Tyrosine residues in phospholipase Cgamma 2 essential for the enzyme function in B-cell signaling.

Phospholipase Cgamma (PLCgamma) isoforms are regulated through activation of tyrosine kinase-linked receptors. The importance of growth factor-stimulated phosphorylation of specific tyrosine residues has been documented for PLCgamma1; however, despite the critical importance of PLCgamma2 in B-cell signal transduction, neither the tyrosine kinase(s) that directly phosphorylate PLCgamma2 nor the sites in PLCgamma2 that become phosphorylated after stimulation are known. By measuring the ability of human PLCgamma2 to restore calcium responses to the B-cell receptor stimulation or oxidative stress in a B-cell line (DT40) deficient in PLCgamma2, we have demonstrated that two tyrosine residues, Tyr(753) and Tyr(759), were important for the PLCgamma2 signaling function. Furthermore, the double mutation Y753F/Y759F in PLCgamma2 resulted in a loss of tyrosine phosphorylation in stimulated DT40 cells. Of the two kinases that previously have been proposed to phosphorylate PLCgamma2, Btk, and Syk, purified Btk had much greater ability to phosphorylate recombinant PLCgamma2 in vitro, whereas Syk efficiently phosphorylated adapter protein BLNK. Using purified proteins to analyze the formation of complexes, we suggest that function of Syk is to phosphorylate BLNK, providing binding sites for PLCgamma2. Further analysis of PLCgamma2 tyrosine residues phosphorylated by Btk and several kinases from the Src family has suggested multiple sites of phosphorylation and, in the context of a peptide incorporating residues Tyr(753) and Tyr(759), shown preferential phosphorylation of Tyr(753).

Requirement of Ras-GTP-Raf complexes for activation of Raf-1 by protein kinase C.

Receptor tyrosine kinase-mediated activation of the Raf-1 protein kinase is coupled to the small guanosine triphosphate (GTP)-binding protein Ras. By contrast, protein kinase C (PKC)-mediated activation of Raf-1 is thought to be Ras independent. Nevertheless, stimulation of PKC in COS cells led to activation of Ras and formation of Ras-Raf-1 complexes containing active Raf-1. Raf-1 mutations that prevent its association with Ras blocked activation of Raf-1 by PKC. However, the activation of Raf-1 by PKC was not blocked by dominant negative Ras, indicating that PKC activates Ras by a mechanism distinct from that initiated by activation of receptor tyrosine kinases.

Differential regulation of Raf-1, A-Raf, and B-Raf by oncogenic ras and tyrosine kinases.

It has previously been shown that maximal activation of Raf-1 is produced by synergistic signals from oncogenic Ras and activated tyrosine kinases. This synergy arises because Ras-GTP translocates Raf-1 to the plasma membrane where it becomes phosphorylated on tyrosine residues 340 and 341 by membrane-bound tyrosine kinases (Marais, R., Light, Y., Paterson, H. F., and Marshall, C. J. (1995) EMBO J. 14, 3136-3145). We have examined whether the other two members of the Raf family, A-Raf and B-Raf, are regulated in a similar way to Raf-1. A-Raf behaves like Raf-1, being weakly activated by oncogenic Ras more strongly activated by oncogenic Src, and these signals synergize to give maximal activation. B-Raf by contrast is strongly activated by oncogenic Ras alone and is not activated by oncogenic Src. These results show that maximal activation of B-Raf merely requires signals that generate Ras-GTP, whereas activation of Raf-1 and A-Raf requires Ras-GTP together with signals that lead to their tyrosine phosphorylation. B-Raf may therefore be the primary target of oncogenic Ras.

A cell surface tethered enzyme improves efficiency in gene-directed enzyme prodrug therapy.

The potential for expressing the bacterial enzyme carboxypeptidase G2 (CPG2) tethered to the outer surface of mammalian cells was examined for use in gene-directed enzyme prodrug therapy. The affinity of CPG2 for the substrate methotrexate was unaffected by three mutations required to prevent N-linked glycosylation. Breast carcinoma MDA MB 361 cells expressing CPG2 internally showed only a very modest increase in sensitivity to the prodrug CMDA because the prodrug did not enter the cells. Cells expressing surface-tethered CPG2, however, became 16-24-fold more sensitive to CMDA and could mount a good bystander effect. Systemic administration of CMDA to mice bearing established xenografts of the transfected cells led to sustained tumor regressions or cures.

Gene-directed enzyme prodrug therapy with a mustard prodrug/carboxypeptidase G2 combination.

The gene for the bacterial enzyme carboxypeptidase G2 (CPG2) was expressed internally in mammalian cells. Mammalian-expressed CPG2 had kinetic properties indistinguishable from bacterially expressed CPG2. Human tumor cell lines A2780, SK-OV-3 (ovarian adenocarcinomas), LS174T, and WiDr (colon carcinomas) were engineered to express constitutively either CPG2 or bacterial beta-galactosidase. These cell lines were subjected to a gene-directed enzyme prodrug therapy regime, using the prodrug 4-[(2-chloroethyl)(2-mesyloxyethyl)amino]benzoyl-L-glutamic acid (CMDA). The lines which expressed CPG2 had enhanced sensitivity to CMDA. Comparing IC50S, WiDr-CPG2 and SK-OV-3-CPG2 were 11-16-fold more sensitive, whereas A2780-CPG2 and LS174T-CPG2 were approximately 95-fold more sensitive than the corresponding control lines. CPG2-expressing cells and control cells were mixed in differing proportions and then treated with prodrug. Total kill occurred when only approximately 12% of cells expressed CPG2 with the WiDr and SK-OV-3 lines and when only 4-5% of cells expressed CPG2 with the LS174T and A2780 lines, indicating a substantial bystander effect. These results establish this CPG2 enzyme/CMDA prodrug system as an effective combination for the gene-directed enzyme prodrug therapy approach.

