Caloric restriction suppresses microglial activation and prevents neuroapoptosis following cortical injury in rats

Traumatic brain injury (TBI) is a widespread cause of death and a major source of adult disability. Subsequent pathological events occurring in the brain after TBI, referred to as secondary injury, continue to damage surrounding tissue resulting in substantial neuronal loss. One of the hallmarks of the secondary injury process is microglial activation resulting in increased cytokine production. Notwithstanding that recent studies demonstrated that caloric restriction (CR) lasting several months prior to an acute TBI exhibits neuroprotective properties, understanding how exactly CR influences secondary injury is still unclear. The goal of the present study was to examine whether CR (50% of daily food intake for 3 months) alleviates the effects of secondary injury on neuronal loss following cortical stab injury (CSI). To this end, we examined the effects of CR on the microglial activation, tumor necrosis factor-α (TNF-α) and caspase-3 expression in the ipsilateral (injured) cortex of the adult rats during the recovery period (from 2 to 28 days) after injury. Our results demonstrate that CR prior to CSI suppresses microglial activation, induction of TNF-α and caspase-3, as well as neurodegeneration following injury. These results indicate that CR strongly attenuates the effects of secondary injury, thus suggesting that CR may increase the successful outcome following TBI.     

Structures of lysenin reveal a shared evolutionary origin for pore-forming proteins and its mode of sphingomyelin recognition

Pore-forming proteins insert from solution into membranes to create lesions, undergoing a structural rearrangement often accompanied by oligomerization. Lysenin, a pore-forming toxin from the earthworm Eisenia fetida, specifically interacts with sphingomyelin (SM) and may confer innate immunity against parasites by attacking their membranes to form pores. SM has important roles in cell membranes and lysenin is a popular SM-labeling reagent. The structure of lysenin suggests common ancestry with other pore-forming proteins from a diverse set of eukaryotes and prokaryotes. The complex with SM shows the mode of its recognition by a protein in which both the phosphocholine headgroup and one acyl tail are specifically bound. Lipid interaction studies and assays using viable target cells confirm the functional reliance of lysenin on this form of SM recognition.     

In silico discovery and biophysical evaluation of novel 5-(2-hydroxybenzylidene) rhodanine inhibitors of DNA gyrase B

Bacterial DNA gyrase is an established and validated target for the development of novel antibacterials. In our previous work, we identified a novel series of bacterial gyrase inhibitors from the class of 4-(2,4-dihydroxyphenyl) thiazoles. Our ongoing effort was designated to search for synthetically more available compounds with possibility of hit to lead development. By using the virtual screening approach, new potential inhibitors were carefully selected from the focused chemical library and tested for biological activity. Herein we report on a novel class of 5-(2-hydroxybenzylidene) rhodanines as gyrase B inhibitors with activity in low micromolar range and moderate antibacterial activity. The binding of the two most active compounds to the enzyme target was further characterised using surface plasmon resonance (SPR) and differential scanning fluorimetry methods (DSF).     

Purification and proteomic characterization of plastids from Brassica napus developing embryos

Plastids are functionally and structurally diverse organelles responsible for numerous biosynthetic reactions within the plant cell. Plastids from embryos have a range of properties depending upon the plant source but compared to other plastid types are poorly understood and therefore, we term them embryoplasts. Isolating intact plastids from developing embryos is challenging due to large starch granules within the stroma and the prevalence of nonplastid, storage organelles (oil bodies and protein storage vacuoles) which compromise plastid integrity and purity, respectively. To characterize rapeseed embryoplasts it was necessary to develop an improved isolation procedure. A new method is presented for the isolation of intact plastids from developing embryos of Brassica napus seeds. Intactness and purity of embryoplast preparations was determined using phase-contrast and transmission electron microscopy, immunoblotting, and multidimensional protein identification technology (MudPIT) MS/MS. Eighty nonredundant proteins were identified by MudPIT analysis of embryoplast preparations. Approximately 53% of these proteins were components of photosystem, light harvesting, cytochrome b/f, and ATP synthase complexes, suggesting ATP and NADPH production are important functions for this plastid type.     

