Cables1 is a tumor suppressor gene that regulates intestinal tumor progression in Apc(Min) mice.

The transformation of colonic mucosal epithelium to adenocarcinoma requires progressive oncogene activation and tumor suppressor gene inactivation. Loss of chromosome 18q is common in colon cancer but not in precancerous adenomas. A few candidate tumor suppressor genes have been identified in this region, including CABLES1 at 18q11.2-12.1. This study investigates the role of CABLES1 in an in vivo mouse model of intestinal adenocarcinoma and in human colon cancer cell culture. Apc(Min/+) mice were crossed with mice harboring targeted inactivation of the Cables1 gene (Cables1(-/-)). The intestinal tumor burden and tumor expression of ß-catenin and PCNA was compared in Cables1(+/+)Apc(Min/+) and Cables1(-/-)Apc(Min/+) mice. ß-catenin activity in human colon cancer cells with CABLES1 inactivation and intestinal progenitor cell function in Cables1(-/-) mice were assayed in vitro. The mean number of small intestinal tumors per mouse was 3.1 ± 0.6 in Cables1(+/+)Apc(Min/+) mice, compared with 32.4 ± 3.5 in the Cables1(-/-)Apc(Min/+) mice (P < 0.0001). Fewer colonic tumors were observed in Cables1(+/+)Apc(Min/+) mice (mean 0.6 ± 0.1) compared with the Cables1(-/-)Apc(Min/+) mice (mean 1.3 ± 0.3, P = 0.01). Tumors from Cables1(-/-)Apc(Min/+) mice demonstrated increased nuclear expression of ß-catenin and an increased number of PCNA-positive cells. In vitro studies revealed that CABLES1 deficiency increased ß-catenin dependent transcription and increased intestinal progenitor cell activity. Loss of Cables1 enhances tumor progression in the Apc(Min/+) mouse model and activates the Wnt/ß-catenin signaling pathway. Cables1 is a tumor suppressor gene on chromosome 18q in this in vivo mouse model and likely has a similar role in human colon cancer.

TIP30 is associated with progression and metastasis of prostate cancer.

Tat-interacting protein 30 (TIP30), a transcriptional repressor for ERalpha-mediated transcription, possesses several characteristics of a tumor suppressor in certain human and mouse cells. It is reported that deletion of TIP30 gene preferentially increases tumorigenesis in the female knockout mice. Here, we analyzed TIP30 gene expression in the databases of several DNA microarray studies of human prostate cancer and show that TIP30 is specifically overexpressed in metastatic prostate cancers. We demonstrate that TIP30 nuclear expression is associated with prostate cancer progression and metastasis by immunohistochemical analysis in primary and metastatic prostate cancers. Consistent with these data, we also show that knockdown of TIP30 expression, through use of a short hairpin RNA-expressing plasmid, suppresses the cellular growth of PC3 and LNCaP prostate cancer cells. Ectopic overexpression of TIP30 stimulates metastatic potential of prostate cancer cells in an in vitro invasion assay, whereas knockdown of TIP30 inhibits the prostate cancer cells invasion. Finally, we demonstrate that ectopic overexpression of TIP30 enhances androgen receptor mediated transcription, whereas knockdown of TIP30 results in a decreased transcription activity. These data provide evidence that TIP30 plays a role in prostate cancer progression and that TIP30 overexpression may promote prostate cancer cell growth and metastasis.

Mechanisms of Cables 1 gene inactivation in human ovarian cancer development.

Cables 1, a cyclin-dependent kinase binding protein, is primarily involved in cell cycle regulation. Loss of nuclear Cables 1 expression is observed in human colon, lung and endometrial cancers. We previously reported that loss of nuclear Cables 1 expression was also observed with high frequency in a limited sample set of human ovarian carcinomas, although the mechanisms underlying loss of nuclear Cables 1 expression remained unknown. Our present objective was to examine Cables 1 expression in ovarian cancer in greater detail, and determine the predominant mechanisms of Cables 1 loss. We assessed potential genetic and epigenetic modifications of the Cables 1 locus through analyses of mutation, polymorphisms, loss of heterozygosity and DNA methylation. We observed a marked loss of nuclear Cables 1 expression in serous and endometrioid ovarian carcinomas that correlated with decreased Cables 1 mRNA levels. Although we detected no Cables 1 mutations, there was evidence of LOH at the Cables 1 locus and epigenetic modification of the Cables 1 promoter region in a subset of ovarian carcinomas and established cancer cell lines. From a functional perspective, over-expression of Cables 1 induced apoptosis, whereas, knockdown of Cables 1 negated this effect. Together these findings suggest that multiple mechanisms underlie the loss of Cables 1 expression in ovarian cancer cells, supporting the hypothesis that Cables 1 is a tumor suppressor in human ovarian cancer.

