El factor de crecimiento endotelial vascular (VEGF) y el fragmento N-terminal de la proteína relacionada con la parathormona (PTHrP) regulan la proliferación de células madre mesenquimales humanas / Vascular endothelial growth factor (VEGF) and the N-terminal portion of parathyroid hormone-related protein (PTHrP) regulate the proliferation of human mesenchymal stem cells

El tejido adiposo contiene un gran número de células madre mesenquimales (Adipose Stem Cells, ASCs) que residen en su estroma vascular. Aunque existe controversia acerca de la capacidad de generar tejido óseo de estas células in vivo, in vitro constituyen un buen modelo de diferenciación osteogénica debido a su semejanza fenotípica con las células estromales de la médula ósea (Bone Marrow Stromal Cells, BMSCs) en cultivo. La diferenciación de las poblaciones osteoprogenitoras de la médula ósea está intensamente regulada por factores locales, como el factor de crecimiento endotelial vascular (VEGF) y la proteína relacionada con la parathormona (PTHrP), que modulan la proliferación de estas poblaciones en distintos estadios de diferenciación. Tanto el VEGF como el fragmento N-terminal de la PTHrP ejercen efectos osteogénicos. En este estudio hipotetizamos que sus efectos sobre la proliferación celular de los osteoprogenitores son dependientes del estadio de diferenciación osteoblástica. Tras confirmar su capacidad de diferenciación in vitro por expresión génica de Runx2 y acumulación de calcio, se analizó la respuesta proliferativa a estímulos con VEGF o PTHrP(1-36) de ASCs sometidas o no a inducción osteogénica. VEGF pero no PTHrP(1-36) estimuló la capacidad proliferativa de las ASCs no inducidas mientras que PTHrP(1-36), pero no VEGF, estimuló la proliferación de las ASCs inducidas, corroborando el papel diferencial de estos factores de crecimiento en distintos estadios de diferenciación (AU)

Adipose tissue contains a large number of mesenchymal stem cells (ASCs) residing in their vascular stroma. Although there is controversy regarding the ability to generate bone tissue from these cells in vivo, the in vitro cells offer a good model of osteogenic differentiation due to its phenotypic similarity with the bone marrow stromal cells (BMSCs) in culture. The differentiation of osteo-progenitor populations of bone marrow is intensely regulated by local factors, such as vascular endothelial growth factor (VEGF) and parathyroid hormone-related protein (PTHrP), which modulate these populations' proliferation in different stages of differentiation. Both the VEGF and the N-terminal fragment of the PTHrP exert osteogenic effects. In this study, we posited that its effects on proliferation of osteo-progenitors are stage dependent of osteoblastic differentiation. After confirming its capacity to in vitro differentiation by Runx2 gene expression and accumulation of calcium, the proliferative response to stimuli was analyzed with VEGF or PTHrP (1-36) of ASCs submitted or not to osteogenic induction. VEGF, but not PTHrP (1- 36), stimulated the proliferative capacity of uninduced ASCs, whereas BMSCs, but not VEGF, stimulated the proliferation of induced ASCs, corroborating the differential role of this growth in different stages of differentiation (AU)

El receptor 2 de VEGF (VEGFR2) y el receptor 1 de la PTH (PTH1R) actúan como mediadores de la respuesta antiapoptótica al estímulo mecánico en las células osteocíticas MLO-Y4 / The VEGF (VEGFR2) 2 receptor and PTH (PTH1R) 1 receptor act as mediators in the anti-apoptotic response to mechanical stimulus in MLO-Y4 osteocyte-like cell

La estimulación mecánica juega un papel fundamental en el mantenimiento de la masa ósea. Dicha estimulación previene la apoptosis de los osteocitos por un mecanismo que implica la acumulación de β-catenina y la translocación nuclear de quinasas reguladas por señales extracelulares (ERK). El factor de crecimiento del endotelio vascular (VEGF) y la proteína relacionada con la parathormona (PTHrP) modulan la formación ósea, aunque su interacción con los osteocitos es desconocida. En el presente estudio hemos evaluado el posible papel del receptor 2 del VEGF (VEGFR2) y del receptor tipo 1 de PTH (PTH1R) en la respuesta antiapoptótica a la estimulación mecánica en células osteocíticas MLO-Y4. Las células se sometieron a estrés mecánico por flujo laminar de fluido (10 min, 10 dinas/cm2) o choque hipotónico (240 mOsm, 1h), o estimuladas con VEGF165 o PTHrP (1-36). Además, comparamos los efectos de sobre-expresar VEGFR2 y el estímulo mecánico en estas células. La estimulación mecánica, el VEGF165 o la PTHrP (1-36), de manera similar, estimularon la viabilidad celular y la estabilización de β-catenina, relacionada con su localización en la membrana. Además, la estimulación mecánica aumentó la presencia del PTH1R en la membrana. La inhibición del VEGFR2 así como el antagonista PTHrP (7-34) disminuyeron estos efectos. Por otro lado, la sobre-expresión del VEGFR2 en las células MLO-Y4 mimetizó el efecto del estímulo mecánico sobre la β-catenina y la viabilidad celular. Estos hallazgos apoyan un papel funcional de ambos sistemas, VEGF/VEGFR2 y PTHrP/PTH1R, en la respuesta temprana a la estimulación mecánica para promover la viabilidad osteocítica (AU)

