Initiation of deregulated growth of multipotent progenitor cells by bcr-abl in vitro.

Expression of the bcr-abl oncogene in multipotent progenitor cells (MPPCs) is implicated as a key event in the development of chronic myelogenous leukemia. Bone marrow enriched for MPPCs was infected with a retrovirus that carried bcr-abl. The mixed-lineage colonies that resulted were responsive to growth factors and could differentiate. These cells later became growth factor-independent but, when injected into severe combined immunodeficient mice, were not leukemogenic. Thus, the presence of bcr-abl alone does not cause growth factor independence, although it initiates a stepwise process. This system may prove useful in the study of other oncogenes that cause leukemia.

Evidence that glucose "marks" beta cells resulting in preferential release of newly synthesized insulin.

Studies of isolated islets labeled with radioactive leucine show that glucose at a critical time "marks" islets in such a way as to cause preferential release of newly synthesized insulin. The preferential release of insulin from marked islets is relatively independent of subsequent secretagogues or rates of insulin secretion. Previous kinetic studies have indicated that the critical time at which marking occurs is after proinsulin biosynthesis but before the secretory event. Thus, secretory cells may regulate the diversion of newly synthesized material for immediate release as it is approaching or transiting the Golgi apparatus.

Heterogeneity and compartmental properties of insulin storage and secretion in rat islets.

To investigate compartmental properties of insulin storage and secretion, isolated rat islets were used for pulse-labeling experiments, after which proinsulin and insulin were purified rigorously. Processing of proinsulin to insulin neared completion by 3 h without additional loss of either radioactive peptide by cellular or extracellular proteolysis. The amount of labeled hormone rapidly diminished in islets; it was secreted at a higher fractional rate than immunoreactive insulin, resulting in secreted insulin's having a higher specific activity than the average cellular insulin. Newly synthesized insulin, therefore, was secreted preferentially. Changes in the specific activity of secreted and cellular insulin with time were consistent with changes predicted for islets containing 33% of their total insulin in a glucose-labile compartment. Predictions were based on steady-state analysis of a simple storage-limited representation of B cell function. Islets from either the dorsal or ventral part of the pancreas also contained 33% of their total insulin in a glucose-labile compartment. The same compartment was mobilized by 20 mM glucose, 50 mM potassium + 2 mM glucose, or 20 MM glucose + 1 mM 3-isobutylmethylxanthine as indicated by the specific activity ratio of secreted vs. cellular insulin, even though average secretion rates with these stimuli differed by more than threefold. In the absence of calcium, the effectiveness of 20 mM glucose as a secretagogue declined markedly, and the older stored insulin was preferentially mobilized because secreted insulin had a lower rather than a higher specific activity than cellular insulin. Results provide insight into the mechanisms of nonrandom mobilization and secretion of insulin form the B cell.

Hyperexpression of interleukin-7 is not necessary or sufficient for transformation of a pre-B lymphoid cell line.

Interleukin-7 (IL-7) is a potent stimulator of pre-B-lymphocyte proliferation. Pre-B cells transformed by a variety of oncogenes including those of the ABL protein tyrosine kinase family were screened for endogenous IL-7 mRNA expression by polymerase chain reaction and a sensitive bioassay for secreted IL-7. Some v-abl but none of the BCR/ABL, v-src, v-fms, v-myc, v-ras, or v-raf transformants analyzed contained elevated IL-7 transcripts. None of the cell lines secreted detectable bioactivity. We overexpressed IL-7 via a retroviral vector in an IL-7-dependent pre-B cell line to assess the potential for autocrine growth stimulation and malignant transformation. We achieved dramatic deregulation of IL-7 translational suppression by removing portions of the 5' flanking region. Levels of IL-7 expression much greater than those needed to establish factor-independent growth did not induce colony formation in agar by IL-7-expressing pre-B cell lines, and the majority of these lines were nontumorigenic in syngeneic mice. The same pre-B cell line transformed by v-abl displayed a highly malignant phenotype while containing dramatically lower IL-7 transcript levels. We conclude that endogenous IL-7 expression is not a necessary event in transformation of pre-B cells, nor is it sufficient to explain the malignant phenotype in v-abl-transformed cells. Up regulation of endogenous IL-7 expression in some transformed pre-B cells may be one of several synergistic events which can lead to malignant conversion.

SH1 domain autophosphorylation of P210 BCR/ABL is required for transformation but not growth factor independence.

