Johanna I. Partanen

A novel endothelial cell surface receptor tyrosine kinase with extracellular epidermal growth factor homology domains.

Endothelial cell surfaces play key roles in several important physiological and pathological processes such as blood clotting, angiogenic responses, and inflammation. Here we describe the cloning and characterization of tie, a novel type of human endothelial cell surface receptor tyrosine kinase. The extracellular domain of the predicted tie protein product has an exceptional multidomain structure consisting of a cluster of three epidermal growth factor homology motifs embedded between two immunoglobulinlike loops, which are followed by three fibronectin type III repeats next to the transmembrane region. Additionally, a cDNA form lacking the first of the three epidermal growth factor homology domains was isolated, suggesting that alternative splicing creates different tie-type receptors. Cells transfected with tie cDNA expression vector produce glycosylated polypeptides of 117 kDa which are reactive to antisera raised against the tie carboxy terminus. The tie gene was located in chromosomal region 1p33 to 1p34. Expression of the tie gene appeared to be restricted in some cell lines; large amounts of tie mRNA were detected in endothelial cell lines and in some myeloid leukemia cell lines with erythroid and megakaryoblastoid characteristics. In addition, mRNA in situ studies further indicated the endothelial expression of the tie gene. The tie receptor tyrosine kinase may have evolved for multiple protein-protein interactions, possibly including cell adhesion to the vascular endothelium.

Fibroblast growth factor receptor-4 shows novel features in genomic structure, ligand binding and signal transduction.

Fibroblast growth factor (FGF) receptor (FGFR) gene family consists of at least four receptor tyrosine kinases that transduce signals important in a variety of developmental and physiological processes related to cell growth and differentiation. Here we have characterized the binding of different FGFs to FGFR‐4. Our results establish an FGF binding profile for FGFR‐4 with aFGF having the highest affinity, followed by K‐FGF/hst‐1 and bFGF. In addition, FGF‐6 was found to bind to FGFR‐4 in ligand competition experiments. Interestingly, the FGFR‐4 gene was found to encode only the prototype receptor in a region where both FGFR‐1 and FGFR‐2 show alternative splicing leading to differences in their ligand binding specificities and to secreted forms of these receptors. Ligands binding to FGFR‐4 induced receptor autophosphorylation and phosphorylation of a set of cellular polypeptides, which differed from those phosphorylated in FGFR‐1‐expressing cells. Specifically, the FGFR‐1‐expressing cells showed a considerably more extensive tyrosine phosphorylation of PLC‐gamma than the FGFR‐4‐expressing cells. Structural and functional specificity within the FGFR family exemplified by FGFR‐4 may help to explain how FGFs perform their diverse functions.

Suppression of oncogenic properties of c-Myc by LKB1-controlled epithelial organization

Cellular organization into epithelial architecture maintains structural integrity and homeostasis by suppressing cell proliferation and apoptosis. However, it is unclear whether the epithelial organization is sufficient to block induction of cell-autonomous cell cycle progression and apoptotic sensitivity by activated oncogenes. We show that chronic activation of oncogenic c-Myc, starting in the developing 3D organotypic mammary acinar structures, results in hyperproliferation and transformed acinar morphology. Surprisingly, acute c-Myc activation in mature quiescent acini with established epithelial architecture fails to reinitiate the cell cycle or transform these structures. c-Myc does reinitiate the cell cycle in quiescent, but structurally unorganized, acini, which demonstrates that proper epithelial architecture is needed for the proliferation blockade. The capability of c-Myc to reinitiate the cell cycle in acinar structures is also restored by the loss of LKB1, a human homologue of the cell polarity protein PAR4. The epithelial architecture also restrains the apoptotic activity of c-Myc, but coactivation of c-Myc and a complementary TNF-related apoptosis-inducing ligand death receptor pathway can induce a strong Bim and Bid-mediated apoptotic response in the established acini. The results together expose surprising proliferation and apoptosis resistance of organized epithelial structures and identify a role for the polarity regulator LKB1 in the development of c–Myc-resistant cell organization.

Tumor suppressor function of Liver kinase B1 (Lkb1) is linked to regulation of epithelial integrity

Although loss of epithelial integrity is a hallmark of advanced cancer, it remains poorly understood whether genetic alterations corrupting this integrity causally facilitate tumorigenesis. We show that conditional deletion of tumor suppressor gene Lkb1 (Par-4) in the mammary gland compromises epithelial integrity manifested by mislocalization of cell polarity markers, lateralization of tight junctions, deterioration of desmosomes and basement membrane (BM), and hyperbranching of the mammary ductal tree. We identify the desmosomal BM remodelling serine protease Hepsin as a key factor mediating Lkb1 loss-induced structural alterations in mammary epithelium and BM fragmentation. Although loss of Lkb1 alone does not promote mammary tumorigenesis, combination of Lkb1 deficiency with oncogenic c-Myc leads to dramatic acceleration in tumor formation. The results coupling Lkb1 loss-mediated epithelial integrity defects to mislocalization of serine protease Hepsin and to oncogenic synergy with c-Myc imply that Lkb1 loss facilitates oncogenic proliferation by releasing epithelial cells from structural BM boundaries.

