Influence of selenium on heat shock protein 70 expression in heat stressed turkey embryos (Meleagris gallopavo)

Heat shock protein 70 (hsp70) family of proteins, which functions as molecular chaperones, has been associated with tolerance to stressors in avian species. Selenium (Se) is an essential trace mineral incorporated into the seleno-enzymes such as glutathione peroxidase (GSHpx). GSHpx reduces oxidized glutathione (GSSG) to reduced glutathione (GSH) in the GSH/GSSG antioxidant system and protects cells from oxidative damage. This study was conducted to examine if the relationship between dietary supplementation of selenium to turkey (Meleagris gallopavo) hens and the embryonic expression of hsp70 and GSHpx activity in heat stressed embryos. Livers of embryos developing in eggs from turkey hens fed diets with or without supplemental Se were analyzed for hsp70 concentration and GSHpx activity before and after recovery from a heating episode. Before heat stress, hsp70 concentrations were equivalent in each treatment, but GSHpx activity was maximized in the SE treatment group. After recovery from the heating episode, hsp70 concentrations were significantly higher (P<0.05) in the non-Se-supplemented groups, but in the Se-supplemented groups the hsp70 concentrations were not different from pre-stress concentrations. In the pre-stress Se-supplemented group, liver GSHpx activity was significantly higher than GSHpx activity in the non-Se-supplemented embryo livers, and in the livers from embryos recovering from heat stress, GSHpx activity in the non-Se-supplemented group was lower than the pre-stress activity and significantly lower than the GSHpx activity in liver from Se-supplemented embryos recovering from heat distress. Se supplementation to the dams resulted in a significant increase in their embryos and that condition would facilitate a decreased incidence of oxidative damage to cells. A more reduced redox status in embryos from Se-supplemented dams decreased the need for cellular protection attributed to stress induced hsp70 and presumably allows heat distressed embryos to resume normal growth and development than embryos from dams with inadequate selenium nutrition.     

Glycopeptides prepared from mouse cerebrum inhibit protein synthesis and cell division in baby hamster kidney cells, but not in their polyoma virus-transformed analogs

Glycopeptides isolated from mouse cerebral cortex cell surfaces (BCSG) were shown to inhibit cell growth and protein synthesis in baby hamster kidney (BHK)-21 cells, whereas polyoma virus-transformed BHK-21 cells (pyBHK-21) were refractory to the inhibitory activity of the glycopeptides. Growth inhibition was shown to be reversible and non-lethal to BHK-21 cells. Despite that difference in sensitivity to the action of the glycopeptides, both cell lines could bind the inhibitor in a saturable fashion and in similar quantities. After trypsinization, BHK-21 cells appeared refractory to the inhibitor, whereas pyBHK-21 cells became sensitive. The data suggested the presence of a receptor for BCSG on the cell surface of both cell lines. Incubating BCSG with conditioned medium from pyBHK-21 cells resulted in loss of the glycopeptide's inhibitory activity. In contrast, medium conditioned by BHK-21 cells had no effect on the inhibitory activity of BCSG. We hypothesize that the refractoriness of pyBHK-21 cells to BCSG is related to their autonomous growth characteristics and failure to respond to topo-inhibitory growth control. BCSG may be a naturally occurring growth regulator whose function can be explored by use of the BHK-21/ pyBHK-21 model system.     

Ascorbate uptake and antioxidant function in peritoneal macrophages

Since activated macrophages generate potentially deleterious reactive oxygen species, we studied whether ascorbic acid might function as an antioxidant in these cells. Thioglycollate-elicited murine peritoneal macrophages contained about 3 mM ascorbate that was halved by culture in ascorbate-free medium. However, the cells took up added ascorbate to concentrations of 6-8 mM by a high-affinity sodium-dependent transport mechanism. This likely reflected the activity of the SVCT2 ascorbate transporter, since its message and protein were present in the cells. Activation of the cells by phagocytosis of latex particles depleted intracellular ascorbate, although not below the basal levels present in the cells in culture. Glutathione (GSH) was unaffected by phagocytosis, suggesting that ascorbate was more sensitive to the oxidant stress of phagocytosis than GSH. Phagocytosis induced a modest increase in reactive oxygen species as well as a progressive loss of alpha-tocopherol, both of which were prevented in cells loaded with ascorbate. These results suggest that activated macrophages can use ascorbate to lessen self-generated oxidant stress and spare alpha-tocopherol, which may protect these long-lived cells from necrosis or apoptosis.     

