Quantitation of TGF-ß proteins in mouse tissues shows reciprocal changes in TGF-ß1 and TGF-ß3 in normal vs neoplastic mammary epithelium.

Transforming growth factor-ßs (TGF-ßs) regulate tissue homeostasis, and their expression is perturbed in many diseases. The three isoforms (TGF-ß1, -ß2, and -ß3) have similar bioactivities in vitro but show distinct activities in vivo. Little quantitative information exists for expression of TGF-ß isoform proteins in physiology or disease. We developed an optimized method to quantitate protein levels of the three isoforms, using a Luminex® xMAP®-based multianalyte assay following acid-ethanol extraction of tissues. Analysis of multiple tissues and plasma from four strains of adult mice showed that TGF-ß1 is the predominant isoform with TGF-ß2 being ~10-fold lower. There were no sex-specific differences in isoform expression, but some tissues showed inter-strain variation, particularly for TGF-ß2. The only adult tissue expressing appreciable TGF-ß3 was the mammary gland, where its levels were comparable to TGF-ß1. In situ hybridization showed the luminal epithelium as the major source of all TGF-ß isoforms in the normal mammary gland. TGF-ß1 protein was 3-8-fold higher in three murine mammary tumor models than in normal mammary gland, while TGF-ß3 protein was 2-3-fold lower in tumors than normal tissue, suggesting reciprocal regulation of these isoforms in mammary tumorigenesis.

XOMA 052, an anti-IL-1ß monoclonal antibody, prevents IL-1ß-mediated insulin resistance in 3T3-L1 adipocytes.

OBJECTIVE: Interleukin-1ß (IL-1ß) has recently been implicated as a major cytokine that is involved in the pancreatic islet inflammation of type 2 diabetes mellitus. This inflammation impairs insulin secretion by inducing beta-cell apoptosis. Recent evidence has suggested that in obesity-induced inflammation, IL-1ß plays a key role in causing insulin resistance in peripheral tissues. DESIGN AND METHODS: To further investigate the pathophysiological role of IL-1ß in causing insulin resistance, the inhibitory effects of IL-1ß on several insulin-dependent metabolic processes in vitro has been neutralized by XOMA 052. The role IL-1ß plays in insulin resistance in adipose tissue was assessed using differentiated 3T3-L1 adipocytes and several parameters involved in insulin signaling and lipid metabolism were examined. RESULTS AND CONCLUSION: IL-1ß inhibited insulin-induced activation of Akt phosphorylation, glucose transport, and fatty acid uptake. IL-1ß also blocked insulin-mediated downregulation of suppressor of cytokine signaling-3 expression. Co-preincubation of IL-1ß with XOMA 052 neutralized nearly all of these inhibitory effects in 3T3-L1 adipocytes. These studies provide evidence, therefore, that IL-1ß is a key proinflammatory cytokine that is involved in inducing insulin resistance. These studies also suggest that the monoclonal antibody XOMA 052 may be a possible therapeutic to effectively neutralize cytokine-mediated insulin resistance in adipose tissue.

Kinetic approach to pathway attenuation using XOMA 052, a regulatory therapeutic antibody that modulates interleukin-1beta activity.

Many therapeutic antibodies act as antagonists to competitively block cellular signaling pathways. We describe here an approach for the therapeutic use of monoclonal antibodies based on context-dependent attenuation to reduce pathologically high activity while allowing homeostatic signaling in biologically important pathways. Such attenuation is achieved by modulating the kinetics of a ligand binding to its various receptors and regulatory proteins rather than by complete blockade of signaling pathways. The anti-interleukin-1beta (IL-1beta) antibody XOMA 052 is a potent inhibitor of IL-1beta activity that reduces the affinity of IL-1beta for its signaling receptor and co-receptor but not for its decoy and soluble inhibitory receptors. This mechanism shifts the effective dose response of the cytokine so that the potency of IL-1beta bound by XOMA 052 is 20-100-fold lower than that of IL-1beta in the absence of antibody in a variety of in vitro cell-based assays. We propose that by decreasing potency of IL-1beta while allowing binding to its clearance and inhibitory receptors, XOMA 052 treatment will attenuate IL-1beta activity in concert with endogenous regulatory mechanisms. Furthermore, the ability to bind the decoy receptor may reduce the potential for accumulation of antibody.target complexes. Regulatory antibodies like XOMA 052, which selectively modulate signaling pathways, may represent a new mechanistic class of therapeutic antibodies.

Somatic mutations lead to an oncogenic deletion of met in lung cancer.

