人胎肝基质细胞培养上清液中造血生长因子的分析

采用人胎肝造血基质细胞的体外液体培养技术,结合造血干细胞和祖细胞的体外测试方法,研究了造血基质细胞所释放的造血生长因子与造血干细胞和祖细胞之间的相互作用。结果表明,在适宜的条件下,人胎肝造血基质细胞可在体外传代培养达100d之久。培养过程中,对不同时间收集的培养上清液进行测试的结果表明,这些贴壁细胞可以不断地释放多种造血活性物质。在100d培养过程中,上清液中始终都可以检出CFU-S增殖刺激物活性。培养第24天的上清液中还可检出BPF和GM-CSF活性。这些造血活性物质对CFU-S的生理状态和祖细胞的增殖与分化有着深刻的影响。但是在培养上清液中未检出IL-3样活性物质。     

Glutathione and glutathione conjugate efflux from cultured liver cells

Efflux of glutathione (GSH) and GSH-conjugates from cultured rat liver epithelial cell lines; the non-tumorigenic ARL-15C₁ and the -glutamyl transpeptidase containing, tumorigenic ARL-16T₂, has been assessed under basal condition and during chronic treatment with 75 and 150 M ethacrynic acid (EA). The intracellular level of GSH increased in proportion to EA concentration during chronic exposure. The rates of GSH and GSH-EA conjugate efflux increased with intracellular GSH in both ARL cell lines.Glutathione-S-transferase activity measured with EA as substrate increased over the experimental time course after treatment with 150, but not 75 M EA. When intracellular GSH content was increased by treatment with the cysteine pro-drug, 2-L-oxothiazolidine 4-carboxylic acid, the rate of GSH efflux was increased, but not the rate of GS-EA conjugate export. Inhibition of -glutamyl transpeptidase by acivicin (AT-125) increased the GSH and GS-EA conjugate efflux rate in ARL-16T₂ cells by factors of approximately 2 and 15, respectively. Acivicin treatment of ARL-16T₂ cells chronically treated with EA elevated GSH efflux rate by 10-fold and GS-EA efflux by 40-fold versus control samples. These studies show that GSH and GSH conjugate efflux are accomplished as independently regulated processes. Efflux of GSH is enhanced by increased in racellular GSH, but increase in the conjugate transport rate requires the presence of the GSH conjugate. The response of the efflux process to treatment with a chronic GSH depleting agent was identical in two cell lines in which the metabolic fate of glutathione is known to differ fundamentally.Abbreviations GSH reduced glutathione - GSSG oxidized glutathione - GS-EA the glutathione conjugate of ethacrynic acid - EA ethacrynic acid - CDNB 1-chloro 2,4-dinitrobenzene - HBS HEPES buffered saline - OTC 2-L-oxothiazolidine 4-carboxylic acid - CYSSG cysteinyl-glutathione mixed disulfide - FDNB 1-fluoro-2,4-dinitrobenzene - GCS -glutamyl cysteine synthetase - GST glutathione-S-transferase - BCA bicinchoninic acid - SDS sodium dodecyl sulfate - PCA perchloric acid     

Biochemical and functional changes of rat liver spheroids during spheroid formation and maintenance in culture: II. nitric oxide synthesis and related changes

Liver cells isolated from intact tissue can reaggregate to form three-dimensional, multicellular spheroids in vitro. During this process, cells undergo a histological and environmental change. How cells respond biochemically to this change has not been studied in detail previously. We have investigated some biochemical changes in rat liver cells during the formation and maintenance of spheroids. Liver cells were isolated from male Sprague rats and spheroids cultured by a gyrotatory-mediated method. Liver cells were shown to respond to the isolation procedure and the formation of spheroids triggered histological environmental changes that increased arginine uptake, nitric oxide (NO) and urea syntheses, as well as raised levels of GSH, GSSG, glutamic acid and aspartic acid secretion within the first couple of days after cell isolation. Levels were maintained at a relatively stable level in the mature spheroids (>5 days) over the 3 week period of observation. P450 1A1 activity was lost in the first 2 days and gradually recovered thereafter. This study, for the first time, shows that liver cells after isolation and during spheroid formation actively uptake arginine and increase NO and urea syntheses. A high level of NO is likely to play an important role in modulating a series of biochemical changes in liver cells. It is considered that liver cells actively respond to the 'challenge' induced by the isolation procedure and subsequent histological environmental changes, and biochemical modulation and instability result. The stable cell-cell contacts and histological environment in mature spheroids permit and support functional recovery and maintenance in vitro. This period of stability permits the use of spheroids in toxicity studies to establish acute and chronic paradigms.     

