FTY720 postconditions isolated perfused heart by a mechanism independent of sphingosine kinase 2 and different from S1P or ischemic postconditioning.

BACKGROUND: We investigated the hypothesis that postconditioning by FTY720 (FTY) in isolated perfused mouse hearts is independent of the sphingosine 1-phosphate (S1P) pathway. MATERIAL AND METHODS: Ex vivo hearts were exposed to postconditioning (POST) by either ischemia or FTY720. Protection against ischemia/reperfusion (IR) injury was measured by recovery of left ventricular developed pressure (LVDP) and infarct size. RESULTS: FTY effectively postconditioned (POST) ex vivo hearts against ischemia/reperfusion (IR) injury as measured by recovery of LVDP and a low infarct size. FTY protection, unlike S1P but like sphingosine (Sph), was insensitive to inhibition of S1P G-Protein Coupled Receptors (GPCRs) or inhibition of PI3 kinase. Protection by FTY and Sph was however blocked by inhibitors of PKA and PKG. Thus, FTY follows the same cardioprotective pathway as Sph. This was further supported by studies of FTY POST in knockout (KO) mice lacking the SphK2 form of Sph kinase that is needed for phosphorylation of FTY to an S1P analog. In the absence of SphK2, FTY (and Sph) POST was still cardioprotective. This differed from the effect of SphK2 KO on protection by ischemic POST (IPOST). IPOST was not effective in KO hearts. To see if the GPCR signaling pathway to protection is normal in KO hearts, we looked at POST by GPCR agonists S1P and adenosine. Both provided effective protection even in KO hearts suggesting that the problem with IPOST in KO hearts is a low level of S1P available for release during IPOST. Thus, pharmacologic POST with FTY or Sph, like adenosine and S1P, is unaffected in the KO. CONCLUSIONS: FTY720 administered in vivo might behave in a dual manner showing both S1P-like effects and sphingosine-like effects. It appears that the latter may have been overlooked and may be the more important in aging hearts.

A sphingosine kinase form 2 knockout sensitizes mouse myocardium to ischemia/reoxygenation injury and diminishes responsiveness to ischemic preconditioning.

Sphingosine kinase (SphK) exhibits two isoforms, SphK1 and SphK2. Both forms catalyze the synthesis of sphingosine 1-phosphate (S1P), a sphingolipid involved in ischemic preconditioning (IPC). Since the ratio of SphK1:SphK2 changes dramatically with aging, it is important to assess the role of SphK2 in IR injury and IPC. Langendorff mouse hearts were subjected to IR (30 min equilibration, 50 min global ischemia, and 40 min reperfusion). IPC consisted of 2 min of ischemia and 2 min of reperfusion for two cycles. At baseline, there were no differences in left ventricular developed pressure (LVDP), ± dP/dtmax, and heart rate between SphK2 null (KO) and wild-type (WT) hearts. In KO hearts, SphK2 activity was undetectable, and SphK1 activity was unchanged compared to WT. Total SphK activity was reduced by 53%. SphK2 KO hearts subjected to IR exhibited significantly more cardiac damage (37 ± 1% infarct size) compared with WT (28 ± 1% infarct size); postischemic recovery of LVDP was lower in KO hearts. IPC exerted cardioprotection in WT hearts. The protective effect of IPC against IR was diminished in KO hearts which had much higher infarction sizes (35 ± 2%) compared to the IPC/IR group in control hearts (12 ± 1%). Western analysis revealed that KO hearts had substantial levels of phosphorylated p38 which could predispose the heart to IR injury. Thus, deletion of the SphK2 gene sensitizes the myocardium to IR injury and diminishes the protective effect of IPC.

P2X7 receptor agonists pre- and postcondition the heart against ischemia-reperfusion injury by opening pannexin-1/P2X7 channels.

