The src oncogene can regulate a human glucose transporter expressed in chicken embryo fibroblasts.

When fibroblasts are transformed by the src oncogene, there is a two- to fivefold increase in glucose transport and in the level of immunoprecipitable glucose transporter protein. In chicken embryo fibroblasts (CEFs), this increase is correlated with a comparable reduction in the rate at which the glucose transporter protein is turned over. In contrast, in mammalian fibroblasts glucose transporter biosynthesis is increased by src, but there is little or no change in its turnover. To further understand the action of src on transporter turnover, we investigated whether a mammalian transporter can be stabilized by src in a chicken cell environment. The human type 1 glucose transporter protein (hGT), originally cloned from HepG2 cells, was expressed in CEFs or Rat-1 fibroblasts by using a retroviral vector. In CEFs transformed by a temperature-sensitive src mutant, tsNY68, turnover of hGT was lower at the permissive temperature (36 degrees C) than at the nonpermissive temperature (42 degrees C). When this protein was expressed in CEFs transformed by wild-type src, no difference in turnover was observed at the two temperatures. In the case of Rat-1 cells transformed by the temperature-sensitive src mutant tsLA29, turnover of hGT was the same at the permissive temperature (35 degrees C) as at the nonpermissive temperature (39.5 degrees C). These data demonstrate that a heterologous glucose transporter behaves in the same way in chicken and rat cells as the respective endogenous transporter, i.e., when src is active, the protein is stablilized against turnover in chicken cells but not in rat cells.     

Degradation and biosynthesis of the glucose transporter protein in chicken embryo fibroblasts transformed by the src oncogene.

The rate of glucose transport in cultured fibroblasts is regulated to a number of physiological variables, including malignant transformation by src, glucose starvation, and stimulation with mitogens. Much of this transport regulation can be accounted for by variations in the amount of transporter protein in the cells. To determine the mechanisms by which levels of the transporter are regulated, we measured the rates of synthesis and degradation of the transporter by pulse-chase experiments and immunoprecipitation of the transporter. We found that transformation by the src oncogene results in a large decrease in the rate at which the transporter protein is degraded but that it does not appreciably increase the rate of transporter biosynthesis. On the other hand, glucose starvation and mitogen stimulation increase the rate of transporter biosynthesis, although a role for control of degradation is possible in these circumstances also. Variations in the rate of glucose transport or the amount of the transporter are not associated with phosphorylation of the transporter protein.     

Effect of hypertonicity on hexose transporter regulation in chicken embryo fibroblasts

The regulation of hexose transporters of cultured fibroblasts was investigated by exposing chicken embryo fibroblasts (CEF) to hypertonic culture medium, a condition known to enhance hexose transport activity. The effects of hypertonicity and the role of protein synthesis were examined with CEF in the basal (glucose fed) and transport enhanced (glucose starved) states. Glucose-fed CEF exposed to hypertonic conditions developed four-fold enhancement of hexose transport activity within 4 hrs; this declined in the following 20 hrs to a level slightly higher than the fed control. Protein synthesis was required in part for this effect, since the presence of cycloheximide during hypertonic exposure of fed CEF blocked the increase in of transport by almost 50%. Although the increased transport produced by glucose starvation was not further enhanced by hypertonicity, hypertonic treatment of starved CEF during glucose refeeding largely prevented the loss of transport activity to the basal, fed state. The hypertonic effects were concentration dependent (240mOsm optimal) and could be elicited with NaCl, KCl, or sucrose. Hypertonic treatment typically led to a greater than 50% decline in the incorporation of [3H]leucine into acid-insoluble fractions. The changes in transport were evident at the plasma membrane level, and studies of membrane vesicles prepared from hypertonically treated fed CEF showed a doubling of both [3H]cytochalasin B binding and the Vmax of D-glucose transport. These findings indicate that exposure of CEF to hypertonic conditions has some effects similar to those produced by glucose starvation and suggest that protein synthesis is to some extent involved in the regulation of hexose transporters in CEF.     

Transformation by the src oncogene alters glucose transport into rat and chicken cells by different mechanisms.

