Shouchun Liu

R-Spondin Family Members Regulate the Wnt Pathway by a Common Mechanism

The R-Spondin (RSpo) family of secreted proteins is implicated in the activation of the Wnt signaling pathway. Despite the high structural homology between the four members, expression patterns and phenotypes in knockout mice have demonstrated striking differences. Here we dissected and compared the molecular and cellular function of all RSpo family members. Although all four RSpo proteins activate the canonical Wnt pathway, RSpo2 and 3 are more potent than RSpo1, whereas RSpo4 is relatively inactive. All RSpo members require Wnt ligands and LRP6 for activity and amplify signaling of Wnt3A, Wnt1, and Wnt7A, suggesting that RSpo proteins are general regulators of canonical Wnt signaling. Like RSpo1, RSpo2-4 antagonize DKK1 activity by interfering with DKK1 mediated LRP6 and Kremen association. Analysis of RSpo deletion mutants indicates that the cysteine-rich furin domains are sufficient and essential for the amplification of Wnt signaling and inhibition of DKK1, suggesting that Wnt amplification by RSpo proteins may be a direct consequence of DKK1 inhibition. Together, these findings indicate that RSpo proteins modulate the Wnt pathway by a common mechanism and suggest that coexpression with specific Wnt ligands and DKK1 may determine their biological specificity in vivo.

The First Propeller Domain of LRP6 Regulates Sensitivity to DKK1

The Wnt coreceptor LRP6 is required for canonical Wnt signaling. To understand the molecular regulation of LRP6 function, we generated a series of monoclonal antibodies against the extra cellular domain (ECD) of LRP6 and selected a high-affinity mAb (mAb135) that recognizes cell surface expression of endogenous LRP6. mAb135 enhanced Wnt dependent TCF reporter activation and antagonized DKK1 dependent inhibition of Wnt3A signaling, suggesting a role in modulation of LRP6 function. Detailed analysis of LRP6 domain mutants identified Ser 243 in the first propeller domain of LRP6 as a critical residue for mAb135 binding, implicating this domain in regulating the sensitivity of LRP6 to DKK1. In agreement with this notion, mAb135 directly disrupted the interaction of DKK1 with recombinant ECD LRP6 and a truncated form of the LRP6 ECD containing only repeats 1 and 2. Finally, we found that mAb135 completely protected LRP6 from DKK1 dependent internalization. Together, these results identify the first propeller domain as a novel regulatory domain for DKK1 binding to LRP6 and show that mAb against the first propeller domain of LRP6 can be used to modulate this interaction.

Alfimeprase: a novel recombinant direct-acting fibrinolytic

Alfimeprase is a recombinant, direct-acting fibrinolytic zinc metalloprotease. Alfimeprase has direct proteolytic activity primarily against the fibrin(ogen) Aα chain. Alfimeprase is covalently bound and neutralised by serum α2-macroglobulin, a prevalent mammalian protease inhibitor. Preclinical pharmacology studies have shown that fibrinolysis with alfimeprase is up to sixfold more rapid than with select plasminogen activators, such as tissue-type plasminogen activator and urokinase. Alfimeprase directly delivered to a site of thrombosis has the potential to be a fast and effective fibrinolytic, which does not generate the systemic lytic state seen with plasminogen activators that is associated with major bleeding, including intracerebral haemorrhage. Phase I and II studies in individuals with arterial or venous thrombotic events indicate that alfimeprase is active and generally well tolerated.