Protection of the heart from ischemia-reperfusion injury can be achieved by ischemic preconditioning and ischemic postconditioning. Previous studies revealed that a complex of pannexin-1 with the P2X(7) receptor forms a channel during ischemic preconditioning and ischemic postconditioning that results in the release of endogenous cardioprotectants. ATP binds to P2X(7) receptors, inducing the formation of a channel in association with pannexin-1. We hypothesized that this channel would provide a pathway for the release of these same cardioprotectants. Preconditioning-isolated perfused rat hearts with 0.4 µM ATP preceding 40 min of ischemia minimized infarct size upon subsequent reperfusion (5% of risk area) and resulted in >80% recovery of left ventricular developed pressure. Postconditioning with ATP after ischemia during reperfusion was also protective (6% infarct and 72% recovery of left ventricular developed pressure). Antagonists of both pannexin-1 (carbenoxolone and mefloquine) and P2X(7) receptors (brilliant blue G and A438079) blocked ATP pre- and postconditioning, indicating that ATP protection was elicited via the opening of a pannexin-1/P2X(7) channel. An antagonist of binding of the endogenous cardioprotectant sphingosine 1-phosphate to its G protein-coupled receptor diminished protection by ATP, which is also consistent with an ATP-dependent release of cardioprotectants. Suramin, an antagonist of binding of ATP (and ADP) to P2Y receptors, was without effect on ATP protection. Benzoyl benzoyl-ATP, a more specific P2X(7) agonist, was also a potent pre- and postconditioning agent and sensitive to blockade by pannexin-1/P2X(7) channel antagonists. The data point out for the first time the potential of P2X(7) agonists as cardioprotectants.

Ischemic preconditioning requires opening of pannexin-1/P2X(7) channels not only during preconditioning but again after index ischemia at full reperfusion.

Protection of the ex vivo rat heart from ischemia/reperfusion injury can be provided by ischemic preconditioning (IPC). Previous studies revealed that a complex of pannexin-1 with the P2X7 receptor forms a channel during IPC that results in the release of cardioprotectants such as adenosine and sphingosine 1-phosphate (S1P) that bind to G-protein-coupled cell surface receptors triggering cardioprotective cell signaling pathways. Antagonists of both pannexin-1 (carbenoxolone and mefloquine) and P2X7 receptors (brilliant blue G) are known to block IPC when administered at the time of preconditioning (Vessey et al. J Cardiovasc Pharmacol Ther 15:190, 2010). We now demonstrate that these same antagonists also block the cardioprotective effects of IPC when added after the index ischemia during full reperfusion. Likewise, addition at full reperfusion of binding antagonists to the endogenous cardioprotectants S1P (VPC) or adenosine (8-SPT) reduced the effectiveness of IPC. These data suggest that IPC has a component that requires the release of cardioprotectants via pannexin-1/P2X7 channels not only during preconditioning phase but again during the early stages of reperfusion following the index ischemia. It was found that the level of cardioprotectant release required at reperfusion to achieve cardioprotection was lower when hearts had been preconditioned. Further, pharmacologic preconditioning with S1P or adenosine was also blocked at reperfusion by antagonists of the pannexin-1/P2X7 channels indicating that pharmacologic preconditioning also requires opening of the channel at full reperfusion. In untreated hearts, key components of the PI3 kinase/Akt signaling pathway were revealed by western analysis to be lost during ischemia. This correlates with an inability to generate phospho-Akt at reperfusion. IPC prevents this loss and thereby primes the cell for response to cardioprotectants released at full reperfusion.

Pannexin-I/P2X 7 purinergic receptor channels mediate the release of cardioprotectants induced by ischemic pre- and postconditioning.

Ischemic pre- and postconditioning protect ex vivo rat hearts from ischemia/reperfusion injury by promoting the release of cardioprotective agents by an unknown mechanism. Because P2X( 7) purinergic receptors are known to combine with pannexin-1 to form channels that allow adenosine triphosphate (ATP) release from cells, we hypothesized that these channels have a role in the release of multiple cardioprotectants during ischemic preconditioning (IPC). Addition of either a pannexin-1 hemichannel blocker (5 micromol/L carbenoxolone [CBX] or 0.4 micromol/L mefloquine [MF]) or a selective antagonist of the rat P2X(7) purinergic receptor (2 micromol/L brilliant blue G [BBG]) blocked IPC. These antagonists also blocked ischemic postconditioning. Preconditioning by exogenous addition of either sphingosine-1-phosphate or adenosine was not blocked by either CBX or BBG, indicating that they only affected the release of endogenous mediators, not any subsequent steps. To determine if only ATP release was mediated by pannexin-1/P2X(7) channels, we added an extra cycle of IPC to release sufficient quantities of additional cardioprotectants to eliminate the dependence on adenosine derivatives. This did not override the inhibition of IPC by CBX or MF, suggesting that the channel mediates the release of multiple cardioprotectants. Inhibitors of other P2X receptors, P2Y receptors, or connexins did not affect IPC. We conclude that a pannexin-1/P2X(7) channel is responsible for the release of cardioprotectants induced by ischemic pre- and postconditioning.