The Cables gene on chromosome 18q is silenced by promoter hypermethylation and allelic loss in human colorectal cancer.

Cables is a cyclin-dependent kinase-binding nuclear protein that maps to chromosome 18q11-12. Here, we assessed Cables expression in 160 colorectal cancers (CRCs), its role in colon cancer cell growth, and the potential mechanisms of Cables inactivation. Expression levels, promoter methylation, and mutational status of Cables were investigated in colon cancer cell lines and primary colon tumors. Chromosome 18q loss of heterozygosity (LOH) was evaluated with multiple polymorphic markers. Cables inhibited cellular proliferation and colony formation in colon cancer cell lines. Cables expression was reduced in 65% of primary CRCs. No mutations were detected in 10 exons of Cables in 20 primary colon tumors. Cables promoter was methylated in cell lines with decreased Cables expression and vice versa. 5-Aza-2'-deoxycytidine resulted in increased Cables expression in methylated cell lines. There was a significant correlation between promoter methylation and Cables gene expression in primary colon tumors. Sixty-five percent of primary colon tumors demonstrated chromosome 18q LOH. LOH involving the Cables region was observed in 35% of cases, including those in which more distal portions of chromosome 18q were retained, and Cables expression was decreased in all such cases. Loss of Cables expression in 65% of CRCs suggests that it is a common event in colonic carcinogenesis, with promoter methylation and LOH appearing to be important mechanisms of Cables gene inactivation.

The Cables gene on chromosome 18Q regulates colon cancer progression in vivo.

Early events involved in the pathogenesis of colorectal cancer include mutations in the Adenomatous Polyposis Coli tumor-suppressor gene and oncogenic KRAS mutations. Later events include deletions on chromosome 18q, which are observed in a high proportion of colorectal cancers. However, the important tumor suppressor genes targeted by these deletions have not been fully defined. A previous study found Cables is located on human chromosome 18q11-12. Loss of Cables expression as determined by immunohistochemical staining (IHC) occurred in 60-70% of sporadic colorectal cancers that were usually correlated to loss of heterozygosity at 18q. To determine if Cables is an important target for the chromosome 18q deletions, the susceptibility of Cables-/- mice to develop colon tumors was studied. A well characterized colonic carcinogen, 1,2-dimethylhydrazine (DMH) was used as a tumor initiator. Cables-/- mice (n = 25) and the Cables+/+ littermates (n = 25) were treated with subcutaneous DMH injections over 20 weeks to initiate tumorigenesis. The median survival after DMH injections was significantly shorter for the Cables-/- mice compared to Cables+/+ littermates. The total number of colorectal tumors that developed in the Cables-/- mice was 46 tumors versus 21 tumors. The increased numbers of colorectal tumors, as well as shorter survival of the Cables-/- mice provides compelling evidence that Cables could play an important role in the pathogenesis and progression of colon cancer in mice. These data coupled with previous observations support the hypothesis that Cables is a relevant target of the chromosome 18q deletions frequently seen in human colorectal cancer.

Aberrant splicing of cables gene, a CDK regulator, in human cancers.

Cables is a novel cell cycle regulatory protein that interacts with cdk2, cdk3, and cdk5. Cables inhibits cdk2 activity by enhancing cdk2 tyrosine 15 phosphorylation by Wee1, which consequently leads to inhibition of cell growth. Loss of Cables expression was found in many human cancers, especially colon and endometrial cancer. However, the role of the Cables gene in cancer development remains unclear. This study was undertaken to analyze transcripts of Cables gene in endometrial and colon cancers. The analysis of RT-PCR products of the Cables gene revealed shortened products in each sample along with the product of the expected size. Sequence analysis indicated that these shortened products represented eight intragenic deletions in Cables mRNA transcripts. Analysis of DNA from the same tumor sample failed to show genomic rearrangements corresponding to the transcripts containing deletions, suggesting that the deletions are the result of RNA splicing. Sequence analysis demonstrated that five of the deletions resulted from alternative splicing (splicing at the exon/intron boundary consensus sites), whereas the remaining three deletions resulted from aberrant splicing (splicing at sites not considered to be exon/intron boundary sites). All three aberrant splicing products were only detected in tumor tissues. Ectopic expression of one of the aberrant splicing products, which was detected in both endometrial and colon carcinomas, resulted in increased cell growth rate in human colon carcinoma HT-29 cells, suggesting a role as a dominant negative mutant.

Increased growth rate, delayed senescense and decreased serum dependence characterize cables-deficient cells.