Transformation of both rat and chicken fibroblasts by the src oncogene leads to a four- to fivefold increase in the rate of glucose transport and in the level of the glucose transporter protein. We have previously shown that, with chicken embryo fibroblasts, transformation leads to a reduction in the rate of degradation of the transporter, with little or no increase in the rate of its biosynthesis. We now show that, with the rat-1 cell line, the opposite result was obtained. src-induced transformation led to an increase in transporter biosynthesis, with little effect on turnover. A src-induced increase in transporter mRNA entirely accounted for the increase in biosynthesis of the protein. By contrast, in chicken embryo fibroblasts, the level of transporter mRNA was low and was not induced to rise by src transformation. Thus, src induced an increase in the level of the glucose transport protein by fundamentally different mechanisms in chicken embryo fibroblasts and rat-1 cells. To test whether this difference was due to rat-1 cells being an immortalized cell line, we measured transporter mRNA levels in primary fibroblast cultures from rat embryos and in parallel cultures transformed by src. Transporter mRNA was inducible by src in these cells. Thus, the difference in mRNA inducibility between chicken and rat cells is not due to immortalization.     

Differential regulation of Akt kinase isoforms by the members of the TCL1 oncogene family.

The members of the TCL1 proto-oncogene family (TCL1, MTCP1, and TCL1b) bind to Akt1, increasing its phosphorylation status and kinase activity. This is thought to be secondary to the formation of TCL1-Akt oligomers within which Akt is preferentially phosphorylated. Here we show that, in contrast to Akt1 and Akt2, which bind to all members of the TCL1 family, Akt3 specifically interacts with TCL1 but not with MTCP1 or TCL1b. This association is functional, as the presence of TCL1 but not MTCP1 or TCL1b increased Akt3 kinase activity in in vitro kinase assays. Functional specificity is determined by the Akt pleckstrin homology domain as chimeric Akt1, where Akt1 PH domain was replaced by that of Akt3 was no longer able to interact with MTCP1 or TCL1b and its kinase activity was solely enhanced by TCL1. Moreover, we show that, in TCL1-overexpressing SUPT-11 T-cell leukemia and P3HR-1 Burkitt's lymphoma cell lines, TCL1 interacts with endogenous Akt1, Akt2, and Akt3. TCL1 enhanced hetero-oligomerization of Akt1 with Akt3 and as a consequence facilitated transphosphorylation of Akt molecules, which may contribute to Akt activation and TCL1-induced leukemogenesis in vivo.     

Differential expression of glucose transporter isoforms during embryonic stem cell differentiation

In mouse blastocysts six facilitative glucose transporter isoforms (GLUT)1-4, 8 and 9 are expressed. We have used the mouse embryonic stem (ES) cell line D3 and spontaneously differentiating embryoid bodies (EB) to investigate GLUT expression and the influence of glucose during differentiation of early embryonic cells. Both ES cells and EBs (2d-20d) expressed GLUT1, 3, and 8, whereas the isoforms 2 and 4 were detectable exclusively in EBs. Differentiation-associated expression of GLUT was analyzed by double staining with stage-specific embryonic antigen (SSEA-1), cytokeratins (CK18, 19), nestin, and desmin. Similar to trophoblast cells in mouse blastocysts the outer cell layer of endoderm-like cells showed a high GLUT3 expression in early EBs. In 20-day-old EBs no GLUT3 protein and only minor GLUT3 mRNA amounts could be detected. A minimal glucose concentration of 5 mM applied during 2 and 8 days of EB culture resulted in up-regulated GLUT4, Oct-4 and SSEA-1 levels and a delay in EB differentiation. We conclude that GLUT expression depends on cellular differentiation and that the expression is modulated by glucose concentration. The developmental and glucose-dependent regulation of GLUT strongly suggests a functional role of glucose and glucose transporters in ES cell differentiation and embryonic development.     

Differential regulation of the expression of transforming growth factor-beta mRNAs by growth factors and retinoic acid in chicken embryo chondrocytes, myocytes, and fibroblasts.