Two types of aspartic proteinases from buckwheat seed--gene structure and expression analysis

Two types of aspartic proteinase (AP) genes have been isolated from the cDNA library of developing buckwheat seeds. Analysis of their sequences showed that one of these, FeAP9, resembled the structure and shared high homology with the so-called typical plant APs characterized by the presence of a plant-specific insert (PSI), an element unique among APs. The other cDNA, FeAPL1, encoded an AP-like protein lacking that domain. Different expression profiles were observed for FeAP9 and FeAPL1. FeAPL1 mRNAs were restricted to the seeds only, whereas FeAP9 mRNAs were also present in the other plant tissues - leaves, roots, and flowers. Higher levels of FeAP9 were observed in senescent leaves compared with green leaves. The differential expression pattern of these two unique APs raises the interesting possibility that these proteinases have unique substrate specificity and may have different roles in plant development and other physiological processes.     

Family as a factor in cerebral palsy prevention

The aim of the study was to assess maternal perception of family impact on the course and outcome of rehabilitation in children with cerebral motor impairment. The study included 135 children with cerebral motor impairment. Their motor development was followed-up over a one-year period by use of structured interview with the children's mothers after 12-month rehabilitation. The course of rehabilitation was assessed by the method of locomotor system functional evaluation. The improvement achieved in motor development was significantly better in the group of children whose mothers found their relationships with extended family excellent than in those whose mothers considered it good or poor. The study showed that mothers to children with cerebral motor impairment frequently feel the lack of extended family support, being it real or perceived as such by the mothers due to their emotional sensitivity, suggesting the need of additional studies of the reasons for this. These findings indicate that greater attention should be paid by health professionals to the psychological support offered to these mothers.     

The short-term and long-term effects of parental age in the bean weevil (Acanthoscelides obtectus)

We examined the influence of parental age on life history traits of their offspring in the lines of bean weevil that have evolved different rates of senescence. Measurements included preadult traits (egg size, embryonic developmental time, total preadult developmental time, preadult viability) and adult traits (body weight, total realized fecundity of females, first day of egg laying, early fecundity, late fecundity and longevity). The negative parental age effects were observed for all traits except for the early and total realized fecundity. We did not detect statistically significant line×parental age interactions for either preadult- or adult-survival, so offspring survival did not change with parental age after selection for early vs. late reproduction. It seems that selection acting on the quality of offspring produced by parents of different ages has not been responsible for the evolution of senescence in bean weevil. This revised version was published online in August 2006 with corrections to the Cover Date.     

Cellular multitasking: the dual role of human Cu-ATPases in cofactor delivery and intracellular copper balance

The human copper-transporting ATPases (Cu-ATPases) are essential for dietary copper uptake, normal development and function of the CNS, and regulation of copper homeostasis in the body. In a cell, Cu-ATPases maintain the intracellular concentration of copper by transporting copper into intracellular exocytic vesicles. In addition, these P-type ATPases mediate delivery of copper to copper-dependent enzymes in the secretory pathway and in specialized cell compartments such as secretory granules or melanosomes. The multiple functions of human Cu-ATPase necessitate complex regulation of these transporters that is mediated through the presence of regulatory domains in their structure, posttranslational modification and intracellular trafficking, as well as interactions with the copper chaperone Atox1 and other regulatory molecules. In this review, we summarize the current information on the function and regulatory mechanisms acting on human Cu-ATPases ATP7A and ATP7B. Brief comparison with the Cu-ATPase orthologs from other species is included.     

Effects of Alkylphosphates and Nitrous Oxide on Microbial Degradation of Polycyclic Aromatic Hydrocarbons

We conducted a series of liquid-culture experiments to begin to evaluate the abilities of gaseous sources of nitrogen and phosphorus to support biodegradation of polycyclic aromatic hydrocarbons (PAHs). Nutrients examined included nitrous oxide, as well as triethylphosphate (TEP) and tributylphosphate (TBP). Cultures were established using the indigenous microbial populations from one manufactured gas plant (MGP) site and one crude oil-contaminated drilling field site. Mineralization of phenanthrene was measured under alternative nutrient regimes and was compared to that seen with ammoniacal nitrogen and PO₄. Parallel cultures were used to assess removal of a suite of three- to five-ring PAHs. In summary, the abilities of the different communities to degrade PAH when supplemented with N₂O, TEP, and TBP were highly variable. For example, in the MGP soil, organic P sources, especially TBP, supported a considerably higher degree of removal of low-molecular-weight PAHs than did PO₄; however, loss of high-molecular-weight compounds was impaired under these conditions. The disappearance of most PAHs was significantly less in the oil field soil when organophosphates were used. These results indicate that the utility of gaseous nutrients for PAH bioremediation in situ may be limited and will very likely have to be assessed on a case-by-case basis.