EC:3.2.1.23 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.2.1.23 (beta-galactosidase)
14,648 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Pituitary adenomas cause clinical manifestations because of mass effects and excess hormone production. This group of tumors represents a tractable target for gene therapy because they are rarely metastatic and because reductions in tumor size and function, in addition to those achieved after surgery, may be of clinical benefit. In this report we describe a strategy for targeting the expression of toxic genes to pituitary cells using adenoviral vectors. Pituitary hormone promoters (human GH or glycoprotein hormone alpha-subunit) were used to express either a marker gene [beta-galactosidase (beta-gal)] or a toxic gene [herpes simplex virus thymidine kinase (TK)]. In GH-producing GH3 cells and in alpha-subunit-producing pituitary tumor cell lines, recombinant adenoviruses containing either the alpha-subunit promoter (Ad alpha Gal; AdaTK) or the GH promoter (AdGHGal; AdGHTK) were expressed at-high levels. Using histological studies and assays for beta-gal activity, expression was shown to persist for at least 21 days, and it was relatively selective for pituitary cell lines. Cytotoxicity studies were performed using the TK-containing vectors and treatment with ganciclovir. Both AdGHTK and AdaTK caused greater than 95% cytotoxicity of GH3 and alphaT3 cells, respectively, at a viral dose (multiplicity of infection, 5 plaque-forming units/cell) that induced minimal toxicity using control viruses. Little cellular toxicity was seen using a nonpituitary cell line (T47D breast tumor cells). The AdGHTK virus also caused marked reduction in the size of GH3 cell tumors that were propagated in nude mice. These studies suggest that adenoviral vectors carrying human pituitary gland specific promoters may be useful for developing gene therapy strategies for the treatment of pituitary adenomas.
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PMID:Targeted expression of toxic genes directed by pituitary hormone promoters: a potential strategy for adenovirus-mediated gene therapy of pituitary tumors. 1002 54

Suicide gene therapy has met limited success for the treatment of rat pituitary tumors. In order to determine the cause of primary pituitary tumor resistance to suicide gene therapy, we studied the transgene expression of an adenoviral (Ad.RSV.beta gal.nls) and a herpes simplex virus-derived (tsK/beta-gal) vector, both harboring the beta-galactosidase reporter gene in rat prolactinomas. Rats carrying experimental prolactinomas received bilateral 1 microl intrapituitary injections of either saline (saline group), 5 x 10(5) plaque-forming units (pfu) tsK/beta-gal (HSV Group) or 5 x 10(5) pfu Ad.RSV.beta gal.nls (RAd Group). Two or seven days later the tumors were examined. Macroscopic inspection of glands injected with either vector showed that the tissue expressing beta-gal was concentrated at the ventral area around the site reached by the tip of the needle. Almost no transgene expression was observed in other sites. Cellularity and lactotrophic cell density was not affected by saline or virus injection. In the injected areas, apoptotic levels were (x +/-S.E.M.): 9.3+/-0.5, 22.1+/-1.1 and 31.7+/-1.4%, for the saline, RAd and HSV groups, respectively. Serum prolactin and growth hormone levels were not affected by virus injection. We conclude that the low diffusibility of viral suspensions in the pituitary tissue may constitute a significant obstacle for achieving full remission of in situ pituitary tumors in rats.
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PMID:Studies on in vivo gene transfer in pituitary tumors using herpes-derived and adenoviral vectors. 1568 May 41