Cell calcium, vitamin E, and the thiol redox system in cytotoxicity

The controversial role of extracellular Ca2+ in toxicity to in vitro hepatocyte systems is reviewed. Recent reports demonstrate that extracellular Ca2+-related cytotoxicity is dependent on Ca2+-influenced vitamin E (alpha-tocopherol) content of isolated hepatocytes. Based on a Ca2+-omission model of in vitro oxidative stress, the role of vitamin E in cytotoxicity is further explored. This model demonstrates the interdependence of the GSH redox system and vitamin E as protective agents during oxidative stress. Following chemical oxidant-induced depletion of intracellular GSH, cell morphology and viability are maintained by the continuous presence of cellular alpha-tocopherol above a threshold level of 0.6-1.0 nmol/10(6) cells. alpha-Tocopherol threshold-dependent cell viability is directly correlated with the prevention of the loss of cellular protein thiols in the absence of intracellular GSH. Potential mechanisms for this phenomenon are explored and include a direct reductive action of alpha-tocopherol on protein thiyl radicals, and the prevention of oxidation of protein thiols by scavenging of lipid peroxyl radicals by alpha-tocopherol. It is suggested that in light of the threshold phenomenon of vitamin E prevention of potentially severe oxidative stress-induced cytotoxicity, its use as a protective agent against an oxidative challenge in vivo should be reassessed.     

A role of vitamin E in protection against cell injury. Maintenance of intracellular glutathione precursors and biosynthesis

The depletion of cell calcium from isolated rat hepatocytes results in stimulated lipid peroxidation, loss of intracellular and mitochondrial GSH (reduced glutathione), and enhancement of both efflux and oxidation of GSH. These events are followed by cell injury and enhance the susceptibility of the cells to toxic chemicals. It is shown herein that an initial event in the generation of such injury is the depletion of cellular alpha-tocopherol. alpha-Tocopheryl succinate addition (25 microM) to the calcium-depleted cells markedly elevated the alpha-tocopherol content of the cells, inhibited the associated lipid peroxidation, and maintained intracellular GSH levels without affecting its efflux or redox status. This resulted in an enhanced formation of total glutathione after a 5-h incubation, which correlated with the alpha-tocopherol content of the cells, and was greater than that expected by a direct sparing action of vitamin E. Inhibition of hepatocyte glutathione biosynthesis by buthionine sulfoximine (0.5 mM) eliminated the enhancement of GSH formation by vitamin E. Analysis of endogenous and 35S-labelled precursors of glutathione biosynthesis by high-performance liquid chromatography demonstrated that the depletion of cellular alpha-tocopherol resulted in the efflux of glutathione precursors. It is concluded that cell injury associated with alpha-tocopherol depletion is partly the result of the efflux of glutathione precursors, and hence diminished biosynthesis and intracellular levels of GSH. These losses and resultant cell injury are preventable by maintenance of cellular alpha-tocopherol levels.     

Deoxyribonucleic acid-dependent ribonucleic acid polymerases from normal and polyoma-transformed BHK-21/C13 cells.

DNA-dependent RNA polymerase (EC 2.7.7.6) ACTIVITIES FROM NORMAL BHK-21/C13 cells and from BHK-21/C13 cells transformed by polyoma virus (PYY cells) were solubilized and fractionated on columns of DEAE-Sephadex. Various properties of the A and B enzymes from the two types of cell were compared. 1. The yields of polymerase relative to the DNA content of the nuclear preparations are similar for both cell types. 2. The ionic-strength optima of polymerases A and B are 12.5 mM and 100mM with respect to (NH4)2SO4 for both cell types. 3. The Mn2+/Mg2+ activity ratio (measured at the respective optimum for each cation) for polymerase A from BHK-21/C13 cells was 1.48 and for the polymerase A from PYY cells was 0.55. The corresponding ratios for polymerase B were 10.11 for BHK-21/C13 cells and 22.75 for PYY cells. 4. Minor differences in the ability of the A polymerases to transcribe native and denatured DNA templates were observed; such differences were not apparent when the B polymerases were compared. 5. All the polymerases were inhibited completely by actinomycin D and by rifampicin AF/013, but not markedly so by rifampicin. Alpha-amanitin inhibited polymerase B but not polymerase A.     