Sphingosine 1-phosphate is an important endogenous cardioprotectant released by ischemic pre- and postconditioning.

Exogenous sphingosine 1-phosphate (S1P) is an effective cardioprotectant against ischemic injury. We have investigated the hypothesis that S1P is also an important endogenous cardioprotectant released during both ischemic preconditioning (IPC) and ischemic postconditioning (IPOST). IPC of ex vivo rat hearts was instituted by two cycles of 3 min ischemia-5 min reperfusion prior to 40 min of index ischemia and then 40 min of reperfusion. IPC resulted in 70% recovery of left ventricular developed pressure (LVDP) upon reperfusion and a small infarct size (10%). VPC23019 (VPC), a specific antagonist of S1P(1 and 3) G protein-coupled receptors (GPCRs), when present during preconditioning blocked protection afforded by two cycles of IPC. VPC also blocked preconditioning of isolated rat cardiac myocytes subjected to hypoxia-reoxygenation injury. Increased release of S1P from myocytes in response to IPC was also demonstrated. These data indicate that S1P is released from myocytes in response to IPC and protects by binding to S1P GPCRs. In the ex vivo heart, if a third cycle of IPC was added to increase release of endogenous mediators, then the need for any individual mediator (e.g., S1P) was diminished and VPC had little effect. The adenosine antagonist 8-(p-sulfophenyl)-theophylline (8-SPT) likewise inhibited protection by two cycles but not three cycles of IPC, but VPC plus 8-SPT inhibited protection by three cycles of IPC. Similar to IPC, IPOST induced by four postindex ischemia cycles of 15 s reperfusion-15 s ischemia resulted in 66% recovery of LVDP and a 7% infarct size. When VPC was present during postconditioning and reperfusion, LVDP only recovered by 26% and the infarct size increased to 27%. Adding an additional cycle of IPOST reduced the inhibitory effect of VPC and 8-SPT individually, but not their combined effect. These studies reveal that S1P is an important mediator of both IPC and IPOST that is released along with adenosine during each cycle of IPC or IPOST.

Sphingolipid signaling and treatment during remodeling of the uninfarcted ventricular wall after myocardial infarction.

The sphingosine kinase (SphK)/sphingosine 1-phosphate (S1P) pathway, known to determine the fate and growth of various cell types, can enhance cardiac myocyte survival in vitro and provide cardioprotection in acute ex vivo heart preparations. However, the relevance of these findings to chronic cardiac pathology has never been demonstrated. We hypothesized that S1P signaling is impaired during chronic remodeling of the uninfarcted ventricle during the evolution of post-myocardial infarction (MI) cardiomyopathy and that a therapeutic enhancement of S1P signaling would ameliorate ventricular dysfunction. SphK expression and activity were measured in the remote, uninfarcted myocardium (RM) of C57Bl/6 mice subjected to coronary artery ligation. The mRNA expression of S1P receptor isoforms was also measured, as was the activation of the downstream S1P receptor mediators. A cardioprotective role for S1P(1) receptor agonism was tested via the administration of the S1P(1)-selective agonist SEW2871 during and after MI. As a result, the expression data suggested that a dramatic reduction in SphK activity in the RM early after MI may reflect a combination of posttranscriptional and posttranslational modulation. SphK activity continued to decline gradually during chronic post-MI remodeling, when S1P(1) receptor mRNA also fell below baseline. The S1P(1)-specific agonism with oral SEW2871 during the first 2-wk after MI reduced apoptosis in the RM and resulted in improved myocardial function, as reflected in the echocardiographic measurement of fractional shortening. In conclusion, these results provide the first documentation of alterations in S1P-mediated signaling during the in situ development of cardiomyopathy and suggest a possible therapeutic role for the pharmacological S1P receptor agonism in the post-MI heart.

