Stephen R. Bolsover

Spatial gradients of intracellular calcium in skeletal muscle during fatigue

We have measured the distribution of intracellular calcium concentration in isolated single muscle fibres fromXenopus laevis using the fluorescent calcium indicator fura-2 with digital imaging fluorescence microscopy. Under control conditions, resting and tetanic calcium were uniform throughout a fibre. When fatigue was produced using a prolonged, high-frequency tetanus, the distribution of calcium within muscle fibres became non-uniform, with greater levels near the outer parts of a fibre than near the centre. This non-uniform distribution of calcium was rapidly abolished by lowering the stimulation frequency. When fatigue was produced using a series of repeated intermittent tetani, tetanic calcium showed an initial small increase, followed by a decrease as stimulation was continued. The distribution of calcium remained uniform under these conditions. Calcium distribution was also uniform during recovery from intermittent tetanic stimulation. Although fibres varied considerably in their fatigue resistance, the time for tension to fall to 50% was correlated with the reduction in tetanic calcium seen at this time. These results indicate that there are at least two patterns of reduced calcium release that can contribute to the development of fatigue. The appearance of a calcium gradient is consistent with impaired t-tubular conduction, while a uniform reduction of calcium is likely to be due to the action of metabolic factors on systems controlling calcium homeostasis within the cell.

Regeneration-enhancing effects of EphA4 blocking peptide following corticospinal tract injury in adult rat spinal cord.

Spinal cord injury often leads to permanent incapacity because long axons cannot regenerate in the CNS. Eph receptors inhibit axon extension through an effect on the actin cytoskeleton. We have previously reported that after injury EphA4 appears at high levels in stumps of corticospinal axons, while a cognate ligand, ephrinB2, is upregulated at the lesion site so as to confine the injured axons. In this study we have infused lesioned spinal cords with a peptide antagonist of EphA4. In treated animals the retrograde degeneration that normally follows corticospinal tract injury is absent. Rather, corticospinal tract axons sprout up to and into the lesion centre. In a behavioural test of corticospinal tract function, peptide treatment substantially improved recovery relative to controls. These results suggest that blocking EphA4 is likely to contribute to a future successful clinical treatment for spinal cord injury.

CAMs and FGF cause a local submembrane calcium signal promoting axon outgrowth without a rise in bulk calcium concentration

Binding of basic fibroblast growth factor (bFGF) and cell adhesion molecules to the nerve cell membrane promotes axon outgrowth. This response can be blocked by antagonists of voltage‐gated calcium channels, yet no change of cytosolic calcium concentration in the growth cone can be detected upon binding of the growth factor bFGF or the cell adhesion molecule L1. Using barium as a charge carrier, we show that bFGF and L1 open a calcium influx pathway in growth cones of rat sensory neurons without changing the membrane voltage. L1 does not activate influx in cells expressing a dominant negative mutant of the fibroblast growth factor receptor (FGFR) tyrosine kinase. FGFR‐activated influx is blocked by specific antagonists of L‐ and N‐type voltage‐gated calcium channels and by an inhibitor of diacylglycerol lipase. We propose that both L1 and bFGF act via the FGFR to generate polyunsaturated fatty acids which in turn cause calcium channels to flicker open and shut. Short‐lived domains of raised calcium at the cytosolic mouth of open channels activate axon outgrowth without raising bulk cytosolic calcium concentration. In confirmation of this model, the rapidly‐acting calcium buffer BAPTA is significantly more effective at blocking FGF‐induced axon outgrowth when compared with the slower buffer EGTA. Generation of short‐lived calcium domains may provide a crucial mechanism for axon guidance during development and for promoting regeneration of damaged axons.

Monomeric IgE Stimulates NFAT Translocation Into the Nucleus, a Rise in Cytosol Ca2+, Degranulation, and Membrane Ruffling in the Cultured Rat Basophilic Leukemia-2H3 Mast Cell Line

Mast cells are key regulators in allergy and inflammation, and release histamine, cytokines, and other proinflammatory mediators. In the classical view, IgE acts merely to prime mast cells, attaching to FcεRs but not evoking any cell signaling response until cross-linked by the presence of a multivalent allergen. However, several recent studies have reported that IgE alone can promote cell survival and cytokine production in the absence of cross-linking by allergen. In this study we demonstrate that acute addition of monomeric IgE elicits a wide spectrum of responses in the rat basophilic leukemia-2H3 mast cell line, including activation of phospholipases Cγ and D, a rise in cytosol Ca2+, NFAT translocation, degranulation, and membrane ruffling within minutes. Calcium transients persist for hours as long as IgE is present resulting in the maintained translocation of the transcription factor NFAT to the nucleus. Removal of IgE reverses the signaling processes. Our results indicate that, far from simply preparing the cells for a response to allergen, monomeric IgE can stimulate signaling pathways that lead to degranulation, membrane ruffling, and NFAT translocation. The mechanism of activation is likely to be via aggregation of the FcεR1 because activation by IgE can be inhibited with monovalent hapten.