Cell-cycle regulation of B-Myb protein expression: specific phosphorylation during the S phase of the cell cycle.

Previous studies revealed that transcription of B-Myb, which encodes a transcription factor related to the c-Myb proto-oncoprotein, is cell-cycle regulated by an E2F transcription factor-mediated repression mechanism operating in G0/G1. To begin to determine the consequences of transcriptional regulation on B-Myb function, we report here further studies of B-Myb protein expression in the cell cycle. We found that G0-arrest of serum-deprived mouse fibroblasts was achieved without significant reduction in B-Myb levels, moreover, over-expression of B-Myb in stably transfected cells did not prevent their entry into G0. Following serum-induction of arrested fibroblasts, B-Myb abundance increased as cells entered S phase to levels significantly greater than found in cycling cells. This was accompanied by the appearance of a novel phosphorylated form of B-Myb (112 kDa) of distinctly lower electrophoretic mobility than B-Myb present in G1 (110 kDa). The 112 kDa species was S phase-specific even in transfected cells overexpressing B-Myb. Consistent with modification in the S phase of the cell cycle, preliminary evidence suggested that a cyclin A/cdk2, but not cyclin E/cdk2 or cyclin D1/cdk4, complex could induce a similar electrophoretic mobility change in baculovirus-specified B-Myb. These findings show that B-Myb expression may be subject to two levels of control during the cell cycle, transcription and protein phosphorylation.

Radioactive labeling of recombinant antibody fragments by phosphorylation using human casein kinase II and [gamma-32P]-ATP.

A wide range of antibody fragments can be expressed in bacteria and detected immunochemically via peptide tags. Using specially designed tags, we have developed a strategy for radiolabeling antibody fragments secreted from bacteria. Tagged antibody fragments were secreted either into the bacterial periplasm or the culture medium. The tag was not subject to proteolysis either in the broth or in human plasma. After affinity purification the antibody fragments were phosphorylated with [gamma-32P]ATP and casein kinase II. The labeled fragments were used in a gel band-shift assay to measure antigen binding affinities. In contrast to non site-specific methods such as radioiodination, antibodies labeled with casein kinase II retain full immunoreactivity. Radioactively phosphorylated antibody fragments may have many other applications, including radioimmunoassays and radioimmunotherapy.

Importance of low affinity Elf-1 sites in the regulation of lymphoid-specific inducible gene expression.

Elf-1 is an Ets family transcription factor that regulates a number of inducible lymphoid-specific genes, including those encoding interleukin 3 (IL-3), granulocyte/macrophage colony-stimulating factor (GM-CSF), and the IL-2 receptor (IL-2R) alpha chain. A minimal oligonucleotide spanning the IL-2R alpha Elf-1 site (-97/-84) bound Elf-1 poorly, but binding activity markedly increased when this oligonucleotide was multimerized or flanking sequences were added. This result is consistent with the requirement of accessory proteins for efficient Elf-1 binding, as has been demonstrated for the GM-CSF and IL-3 promoters. A binding site selection analysis revealed the optimal Elf-1 consensus motif to be A(A/t)(C/a)CCGGAAGT(A/S), which is similar to the consensus motif for the related Drosophila E74 protein. This minimal high affinity site could bind Elf-1 and functioned as a stronger transcription element than the -97/-84 IL-2R alpha oligonucleotide when cloned upstream of a heterologous promoter. In contrast, in the context of the IL-2R alpha promoter, conversion of the naturally occurring low affinity Elf-1 site to an optimal site decreased inducible activation of a reporter construct in Jurkat cells. This finding may be explained by the observation that another Ets family protein, ER GB/Fli-1, can efficiently bind only to the optimal site, and in this context, interferes with Elf-1 binding. Therefore, high affinity Elf-1 sites may lack sufficient binding specificity, whereas naturally occurring low affinity sites presumably favor the association of Elf-1 in the context of accessory proteins. These findings offer an explanation for the lack of optimal sites in any of the known Elf-1-regulated genes.

Ras recruits Raf-1 to the plasma membrane for activation by tyrosine phosphorylation.

A central feature of signal transduction downstream of both receptor and oncogenic tyrosine kinases is the Ras-dependent activation of a protein kinase cascade consisting of Raf-1, Mek (MAP kinase kinase) and ERKs (MAP kinases). To study the role of tyrosine kinase activity in the activation of Raf-1, we have examined the properties of p74Raf-1 and oncogenic Src that are necessary for activation of p74Raf-1. We show that in mammalian cells activation of p74Raf-1 by oncogenic Src requires pp60Src to be myristoylated and the ability of p74Raf-1 to interact with p21Ras-GTP. The Ras/Raf interaction is required for p21Ras-GTP to bring p74Raf-1 to the plasma membrane for phosphorylation at tyrosine 340 or 341, probably by membrane-bound pp60Src. When oncogenic Src is expressed with Raf-1, p74Raf-1 is activated 5-fold; however, when co-expressed with oncogenic Ras and Src, Raf-1 is activated 25-fold and this is associated with a further 3-fold increase in tyrosine phosphorylation. Thus, p21Ras-GTP is the limiting component in bringing p74Raf-1 to the plasma membrane for tyrosine phosphorylation. Using mutants of Raf-1 at Tyr340/341, we show that in addition to tyrosine phosphorylation at these sites, there is an additional activation step resulting from p21Ras-GTP recruiting p74Raf-1 to the plasma membrane. Thus, the role of Ras in Raf-1 activation is to bring p74Raf-1 to the plasma membrane for at least two different activation steps.