BACKGROUND: Cellular metabolic dysfunction is associated with occurrence of multiple-organ failure after critical illness. Glutamine (GLN) attenuates cellular metabolic dysfunction in critical illness models. The mechanism of this protection is unclear. We previously demonstrated that GLN's benefit in critical illness might be due to enhanced heat shock protein (HSP) expression. We hypothesize that GLN's attenuation of cellular metabolic dysfunction is dependent on presence of heat shock factor-1 (HSF-1). METHODS: HSF-1 wild-type and knockout mouse embryonic fibroblasts (HSF-1+/+ and HSF-1-/-) were used in all experiments. Cells were not treated, or were treated with 8 mmol/L GLN and immediately exposed to heat stress injury (45 degrees C for 45 minutes). Cells were harvested for metabolic analysis by nuclear magnetic resonance (NMR) at 24 hours postinjury. Cell survival was assessed using the MTS assay. RESULTS: GLN treatment in HSF-1+/+ cells led to significant attenuation of decreases in adenosine triphosphate (ATP)/adenosine diphosphate (ADP) ratio, phosphomonoester/phosphodiester (PME/PDE) ratio, and cell survival observed in non-GLN-treated HSF-1+/+ cells. In HSF-1-/- cells, the beneficial effect of GLN on preservation of ATP/ADP ratio, PME/PDE proliferation, and cell survival was lost. GLN-treated HSF-1-/- cells had a significant increase in extracellular lactate concentrations vs GLN-treated HSF+/+ cells. CONCLUSIONS: GLN treatment attenuated cellular metabolic dysfunction and improved cell membrane recovery only in HSF-1+/+ cells. Cellular injury, as measured by lactate release and cell survival assay, was improved by GLN treatment in HSF-1+/+ cells alone. Thus, GLN's beneficial effect on cellular metabolic dysfunction and cell survival appears to be dependent on HSF-1 expression.
BACKGROUND: Cellular metabolic dysfunction is associated with occurrence of multiple-organ failure after critical illness. Glutamine (GLN) attenuates cellular metabolic dysfunction in critical illness models. The mechanism of this protection is unclear. We previously demonstrated that GLN's benefit in critical illness might be due to enhanced heat shock protein (HSP) expression. We hypothesize that GLN's attenuation of cellular metabolic dysfunction is dependent on presence of heat shock factor-1 (HSF-1). METHODS:HSF-1 wild-type and knockout mouse embryonic fibroblasts (HSF-1+/+ and HSF-1-/-) were used in all experiments. Cells were not treated, or were treated with 8 mmol/L GLN and immediately exposed to heat stress injury (45 degrees C for 45 minutes). Cells were harvested for metabolic analysis by nuclear magnetic resonance (NMR) at 24 hours postinjury. Cell survival was assessed using the MTS assay. RESULTS:GLN treatment in HSF-1+/+ cells led to significant attenuation of decreases in adenosine triphosphate (ATP)/adenosine diphosphate (ADP) ratio, phosphomonoester/phosphodiester (PME/PDE) ratio, and cell survival observed in non-GLN-treated HSF-1+/+ cells. In HSF-1-/- cells, the beneficial effect of GLN on preservation of ATP/ADP ratio, PME/PDE proliferation, and cell survival was lost. GLN-treated HSF-1-/- cells had a significant increase in extracellular lactate concentrations vs GLN-treated HSF+/+ cells. CONCLUSIONS:GLN treatment attenuated cellular metabolic dysfunction and improved cell membrane recovery only in HSF-1+/+ cells. Cellular injury, as measured by lactate release and cell survival assay, was improved by GLN treatment in HSF-1+/+ cells alone. Thus, GLN's beneficial effect on cellular metabolic dysfunction and cell survival appears to be dependent on HSF-1 expression.
Authors: Paul E Wischmeyer; Rachael A Mintz-Cole; Christine H Baird; Kirk A Easley; Addison K May; Harry C Sax; Kenneth A Kudsk; Li Hao; Phong H Tran; Dean P Jones; Henry M Blumberg; Thomas R Ziegler Journal: Clin Nutr Date: 2019-03-13 Impact factor: 7.324