Sphingosine protects aging hearts from ischemia/reperfusion injury: Superiority to sphingosine 1-phosphate and ischemic pre- and post-conditioning.

Aging hearts are known to have diminished capacity to be protected against reoxygenation ischemia/reperfusion (IR) injury provided by various cardioprotective regimens. In search of a more successful regimen, we have studied the response of aged hearts to preconditioning (PC) and postconditioning (POST) elicited by sphingosine or sphingosine 1-phosphate treatment.An ex vivo rat heart model was used to study the ability of PC and POST to protect old hearts (27 month) against I/R injury generated by 40 minutes (min) of index ischemia followed by 40 min of reperfusion. The response to ischemic PC was reduced in 27 month old hearts relative to 3-6 month (young) hearts as noted by a poor recovery of left ventricular developed pressure (LVDP) upon reperfusion (45% vs. 74% in young hearts) and a large infarct size after 40 min of reperfusion (37% versus 8% in young hearts). PC with sphingosine 1-phosphate (S1P) was also poor in old hearts yielding only 49% recovery of LVDP and a 27% infarct size. In contrast, PC with sphingosine was unaffected by aging; the 78% recovery of LVDP and 8% infarct size were not different from young hearts. Ischemic POST was less affected by aging than ischemic PC, but the old hearts still experienced infarct sizes of 28%. POST of old hearts with S1P was also associated with a substantial infarct size (24%). However, POST of old hearts with sphingosine was superior to the other forms of POST in that it reduced the infarct size to 12%. S1P levels were found to be lower in old hearts which may contribute to the decreased effectiveness of ischemic PC and POST. Further, phospho-Akt levels and distribution were altered in response to cardioprotection in the old hearts. In conclusion, POST was less affected by aging than PC; and sphingosine is a uniquely effective agent for both PC and POST of aging hearts.

Combined sphingosine, S1P and ischemic postconditioning rescue the heart after protracted ischemia.

Both sphingosine and sphingosine-1-phosphate (S1P) were able to protect the ex vivo rat heart from ischemia reperfusion injury when added to the perfusion medium at the time of reperfusion after a 40min ischemia (postconditioning). Inhibitor studies revealed distinct mechanisms of protection, with S1P employing a G-protein coupled receptor pathway and sphingosine a cyclic nucleotide dependent protein kinase pathway. However, both restored ischemia-induced depletion of phospho-AKT. Extending the ischemia to 75min reduced protection by both S1P and sphingosine, but protection could be enhanced by employing them in combination. Extending the time of ischemia further to 90min almost eliminated cardioprotection by S1P or sphingosine; and their combination gave only modest protection. However, when S1P plus sphingosine was combined with a novel ramped ischemic postconditioning regimen, left ventricle developed pressure recovered by 66% and there was only a 6% infarct size. The data indicate that detrimental changes are accumulating during protracted ischemia but for up to 90min this damage is not irreversible and hearts can still recover with proper treatment.

Sphingosine can pre- and post-condition heart and utilizes a different mechanism from sphingosine 1-phosphate.

