Biphasic effects of orexin-A on autonomic nerve activity and lipolysis.

Previously, we showed that orexin-A, a 33-aa peptide, influences renal sympathetic nerve activity. Because the autonomic nervous system plays an important role in the regulation of lipid metabolism, we investigated the in vivo effects of orexin-A on the sympathetic nerve activity innervating white adipose tissue (WAT-SNA) and lipolysis. We found that intracerebroventricular (icv) administration of orexin-A at doses of 1 microg/rat and 10 ng/rat elevated and suppressed WAT-SNA, respectively. The effect of the high dose of orexin-A (1 microg/rat) was eliminated by pretreatment with diphenhydramine hydrochloride, a histamine H(1) receptor antagonist. In contrast, the effect of the low dose of orexin-A (10 ng/rat) was suppressed by thioperamide maleate salt, a histamine H(3) receptor antagonist. Moreover, icv administration of 1 microg/rat and 10 ng/rat of orexin-A increased and decreased the levels of plasma free fatty acids (FFAs), respectively. The effect of 1 microg/rat of orexin-A on plasma FFA was eliminated by propranolol hydrochloride, a beta-adrenergic receptor blocker, and also by diphenhydramine. The effect of orexin-A at dose of 10 ng/rat disappeared by pretreatment with atropine sulfate, a muscarinic receptor blocker, and thioperamide maleate salt. Our results suggest that high doses of orexin-A may regulate the lipolytic processes in adipose tissue through facilitation of the sympathetic nervous system, which is driven by histamine neurons through the H(1) receptor, and that the beta(3)-receptor may be involved in this enhanced lipolytic response. Low doses of orexin-A, on the other hand, may lower lipolysis by suppressing sympathetic nerve activity via the H(3)-receptor, and the muscarinic receptor may be related to this response.

Regulation of sympathetic nerve activity by L-carnosine in mammalian white adipose tissue.

Previously, we showed that l-carnosine, a bioactive dipeptide, influences the sympathetic nerve activity innervating kidney and brown adipose tissue. Because the autonomic nervous system plays an important role in the regulation of lipid metabolism, we investigated the in vivo effects of L-carnosine on the sympathetic nerve activity innervating white adipose tissue (SNA-WAT) and lipolysis. We found that intraperitoneal (ip) administration of L-carnosine at doses of 100 ng/rat and 10 microg/rat elevated and suppressed SNA-WAT, respectively. The effect of lower dose of L-carnosine (100 ng/rat) was eliminated by pretreatment with diphenhydramine hydrochloride, a histamine H(1) receptor antagonist. In contrast, the effect of higher dose of L-carnosine (10 microg/rat) was suppressed by thioperamide maleate salt, a histamine H(3) receptor antagonist. Moreover, ip administration of 100 ng and 10 microg of L-carnosine increased and decreased the levels of plasma free fatty acids (FFAs), respectively. The changes of plasma FFAs resulting from the exposure to 100 ng and 10 microg of L-carnosine were diminished by the beta-adrenergic receptor blocker propranolol hydrochloride and the muscarinic receptor blocker atropine sulfate, respectively; and eliminated by the corresponding histamine receptor antagonists, which eliminated the changes in SNA-WAT. Our results suggest that low doses of L-carnosine may regulate the lipolytic processes in adipose tissue through facilitation of the sympathetic nervous system, which is driven by histamine neurons through the H(1) receptor, and that the beta(3)-receptor may be involved in this enhanced lipolytic response. High doses of L-carnosine, on the other hand, may lower lipolysis by suppressing sympathetic nerve activity via the H(3) receptor, and the muscarinic receptor may be related to this response.

[Research development of catalytic-kinetic spectrophotometric determination of trace manganese].

A review of recent research progresses in the determination of trace amount of manganese with catalytic-kinetic spectrophotometric method is presented and discussed in the present paper. Firstly, by comparison it is showed that catalytic-kinetic spectrophotometry has more advantages than atomic absorption spectrophotometry and extraction-spectrophotometry for the determination of trace amounts of manganese. The review and discussion of the recent research developments in the catalytic discoloring spectrophotometry and catalytic coloring spectrophotometry for the determination of trace amounts of manganese are given respectively. Finally the development trends and application perspectives for the catalytic-kinetic spectrophotometry in the future are discussed and probed. Twenty five references are cited.