The cytoskeletal regulatory scaffold protein GIT2 modulates mesenchymal stem cell differentiation and osteoblastogenesis.

G protein-coupled receptor kinase interacting protein 2 (GIT2) is a signaling scaffold protein involved in the regulation of cytoskeletal structure, membrane trafficking, and G protein-coupled receptor internalization. Since dynamic cytoskeletal reorganization plays key roles both in osteoblast differentiation and in the maintenance of osteoclast polarity during bone resorption, we hypothesized that skeletal physiology would be altered in GIT2(-/-) mice. We found that adult GIT2(-/-) mice have decreased bone mineral density and bone volume in both the trabecular and cortical compartments. This osteopenia was associated with decreased numbers of mature osteoblasts, diminished osteoblastic activity, and increased marrow adiposity, suggesting a defect in osteoblast maturation. In vitro, mesenchymal stem cells derived from GIT2(-/-) mice exhibited impaired differentiation into osteoblasts and increased adipocyte differentiation, consistent with a role for GIT2 in mesenchymal stem cell fate determination. Despite elevated osteoclast inducing cytokines and osteoclast numbers, GIT2(-/-) mice also exhibit impaired bone resorption, consistent with a further role for GIT2 in regulating osteoclast function. Collectively, these findings underscore the importance of the cytoskeleton in both osteoblast and osteoclast function and demonstrate that GIT2 plays essential roles in skeletal metabolism, affecting both bone formation and bone resorption in vivo.

Differential copy number aberrations in novel candidate genes associated with progression from in situ to invasive ductal carcinoma of the breast.

Only a minority of intraductal carcinomas of the breast give rise to stromally invasive disease. We microdissected 206 paraffin blocks representing 116 different cases of low-grade ductal carcinoma in situ (DCIS). Fifty-five were pure DCIS (PD) cases without progression to invasive carcinoma. Sixty-one cases had a small invasive component. DNA was extracted from microdissected sections and hybridized to high-density bacterial artificial chromosome arrays. Array comparative genomic hybridization analysis of 118 hybridized DNA samples yielded data on 69 samples that were suitable for further statistical analysis. This cohort included 20 pure DCIS cases, 25 mixed DCIS (MD), and 24 mixed invasive carcinoma samples. PD cases had a higher frequency of DNA copy number changes than MD cases, and the latter had similar DNA profiles compared to paired invasive carcinomas. Copy number changes on 13 chromosomal arms occurred at different rates in PD versus MD lesions. Eight of 19 candidate genes residing at those loci were confirmed to have differential copy number changes by quantitative PCR. NCOR2/SMRT and NR4A1 (both on 12q), DYNLRB2 (16q), CELSR1, UPK3A, and ST13 (all on 22q) were more frequently amplified in PD. Moreover, NCOR2, NR4A1, and DYNLRB2 showed more frequent copy number losses in MD. GRAP2 (22q) was more often amplified in MD, whereas TAF1C (16q) was more commonly deleted in PD. A multigene model comprising these candidate genes discriminated between PD and MD lesions with high accuracy. These findings suggest that the propensity to invade the stroma may be encoded in the genome of intraductal carcinomas.

The genomic relationship between primary breast carcinomas and their nodal metastases.

We screened the whole tumor genome to identify DNA copy number gains and losses that discriminate between primary breast carcinomas (MP) and their nodal metastases (ML). Six candidate genes were confirmed by quantitative PCR to have differentially distributed copy number changes. Three of the genes (ERRγ, DDX6, and TIAM1) were more commonly amplified in nodal metastases. Principal component analysis revealed that MP-ML pairs varied markedly in their genomic divergence. The latter was larger in PR-negative tumors. Nodal metastases may form early or late in the development of breast carcinomas and PR-negative tumors may metastasize earlier or are genomically less stable.

Identification of metastasis-associated breast cancer genes using a high-resolution whole genome profiling approach.

