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Browsing by Author "Turner, Charles H"
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Item CD44+/CD24- breast cancer cells exhibit enhanced invasive properties: an early step necessary for metastasis(BMC, 2006) Sheridan, Carol; Kishimoto, Hiromitsu; Fuchs, Robyn K; Mehrotra, Sanjana; Bhat-Nakshatri, Poornima; Turner, Charles H; Goulet, Robert; Badve, Sunil; Nakshatri, HarikrishnaIntroduction A subpopulation (CD44+/CD24-) of breast cancer cells has been reported to have stem/progenitor cell properties. The aim of this study was to investigate whether this subpopulation of cancer cells has the unique ability to invade, home, and proliferate at sites of metastasis. Methods CD44 and CD24 expression was determined by flow cytometry. Northern blotting was used to determine the expression of proinvasive and 'bone and lung metastasis signature' genes. A matrigel invasion assay and intracardiac inoculation into nude mice were used to evaluate invasion, and homing and proliferation at sites of metastasis, respectively. Results Five among 13 breast cancer cell lines examined (MDA-MB-231, MDA-MB-436, Hs578T, SUM1315, and HBL-100) contained a higher percentage (>30%) of CD44+/CD24- cells. Cell lines with high CD44+/CD24- cell numbers express basal/mesenchymal or myoepithelial but not luminal markers. Expression levels of proinvasive genes (IL-1α, IL-6, IL-8, and urokinase plasminogen activator [UPA]) were higher in cell lines with a significant CD44+/CD24- population than in other cell lines. Among the CD44+/CD24--positive cell lines, MDA-MB-231 has the unique property of expressing a broad range of genes that favor bone and lung metastasis. Consistent with previous studies in nude mice, cell lines with CD44+/CD24- subpopulation were more invasive than other cell lines. However, only a subset of CD44+/CD24--positive cell lines was able to home and proliferate in lungs. Conclusion Breast cancer cells with CD44+/CD24- subpopulation express higher levels of proinvasive genes and have highly invasive properties. However, this phenotype is not sufficient to predict capacity for pulmonary metastasis.Item Heritability of Lumbar Trabecular Bone Mechanical Properties in Baboons(2010-03) Havill, LM; Allen, Matthew R.; Bredbenner, DB; Burr, David B.; Nicolella, DP; Turner, Charles H; Warren, DM; Mahaney, MCGenetic effects on mechanical properties have been demonstrated in rodents, but not confirmed in primates. Our aim was to quantify the proportion of variation in vertebral trabecular bone mechanical properties that is due to the effects of genes. L3 vertebrae were collected from 110 females and 46 male baboons (6–32 years old) from a single extended pedigree. Cranio-caudally oriented trabecular bone cores were scanned with microCT then tested in monotonic compression to determine apparent ultimate stress, modulus, and toughness. Age and sex effects and heritability (h2) were assessed using maximum likelihood-based variance components methods. Additive effects of genes on residual trait variance were significant for ultimate stress (h2 = 0.58), toughness (h2 = 0.64), and BV/TV (h2 = 0.55). When BV/TV was accounted for, the residual variance in ultimate stress accounted for by the additive effects of genes was no longer significant. Toughness, however, showed evidence of a non-BV/TV-related genetic effect. Overall, maximum stress and modulus show strong genetic effects that are nearly entirely due to bone volume. Toughness shows strong genetic effects related to bone volume and shows additional genetic effects (accounting for 10% of the total trait variance) that are independent of bone volume. These results support continued use of bone volume as a focal trait to identify genes related to skeletal fragility, but also show that other focal traits related to toughness and variation in the organic component of bone matrix will enhance our ability to find additional genes that are particularly relevant to fatigue-related fractures.Item Parathyroid Hormone Enhances Mechanically Induced Bone Formation, Possibly Involving L-Type Voltage- Sensitive Calcium Channels(2003-04) Li, Jiliang; Duncan, Randall L; Burr, David B.; Gattone, Vincent H; Turner, Charles HPTH and mechanical loading might act synergistically on bone formation. We tested the in vivo effect of the L-type voltage-sensitive calcium channel (VSCC) blocker, verapamil, on bone formation induced by human PTH-(1–34) (PTH) injection with or without mechanical loading. Adult rats were divided into eight groups: vehicle, verapamil, PTH, or verapamil plus PTH with or without mechanical loading. Verapamil (100 mg/kg) was given orally 90 min before loading. PTH (80 μg/kg) was injected sc 30 min before loading. Loading applied to tibia and ulna for 3 min significantly increased the bone formation rate on both the endocortical surface of tibia and the periosteal surface of ulna (P < 0.0001). Treatment with PTH enhanced load-induced bone formation by 53% and 76% (P < 0.001) on the endocortical and periosteal surfaces, respectively. Treatment with verapamil suppressed load-induced bone formation rate by 77% and 59% (P < 0.01). Furthermore, verapamil suppressed bone formation in rats subjected to PTH plus loading by 74% and 68% (P < 0.0001) at the tibia and ulna, respectively. In the groups without loading, neither verapamil nor PTH treatment significantly changed any bone formation parameter. This study indicates that L-type VSCCs mediate load-induced bone formation in vivo. Furthermore, PTH enhances load-induced bone adaptation through involvement of L-type VSCCs.Item Skeletal loading in animals(2001) Robling, Alexander G; Burr, David B.; Turner, Charles HA number of in vivo skeletal loading models have been developed to test specific hypotheses addressing the key mechanical and biochemical signals involved in bone’s adaptive response to loading. Exercise protocols, osteotomy procedures, loading of surgically implanted pins, and force application through the soft tissues are common approaches to alter the mechanical environment of a bone. Although each animal overload model has a number of assets and limitations, models employing extrinsic forces allow greater control of the mechanical environment. Sham controls, for both surgical intervention (when performed) and loading, are required to unequivocally demonstrate that responses to loading are mechanically adaptive. Collectively, extrinsic loading models have fostered a greater understanding of the mechanical signals important for stimulating bone cells, and highlighted the roles of key signaling molecules in the adaptive response.