Consistent with previous reports, sphingosine at a high concentration (5 microM) was cardiotoxic as evidenced by increased infarct size in response to ischemia/reperfusion in an ex vivo rat heart. Sphingosine 1-phosphate (S1P) at 5 microM was cardioprotective. However, at a physiologic concentration (0.4 microM) sphingosine as well as S1P was effective in protecting the heart from ischemia/reperfusion injury both when perfused prior to 40 min of ischemia (preconditioning) or when added to reperfusion media following ischemia (postconditioning). Protection by sphingosine and S1P was evidenced with both pre- and post-conditioning by a >75% recovery of left ventricular developed pressure during reperfusion and a decrease in infarct size from 45% of the risk area to less than 8%. When VPC23019, an S1P(1and3)G-protein coupled receptor antagonist, was added to the preconditioning or postconditioning medium along with S1P, it completely blocked S1P-induced protection. However, VPC 23019 did not affect the ability of 0.4 microM sphingosine to either precondition or postcondition hearts. Studies of preconditioning revealed that inhibition of protein kinase C with GF109203X blocked preconditioning by S1P. However, GF109203X did not affect preconditioning by 0.4 microM sphingosine. Likewise, cotreatment with the PI3 kinase inhibitor wortmanin blocked preconditioning by S1P but not by sphingosine. By contrast, inhibition of protein kinase G with KT5823 had no effect on S1P preconditioning but completely eliminated preconditioning by sphingosine. Also, the protein kinase A inhibitory peptide 14-22 amide blocked preconditioning by sphingosine but not S1P. These data reveal for the first time that sphingosine is not toxic at physiologic concentrations but rather is a potent cardioprotectant that utilizes a completely different mechanism than S1P; one that is independent of G-protein coupled receptors and utilizes cyclic nucleotide-dependent pathways.

Ischaemic postconditioning protects isolated mouse hearts against ischaemia/reperfusion injury via sphingosine kinase isoform-1 activation.

AIMS: Sphingosine-1-phosphate (S1P) plays a vital role in cytoskeletal rearrangement, development, and apoptosis. Sphingosine kinase-1 (SphK1), the key enzyme catalyzing the formation of S1P, mediates ischaemic preconditioning. Ischaemic postconditioning (POST) has been shown to protect hearts against ischaemia/reperfusion injury (IR). To date, no studies have examined the role of SphK1 in POST. METHODS AND RESULTS: Wild-type (WT) and SphK1 null (KO) mouse hearts were subjected to IR (45 min of global ischaemia and 45 min of reperfusion) in a Langendorff apparatus. Left ventricular developed pressure (LVDP), maximum velocity of increase or decrease of LV pressure (+/-dP/dtmax), and LV end-diastolic pressure (LVEDP) were recorded. Infarction size was measured by 1% triphenyltetrazolium chloride staining. POST, consisting of 5 s of ischaemia and 5 s of reperfusion for three cycles after the index ischaemia, protected hearts against IR: recovery of LVDP and +/-dP/dtmax were elevated; LVEDP was decreased; infarction size (% of risk area) was reduced from 40 +/- 2% in the control group to 29 +/- 2% of the risk area in the POST group (P < 0.05, n = 4 per group). Phosphorylation of Akt and extracellular signal-regulated kinases detected by Western blotting was increased at 10 min of reperfusion. The protection induced by POST was abolished in KO hearts. Infarction size in KO hearts (57 +/- 5%) was not different from the KO control group (53 +/- 5% of risk area, n = 4, P = NS). CONCLUSIONS: A short period of ischaemic POST protected WT mouse hearts against IR. The cardiac protection induced by POST was abrogated in SphK1-KO mouse hearts. Thus, SphK1 is critical for successful ischaemic POST.

Dimethylsphingosine and FTY720 inhibit the SK1 form but activate the SK2 form of sphingosine kinase from rat heart.

Fractionation of cytosolic sphingosine kinase (SKase) activity by gel filtration chromatography gave rise to a 96-kDa peak that contained only the SK2 form of SKase (by Western analysis) and a broad ca. 46 kDa peak that contained only SK1 forms. SK2 appeared to have a bound accessory protein. When tested with the classic SKase inhibitor dimethylsphingosine (DMS), SK1 was extensively inhibited; however, SK2 was not inhibited but unexpectedly was activated. Activation of SK2 was the result of DMS enhancing the affinity of the enzyme for sphingosine, and, at low concentrations of ATP and sphingosine, activated by more than 100%. Activation of SK2 could be demonstrated in the cytosolic fraction indicating it was unrelated to the purification step. The immunomodulator FTY720 also activated SK2 (although to a lesser extent), but was a potent inhibitor of SK1. SK2 from rat liver and spleen was also not inhibited by DMS. L-Sphingosine and to a lesser extent dihydrosphingosine and phytosphingosine were effective inhibitors of both forms.

A sphingosine kinase 1 mutation sensitizes the myocardium to ischemia/reperfusion injury.

