Soluble monomeric EphrinA1 is released from tumor cells and is a functional ligand for the EphA2 receptor.

The ephrinA1 ligand exerts antioncogenic effects in tumor cells through activation and downregulation of the EphA2 receptor and has been described as a membrane-anchored protein requiring clustering for function. However, while investigating the ephrinA1/EphA2 system in the pathobiology of glioblastoma multiforme (GBM), we uncovered that ephrinA1 is released from GBM and breast adenocarcinoma cells as a soluble, monomeric protein and is a functional form of the ligand in this state. Conditioned media containing a soluble monomer of ephrinA1 caused EphA2 internalization and downregulation, dramatic alteration of cell morphology and suppression of the Ras-MAPK pathway. Moreover, soluble monomeric ephrinA1 was functional in a physiological context, eliciting collapse of embryonic neuronal growth cones. We also found that ephrinA1 is cleaved from the plasma membrane of GBM cells, an event which involves the action of a metalloprotease. Thus, the ephrinA1 ligand can, indeed, function as a soluble monomer and may act in a paracrine manner on the EphA2 receptor without the need for juxtacrine interactions. These findings have important implications for further deciphering the function of these proteins in pathology and physiology, as well as for the design of ephrinA1-based EphA2-targeted antitumor therapeutics.

VEGF-D is an X-linked/AP-1 regulated putative onco-angiogen in human glioblastoma multiforme.

BACKGROUND: Glioblastoma multiforme (GBM) is a hypervascularized and locally infiltrating brain tumor of astroglial origin with a very poor prognosis. An X-linked c-fos oncogene-inducible mitogenic, morphogenic, and angiogenic factor, endothelial growth factor-D (VEGF-D), is the newest mammalian member of VEGF family. We analyzed VEGF-D in GBM because of its high angiogenic potential and its linkage to the X chromosome. MATERIALS AND METHODS: Nonmalignant brain and GBM tissue sections as well as GBM cell lines were analyzed by immunofluorescence for the expression of VEGF-D, factor VIII (endothelial cell marker), glial-fibrillary acidic protein (GFAP) (astrocytic cell lineage cytoplasmic marker), and several Fos family transcription factors, including c-Fos and Fra-1. The proteins were also detected by Western blots. The differences between genotypes of normal brain and GBM cells were examined by cDNA microarrays. RESULTS AND CONCLUSIONS: GBM expressed ubiquitously VEGF-D, which colocalized with GFAP. Contrary to our expectations, low levels of c-Fos were detected in GBM cells. However, we identified another Fos family member, Fra-1, together with its transcriptional activation partner, c-Jun, as being stably up-regulated in GBM cells. Furthermore, we demonstrated that a fra-1 transgene induced VEGF-D expression in cultured cells and GBM cell stimulation evoked a sustained increase in both Fra-1 and VEGF-D levels. This study reveals that an up-regulation of AP-1 factors may be a hallmark of GBM. Because VEGF-D activates VEGF receptor 2 and 3, receptors important for tumor angiogenesis, it may represent an X-linked/AP-1-regulated onco-angiogen in human GBM. The VEGF-D system and AP-1 activity appear to be very attractive targets for new molecular diagnostics and rational molecular anti-cancer therapies.

Expression of a restrictive receptor for interleukin 13 is associated with glial transformation.

We have previously documented that the vast majority of high-grade gliomas over-express binding sites for interleukin 13 (IL13) in situ. We now extend this analysis to evaluate the distribution of the binding of IL13 among other brain tumors. Tumor specimens from patients with low-grade gliomas, oligodendrogliomas, ependymomas, pilocytic astrocytomas, gliosarcomas, medulloblastomas, meningiomas, and metastases to the brain were analyzed and compared to a new series of glioblastoma multiforme (GBM) samples. Serial tumor tissue sections were incubated with 125I-labeled (i) IL13, (ii) antibody against transferrin (Tf) receptor, and (iii) epidermal growth factor (EGF). Most (17/18) GBMs stained specifically for IL13 binding sites while sections from 3/11 low-grade gliomas, 5/5 high-grade gliomas (grade III), 3/5 oligodendrogliomas (all three were anaplastic), and 1/2 gliosarcomas also showed specific binding for IL13. We did not detect IL13 binding sites in medulloblastomas (0/4) and found them only in 2/20 meningiomas. Metastases to the brain (4/12, i.e., lung adenocarcinomas and renal cell carcinoma) showed some binding of 125I-IL13. The presence of receptors for Tf was ubiquitous among all studied tumors while EGF receptor expression was much more variable. Since it appears that primarily the least differentiated forms of gliomas possess IL13 binding sites in abundance, it is plausible that IL 13 receptor expressed in low-grade gliomas might be a prognostically significant marker associated with their progression to high-grade gliomas. Finally, we demonstrate that the glioma-associated IL13 receptor is truly more restrictive in nature also due to its selective representation among brain tumors of glial origin.