(R)- and (S)-verapamil differentially modulate the multidrug-resistant protein MRP1

The multidrug-resistant protein MRP1 (involved in the cancer cell multidrug resistance phenotype) has been found to be modulated by racemic verapamil (through stimulation of glutathione transport), inducing apoptosis of human MRP1 cDNA-transfected baby hamster kidney 21 (BHK-21) cells and not of control BHK-21 cells. In this study, we show that the two enantiomers of verapamil have different effects on MRP1 activity. Only the S-isomer (not the R-isomer) potently induced the death of MRP1-transfected BHK-21 cells. The decrease in cellular glutathione content induced by the S-isomer, which was not observed with the R-isomer, was stronger than that induced by the racemic mixture, indicating that the R-isomer antagonized the S-isomer effect. Both enantiomers altered leukotriene C(4) and calcein transport by MRP1. Thus, the R-isomer behaved as an inhibitor, which was confirmed by its ability to revert the multidrug resistance phenotype toward vincristine. Molecular studies on purified MRP1 using fluorescence spectroscopy showed that both enantiomers bound to MRP1 with high affinity, with the binding being prevented by glutathione. Furthermore, conformational changes induced by the two enantiomers (monitored by sodium iodide accessibility of MRP1 tryptophan residues) were quite different, correlating with their distinct effects. (S)-Verapamil induces the death of potentially resistant tumor cells, whereas (R)-verapamil sensitizes MRP1-overexpressing cells to chemotherapeutics. These results might be of great potential interest in the design of new compounds able to modulate MRP1 in chemotherapy.     

Antioxidants and herbal extracts protect HT-4 neuronal cells against glutamate-induced cytotoxicity

Antioxidant therapy has been shown to be beneficial in neurological disorders including Alzheimer's disease and cerebral ischemia. Glutamate-induced cytotoxicity in HT-4 neuronal cells has been previously demonstrated to be due to oxidative stress caused by depletion of cellular glutathione (GSH). The present study demonstrates that a wide variety of antioxidants inhibit glutamate-induced cytotoxicity in HT-4 neuronal cells. Low concentrations of alpha-tocopherol and its analogs were highly effective in protecting neuronal cells against cytotoxicity. Purified flavonoids and herbal extracts of Gingko biloba (EGb 761) and French maritime pine bark (Pycnogenol) were also effective. We have previously shown that pro-glutathione agents can spare GSH and protect cells from glutamate insult in a C6 glial cell model. The protective effects of nonthiol-based antioxidants tested in the HT-4 line were not mediated via GSH level modulation. In contrast, protective effects of thiol-based pro-glutathione agents alpha-lipoic acid (LA) and N-acetyl cysteine (NAC) corresponded with a sparing effect on GSH levels in glutamate-treated HT-4 cells. Glutamate-induced cytotoxicity in HT-4 cells is a useful model system for testing compounds or mixtures for antioxidant activity.     

Increases in tumor necrosis factor-alpha in response to thyroid hormone-induced liver oxidative stress in the rat