Mechanical stimulation plays a crucial role in bone mineral maintenance. This stimulation prevents osteocyte apoptosis by a mechanism that involves β-catenin accumulation and nuclear translocation of extracellular-signal-regulated kinases (ERKs). The vascular endothelial growth factor (VEGF) and parathyroid hormone-related protein (PTHrP) modulate bone formation, although their interaction with osteocytes is unknown. In this paper we have considered the possible role of VEGF (VEGFR2) 2 receptor and PTH (PTH1R) type 1 receptor in the anti-apoptotic response to mechanical stimulation of MLO-Y4 osteocyte-like cells. The cells were subjected to mechanical stress by laminar fluid flow (10 min, 10 dinas/cm2 ) or hypotonic shock (240 mOsm, 1h), or stimulated with VEGF165 or PTHrP (1-36). We also compared the effects of overexpressed VEGFR2 and mechanical stimulation of these cells. Mechanical stimulation, VEGF165 or PTHrP (1-36) stimulated cellular viability and β-catenin stabilization in a similar manner, associated with its localization in the membrane. Mechanical stimulation increased PTH1R presence in the membrane. VEGFR2 inhibition as well as the PTHrP (7-34) antagonist reduced these effects. On the other hand, VEGFR2 overexpression in MLO-Y4 cells mimicked the mechanical stimulation effect on β-catenin and cellular viability. Our findings support a functional role for both systems, VEGF/VEGFR2 and PTHrP/PTH1R, in the early response to mechanical stimulation in promoting osteocyte-like viability (AU)

La elevada glucosa altera la respuesta anti-apoptótica del estímulo mecánico en osteocitos de ratón MLO-Y4 / High glucose alters the antiapoptotic response to mechanical stimulation in MLO-Y4 osteocytic cells

El estrés oxidativo es clave en el envejecimiento y en los estados diabéticos. La carga mecánica es decisiva para mantener la masa ósea. La respuesta del hueso a los estímulos mecánicos parece reducirse con el envejecimiento y probablemente en la enfermedad ósea provocada por la diabetes. Entender los mecanismos mediante los que el estrés oxidativo afecta a la función de las células óseas, y en concreto a la mecanotransducción en el osteocito, podría proporcionar nuevas dianas moleculares para mejorar los tratamientos actuales y el diseño de otros nuevos para prevenir la pérdida de masa ósea. Nuestros resultados indican que un medio de alta glucosa («diabético») ejerce un efecto negativo sobre la capacidad de los osteocitos para responder a estímulos mecánicos, a través de la interacción con la β-catenina. Además, estos hallazgos sugieren que el estímulo mecánico promueve la viabilidad osteocítica, al menos en parte, a través de la producción de la proteína relacionada con la parathormona (PTHrP) (AU)

Oxidative stress is a key factor in aging and diabetes. Mechanical loading is critical to maintain bone mass. The response of bone to mechanical stimuli appears to be reduced with aging and probably in bone disease caused by diabetes. Understanding the mechanisms by which oxidative stress affects function of bone cells, and specifically to osteocyte mechanotransduction, may provide new molecular targets to improve current treatments and design new treatments to prevent bone loss. Our results indicate that high glucose medium («diabetic ») has a negative effect on the ability of osteocytes to respond to mechanical stimuli affecting b-catenin and apoptosis. Moreover, these findings suggest that the mechanical stimulus promotes viability osteocytic, at least in part, through production of parathyroid hormone related protein (PTHrP) (AU)

The C-terminal fragment of parathyroid hormone-related peptide promotes bone formation in diabetic mice with low-turnover osteopaenia.