Regulation of apoptosis by glutathione redox state in PC12 cells exposed simultaneously to iron and ascorbic acid

We previously reported that the levels of non-protein-bound iron (NPBI) and ascorbic acid (AA) are markedly increased in the cerebrospinal fluid of infants with perinatal asphyxia. The present study showed that FeSO4 and AA synergistically induced apoptosis of PC12 cells, which was prevented by alpha-tocopherol and glutathione (GSH) ethyl ester. Markers of free radical damage, such as ortho-tyrosine, meta-tyrosine, and F(2alpha)-isoprostane, showed a gradual increase. AA and ferrous NPBI disappeared rapidly from the culture medium, but exposure for only a few hours was sufficient to trigger apoptosis. Intracellular GSH decreased progressively along with a concomitant increase of glutathione disulfide (GSSG). The baseline half-cell reduction potential (Ehc) for GSSG, 2H+/2GSH couple was -246 mV and an Ehc of -200 mV was the critical level to switch on apoptosis, although some cells escaped this fate by transient increase of intracellular GSH. Once Ehc reached around -165 mV (81 mV oxidation from the baseline), all cells lost the ability to maintain an adequate intracellular GSH level and subsequently underwent apoptosis. These findings at least partly explain the mechanism of Fe-AA cytotoxicity, in that ferrous iron catalyzes hydroxyl radical generation and induces lipid peroxidation, after which subsequent depletion of GSH raises Ehc to the critical level for triggering or potentiating the apoptotic cascade.     

Metabolism, not autoxidation, plays a role in α-oxoaldehyde- and reducing sugar-induced erythrocyte GSH depletion: Relevance for diabetes mellitus

Erythrocyte and lens reduced glutathione (GSH) levels are often lower in patients with diabetes whereas erythrocyte dicarbonyl levels are often higher. We hypothesise that high plasma carbohydrates may be metabolised by glycolytic and pentose phosphate pathways to form -oxoaldehydes, which deplete cellular GSH. Our aims were: (1) to compare the effectiveness of various carbohydrates or metabolites at depleting erythrocyte GSH, (2) to determine if GSH loss is related to the autoxidation or metabolism of carbohydrates. It was found that erythrocyte GSH was depleted by 50% (ED-50) at t = 2.5 h when erythrocytes were incubated with the following: methylglyoxal (MG) 23 M, glyoxal 75 M, DL-glyceraldehyde 299 M, deoxyribose 606 M, xylitol 626 M, and ribose 2 mM. The glycolytic inhibitors, sodium arsenate and KF prevented ribose, deoxyribose, xylitol and MG-induced GSH depletion in erythrocytes over 2 h. However, the antioxidant trolox and the ferric chelator detapac did not affect MG-induced GSH depletion. These data suggest that the carbohydrates or glyceraldehyde were metabolised to form carbonyls such as MG which depleted erythrocyte GSH as a result of catalysis by glyoxalase I. None of the carbohydrates were autoxidised to carbonyls over this time period. We speculate that as a result of GSH depletion, subsequent glycoxidative stress affects erythrocyte function and contributes to diabetic complications.     