P210 BCR/ABL is a chimeric oncogene implicated in the pathogenesis of chronic myelogenous leukemia. BCR sequences have been shown to be required for activation of the tyrosine kinase and transforming functions of BCR/ABL. In this work, we show that two other structural requirements for full transforming activity of P210 BCR/ABL include a functional tyrosine kinase and the presence of tyrosine 1294, a site of autophosphorylation within the tyrosine kinase domain. Replacement of tyrosine 1294 with phenylalanine (1294F) greatly diminishes the transforming activity of BCR/ABL without affecting the specific activity of the protein tyrosine kinase. Expression of an exogenous myc gene in fibroblasts partially complements the transforming capacity of mutant P210 BCR/ABL (1294F). Surprisingly, tyrosine 1294 is not required for efficient induction of growth factor-independence in hematopoietic cell lines by P210 BCR/ABL. These results suggest that autophosphorylation at tyrosine 1294 may be important for recognition and phosphorylation of cellular substrates in the pathway of transformation, but it is not critical for mediating the events which lead to growth factor independence.

Mapping signal transduction pathways by phage display.

Rapid identification of proteins that interact with a novel gene product is an important element of functional genomics. Here we describe a phage display-based technique for interaction screening of complex cDNA libraries using proteins or synthetic peptides as baits. Starting with the epidermal growth factor receptor (EGFR) cytoplasmic tail, we identified known protein interactions that link EGFR to the Ras/MAP kinase signal transduction cascade and several novel interactions. This approach can be used as a rapid and efficient tool for elucidating protein networks and mapping intracellular signal transduction pathways.

The 5' non-coding region of the BCR/ABL oncogene augments its ability to stimulate the growth of immature lymphoid cells.

The Philadelphia chromosome (Ph1, t9:22;34:q11) is a reciprocal translocation between chromosome 22 and chromosome 9 which results in the formation of the chimeric BCR/ABL oncogene. Alternative forms of BCR/ABL are produced by splicing different sets of exons of the BCR gene to a common set of c-ABL sequences. This results in the formation of an 8.7 kilobase mRNA that encodes the P210 BCR/ABL gene product or a 7.0 kilobase mRNA that encodes the P185 BCR/ABL gene product. Both BCR/ABL transcripts derive their 5' non-coding sequences from the BCR gene locus. This 5' region is over 500 nucleotides in length, has a GC content greater than 75% and has a short open reading frame. To determine if this unusual 5' non-coding region plays a role in BCR/ABL transformation, we prepared retroviral vectors containing identical BCR/ABL coding regions but differing in the length of the BCR 5' non-coding region. Matched viral stocks were evaluated for their ability to transform bone marrow in vitro and for their ability to cause tumors when inoculated into 3- to 4-week-old mice. In this report we present the unexpected finding that the BCR/ABL 5' non-coding region augments the transforming activity of both P210 and P185 BCR/ABL in vitro. In vivo, BCR/ABL is a weak tumorigenic agent and its potency is enhanced by the presence of the 5' non-coding region.

Key role of Shc signaling in the transforming pathway triggered by Ret/ptc2 oncoprotein.

The RET/PTC oncogenes, generated by chromosomal rearrangements in papillary thyroid carcinomas, are constitutively activated versions of protoRET, a gene encoding two protein isoforms of a transmembrane tyrosine kinase receptor. By using Ret/ptc2 short isoform (iso9), we have previously demonstrated that Tyr586 (Tyr1062 of protoRet) is the docking site for both the PTB and the SH2 domains of Shc. To determine the relevance of this interaction for the transforming activity of Ret/ptc oncogenes, we have generated and characterized novel Ret/ptc mutants unable to activate Shc: Ret/ptc2 long isoform (iso51)-Y586F and both isoforms of Ret/ptc2-N583A. These mutants neither activate Shc nor transform NIH3T3 cells. Since Tyr1062 shows features of a multifunctional docking site, we have used a Shc mutant (Shc Y317F) to directly assess Shc role. We have demonstrated that in our cell system Shc Y317F behaves like a dominant interfering mutant on the activation of the Grb2-Sos pathway by endogenous Shc triggered by Ret/ptc2. A strong reduction of the transforming activity of Ret/ptc2 in presence of this mutant was also demonstrated. Our data suggest that Shc activation play a key role in the transforming pathways triggered by Ret/ptc oncoproteins. Moreover, we have shown that coexpression of the Shc-Y317F mutant with Ret/ptc2 specifically causes apoptosis, and that the surviving cells lose the long-term expression of one of the two genes.