Molecular expression analysis of restrictive receptor for interleukin 13, a brain tumor-associated cancer/testis antigen.

BACKGROUND: The vast majority of patients with high-grade gliomas (HGG) over-express interleukin 4 (IL4)-independent binding sites for IL13 in situ. In addition, mutated IL13-based cytotoxins directed specifically toward glioma-associated sites are arguably the most active anti-glioma agents. Two IL13 receptor (R) proteins were identified: (1) IL13R alpha', a component of the signaling, heterodimeric high-affinity receptor for IL13 that is shared with IL4, and (2) IL13R alpha, a monomeric, IL4-independent receptor. MATERIALS AND METHODS: We analyzed gene expression of IL13R alpha, IL13R alpha' and that of IL4Rbeta, which is the other subunit of the shared IL13/4 receptor. The study was conducted with 40 human normal adult tissues, 20 discrete regions of the central nervous system (CNS), 7 fetal tissues, several cultured cell lines, and surgical CNS specimens. RESULTS: The most striking feature of the IL13R alpha gene expression was the virtual lack of its transcripts within the CNS. Furthermore, only the testes exhibited a prominent presence of the mRNA for IL13R alpha among peripheral organs. In contrast, the components of the shared IL13/4 receptor were readily detected both in the CNS and in vital organs, such as liver, heart, lungs, and gastrointestinal tract. CONCLUSIONS: The results strongly support a need to redirect IL13 towards its more restrictive, IL4-independent, receptor for glioma diagnosis and therapies. Moreover, the gene for IL13R alpha resides on chromosome X. Since IL13R alpha is (1) a cancer-associated protein, (2) virtually restricted to testes among normal tissues, and (3) its gene is on chromosome X, IL13R alpha is unexpectedly categorized as a cancer/testis antigen. Our findings make IL13R alpha even more attractive as a target for variety of approaches in glioma molecular management.

Receptor for interleukin 13 is abundantly and specifically over-expressed in patients with glioblastoma multiforme.

We have recently documented that the vast majority of patients with glioblastoma multiforme (GBM) over-express a receptor (R) for interleukin 13 (IL13) in situ. We have now evaluated further the degree of relative specificity of the binding of IL13 to GBM when compared with other growth factor receptors. Tumor samples of 11 patients with GBM, 7 various normal brain samples, and several cell lines in culture were examined. Same patient tissue sections were incubated with 125I-labeled: IL13, monoclonal antibody HB21 against human transferrin (Tf) receptor, epidermal growth factor (EGF), and an IL4 antagonist, IL4.Y124D. All 11 GBMs stained specifically, densely, and relatively homogeneously for both IL13R and TfR. Seven GBM specimens showed specific binding for 125I-EGF, but it was less homogeneous when compared with IL13R or TfR. Two of the GBMs studied demonstrated extremely high density of the EGFR. Furthermore, we did not detect significant presence of the IL4R in the studied GBM specimens in situ. All sections of non-malignant brain tissues examined showed avid binding by the TfR with lack of consistent and specific binding of 125I-IL13 or -EGF. Thus, it appears that the GBM-associated IL13R is considerably more specific to GBM that the one for Tf and more frequently and homogeneously expressed than the EGFR. These results render further support for the hIL13R being a new unique candidate for delivery of variety of anti-GBM therapies.

Receptor for interleukin 13 is a marker and therapeutic target for human high-grade gliomas.

Glioblastoma multiforme (GBM) is an incurable brain tumor. Due to the striking heterogeneity that characterizes GBM, there is no known tumor-specific antigen or receptor that is expressed by a majority of GBM patients. We found that virtually all studied human GBM specimens (23 samples) abundantly expressed a receptor for interleukin (IL)-13 in situ, whereas normal human brain had few, if any, IL-13-binding sites. The GBM-associated IL-13 receptor was both quantitatively and qualitatively different from and, thus, more restrictive than the shared signaling receptor of normal tissue: it was IL-4 independent. The receptor for IL-13 was overexpressed by a majority of cancer cells in situ. Furthermore, cytotoxins targeted to this more restrictive IL-13R produced cures in animals bearing xenografts of human high-grade gliomas. Thus, unexpectedly, the receptor for an immune regulatory cytokine may be a long sought marker and, concomitantly, a unique imaging site and therapeutic target for GBM, the most malignant and the most heterogeneous of brain tumors.