Inhibition of apoptosis in serum starved porcine embryonic fibroblasts

In nuclear transplantation, serum starvation is a general method to synchronize donor cells at the quiescent stage (G(0)) of the cell cycle. However, serum starvation during culture of mammalian cells may induce cell death, especially through apoptosis, thus contributing to the low efficiency of nuclear transplantation. This study was performed to characterize apoptosis during serum starvation and to determine the effects of apoptosis inhibitors such as a protease inhibitor [alpha(2)-macroglobulin (MAC)] and antioxidants [N-acetylcysteine (NAC), glutathione (GSH)] on serum starved porcine embryonic fibroblasts (PEF). PEF, collected from day 25-30 porcine fetuses, were cultured for 5 days in media containing 0.5% FBS to induce quiescence. Serum starved PEF showed typical morphology of apoptotic cells and stained for DNA fragmentation by TUNEL assay (26.7%). All apoptosis inhibitors tested in this study significantly (P < 0.05) reduced apoptosis of serum starved PEF, with antioxidants having better results (MAC: 7.4% vs. NAC: 1.0%, and GSH: 0.8%). Equally and importantly, the treatment with apoptosis inhibitors did not change the proportion of G(0)/G(1) stage cells. Therefore, the addition of MAC and antioxidants during serum starvation of PEF reduces apoptosis of quiescent fibroblasts and may contribute to increasing the efficiency of nuclear transplantation by improving the quality of donor nuclei.     

FH/Wjd大鼠酒精性肝损伤模型探讨

目的对FH/W jd大鼠酒精性肝损伤模型进行探讨。方法 FH/W jd大鼠按体重随机分为饮水组和饮酒组,两组均自由饮食。16周后取血,检测血清ALT、AST、TBIL、TG、CHO;取肝脏,匀浆后检测TG、GSH;流式细胞仪检测肝细胞凋亡率;Western blot检测肝脏组织PPARα蛋白表达;肝脏HE染色观察组织病理学改变。结果与饮水组比较,饮酒组两种性别FH/W jd大鼠血清TBIL、TG含量显著升高,饮酒组雌性大鼠血清ALT、CHO显著降低;饮酒组两种性别大鼠肝脏TG含量显著升高,GSH含量呈现降低趋势;饮酒组两种性别大鼠肝细胞凋亡率亦呈降低趋势;饮酒组肝脏PPARα蛋白表达明显上调;饮酒组组织病理学改变以小泡性脂肪变性为主。结论长期自主摄入酒精可以造成FH/W jd大鼠肝脏损伤。     

Potential mechanisms of leukemia cell resistance to TRAIL-induced apopotosis

There are many factors contributing to the resistance to TRAIL (Tumor necrosis factor-related apoptosis-inducing ligand)-induced apoptosis. However, it is not clear whether the mechanism of resistance to TRAIL is constitutive or inductive. Therefore, the purpose of this study was to investigate the resistant mechanisms to TRAIL at different levels in the apoptotic pathway. The human T-lymphoblastic leukemic CEM cell line showed more resistant to TRAIL-induced apoptosis compared with the human chronic myeloid leukemic K562 cell line. Lower level of constitutive caspase-8 expression in the CEM cell line led to a poor response to both TRAIL-induced activation of caspase-3 and reduction in the mitochondrial membrane potential (m). There was no significant difference in the constitutive levels of NF-B in CEM and K562 cell lines. However, CEM cells showed a faster response to TRAIL-induced NF-B activation than K562 cells. TRAIL-induced regulation of Bcl-2 family of proteins included an up-regulation in Bcl-2/Bcl-XL and a down-regulation in Bax. IAPs, such as XIAP, cIAP-1, cIAP-2 and Survivin were all up-regulated during the treatment with TRAIL. In summary, our data suggest that the leukemic cells resistance to TRAIL-induced apoptosis might be due to the deficiency in the constitutive caspase-8 expression. Development of potential resistance to apoptosis by TRAIL can occur in both TRAIL-resistant and TRAIL-sensitive leukemic cells.     

