Study of Risk Factors, Causative Organisms & Their Sensitivity Pattern in Neonatal Sepsis in a Community Based Tertiary Level Hospital.

Neonatal sepsis is one of the most common reasons for admission to neonatal units in developing countries. It is also a major cause of mortality in both developed and developing countries. The type and pattern of organisms that cause neonatal sepsis changes over time and vary from one hospital to another hospital, even in the same country. In addition the causative organisms have developed increased drug resistance for the last two decades. Maternal, neonatal and environmental risk factors have contributed for the development of sepsis. To study the risk factors, causative organism and bacterial sensitivity pattern in cases of neonatal sepsis. This cross-sectional study was conducted over a period of six months. The study included 100 patients admitted at the neonatal ward of Department of Pediatrics, Community Based Medical College Bangladesh, Mymensingh, Bangladesh. Blood samples for culture were taken aseptically before starting antibiotic therapy. Microorganisms were isolated and identified by standard microbiological processes and antimicrobial sensitivity patterns were performed against amikacin, gentamicin, ceftriaxone, ciprofloxacin and ceftazidime. The factors which carried a significant risk for development of neonatal sepsis were low birth weight, preterm neonates, meconium stained liquor and prolonged rupture of membrane (>18 hours). Gram negative organisms predominated (68.8%) with Escherichia coli (33.3%) being the commonest. The gram negative bacteria which were isolated sensitive to amikacin, gentamicin and ceftriaxone. The organisms also relatively more sensitive to ciprofloxacin and highly sensitive to ceftazidime. The Gram positive bacteria showed sensitivity against only the antibiotic Ceftriaxone and Ciprofloxacin. The overall mortality was 9%. The outcome of the study will contribute to preventing and treating neonatal sepsis in the hospital.

Fluidized bed reactor for the biological treatment of ion-exchange brine containing perchlorate and nitrate.

The removal of perchlorate and nitrate from contaminated drinking water using regenerable ion-exchange processes produces a high salt brine (3-10% NaCl) laden with high concentrations of perchlorate and nitrate. This bench-scale research describes the operation of acetate-fed granular activated carbon (GAC) based fluidized bed reactors (FBR) for perchlorate-only, and combined nitrate and perchlorate removal from synthetic brine (6% NaCl). The GAC was inoculated with a salt-tolerant culture developed by the authors and used previously in batch systems. An FBR was an effective design for perchlorate reduction and exhibited first-order degradation kinetics with respect to perchlorate concentrations. Nitrate was also removed by the organisms in the column and had no negative effects on the removal of perchlorate using the FBR design. However, at higher concentrations of nitrate the FBR was more difficult to operate due to loss of carbon and biomass from the formation of nitrogen bubbles and the high recycle flow rates needed.

Mouse Rt6.1 is a thiol-dependent arginine-specific ADP-ribosyltransferase.

Mouse T-cell antigens Rt6.1 and Rt6.2 are glycosylphosphatidylinositol-anchored arginine-specific adenosine diphosphate (ADP)-ribosyltransferases. In the present study, we obtained evidence that an arginine-specific ADP-ribosyltransferase activity liberated from BALB/c mouse splenocytes by phosphatidylinositol-specific phospholipase C increased fivefold in the presence of dithiothreitol and that the activity was immunoprecipitated by polyclonal antibodies generated against recombinant rat RT6.1. When mouse Rt6.1 was expressed as a recombinant protein, the transferase activity of Rt6.1 was stimulated by dithiothreitol, and inhibited by N-ethylmaleimide, while activities of recombinant mouse Rt6.2 and the Glu-207 mutant of rat RT6.1 [Hara, N., Tsuchiya, M., and Shimoyama, M. (1996) J. Biol. Chem. 271, 29552-29555] were unaffected by either agent. In addition to four cysteine residues conserved among mouse Rt6 and rat RT6 antigens, Rt6.1 has two extra cysteine residues at positions 80 and 201. To investigate a contribution of these extra cysteines in mouse Rt6.1 to thiol dependency of Rt6.1 transferase activity, Cys-80 and Cys-201 of Rt6.1 were replaced with serine and phenylalanine, respectively, the corresponding residues of mouse Rt6. 2 and rat RT6.1. Transferase activity of the Phe-201 mutant of Rt6.1 lost thiol dependency while that of the Ser-80 mutant remained thiol-dependent. Thus, we conclude that mouse Rt6.1 is a thiol-dependent arginine-specific ADP-ribosyltransferase, and that Cys-201 confers thiol dependency on Rt6.1 transferase. Our study indicates that arginine-specific ADP-ribosyltransferase activity detected on BALB/c mouse splenocytes is attributed to Rt6.1 and that Rt6.1 differs from Rt6.2 in enzymatic property of the transferase and perhaps in immunoregulatory functions.

GTP-dependent modification of a 21-kDa substrate with NAD+ in bovine brain soluble fraction is not ADP-ribosylation of small G-protein but tailing of tRNA.

