Relationship between glycemic control and OPG gene polymorphisms with lower bone mineral density in patients with type 1 Diabetes mellitus

ABSTRACT The aim of the present study was to investigate the bone mineral density (BMD) of patients with type 1 Diabetes mellitus (T1DM). We also assessed the association between osteoprotegerin (OPG) genetic polymorphisms and BMD. Genotyping was performed for 1181G>C and 163A>G OPG polymorphisms by allelic discrimination in 119 patients with T1DM and 161 normoglycemic (NG) individuals, aged 6 to 20 years old. Glycemic control, serum parameters of bone metabolism and BMD were evaluated. T1DM patients showed low BMD, poor glycemic control and decreased total calcium values when compared to controls (p < 0.05). For all the polymorphisms studied, the genotype and allele frequencies in patients with T1DM were not significantly different from the controls. In patients with T1DM, carriers of OPG 1181CC showed higher concentrations of ionized calcium compared to patients with GG+GC genotypes. These results suggest that low BMD is associated with poor glycemic control in T1DM. Despite the lack of a detected association between OPG polymorphisms and BMD in these patients, the increased ionized calcium in those carrying OPG 1181CC suggests a possible increase in osteoclastogenesis, a conclusion that may be supported by the lower BMD observed in these subjects.

Counteracting bone fragility with human amniotic mesenchymal stem cells.

The impaired maturation of bone-forming osteoblasts results in reduced bone formation and subsequent bone weakening, which leads to a number of conditions such as osteogenesis imperfecta (OI). Transplantation of human fetal mesenchymal stem cells has been proposed as skeletal anabolic therapy to enhance bone formation, but the mechanisms underlying the contribution of the donor cells to bone health are poorly understood and require further elucidation. Here, we show that intraperitoneal injection of human amniotic mesenchymal stem cells (AFSCs) into a mouse model of OI (oim mice) reduced fracture susceptibility, increased bone strength, improved bone quality and micro-architecture, normalised bone remodelling and reduced TNFα and TGFß sigalling. Donor cells engrafted into bones and differentiated into osteoblasts but importantly, also promoted endogenous osteogenesis and the maturation of resident osteoblasts. Together, these findings identify AFSC transplantation as a countermeasure to bone fragility. These data have wider implications for bone health and fracture reduction.

IFN-γ directly inhibits TNF-α-induced osteoclastogenesis in vitro and in vivo and induces apoptosis mediated by Fas/Fas ligand interactions.

Cytokines secreted by T cells play a pivotal role in inflammatory bone destruction. Tumor necrosis factor-α (TNF-α) is a major proinflammatory cytokine produced by macrophages following T cell activation, and directly promotes osteoclast differentiation resulting in accelerated bone resorption. Interferon-γ (IFN-γ) attenuates RANKL-initiated cellular signals through osteoclast formation and counterbalances aberrant bone resorption. With respect to this crosstalk during osteoclastogenesis, the direct interruption of IFN-γ in TNF-α-induced osteoclast formation still requires elucidation. We have demonstrated that IFN-γ directly inhibits osteoclastogenesis induced by TNF-α stimulation and accelerates apoptosis mediated by Fas/Fas ligand signals. There were a decreased number of osteoclasts and reduced mRNA levels encoding Nfatc1 in cultured bone marrow macrophages. Apoptotic responses of cultured cells were observed, with accelerated nuclear fragmentation in osteoclast precursor cells and increased FasL mRNA levels in bone marrow cells stimulated with TNF-α evident. IFN-γ reduced the level of osteoclastogenesis in response to TNF-α treatment in vivo. IFN-γ inhibited TNF-α-induced osteoclastogenesis in mice with T cells that had been exposed to anti-CD4 and -CD8 antibodies. These results provide evidence that IFN-γ directly inhibits osteoclastogenesis and induces cells apoptosis by Fas/FasL signals, leading to the indirect regulation of bone resorption, which is required for protective roles in bone destruction at an inflammation site.

Genetics: what's it got to do with family health care?

Genetics is an important contributory factor in many medical conditions. Having an understanding of the genetic basis of diseases can therefore be helpful in identifying and supporting people who have, or are at risk of having, a genetic condition. Most of the current practical applications relate to conditions which are known to have a definite mode of inheritance (for instance cystic fibrosis or familial hypercholesterolaemia) or which are due to chromosomal anomalies (such as Down syndrome). Current research projects are attempting to identify and understand the genetic factors associated with common diseases (such as diabetes and Crohn's disease) but it will be some time before these are likely to be useful clinically. Key skills in the delivery of a holistic family practice service include being able to collect a genetic family history, identifying people at risk and knowing how to refer to specialist services.

In utero transplantation of adult bone marrow decreases perinatal lethality and rescues the bone phenotype in the knockin murine model for classical, dominant osteogenesis imperfecta.

Autosomal dominant osteogenesis imperfecta (OI) caused by glycine substitutions in type I collagen is a paradigmatic disorder for stem cell therapy. Bone marrow transplantation in OI children has produced a low engraftment rate, but surprisingly encouraging symptomatic improvements. In utero transplantation (IUT) may hold even more promise. However, systematic studies of both methods have so far been limited to a recessive mouse model. In this study, we evaluated intrauterine transplantation of adult bone marrow into heterozygous BrtlIV mice. Brtl is a knockin mouse with a classical glycine substitution in type I collagen [alpha1(I)-Gly349Cys], dominant trait transmission, and a phenotype resembling moderately severe and lethal OI. Adult bone marrow donor cells from enhanced green fluorescent protein (eGFP) transgenic mice engrafted in hematopoietic and nonhematopoietic tissues differentiated to trabecular and cortical bone cells and synthesized up to 20% of all type I collagen in the host bone. The transplantation eliminated the perinatal lethality of heterozygous BrtlIV mice. At 2 months of age, femora of treated Brtl mice had significant improvement in geometric parameters (P < .05) versus untreated Brtl mice, and their mechanical properties attained wild-type values. Our results suggest that the engrafted cells form bone with higher efficiency than the endogenous cells, supporting IUT as a promising approach for the treatment of genetic bone diseases.