Expression of the p75 TNF receptor is linked to TNF-induced NFkappaB translocation and oxyradical neutralization in glial cells

Tumor necrosis factor (TNF)-family cytokines induce reactive oxygen species (ROS) that injure vulnerable populations of brain cells. Among glia, oligodendrocytes are particularly susceptible to TNF-induced ROS whereas microglia are protected. We previously found that oligodendrocytes in vitro predominantly express the p55 type-1 TNF receptor, while microglial cells express both type-1 and p75 type-2 receptors. We hypothesized that differential TNF receptor expression and attendant signaling underlies the relative vulnerability of oligodendrocytes, versus microglia, to TNF-induced injury. To test this hypothesis, purified cultures of glial cells were incubated 0–48 hr with TNFa or lymphotoxin-alpha, following which levels of ROS, glutathione (GSH), nuclear factor kappa-B (NFB) translocation, and anti-oxidant proteins and activity were measured. 48 hr exposure to TNF increased ROS levels 28% and decreased GSH levels 17% in oligodendrocytes, but decreased levels ROS levels 24% and increased GSH levels 112% increase in microglia. Thirty to 180 min exposure to TNF increased NFkB nuclear translocation to a greater extent and for a longer time in microglia versus oligodendrocytes, and this was followed 24–48 hr later with 3- to 13-fold increases in microglia manganese superoxide dismutase protein levels and 6-fold increases in enzyme activity. Collectively, these data suggest that signals transduced through the p75 receptor activate anti-oxidant mechanisms that protect microglia from TNF-induced injury. Lacking such signals, oligodendrocytes are considerably more vulnerable to the injurious effects of TNF.     

Apoptosis in arsenic trioxide-treated Calu-6 lung cells is correlated with the depletion of GSH levels rather than the changes of ROS levels

Arsenic trioxide (ATO) can regulate many biological functions such as apoptosis and differentiation in various cells. We investigated an involvement of ROS such as H(2)O(2) and O(2)(*-), and GSH in ATO-treated Calu-6 cell death. The levels of intracellular H(2)O(2) were decreased in ATO-treated Calu-6 cells at 72 h. However, the levels of O(2)(*-) were significantly increased. ATO reduced the intracellular GSH content. Many of the cells having depleted GSH contents were dead, as evidenced by the propidium iodine staining. The activity of CuZn-SOD was strongly down-regulated by ATO at 72 h while the activity of Mn-SOD was weakly up-regulated. The activity of catalase was decreased by ATO. ROS scavengers, Tiron and Trimetazidine did not reduce levels of apoptosis and intracellular O(2)(*-) in ATO-treated Calu-6 cells. Tempol showing a decrease in intracellular O(2)(*-) levels reduced the loss of mitochondrial transmembrane potential (DeltaPsi(m)). Treatment with NAC showing the recovery of GSH depletion and the decreased effect on O(2)(*-) levels in ATO-treated cells significantly inhibited apoptosis. In addition, BSO significantly increased the depletion of GSH content and apoptosis in ATO-treated cells. Treatment with SOD and catalase significantly reduced the levels of O(2)(*-) levels in ATO-treated cells, but did not inhibit apoptosis along with non-effect on the recovery of GSH depletion. Taken together, our results suggest that ATO induces apoptosis in Calu-6 cells via the depletion of the intracellular GSH contents rather than the changes of ROS levels.     

Rat hepatocytes prepared without collagenase: Prolonged retention of differentiated characteristics in culture