Monoclonal antibodies against IREM-1: potential for targeted therapy of AML

IREM-1 is an inhibitory cell surface receptor with an unknown function and is expressed on myeloid cell lineages, including cell lines derived from acute myeloid leukemia (AML) patients. We have generated a series of monoclonal antibodies (mAbs) against the extracellular domain of IREM-1 and further assessed its expression in normal and AML cells. IREM-1 was restricted to cells from myeloid origin and extensive expression analysis in primary cells obtained from AML patients showed IREM-1 expression in leukemic blasts of 72% (39/54) of samples. We therefore searched for specific IREM-1 mAbs with activity in functional complement-dependent cytotoxicity (CDC) and antibody-dependent cellular cytotoxicity (ADCC). Lead mAbs against IREM-1 showed specific cytotoxic activity against a variety of AML-derived cell lines and freshly isolated blasts from AML patients. Internalization of mAbs upon IREM-1 binding was also shown. In vivo anticancer activity of lead mAbs was observed in an established HL-60 xenograft model with a tumor growth delay of up to 40% and in a model using primary human AML cells, where treatment with anti-IREM-1 mAb resulted in a significant reduction of engrafted human cells. These results demonstrate IREM-1 as a potential novel target for immunotherapy of AML.

The lymphoid cell surface receptor NTB-A: a novel monoclonal antibody target for leukaemia and lymphoma therapeutics

NTB‐A is a CD2‐related cell surface protein expressed primarily on lymphoid cells including B‐lymphocytes from chronic lymphocytic leukaemia (CLL) and lymphoma patients. We have generated a series of monoclonal antibodies (mAbs) against NTB‐A and assessed their therapeutic potential for CLL. Selective mAbs to NTB‐A were further tested in functional complement‐dependent cytotoxicity (CDC) and antibody‐dependent cellular cytotoxicty (ADCC) assays in cell lines and B lymphocytes freshly isolated from CLL patients. While lower levels of NTB‐A were detected in T and natural killer (NK) cells, CDC activity was demonstrated primarily in B cells isolated from CLL patients and B lymphoma cell lines. Knockdown of NTB‐A by small interfering RNA in target cells results in lower cytotoxicity, demonstrating the specificity of the mAbs. Furthermore, anti NTB‐A mAbs demonstrated anti‐tumour activity against CA46 human lymphoma xenografts in nude mice and against systemically disseminated Raji human lymphoma cells in severe combined immunodeficient mice. Taken together, these results demonstrate NTB‐A as a potential new target for immunotherapy of leukaemia and lymphomas.

Abstract C165: Development of a probody drug conjugate (PDC) against CD166 for the treatment of multiple cancers

Antibody drug conjugates (ADCs) have shown their greatest clinical utility when targeting antigens expressed at very high levels on cancer cells that have coincidentally lower expression in normal tissues. This is exemplified by the approvals of trastuzumab emtansine for her2neu 3+ breast cancer and brentuximab vedotin for Hodgkins Disease and Anaplastic large-cell lymphoma. Both drugs are approved for subsets of specific cancer types where target antigen expression is particularly high relative to expression in normal tissues. There are other cell surface antigens that are highly expressed on cancer cells and normal tissues, but the utility of such antigens as ADC targets is restricted by their corresponding expression in normal tissues. One such target is CD166 (ALCAM), which shows 3+ expression by IHC in most donors of multiple cancer types, e.g., ca. 70% prevalence in breast, prostate, and lung cancers but also expression in multiple normal tissues including lung, GI tissues, and liver. Thus CD166 has not been progressed as a target for ADCs. Probody™ therapeutics are fully recombinant antibody prodrugs that are converted to active antibodies by tumor-associated proteases. Preclinical in vivo studies show that Probody therapeutics remain substantially inactive in normal tissues and in circulation. As such, Probody drug conjugates (PDCs), unlike ADCs, enable targeting of high expression tumor targets that are also expressed in normal tissues. We have developed an anti-CD166 Probody therapeutic selected for specific binding, internalization, and cross reactivity to cynomolgus macaque as a species for toxicology assessments. This therapeutic has been conjugated to spdb-DM4 and tested in preclinical models of efficacy and safety. Treatment with the PDC has led to complete regressions in models of lung and breast cancer at therapeutically relevant doses. These same doses were assessed for safety in cynomolgus monkeys. The safety and efficacy profiles for the anti-CD166 PDC are supportive of progression to clinical development of this anti-CD166 Probody drug conjugate. Citation Format: Annie Yang Weaver, Shweta Singh, Amy DuPage, Jason Sagert, Jeanne Flandez, Elizabeth Menendez, Judi Ford, Michael Krimm, Stephen Moore, Margaret Nguyen, Andrew Jang, Eric Brecht, Yuanhui Huang, Linnea Diep, Nicole Lapuyade, Tereza Sputova, James West, Olga Vasiljeva, Shouchun Liu, Jennifer Richardson, W. Michael Kavanaugh, Jonathan A. Terrett, Luc R. Desnoyers. Development of a probody drug conjugate (PDC) against CD166 for the treatment of multiple cancers. [abstract]. In: Proceedings of the AACR-NCI-EORTC International Conference: Molecular Targets and Cancer Therapeutics; 2015 Nov 5-9; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2015;14(12 Suppl 2):Abstract nr C165.

