Cold wind stimulation reflex.

The bradycardia induced by cold wind blown on the face and the early cephalic release of insulin induced by feeding have been shown to be caused by a vagal reflex stimulation. An experiment was designed to determine whether cold wind blown on the face would induce both pancreatic and cardiac stimulation. A 4 degrees C wind blown on the face for 4 min produced a rapid and persistent bradycardia, which interestingly persisted for up to 35 min after the test. The effect on respiration rate is more gradual and vanishes immediately after cold wind stimulation. Cold wind produced a slight reduction of insulin secretion, as evidenced by the fall of both plasma insulin and C-peptide, and caused a significant increase in plasma norepinephrine. These results suggest that the cold wind action of the vagus nerve is exerted on the heart and that of the sympathetic on the pancreas, whereas during the cephalic phase of feeding a vagal influence is observed on the pancreas and a sympathetic action on the heart. The mechanisms of the quantitative and qualitative control of these autonomic responses are not known and deserve further investigation.     

Cold lability of membrane-bound F1-ATPase.

1. Preincubation of MgATP submitochondrial particles with EDTA or Tris.HCl liberated a measurable amount of ATPase inhibitor that could be rapidly purified using only trichloroacetic acid precipitation and heat treatment. 2. In spite of the emergence of high ATPase activity, a considerable amount of ATPase inhibitor was left in the particles. Comparative analysis of other submitochondrial preparations indicated that only AS-particles were effectively depleted. 3. The high ATPase activity of inhibitor-deficient particles, was labile at low temperature provided that the exposure to cold was done in the presence of MgATP. Other nucleotides could not substitute for ATP. Glycerol inhibited and salts enhanced the cold inactivation of membrane-bound F1-ATPase. Isolation of F1-ATPase from cold-inactivated particles yielded a soluble preparation of correspondingly lower activity. 4. It is concluded that together with the increase of ATPase activity, the ATP-dependent cold lability of membrane-bound F1-ATPase and the dislocation of ATPase inhibitor at non operative sites reveal the extent of ATPase complex disorganization.     

Cold adaptation and thyroid hormone metabolism.

Resting oxygen consumption and energy expenditure is sensitive to slight alterations in thyroid function. This means that timing and magnitude of cold adaptation would to some extent depend on thyroid function. Local thyroid hormone metabolism is important for energy expenditure and dissipation of heat in special tissues. Recruitment of brown adipocytes and upregulation of uncoupling protein 1 in mitochondria depends on high tissue T3 concentrations. Most of this T3 is derived from local 5' deiodination of T4. Brown fat is vital for cold exposed mice and rats, and may be important for temperature adaptation in human neonates. The role of thyroid hormone metabolism in adult human cold adaptation has not been finally clarified. Hypothetically, cold exposure may enhance T3 production by deiodination of T4 in skeletal muscle, which may enhance heat production in muscle via a change in muscle fiber type. Another hypothetical possibility is recruitment of brown adipocytes embedded in white adipose tissue in human adults. Understanding cold adaptation in human adults may lead to development of new drugs against obesity.     

Cold activation of complement i. presence of coagulation-related activator.

Determination of the complement titer in the serum and plasm of 120 patients with chronic liver diseases showed that in eight (7%) patients with cirrhosis of the liver, chronic active or chronic inactive hepatitis complement in the serum was less than half in the plasma. The dissociation of complement serum and plasma was due to cold activation of the classical pathway of complement in vitro since serum drawn from these patients at 37 degrees C lost hemolytic activity in 4 hours when transferred to a cold environment. Neither HB antigen nor cryoglobulin participated in this phenomenon. The activation of complement in the cold could be prevented by increasing the ionic strength, or by adding vitamin E or, to a lesser extent its vehicle HCO-60, while heparin, Trasylol, soybean trypsin inhibitor, or hirudin had no effect. Trans-AMCHA prevented activation in one case. It is speculated that a factor appearing as a result of blood clotting is able to activate the classical pathway of complement in the cold; it is probably not related to Hageman factor (factor XII), factor VII, thrombin, kallikrein.