Oncogenic Flt3 receptors display different specificity and kinetics of autophosphorylation.

OBJECTIVE: Fms-like tyrosine kinase-3 (Flt3), a growth factor receptor normally expressed in hematopoietic progenitor cells, has been shown to have an important role in development of acute myeloid leukemia (AML) due to activating mutations. Flt3 mutations are found in approximately one-third of AML patients and correlate with a poor prognosis, thus making the Flt3 receptor a potential therapeutic target. The aim of the investigation was to analyze the kinetics and specificity of Flt3 autophosphorylation in wild-type Flt3 as well as in oncogenic Flt3 mutants. MATERIALS AND METHODS: We have used Ba/F3 cells stably expressing either wild-type, internal tandem duplication, or D835Y mutants of Flt3 in order to compare the site selectivity of tyrosine phosphorylation sites. By the use of a panel of phosphospecific antibodies directed against potential tyrosine phosphorylation sites in Flt3, we identified several novel phosphorylation sites in Flt3 and studied the kinetics and specificity of ligand-induced phosphorylation in living cells. RESULTS: Eight phosphorylated tyrosines (pY589, pY591, pY599, pY726, pY768, pY793, pY842, and pY955) were investigated and shown to be differentially phosphorylated in the wild-type versus the mutated receptors. Furthermore, we show that tyrosines 726, 793, and 842 are novel phosphorylation sites of Flt3 in intact cells. CONCLUSION: In this study, we have looked at the site-specific phosphorylation in the wild-type Flt3 in comparison to the mutants found in AML. We observed not only quantitative changes but, more importantly, qualitative differences in the phosphorylation patterns of the wild-type and the mutated Flt3 receptors, which might enhance the understanding of the mechanisms by which Flt3 contributes to AML in patients with mutations in Flt3.

Grb2 mediates negative regulation of stem cell factor receptor/c-Kit signaling by recruitment of Cbl.

Aberrant activation of c-Kit is involved in a number of human diseases including cancers and leukemias. Certain receptor tyrosine kinases, such as epidermal growth factor receptor, have been shown to indirectly recruit Cbl through the adapter protein Grb2, leading to receptor ubiquitination and degradation. In order to study the role of Grb2 in c-Kit degradation, a series of mutations of the Grb2 binding sites in c-Kit were generated (Y703F, Y936F, and Y703F/Y936F). Since other signal transduction molecules are also known to bind Y703 and Y936, the more selective asparagine-to-alanine (N-to-A) mutants N705A, N938A, and N705A/N938A were generated. We could clearly demonstrate that binding of Grb2 was dependent on intact phosphorylation sites Y703 and Y936. Furthermore, we could demonstrate the presence of Cbl in a complex with Grb2 and c-Kit. Thus, Grb2 is able to indirectly recruit Cbl to c-Kit. In the N-to-A mutants, Cbl phosphorylation was strongly reduced, which correlated with reduced ubiquitination of c-Kit as well as decreased internalization and degradation of the receptor. Taken together, we have demonstrated that, in addition to its role in positive signaling via the Ras/Erk pathway, Grb2 mediates c-Kit degradation through recruitment of Cbl to c-Kit, leading to ubiquitination of c-Kit followed by internalization and degradation.

Identification of Y589 and Y599 in the juxtamembrane domain of Flt3 as ligand-induced autophosphorylation sites involved in binding of Src family kinases and the protein tyrosine phosphatase SHP2.

Early signal relay steps upon ligand binding to the receptor tyrosine kinase Flt3 (ie, sites of Flt3 autophosphorylation and subsequent docking partners) are mainly unresolved. By immunoprecipitation of specific tryptic peptides contained in the juxtamembrane region of human Flt3 and subsequent radiosequencing, we identified the tyrosine residues 572, 589, 591, and 599 as in vivo autophosphorylation sites. Focusing on Y589 and Y599, we examined Flt3 ligand (FL)-mediated responses in wild-type-Flt3-(WT-Flt3-), Y589F-Flt3-, and Y599F-Flt3-expressing 32D cells. Compared with WT-Flt3-32D cells upon ligand stimulation, 32D-Y589F-Flt3 showed enhanced Erk activation and proliferation/survival, whereas 32D-Y599F-Flt3 cells hereby displayed substantially diminished responses. Both pY589 and pY599 were identified as association sites for signal relay molecules including Src family kinases and SHP2. Consistently, 32D-Y589F-Flt3 and 32D-Y599F-Flt3 showed decreased FL-triggered activation of Src family kinases. Interference with the Src-dependent negative regulation of Flt3 signaling may account for the enhanced mitogenic response of Y589F-Flt3. Y599 was additionally found to interact with the protein tyrosine phosphatase SHP2 in a phosphorylation-dependent manner. As Y599F-Flt3-32D was unable to associate with and to phosphorylate SHP2 and since silencing of SHP2 in WT-Flt3-expressing cells mimicked the Y599F-Flt3 phenotype, we hypothesize that recruitment of SHP2 to pY599 contributes to FL-mediated Erk activation and proliferation.