Abstract 2975: Development of a probody drug conjugate (PDC) targeting CD71 for the treatment of solid tumors and lymphomas

The targets of Antibody Drug Conjugates (ADCs) have typically been selected by identifying transmembrane antigens that are highly expressed in tumors but are low or absent in normal tissues. The number of potential ADC targets meeting these requirements is limited, either because expression in tumors is not high enough for optimal efficacy, or because expression in normal tissues is too high, leading to toxicity. Probody (TM) therapeutics are antibody prodrugs designed to remain inactive until proteolytically activated in the tumor microenvironment. Probody technology therefore has the potential to enable targeting of more desirable tumor antigens with higher, more persistent and more homogeneous expression in tumors, while limiting toxicity due to interaction with these antigens in normal tissues. CD71 (transferrin receptor) is an example of a highly desirable ADC target, because of its well-characterized ability to efficiently internalize and deliver an ADC payload intracellularly. Further, CD71 is expressed at homogeneously high levels (3+ expression by IHC) in almost all tumor types, including in metastatic disease. However, because CD71 is also expressed on multiple normal cell types, including many progenitor hematological cells, we reasoned that a CD71-targeted ADC would be challenging to develop. To enable targeting of CD71, we have developed an anti-CD71 Probody Drug Conjugate (PDC) CX-2005, which can be activated by multiple proteases in the tumor microenvironment, but which remains in a relatively inactive form while in circulation and in normal tissues. CX-2005 produces complete tumor regressions at therapeutic doses in mouse models of lymphoma, breast cancer and lung cancer. Consistent with our hypothesis that it would be difficult to develop an anti-CD71 ADC, treatment of cynomolgus monkeys with an anti-CD71 ADC at doses that were efficacious in mouse tumor models caused life-threatening depletion of CD71-expressing hematopoietic cells, including neutrophils, lymphocytes and RBCs. In contrast, these toxicities were not observed in monkeys treated with the same dose of the anti-CD71 PDC, consistent with the Probody therapeutic avoiding interaction with these normal cells. Our data demonstrate that, in preclinical studies, Probody drug conjugates can safely and effectively target attractive tumor antigens like CD71 which have been difficult to effectively approach with traditional ADCs due to their expression on critical normal tissues. Further, our data support the development of Probody therapeutics directed against CD71 in multiple different cancers. PROBODY is a trademark of CytomX Therapeutics, Inc. Citation Format: Shweta Singh, Amy DuPage, Annie Yang Weaver, Jason Sagert, Clayton White, Michael Krimm, Yuanhui Huang, Linnea Diep, Kim Tipton, Shouchun Liu, Jennifer Richardson, W. Michael Kavanaugh, Jonathan A. Terrett, Luc R. Desnoyers. Development of a probody drug conjugate (PDC) targeting CD71 for the treatment of solid tumors and lymphomas. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 2975.