Focal adhesion kinase splice variants maintain primitive acute myeloid leukemia cells through altered Wnt signaling.

Focal adhesion kinase (FAK) activity contributes to many advanced cancer phenotypes, but little is known about its role in human acute myeloid leukemia (AML). Here, we show that FAK splice variants are abnormally expressed in the primitive leukemic cells of poor prognosis AML patients. In the CD34(+) 38(-) 123(+) long-term culture-initiating cell-enriched leukemic cells of these patients, FAK upregulates expression of Frizzled-4 and phosphorylates Pyk2 to enable the required association of Pyk2 with the Wnt5a/Frizzled-4/LRP5 endocytosis complex and downstream activation of ß-catenin, thereby replacing the Wnt3a-controlled canonical pathway used by normal hematopoietic stem cells. Transduction of primitive normal human hematopoietic cells with FAK splice variants induces a marked increase in their clonogenic activity and signaling via the Wnt5a-controlled canonical pathway. Targeting FAK or ß-catenin efficiently eradicates primitive leukemic cells in vitro suggesting that FAK could be a useful therapeutic target for improved treatment of poor prognosis AML cases.

Organization and post-transcriptional processing of focal adhesion kinase gene.

BACKGROUND: Focal adhesion kinase (FAK) is a non-receptor tyrosine kinase critical for processes ranging from embryo development to cancer progression. Although isoforms with specific molecular and functional properties have been characterized in rodents and chicken, the organization of FAK gene throughout phylogeny and its potential to generate multiple isoforms are not well understood. Here, we study the phylogeny of FAK, the organization of its gene, and its post-transcriptional processing in rodents and human. RESULTS: A single orthologue of FAK and the related PYK2 was found in non-vertebrate species. Gene duplication probably occurred in deuterostomes after the echinoderma embranchment, leading to the evolution of PYK2 with distinct properties. The amino acid sequence of FAK and PYK2 is conserved in their functional domains but not in their linker regions, with the absence of autophosphorylation site in C. elegans. Comparison of mouse and human FAK genes revealed the existence of multiple combinations of conserved and non-conserved 5'-untranslated exons in FAK transcripts suggesting a complex regulation of their expression. Four alternatively spliced coding exons (13, 14, 16, and 31), previously described in rodents, are highly conserved in vertebrates. Cis-regulatory elements known to regulate alternative splicing were found in conserved alternative exons of FAK or in the flanking introns. In contrast, other reported human variant exons were restricted to Homo sapiens, and, in some cases, other primates. Several of these non-conserved exons may correspond to transposable elements. The inclusion of conserved alternative exons was examined by RT-PCR in mouse and human brain during development. Inclusion of exons 14 and 16 peaked at the end of embryonic life, whereas inclusion of exon 13 increased steadily until adulthood. Study of various tissues showed that inclusion of these exons also occurred, independently from each other, in a tissue-specific fashion. CONCLUSION: The alternative coding exons 13, 14, 16, and 31 are highly conserved in vertebrates and their inclusion in mRNA is tightly but independently regulated. These exons may therefore be crucial for FAK function in specific tissues or during development. Conversely pathological disturbance of the expression of FAK and of its isoforms could lead to abnormal cellular regulation.

[Neuronal isoforms of Src, Fyn and Lck tyrosine kinases: A specific role for p56lckN in neuron protection]. / Les isoformes neuronales des tyrosines kinases Src, Fyn et Lck : rôle particulier de la p56lckN dans la survie neuronale.

The two main tyrosine kinases (TK) in the brain are p60Src and p59Fyn, expressed as specific isoforms (p60SrcNI, p60SrcNI+NII and p59fynB). They play a pivotal role in some major processes such as neuronal growth and myelinisation. Another member of this TK family was then reported in brain, the p56lck. Its name Lck (lymphocyte cell kinase) indicates its cellular specificity observed initially, so its presence in the brain was intriguing. But no further studies were performed to understand its role in brain until recent clinical studies on Alzheimer patients' brains. One study reveals a decreased p56lck level in the brains of these patients while another study shows an association between one peculiar SNP (single nucleotide polymorphism) of the lck gene and some cases of the disease. These new data prompt us to reinvestigate the original biochemical data and to confront them with the present knowledge. This analysis suggests some hypothesis concerning both the Lck protein expressed in the brain (rather an isoform than the lymphocyte protein itself) and its role (to maintain the neuronal survival presumably by protecting them from inflammation, the main pathway that leads to neuron degeneracy).

[Expression of the p56lck by colon tumors: a marker of their invasive capacity?]. / Expression de la p56lck par les tumeurs du côlon: un marqueur de leur potentiel invasif?

Since its discovery in murine thymoma in 1982, the p56lck (lymphocyte cellular kinase) has been shown to be a pivotal enzyme to both maturation of thymocytes and activation and proliferation of peripheral lymphocytes. The p56lck sequence appeared highly homologous to that of the oncogene p60c-src as did its exon-intron organisation. These data have suggested the lck gene originates from the ancestral src gene by the exon-shuffling mechanism. However, and in spite of this relationship with the p60src oncogene which is often implicated in human cancers, p56lck does not appear involved in lymphoproliferative diseases, either by overexpression or activating mutations. Nevertheless, its aberrant expression has been reported in some carcinomas (colon, lung and mammary). This unexpected expression of a lymphoid-specific protein in solid tumors remained enigmatic until recent studies. In this review, we report these data and explain the possible mechanisms which could lead to the p56lck ectopic expression. We also discuss of signalling pathways which could be affected by the abnormal presence of the p56lck in these tumoral epithelial cells. In particular, we indicate that p56lck could favor metastases by facilitating loss of cell adhesion.