Transforming growth factor-beta (TGF-beta) autoregulates its expression in several mammalian cell types. We now report that addition of TGF-beta s 1, 2, and 3 to primary chicken embryo cells differentially affects expression of the messenger RNAs for the different TGF-beta isoforms depending on the cell type. In cultured sternal chondrocytes, addition of TGF-beta s 1, 2, or 3 results in an increase in the steady-state levels of the messenger RNAs for TGF-beta s 2 and 3, but does not change expression of TGF-beta 4 mRNA. In contrast, in cultured cardiac myocytes, addition of TGF-beta s 1, 2, or 3 results in an increase in expression of TGF-beta s 3 and 4 mRNAs, but does not change expression of TGF-beta 2 mRNA. Moreover, expression of TGF-beta s 2, 3, and 4 mRNAs is not affected by addition of any of the TGF-beta s to fibroblasts. Addition of platelet-derived growth factor (PDGF), epidermal growth factor (EGF), or interleukin-1 (IL-1) to these chicken cells also has differential effects on expression of the different TGF-beta mRNAs depending on the cell type. Retinoic acid also has contrasting effects on chondrocytes and myocytes either increasing or decreasing, respectively, expression of TGF-beta s 2 and 3 mRNAs and TGF-beta 2 protein. Our results indicate a complex pattern of regulation of the different TGF-beta genes by themselves as well as by PDGF, EGF, IL-1, dexamethasone, TPA, and retinoic acid in chicken embryo cells.     

Ubiquitin in stressed chicken embryo fibroblasts

Ubiquitin, a small 76-amino acid protein which is highly conserved in eukaryotic cells, occurs in several forms other than the free polypeptide. Among these are protein conjugates in which ubiquitin is covalently linked in lysylpeptide bond to lysl residues of other proteins and fusion proteins in which the amino-terminal domain is the precise ubiquitin sequence. Ubiquitin plays a role in cellular proteolytic degradation and in chromatin structure and has been postulated to be involved in the induction of a set of proteins which function during the cellular response to various kinds of environmental stress. We have measured the various forms of ubiquitin in cultures of chicken embryo fibroblasts under normal growth conditions and after treatment with a thermal or chemical stress. Levels of free ubiquitin fell slightly, ubiquitin conjugate levels rose shortly after stress began, and both then increased substantially as one of the cell's ubiquitin-encoding genes was activated by stress. The level of a protein synthesized as the carboxyl-terminal domain of one ubiquitin fusion protein was unchanged by a heat stress. The most dramatic effect was seen in the rapid disappearance of the ubiquitinated form of histone H2A, one of the major ubiquitin conjugates in cells in the interphase portion of their growth cycle. A significant rise in protein turnover was detected as a result of the stress, but occurred only when cells were removed from the stress condition. These results suggest that ubiquitin plays an important role both during and after stress, but fails to support hypotheses for ubiquitin and proteolysis in the activation of stress genes.     

A rearranged junD transforms chicken embryo fibroblasts.

A complementary DNA clone synthesized from the chicken junD mRNA, containing 5'- and 3'-untranslated sequences, was inserted in the retroviral expression vector RCAS to yield the construct JD. A second RCAS construct (DDDD) contained only the coding domains of JunD. DDDD did not transform upon primary transfection, but JD produced small numbers of transformed cell foci in chicken embryo fibroblast cultures. The virus recovered from these foci, JDV, was moderately transforming for chicken fibroblasts and weakly oncogenic in the animal. Its genome was rearranged, showing evidence for two recombination events. The first crossover was located between 5'-untranslated and coding sequences of junD and incorporated part of the 5'-untranslated region into an open reading frame. The second crossover occurred between junD and gag. The two crossovers generate a single open reading frame of 2064 nucleotides that encodes an 85 kilodalton protein in which sequences in the amino-terminal region of JunD are duplicated. This gag junD reading frame was recloned and then reconstituted into a replication-defective but transformation-competent retrovirus, indicating that the Gag-JunD fusion protein is the effector of transformation. A construct containing this rearranged coding sequence of JunD in Rc/RSV transactivated the collagenase promoter in chicken cells. Southern blot analysis of several independently isolated JunD transformants and deletion analysis of JDV indicated that duplication of a domain in the amino-terminal region of JunD is crucial for transformation and transactivation.     