Cables (Cables1), a recently described growth suppressor protein that maps to human chromosome 18q11-12, is lost in many primary colon, lung, and gynecological malignancies. Cultured cell lines that overexpress Cables show a reduction in cell proliferation and Cables(-/-) mice are viable with normal embryonic development. Since Cables expression is lost in primary human tumors and overexpression of Cables suggests a role in growth suppression, we investigated growth properties of primary mouse embryonic fibroblasts (MEFs) from Cables(-/-) and Cables(+/+) mice. Cables(-/-) MEFs exhibited a doubling time of 43-45 hours compared to 73-75 hours for the Cables(+/+)MEFs. Similarly, Cables(-/-) MEFs show a delayed onset of senescence and extension of lifespan, while the Cables(+/+) MEFs ceased proliferating after eight cumulative population doublings. Cables(-/-) MEFs were able to proliferate in low serum concentrations. These data provide convincing evidence that Cables plays a role in the regulation of cell proliferation and survival.

Defining the extent of cables loss in endometrial cancer subtypes and its effectiveness as an inhibitor of cell proliferation in malignant endometrial cells in vitro and in vivo.

Loss of Cables expression is associated with a high incidence of endometrial hyperplasia and endometrial adenocarcinoma in humans. The Cables mutant mouse develops endometrial hyperplasia and following exposure to chronic estrogen develops early endometrial adenocarcinoma. The objectives of the current study were to determine if: (1) loss of Cables expression occurred in high grade endometrioid adenocarcinoma, uterine serous and clear cell carcinoma as observed in endometrial hyperplasia and low grade endometrial adenocarcinoma; (2) overexpression of Cables inhibited cell proliferation in endometrial cancer (EC) cells in vitro and in vivo; and (3) progesterone could regulate the expression of Cables mRNA. Hyperplastic endometrium and low and high grade endometrioid adenocarcinoma showed loss of Cables expression when compared to benign control secretory endometrium. Loss of Cables expression in serous and clear cell tumors was similar to that observed in endometrioid adenocarcinomas with greater than 80% showing loss of protein expression. Treatment of EC lines with progesterone increased cables expression in low-grade EC whereas it had no effect on cables expression in cells derived from high-grade EC. The progesterone-induced increase in cables was abrogated in the presence of a progesterone receptor (PR) antagonist, suggesting the PR mediates the increase. Cables overexpression inhibited cell proliferation of well differentiated EC cells and had no effect on the poorly differentiated EC cells. The capacity to form tumors was dramatically reduced in the Cables overexpressing cell lines compared to those cells containing the control vector. Collectively these results suggest that Cables is an important regulator of cell proliferation and loss of Cables expression contributes to the development of all types of EC.

Effect of keratinocyte growth factor and activin on cell growth in the human prostatic cancer cell line LNCaP.

Keratinocyte growth factor (KGF) has paracrine properties in the human prostate which stimulate epithelial cell growth. Activins have profound effects on cell growth and function in the human prostate, and are expressed in LNCaP, DU 145 and PC3 cells. LNCaP cells were characterized by immuncytochemistry, an immunoassay and polymerase chain reaction. A 3[H]thymidine assay was used with 0.01-10 nM dihydrotestosterone, 10 micro M flutamide, 1-100 ng/ml KGF and 3 nM activin. LNCaP cells expressed Ki67, PSA, cytokeratins (8, 18, 19, 14, 15) androgenreceptor but no KGF protein. LNCaP cells showed telomerase activity. Furthermore, ARmRNA (365 bp), but no KGF or KGFRmRNA were expressed. KGF ELISA detected no intracellular or secreted KGF. DHT (1, 10 and 100 nM) and KGF (10 and 100 ng/ml) significantly stimulated LNCaP cell proliferation. However, flutamide and 3 nM activin A significantly decreased cell proliferation in the presence and absence of KGF. The results of our experiments support the hypothesis that cell growth and proliferative characteristics of LNCaP cells are modulated by KGF and activin A.

Loss of cables, a cyclin-dependent kinase regulatory protein, is associated with the development of endometrial hyperplasia and endometrial cancer.

Endometrial cancer is the most common gynecological cancer in Western industrialized countries. Cables, a cyclin-dependent kinase binding protein, plays a role in proliferation and/or differentiation. Cables mutant mice are viable, but develop endometrial hyperplasia and carcinoma in situ at a young age. Exposure to chronic low levels of estrogen results in development of endometrial cancer, similar to that observed in the postmenopausal female. In vitro and in vivo studies demonstrate that levels of Cables mRNA in benign human endometrial epithelium are up-regulated by progesterone and down-regulated by estrogen. Furthermore, nuclear immunostaining for Cables is lost in a high percentage of cases of human endometrial hyperplasia and adenocarcinoma, which are likely the product of unopposed estrogen. The loss of Cables immunostaining in the human endometrial cancer samples correlates with a marked decrease in Cables mRNA. Ectopic expression of Cables in human endometrial cells dramatically slows cell proliferation. Collectively, these data provide evidence that Cables is hormonally regulated and is involved in regulating endometrial cell proliferation. In addition, loss or suppression of Cables may be an early step in the development of endometrial cancer.