Rat hepatocytes prepared by collagenase digestion or ED TA dissociation were examined in culture for comparison of culture stability and morphology, and retention of selected adult rat liver characteristics. Cells prepared by EDTA perfusion followed by Percoll cen trifugation were deemed to form confluent monolayer cultures more rapidly and monolayers remained intact for up to 21 days without signs of nonparenchymal cell growth or loss of primary hepatocyte appearance. The spectrally determined cytochrome P-450 content remained constant through eight days in culture. Collagenase prepared cells contained an identical amount of P-450 but within 72 hr lost greater than 80% of the spectrally detectable P-450. Glutathione (GSH) content was higher in the EDTA-prepared hepatocytes and remained constant with only a modest effect of transferrin and selenium (TI S) supplementation, while GSH levels in collagenaseprepared cells increased, thereafter decreased with time in culture and was dependent on TI S supplementation. Cells prepared with ED TA also displayed an increase in GSH efflux rate in response to chronic GSH depletion by ethacrynic acid. -Cystathionase (CNase) activity was retained at initial levels in ED TAprepared hepatocytes supplemented with TI S and declined only about 25% in unsupplemented cells. Collagenase-prepared cells lost 75% of CNase activity by 72 hr. The established marker of hepatocyte neoplastic transformation, -glutamyl trans-peptidase (GGT), increased rapidly in collagenase-prepared cells. The accumulation of GGT was slowed by T/S supplementation. GGT activity did not increase in EDTA-prepared hepatocytes. Evaluation of morphological and biochemical criteria suggest that hepatocytes prepared without collagenase present superior model systems for the study of biochemical events through more extended culture times.Abbreviations CNase -cystathionase - EDTA ethylenediamine tetraacetic acid - GGT -glutamyl transpeptidase - GSH reduced glutathione - GSSG oxidized glutathione - HEPES N-2-hydroxyethylpiperizine-N-2-ethane-sulfonic acid - SAH S-adenosylhomocysteine - SAM S-adenosylmethionine - T/S transferrin- and selenite-supplemented     

Apoptosis in the liver and its role in hepatocarcinogenesis

Apoptosis seems to be the predominant type of active cell death in the liver (type I), while in other tissues cells may die via biochemically and morphologically different pathways (type II, type III). Active cell death is under the control of growth factors and death signals. In the liver, endogenous factors, such as transforming growth factor 1 (TGF-1), activin A, CD95 ligand, and tumor necrosis factor (TNF) may be involved in induction of apoptosis. Release and action of these death factors seems to be triggered by exogenous signals such as withdrawal of hepato-mitogens, food restriction, etc.During stages of hepatocarcinogenesis, not only DNA synthesis but also apoptosis gradually increase from normal to preneoplastic to adenoma and carcinoma tissue. Also, in human carcinomas, birth and death rates of cells are several times higher than in surrounding liver. (Pre)neoplastic liver cells are more susceptible than normal hepatocytes to stimulation of cell replication and of cell death. Consequently, tumor promoters may act as survival factors, i.e., inhibit apoptosis preferentially in preneoplastic and even in malignant liver cells, thereby stimulating selective growth of (pre)neoplastic lesions. On the other hand, regimens favoring apoptosis and lowering cell replication may result in selective elimination of (pre)neoplastic cell clones from the liver. Finally, we have studied the first stage of carcinogenesis, namely the appearance of putatively initiated cells after a single dose of the genotoxic carcinogen N-nitrosomorpholine (NNM). Most of these cells were found to be eliminated by apoptosis, suggesting that initiation, at the organ level, can be reversed at least partially by preferential elimination of initiated cells. These events may be regulated by autocrine or paracrine actions of survival factors.     

Can we reduce oxidative stress with liver transplantation?

BackgroundThe aim of this study was to determine the levels of lipid peroxidation (MDA) and antioxidants such as reduced glutathione (GSH), catalase (CAT) and superoxide dismutase (SOD) in the blood serum of patients with cirrhosis and liver transplantation.MethodsIn this study, serum malondialdehyde acid (MDA) levels, superoxide dismutase (SOD), reduced glutathione (GSH), and catalase (CAT) activities were measured spectrophotometrically and compared to the results of the healthy control group.ResultsSOD, CAT and GSH activities were significantly decreased in the patient groups compared to the healthy control group (p<0.05). MDA levels were significantly higher in the patient group compared to the healthy control group (p <0.05).ConclusionsIn conclusion, this study demonstrated that oxidative stress may play an important role in the development of liver cirrhosis and in liver transplantation. This study is the first one to show how MDA, SOD, CAT and GSH levels change in liver cirrhosis and liver transplantation, while further studies are essential to investigate antioxidant enzymes and oxidative stress status in patients with cirrhosis and liver transplantation.     

