Induction of glutamine synthetase expression after major burn injury is tissue specific and temporally variable

Proteomics reveals that quinoa bioester promotes replenishing effects in epidermal tissue

The continuous search for natural products that attenuate age-related losses has increasingly gained notice; among them, those applicable for skin care have drawn significant attention. The bioester generated from the Chenopodium quinoa’s oil is a natural-origin ingredient described to produce replenishing skin effects. With this as motivation, we used shotgun proteomics to study the effects of quinoa bioester on human reconstructed epidermis tridimensional cell cultures after 0, 3, 6, 12, 24, and 48 h of exposure. Our experimental setup employed reversed-phase nano-chromatography coupled online with an Orbitrap-XL and PatternLab for proteomics as the data analysis tool. Extracted ion chromatograms were obtained as surrogates for relative peptide quantitation. Our findings spotlight proteins with increased abundance, as compared to the untreated cell culture counterparts at the same timepoints, that were related to preventing premature aging, homeostasis, tissue regeneration, protection against ultraviolet radiation and oxidative damage.

Keratinocytes as depository of ammonium-inducible glutamine synthetase: age- and anatomy-dependent distribution in human and rat skin

In inner organs, glutamine contributes to proliferation, detoxification and establishment of a mechanical barrier, i.e., functions essential for skin, as well. However, the age-dependent and regional peculiarities of distribution of glutamine synthetase (GS), an enzyme responsible for generation of glutamine, and factors regulating its enzymatic activity in mammalian skin remain undisclosed. To explore this, GS localization was investigated using immunohistochemistry and double-labeling of young and adult human and rat skin sections as well as skin cells in culture. In human and rat skin GS was almost completely co-localized with astrocyte-specific proteins (e.g. GFAP). While GS staining was pronounced in all layers of the epidermis of young human skin, staining was reduced and more differentiated among different layers with age. In stratum basale and in stratum spinosum GS was co-localized with the adherens junction component beta-catenin. Inhibition of, glycogen synthase kinase 3beta in cultured keratinocytes and HaCaT cells, however, did not support a direct role of beta-catenin in regulation of GS. Enzymatic and reverse transcriptase polymerase chain reaction studies revealed an unusual mode of regulation of this enzyme in keratinocytes, i.e., GS activity, but not expression, was enhanced about 8-10 fold when the cells were exposed to ammonium ions. Prominent posttranscriptional up-regulation of GS activity in keratinocytes by ammonium ions in conjunction with widespread distribution of GS immunoreactivity throughout the epidermis allows considering the skin as a large reservoir of latent GS. Such a depository of glutamine-generating enzyme seems essential for continuous renewal of epidermal permeability barrier and during pathological processes accompanied by hyperammonemia.

Molecular approach to annelid regeneration: cDNA subtraction cloning reveals various novel genes that are upregulated during the large-scale regeneration of the oligochaete, Enchytraeus japonensis

To identify genes specifically activated during annelid regeneration, suppression subtractive hybridization was performed with cDNAs from regenerating and intact Enchytraeus japonensis, a terrestrial oligochaete that can regenerate a complete organism from small body fragments within 4-5 days. Filter array screening subsequently revealed that about 38% of the forward-subtracted cDNA clones contained genes that were upregulated during regeneration. Two hundred seventy-nine of these clones were sequenced and found to contain 165 different sequences (79 known and 86 unknown). Nine clones were fully sequenced and four of these sequences were matched to known genes for glutamine synthetase, glucosidase 1, retinal protein 4, and phosphoribosylaminoimidazole carboxylase, respectively. The remaining five clones encoded an unknown open-reading frame. The expression levels of these genes were highest during blastema formation. Our present results, therefore, demonstrate the great potential of annelids as a new experimental subject for the exploration of unknown genes that play critical roles in animal regeneration.

Quantitative effects of thermal injury and insulin on the metabolism of the skeletal muscle using the perfused rat hindquarter preparation

Injury from a severe burn or trauma can propel the body into a hypermetabolic state that can lead to the significant erosion of lean muscle mass. Investigations describing this process have been somewhat limited due to the lack of adequate experimental models. Here we report the use of a perfused rat hindquarter preparation to study the consequences of a moderate burn injury (approximately 20% total body surface area), with or without the addition of exogenous insulin (12.5 mU/mL), on the fluxes of major metabolites across the isolated skeletal muscle. The metabolic flux data was further analyzed using metabolic flux analysis (MFA), which allows for the estimation of the impact of these conditions on the intracellular muscle metabolism. Results indicate that this model is able to capture the increased rate of proteolysis, glutamine formation, and the negative nitrogen balance associated with the burn-induced hypermetabolic state. The inclusion of exogenous insulin resulted in significant changes in several fluxes, including an increase in the metabolism of glucose and the flux through the pentose phosphate pathway, as well as a reduction in the metabolism of glutamine, alanine, and leucine. However, insulin administration did not affect the nitrogen balance or the rate of proteolysis in the muscle, as has been suggested using other techniques. The use of the perfused hindquarter model coupled with MFA is a physiologically relevant and experimentally flexible platform for the exploration of skeletal muscle metabolism under catabolic conditions, and it will be useful in quantifying the specific metabolic consequences of other therapeutic advances.

