Abelson kinase's intrinsically disordered region plays essential roles in protein function and protein stability.

BACKGROUND: The non-receptor tyrosine kinase Abelson (Abl) is a key player in oncogenesis, with kinase inhibitors serving as paradigms of targeted therapy. Abl also is a critical regulator of normal development, playing conserved roles in regulating cell behavior, brain development and morphogenesis. Drosophila offers a superb model for studying Abl's normal function, because, unlike mammals, there is only a single fly Abl family member. In exploring the mechanism of action of multi-domain scaffolding proteins like Abl, one route is to define the roles of their individual domains. Research into Abl's diverse roles in embryonic morphogenesis revealed many surprises. For instance, kinase activity, while important, is not crucial for all Abl activities, and the C-terminal F-actin binding domain plays a very modest role. This turned our attention to one of Abl's least understood features-the long intrinsically-disordered region (IDR) linking Abl's kinase and F-actin binding domains. The past decade revealed unexpected, important roles for IDRs in diverse cell functions, as sites of posttranslational modifications, mediating multivalent interactions and enabling assembly of biomolecular condensates via phase separation. Previous work deleting conserved regions in Abl's IDR revealed an important role for a PXXP motif, but did not identify any other essential regions. METHODS: Here we extend this analysis by deleting the entire IDR, and asking whether Abl∆IDR rescues the diverse roles of Abl in viability and embryonic morphogenesis in Drosophila. RESULTS: This revealed that the IDR is essential for embryonic and adult viability, and for cell shape changes and cytoskeletal regulation during embryonic morphogenesis, and, most surprisingly, revealed a role in modulating protein stability. CONCLUSION: Our data provide new insights into the role of the IDR in an important signaling protein, the non-receptor kinase Abl, suggesting that it is essential for all aspects of protein function during embryogenesis, and revealing a role in protein stability. These data will stimulate new explorations of the mechanisms by which the IDR regulates Abl stability and function, both in Drosophila and also in mammals. They also will stimulate further interest in the broader roles IDRs play in diverse signaling proteins. Video Abstract.

Abelson kinase acts as a robust, multifunctional scaffold in regulating embryonic morphogenesis.

Abelson family kinases (Abls) are key regulators of cell behavior and the cytoskeleton during development and in leukemia. Abl's SH3, SH2, and tyrosine kinase domains are joined via a linker to an F-actin-binding domain (FABD). Research on Abl's roles in cell culture led to several hypotheses for its mechanism of action: 1) Abl phosphorylates other proteins, modulating their activity, 2) Abl directly regulates the cytoskeleton via its cytoskeletal interaction domains, and/or 3) Abl is a scaffold for a signaling complex. The importance of these roles during normal development remains untested. We tested these mechanistic hypotheses during Drosophila morphogenesis using a series of mutants to examine Abl's many cell biological roles. Strikingly, Abl lacking the FABD fully rescued morphogenesis, cell shape change, actin regulation, and viability, whereas kinase-dead Abl, although reduced in function, retained substantial rescuing ability in some but not all Abl functions. We also tested the function of four conserved motifs in the linker region, revealing a key role for a conserved PXXP motif known to bind Crk and Abi. We propose that Abl acts as a robust multidomain scaffold with different protein motifs and activities contributing differentially to diverse cellular behaviors.

Dysregulation of autoantigen genes in ANCA-associated vasculitis involves alternative transcripts and new protein synthesis.

Proteinase 3 (PR3) and myeloperoxidase (MPO) are two major autoantigens in patients with vasculitis with ANCA. The genes encoding these autoantigens are abnormally expressed in peripheral granulocytes of patients with active ANCA-associated vasculitis. This study provides evidence that this transcriptional dysregulation results in a variety of mRNA processing events from the PRTN3 gene locus. In addition to elevated levels of PR3 message, leukocyte RNA from patients contained PR3 transcripts with an alternative 3' untranslated region. Furthermore, we detected usage of an alternative transcription start site within intron 1 of the PRTN3 gene locus that coincided with active disease (odds ratio, 3.3; 95% confidence interval, 1.3 to 8.4; P=0.01). This promoter may be developmentally regulated, because it was active in normal human bone marrow, multiple leukemia cell lines, MCF-7 cells, and subjects after GM-CSF treatment but not subjects with a neutrophil left shift. This transcript, which lacks exon 1 of PRTN3, encodes a 24-kD protein (p24(PR3/MBN)) with a sequence similar to that previously described for myeloblastin. Notably, PR3, p24(PR3/MBN), and MPO were synthesized in cultured neutrophils from patients with active ANCA-associated vasculitis, indicating that increased transcription results in newly synthesized autoantigens in peripheral neutrophils of patients. The synthesis of p24(PR3/MBN) seems to expand the autoantigen repertoire, because immunoblots showed that sera from patients recognized p24(PR3/MBN). These findings emphasize the importance of transcriptional dysregulation of the autoantigen in autoimmune disease.