PURPOSE: We employed a whole genome tumor profiling approach in an attempt to identify DNA copy number alterations (CNAs) and new candidate genes that are correlated with the metastatic potential of a primary breast carcinoma and with progression at the metastatic site. METHODS: Fifty-four small (≤ 2 cm), high grade, ER-positive, formalin-fixed invasive ductal carcinomas were suitable for whole genome profiling analysis. Twenty-four of them did not form metastases within 5-10 years (unmatched primaries, UP). Thirty tumors had at least one synchronous axillary lymph node metastasis (matched primaries, MP; matched lymph node metastases, ML). Genomic DNA was hybridized to high density (19k) BAC arrays. Statistical analysis revealed differential distributions of CNAs between UP and MP and between MP and ML, respectively. We selected 27 candidate genes for validation experiments using quantitative (Q-)PCR of genomic DNA. For tetraspanin TSPAN1, we studied mRNA expression levels in a separate cohort of primary breast carcinomas and in breast cell lines. RESULTS: Matched primary (MP) tumors had a threefold higher rate of DNA copy number losses compared to UP tumors. In the UP-MP comparison, 186 BACs were differentially amplified or deleted. Most of them were localized to chromosomes 7p, 16q and 18q. In the MP-ML comparison, 131 BACs showed differential CNAs. Most of them were localized to chromosomes 1q and 20. By Q-PCR, seven candidate genes could be confirmed to show differential distributions of CNAs. TSPAN1 was amplified in UP and deleted in MP tumors. The gene was markedly downregulated in ER-negative and high-grade breast cancers. CONCLUSIONS: Metastasizing tumors had a higher rate of deletions, suggesting possible inactivation of metastasis suppressor genes. We provide preliminary evidence that TSPAN1 may be another important breast cancer suppressor gene belonging to the tetraspanin superfamily.

Fully deleted adenovirus persistently expressing GAA accomplishes long-term skeletal muscle glycogen correction in tolerant and nontolerant GSD-II mice.

Glycogen storage disease type II (GSD-II) patients manifest symptoms of muscular dystrophy secondary to abnormal glycogen storage in cardiac and skeletal muscles. For GSD-II, we hypothesized that a fully deleted adenovirus (FDAd) vector expressing hGAA via nonviral regulatory elements (PEPCK promoter/ApoE enhancer) would facilitate long-term efficacy and decrease propensity to generate anti-hGAA antibody responses against hepatically secreted hGAA. Intravenous delivery of FDAdhGAA into GAA-tolerant or nontolerant GAA-KO mice resulted in long-term hepatic secretion of hGAA. Specifically, nontolerant mice achieved complete reversal of cardiac glycogen storage and near-complete skeletal glycogen correction for at least 180 days and tolerant mice for minimally 300 days coupled with the preservation of muscle strength. Anti-hGAA antibody levels in both mouse strains were significantly less relative to those previously generated by CMV-driven hGAA expression in nontolerant GAA-KO mice. However, plasma GAA levels decreased in nontolerant GAA-KO mice despite long-term intrahepatic GAA expression from the persistent vector. This intriguing result is discussed in light of other examples of "tolerance" induction by gene-transfer-based approaches.

Identification of OTX2 as a medulloblastoma oncogene whose product can be targeted by all-trans retinoic acid.

Through digital karyotyping of permanent medulloblastoma cell lines, we found that the homeobox gene OTX2 was amplified more than 10-fold in three cell lines. Gene expression analyses showed that OTX2 transcripts were present at high levels in 14 of 15 (93%) medulloblastomas with anaplastic histopathologic features. Knockdown of OTX2 expression by siRNAs inhibited medulloblastoma cell growth in vitro, whereas pharmacologic doses of all-trans retinoic acid repressed OTX2 expression and induced apoptosis only in medulloblastoma cell lines that expressed OTX2. These observations suggest that OTX2 is essential for the pathogenesis of anaplastic medulloblastomas and that these tumors may be amenable to therapy with all-trans-retinoic acid.

