University of Siena

About: University of Siena is a education organization based out in Siena, Italy. It is known for research contribution in the topics: Population & Cancer. The organization has 12179 authors who have published 33334 publications receiving 1008287 citations. The organization is also known as: Università degli studi di Siena & Universita degli studi di Siena.

Aromatase activity and bone homeostasis in men.

Abstract: It is known that sex steroid hormones play an important role in the maintenance of bone mass in males as well as in females. Even though androgens are the major sex steroids in men, their primacy in regulating male skeletal remodeling has been increasingly questioned as direct and indirect evidence emerged suggesting that estrogens may also play a major role in male skeletal health. Recent data suggested that a threshold level of bioavailable estradiol is needed to prevent bone loss, and that with aging an increasing percentage of elderly men begin to fall below this level. The testes account for, at most, 15% of circulating estrogens in the male; the remaining 85% comes from peripheral aromatization of androgen precursors in different tissues, including bone. Human models of aromatase deficiency were the first to demonstrate the critical importance of the conversion of circulating androgens into estrogen in regulating male skeletal homeostasis. All four cases of aromatase-deficient men reported to date showed an identical skeletal phenotype, characterized by tall stature due to continued longitudinal growth, unfused epiphyses, high bone turnover, and osteopenia. Studies using knockout mice along with experimental observations in rats treated with an aromatase inhibitor provided useful information about the importance of aromatase in the male skeleton. Confirmatory evidence comes from recent interventional studies in adult men using aromatase inhibition, which confirmed that estrogens are critically important to the male skeleton by helping to control rates of bone remodeling. Intriguingly, common polymorphisms at the human aromatase (CYP19) gene have been associated with differences in aromatase activity, bone turnover, and rates of bone loss in elderly men, suggesting that variations in aromatase efficiency may also be relevant for skeletal homeostasis. Several additional mechanisms have been proposed in which aromatase activity could be modulated under certain circumstances in different tissues. Additional studies are needed to identify how these genetic, environmental, pathological, and pharmacological influences might modulate aromatase activity in vivo, increasing or reducing estrogen production in males and thereby affecting skeletal health.

miR-29b negatively regulates human osteoclastic cell differentiation and function: implications for the treatment of multiple myeloma-related bone disease.

Abstract: Skeletal homeostasis relies upon a fine tuning of osteoclast (OCL)-mediated bone resorption and osteoblast (OBL)-dependent bone formation. This balance is unsettled by multiple myeloma (MM) cells, which impair OBL function and stimulate OCLs to generate lytic lesions. Emerging experimental evidence is disclosing a key regulatory role of microRNAs (miRNAs) in the regulation of bone homeostasis suggesting the miRNA network as potential novel target for the treatment of MM-related bone disease (BD). Here, we report that miR-29b expression decreases progressively during human OCL differentiation in vitro. We found that lentiviral transduction of miR-29b into OCLs, even in the presence of MM cells, significantly impairs tartrate acid phosphatase (TRAcP) expression, lacunae generation, and collagen degradation, which are relevant hallmarks of OCL activity. Accordingly, expression of cathepsin K and metalloproteinase 9 (MMP9) as well as actin ring rearrangement were impaired in the presence of miR-29b. Moreover, we found that canonical targets C-FOS and metalloproteinase 2 are suppressed by constitutive miR-29b expression which also downregulated the master OCL transcription factor, NAFTc-1. Overall, these data indicate that enforced expression of miR-29b impairs OCL differentiation and overcomes OCL activation triggered by MM cells, providing a rationale for miR-29b-based treatment of MM-related BD.

Bacterial nonspecific acid phosphohydrolases: Physiology, evolution and use as tools in microbial biotechnology

Abstract: Bacterial nonspecific acid phosphohydrolases (NSAPs) are secreted enzymes, produced as soluble periplasmic proteins or as membrane-bound lipoproteins, that are usually able to dephosphorylate a broad array of structurally unrelated substrates and exhibit optimal catalytic activity at acidic to neutral pH values. Bacterial NSAPs are monomeric or oligomeric proteins containing polypeptide components with an M(r) of 25-30 kDa. On the basis of amino acid sequence relatedness, three different molecular families of NSAPs can be distinguished, indicated as molecular class A, B and C, respectively. Members of each class share some common biophysical and functional features, but may also exhibit functional differences. NSAPs have been detected in several microbial taxa, and enzymes of different classes can be produced by the same bacterial species. Structural and phyletic relationships exist among the various bacterial NSAPs and some other bacterial and eucaryotic phosphohydrolases. Current knowledge on bacterial NSAPs is reviewed, together with analytical tools that may be useful for their characterization. An overview is also presented concerning the use of bacterial NSAPs in biotechnology.