Amines whose pK values lie between about 5 and 9 are lysosomotropic because lysosomes are acidic intracellular compartments. If such amines bear long hydrophobic chains, they become detergents upon protonation inside the lysosomes, rupturing the lysosomal membrane and killing the cell. Six types of lysosomotropic amines have been prepared that all behave in the expected manner. They are cytotoxic to all lysosome-bearing cells but not red blood cells, which lack lysosomes. Their mode of action, the effect of alkyl chain length on activity, and the fact that their cytotoxic action appears only above a threshhold intracellular concentration support the belief that they behave as lysosomotropic detergents. Among the potential applications is cancer chemotherapy.
Several laboratories, including our own have reported the synthesis and activity of certain low relative molecular mass inhibitors of mammalian serine proteases, especially human leukocyte elastase (HLE, EC 3.4.21.37), an enzyme whose degradative activity on lung elastin has been implicated as a major causative factor in the induction of pulmonary emphysema, and which is present in the azurophil granules of human polymorphonuclear leukocytes (PMN). Normally, these granules fuse with phagosomes containing engulfed foreign material (such as bacteria), and HLE, in combination with other lysosomal enzymes, catabolizes the particles. Under certain pathological conditions, however, PMN become attached to host protein (elastin fibres, basement membrane, connective tissue, immune complexes), and in response to this adherence, the granules may fuse with the PMN outer membrane and release their contents, including HLE, directly onto the tissue. Besides emphysema, HLE may also contribute to the pathogenesis of disease states such as adult respiratory distress syndrome, and its potential involvement in rheumatoid arthritis makes HLE inhibitors of considerable interest. It is known that cephalosporin antibiotics (for example, cephalothin (compound I, Table 2)) are acylating inhibitors of bacterial serine proteases which help synthesize the cell wall by performing a transpeptidation reaction on a peptidyl substrate bearing a D-Ala-D-Ala terminus. We now report that neutral cephalosporins (that is, compounds not bearing a free carboxyl at position C-4) can be modified to become potent time-dependent inhibitors of HLE.
The continuing discovery and development of beta-lactams as antibiotics has had an unparalleled impact on the overall health and well-being of society. Recently, appropriately substituted cephalosporins were shown to be potent inhibitors of elastase, suggesting a novel therapeutic role for the beta-lactams in the control of emphysema and other degenerative diseases. We have now solved and partially refined at atomic resolution the structure of a complex of porcine pancreatic elastase with the time-dependent irreversible inhibitor 3-acetoxymethyl-7-alpha-chloro-3-cephem-4-carboxylate-1,1-dioxide tert-butyl ester (I), the most potent of the beta-lactam elastase inhibitors yet reported. (Porcine pancreatic elastase is a close relative of the desired drug target, human polymorphonuclear leukocyte elastase.) A mechanism of action is presented, based on the structure and on biochemical evidence (T.-Y.L. et al., in preparation), which clarifies the operational similarities and differences between beta-lactam elastase inhibitors and antibiotics. Features of the reaction include the expulsion of a leaving group at the cephalosporin 3' position and the formation of two covalent bonds with the active site of porcine pancreatic elastase at residues Ser 195 and His 57.
Cancer cells need cholesterol to make new membrane. They get it either by de novo synthesis or from low-density lipoprotein (LDL), or both. Some types of cancer have very high LDL requirements. LDL particles, which circulate in the blood, contain a cholesteryl ester core surrounded by a phospholipid coat containing apoproteins that are recognized by LDL receptors on cell surfaces. After attachment to cells, LDL is endocytosed into lysosomes, where the core is exposed and hydrolyzed. A technique is known whereby LDL can be isolated, its core removed and replaced by a compatible lipophilic substance, and then reconstituted into intact LDL particles that are recognized and internalized by cells in the normal manner. A series of cytotoxic compounds has been synthesized, designed to be compatible with reconstituted LDL, and directed against cancers that copiously internalize LDL. They were evaluated by measuring the toxicity of reconstituted LDL toward test cells bearing LDL receptors. Selectivity was determined by comparison, either with mutant cells with few LDL receptors or with reconstituted methylated LDL (which is not recognized by LDL receptors) on normal cells. Two compounds, 19 and 25, were found that reconstitute well, kill or arrest the test cells at reasonably low concentrations, and are completely selective, suggesting that they are delivered to cells exclusively via the LDL pathway.
The 3-substituted benzazepinone, L-692,429 (compound 1), is the prototype compound of a novel class of compounds that stimulate release of growth hormone (GH). The molecule evolved from efforts to identify a non-peptide mimic of the growth hormone-releasing hexapeptide, GHRP-6. Compound 1 is prepared by sequential attachment of dimethyl-beta-alanine and 2'-biphenylyltetrazole side chains to a chiral 3-aminobenzolactam nucleus. Comparison of the biological activity of 1 with the corresponding six- and eight-membered lactam analogs shows the seven-membered benzazepinone skeleton to be preferred. Molecular modeling of the structurally diverse GH secretagogues, L-692,429 and GHRP-6, was performed.
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