Summary
Increased fragility has been described in humans with polycythemia vera (PV). Herein, we describe an osteoporotic phenotype associated with decreased osteoblast activity in a mouse model of ...PV and another mouse of polycythemia and elevated circulating erythropoietin (EPO). Our results are important for patients with PV or those treated with recombinant EPO (rEPO).
Introduction
PV and other myeloproliferative syndromes have been recently associated with an increased risk for fractures. However, the presence of osteoporosis in these patients has not been well documented. EPO, a hormone primarily known to stimulate erythropoiesis, has been shown recently to regulate bone homeostasis in mice. The aim of this study was to examine the bone phenotype of a mouse model of PV and compare it to that of animals with polycythemia caused by elevated circulating EPO.
Methods
Bone mass and remodeling were evaluated by micro-computed tomography and histomorphometry. The JAK2
V617F
knock-in mouse, a model of human PV, manifests polycythemia and low circulating EPO levels. Results from this mouse were compared to wild type (wt) controls and the tg6 transgenic mouse that shows polycythemia caused by increased constitutive expression of EPO.
Results
Compared to wt, both JAK2
V617F
and tg6 mice had a decrease in trabecular bone mass. Tg6 mice showed an additional modest decrease in cortical thickness and cortical bone volume per tissue volume (
P
< 0.01) suggesting a more severe bone phenotype than JAK2
V617F
. Decreased osteoblast numbers and bone formation along with normal osteoclast numbers and activity were found in both mice.
Conclusions
This study indicates that PV is associated with low bone mass and decreased osteoblast activity in mice. Our results support future studies of osteoporosis in affected humans. Polycythemia caused by chronically elevated circulating EPO also results in bone loss, and implications on patients treated with rEPO should be evaluated.
Non-transfusion-dependent thalassemias include a variety of phenotypes that, unlike patients with beta (β)-thalassemia major, do not require regular transfusion therapy for survival. The most ...commonly investigated forms are β-thalassemia intermedia, hemoglobin E/β-thalassemia, and α-thalassemia intermedia (hemoglobin H disease). However, transfusion-independence in such patients is not without side effects. Ineffective erythropoiesis and peripheral hemolysis, the hallmarks of disease process, lead to a variety of subsequent pathophysiologies including iron overload and hypercoagulability that ultimately lead to a number of serious clinical morbidities. Thus, prompt and accurate diagnosis of non-transfusion-dependent thalassemia is essential to ensure early intervention. Although several management options are currently available, the need to develop more novel therapeutics is justified by recent advances in our understanding of the mechanisms of disease. Such efforts require wide international collaboration, especially since non-transfusion-dependent thalassemias are no longer bound to low- and middle-income countries but have spread to large multiethnic cities in Europe and the Americas due to continued migration.
Gene addition strategies are rational approaches to the treatment of sickle cell anemia and thalassemia. The goal of such genetic treatments is to introduce a functional globin transcription unit in ...hematopoietic stem cells and express the transgene in a manner that is erythroid-specific, elevated, relatively constant from one cell to another, and sustained over time. Gene transfer is mediated by an expanding array of viral and nonviral vectors. High-titer retroviral vectors harboring the human beta-globin gene and the core sequences of the human beta-globin locus control region yield erythroid-specific gene expression in erythroid cell lines and in short-term murine bone marrow chimeras. However, we show that expression remains subject to position effect variegation and often decreases over time in vivo. Rather than a progressive transcriptional silencing in all cells, we ascribe the waning expression to the gradual emergence in blood of erythroid progeny derived from more and more primitive precursor cells in the months after transplantation. In our model, transgene expression is therefore determined by the integration site and the differentiation stage of the transduced cell at the time of integration. Globin expression is thus different in the progeny of a transduced erythroid progenitor cell and in the erythroid progeny of a transduced hematopoietic stem cell, reflecting the effect of flanking chromatin in differentiated cells and of chromatin remodeling at the site of integration in the progeny of multipotential cells. This model predicts that insulators and matrix attachment regions could be highly valuable to gene therapy in combination with potent transcriptional activators. When efficient gene transfer in hematopoietic stem cells is achieved at last, the challenge will be to regulate gene expression in vivo and overcome transgene variegation and transgene silencing.