Activating mutations in receptor tyrosine kinases play a critical role in oncogenesis. Despite evidence that Met kinase is deregulated in human cancer, the role of activating mutations in cancers other than renal papillary carcinoma has not been well defined. Here we report the identification of somatic intronic mutations of Met kinase that lead to an alternatively spliced transcript in lung cancer, which encodes a deletion of the juxtamembrane domain resulting in the loss of Cbl E3-ligase binding. The mutant receptor exhibits decreased ubiquitination and delayed down-regulation correlating with elevated, distinct Met expression in primary tumors harboring the deleted receptor. As a consequence, phospho-Met and downstream mitogen-activated protein kinase activation is sustained on ligand stimulation. Cells expressing the Met deletion reveal enhanced ligand-mediated proliferation and significant in vivo tumor growth. A hepatocyte growth factor competitive Met antagonist inhibits receptor activation and proliferation in tumor cells harboring the Met deletion, suggesting the important role played by ligand-dependent Met activation and the potential for anticancer therapy. These results support a critical role for Met in lung cancer and somatic mutation-driven splicing of an oncogene that leads to a different mechanism for tyrosine kinase activation through altered receptor down-regulation in human cancer.

Selective cyclin-dependent kinase 2/cyclin A antagonists that differ from ATP site inhibitors block tumor growth.

A central function of the tumor suppressor retinoblastoma (Rb) is its ability to repress E2F transcriptional activity. Many cancers harbor inactivated Rb and consequently deregulated E2F. RXL peptides inhibit E2F recruitment and phosphorylation by CDK2/cyclin A. Here we report that RXL peptides selectively kill tumor cells with deregulated Rb/cyclin D pathways. We extend these observations to tumor models and demonstrate inhibition of tumor growth in SV40 large T transformed Balb/c 3T3 grafts and in HER2 transgenic tumors. Moreover, our observations reveal that RXL peptide-treated tumors undergo apoptosis. Our results indicate that RXL motif-based inhibitors will provide selective antiproliferative agents with in vivo efficacy in tumors with deregulated Rb/cyclin D pathways.

Unusual proteolytic activation of pro-hepatocyte growth factor by plasma kallikrein and coagulation factor XIa.

Hepatocyte growth factor (HGF), the ligand for the receptor tyrosine kinase c-Met, is composed of an alpha-chain containing four Kringle domains (K1-K4) and a serine protease domain-like beta-chain. Receptor activation by HGF is contingent upon prior proteolytic conversion of the secreted inactive single chain form (pro-HGF) into the biologically active two chain form by a single cleavage at the Arg(494)-Val(495) bond. By screening a panel of serine proteases we identified two new HGF activators, plasma kallikrein and coagulation factor XIa (FXIa). The concentrations of kallikrein and FXIa to cleave 50% (EC(50)) of (125)I-labeled pro-HGF during a 4-h period were 10 and 17 nm. Unlike other known activators, both FXIa and kallikrein processed pro-HGF by cleavage at two sites. Using N-terminal sequencing they were identified as the normal cleavage site Arg(494)-Val(495) and the novel site Arg(424)-His(425) located in the K4 domain of the alpha-chain. The identity of this unusual second cleavage site was firmly established by use of the double mutant HGF(R424A/R494E), which was completely resistant to cleavage by kallikrein and FXIa. Experiments with another mutant form, HGF(Arg(494) --> Glu), indicated that cleavage at the K4 site was independent of a prior cleavage at the primary, kinetically preferred Arg(494)-Val(495) site. The cleavage at the K4 site had no obvious consequences on HGF function, because it was fully capable of phosphorylating the c-Met receptor of A549 cells. This may be explained by the disulfide bond network in K4, which holds the cleaved alpha-chain together. In conclusion, the ability of plasma kallikrein and FXIa to activate pro-HGF in vitro raises the possibility that mediators of inflammation and blood coagulation may also regulate processes that involve the HGF/c-Met pathway, such as tissue repair and angiogenesis.

Inhibition of ligand-mediated HER2 activation in androgen-independent prostate cancer.

Hormone-independent tumor growth and metastasis are associated with increased mortality in human prostate cancer. In this study, we evaluate a potential role for ligand-mediated activation of HER2 receptor tyrosine kinase in androgen-independent prostate cancers. HER2, HER3, and epidermal growth factor receptor were detected in the androgen-independent cell line 22Rv1. Heregulin stimulation results in receptor phosphorylation and cell proliferation that is inhibited by increasing concentrations of anti-HER2 recombinant humanized monoclonal antibody (rhuMAb) 2C4. Furthermore, inhibition of tumor growth was observed in xenografts derived from 22Rv1 cells when treated with rhuMAb 2C4 in a dose-dependent manner. These studies provide a framework, both in vitro and in vivo, to examine the molecular mechanisms of ligand-driven HER2 activation in androgen-independent tumorigenesis.