Thyroid hormone-induced calorigenesis contributes to liver oxidative stress and promotes an increased respiratory burst activity in Kupffer cells, which could conceivably increase the expression of redox-sensitive genes, including those coding for cytokines. Our aim was to test the hypothesis that L-3,3',5-triiodothyronine (T3)-induced liver oxidative stress would markedly increase the production of TNF-alpha by Kupffer cells and its release into the circulation. Sprague-Dawley rats receive a single dose of 0.1 mg T3/kg or vehicle (controls) and determinations of liver O2 consumption, serum TNF-alpha, rectal temperature, and serum T3 levels, were carried out at different times after treatment. Hepatic content of total reduced glutathione (GSH) and biliary glutathione disulfide (GSSG) efflux were measured as indices of oxidative stress. In some studies, prior to T3 injection animals were administered either (i) the Kupffer cell inactivator gadolinium chloride (GdCl3), (ii) the antioxidants alpha-tocopherol and N-acetyl-L-cysteine (NAC), or (iii) an antisense oligonucleotide against TNF-alpha (ASO TJU-2755). T3 elicited an 80-fold increase in the serum levels of TNF-alpha at 22h after treatment, which coincided with the onset of thyroid calorigenesis. Pretreatment with GdCl3, alpha-tocopherol, NAC, and ASO TJU-2755 virtually abolished this effect and markedly reduced T3-induced liver GSH depletion and the increases in biliary GSSG efflux. It is concluded that the hyperthyroid state in the rat increases the circulating levels of TNF-alpha by actions exerted at the Kupffer cell level and these are related to the oxidative stress status established in the liver by thyroid calorigenesis.     

Vitamin E protection against chemical-induced cell injury. I. Maintenance of cellular protein thiols as a cytoprotective mechanism

Vitamin E protection against chemical-induced toxicity to isolated hepatocytes was examined during an imbalance in the thiol redox system. Intracellular reduced glutathione (GSH) was depleted by two chemicals of distinct mechanisms of action: adriamycin, a cancer chemotherapeutic agent that undergoes redox cycling, producing reactive oxygen species that consume GSH, and ethacrynic acid, a direct depleter of GSH. The experimental system used both nonstressed vitamin E-adequate isolated rat hepatocytes and compromised hepatocytes subjected to physiologically induced stress, generated by incubation in calcium-free medium. At doses whereby intracellular GSH was near total depletion, cell injury induced by either chemical was found to follow the depletion of cellular alpha-tocopherol, regardless of the status of the GSH redox system. Changes in protein thiol contents of the cells closely paralleled the changes in alpha-tocopherol contents throughout the incubation period. Supplementation of the calcium-depleted hepatocytes with alpha-tocopheryl succinate (25 microM) markedly elevated their alpha-tocopherol content and prevented the toxicities of both drugs. The prevention of cell injury and the elevation in alpha-tocopherol contents were both associated with a prevention of the loss in cellular protein thiols in the near total absence of intracellular GSH. The mechanism of protection by vitamin E against chemical-induced toxicity to hepatocytes may therefore be an alpha-tocopherol-dependent maintenance of cellular protein thiols.     

EGF mediates protection against Fas-induced apoptosis by depleting and oxidizing intracellular GSH stocks

Several pieces of evidence have demonstrated the importance of reduction/oxidation (redox) signaling in biological processes, including sensitivity toward apoptosis. In parallel, it was recently reported that growth factors induce the generation of reactive oxygen species (ROS). Therefore, we tested the hypothesis that the anti-apoptotic effect of epidermal growth factor (EGF) was mediated by changes in the redox state of hepatocytes through changes in GSH stocks. Isolated mouse hepatocytes were cultured and exposed to anti-Fas stimulation in order to induce apoptosis. Cell death by apoptosis was assessed by Hoechst 33258 staining and by measuring caspase-3 proteolysis activity. Cell treatment with EGF significantly decreased total (GSx) and reduced (GSH) glutathione levels in the presence and the absence of anti-Fas. Furthermore, glutathione reductase activity was lower in EGF-treated cultures (by 28%) as compared to untreated cultures which lead to a significant decline in GSH/GSx ratio. These effects were found to be EGF-receptor tyrosine kinase activity dependent. Co-stimulation of cells with anti-Fas and EGF attenuated caspase-3 activation and cell death by apoptosis by 70%. GSH monoethylester (GSHmee) significantly attenuated the effect of EGF on GSH and GSH/GSx ratio. It caused an increase in caspase-3 activation and in the percentage of apoptotic cells in anti-Fas + EGF-treated cells, thus resulting in a 53% decline in the protective effect of EGF. In conclusion, EGF induces a significant and specific depletion and oxidization of intracellular GSH, paralleled by a protection against Fas-induced apoptosis. GSH repenishment partly counteracted these effects suggesting that GSH depletion contributed to the protective effect of EGF against caspase-3 activation and cell death by apoptosis.     