Contrasting patterns of insulin biosynthesis, compartmental storage, and secretion. Rat tumor versus islet cells.

A series of 3H-leucine pulse-labeling experiments was carried out with dispersed cells freshly isolated from transplanted rat insulinomas. After secreted fractions were separated, insulin was purified and specific activities were determined for both secreted and average cellular insulins. Labeling patterns in this line of tumor cells were compared with those previously established for isolated rat islets. With both tumors and islets, conversion of labeled proinsulin to insulin occurred to the same extent by 2.5 h, suggesting similar onset and half-time of proteolysis in these cells. However, total cellular insulin in tumors attained a threefold higher specific activity than in islets. Because total B-cell mass in these tumors was unknown, either a more rapid proinsulin biosynthesis or diminished cellular storage (or both) could lead to this faster fractional replacement of total stored insulin. Insulin secretion in these tumor cells was insensitive to high glucose but responded, albeit poorly, to leucine plus 3-isobutyl-1-methylxanthine (IBMX). Under all secretory conditions tested, tumor cells continuously secreted insulin at elevated fractional rates, which were slightly higher than fractional insulin secretory rates in maximally glucose-stimulated islets. In contrast with normal islets, newly synthesized insulin was stored homogeneously in tumor cells, and compartmental storage characteristics were not generated by incubation with either 20 mM glucose or leucine plus IBMX in the marking period. Thus, preferential secretion of insulin was never observed in tumor cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of tolbutamide pretreatment on the rate of conversion of newly synthesized proinsulin to insulin and the compartmental characteristics of insulin storage in isolated rat islets.

Tolbutamide (1 g/kg body wt) was administered to male rats for 3 days to determine the effects of this pretreatment on subsequent insulin biosynthesis and compartmental storage characteristics of freshly isolated islets. Islets were isolated 16 h after the last tolbutamide administration, at a time when fed plasma glucose concentrations were normal. Islet glucagon was unchanged but insulin content was significantly reduced (38 +/- 1.2 ng IRI/islet from seven untreated rats versus 7.9 +/- 1.2 ng IRI/islet from eight treated rats). After tolbutamide pretreatment, the rate of incorporation of 3H-leucine into islet proinsulin was unchanged, but the t1/2 of labeled proinsulin-to-insulin conversion was significantly (P less than 0.001) decreased from 36 to 20 min. After treatment, actual rates of glucose-stimulated insulin secretion were 50% lower, however, because due to the proportionately greater depletion of islet insulin content, the fractional rate of secretion was increased two-fold. After treatment, there was evidence of compartmental, heterogeneous insulin storage, and glucose still marked newly synthesized insulin for preferential release; however, the differential release of new and old insulin converged rapidly with time. Mathematical integration of the data suggested dilution of the newly synthesized insulin compartment with unlabeled insulin during the chase period, but additionally indicated more rapid mixing of newly synthesized with previously stored, unlabeled insulin. Thus, tolbutamide-treated rats partially compensated for acute insulin depletion by increasing the rate of proinsulin-to-insulin conversion, but not increasing the rate of proinsulin biosynthesis; doubling the glucose-stimulated fractional secretory rate of the depleted cellular insulin storage compartment; and retaining compartmental storage characteristics but mixing newly synthesized insulin more rapidly with the compartment of previously stored, unlabeled insulin.

Differential kinetics of rat insulin I and II processing in rat islets of Langerhans.

Synthesis and processing of radiolabelled rat insulin I and II were studied by pulse-labelling freshly isolated rat islets with [3H]leucine and chasing in 2 mM glucose for up to 270 min (which minimized insulin secretion, less than 1%/h). Islet samples were taken during the chase period and analyzed for their rat insulin I and II content by high-performance liquid chromatography. Prior to 60 min chase rat insulin I accounted for greater than 85% of the radiolabelled insulin present. With longer periods of chase, the relative percentage of rat insulin II progressively increased so that by completion of proinsulin to insulin processing the two labelled rat insulins were present in the same proportion as the relative immunoreactive content, approx. 60:40% insulin I/insulin II. Thus, although islets synthesize the two insulins in proportion to their relative immunoreactive content, rat insulin I and II are processed with different kinetics.

Molecular mechanisms of Bcr-Abl-induced oncogenesis.