The mammalian securin, pituitary tumor-transforming gene (Pttg), regulates sister chromatid separation during mitosis. Mice deficient in Pttg expression exhibit organ-specific hypoplasia of the testis, spleen, pituitary, and postmaturity pancreatic beta-cells, pointing to a possible adult stem cell defect. Bone marrow stem cells (BMSCs) contribute to bone, cartilage, and fat tissue repair and regeneration, and multipotent adult progenitor cells (MAPCs) have broader differentiation ability. Bone marrow cells derived under MAPC conditions are involved in a spectrum of tissue repair. We therefore tested whether Pttg deletion affects stem cell proliferation and differentiation. BMSCs were isolated under MAPC conditions, although unlike MAPCs, wild-type (WT) and Pttg(-/-) BMSCs do not express octamer-binding transcription factor 4 and are stem cell antigen-I positive. WT and Pttg(-/-) cells did not differ in their ability to differentiate into adipogenic, osteogenic, or hepatocyte-like cells or in phenotypic markers. Cells underwent >100 population doublings, with no observed transforming events. Pttg-null BMSCs replicated 27% slower than WT BMSCs, and under hypoxic conditions, this difference widened. Although apoptosis was not enhanced in Pttg(-/-) cells, Pttg(-/-) BMSC senescence-associated beta-galactosidase activity was elevated, consistent with enhanced p21 protein levels. Using gene array assays, DNA repair genes were shown to be upregulated in Pttg(-/-) BMSCs, whereas genes involved in cell cycle progression, including cyclin D(1), were decreased. Separase, the protease regulated by Pttg, has been implicated in DNA damage repair and was downregulated in Pttg(-/-) BMSCs. Separase was constitutively phosphorylated in Pttg(-/-) cells, a modification likely serving as a compensatory mechanism for Pttg deletion. The results indicate that Pttg deletion reduces BMSC proliferation, renders cells more sensitive to hypoxia, and enhances senescent features, thus pointing to a role for Pttg in the maintenance and proliferation of BMSCs.
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PMID:Discordant proliferation and differentiation in pituitary tumor-transforming gene-null bone marrow stem cells. 1762 43

Understanding factors subserving pituitary cell proliferation enables understanding mechanisms underlying uniquely benign pituitary tumors. Pituitary tumor-transforming gene (Pttg) deletion results in pituitary hypoplasia, low pituitary cell proliferation rates, and rescue of pituitary tumor development in Rb(+/-) mice. Pttg(-/-) pituitary glands exhibit ARF/p53/p21-dependent senescence pathway activation evidenced by up-regulated p19, cyclin D1, and Bcl-2 protein levels and p53 stabilization. High pituitary p21 levels in the absence of PTTG were associated with suppressed cyclin-dependent kinase 2 activity, Rb phosphorylation, and cyclin A expression, all required for cell cycle progression. Although senescence-associated beta-galactosidase was enhanced in Pttg-deficient pituitary glands, telomere lengths were increased. DNA damage signaling pathways were activated and aneuploidy was evident in the Pttg-deficient pituitary, triggering senescence-associated genes. To confirm the p21 dependency of decreased proliferation and senescence in the Pttg-null pituitary, mouse embryonic fibroblast (MEF) colony formation was tested in wild-type, Pttg(-/-), Rb(+/-), Rb(+/-)Pttg(-/-), and Rb(+/-)Pttg(-/-)p21(-/-) cells. Rb(+/-)Pttg(-/-) MEFs, unlike Rb(+/-) cells, failed to produce colonies and exhibited high levels of senescence. p21 deletion from Rb(+/-)Pttg(-/-) MEFs enhanced anchorage-independent cell growth, accompanied by a marked decrease in senescence. As cell proliferation assessed by bromodeoxyuridine incorporation was higher in Rb(+/-)Pttg(-/-)p21(-/-) relative to Rb(+/-)Pttg(-/-) pituitary glands, p21-dependent senescence provoked by Pttg deletion may underlie pituitary hypoplasia and decreased tumor development in Rb(+/-)Pttg(-/-) mice.
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PMID:Senescence mediates pituitary hypoplasia and restrains pituitary tumor growth. 1797 1

As commonly encountered, pituitary adenomas are invariably benign. We therefore studied protective pituitary proliferative mechanisms. Pituitary tumor transforming gene (Pttg) deletion results in pituitary p21 induction and abrogates tumor development in Rb(+/-)Pttg(-/-) mice. p21 disruption restores attenuated Rb(+/-)Pttg(-/-) pituitary proliferation rates and enables high penetrance of pituitary, but not thyroid, tumor growth in triple mutant animals (88% of Rb(+/-) and 72% of Rb(+/-)Pttg(-/-)p21(-/-) vs. 30% of Rb(+/-)Pttg(-/-) mice developed pituitary tumors, P < 0.001). p21 deletion also accelerated S-phase entry and enhanced transformation rates in triple mutant MEFs. Intranuclear p21 accumulates in Pttg-null aneuploid GH-secreting cells, and GH(3) rat pituitary tumor cells overexpressing PTTG also exhibited increased levels of mRNA for both p21 (18-fold, P < 0.01) and ATM (9-fold, P < 0.01). PTTG is abundantly expressed in human pituitary tumors, and in 23 of 26 GH-producing pituitary adenomas with high PTTG levels, senescence was evidenced by increased p21 and SA-beta-galactosidase. Thus, either deletion or overexpression of Pttg promotes pituitary cell aneuploidy and p53/p21-dependent senescence, particularly in GH-secreting cells. Aneuploid pituitary cell p21 may constrain pituitary tumor growth, thus accounting for the very low incidence of pituitary carcinomas.
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PMID:p21(Cip1) restrains pituitary tumor growth. 1898 26