Differential regulation of two distinct families of glucose transporter genes in Trypanosoma brucei.

A tandemly arranged multigene family encoding putative hexose transporters in Trypanosoma brucei has been characterized. It is composed of two 80% homologous groups of genes called THT1 (six copies) and THT2 (five copies). When Xenopus oocytes are microinjected with in vitro-transcribed RNA from a THT1 gene, they express a glucose transporter with properties similar to those of the trypanosome bloodstream-form protein(s). This THT1-encoded transport system for glucose differs from the human erythrocyte-type glucose transporter by its moderate sensitivity to cytochalasin B and its capacity to transport D-fructose. These properties suggest that the trypanosomal transporter may be a good target for antitrypanosomal drugs. mRNA analysis revealed that expression of these genes was life cycle stage dependent. Bloodstream forms express 40-fold more THT1 than THT2. In contrast, procyclic trypanosomes express no detectable THT1 but demonstrate glucose-dependent expression of THT2.     

Differential regulation of glucose transporter gene expression in adipose tissue or septic rats.

To understand the molecular mechanisms responsible for the sepsis-induced enhanced glucose uptake, we have examined the levels of GLUT4 and GLUT1 mRNA and protein in the adipose tissue of septic animals. Rats were challenged with a nonlethal septic insult where euglycemia was maintained and hexose uptake in adipose tissue was markedly elevated. Northern blot analysis of total RNA isolated from epididymal fat pads indicated differential regulation of the mRNA content for the two transporters: GLUT1 mRNA was increased 2.6 to 4.6-fold, while GLUT4 mRNA was decreased by 2.5 to 2.9-fold. Despite the difference in mRNA levels, both GLUT1 and GLUT4 protein were down regulated in plasma membranes (40% and 25%, respectively) and microsomal membranes (42% and 25%, respectively) of the septic animals. The increased glucose uptake cannot be explained by the membrane content of GLUT1 and GLUT4 protein. Thus, during hypermetabolic sepsis, increased glucose utilization by adipose tissue is dependent on alternative processes.     

Domains responsible for the differential targeting of glucose transporter isoforms.

Facilitative glucose transporter isoforms, GLUT1 and GLUT4, have different intracellular distributions despite their very similar structure. In insulin-responsive tissues such as adipose tissues and muscle, GLUT4 protein resides mainly in the intracellular region in a basal condition and is translocated to the plasma membrane upon stimulation of insulin. In contrast, GLUT1 protein was distributed about equally between plasma membranes and low density microsomal membranes in 3T3-L1 adipocytes. Furthermore, GLUT1 and GLUT4 were reported to be differentially targeted to the plasma membrane and intracellular region, respectively, when expressed in Chinese hamster ovary cells and HepG2 cells. To elucidate the differential intracellular targeting mechanisms, several chimeric glucose transporters in which portions of GLUT4 are replaced with corresponding portions of GLUT1 have been stably expressed in Chinese hamster ovary cells. Immunofluorescence and immunoelectron microscopy as well as measurement of glucose transport activity revealed that two domains of GLUT4, which are not the NH2- or COOH-terminal domain, determine its targeting to the intracellular vesicles. The first domain contains the consensus sequence of the leucine zipper structure, suggesting that a dimer-forming structure of the glucose transporter might be required for its proper targeting. The other domain contains 28 amino acids, nine of which are different between GLUT1 and GLUT4. Immunoelectron microscopy revealed that the chimeric transporters containing both of these two domains of GLUT1, only the first domain of GLUT1, and none of the domains, exhibited a different cellular distribution with approximately 65, 30, and 15% of the transporters apparently on the plasma membrane, respectively. The addition of insulin did not alter the apparent cellular distributions of these chimeric transporters. These domains would be specifically recognized by intracellular targeting mechanisms in Chinese hamster ovary cells.     