Antisense wnt-5a mimics wnt-1-mediated C57MG mammary epithelial cell transformation.

The disruption of the normal expression of wnt-5a in cell lines and in tumors is becoming increasingly recognized as important in cell transformation and tumorigenesis. For example, in endometrial cancer wnt-5a is downregulated compared to normal tissue. Our laboratory has recently found that the ectopic expression of wnt-5a in human RCC23 renal carcinoma cells missing wnt-5a gene expression suppresses in vitro cell growth and telomerase enzyme activity. Furthermore, ectopic wnt-5a in MC-T16 uroepithelial cancer cells missing the region of chromosome 3p where wnt-5a has been mapped reverts uroepithelial cell tumorigenesis in athymic nude mice. These studies were based upon the previous finding that wnt-1 and wnt-2 transform C57MG mammary epithelial cells by downregulating the endogenous expression of wnt-5a. We now report that transfecting C57MG cells with a mammalian expression vector carrying antisense wnt-5a results in a cell phenotype that mimics cell transformation by ectopic wnt-1 or wnt-2. Correspondingly, wnt-1-transformed cells are partially reverted in the presence of ectopic wnt-5a. We conclude from this that wnt-5a is an important regulator of cell growth and differentiation and its loss of expression leads to cell transformation.

Novel way to increase targeting specificity to a human glioblastoma-associated receptor for interleukin 13.

Human brain cancers (gliomas) overexpress large numbers of a receptor for interleukin 13 (IL13), making this receptor an attractive target for anti-glioma therapies. We have recently proposed that the glioma-associated IL13 receptor is different from the one expressed on some hemopoietic and somatic cells. In an attempt to identify an even more glioma-specific target, we have used an antagonist of a related cytokine, IL4, which neutralizes the physiological effects of both IL13 and IL4 on normal cells. Here we demonstrate that the IL4 antagonist also counteracts the action of cytotoxins targeted to the IL13 receptor on normal human cells. Importantly, the IL4 antagonist does not inhibit IL13-based cytotoxins on glioma cells at all. Thus, the IL13 receptor on glioma cells can be categorized as tumor-specific in the presence of an IL4 antagonist. We conclude that IL13 receptor-directed cytotoxins can be delivered to glioma cells without being cytotoxic to normal cells.

Novel anti-brain tumor cytotoxins specific for cancer cells.

The vast majority of brain cancers (gliomas) express a receptor (R) for interleukin 13 (IL13). In order to achieve specific targeting of the IL13R in gliomas, we have mutagenized human (h) IL13. The mutation was made to alter IL13 interaction with the shared functional IL13/4 normal tissue receptor, but not with the glioma-associated receptor. We have thus produced hIL13.E13K (glutamic acid at position 13 changed to lysine) and fused it to derivatives of Pseudomonas exotoxin A. The hIL13.E13K-based cytotoxins are less active on normal cells and thus less toxic, and are better antitumor agents compared with the cytotoxins containing nonmutagenized hIL13.

Reversion of uroepithelial cell tumorigenesis by the ectopic expression of human wnt-5a.

Wnt gene family members are thought to play an important role in cell growth and differentiation. When normal wnt gene expression is disrupted, there is the potential for cell transformation. We have found previously that a strong correlation exists between the loss of normal wnt-5a gene expression and cell transformation (Olson and Papkoff, Cell Growth & Differ., 5: 197-206, 1994). Recently, this has been tested directly using antisense wnt-5a, which, when expressed in mouse mammary cells, results in cell transformation (Olson and Gibo, Antisense wnt-5a transforms C57MG mouse mammary epithelial cells, manuscript in preparation). We hypothesize that wnt-5a is a growth-regulating gene, the disruption of which could result in tumorigenesis. The multistage progression of many human cancers involves the loss of normal tumor suppressor gene(s) activity. Several tumor suppressor genes are thought to map to chromosome 3p11-p25. We have studied the ectopic expression of human wnt-5a (3p14-p21) in a tumorigenic uroepithelial cell line with deletion of chromosome 3p13-p21.2. This results in loss of tumorigenicity in athymic nude mice and suppresses anchorage-independent cell growth in soft agar. This suggests that human wnt-5a is a novel tumor suppressor gene in uroepithelial cell carcinoma and may be one of the suppressor genes deleted or rearranged on chromosome 3p.

