458, a transition-state analogue presumably binding at the catalytic site, and ligand competition binding experiments revealed no competition between L685458 and the exon 9 peptide. These data are consistent with the proposed gamma-secretase mechanism involving separate substrate-binding and catalytic sites and binding of the exon 9 peptide at the substrate-binding site, but not the catalytic site of gamma-secretase. NMR analyses demonstrated the presence of a loop structure with a beta-turn in the middle of the exon 9 peptide and a loose alpha-helical conformation for the rest of the peptide. Such a structure supports the hypothesis that this exon 9 peptide can adopt a distinct conformation, one that is compact enough to occupy the putative substrate-binding site without necessarily interfering with binding of small molecule inhibitors at other sites on gamma-secretase. We hypothesize that gamma-secretase cleavage activation may be a result of a cleavage-induced conformational change that relieves the inhibitory effect of the intact exon 9 loop occupying the substrate-binding site on the immature enzyme. It is possible that the DeltaE9 mutation causes Alzheimer's disease because cleavage activation of gamma-secretase is no longer necessary, alleviating constraints on Abeta formation.     

Pseudomonads: major antagonistic endophytic bacteria to suppress bacterial wilt pathogen, <Emphasis Type="Italic">Ralstonia solanacearum</Emphasis> in the eggplant (<Emphasis Type="Italic">Solanum melongena</Emphasis> L.)

Endophytic bacteria of eggplant, cucumber and groundnut were isolated from different locations of Goa, India. Based on in vitro screening, 28 bacterial isolates which effectively inhibited Ralstonia solanacearum, a bacterial wilt pathogen of the eggplant were characterized and identified. More than 50% of these isolates were Pseudomonas fluorescens in which a vast degree of variability was found to exist when biochemical characteristics were compared. In greenhouse experiments, the plants treated with Pseudomonas isolates (EB9, EB67), Enterobacter isolates (EB44, EB89) and Bacillus isolates (EC4, EC13) reduced the wilt incidence by more than 70%. All the selected isolates reduced damping off by more than 50% and improved the growth of seedlings in the nursery stage. Most of the selected antagonists produced an antibiotic, DAPG, which inhibited R. solanacearum under in vitro conditions and might have been responsible for reduced wilt incidence under in vivo conditions. Also production of siderophores and IAA in the culture medium by the antagonists was recorded, which could be involved in biocontrol and growth promotion in crop plants. From our study we conclude that Pseudomonas is the major antagonistic endophytic bacteria from eggplants which have the potential to be used as a biocontrol agent as well as plant growth-promoting rhizobacteria. Large scale field evaluation and detailed knowledge on antagonistic mechanism could provide an effective biocontrol solution for bacterial wilt of solanaceous crops.     

Mouse Gestation Length Is Genetically Determined

Background

Preterm birth is an enormous public health problem, affecting over 12% of live births and costing over $26 billion in the United States alone. The causes are complex, but twin studies support the role of genetics in determining gestation length. Despite widespread use of the mouse in studies of the genetics of preterm birth, there have been few studies that actually address the precise natural gestation length of the mouse, and to what degree the timing of labor and birth is genetically determined.

Methodology/Principal Findings

To further develop the mouse as a genetic model of preterm birth, we developed a high-throughput monitoring system and measured the gestation length in 15 inbred strains. Our results show an unexpectedly wide variation in overall gestation length between strains that approaches two full days, while intra-strain variation is quite low. Although litter size shows a strong inverse correlation with gestation length, genetic difference alone accounts for a significant portion of the variation. In addition, ovarian transplant experiments support a primary role of maternal genetics in the determination of gestation length. Preliminary analysis of gestation length in the C57BL/6J-Chr#^A/J/NaJ chromosome substitution strain (B.A CSS) panel suggests complex genetic control of gestation length.

Conclusions/Significance

Together, these data support the role of genetics in regulating gestation length and present the mouse as an important tool for the discovery of genes governing preterm birth.