Neuroprotection by α-Lipoic Acid in Streptozotocin-Induced Diabetes

Glial cells provide structural and metabolic support for neurons, and these cells become reactive to any insult to the central nervous system. The streptozotocin (STZ) rat model was used to study glial reactivity and the prevention of gliosis by alpha-lipoic acid (alpha-LA) administration. The expression of glial fibrillary acidic protein (GFAP), S100B protein, and neuron specific enolase (NSE) was determined as well as lipid peroxidation (LPO) and glutathione (GSH) levels in some brain tissues. Western blot analyses showed GFAP, S100B, and NSE levels significantly increased under STZ-induced diabetes in brain, and LPO level increased as well. Administration of alpha-LA reduced the expression both of glial and neuronal markers. In addition, alpha-LA significantly prevented the increase in LPO levels found in diabetic rats. GSH levels were increased by the administration of alpha-LA. This study suggests that alpha-LA prevents neural injury by inhibiting oxidative stress and suppressing reactive gliosis.     

Intracellular GSH level is a factor in As4.1 juxtaglomerular cell death by arsenic trioxide

Arsenic trioxide has been known to regulate many biological functions such as cell proliferation, apoptosis, differentiation, and angiogenesis in various cell lines. We investigated the involvement of GSH and ROS such as H(2)O(2) and O(2)(*-) in the death of As4.1 cells by arsenic trioxide. The intracellular ROS levels were changed depending on the concentration and length of incubation with arsenic trioxide. The intracellular O(2)(*-) level was significantly increased at all the concentrations tested. Arsenic trioxide reduced the intracellular GSH content. Treatment of Tiron, ROS scavenger decreased the levels of ROS in 10 microM arsenic trioxide-treated cells. Another ROS scavenger, Tempol did not decrease ROS levels in arsenic trioxide-treated cells, but slightly recovered the depleted GSH content and reduced the level of apoptosis in these cells. Exogenous SOD and catalase did not reduce the level of ROS, but did decrease the level of O(2)(*-). Both of them inhibited GSH depletion and apoptosis in arsenic trioxide-treated cells. In addition, ROS scavengers, SOD and catalase did not alter the accumulation of cells in the S phase induced by arsenic trioxide. Furthermore, JNK inhibitor rescued some cells from arsenic trioxide-induced apoptosis, and this inhibitor decreased the levels of O(2)(*-) and reduced the GSH depletion in these cells. In summary, we have demonstrated that arsenic trioxide potently generates ROS, especially O(2)(*-), in As4.1 juxtaglomerular cells, and Tempol, SOD, catalase, and JNK inhibitor partially rescued cells from arsenic trioxide-induced apoptosis through the up-regulation of intracellular GSH levels.     

Suppression of arsenic trioxide-induced apoptosis in HeLa cells by N-acetylcysteine

Arsenic trioxide (ATO) can affect many biological functions such as apoptosis and differentiation in various cells. We investigated the involvement of ROS and GSH in ATO-induced HeLa cell death using ROS scavengers, especially N-acetylcysteine (NAC). ATO increased intracellular O(2)(*-) levels and reduced intracellular GSH content. The ROS scavengers, Tempol, Tiron and Trimetazidine, did not significantly reduce levels of ROS or GSH depletion in ATO-treated HeLa cells. Nor did they reduce the apoptosis induced by ATO. In contrast, treatment with NAC reduced ROS levels and GSH depletion in the ATO-treated HeLa cells and prevented ATO-induced apoptosis. Treatment with exogenous SOD and catalase reduced the depletion of GSH content in ATO-treated cells. Catalase strongly protected the cells from ATO-induced apoptosis. In addition, treatment with SOD, catalase and NAC slightly inhibited the G1 phase accumulation induced by ATO. In conclusion, NAC protects HeLa cells from apoptosis induced by ATO by up-regulating intracellular GSH content and partially reducing the production of O(2)(*-).     