Over-expression of Hsp70 in BHK-21 cells engineered to produce recombinant factor VIII promotes resistance to apoptosis and enhances secretion

Production of coagulation factor VIII (FVIII) by recombinant cell lines is limited by its failure to reach or maintain the native conformation in the endoplasmic reticulum. This results in significant cytoplasmic degradation and/or aggregation of the misfolded product. The molecular chaperone Hsp70 was overexpressed in an attempt to increase the recombinant FVIII (rFVIII) secretion. The characteristics of increased Hsp70 expression were investigated by comparing a clone of BHK-21 cells expressing rFVIII (rBHK-21(host)) to a chaperone clone derived by transfection of the host clone with human Hsp70 (rBHK-21(Hsp70)) in small-scale batch cell cultures. To aid this investigation a number of fluorescence based cellular apoptosis assays were developed and optimized. These assays demonstrated sub-populations of rBHK-21(host) cells that were apoptotic in nature and were identified prior to the loss in plasma membrane integrity. Dual staining for intracellular rFVIII and caspase-3 activation showed a reduction in intracellular rFVIII in rBHK-21(host) cells that correlated with a significant increase in active caspase-3, suggesting that apoptosis was a factor limiting rFVIII secretion. In sharp contrast there was more intracellular rFVIII and less active caspase-3 in rBHK-21(Hsp70) cell cultures. Moreover when grown in batch culture, rBHK-21(Hsp70) cells released rFVIII of higher specific activity (active FVIII protein/total FVIII protein), suggesting improved product quality. Thus, increased expression of HSP70 led to an increased yield of a secreted recombinant protein by inhibition of apoptosis and promoting proper conformational maturation of rFVIII in sub-optimal bioreactor conditions.     

Cell surface staining of recombinant factor VIII is reduced in apoptosis resistant BHK-21 cells

We have recently demonstrated an increase in recombinant factor VIII (rFVIII) secretion from BHK-21 cells (rBHK-21(host)) following an over-expression of the chaperone protein heat shock protein 70 (Hsp70) (rBHK-21(Hsp70)) due to an inhibition of apoptotic cell death and an increased cellular expression of rFVIII [Ishaque, A., Thrift, J., Murphy, J.E., Konstantin, K., 2007. Over-expression of Hsp70 in BHK-21 cells engineered to produce recombinant factor VIII promotes resistance to apoptosis and enhances secretion. Biotechnol. Bioeng. Biotech. Bioeng. 97, 144-155]. In the present study we investigated the difference in adherence of rFVIII to the cell membrane surface by comparing changes in cell viability and extent of phosphatidylersine (PS) exposure in apoptosis between rBHK-21(host), rBHK-21(Hsp70), and parental BHK-21 cells devoid of rFVIII expression (BHK-21(native)) during batch cell culture experiments. The Zenon technique was used to double stain for cell surface and intracellular rFVIII using flow cytometric Guava PCA analysis. By this quantitative analysis intracellular rFVIII was shown to decrease in rBHK-21(host) cells as the cell viability declined while the rFVIII cell surface staining increased. Conversely, rBHK-21(Hsp70) cell cultures displayed higher cell viability and intracellular rFVIII with less cell surface rFVIII staining. Time dependent increases of rFVIII adherence to the surface of rBHK-21(host) cells and its reduction on the surface of rBHK-21(Hsp70) cells was also confirmed by fluorescence microscopy. Furthermore, greater rFVIII cell surface staining correlated with an increase in detectable PS exposure on the surface of BHK-21(native) batch cell cultures. However, PS exposure could not be identified to the same extent on rBHK-21(host) cells despite a similar decline in cell viability between rBHK-21(host) and BHK-21(native) batch cultures. Any exposed PS on rBHK-21(host) cells was most likely masked by secreted rFVIII, mimicking the effect on activated platelets where the externalization of PS also occurs, and serves as a ligand for FVIII activation in the blood coagulation cascade. Taken together we have identified that rFVIII sequestration on the membrane surface is another potential limitation to rFVIII productivity and one which can also be alleviated by reduction of apoptosis in a clone expressing human HSP70.     

