Ward Sents

STALK CELL PHENOTYPE DEPENDS ON INTEGRATION OF NOTCH AND SMAD1/5 SIGNALING CASCADES

Gradients of vascular endothelial growth factor (VEGF) induce single endothelial cells to become leading tip cells of emerging angiogenic sprouts. Tip cells then suppress tip-cell features in adjacent stalk cells via Dll4/Notch-mediated lateral inhibition. We report here that Smad1/Smad5-mediated BMP signaling synergizes with Notch signaling during selection of tip and stalk cells. Endothelium-specific inactivation of Smad1/Smad5 in mouse embryos results in impaired Dll4/Notch signaling and increased numbers of tip-cell-like cells at the expense of stalk cells. Smad1/5 downregulation in cultured endothelial cells reduced the expression of several target genes of Notch and of other stalk-cell-enriched transcripts (Hes1, Hey1, Jagged1, VEGFR1, and Id1-3). Moreover, Id proteins act as competence factors for stalk cells and form complexes with Hes1, which augment Hes1 levels in the endothelium. Our findings provide in vivo evidence for a regulatory loop between BMP/TGFβ-Smad1/5 and Notch signaling that orchestrates tip- versus stalk-cell selection and vessel plasticity.

The biogenesis of active protein phosphatase 2A holoenzymes: a tightly regulated process creating phosphatase specificity

Protein phosphatase type 2A (PP2A) enzymes constitute a large family of Ser/Thr phosphatases with multiple functions in cellular signaling and physiology. The composition of heterotrimeric PP2A holoenzymes, resulting from the combinatorial assembly of a catalytic C subunit, a structural A subunit, and regulatory B‐type subunit, provides the essential determinants for substrate specificity, subcellular targeting, and fine‐tuning of phosphatase activity, largely explaining why PP2A is functionally involved in so many diverse physiological processes, sometimes in seemingly opposing ways. In this review, we highlight how PP2A holoenzyme biogenesis and enzymatic activity are controlled by a sophisticatedly coordinated network of five PP2A modulators, consisting of α4, phosphatase 2A phosphatase activator (PTPA), leucine carboxyl methyl transferase 1 (LCMT1), PP2A methyl esterase 1 (PME‐1) and, potentially, target of rapamycin signaling pathway regulator‐like 1 (TIPRL1), which serve to prevent promiscuous phosphatase activity until the holoenzyme is completely assembled. Likewise, these modulators may come into play when PP2A holoenzymes are disassembled following particular cellular stresses. Malfunctioning of these cellular control mechanisms contributes to human disease. The potential therapeutic benefits or pitfalls of interfering with these regulatory mechanisms will be briefly discussed.

Mice lacking phosphatase PP2A subunit PR61/B’δ (Ppp2r5d) develop spatially restricted tauopathy by deregulation of CDK5 and GSK3β

Functional diversity of protein phosphatase 2A (PP2A) enzymes mainly results from their association with distinct regulatory subunits. To analyze the functions of one such holoenzyme in vivo, we generated mice lacking PR61/B’δ (B56δ), a subunit highly expressed in neural tissues. In PR61/B’δ-null mice the microtubule-associated protein tau becomes progressively phosphorylated at pathological epitopes in restricted brain areas, with marked immunoreactivity for the misfolded MC1-conformation but without neurofibrillary tangle formation. Behavioral tests indicated impaired sensorimotor but normal cognitive functions. These phenotypical characteristics were further underscored in PR61/B’δ-null mice mildly overexpressing human tau. PR61/B’δ-containing PP2A (PP2AT61δ) poorly dephosphorylates tau in vitro, arguing against a direct dephosphorylation defect. Rather, the activity of glycogen synthase kinase-3β, a major tau kinase, was found increased, with decreased phosphorylation of Ser-9, a putative cyclin-dependent kinase 5 (CDK5) target. Accordingly, CDK5 activity is decreased, and its cellular activator p35, strikingly absent in the affected brain areas. As opposed to tau, p35 is an excellent PP2AT61δ substrate. Our data imply a nonredundant function for PR61/B’δ in phospho-tau homeostasis via an unexpected spatially restricted mechanism preventing p35 hyperphosphorylation and its subsequent degradation.

Structure, regulation, and pharmacological modulation of PP2A phosphatases.

Protein phosphatases of the type 2A family (PP2A) represent a major fraction of cellular Ser/Thr phosphatase activity in any given human tissue. In this review, we describe how the holoenzymic nature of PP2A and the existence of several distinct PP2A composing subunits allow for the generation of multiple structurally and functionally different PP2A complexes, explaining why PP2A is involved in the regulation of so many diverse cell biological and physiological processes. Moreover, in human disease, most notably in several cancers and Alzheimers Disease, PP2A expression and/or activity have been found significantly decreased, underscoring its important functions as a major tumor suppressor and tau phosphatase. Hence, several recent preclinical studies have demonstrated that pharmacological restoration of PP2A activity, as well as pharmacological PP2A inhibition, under certain conditions, may be of significant future therapeutic value.

