Purification and crystallization of a dimeric form of acetylcholinesterase from Torpedo californica subsequent to solubilization with phosphatidylinositol-specific phospholipase C

A dimeric form of acetylcholinesterase from Torpedo californica was purified to homogeneity by affinity chromatography subsequent to solubilization with a phosphatidylinositol-specific phospholipase C of bacterial origin. Bipyramidal crystals of the enzyme were obtained from solutions in polyethylene glycol 200. The crystals diffract to 2.0 A (1 A = 0.1 nm) resolution. They were found to be orthorhombic, space group P2221, with a = 163.4(+/- 0.2) A, b = 112.1(+/- 0.2) A, c = 81.3(+/- 0.1) A.     

Gangliosides stimulate astroglial cell proliferation in the absence of serum

Previous studies with microcultures of astroglial (AG) cells from newborn rat cerebrum had shown an ability of gangliosides to interact with AG cells cultured under defined conditions. We have now investigated the capability of gangliosides to stimulate DNA synthesis and cell number increases in similar secondary microcultures of newborn rat cerebrum AG cells. At a concentration of 6 X 10(-5)M, GM1 ganglioside stimulated DNA synthesis and increased cell numbers, with DNA synthesis leading cell increases by 12-24 hr. The ganglioside-induced AG cell proliferative response occurred with GD1a, GD1b and GT1b, GT1b being the most potent at 10(-5)M--while asialo GM1 and sialic acid were without effect. In the standard test cultures, DNA synthesis declined very steeply after the first day, with cell numbers stabilizing at the level reached after 2 days. Ganglioside was not itself responsible for the restricted proliferative response, as serum produced the same behaviors.     

Regulation of Na+,K+ pump activity by nerve growth factor in chick embryo dorsal root ganglion cells

Nerve growth factor (NGF) is required for the growth and development of sensory and sympathetic neurons. Incubation of chick dorsal root ganglionic cells without NGF resulted in a decrease of active (Na+,K+-pump-mediated) K+ influx over a period of several hours. Addition of NGF to NGF-deprived cells caused 1) a return of the active K+ influx to the values occurring in cells continuously exposed to NGF, preceded by 2) a very rapid, but transient overstimulation of the Na+,K+-pump-mediated K+ influx. Restoration of normal Na+,K+-pump activity occurred at NGF concentrations of 1 biological unit/ml or greater, whereas the NGF concentration in the 1-100 biological unit/ml range affected the rapidity with which the pump restoration took place. The transient pump behavior was only observed in NGF-deprived cells and could not be elicited in NGF-supported steady-state cells or in cells having already received delayed NGF once. This transient Na+,K+-pump behavior was exclusively displayed in conjunction with a high intracellular Na+ concentration. Decreasing the external Na+ concentration below 70 mM reduced the hyperstimulation response to NGF, until at 10 mM Na+ the delayed presentation of NGF caused no overshoot at all. The effect of NGF on the Na+,K+-pump was specific for the NGF molecule and could not be mimicked by other proteins.     

Short-latency ionic effects of nerve growth factor deprivation and readministration on ganglionic cells

Nerve growth factor (NGF) is likely to exert its trophic action on dorsal root ganglion (DRG) and on sympathetic ganglion neurons by controlling a crucial function of these cells. This function would in turn regulate other cellular machineries and, ultimately, lead to the traditional NGF consequences, such as survival and neuritic growth. A corollary of this view is that the key to NGF action must lie in short-latency events, occurring within minutes of NGF administration. Chick embryo DRG dissociates have proved to be an effective experimental system to investigate short-latency responses to NGF, in that (1) measurable functional deficits develop over 6 h of NGF deprivation in vitro and (2) delayed presentation of NGF promptly and fully restores the defective function. The first deficit observed in this experimental system, a decline in RNA-labeling capability, led to the recognition that NGF controls the transport of selected exogenous substrates, all of which are Na⁺-coupled and depend on an Na⁺ gradient across the neuronal membrane. Subsequent work showed that NGF controlled such transport systems by actually regulating the neuronal ability to control intracellular Na⁺. Under NGF deprivation, the DRG cells accumulate Na⁺ to levels that reflect, and presumably equate, the extracellular Na⁺ concentrations. Conversely, on delayed NGF administration, the accumulated Na⁺ is actively extruded to an extent and at a speed that depends on the NGF concentration. The Na⁺ response is elicited by both Beta and 7S NGF, but not by other proteins tested. All ganglionic systems that display a requirement for exogenous NGF in culture have also displayed the Na⁺ response to NGF. The Na⁺ response is grossly paralleled by a K⁺ response. DRG dissociates, in which intracellular K⁺ has been pre-equilibrated with extracellular ⁸⁶Rb⁺, lose their ⁸⁶Rb⁺ over 6 h of NGF deprivation and restore it on delayed NGF administration. The regulation by NGF of mechanisms controlling intracellular Na⁺ and K⁺ levels in their target neurons is likely to occupy an early and fundamentl place in the sequence of events underlying the mode of action of this factor.