BACKGROUND AND PURPOSE: Current data suggest that parathyroid hormone (PTH)-related peptide (PTHrP) domains other than the N-terminal PTH-like domain contribute to its role as an endogenous bone anabolic factor. PTHrP-107-139 inhibits bone resorption, a fact which has precluded an unequivocal demonstration of its possible anabolic action in vivo. We thus sought to characterize the osteogenic effects of this peptide using a mouse model of diabetic low-turnover osteopaenia. EXPERIMENTAL APPROACH: PTHrP-107-139 was administered to streptozotocin-induced diabetic mice, with or without bone marrow ablation, for 13 days. Osteopaenia was confirmed by dual-energy X-ray absorptiometry and microcomputed tomography analysis. Histological analysis was performed on paraffin-embedded bone tissue sections by haematoxylin/eosin and Masson's staining, and tartrate-resistent acid phosphatase immunohistochemistry. Mouse bone marrow stromal cells and osteoblastic MC3T3-E1 cells were cultured in normal and/or high glucose (HG) medium. Osteogenic and adipogenic markers were assessed by real-time PCR, and PTHrP and the PTH(1) receptor protein expression by Western blot analysis. KEY RESULTS: PTHrP-107-139 reversed the alterations in bone structure and osteoblast function, and also promoted bone healing after marrow ablation without affecting the number of osteoclast-like cells in diabetic mice. This peptide also reversed the high-glucose-induced changes in osteogenic differentiation in both bone marrow stromal cells and the more differentiated MC3T3-E1 cells. CONCLUSIONS AND IMPLICATIONS: These findings demonstrate that PTHrP-107-139 promotes bone formation in diabetic mice. This mouse model and in vitro cell cultures allowed us to identify various anabolic effects of this peptide in this scenario.

Comparison of visual outcomes, photopic contrast sensitivity, wavefront analysis, and patient satisfaction following cataract extraction and IOL implantation: aspheric vs spherical acrylic lenses.

PURPOSE: To determine vision quality when testing two acrylic intraocular lenses (IOLs), AcrysofIQ and AcrysofSingle-Piece, after routine cataract extraction and IOL implantation.SettingStorm Eye Institute and Magill Research Center for Vision Correction, Medical University of South Carolina, Charleston, SC, USA. METHODS: Prospective, randomized, double-masked study that included 53 eyes of 27 patients who underwent bilateral cataract extraction and IOL implantation. Patients were randomly divided into two groups depending on the type of IOL implanted: AcrysofIQ or AcrysofSingle-Piece. Preoperative, 1- and 3-month postoperative evaluations included ETDRS visual acuity, photopic contrast sensitivity, pupil size, wavefront testing, and a subjective questionnaire. Comparisons between the two groups and comparisons to baseline were made at each visit. P<0.05 was considered statistically significant. RESULTS: Preoperative, statistically significant differences were evident in response to the subjective questionnaire (near activities, driving dimensions, and overall score) between the two groups. Postoperatively there was a greater increase in contrast sensitivity at 1 and 3 months in the AcrysofIQ group when compared to baseline. Patients with AcrysofIQ IOL had a significant reduction in total high-order aberrations (HOA) and spherical aberration (SA) when compared to those patients with AcrysofSingle-Piece at 1 and 3 months and to baseline. Postoperative patient satisfaction showed no difference among the groups. CONCLUSION: The use of a new aspheric acrylic IOL may improve the quality of vision as a result of the reduction of total HOA and SA.

Diabetes Mellitus y pérdida de masa ósea / Diabetes Mellitus and bone mass loss

La diabetes mellitus es una enfermedad que afecta a unos 200 millones de personas en el mundo. Estudios epidemiológicos y experimentales demuestran la existencia de una pérdida de masa ósea asociada a la diabetes de tipo 1. Esta pérdida parece estar mediada por diversos factores endocrinos y/o locales, entre los que se incluyen: la insulina, el factor similar a la insulina tipo 1 (IGF-1), péptidos pancreáticos (amilina, leptina y preptina), hormonas intestinales (GLP-1 y GLP-2) y la vitamina D. Sin embargo, en la diabetes tipo 2 no existen datos concluyentes que la relacionen con una disminución de la masa ósea

Diabetes mellitus is a disease affecting about 200 million people worldwide. Both epidemiological and experimental studies have demonstrated the existence of a diabetes-related bone loss in type 1 diabetic patients. This relationship seems to be mediated by different endocrine and local factors, namely insulin, insulin-like growth factor 1 (IGF-1), pancreatic peptides (amylin, leptin, and preptin), intestinal hormones (GLP-1 y GLP-2), and vitamin D. However, no such relationship has been demonstrated in type 2 diabetes