calpain and Magnesium-Deficiency

Magnesium (Mg) plays important roles in maintaining genomic stability and cellular redox. Mg also serves as nature's physiological calcium (Ca) channel antagonist, controlling intracellular Ca entry. Because Ca is the most important second messenger, its intracellular concentration is tightly regulated. Excess intracellular Ca can activate aberrant signaling pathways leading to the acquisition of pathological characteristics and cell injury. Several epidemiological studies have linked Mg deficiency (MgD) and increased Ca:Mg ratios with higher incidences of colon cancer and increased mortality. While it is estimated that less than 50% of the US population consumes the recommended daily allowance for Mg, Ca supplementation is widespread. Therefore, we studied the effect of MgD, with variable Ca:Mg ratios on cellular oxidative stress, cell migration, calpain activity, and associated signaling pathways using the CT26 colon cancer cell line. MgD (with Ca:Mg ratios >1) elevated intracellular Ca levels, calpain activity and TRPM7 expression, as well as oxidative stress and cell migration, consistent with observed degradation of full-length E-cadherin, β-catenin, and N-terminal FAK. MgD was accompanied by enhanced degradation of IκBα and the transactivation domain containing the C-terminus of NF-κB p65 (RelA). MgD-exposed CT26 cells exhibited increased p53 degradation and aneuploidy, markers of genomic instability. By contrast, these pathological changes were not observed when CT26 were cultured under MgD conditions where the Ca:Mg ratio was kept at 1. Together, these data support that exposure of colon cancer cells to MgD with physiological Ca concentrations (or increasing Ca:Mg ratios) leads to the acquisition of a more aggressive, metastatic phenotype.

Topics: Calcium; Calpain; Colonic Neoplasms; Humans; Magnesium; Magnesium Deficiency; Oxidative Stress; Phenotype; Protein Serine-Threonine Kinases; TRPM Cation Channels; Tumor Cells, Cultured

Traumatic brain injury results in a profound decline in intracellular magnesium ion levels that may jeopardize critical cellular functions. We examined the consequences of preinjury magnesium deficiency and post-traumatic magnesium treatment on injury-induced cytoskeletal damage and cell death at 24 h after injury. Adult male rats were fed either a normal (n = 24) or magnesium-deficient diet (n = 16) for 2 wk prior to anesthesia and lateral fluid percussion brain injury (n = 31) or sham injury (n = 9). Normally fed animals were then randomized to receive magnesium chloride (125 micromol, i.v., n = 10) or vehicle solution (n = 11) at 10 min postinjury. Magnesium treatment reduced cortical cell loss (p < 0.05), cortical alterations in microtubule-associated protein-2 (MAP-2) (p < 0.05), and both cortical and hippocampal calpain-mediated spectrin breakdown (p < 0.05 for each region) when compared to vehicle treatment. Conversely, magnesium deficiency prior to brain injury led to a greater area of cortical cell loss (p < 0.05 compared to vehicle treatment). Moreover, brain injury to magnesium-deficient rats resulted in cytoskeletal alterations within the cortex and hippocampus that were not observed in vehicle- or magnesium-treated animals. These data suggest that cortical cell death and cytoskeletal disruptions in cortical and hippocampal neurons may be sensitive to magnesium status after experimental brain injury, and may be mediated in part through modulation of calpains.

Topics: Animals; Brain; Brain Injuries; Calpain; Cell Death; Cell Survival; Cerebral Cortex; Cytoskeleton; Disease Models, Animal; Hippocampus; Magnesium; Magnesium Deficiency; Male; Microtubule-Associated Proteins; Neurons; Neuroprotective Agents; Rats; Rats, Sprague-Dawley; Spectrin