Ontogeny of zeta (zeta), the opioid growth factor receptor, in the rat brain.

Opioid growth factor (OGF), [Met5]enkephalin, serves as an inhibitory influence on the developing nervous system and is especially targeted to cell proliferative events. OGF interacts with the zeta (zeta) opioid receptor to perform its function. Using [3H]-[Met5]enkephalin, the ontogeny of the zeta receptor in the whole brain and cerebellum of rats was explored. Specific and saturable binding was recorded at the earliest time sampled, prenatal day 15 (E15). In the whole brain, binding capacity (Bmax) was two-fold greater at E15 than at E18 and E20. The quantity of zeta receptor appeared to increase in the first postnatal week, reaching a maximum on postnatal day 8. Binding decreased the remainder of the 2nd week and between postnatal days 15 and 25 binding was no longer recorded. In the cerebellum, binding capacity increased from E20 to the 2nd postnatal week, reaching a maximum on postnatal days 8-10. The Bmax of the zeta receptor decreased precipitously on postnatal day 11, being 5.4-fold lower than on postnatal day 10. Between postnatal days 21 and 30, no binding was observed. The binding affinities of the whole brain and cerebellum were 2.3 and 2.7 nM, respectively, and no differences between ages could be detected. Continuous opioid receptor blockade from birth to postnatal day 6 increased body weight, the Bmax of the zeta receptor in the whole brain and cerebellum (but not the Kd), and increased the number of layers of germinal cells in the cerebellum.(ABSTRACT TRUNCATED AT 250 WORDS)

Zeta (zeta), a growth-related opioid receptor in developing rat cerebellum: identification and characterization.

Endogenous opioids and opioid receptors (i.e. endogenous opioid systems) are expressed during neural ontogeny, and play a role in the development of the nervous system. Using [3H][Met5]-enkephalin, a potent ligand involved in neural growth, particularly cell proliferation, specific and saturable binding was detected in homogenates of 6-day-old rat cerebellum; the data were consistent with a single binding site. Scatchard analysis yielded a binding affinity (Kd) of 2.2 nM and a binding capacity (Bmax) of 22.3 fmol/mg protein. Binding was linear with protein concentration, dependent on time, temperature, and pH, and was sensitive to Na+, Mg2+, and guanyl nucleotides. Optimal binding required protease inhibitors, and pretreatment of the homogenates with trypsin markedly reduced binding, suggesting that the binding site was proteinaceous in character. The [Met5]-enkephalin binding site was an integral membrane protein located in the nuclear fraction. Competition experiments indicated that [Met5] enkephalin was the most potent displacer of [3H][Met5]-enkephalin, and that binding was stereospecific. In the adult rat cerebellum, non-opioid receptor binding of [3H][Met5]-enkephalin was recorded, mu and kappa receptors were also found in the developing rat cerebellum, while mu, delta, and kappa receptors were recorded in adult cerebellar tissue. The function, pharmacological and biochemical characteristics, subcellular distribution, and temporal expression of the [Met5]-enkephalin binding site suggest the presence of a unique opioid receptor, termed zeta (zeta), in the developing nervous system.

Adult and developing human cerebella exhibit different profiles of opioid binding sites.

The binding of [3H][D-Ala2,MePhe4,Gly-ol5]enkephalin (DAGO), [3H][D-Pen2,5]enkephalin (DPDPE), [3H]ethylketocyclazocine (EKC), and [3H][Met5]enkephalin (MET) was used to examine mu-, delta-, kappa-, and zeta-receptors, respectively, in the developing (birth to postnatal day 19) and adult human cerebellum. Specific and saturable binding of all ligands was recorded in developing brains, and of [3H]DAGO, [3H]DPDPE, and [3H]EKC in adult cerebellum; all data fit a single homogeneous binding site for each ligand. However, the ontogenic profile of opioid receptor subtypes differed. Delta- and kappa-receptor capacities were 7.8- and 3.6-fold, respectively, greater in infant cerebellum than in adults. The mu-receptor decreased over 7-fold in both binding affinity and capacity after day 2; by adulthood, the binding affinity was the same as in newborns but only one-half the binding capacity was recorded. The concentration of zeta-receptors was 20-fold greater in subjects 2-19 days of age than in newborns. These data demonstrate the presence, and distinct developmental profiles, of opioid receptors in human cerebellum. Although the function of mu-, delta-, and kappa-receptors in human cerebellum are unclear, the growth-related zeta-receptor is present at a time of cell replication and differentiation but is not detected in mature cerebellum.