Increased collagen synthesis in myeloblastosis-associated virus-infected chicken embryo fibroblasts.

Chicken embryo fibroblasts infected with a non-transforming derivative of avian myeloblastosis virus [MAV-2(0)] showed a threefold increase in the biosynthesis of collagen compared to values in normal counterparts. In contrast, non-collagen protein synthesis was unchanged.     

Differential regulation of glucose transporter activity and expression in red and white skeletal muscle.

Insulin-stimulated glucose transport activity and GLUT4 glucose transporter protein expression in rat soleus, red-enriched, and white-enriched skeletal muscle were examined in streptozotocin (STZ)-induced insulin-deficient diabetes. Six days of STZ-diabetes resulted in a nearly complete inhibition of insulin-stimulated glucose transport activity in perfused soleus, red, and white muscle which recovered following insulin therapy. A specific decrease in the GLUT4 glucose transporter protein was observed in soleus (3-fold) and red (2-fold) muscle which also recovered to control values with insulin therapy. Similarly, cardiac muscle displayed a marked STZ-induced decrease in GLUT4 protein that was normalized by insulin therapy. White muscle displayed a small but statistically significant decrease in GLUT4 protein (23%), but this could not account for the marked inhibition of insulin-stimulated glucose transport activity observed in this tissue. In addition, GLUT4 mRNA was found to decrease in red muscle (2-fold) with no significant alteration in white muscle. The effect of STZ-induced diabetes was time-dependent with maximal inhibition of insulin-stimulated glucose transport activity at 24 h in both red and white skeletal muscle and half-maximal inhibition at approximately 8 h. In contrast, GLUT4 protein in red and white muscle remained unchanged until 4 and 7 days following STZ treatment, respectively. These data demonstrate that red skeletal muscle displays a more rapid hormonal/metabolic-dependent regulation of GLUT4 glucose transporter protein and mRNA expression than white skeletal muscle. In addition, the inhibition of insulin-stimulated glucose transport activity in both red and white muscle precedes the decrease in GLUT4 protein and mRNA levels. Thus, STZ treatment initially results in a rapid uncoupling of the insulin-mediated signaling of glucose transport activity which is independent of GLUT4 protein and mRNA levels.     

Differential role of MAP kinase isoforms in malachite green transformed Syrian hamster embryo fibroblasts in culture

Malachite green (MG) induces DNA damage and malignant transformation of Syrian hamster embryo (SHE) cells in primary culture. In the present study, we have studied the role of all the three isoforms of mitogen activated protein (MAP) kinases i.e. ERK (extracellular regulated kinase), JNK (JUN- N- terminal kinase) and p38 kinase during transformation of SHE cells by MG. The results showed that transformed cells were associated with a decreased expression of phosphoactive ERK and JNK and increased expression of p38 kinase as evident from the Western blot, immunofluorescence and flow cytometry studies. Also, a persistent nuclear localization of p38 kinase was observed in the transformed cells. The present study indicated that p38 kinase was present at higher levels and seemed to be associated with transformation, which suggested that inhibitors of p38 kinase could serve in general as potential agents for selective cancer therapy.     

Expression of the v-erbA oncogene in chicken embryo fibroblasts stimulates their proliferation in vitro and enhances tumor growth in vivo

In contrast to uninfected chicken embryo fibroblasts (CEFs), CEFs infected with a retroviral vector that carries the v-erbA gene of avian erythroblastosis virus displayed new properties. These included limited anchorage-independent growth in soft agar, growth without latency in serum-supplemented medium, ability to overcome quiescence induced by serum deprivation, growth at low cell density, and an extended life span in vitro. Furthermore, when explanted in vivo onto the chorioallantoic membrane of chicken embryo, the transformed CEFs expressing v-erbA in addition to v-erbB exhibited a high proliferative rate, giving rise to fibrosarcoma tumors that were ten times larger than those developed from transformed CEFs expressing v-erbB alone. All these data show that CEFs expressing the v-erbA oncogene display activated growth and suggest that the v-erbA product interferes with the mechanisms regulating the growth and/or differentiation of primary CEFs.