Direct microsensor measurement of nitric oxide production by the osteoclast.

Nitric oxide (NO) triggers marked osteoclast retraction which closely resembles that due to Ca2+. The effect of Ca2+ has been attributed to a stimulated release of NO. Here, we show for the first time, by direct measurement with a microsensor, that osteoclasts do indeed produce NO and that this production is enhanced by a high Ca2+. We also show that the Ca2+ ionophore, A23187, mimics the latter. Furthermore, osteoclasts on dentine produce more NO than osteoclasts on glass and NO release from dentine-plated osteoclasts is much less sensitive to stimulation by Ca2+. Finally, the microsomal Ca2+ store-depleting agent, thapsigargin, attenuates NO release only from osteoclasts on glass, suggesting that stored Ca2+ has the dominant effect in modulating NO release from non-resorbing cells. NO is a powerful inhibitor of bone resorption: a direct demonstration of its production is therefore strong evidence for a role in modulating osteoclast function.     

Selective antagonism of calcitonin-induced osteoclastic quiescence (Q effect) by human calcitonin gene-related peptide-(Val8Phe37)

Exposure of isolated rat osteoclasts to calcitonin (CT) leads to an abrupt cessation of cell motility (Q effect) followed by cell retraction (R effect). We have previously shown that these effects are mediated by two G proteins that appear to activate separate post-receptor pathways. The present study demonstrates that the Q but not the R effect of CT (0.006 microM) is abolished in the presence of human calcitonin gene-related peptide (CGRP)-(Val8Phe37) (0.5 microM), a fragment analogue of human CGRP. This selective antagonism suggests that the Q effect could result from an action of CT upon a site that is distinct from that producing the R effect. The former site ('amylin site') also appears to interact with related peptides, amylin and CGRP, whilst the latter site ('CT site') specifically interacts with CT.     

'Calcium-activated' intracellular calcium elevation: a novel mechanism of osteoclast regulation

The osteoclast is unique in its capacity to resorb bone. An unbalanced increase in this activity causes osteoporosis, a crippling bone disease that poses a major public health problem. Despite this, our understanding of osteoclast regulation is very limited. Calcitonin is the only known physiological inhibitor of osteoclast function. We demonstrate here for the first time that the concentration of calcium ions at the resorptive site directly regulates osteoclast function by modulating the intracellular free calcium concentration. This represents an important feedback mechanism of osteoclast control.     

依赖于微环境的TGFβ信号

转化生长因子β（transforming growth factor β，TGFβ）家族成员是一类分泌的细胞因子，在胚胎发育、免疫调节、伤口修复、细胞增殖和抑制等过程中发挥重要作用。其中,TGFβ1、TGFβ2和TGFβ3在进化上最晚出现，并以潜伏态分泌。有别于家族中的大多数成员，TGFβ1-3的信号具有时空区域性，并依赖于其所处的微环境。阐明依赖于微环境的TGFβ信号的多层次调控机制对于理解TGFβ信号在免疫、癌症等生理、病理条件下的功能，以及开发临床治疗策略具有重要意义。本文从TGFβ前体复合物的结构入手，并从TGFβ的激活，配体-受体识别，跨膜信号传导及转录调控等方面，论述依赖于微环境的TGFβ信号的调控机制，同时讨论肿瘤微环境中多效的TGFβ信号，进而对今后的研究方向进行展望。     

Effects of organic compounds on the degradation ofp-nitrophenol in lake and industrial wastewater by inoculated bacteria

Many microorganisms fail to degrade pollutants when introduced in different natural environments. This is a problem in selecting inocula for bioremediation of polluted sites. Thus, a study was conducted to determine the success of four inoculants to degradep-nitrophenol (PNP) in lake and industrial wastewater and the effects of organic compounds on the degradation of high and low concentrations of PNP in these environments.Corynebacterium strain Z4 when inoculated into the lake and wastewater samples containing 20 µg/ml of PNP degraded 90% of PNP in one day. Addition of 100 µg/ml of glucose as a second substrate did not enhance the degradation of PNP and the bacterium utilized the two substrates simultaneously. Glucose used at the same concentration (100 µg/ml), inhibited degradation of 20 µg of PNP in wastewater byPseudomonas strain MS. However, glucose increased the extent of degradation of PNP byPseudomonas strain GR. Phenol also enhanced the degradation of PNP in wastewater byPseudomonas strain GR, but had no effect on the degradation of PNP byCorynebacterium strain Z4.Addition of 100 µg/ml of glucose as a second substrate into the lake water samples containing low concentration of PNP (26 ng/ml) enhanced the degradation of PNP and the growth ofCorynebacterium strain Z4. In the presence of glucose, it grew from 2×10⁴ to 4×10⁴ cells/ml in 3 days and degraded 70% of PNP as compared to samples without glucose in which the bacterium declined in cell number from 2×10⁴ to 8×10³ cells/ml and degraded only 30% PNP. The results suggest that in inoculation to enhance biodegradation, depending on the inoculant, second organic substrate many play an important role in controlling the rate and extent of biodegradation of organic compounds.Abbreviations PNP p-nitrophenol