Labeling of 21-kDa material was observed when bovine brain soluble fraction was incubated with [adenylate-32P]NAD+ in the presence of GTP. The 21-kDa substrate, slightly smaller than C3 substrate in size, was labeled even without C3 exoenzyme. GTP could be replaced by nucleoside triphosphates other than ATP while ATP inhibited the GTP-induced labeling of 21-kDa substrate. After incubation of the soluble fraction with [adenylate-32P]NAD+ in the presence of GTP, [32P]ADP and [32P]ATP were detected in addition to [32P]AMP and [32P]ADP-ribose while only the last two nucleotides were observed without GTP. The 21-kDa substrate was labeled with [alpha-32P]ATP even in the absence of GTP, suggesting adenylylation rather than ADP-ribosylation. The labeled 21-kDa substrate, was extractable by phenol, disappeared with RNase treatment but not with tryptic digestion. Alkaline treatment of the phenol extract yielded an equal mixture of 3'-[32P]CMP and 2'-[32P]CMP. From these results we concluded that the 21-kDa labeling is a result of tRNA tailing with [alpha-32P]ATP generated from the [32P]AMP moiety of [adenylate-32P]NAD+. Results from reconstitution experiments using enzymes and tRNA purified from bovine brain soluble fraction, which are involved in this pathway, confirmed our conclusion.

ADP-ribosylation of tuftsin suppresses its receptor-binding capacity and phagocytosis-stimulating activity to murine peritoneal macrophages.

Arginine-specific ADP-ribosyltransferase present in granules of chicken polymorphonuclear leukocytes (so-called heterophils) is released into the extracellular space by stimulus of calcium ionophore A23187 or opsonized zymosan [Terashima et al. (1996) J. Biochem. 120, 1209-1215]. In the present work, we examined extracellular targets of the released transferase and identified tuftsin, a phagocytosis-stimulating tetrapeptide derived from leukokinin, as a preferential substrate of the enzyme in chicken plasma. Specific binding of FITC-tuftsin to murine peritoneal macrophages, observed under a fluorescent microscope, was impaired by ADP-ribosylation of the labelled peptide. Phagocytic assay analyzed by flow cytometry revealed that ADP-ribosylation of tuftsin decreased its phagocytosis-stimulating activity towards the macrophages. Thus, the ADP-ribosylation of tuftsin apparently decreases its biological activity and ADP-ribosylation may possibly be involved in inflammatory processes through alterations in tuftsin activity.

Immunohistochemical localization of ADP-ribosylarginine hydrolase in rodent CNS.

Polyclonal antibodies were generated against ADP-ribosylarginine hydrolase (AAH), using recombinant fusion protein of rat AAH and glutathione-S-transferase as a immunogen, and affinity-purified. Western blotting showed that the antibodies recognized in mouse brain homogenate a single protein with a molecular mass of 38 kDa, the expected size for mouse AAH. An analysis using the antibodies revealed that heavy labelings were apparent in various brain regions. In the cerebral cortex, pyramidal cells in layers III and V were the most heavily labeled. In the hippocampal formation, labeling was present on the pyramidal neurons and granule cells. The most heavily immunostained cell type was the pyramidal neuron of CA3. In the cerebellum, Purkinje cells were the most heavily labeled. Less intense staining was present over the granule cells. In the basal ganglia, neurons in the caudate nucleus and large multipolar cells in the amygdaloid complex were immunoreactive. Heavy labeling was seen in many midbrain and brainstem nuclei. Neurons in the habenula and ependymal cells were stained heavily. On Western blot analysis of rat cerebrospinal fluid (CSF), the anti-AAH antibodies recognized a protein with a molecular mass of 38 kDa. This is apparently the first evidence of a widespread but distinctive distribution of AAH in neurons of mouse brain and the presence of extracellular AAH in rat CSF.

Exocytosis of arginine-specific ADP-ribosyltransferase and p33 induced by A23187 and calcium or serum-opsonized zymosan in chicken polymorphonuclear leukocytes.

Exocytosis is a common phenomenon in neutrophil functions. We earlier reported the co-localization of arginine-specific ADP-ribosyltransferase [EC 2.4.2.31] and its target protein p33 (mim-1 protein) in cytoplasmic granules in chicken polymorphonuclear leukocytes (so-called heterophils) [Mishima, K., Terashima, M., Obara, S., Yamada, K., Imai, K., and Shimoyama, M. (1991) J. Biochem. 110, 388-394]. In the present study, we obtained evidence that the transferase and p33 were released into the extracellular space by the stimulus of calcium ionophore A23187 or serum-opsonized zymosan, but scarcely by phorbol myristate acetate (PMA) or N-formyl-Met-Leu-Phe (fMLP), thereby indicating the co-localization of the transferase and p33 in the azurophilic granules, and not in specific granules. [32P]ADP-ribosylation of p33 occurred in the extracellular space, induced by the stimulus of A23187 or opsonized zymosan in the presence of [32P]NAD. Our findings are interpreted to mean that heterophil transferase and p33 may be involved in neutrophil functions during processes of inflammation.

Vortex-mixing-induced inactivation of arginine-specific ADP-ribosyltransferase activity and re-activation of the less-active form by dithiothreitol plus NaCl under anaerobic conditions.

We observed dilution/vortex-mixing-induced inactivation of arginine-specific ADP-ribosyltransferase purified from chicken peripheral polymorphonuclear granulocytes (heterophils) and re-activation of the less active form by dithiothreitol plus NaCl, under anaerobic conditions. The vortex-mixing-induced inactivation of the diluted enzyme was rapid; more than 85% of the enzyme activity was lost with 1-min vortex-mixing at room temperature. When the less-active form of the enzyme was treated with 10 mM dithiothreitol plus 0.2 M NaCl, under anaerobic conditions, more than 50% of the enzyme activity was restored. Putative mechanisms of the vortex-mixing-induced inactivation and dithiothreitol/NaCl-dependent re-activation of the arginine-specific ADP-ribosyltransferase are discussed.