Glucocorticoid induced expression of glutamine synthetase in hepatoma cells

The enzyme glutamine synthetase (GS) ranks as one of the most remarkable glucocorticoid-inducible vertebrate genes. However, little is known about the responsible DNA elements and the mode of glucocorticoid action. This is especially the case for the induction of GS in hepatoma cells. In the work presented, the rat hepatoma cell line FAO was used as a model to study the induction of GS under the influence of glucocorticoids. FAO cells do not show GS activity in the absence of glucocorticoids and are strongly responding to their presence. Analyzing sequences of several thousand base pairs upstream and downstream from the transcriptional start point of the GS gene, a glucocorticoid responsible element was identified within the first intron of the gene. However, evidence is presented that aside from a primary effect on transcription glucocorticoids mediate their effect on the expression of GS also at the posttranscriptional level.

Metabolic evidence for adaptation to a high protein diet in rats

This study was designed to assess the effects of long-term adaptation to a high protein diet on energy intake, body weight gain, body composition and splanchnic metabolic indicators in rats. For this purpose, adult male Wistar rats were fed either a 50 g/100 g dry matter (DM) protein diet (P50 group) or a 14 g/100 g DM protein diet (P14 group) for 21 d. These two groups were compared with a P14 pair-fed (P14-pf) group that consumed the same daily energy as the P50 group. The energy intake of the P50 group was 16 +/- 1% less than that of the P14 group (P < 0.05), and the P50 group had significantly lower body weight. The P50 group had significantly less adipose tissue compared with both P14 and P14-pf rats. The activities of the brush border membrane enzymes, neutral aminopeptidase and gamma-glutamyl transferase, were significantly higher in the P50 group than in the P14 rats. Similarly, the activities of alanine aminotransferase, arginase and serine dehydratase were significantly higher in the liver of P50 rats compared with P14 rats. Both amino acid transporter system A and X(A,G-) activities, measured in freshly isolated hepatocytes, were significantly higher in the P50 group (8- and 1.5-fold, P < 0.05, respectively) compared with the P14 group. The 1.5-fold increase in the steady-state activity of X(A,G-) was accompanied by a doubling of EAAT2 mRNA, involved in the system X(A,G-). This study provides confirmation that specific biochemical and molecular adaptive processes of the splanchnic area are involved in the response to variations in the protein content of the diet.

Identification of glucocorticoid-responsive elements that control transcription of rat glutamine synthetase

Basal expression of glutamine synthetase (GS) is very low in rat lung and muscle and remarkably enhanced by glucocorticoid hormones during trauma and catabolic states. Although this response is believed to be transcriptionally regulated, the genetic elements responsible for tissue-specific glucocorticoid induction of GS expression have not been identified. A rat lung epithelial cell line (L2) and a glucocorticoid receptor-deficient human prostate cancer cell line (PC3), together with GS reporter gene constructs, were utilized in gene transfer experiments to identify two regions within the rat genomic clone gGS3 that imparted dexamethasone (Dex) responsiveness to both the homologous GS promoter and the heterologous herpes simplex virus thymidine kinase promoter in glucocorticoid receptor-dependent fashions. One region lies nearly 6 kb upstream of the GS transcription initiation site, and the other lies within the first intron of the GS gene. Dex responsiveness was localized to a 325-bp fragment of the intron region containing a canonical glucocorticoid response element and to a 225-bp fragment of the far-upstream region containing three separate glucocorticoid response element half-sites. The GS promoter exhibited relatively high basal activity that was repressed by inclusion of the far-upstream or the intron glucocorticoid-responsive region. Dex treatment negated this repression. A model is suggested in which the glucocorticoid-receptor unit causes derepression of lung and muscle GS transcription during trauma and catabolic states.

Glutamine synthetase gene expression in the lungs of endotoxin-treated and adrenalectomized rats

During sepsis, the lung responds by exporting increased amounts of the amino acid glutamine. This response is accompanied by increased enzymatic activity of glutamine synthetase (GS), which catalyzes the synthesis of glutamine from glutamate and ammonia. It is also known that GS expression in the rat lung can be induced by glucocorticoid hormones. To determine whether the septic response and the response to glucocorticoids are related, we have characterized the induction of GS expression during lipopolysaccharide (LPS)-induced endotoxemia in normal, neutropenic, and adrenalectomized rats. Normal rats exhibited a time- and dose-dependent induction of GS mRNA levels after a single intraperitoneal dose of LPS. Responses to LPS were maximal at doses of 0.1 mg/kg body wt and above. A single 10 mg/kg body wt dose of LPS led to a rapid, transient sevenfold increase in GS mRNA (P < or = 0.1) and a twofold increase in GS protein level 8 h postinjection. Induction of lung GS mRNA 4 h after LPS injection was approximately fivefold in neutropenic (P < or = 0.1) and fourfold in nonneutropenic control rats (P < or = 0.1), suggesting that infiltrating neutrophils or neutrophil-derived factors are not required for GS induction. In response to high-dose, short-term endotoxemia, adrenalectomized rat lung GS mRNA increased twofold (P < or = 0.02) compared with sixfold in sham-operated control rats (P < or = 0.02). However, in response to low-dose, long-term endotoxemia, adrenalectomized rat lung GS mRNA increased threefold (P < or = 0.02) compared with fourfold in sham-operated control rats (P < or = 0.02). Adrenalectomy did not affect the elevation of lung GS mRNA levels in response to dexamethasone. In addition, GS mRNA was induced four- and sixfold in rat microvascular pulmonary endothelial cells exposed to plasma from control and septic rats, respectively. The addition of a glucocorticoid antagonist, RU-38486, completely blocked GS gene induction in the presence of control plasma but only attenuated the response to plasma from septic animals by 30%. These results suggest that GS gene induction during sepsis is only partially mediated by adrenal-derived glucocorticoid hormones.