Pituitary tumor transforming gene (PTTG) encodes a securin protein critical in regulating chromosome separation. PTTG-null (PTTG(-/-)) mice exhibit pancreatic beta-cell hypoplasia and insulinopenic diabetes. We tested whether PTTG deletion causes beta-cell senescence, resulting in diminished beta-cell mass. We examined beta-cell mass, proliferation, apoptosis, neogenesis, cell size, and senescence in PTTG(-/-) and WT mice from embryo to young adulthood before diabetes is evident. The roles of cyclin-dependent kinase inhibitors and DNA damage in the pathogenesis of diabetes in PTTG(-/-) mice were also addressed. Relative beta-cell mass in PTTG(-/-) mice began to decrease at 2-3 wk, whereas beta-cell proliferation rate was initially normal but decreased in PTTG(-/-) mice beginning at 2 months. Apoptosis was also much more evident in PTTG(-/-) mice. At 1 month, beta-cell neogenesis was robust in wild-type mice but was absent in PTTG(-/-) mice. In addition, the size of beta-cells became larger and macronuclei were prominent in PTTG(-/-) animals. Senescence-associated beta-galactosidase was also active in PTTG(-/-) beta-cells at 1 month. Cyclin-dependent kinase inhibitor p21 was progressively up-regulated in PTTG(-/-) islets, and p21 deletion partially rescued PTTG(-/-) mice from development of diabetes. mRNA array showed that DNA damage-associated genes were activated in PTTG(-/-) islets. We conclude that beta-cell apoptosis and senescence contribute to the diminished beta-cell mass in PTTG(-/-) mice, likely secondary to DNA damage. Our results also suggest that ductal progenitor beta-cells are exhausted by excessive neogenesis induced by apoptosis in PTTG(-/-) mice.
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PMID:Diminished pancreatic beta-cell mass in securin-null mice is caused by beta-cell apoptosis and senescence. 1921 44

Pituitary tumor transforming gene (PTTG1, securin) is involved in cell-cycle control through inhibition of sister-chromatid separation. Elevated levels of PTTG1 were found to be associated with many different tumor types that might be involved in late stage tumor progression. However, the role of PTTG1 in early stage of tumorigenesis is unclear. Here we utilized the adenovirus expression system to deliver PTTG1 into normal human fibroblasts to evaluate the role of PTTG1 in tumorigenesis. Expressing PTTG1 in normal human fibroblasts inhibited cell proliferation. Several senescence-associated (SA) phenotypes including increased SA-beta-galactosidase activities, decreased bromodeoxyuridine incorporation, and increased SA-heterochromatin foci formation were also observed in PTTG1-expressing cells, indicating that PTTG1 overexpression induced a senescent phenotype in normal cells. Significantly, the PTTG1-induced senescence is p53-dependent and telomerase-independent, which is distinctively different from that of replicative senescence. The mechanism of PTTG1-induced senescence was also analyzed. Consistent with its role in regulating sister-chromatid separation, overexpression of PTTG1 inhibited the activation of separase. Consequently, the numbers of cells with abnormal nuclei morphologies and chromosome separations were increased, which resulted in activation of the DNA damage response. Thus, we concluded that PTTG1 overexpression in normal human fibroblasts caused chromosome instability, which subsequently induced p53-dependent senescence through activation of DNA-damage response pathway.
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PMID:Overexpression of the pituitary tumor transforming gene induces p53-dependent senescence through activating DNA damage response pathway in normal human fibroblasts. 2045 81