Publisher Correction: Menisci protect chondrocytes from load-induced injury.

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Menisci protect chondrocytes from load-induced injury.

Menisci in the knee joint are thought to provide stability, increased contact area, decreased contact pressures, and offer protection to the underlying articular cartilage and bone during joint loading. Meniscal loss or injury is typically accompanied by degenerative changes in the knee, leading to an increased risk for osteoarthritis in animals including humans. However, the detailed mechanisms underlying joint degeneration and the development of osteoarthritis remain largely unknown, and the acute effects of meniscal loss have not been studied systematically. We developed a microscopy-based system to study microscale joint mechanics in living mice loaded by controlled muscular contractions. Here, we show how meniscal loss is associated with rapid chondrocyte death (necrosis) in articular cartilage within hours of injury, and how intact menisci protect chondrocytes in vivo in the presence of intense muscle-based joint loading and/or injury to the articular cartilage. Our findings suggest that loading the knee after meniscal loss is associated with extensive cell death in intact and injured knees, and that early treatment interventions should be aimed at preventing chondrocyte death.

Estimating the electrostatic potential at the acetylcholine receptor agonist site using power saturation EPR.

Continuous wave EPR power saturation was used to measure electrostatic potentials at spin-labeled sites. Membrane surface potentials were estimated by power saturating the EPR spectrum of a membrane bound 14N spin-labeled amphiphile in the presence of a neutral or positively charged 15N labeled aqueous spin probe. The potentials that are measured are in good agreement with other probe measurements and with the predictions of the Gouy-Chapman-Stern theory, indicating that this is a valid approach to determine electrostatic potentials. A spin-labeled affinity probe based on maleimidobenzyltrimethylammonium was synthesized and could be derivatized to a sulfhydryl near either agonist site on the nicotinic acetylcholine receptor. The amplitudes of motion of the spin-probe on the ns time scale are significantly different when the two labeled sites are compared, and the probe is more restricted in its motion when attached to the more easily labeled site. When attached to this agonist site, power saturation EPR yields an electrostatic potential of -15 mV. Two other sulfhydryl-specific probes were used to label this site in reconstituted receptor containing membranes. These probes show less contact with the receptor and reduced electrostatic potentials, indicating that there is a strong spatial dependence to the potential at the agonist site. This work demonstrates that power saturation EPR provides a general method that can be used to estimate electrostatic potentials at any specifically spin-labeled macromolecular site.

Conformation of the gamma subunit at the gamma-epsilon-c interface in the complete Escherichia coli F(1)-ATPase complex by site-directed spin labeling.

Structure-function relationships of the gamma-epsilon-c subunit interface of F(O)F(1) ATP synthase, a region of subunit interactions important in coupling between catalysis and transport, were investigated by site-directed spin labeling and electron paramagnetic resonance (EPR) spectroscopy. The EPR line widths and collision accessibilities of 18 spin-labeled, unique cysteine F(1) mutants from gammaLeu198 to gammaLeu215 indicate an alternating pattern in the mobility and accessibility parameters for positions gamma201-209, which is reminiscent of a beta-strand. Labels at positions gamma204 and gamma210 show tertiary contact upon F(1) binding to F(O) and gammaD210C has reduced coupling efficiency. gammaE208C could not be spin labeled, but the uncoupling effects of gammaE208K are suppressed by second-site mutations in the polar loop of subunit c [Ketchum, C. J. and Nakamoto, R. K. (1998) J. Biol. Chem. 273, 22292-22297]. The restricted mobility and accessibility of spin labels in the odd-numbered positions between gamma201 and gamma207 plus the 2-4-fold higher values in k(cat) for ATP hydrolysis of these same mutant F(1) indicate that the interactions of these residues with the epsilon subunit mediate its inhibitory activity. Disrupted interactions with epsilon subunit also cause reduced coupling efficiency. We propose a model for the gamma-epsilon-c interface of Escherichia coli F(O)F(1) ATP synthase in which side chains from the odd-numbered residues of the gammaLys201-gammaTyr207 beta-strand directly and functionally interact with the epsilon subunit, while the even-numbered, acidic residues gammaAsp204, gammaGlu208, and gammaAsp210 interact with the F(O) sector, probably with subunit c. gamma Subunit interactions with both subunits in this region are important for coupling efficiency.