The chimeric Bcr-Abl oncogene has been implicated in the pathogenesis of chronic myelogenous leukemia (CML) and Philadelphia chromosome (Ph1)-positive acute lymphocytic leukemia (ALL). The Bcr-Abl protein is a complex structure comprising discrete domains associated with specific biochemical and biological functions. These domains function through their ability to activate distinct signal transduction pathways responsible for Bcr-Abl's oncogenic behavior. This review will present our current understanding of signal transduction pathways involved in Bcr-Abl-induced pathophysiology, with particular emphasis on potential targets for therapeutic intervention.

Mutant forms of growth factor-binding protein-2 reverse BCR-ABL-induced transformation.

Growth factor-binding protein 2 (Grb2) is an adaptor protein that links tyrosine kinases to Ras. BCR-ABL is a tyrosine kinase oncoprotein that is implicated in the pathogenesis of Philadelphia chromosome (Ph1)-positive leukemias. Grb2 forms a complex with BCR-ABL and the nucleotide exchange factor Sos that leads to the activation of the Ras protooncogene. In this report we demonstrate that Grb2 mutant proteins lacking amino- or carboxyl-terminal src homology SH3 domains suppress BCR-ABL-induced Ras activation and reverse the oncogenic phenotype. The Grb2 SH3-deletion mutant proteins bind to BCR-ABL and do not impair tyrosine kinase activity. Expression of the Grb2 SH3-deletion mutant proteins in BCR-ABL-transformed Rat-1 fibroblasts and in the human Ph1-positive leukemic cell line K562 inhibits their ability to grow as foci in soft agar and form tumors in nude mice. Furthermore, expression of the Grb2 SH3-deletion mutants in K562 cells induced their differentiation. Because Ras plays an important role in signaling by receptor and nonreceptor tyrosine kinases, the use of interfering mutant Grb2 proteins may be applied to block the proliferation of other cancers that depend in part on activated tyrosine kinases for growth.

Identification of structural characteristics that contribute to a difference in antiapoptotic function between human insulin and insulin-like growth factor 1 receptors.

To determine whether potentiation of cell survival is an intrinsic function among the insulin receptor tyrosine kinase (RTK) family, we compared the ability of insulin receptor (IR) and insulin-like growth factor 1 receptor (IGF-IR) cytoplasmic tails to attenuate apoptosis. Expression and activation of IGF-IR, in interleukin-3 (IL-3)-dependent 32Dcl.3 cells, prevents death under conditions of IL-3 withdrawal. In contrast, a chimeric receptor comprising the extracellular portion of IGF-IR fused to the cytoplasmic tail of IR (chIR) fails to promote cell survival when activated with ligand. Both chIR and IGF-IR exhibit comparable levels of enzymatic activity as evidenced by their ability to autophosphorylate and transphosphorylate the shc protein in vivo. Both chIR and IGF-IR can activate the MAPK signal transduction pathway; however, neither RTK is capable of promoting mitogenesis in the absence of IRS proteins. Structure function analysis of the IR cytoplasmic tail reveals that replacing the COOH-terminal 94 amino acids of the IR cytoplasmic tail with the comparable sequence from IGF-IR confers full antiapoptotic function. Furthermore, mutation of only two amino acids within IR, Phe-1264 and His-1265 to tyrosine (chIR/YY) is sufficient to impart a cell survival activity comparable to wild-type IGF-IR. Amino acid residues Phe-1264 and His-1265 of IR are in a region comparable to Tyr-1250 and Tyr-1251 within human IGF-IR. The amino acid sequence of IR from other species contains at least one tyrosine residue in this region, suggesting that differences in antiapoptotic function we observed may represent a characteristic unique to human members of this RTK family. The ability of IGF-IR or chIR/YY to prevent apoptosis is not blocked by addition of the PI3K inhibitor wortmannin. These studies define a critical region responsible for mediating cell survival through a novel interaction that is independent of mitogenesis.

Cyclophosphamide treatment of prediabetic Chinese hamsters.

To assess the immune system's involvement in the causation of diabetes in the genetically diabetic Chinese hamster, "prediabetic" animals were immunosuppressed with cyclophosphamide, starting several weeks prior to the expected onset of hyperglycemia. The immunosuppressant dose was titrated to maximally depress the lymphocyte count without significant deleterious effects on food consumption, body weight or granulocyte count. Immunosuppression did not prevent or postpone the development of hyperglycemia or glucosuria. This suggests that if there is an autoimmune component in the etiology of diabetes in the genetically diabetic Chinese hamster, it takes place earlier or is of a more specific nature than that investigated in the present study.

