Recent developments in lipid emulsions: relevance to intensive care.

For years, intravenous lipid supply has been considered as a means of providing an efficient fuel to many tissues of the body and of preventing or correcting essential fatty acid deficiency. The potential for lipid emulsions to modulate cell function via their content of specific fatty acids and of liposoluble vitamins has not received much attention yet. Soybean [long-chain triglycerides (LCT)] emulsions provide a valuable source of energy, but they are excessively rich in omega-6 essential fatty acids (FAs). Their infusion is associated with an accumulation of linoleate and a reduction of long-chain (> or = C20) omega-6 and omega-3 fatty acids in cell membrane phospholipids, as well as with a depletion of antioxidant status, associated with a reduction of alpha-tocopherol in plasma lipoproteins. Infusions of the mixed medium-chain triglycerides (MCT)/LCT (50%:50%; wt:wt) largely bypass these disadvantages. In addition, plasma elimination of MCT/LCT is faster than that of LCT. Recent advances indicate a great potential for omega-3 FAs incorporated into membrane phospholipids to modulate cell response to various stimuli and to influence several intracellular metabolic processes. Furthermore, some of these FA directly influence the production and the action of important mediators, the eicosanoids. In practical terms, an increased intake of omega-3 FAs may reduce inflammatory and thrombotic responses while protecting tissue microperfusion and immune defenses. Such properties may find interesting applications in several types of intensive care unit patients, provided that omega-3 FA incorporation takes place promptly. We recently had the opportunity to study in vitro and in vivo the metabolism of emulsions made of a mixture of MCT, soybean LCT, and fish oil triglycerides. Plasma elimination of such preparations appeared to be very fast, and their infusion was not associated with a prolonged residence of emulsion particles. In addition, uptake of remnants enriched with omega-3 FAs and liposoluble vitamins was fairly fast and occurred in several types of cells, leading to an efficient incorporation of omega-3 FAs in cell membranes within a few hours. The understanding that remnant uptake plays a significant role in the delivery of components included in lipid emulsions opens new areas of investigation and is likely to find several conditions of applications for new types of preparations.

Molecular cloning of an orphan G-protein-coupled receptor that constitutively activates adenylate cyclase.

A human gene encoding an orphan G-protein-coupled receptor named ACCA (adenylate cyclase constitutive activator) was isolated from a genomic library using as a probe a DNA fragment obtained by low-stringency PCR. Human ACCA (hACCA) is a protein of 330 amino acids that exhibits all the structural hallmarks of the main family of G-protein-coupled receptors. Expression of hACCA resulted in a dramatic stimulation of adenylate cyclase, similar in amplitude to that obtained with other Gs-coupled receptors fully activated by their respective ligands. This stimulation was obtained in a large variety of stable cell lines derived from various organs, and originating from different mammalian species. hACCA was found to be the human homologue of a recently reported mouse orphan receptor (GPCR21). The mouse ACCA (mACCA) was therefore recloned by PCR, and expression of mACCA in Cos-7 cells demonstrated that the mouse receptor behaved similarly as a constitutive activator of adenylate cyclase. It is not known presently whether the stimulation of adenylate cyclase is the result of a true constitutive activity of the receptor or, alternatively, is the consequence of a permanent stimulation by a ubiquitous ligand. The tissue distribution of mACCA was determined by RNase protection assay. Abundant transcripts were found in the brain, whereas lower amounts were detected in testis, ovary and eye. Various hypotheses concerning the constitutive activity of ACCA and their potential biological significance are discussed.

Molecular cloning of a mouse melanocortin 5 receptor gene widely expressed in peripheral tissues.

A mouse genomic clone named HGMP01B has been isolated by homology screening with a probe representing part of the human melanocortin 3 receptor gene. HGMP01B was found to encode a 325 amino acid protein with all the landmarks of G-protein-coupled receptors and belonging to the growing melanocortin receptor family. This receptor displays four potential sites for N-linked glycosylation and five potential sites of phosphorylation by protein kinase C. The HGMP01B gene was found to be expressed in many tissues, including skin, adrenal gland, skeletal muscle, bone marrow, spleen, thymus, gonads, uterus, and brain. A stable Chinese hamster ovary (CHO) cell line expressing approximately 10,000 receptors per cell was established. This cell line displayed a saturable binding capacity for the radioiodinated alpha-melanocyte-stimulating hormone (alpha-MSH) analog [Nle4,D-Phe7]-alpha-MSH (NDP-MSH) with an apparent Kd of 1.47 +/- 0.15 nM. Binding of the labeled ligand was competed for by all melanocortin peptides, except beta-endorphin or corticotropin-like intermediate lobe peptide (CLIP). NDP-MSH was the most powerful competitor, followed by alpha-MSH, adrenocorticotropic hormone (ACTH), beta-MSH, the gamma-MSHs, and ACTH 4-10. Functional assays confirmed that HGMP01B, like other melanocortin receptors, stimulated adenylyl cyclase. The potency order obtained in these cyclic adenosine monophosphate (cAMP) accumulation assays was consistent with that of the binding studies. HGMP01B therefore appears as a fifth melanocortin receptor (MC5), responding mainly to alpha-MSH (EC50 = 1.07 +/- 0.13 nM) and endowed with a pharmacological profile similar to that of the melanocyte MSH (MC1) receptor, but characterized by a broad tissue distribution.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular cloning, functional expression and pharmacological characterization of a mouse melanocortin receptor gene.