OBJECTIVE: Sphingosine kinase (SphK) is a key enzyme in the synthesis of sphingosine 1-phosphate (S1P), a bioactive sphingolipid. SphK is involved in ischemic preconditioning (IPC). To date no studies in genetically altered animals have examined the role of SphK1 in myocardial ischemia/reperfusion (IR) injury and IPC. METHODS AND RESULTS: Wild-type and SphK1 null mouse hearts were subjected to IR (50 min global ischemia and 40 min reperfusion) in a Langendorff apparatus. IPC consisted of 2 min of global ischemia and 2 min of reperfusion for two cycles. At baseline, there were no differences in left ventricular developed pressure (LVDP), +/-dP/dtmax, and LV end-diastolic pressure (EDP) between SphK1 mutant and wild-type (WT) mouse hearts. In the mutants, total SphK enzyme activity was reduced by 44% and S1P levels were decreased by 41%. SphK1 null hearts subjected to IR exhibited more cardiac damage compared with WT: LVDP and +/-dP/dtmax decreased, LVEDP increased, and infarct size increased (n=6, P<0.05). Apoptosis was markedly enhanced in SphK1 mutant IR mouse hearts. IPC was cardioprotective in WT hearts, but this protection appeared to be ineffective in SphK1 null hearts. There was no change in infarct size in the IPC+IR group compared to the IR group in the null hearts (50.1+/-5.0% vs 45.0+/-3.8%, n=6, P=NS). IPC remained ineffective in the null hearts even when the index ischemia time was shortened by 10 min. CONCLUSIONS: Deletion of the SphK1 gene sensitizes the myocardium to IR injury and appears to impair the protective effect of IPC. These data provide the first genetic evidence that the SphK1-S1P pathway is a critical mediator of IPC and cell survival.

Adult cardiac fibroblasts null for sphingosine kinase-1 exhibit growth dysregulation and an enhanced proinflammatory response.

Cardiac fibroblasts are critical for the maintenance of extracellular matrix deposition and turnover in the normal heart and are key mediators of inflammatory and fibrotic myocardial remodeling in the injured and failing heart. Sphingosine kinase (SphK) activation is a well-recognized determinant of cell fate in cardiac myocytes and other cells, but SphK responses have not previously been studied in cardiac fibroblasts. Initially we found that total SphK activity is over 10-fold higher in cardiac fibroblasts than in adult mouse cardiac myocytes. SphK is composed of two major isoforms, SphK-1 and SphK-2. In fibroblasts isolated from SphK-1 knockout mice, SphK activity was greatly reduced indicating that SphK-1 is the major isoform expressed in these cells. To determine whether SphK regulates cell proliferation and the proinflammatory protein inducible nitric oxide synthase (iNOS), we exposed cultured cardiac fibroblasts to the cytokine interleukin-1beta (IL-1beta) and/or hypoxia. Both hypoxia and IL-1beta alone and in combination enhanced fibroblast SphK activity. In wild-type fibroblasts, hypoxia induced proliferation, but in SphK-1 null fibroblasts this response was blunted even in the presence of serum. In contrast, we found that iNOS expression and NO production were enhanced in SphK-1 null fibroblasts during hypoxia. In wild-type fibroblasts, IL-1beta was only a weak inducer of iNOS and of NO accumulation and hypoxia alone had no significant effect on iNOS activation. However, IL-1beta in combination with hypoxia extensively stimulated iNOS and NO production, and this stimulation was enhanced in SphK-1 null fibroblasts. We conclude that activation of endogenous SphK-1 serves a dual regulatory function: it is required for optimal cardiac fibroblast proliferation but is a negative modulator of proinflammatory responses during hypoxia.

Deletion of the sphingosine kinase-1 gene influences cell fate during hypoxia and glucose deprivation in adult mouse cardiomyocytes.