The Basic Biology of PP2A in Hematologic Cells and Malignancies

Reversible protein phosphorylation plays a crucial role in regulating cell signaling. In normal cells, phosphoregulation is tightly controlled by a network of protein kinases counterbalanced by several protein phosphatases. Deregulation of this delicate balance is widely recognized as a central mechanism by which cells escape external and internal self-limiting signals, eventually resulting in malignant transformation. A large fraction of hematologic malignancies is characterized by constitutive or unrestrained activation of oncogenic kinases. This is in part achieved by activating mutations, chromosomal rearrangements, or constitutive activation of upstream kinase regulators, in part by inactivation of their anti-oncogenic phosphatase counterparts. Protein phosphatase 2A (PP2A) represents a large family of cellular serine/threonine phosphatases with suspected tumor suppressive functions. In this review, we highlight our current knowledge about the complex structure and biology of these phosphatases in hematologic cells, thereby providing the rationale behind their diverse signaling functions. Eventually, this basic knowledge is a key to truly understand the tumor suppressive role of PP2A in leukemogenesis and to allow further rational development of therapeutic strategies targeting PP2A.

PP2A Inactivation Mediated by PPP2R4 Haploinsufficiency Promotes Cancer Development

Protein phosphatase 2A (PP2A) complexes counteract many oncogenic kinase pathways. In cancer cells, PP2A function can be compromised by several mechanisms, including sporadic mutations in its scaffolding A and regulatory B subunits or more frequently through overexpression of cellular PP2A inhibitors. Here, we identify a novel genetic mechanism by which PP2A function is recurrently affected in human cancer, involving haploinsufficiency of PPP2R4, a gene encoding the cellular PP2A activator PTPA. Notably, up to 70% of cancer patients showed a heterozygous deletion or missense mutations in PPP2R4 Cancer-associated PTPA mutants exhibited decreased abilities to bind the PP2A-C subunit or activate PP2A and failed to reverse the tumorigenic phenotype induced by PTPA suppression, indicating they function as null alleles. In Ppp2r4 gene-trapped (gt) mice showing residual PTPA expression, total PP2A activity and methylation were reduced, selectively affecting specific PP2A holoenzymes. Both PTPAgt/gt and PTPA+/gt mice showed higher rates of spontaneous tumors, mainly hematologic malignancies and hepatocellular adenomas and carcinomas. These tumors exhibited increased c-Myc phosphorylation and increased Wnt or Hedgehog signaling. We observed a significant reduction in lifespan in PTPA+/gt mice compared with wild-type mice. In addition, chemical-induced skin carcinogenesis was accelerated in PTPA+/gt compared with wild-type mice. Our results provide evidence for PPP2R4 as a haploinsufficient tumor suppressor gene, defining a high-penetrance genetic mechanism for PP2A inhibition in human cancer. Cancer Res; 77(24); 6825-37. ©2017 AACR.

Loss of protein phosphatase 2A regulatory subunit B56δ promotes spontaneous tumorigenesis in vivo

Protein Phosphatase 2A (PP2A) enzymes counteract diverse kinase-driven oncogenic pathways and their function is frequently impaired in cancer. PP2A inhibition is indispensable for full transformation of human cells, but whether loss of PP2A is sufficient for tumorigenesis in vivo has remained elusive. Here, we describe spontaneous tumor development in knockout mice for Ppp2r5d, encoding the PP2A regulatory B56δ subunit. Several primary tumors were observed, most commonly, hematologic malignancies and hepatocellular carcinomas (HCCs). Targeted immunoblot and immunohistochemistry analysis of the HCCs revealed heterogeneous activation of diverse oncogenic pathways known to be suppressed by PP2A-B56. RNA sequencing analysis unveiled, however, a common role for oncogenic c-Myc activation in the HCCs, independently underscored by c-Myc Ser62 hyperphosphorylation. Upstream of c-Myc, GSK-3β Ser9 hyperphosphorylation occurred both in the HCCs and non-cancerous B56δ-null livers. Thus, uncontrolled c-Myc activity due to B56δ-driven GSK-3β inactivation is the likely tumor predisposing factor. Our data provide the first compelling mouse genetics evidence sustaining the tumor suppressive activity of a single PP2A holoenzyme, constituting the final missing incentive for full clinical development of PP2A as cancer biomarker and therapy target.

13-P039 Endothelial specific Smad1 and Smad5 deficiency reveals a crutial role of BMP Smads in angiogenesis and lymphangiogenesis

Heparan sulfate (HS) proteoglycans comprising HS glycosaminoglycan chains (HS-chains) and core proteins function in the membrane and extracellular matrix (ECM) as co-receptors for growth factors; i.e., they modulate activity of signaling factors via controlling their extracellular stabilization and movement. However, precise mechanisms by which HS-chains regulate complex mammalian morphogenetic processes remain to be elucidated. This study demonstrated the pivotal roles played by HS-chains in spatio-temporal distribution of Fgf signaling in the mouse embryo. We identified the transgene insertion allele of Ext2 which catalyzes elongation of HS-chains. Ext2deficient embryos displayed early embryonic defects due to lack of HS-chains. Marker expression analyses indicated that HSchains are essential for response to Fgf signaling. Localization of FGF4, FGFR2, HS-chains and syndecan-1 during extraembryonic ectoderm development revealed that HS-chains control the FGF ligand distribution in target cells. Accordingly, HSchains expression is distinctively specific to those areas in which Fgf signaling is potentially active. Additional fine mosaic analyses with single cell resolution involving chimeras demonstrated that cell-autonomous or immediately adjoining expression of membrane-associated HS-chains is crucial for early embryonic development, supporting that HS-chains function in the distribution but not movement of FGF primarily. Given that 22 FGF ligands, 4 FGF receptors and 12 membrane-associated core proteins are redundantly expressed in the mouse embryo, we hypothesized that spatiallyand temporally-specific expression of Ext2-dependent HS-chains contribute to FGF distribution during mammalian morphogenesis, e.g., formation of morphogen gradients.