Isolation of cell-surface glycopeptides from bovine cerebral cortex that inhibit cell growth and protein synthesis in normal but not in transformed cells.

Glycopeptides were isolated from the cell surfaces of bovine cerebral cortex that could inhibit increase in cell numbers in tissue culture and cellular protein synthesis. This cell growth inhibition apparently affected all cells exposed, could completely block cell division in a reversible manner and synchronized BHK-21 cell cultures. Polyoma-virus-transformed BHK-21 cells were completely insensitive to the inhibitor. Fractionation of the inhibitor on a Bio-Gel P-100 column revealed two peaks of biologically active material eluting at apparent molecular weights of 45 000 and 10 000 with A 1cm,280 1% 11.0. Affinity purification of the inhibitory fractions on a Ulex europaeus agglutination I lectin column resulted in retention of the inhibitory activity, suggesting the inhibitor material was a glycopeptide. Subsequent elution with 0.10 M-fucose resulted in a 244-fold increase in the specific biological activity over the starting material. Although purified from bovine brain, the material could inhibit baby-hamster kidney cell protein synthesis by 50% at a concentration of 5 x 10(6) molecules per target cell. Analysis by competitive radioimmunoassay or immunoadsorption indicated that the bovine inhibitor was structurally related to, although not necessarily identical with, a similar inhibitory glycopeptide preparation that we had previously isolated from mouse brain.     

Scoparia dulcis, a traditional antidiabetic plant, protects against streptozotocin induced oxidative stress and apoptosis in vitro and in vivo

Oxidative stress is implicated in the pathogenesis of diabetic complications. The experiments were performed on normal and experimental male Wistar rats treated with Scoparia dulcis plant extract (SPEt). The effect of SPEt was tested on streptozotocin (STZ) treated Rat insulinoma cell lines (RINm5F cells) and isolated islets in vitro. Administration of an aqueous extract of Scoparia dulcis by intragastric intubation (po) at a dose of 200 mg/kg body weight significantly decreased the blood glucose and lipid peroxidative marker thiobarbituric acid reactive substances (TBARS) with significant increase in the activities of plasma insulin, pancreatic superoxide dismutase (SOD), catalase (CAT), and reduced glutathione (GSH) in streptozotocin diabetic rats at the end of 15 days treatment. Streptozotocin at a dose of 10 mug/mL evoked 6-fold stimulation of insulin secretion from isolated islets indicating its insulin secretagogue activity. The extract markedly reduced the STZ-induced lipidperoxidation in RINm5F cells. Further, SPEt protected STZ-mediated cytotoxicity and nitric oxide (NO) production in RINm5F cells. Treatment of RINm5F cells with 5 mM STZ and 10 mug of SPEt completely abrogated apoptosis induced by STZ, suggesting the involvement of oxidative stress. Flow cytometric assessment on the level of intracellular peroxides using fluorescent probe 2'7'-dichlorofluorescein diacetate (DCF-DA) confirmed that STZ (46%) induced an intracellular oxidative stress in RINm5F cells, which was suppressed by SPEt (21%). In addition, SPEt also reduced (33%) the STZ-induced apoptosis (72%) in RINm5F cells indicating the mode of protection of SPEt on RIN m5Fcells, islets, and pancreatic beta-cell mass (histopathological observations). Present study thus confirms antihyperglycemic effect of SPEt and also demonstrated the consistently strong antioxidant properties of Scoparia dulcis used in the traditional medicine.     

BHK-21-derived cell lines that produce basic fibroblast growth factor, but not parental BHK-21 cells, initiate neuronal differentiation of neural crest progenitors.