OBJECTIVES: Activation of sphingosine kinase (SphK), which has two known isoforms, is responsible for the synthesis of sphingosine 1-phosphate (S1P), a cell survival factor. We tested the following hypotheses: 1] cardiac myocytes null for the SphK1 gene are more vulnerable to the stress of hypoxia+glucose deprivation; 2] the monoganglioside GM-1, which activates SphK via protein kinase C epsilon, is ineffective in SphK1-null myocytes; 3] S1P generated by SphK activation requires cellular export to be cardioprotective. METHODS: We cultured adult mouse cardiac myocytes from wildtype and SphK1-null mice (deletion of exons 3-6) and measured cell viability by trypan blue exclusion. RESULTS: In wildtype adult mouse cardiomyocytes subjected to 4 h of hypoxic stress+glucose deprivation, cell viability was significantly higher than in SphK1-null cardiomyocytes. SphK1-null cells also displayed more mitochondrial cytochrome C release. Cell death induced by hypoxia+glucose deprivation was substantially prevented by pretreatment with exogenous S1P in both wildtype and SphK1-null myocytes, but S1P was effective at a lower concentration in wildtype cells. Hence, the absence of the Sphk1 gene did not affect receptor coupling or downstream signal transduction. Pretreatment for 1 h with 1 microM of the monoganglioside GM-1 increased survival in wildtype cells, but not in SphK1-null myocytes. Thus, activation of SphK1 by GM-1 leads to cell survival. In wildtype cells, enhanced survival produced by GM-1 was abrogated by pretreatment either with 300 nM of the S1P(1) receptor-selective antagonist VPC23019 or with 100 ng/ml of pertussis toxin for 16 h before exposure to hypoxia+glucose deprivation. CONCLUSION: As the effect of GM-1 is blocked both at the receptor and the G-protein (Gi) levels, we conclude that S1P generated by GM-1 treatment must be exported from the cell and acts in a paracrine or autocrine manner to couple with its cognate receptor.

Role of sphingosine kinase activity in protection of heart against ischemia reperfusion injury.

BACKGROUND: Sphingosine kinase (SKase) has been implicated in the protection of hearts from ischemia/reperfusion injury. This hypothesis was further examined. MATERIAL/METHODS: Changes in SKase activity and cardiac function (left ventricular developed pressure, LVDP, and infarct size) in response to ischemia and reperfusion were studied in adult rat hearts by the ex vivo Langendorff method. Following initial equilibration or preconditioning, there was 45 min no-flow ischemia and then 45 min of reperfusion. RESULTS: SKase activity declined 61% during ischemia and did not recover upon reperfusion. LVDP also did not recover upon reperfusion and the infarct size was 47%. A short 30 min period of ischemia was associated with variable recovery of SKase activity that directly correlated with LVDP recovery. Preconditioning of hearts reduced the decrease in SKase activity during ischemia by half, and upon reperfusion activity returned to normal. The LVDP recovered 79% and infarct size was small. Preconditioned hearts had higher S-1-P levels after ischemia/reperfusion relative to non-preconditioned hearts. The decline in SKase activity during ischemia of preconditioned hearts could not be mimicked in vitro by treatment with protein phosphatases. Attempts to alter activity of SKase from control, preconditioned, ischemic, or reperfused hearts by phosphorylation with ERK1/2 were unsuccessful. Treatment of non-preconditioned hearts at reperfusion with 100 nM S-1-P improved recovery of LVDP. The SKase inhibitor dimethylsphingosine blocked hemodynamic recovery in preconditioned hearts. CONCLUSIONS: The data support a role for SKase activity in recovery of hemodynamic function after ischemic injury and also in the cardioprotective effect of preconditioning.

A rapid radioassay for sphingosine kinase.

A solvent-extraction-based radioassay for measuring sphingosine kinase (SKase) activity has been developed. The assay utilizes [3H]sphingosine substrate and differentially extracts the [3H]sphingosine-1-phosphate product. The extracted radioactivity is demonstrated to be primarily [3H]sphingosine-1-phosphate with less than 1% contamination by [3H]sphingosine. When assaying SKase activity in the soluble cell fraction, the extraction efficiency of the labeled sphingosine-1-phosphate product is a reproducible 78%, which allows for a simple back calculation to correct for the 22% extraction loss. With minor modification, the assay is also a reproducible procedure for determining SKase activity in subcellular membrane fractions. The assay is far more rapid than thin-layer chromatography and high-performance liquid chromatography methods, which makes it possible to do a large number of assays in a short period of time. The utility of the assay is demonstrated by using it to conduct a complete bisubstrate kinetic analysis of rat heart SKase.