Growth arrest and apoptosis in adult T cell leukemia cell lines following IL-2 deprivation.

Adult T-cell leukemia (ATL) is a peripheral T-cell neoplasm caused by human T-cell leukemia virus type-I (HTLV-I). Since ATL cells often require IL-2 for their proliferation and survival, we examined the effect of IL-2 deprivation on the IL-2-dependent ATL cells established from ATL patients. After IL-2 withdrawal, these cells were arrested in the G1 phase and then underwent apoptosis. p27Kip1 was observed to act as a cell cycle inhibitor. A decrease in the amount of Bcl-xL was more distinct than that of Bcl-2, while Bax increased slightly during IL-2 withdrawal. The activation of caspase-3 and the loss of mitochondrial membrane potential were also observed. An overexpression of Bcl-xL protein in the KK1, one of the ATL cell lines, suppressed apoptosis by the 3rd day, however, apoptosis could not be prevented completely. Thereafter, a decrease in Bcl-xL and an activation of caspase-3 were observed even under the overexpression of Bcl-xL. The mitochondrial membrane potential and the intra-cellular levels of reactive oxygen species (ROS) also changed due to IL-2 deprivation. From these results, the IL-2 signals are considered to be essential for the survival of ATL cells, and the interruption of IL-2 signaling might thus be useful as a potentially new treatment for ATL.

Targeting of interleukin-2 to human MK-1-expressing carcinoma by fusion with a single-chain Fv of anti-MK-1 antibody.

BACKGROUND: Targeting of cytokines into the tumor sites using antibody-cytokine fission proteins represents a novel approach in cancer immunotherapy. We previously reported a novel monoclonal antibody, FU-MK-1, which recognizes a glycoprotein antigen (termed MK-1 antigen) that is overexpressed on the surface of a majority of carcinomas. MATERIALS AND METHODS: To target IL-2 and cytotoxicity of effector cells to MK-1-expressing tumor cells, we genetically fused recombinant human interleukin-2 (rhIL-2) to a single chain variable fragment (scFv) antibody derived from FU-MK-1. The resulting fission protein, designated FUscFv/IL-2 was expressed in Pichia pastoris, purified by Ni-affinity chromatography, and characterized for the MK-1-binding specificity and the IL-2 biological activity. RESULTS: The FUscFv/IL-2 fusion protein effectively introduced a specific cytotoxicity of lymphokine-activated killer cells to the tumor cells and consequently suppressed the tumor growth in a SCID mouse xenograft model. CONCLUSION: This approach may be used for in vivo administration to localize IL-2 to tumor tissues, enhancing the immune response to human MK-1-expressing tumors while reducing systemic side-effects.

Tumor growth suppression by a retroviral vector displaying scFv antibody to CEA and carrying the iNOS gene.

BACKGROUND: In a recent in vitro study we demonstrated a specifically-targeted killing of CEA-expressing cells by a recombinant bifunctional retrovector displaying an scFv antibody to CEA and carrying the iNOS gene. In this study, we tested whether a gene therapy using the recombinant retrovirus could inhibit the growth of CEA-expressing tumors in mice. MATERIALS AND METHODS: SCID mice were inoculated s.c. on the back with CEA-expressing MKN-45 cells on day 0. The recombinant viral particles were injected into the inoculated sites on days 3, 5 and 7 and tumor size was measured every 5 days. RESULTS: The s.c. administration of the recombinant retrovirus produced a marked growth inhibition of MKN-45 tumors in SCID mice. When the actual tumor weights were measured 50 days after initiation of treatment, about 70% reduction was observed in the treated group as compared to the control groups. CONCLUSION: This approach may also be applied to other tumor antigens expressed on cancer cells and is a step towards the cell specific suppression of tumorigenicity.