Identification of ammonium ion and 2,6-bis(omega-aminobutyl)- 3, 5-diiminopiperazine as endogenous factors that account for the "burst" of sphingosine upon changing the medium of J774 cells in culture.

Cells in culture often undergo a "burst" of free sphingosine, sphingosine 1-phosphate, ceramide, and other bioactive lipids upon removal of "conditioned" medium, and at least one lipid signaling pathway (protein kinase C) has been shown to be affected by these changes (Smith, E. R. & Merrill A. H., Jr. (1995) J. Biol. Chem. 270, 18749-18758; Smith, E. R., Jones, P. L., Boss, J. M. & Merrill, A. H., Jr. (1997) J. Biol. Chem. 272, 5640-5646). Whereas increases in sphinganine and dihydroceramide are responses to provision of precursors for sphingolipid biosynthesis de novo in the new medium, the sphingosine burst is due to sphingolipid turnover upon removal of suppressive factor(s) in conditioned medium. This study describes the purification and characterization of these suppressive factors. Conditioned medium from J774 cells was fractionated into two components that suppress the burst as follows: ammonium ion, which reaches 2-3 mM within 48 h of cell culture; and a low molecular weight, cationic compound that has been assigned the structure 2, 6-bis(omega-aminobutyl)-3,5-diimino-piperazine (for which we suggest the name "batrachamine" based on its appearance) by (1)H and (13)C NMR, Fourier transform infrared spectroscopy, and mass spectrometric analyses. The physiological significance of these compounds as suppressors of sphingolipid metabolism is unclear; however, ammonium ion is a by-product of amino acid catabolism and reaches high concentrations in some tissues. Batrachamine is even more intriguing because this is, as far as we are aware, the first report of a naturally occurring compound of this structural type. Considering the many cell functions that are affected by sphingoid bases and their derivatives, the effects of NH(4) and batrachamine on sphingolipid metabolism may have important implications for cell regulation.

Inhibition of skin carcinomas but not papillomas by sphingosine, N-methylsphingosine, and N-acetylsphingosine.

The sphingoid base backbones of sphingolipids are highly bioactive compounds that affect cell growth, differentiation, diverse cell behaviors, and programmed cell death. Therefore, the efficacy of sphingosine (SPH) and the analogs N-acetylsphingosine (NAS), N-methylsphingosine (NMS), octylamine (OCT), and sterylamine (STR) in the prevention of skin cancer was assessed in female Sencar mice by measuring effects on the induction of epidermal ornithine decarboxylase (ODC) activity and hyperplasia by 12-O-tetradecanoylphorbol-13-acetate (TPA) and effects on the induction of skin tumors by 7, 12-dimethylbenz[a]anthracene (DMBA) and TPA. ODC was measured in the shaved dorsal skin of mice treated topically with 0.05-20 mumol of these compounds 30 minutes before application of 8.5 nmol of TPA in 0.2 ml of acetone. ODC activity was inhibited by > or = 5 mumol of SPH and STR, > or = 10 mumol of NAS and NMS, and 20 mumol of OCT. In contrast, the induction of hyperplasia was not inhibited by application of these compounds 30 minutes before TPA. Two carcinogenesis studies were conducted with 10 nmol of DMBA as the initiator and 3.2 nmol of TPA (2x/wk for 15 wk) as the promoter. In the first study, NAS, NMS, OCT, and STR (0.05 and 0.5 mumol) were applied before each TPA application. Papilloma incidence and multiplicity were not inhibited, but NAS (0.05 mumol) and NMS (0.05 and 0.50 mumol) increased cancer-free survival. In the second experiment, SPH, NAS, and NMS (0.05 and 0.5 mumol) were applied 30 minutes before each TPA treatment and twice weekly for 10 weeks after the final TPA treatment. Papilloma incidence and multiplicity were not inhibited; however, the proportion of mice without carcinoma was increased by both doses of SPH and by 0.5 mumol of NAS. Thus low doses of sphingolipids that were not effective in inhibiting ODC activity, reducing hyperplasia, or preventing epidermal papilloma development were, nonetheless, effective in inhibiting carcinoma development.

Acylation of naturally occurring and synthetic 1-deoxysphinganines by ceramide synthase. Formation of N-palmitoyl-aminopentol produces a toxic metabolite of hydrolyzed fumonisin, AP1, and a new category of ceramide synthase inhibitor.

Fumonisin B1 (FB1) is the predominant member of a family of mycotoxins produced by Fusarium moniliforme (Sheldon) and related fungi. Certain foods also contain the aminopentol backbone (AP1) that is formed upon base hydrolysis of the ester-linked tricarballylic acids of FB1. Both FB1 and, to a lesser extent, AP1 inhibit ceramide synthase due to structural similarities between fumonisins (as 1-deoxy-analogs of sphinganine) and sphingoid bases. To explore these structure-function relationships further, erythro- and threo-2-amino, 3-hydroxy- (and 3, 5-dihydroxy-) octadecanes were prepared by highly stereoselective syntheses. All of these analogs inhibit the acylation of sphingoid bases by ceramide synthase, and are themselves acylated with Vmax/Km of 40-125 for the erythro-isomers (compared with approximately 250 for D-erythro-sphinganine) and 4-6 for the threo-isomers. Ceramide synthase also acylates AP1 (but not FB1, under the conditions tested) to N-palmitoyl-AP1 (PAP1) with a Vmax/Km of approximately 1. The toxicity of PAP1 was evaluated using HT29 cells, a human colonic cell line. PAP1 was at least 10 times more toxic than FB1 or AP1 and caused sphinganine accumulation as an inhibitor of ceramide synthase. These studies demonstrate that: the 1-hydroxyl group is not required for sphingoid bases to be acylated; both erythro- and threo-isomers are acylated with the highest apparent Vmax/Km for the erythro-analogs; and AP1 is acylated to PAP1, a new category of ceramide synthase inhibitor as well as a toxic metabolite that may play a role in the diseases caused by fumonisins.

Synthesis and protein kinase C inhibitory activities of balanol analogs with replacement of the perhydroazepine moiety.

Balanol is a potent protein kinase C (PKC) inhibitor that is structurally composed of a benzophenone diacid, a 4-hydroxybenzamide, and a perhydroazepine ring. A number of balanol analogs in which the perhydroazepine moiety is replaced have been synthesized and their biological activities evaluated against both PKC and cAMP-dependent kinase (PKA). The results suggested that the activity and the isozyme/kinase selectivity of these compounds are largely related to the conformation about this nonaromatic structural element of the molecules.

Fumonisin toxicity and sphingolipid biosynthesis.

Fumonisins are inhibitors of sphinganine (sphingosine) N-acyltransferase (ceramide synthase) in vitro, and exhibit competitive-type inhibition with respect to both substrates of this enzyme (sphinganine and fatty acyl-CoA). Removal of the tricarballylic acids from fumonisin B1 reduces the potency by at least 10 fold; and fumonisin A1 (which is acetylated on the amino group) is essentially inactive. Studies with diverse types of cells (hepatocytes, neurons, kidney cells, fibroblasts, macrophages, and plant cells) have established that fumonisin B1 not only blocks the biosynthesis of complex sphingolipids; but also, causes sphinganine to accumulate. Some of the sphinganine is metabolized to the 1-phosphate and degraded to hexadecanal and ethanolamine phosphate, which is incorporated into phosphatidylethanolamine. Sphinganine is also released from cells and, because it appears in blood and urine, can be used as a biomarker for exposure. The accumulation of these bioactive compounds, as well as the depletion of complex sphingolipids, may account for the toxicity, and perhaps the carcinogenicity, of fumonisins.