Myc-induced AMPK-phospho p53 pathway activates Bak to sensitize mitochondrial apoptosis

Oncogenic transcription factor Myc deregulates the cell cycle and simultaneously reprograms cellular metabolism to meet the biosynthetic and bioenergetic needs of proliferation. Myc also sensitizes cells to mitochondria-dependent apoptosis. Although metabolic reprogramming has been circumstantially connected to vulnerability to apoptosis, the connecting molecular pathways have remained poorly defined. Here, we show that Myc-induced altered glutamine metabolism involves ATP depletion and activation of the energy sensor AMP-activated protein kinase (AMPK), which induces stabilizing phosphorylation of p53 at Ser15. Under influence of Myc, AMPK-stabilized tumor suppressor protein p53 accumulates in the mitochondria and interacts with the protein complex comprised of B-cell lymphoma 2 (Bcl-2) antagonist/killer (BAK) and Bcl2-like 1 (Bcl-xL). Mitochondrial p53 induces conformational activation of proapoptotic Bak without disrupting the Bak–Bcl-xL interaction. Further liberation of Bak specifically from the p53-activated Bak–Bcl-xL complex leads to spontaneous oligomerization of Bak and apoptosis. Thus, Myc-induced metabolic changes are coupled via AMPK and phospho-p53 to the mitochondrial apoptosis effector Bak, demonstrating a cell-intrinsic mechanism to counteract uncontrolled proliferation.

c-Myc primed mitochondria determine cellular sensitivity to TRAIL-induced apoptosis

Oncogenic c‐Myc renders cells sensitive to TRAIL‐induced apoptosis, and existing data suggest that c‐Myc sensitizes cells to apoptosis by promoting activation of the mitochondrial apoptosis pathway. However, the molecular mechanisms linking the mitochondrial effects of c‐Myc to the c‐Myc‐dependent sensitization to TRAIL have remained unresolved. Here, we show that TRAIL induces a weak activation of procaspase‐8 but fails to activate mitochondrial proapoptotic effectors Bax and Bak, cytochrome c release or downstream effector caspase‐3 in non‐transformed human fibroblasts or mammary epithelial cells. Our data is consistent with the model that activation of oncogenic c‐Myc primes mitochondria through a mechanism involving activation of Bak and this priming enables weak TRAIL‐induced caspase‐8 signals to activate Bax. This results in cytochrome c release, activation of downstream caspases and postmitochondrial death‐inducing signaling complex ‐independent augmentation of caspase‐8‐Bid activity. In conclusion, c‐Myc‐dependent priming of the mitochondrial pathway is critical for the capacity of TRAIL‐induced caspase‐8 signals to activate effector caspases and for the establishment of lethal caspase feedback amplification loop in human cells.

c-Myc Blazing a Trail of Death: Coupling of the Mitochondrial and Death Receptor Apoptosis Pathways by c-Myc

TRAIL ligand induces selectively apoptosis in tumor cells by binding to two death receptors (DR4 and DR5) and holds promise as a potential therapeutic agent against cancer. While it has been known for long time that TRAIL receptors are commonly expressed in wide variety of normal tissues, it is not well understood why TRAIL kills tumor cells but leaves normal cells unharmed. The prototypic oncogene c-Myc promotes the cell cycle and simultaneously primes activation of the Bcl-2 family controlled mitochondria apoptosis pathway. A striking reflection of the c-Myc-dependent apoptotic sensitization is the dramatic c-Myc-induced vulnerability of cells to TRAIL and other death receptor ligands. Here we summarize the recent findings regarding the death mechanisms of TRAIL/TRAIL receptor system and the connection of c-Myc to the mitochondrial apoptosis pathway, focusing on our work that couples c-Myc via Bak to the TRAIL death receptor pathway. Finally, we present a mitochondria-priming model to explain how c-Myc-Bak interaction amplifies the TRAIL-induced caspase 8-Bid pathway to induce fullblown apoptosis. We discuss the implications of these findings for understanding the selective cytotoxicity of TRAIL and for the therapeutic exploitation of the death receptor pathway.