We describe the cloning of the mouse HGMP01A gene that encodes a melanocortin receptor functionally distinct from the adrenal cortex corticotropin (adrenocorticotrophic hormone; ACTH) receptor and the melanocyte-stimulating hormone (MSH) receptor expressed in melanoma. The gene encodes a protein of 323 amino acids with a calculated molecular mass of 35,800 Da, displaying potential sites for N-linked glycosylation and phosphorylation by protein kinase C. An RNAase protection assay detected weak expression in the brain, but not in adrenal gland, skin, or any of the other tissues tested. Stable CHO cell lines expressing over 100,000 receptors per cell were generated. The recombinant receptor binds iodinated [Nle4,D-Phe7]alpha-MSH (NDP-MSH) with an apparent Kd of 700 pM. Displacement of the ligand by a variety of pro-opiomelanocortin-derived peptides revealed a pharmacological profile distinct from that of the classical ACTH and MSH receptors. NDP-MSH was the most powerful competitor (IC50 1.4 nM), followed by gamma-MSH (IC50 7 nM). alpha-MSH, beta-MSH and ACTH-(1-39) were significantly less potent, with IC50 values of 30, 19 and 21 nM respectively. ACTH-(4-10) was poorly active (IC50 2.4 microM), while corticotropin-like intermediate lobe peptide (CLIP) and beta-endorphin were totally ineffective. The recombinant receptor was found to stimulate adenylate cyclase. The potency order of the agonists in this assay was consistent with that of the binding displacement assays. This receptor represents the orthologue of the human melanocortin 3 receptor reported recently. The growing family of melanocortin receptors constitute the molecular basis for the variety of actions of melanocortins that have been described over the years. The availability of functionally expressed receptors from the melanocortin family will allow the development of a specific pharmacology, and a better understanding of the function of the pro-opiomelanocortin-derived peptides.

Molecular cloning, functional expression and pharmacological characterization of a human bradykinin B2 receptor gene.

The gene encoding a putative G protein-coupled receptor (HG10) was cloned from human genomic DNA by low stringency PCR and found to be homologous to the recently described rat bradykinin B2 receptor. The receptor was expressed in xenopus oocytes and stably transfected CHO cell lines. Binding studies demonstrated that HG10 encodes a high affinity BK receptor with an apparent Kd of 150 pM. Displacement by BK agonists and antagonists allowed the characterization of the receptor as a B2 subtype. Functional coupling to the Ca(2+)-phosphatidylinositol cascade was demonstrated in transfected CHO cells where inositol phosphates accumulation and intracellular calcium concentration were elevated in response to BK stimulation. The agonistic and antagonistic properties of BK analogs do not match strictly the pharmacological profile described for the rat or guinea pig B2 receptor subtypes or the putative B3 subtype. This discrepancy is attributed either to species variability or to differences in the coupling efficiency of receptors to the transduction cascade in different cell types. From our results, the existence of B3 receptors and of B2 subtypes appears questionable.

Expression of members of the putative olfactory receptor gene family in mammalian germ cells.

A series of genomic and complementary DNA clones encoding new putative members of G protein-coupled receptors were isolated using homology cloning and low-stringency polymerase chain reaction. Among the unidentified receptors ('orphan receptors'), a human genomic clone (HGMP07) was characterized by the presence of its transcripts in the testis and by its belonging to a large subfamily of genes sharing extensive sequence similarities. Sequence comparison demonstrated that this gene subfamily is the human counterpart of the putative rat olfactory receptors cloned recently. Another 48 members of the family were cloned. Northern blotting further demonstrated the presence of olfactory receptor transcripts in germ cells. Our finding suggests that a common receptor gene family encodes olfactory receptors and sperm cell receptors that could be involved in chemotaxis during fertilization.