Gary S. Stein

Biosynthesis of Osteogenic Growth Peptide via Alternative Translational Initiation at AUG85 of Histone H4 mRNA

The osteogenic growth peptide (OGP) is an extracellular mitogen identical to the histone H4 (H4) COOH-terminal residues 90–103, which regulates osteogenesis and hematopoiesis. By Northern analysis, OGP mRNA is indistinguishable from H4 mRNA. Indeed, cells transfected with a construct encoding [His102]H4 secreted the corresponding [His13]OGP. These results suggest production of OGP from H4 genes. Cells transfected with H4-chloramphenicol acetyltransferase (CAT) fusion genes expressed both “long” and “short” CAT proteins. The short CAT was retained following an ATG → TTG mutation of the H4 ATG initiation codon, but not following mutation of the in-frame internal ATG85 codon, which, unlike ATG1, resides within a perfect context for translational initiation. These results suggest that a PreOGP is translated starting at AUG85. The translational initiation at AUG85could be inhibited by optimizing the nucleotide sequence surrounding ATG1 to maximally support upstream translational initiation, thus implicating leaky ribosomal scanning in usage of the internal AUG. Conversion of the predicted PreOGP to OGP was shown in a cell lysate system using synthetic [His102]H4-(85–103) as substrate. Together, our results demonstrate that H4 gene expression diverges at the translational level into the simultaneous parallel production of both H4, a nuclear structural protein, and OGP, an extracellular regulatory peptide.

Integrin alphavbeta6 promotes an osteolytic program in cancer cells by upregulating MMP2

The molecular circuitries controlling osseous prostate metastasis are known to depend on the activity of multiple pathways, including integrin signaling. Here, we demonstrate that the αvβ6 integrin is upregulated in human prostate cancer bone metastasis. In prostate cancer cells, this integrin is a functionally active receptor for fibronectin and latency associated peptide-TGFβ1; it mediates attachment and migration upon ligand binding and is localized in focal contacts. Given the propensity of prostate cancer cells to form bone metastatic lesions, we investigated whether the αvβ6 integrin promotes this type of metastasis. We show for the first time that αvβ6 selectively induces matrix metalloproteinase 2, MMP2, in vitro in multiple prostate cancer cells, and promotes osteolysis in vivo in an immunodeficient mouse model of bone metastasis through upregulation of MMP2, but not MMP9. The effect of αvβ6 on MMP2 expression and activity is independent of androgen receptor in the analyzed prostate cancer cells. Increased levels of PTHrP, known to induce osteoclastogenesis, were also observed in αvβ6 expressing cells. However, using MMP2 shRNA, we demonstrate that the αvβ6 effect on bone loss is due to upregulation of soluble MMP2 by the cancer cells, not to changes in tumor growth rate. Another related αv-containing integrin, αvβ5, fails to show similar responses, underscoring the significance of αvβ6 activity. Overall, these mechanistic studies establish that expression of a single integrin, αvβ6, contributes to the cancer cell -mediated program of osteolysis by inducing matrix degradation through MMP2. Our results open new prospects for molecular therapy of metastatic bone disease.The molecular circuitries controlling osseous prostate metastasis are known to depend on the activity of multiple pathways, including integrin signaling. Here, we demonstrate that the αvβ6 integrin is upregulated in human prostate cancer bone metastasis. In prostate cancer cells, this integrin is a functionally active receptor for fibronectin and latency-associated peptide-TGF-β1; it mediates attachment and migration upon ligand binding and is localized in focal contacts. Given the propensity of prostate cancer cells to form bone metastatic lesions, we investigated whether the αvβ6 integrin promotes this type of metastasis. We show for the first time that αvβ6 selectively induces matrix metalloproteinase 2 (MMP2) in vitro in multiple prostate cancer cells and promotes osteolysis in vivo in an immunodeficient mouse model of bone metastasis through upregulation of MMP2, but not MMP9. The effect of αvβ6 on MMP2 expression and activity is independent of androgen receptor in the analyzed prostate cancer cells. Increased levels of parathyroid hormone-related protein (PTHrP), known to induce osteoclastogenesis, were also observed in αvβ6-expressing cells. However, by using MMP2 short hairpin RNA, we demonstrate that the αvβ6 effect on bone loss is due to upregulation of soluble MMP2 by the cancer cells, not due to changes in tumor growth rate. Another related αv-containing integrin, αvβ5, fails to show similar responses, underscoring the significance of αvβ6 activity. Overall, these mechanistic studies establish that expression of a single integrin, αvβ6, contributes to the cancer cell-mediated program of osteolysis by inducing matrix degradation through MMP2. Our results open new prospects for molecular therapy for metastatic bone disease.

Cell Cycle Control of Transcription at the G1/S Phase Transition

Competency for proliferation and cell cycle progression are functionally linked to the activities of regulatory factors that modulate the cell division cycle in response to the multi-directional signals of cell type specific signaling cascades. The parameters that mediate growth control are complex and interdependent, and whether cells grow or cease division reflects the integration of a broad spectrum of positive and negative growth regulatory signals that operate within distinct biological contexts. Equally important from a clinical perspective, fidelity of cell cycle regulatory mechanisms is compromised in transformed and tumor cells and in nonmalignant disorders, and reflects deregulation of cell growth or abrogation of cell death.

Epigenetic Changes Associated with Chromosomal Translocation in Leukemia

Soraya Gutierrez1, Amjad Javed2, Janet Stein3, Gary Stein3, Sandra Nicovani4, Valentina Fernandez1, Ricardo Alarcon1, Marcela Stuardo1, Milka Martinez1, Marcela Hinojosa1 and Boris Rebolledo-Jaramillo1 1Universidad de Concepcion, Departamento de Bioquimica y Biologia Molecular, 2University of Alabama Department of Oral and Maxillofacial Surgery 3University of Massachusetts 4Universidad Santo Tomas; 1,4Chile, 2.3USA