3D view to tumor suppression: Lkb1, polarity and the arrest of oncogenic c-Myc.

Machiavelli wrote, in his famous political treatise Il Principe, about disrupting organization by planting seeds of dissension or by eliminating necessary support elements. Tumor cells do exactly that by disrupting the organized architecture of epithelial cell layers during progression from contained benign tumor to full-blown invasive cancer. However, it is still unclear whether tumor cells primarily break free by activating oncogenes powerful enough to cause chaos or by eliminating tumor suppressor genes guarding the order of the epithelial organization. Studies in Drosophila have exposed genes that encode key regulators of the epithelial apicobasal polarity and which, upon inactivation, cause disorganization of the epithelial layers and promote unscheduled cell proliferation. These polarity regulator/tumor suppressor proteins, which include products of neoplastic tumor suppressor genes (nTSGs), are carefully positioned in polarized epithelial cells to maintain the order of epithelial structures and to impose a restraint on cell proliferation. In this review, we have explored the presence and prevalence of somatic mutations in the human counterparts of Drosophila polarity regulator/tumor suppressor genes across the human cancers. The screen points out LKB1, which is a causal genetic lesion in Peutz-Jeghers cancer syndrome, a gene mutated in certain sporadic cancers and a human homologue of the fly polarity gene par-4. We review the evidence linking Lkb1 to polarity regulation in the scope of our recent results suggesting a coupled role for Lkb1 as an architect of organized acinar structures and a suppressor of oncogenic c-Myc. We finally present models to explain how Lkb1-dependent formation of epithelial architecture is coupled to suppression of normal and oncogene-induced proliferation.

Chk1 targeting reactivates PP2A tumor suppressor activity in cancer cells

Checkpoint kinase Chk1 is constitutively active in many cancer cell types and new generation Chk1 inhibitors show marked antitumor activity as single agents. Here we present a hitherto unrecognized mechanism that contributes to the response of cancer cells to Chk1-targeted therapy. Inhibiting chronic Chk1 activity in cancer cells induced the tumor suppressor activity of protein phosphatase protein phosphatase 2A (PP2A), which by dephosphorylating MYC serine 62, inhibited MYC activity and impaired cancer cell survival. Mechanistic investigations revealed that Chk1 inhibition activated PP2A by decreasing the transcription of cancerous inhibitor of PP2A (CIP2A), a chief inhibitor of PP2A activity. Inhibition of cancer cell clonogenicity by Chk1 inhibition could be rescued in vitro either by exogenous expression of CIP2A or by blocking the CIP2A-regulated PP2A complex. Chk1-mediated CIP2A regulation was extended in tumor models dependent on either Chk1 or CIP2A. The clinical relevance of CIP2A as a Chk1 effector protein was validated in several human cancer types, including neuroblastoma, where CIP2A was identified as an NMYC-independent prognostic factor. Because the Chk1-CIP2A-PP2A pathway is driven by DNA-PK activity, functioning regardless of p53 or ATM/ATR status, our results offer explanative power for understanding how Chk1 inhibitors mediate single-agent anticancer efficacy. Furthermore, they define CIP2A-PP2A status in cancer cells as a pharmacodynamic marker for their response to Chk1-targeted therapy.

Faulty epithelial polarity genes and cancer.

Epithelial architecture is formed in tissues and organs when groups of epithelial cells are organized into polarized structures. The epithelial function and integrity as well as signaling across the epithelial layer is orchestrated by apical junctional complexes (AJCs), which are landmarks for PAR/CRUMBS and lateral SCRIB polarity modules and by dynamic interactions of the cells with underlying basement membrane (BM). These highly organized epithelial architectures are demolished in cancer. In all advanced epithelial cancers, malignant cells have lost polarity and connections to the basement membrane and they have become proliferative, motile, and invasive. Clearly, loss of epithelial integrity associates with tumor progression but does it contribute to tumor development? Evidence from studies in Drosophila and recently also in vertebrate models have suggested that even the oncogene-driven enforced cell proliferation can be conditional, dependant on the influence of cell-cell or cell-microenvironment contacts. Therefore, loss of epithelial integrity may not only be an obligate consequence of unscheduled proliferation of malignant cells but instead, malignant epithelial cells may need to acquire capacity to break free from the constraints of integrity to freely and autonomously proliferate. We discuss how epithelial polarity complexes form and regulate epithelial integrity, highlighting the roles of enzymes Rho GTPases, aPKCs, PI3K, and type II transmembrane serine proteases (TTSPs). We also discuss relevance of these pathways to cancer in light of genetic alterations found in human cancers and review molecular pathways and potential pharmacological strategies to revert or selectively eradicate disorganized tumor epithelium.