A superoxide anion generator, pyrogallol induces apoptosis in As4.1 cells through the depletion of intracellular GSH content

We investigated the involvement of ROS such as H2O2 and O2*-, and GSH in As4.1 cell death induced by pyrogallol. The intracellular H2O2 levels were decreased or increased depending on the concentration and incubation time of pyrogallol. The levels of O2*- were significantly increased. Pyrogallol reduced the intracellular GSH content. And ROS scavengers, Tempol, Tiron, Trimetazidine and NAC could not significantly down-regulate the production of H2O2 and O2*-. However, these ROS scavengers slightly inhibited apoptosis. Interestingly, Tempol showing the recovery of GSH depletion induced by pyrogallol significantly decreased apoptosis without the significant reduction of intracellular O2*- levels. SOD and catalase did not change the level of H2O2 but decreased the level of O2*-. The inhibition of GSH depletion by these was accompanied with the decrease of apoptosis, as evidenced by sub-G1 DNA content, annexin V staining, mitochondria membrane potential (DeltaPsi(m)) and Western data. In addition, ROS scavengers and SOD did not alter a G2 phase accumulation of the cell cycle induced by pyrogallol. However, catalase changed the cell cycle distributions of pyrogallol-treated cells to those of pyrogallol-untreated cells. In summary, we have demonstrated that pyrogallol potently generates ROS, especially O2*-, in As4.1 JG cells, and Tempol, SOD and catalase could rescue to a lesser or greater extent cells from pyrogallol-induced apoptosis through the up-regulation of intracellular GSH content.     

Glutathione export during apoptosis requires functional multidrug resistance-associated proteins

GSH is released in cells undergoing apoptosis, and the present study indicates that the multidrug resistance-associated proteins (MRPs/ABCC) are responsible for this GSH release. Jurkat cells released approximately 75-80% of their total intracellular GSH during both Fas antibody- and staurosporine-induced apoptosis. In contrast, Raji cells, a lymphocyte cell line that is deficient in phosphatidylserine externalization, did not release GSH during apoptosis, and other apoptotic features appeared more slowly in these cells. Jurkat and Raji cell lines expressed comparable MRP and OATP/SLCO (organic anion-transporting polypeptide) mRNA levels, and MRP1 protein levels; however, differences existed in MRP1 localization and function. In Jurkat cells, MRP1 was largely localized to the plasma membrane, and these cells exported the MRP substrate calcein. Calcein release was enhanced during apoptosis. In contrast, Raji cells had little MRP1 at the plasma membrane and did not export calcein under basal or apoptotic conditions, indicating that these cells lack functional MRPs at the plasma membrane. GSH release in Jurkat cells undergoing apoptosis was inhibited by the organic anion transport inhibitors MK571, sulfinpyrazone, and probenecid, supporting a role for the MRP transporters in this process. Furthermore, when MRP1 expression was decreased with RNA interference, GSH release was lower under both basal and apoptotic conditions, providing direct evidence that MRP1 is involved in GSH export.     

Retroviral transfer of antisense sequences results in reduction of c-Abl and induction of apoptosis in hemopoietic cells

The c-abl proto-oncogene is ubiquitously expressed during mammalian development. Activated forms of c-Abl proteins are oncogenic and have been shown to suppress apoptosis. The biological role of normal c-Abl protein is unknown. In this study, we have introduced c-abl antisense sequences into various hemopoietic cells by retroviral gene transfer. Introduction and expression of the antisense sequence effectively reduced the amount of c-Abl protein in a number of transduced hemopoietic cells, that consequently underwent apoptosis. When factor-dependent cell lines were examined, we observed that the addition of sufficient amounts of growth factors could suppress apoptosis in myeloid but not in lymphoid lines. The ability of myeloid cells to be rescued by growth factors correlated with upregulation of mRNA level of IL-3 receptor subunits. Our data suggest that c-Abl provides an anti-apoptotic signal during mammalian cell growth, and that myeloid and lymphoid cells are different in their resistance to apoptosis.