Efficient transplantation of BCR-ABL-induced chronic myelogenous leukemia-like syndrome in mice.

Lethally irradiated mice reconstituted with bone marrow expressing P210 BCR-ABL can develop myeloproliferative syndromes that resemble the initial phase of human chronic myelogenous leukemia (CML). Mice that develop the CML-like syndrome can be segregated into two groups based on the latency with which the granulocytic disease appears--early onset (< 20 weeks) and late onset (> 20 weeks). Only cells from mice exhibiting the late-onset CML-like syndrome can efficiently propagate the disease when transplanted into sublethally irradiated syngeneic recipients. Mice engrafted with late-onset murine CML cells develop a range of hematopoietic disorders that originate from multipotent stem cells. The chronic granulocytic hyperplasia can be propagated by serial transplantation into secondary and tertiary recipient mice. The majority of transplanted mice succumb to acute myeloid and B- and T-lymphoid leukemias. These data support the idea that late-onset murine CML originates from a multipotent progenitor cell with a high replicating capacity. The inability to transplant the disease from mice developing the early-onset CML-like syndrome suggests that this disorder may originate from more differentiated progenitor cells with limited replication capacity that have undergone clonal expansion but are not immortalized. Although both early- and late-onset CML-like syndromes exhibit granulocytic hyperplasia, these disorders represent distinct diseases that appear to originate from different hematopoietic cell types. The late-onset CML-like disease and transfer to secondary recipients provides a useful murine model with features of the chronic and acute phases of human CML.

Propagation of human blastic myeloid leukemias in the SCID mouse.

Existing in vitro culture technology does not permit the routine propagation of most human myeloid leukemias. Previous work has shown the usefulness of mice with severe combined immunodeficiency (SCID) for the growth of human lymphoblastic leukemia. We show here that human myeloid cell lines and bone marrow samples from patients with acute myeloid leukemia (AML) and blast crisis of chronic myeloid leukemia (CML) also grow in SCID mice. Human AML or CML cell lines (three of three lines tested) grew in the bone marrow and peripheral blood of the mice after intravenous (IV) inoculation in a pattern closely resembling human AML. To define the best conditions for the growth of primary human myeloid leukemia cells, samples were transplanted into mice at several alternative sites. Using flow cytometry and Southern analysis, mice were analyzed at defined intervals up to 36 weeks after transplantation for the presence of human cells in various tissues. For four of four patients with AML and two of two patients with blast crisis of CML, myeloblasts grew locally at the site of implantation and were detected in the murine hematopoietic tissues. In contrast, marrow implants from patients in the chronic phase of CML (six patients) showed infrequent and limited myeloid growth in the mice. These findings demonstrate that the SCID mouse is a reproducible system for the propagation of blastic human myeloid leukemias. The differential growth of early- versus late-phase CML suggests that the SCID mouse may be a useful assay for identifying biologically aggressive leukemias early in their clinical presentation.

Ewing sarcoma 11;22 translocation produces a chimeric transcription factor that requires the DNA-binding domain encoded by FLI1 for transformation.

The 11;22 chromosomal translocation specifically linked to Ewing sarcoma and primitive neuroectodermal tumor results in a chimeric molecule fusing the amino-terminal-encoding portion of the EWS gene to the carboxyl-terminal DNA-binding domain encoded by the FLI1 gene. We have isolated a fourth EWS-FLI1 fusion cDNA that is structurally distinct from the three forms previously described. To determine the transforming activity of this gene, alternative forms of the EWS-FLI1 fusion were transduced into NIH 3T3 cells. Cells expressing either type 1 or type 4 fusion constructs formed foci in culture and colonies in soft agar, indicating that EWS-FLI1 is a transforming gene. EWS-FLI1 deletion mutants were created to map functionally the critical regions within the chimera. Deletion of either the EWS domain or the FLI1 corresponding to the DNA-binding domain totally abrogated the ability for EWS-FLI1 to transform 3T3 cells. These data indicate that the oncogenic effect of the 11;22 translocation is caused by the formation of a chimeric transcription factor. Formation of chimeric transcription factors has now been demonstrated to promote tumors of both neuroectodermal and hematopoietic origin, suggesting that this may be a common mechanism in human carcinogenesis.