SHP-2 can suppress transformation induced by platelet-derived growth factor

Clonal evolution in tyrosine kinase inhibitor-resistance: lessons from in vitro-models

Introduction

Resistance in anti-cancer treatment is a result of clonal evolution and clonal selection. In chronic myeloid leukemia (CML), the hematopoietic neoplasm is predominantly caused by the formation of the BCR::ABL1 kinase. Evidently, treatment with tyrosine kinase inhibitors (TKIs) is tremendously successful. It has become the role model of targeted therapy. However, therapy resistance to TKIs leads to loss of molecular remission in about 25% of CML patients being partially due to BCR::ABL1 kinase mutations, while for the remaining cases, various other mechanisms are discussed.

Methods

Here, we established an in vitro-TKI resistance model against the TKIs imatinib and nilotinib and performed exome sequencing.

Results

In this model, acquired sequence variants in NRAS, KRAS, PTPN11, and PDGFRB were identified in TKI resistance. The well-known pathogenic NRAS p.(Gln61Lys) variant provided a strong benefit for CML cells under TKI exposure visible by increased cell number (6.2-fold, p < 0.001) and decreased apoptosis (-25%, p < 0.001), proving the functionality of our approach. The transfection of PTPN11 p.(Tyr279Cys) led to increased cell number (1.7-fold, p = 0.03) and proliferation (2.0-fold, p < 0.001) under imatinib treatment.

Discussion

Our data demonstrate that our in vitro-model can be used to study the effect of specific variants on TKI resistance and to identify new driver mutations and genes playing a role in TKI resistance. The established pipeline can be used to study candidates acquired in TKI-resistant patients, thereby providing new options for the development of new therapy strategies to overcome resistance.

KIDs rule: regulatory phosphorylation of RTKs

Receptor tyrosine kinases (RTKs) are mediators of multiple cell signaling networks linked to cell growth and differentiation. In general, they exhibit similar overall structure with a ligand-binding extracellular domain and a conserved intracellular tyrosine kinase domain. In many RTKs, the kinase domain is interrupted by a sequence known as the kinase insert domain (KID). In addition to phosphorylation sites within the kinase domain, regulatory phosphorylation also occurs within the KID of several RTKs important in human health and disease. Phosphorylation of specific Tyr or Ser residues within the KID of some RTKs triggers distinct cellular signaling outcomes. Here, we review the functionality of KIDs throughout all RTK families, and provide justification for further study of this often-overlooked domain.

Shp2 suppresses PyMT-induced transformation in mouse fibroblasts by inhibiting Stat3 activity

We have examined the effect of expression of the protein tyrosine phosphatase Shp2 on transformation by the mouse polyoma virus middle T antigen (PyMT). Gain-of-function mutations in Shp2 indicate that it may serve as an oncogene in several types of human leukemia. Paradoxically, however, some catalytically dominant-negative mutations of Shp2 have also been identified in leukemia and neuroblastomas. In this study, we show that Shp2 suppresses transformation induced by PyMT, the major polyoma viral oncoprotein known to act through binding and activation of pp60(c-src). Over-expression of a catalytically inactive Shp2 mutant in NIH3T3 cells significantly enhanced PyMT-induced transformation. Conversely, re-introduction of Shp2 into Shp2-deficient cells strongly inhibited PyMT-induced transformation and tumorigenesis. Short hairpin RNA (shRNA)-mediated Shp2 knockdown potentiated PyMT-induced transformation. Finally, we present evidence that the transformation-suppressive effects of Shp2 are mediated at least partially through the inhibition of signal transducers and activators of transcription 3.