We present evidence that basic fibroblast growth factor (bFGF)-producing cells stimulate primary differentiation of neurons from neural crest progenitors. Baby hamster kidney (BHK-21) cells were stably cotransfected with plasmid pSV2/neo, which contains the gene conferring resistance to the neomycin analog G418 and expression vectors containing the human bFGF cDNA. Various clones, which differed in their bFGF production levels, were isolated. Homogeneous neural crest cells were cultured on monolayers of bFGF-producing, BHK-21-derived cell lines. While the parental BHK-21 cells, which do not produce detectable bFGF, had poor neurogenic ability, the various bFGF-producing clones promoted a 1.5- to 4-fold increase in neuronal cell number compared to the parental cells. This increase was correlated with the levels of bFGF produced by the different transfected clones, which ranged between 2.3 and 140 ng/mg protein. In contrast, no stimulation of neuronal differentiation was observed when neural crest cells were grown on monolayers of parental BHK cells transfected with plasmid pSV2/neo alone, or on a parental BHK-derived clone, which secretes high amounts of recombinant vascular endothelial growth factor (VEGF). Furthermore, the neuron-promoting ability of bFGF-producing cells could be mimicked by addition of exogenous bFGF to neural crest cells grown on the parental BHK line. A similar treatment of neural crest cells grown on laminin substrata, instead of BHK cells, resulted in increased survival of non-neuronal cells, but not of neurons (see also Kalcheim, C. 1989, Dev. Biol. 134, 1-10). Taken together, these results suggest that bFGF stimulates neuronal differentiation of neural crest cells by a cell-mediated signalling mechanism.     

G2 cell cycle arrest induced by glycopeptides isolated from the bovine cerebral cortex

The ability of glycopeptides, isolated from bovine cerebral cortex, to alter cell division was studied by cell-cycle analyses. The results showed that glycopeptides arrested baby hamster kidney (BHK)-21 cells and Chinese hamster ovary (CHO) cells in the G2 phase of the cell cycle. Upon removal of the growth inhibition from arrested BHK-21 cells, the mitotic index in colchicine-treated cultures increased from 5 to 40% within 6 h and the increase in mitotic activity was accompanied by a complete doubling of all arrested cells within this 6- h time period. Determination of DNA content in growth-arrested BHK-21 cells showed that growth-arrested cells contained about twice the DNA of control cell cultures. Although CHO cells treated in a like manner with growth inhibitor could not be arrested for the same length of time as BHK-21 cells (18 h vs. 72 h before initiation of escape) and to the same degree (60% of the cell population vs. 99% of BHK-21 cells), the escape kinetics of CHO cells did indicate a G2 arrest. Approximately 3.5 h after escape began, CHO cell numbers in treated cultures attained the cell numbers found in control cultures. This rapid growth phase occurring in less than 4 h indicated that the growth inhibitor induced a G2 arrest-point in CHO cells that was not lethal since the entire arrested cell population divided.     

The antiapoptotic protein Mcl-1 controls the type of cell death in Theiler's virus-infected BHK-21 cells

Theiler's murine encephalomyelitis virus (TMEV) results in a persistent central nervous system infection (CNS) and immune-mediated demyelination in mice. TMEV largely persists in macrophages (Ms) in the CNS, and infected Ms in vitro undergo apoptosis, whereas the infection of other rodent cells produces necrosis. We have found that necrosis is the dominant form of cell death in BeAn virus-infected BHK-21 cells but that ~20% of cells undergo apoptosis. Mcl-1 was highly expressed in BHK-21 cells, and protein levels decreased upon infection, consistent with onset of apoptosis. In infected BHK-21 cells in which Mcl-1 expression was knocked down using silencing RNAs there was a 3-fold increase in apoptotic cell death compared to parental cells. The apoptotic program switched on by BeAn virus is similar to that in mouse Ms, with hallmarks of activation of the intrinsic apoptotic pathway in a tumor suppressor protein p53-dependent manner. Infection of stable Mcl-1-knockdown cells led to restricted virus titers and increased physical to infectious particle (PFU) ratios, with additional data suggesting that a late step in the viral life cycle after viral RNA replication, protein synthesis, and polyprotein processing is affected by apoptosis. Together, these results indicate that Mcl-1 acts as a critical prosurvival factor that protects against apoptosis and allows high yields of infectious virus in BHK-21 cells.