Characterization of triacsin C inhibition of short-, medium-, and long-chain fatty acid: CoA ligases of human liver.

Short-, medium-, and long-chain fatty acid:CoA ligases from human liver were tested for their sensitivity to inhibition by triacsin C. The short-chain fatty acid:CoA ligase was inhibited less than 10% by concentrations of triacsin C as high as 80 microM. The two mitochondrial xenobiotic/medium-chain fatty acid:CoA ligases (XM-ligases), HXM-A and HXM-B, were partially inhibited by triacsin C, and the inhibitions were characterized by low affinity for triacsin C (K(I) values > 100 microM). These inhibitions were found to be the result of triacsin C competing with medium-chain fatty acid for binding at the active site. The microsomal and mitochondrial forms of long-chain fatty acid:CoA ligase (also termed long-chain fatty acyl-CoA synthetase, or long-chain acyl-CoA synthetase LACS) were potently inhibited by triacsin C, and the inhibition had identical characteristics for both LACS forms. Dixon plots of this inhibition were biphasic. There is a high-affinity site with a K(I) of 0.1 microM that accounts for a maximum of 70% of the inhibition. There is also a low affinity site with a K(I) of 6 microM that accounts for a maximum of 30% inhibition. Kinetic analysis revealed that the high-affinity inhibition of the mitochondrial and microsomal LACS forms is the result of triacsin C binding at the palmitate substrate site. The high-affinity triacsin C inhibition of both the mitochondrial and microsomal LACS forms was found to require a high concentration of free Mg(2+), with the EC(50) for inhibition being 3 mM free Mg(2+). The low affinity triacsin C inhibition was also enhanced by Mg(2+). The data suggests that Mg(2+) promotes triacsin C inhibition of LACS by enhancing binding at the palmitate binding site. In contrast, the partial inhibition of the XM-ligases by triacsin C, which showed only a low-affinity component, did not require Mg(2+).

Isolation, sequencing, and expression of a cDNA for the HXM-A form of xenobiotic/medium-chain fatty acid:CoA ligase from human liver mitochondria.

The purification of xenobiotic/medium-chain fatty acid:CoA ligases (XM-ligases) from human liver mitochondria resulted in the isolation of two chromatographically separable forms (HXM-A and HXM-B). These two forms were purified to near homogeneity, cleaved with cyanogen bromide, the resulting peptides separated, and the N-terminus of two of the peptides partially sequenced. Identical sequences were obtained for HXM-A and HXM-B for the two peptides. These sequences were used to design probes for screening a human liver cDNA library. This resulted in the isolation of two overlapping cDNAs. Using these sequences we were able to design PCR primers that resulted in the isolation of a full-length cDNA from a human cDNA library. The cDNA contained 1731 bp of open reading frame and coded for a 64230-Da protein. This protein bears 56.2% amino acid homology to the MACS1 (medium-chain acyl-CoA synthetase) enzyme, 58.7% homology to the bovine XL-III XM-ligase, and 81.5% homology to the bovine XL-I XM-ligase. The cDNA could be expressed in COS cells, and the expressed enzyme had greater benzoate activity than phenylacetate activity, which is consistent with the known substrate specificity of HXM-A.

Techniques for measuring the activity of carboxylic acid:CoA ligase and acyl-CoA:amino acid N-acyltransferase: the amino acid conjugation pathway.

A wide variety of xenobiotic carboxylic acids are metabolized to their amino acid conjugates via a pathway that exists primarily in liver and kidney. This conjugation occurs in a two-step pathway catalyzed by two distinct types of enzymes, ligases and transferases. Measurements of acyl-CoA ligase activity include monitoring the rate of appearance of AMP or PPi, or the CoA adduct. N-acyltransferases catalyze formation of an amino acid conjugate from the CoA-activated intermediate, releasing CoA. This reaction is monitored by following the release of free CoA or the disappearance of the acyl-CoA adduct.