Manipulating thyroid status alters endoplasmic reticulum calcium homeostasis in rat cerebellum.

Thyroid-related hormones regulate the efficiency and expression of sarco-endoplasmic reticulum calcium ATPases in cardiac and skeletal muscle. However, little is known about the relationship between thyroid hormones and calcium (Ca2+) homeostasis in the brain. It is hypothesized that manipulating rat thyroid hormone levels would induce significant brain Ca2+ adaptations consistent with clinical findings. Adult male Sprague-Dawley rats were assigned to one of three treatment groups for 28 days: control, hypothyroid (6-n-propyl-2-thiouracil (PTU), an inhibitor of thyroxine (T4) synthesis), and hyperthyroid (T4). Throughout, rats were given weekly behavioral tests. Ca2+ accumulation decreased in the cerebellum in both hyper- and hypothyroid animals. This was specific to different ER pools of calcium with regional heterogeneity in the response to thyroid hormone manipulation. Behavioral tasks demonstrated sensitivity to thyroid manipulation, and corresponded to alterations in calcium homeostasis. Ca2+ accumulation heterogeneity in chronic hyper- and hypothyroid animals potentially explains clinical manifestations of altered thyroid status.

Regulation of sarcoendoplasmic reticulum Ca2+-ATPase (SERCA) in turtle muscle and liver during acute exposure to anoxia.

The freshwater turtle Trachemys scripta elegans naturally tolerates extended periods of anoxia during winter hibernation at the bottom of ice-locked ponds. Survival in this anoxic state is facilitated by a profound depression of metabolic rate. As calcium levels are known to be elevated in anoxic turtles, and ion pumping is an ATP-expensive process, we proposed that activity of the sarcoendoplasmic reticulum Ca(2+)-ATPase (SERCA) would be reduced in muscle and liver of T. s. elegans during acute (up to 20 h) exposure to anoxia. SERCA activity decreased approximately 30% in liver and approximately 40% in muscle after 1 h anoxia exposure and was approximately 50% lower after 20 h of anoxia exposure in both tissues, even though SERCA protein levels did not change. SERCA kinetic parameters (increased substrate K(m) values, increased Arrhenius activation energy) were indicative of a less active enzyme form under anoxic conditions. Interestingly, the less active SERCA in anoxic turtles featured greater stability than the enzyme from normoxic animals as determined by both kinetic analysis (effect of low pH and low temperatures on K(m) MgATP) and conformational resistance to urea denaturation. The quick time course of deactivation and the stable changes in kinetic parameters that resulted suggested that SERCA was regulated by a post-translational mechanism. In vitro experiments indicated that SERCA activity could be blunted by protein phosphorylation and enhanced by dephosphorylation in a tissue-specific manner.

EsMlp, a muscle-LIM protein gene, is up-regulated during cold exposure in the freeze-avoiding larvae of Epiblema scudderiana.

Screening of a cDNA library identified transcripts that were up-regulated by cold (4 or -20 degrees C) exposure in larvae of the freeze-avoiding goldenrod gall moth, Epiblema scudderiana. One clone contained a full-length open reading frame encoding a protein of 94 amino acids. The gene product, with 79.1% of residues identical with the Drosophila LIM protein Mlp60A, was named EsMlp and contained a single LIM domain and consensus sequences characteristic of a LIM protein. Transcript levels rose approx twofold when larvae were shifted from 4 to -20 degrees C and approx threefold over the midwinter months compared with larvae sampled in October or April. EsMlp expression was high in larval head (possibly due to expression in pharyngeal muscles) and body wall but was not detected in fat body. Immunoblotting revealed a three- to fourfold increase in EsMlp protein in midwinter larvae (January-February) compared with November-collected animals and a further rise to eightfold higher than November values in larvae collected in April. Cold up-regulation of EsMlp and the pattern of EsMlp levels in the larvae suggest possible roles for the protein, such as in muscle maintenance over the winter or as a preparative function that could facilitate the rapid resumption of development and metamorphosis when environmental temperatures rise in the spring.