Accumulation of the inhibitory receptor EphA4 may prevent regeneration of corticospinal tract axons following lesion

We have examined the expression of Eph receptors and their ephrin ligands in adult rat spinal cord before and after lesion. Neurons in adult motor cortex express EphA4 mRNA, but the protein is undetectable in uninjured corticospinal tract. In contrast, after dorsal column hemisection EphA4 protein accumulates in proximal axon stumps. One of the ligands for EphA4, ephrinB2, is normally present in the grey matter flanking the corticospinal tract but after injury is markedly up‐regulated in astrocytes in the glial scar. The result is that, after a lesion, corticospinal tract axons bear high levels of EphA4 and are surrounded to front and sides by a continuous basket of cognate inhibitory ephrin ligand. We suggest that a combination of EphA4 accumulation in the injured axons and up‐regulation of ephrinB2 in the surrounding astrocytes leads to retraction of corticospinal axons and inhibition of their regeneration in the weeks after a spinal lesion.

A narrow window of intracellular calcium concentration is optimal for neurite outgrowth in rat sensory neurones

We have examined neurite outgrowth in rat sensory neurones when cytosolic free calcium concentration ([Ca2+]i) was varied in the range 0-60 nM. Neurite outgrowth was maximal at 35 nM [Ca2+]i and was reduced at higher and lower values of [Ca2+]i. These results provide direct evidence for Mattson and Katers suggestion of an optimal calcium range for growth cone function.

Intracellular ion imaging using fluorescent dyes: artefacts and limits to resolution.

Development of highly efficient fluorescent ratio indicators has made imaging of ion concentrations within individual cells possible (Grynkiewicz et al. 1985; Tsien and Poenie 1986). Ion imaging is a complex technique and is therefore prone to artefacts. In this paper we investigate the limits of the technique and its potential pitfalls. The spatial resolution of an imaging system is determined for different cell geometries. We describe a technique to increase the time resolution of existing systems by using a single excitation wavelength to measure changes in ion concentration. We demonstrate examples of potential artefacts arising from hardware limitations, image processing and fundamental optics. Methods for recognition and minimization of these problems are discussed.

Spontaneous activity-independent intracellular calcium signals in the developing spinal cord of the zebrafish embryo

Calcium signals play an important role in a variety of processes necessary for neuronal development. Whilst the characteristics and function of calcium signals have been comprehensively examined in vitro, the significance of these signals during development in an intact embryo remains unclear. In this study, we have examined the spatial and temporal patterns of intracellular calcium signals in precursor cells (cells without processes) within the spinal cord of the intact zebrafish embryo aged between 17 and 27 h. In total, approximately one-third of cells displayed spontaneous intracellular calcium transients. The calcium transients had an average peak amplitude of 33.3 (+/-2.8%) above baseline, a duration of 52.2 (+/-6.3 s) and occurred with an average frequency of 4.6 (+/-0.4 per hour). Calcium transients were observed in precursor cells located throughout the spinal cord, with the highest percentage of active cells (35.1+/-8%) occurring at a developmental time of 21-22 h. Furthermore these intracellular calcium signals were observed in the presence of tricaine, indicating that they are not generated via sodium-dependent action potentials. In precursor cells loaded with the calcium buffer BAPTA both the frequency and the amplitude of the calcium transients was significantly reduced. The intracellular calcium transients may represent a common activity-independent calcium-mediated mechanism that contributes to the regulation of neuronal development in the spinal cord of the zebrafish embryo during the segmentation and early pharyngula period.

Buffering intracellular calcium disrupts motoneuron development in intact zebrafish embryos.

Numerous studies, performed mainly on dissociated cells, have shown that calcium signals have a role during different stages of neuronal development. However, the actions of calcium during neuronal development in vivo remain to be established. The present study has investigated the role of intracellular calcium signals during development of motoneurons in the spinal cord of intact zebrafish embryos. Loading blastomeres of early embryos with either the calcium buffer BAPTA or the calcium reporter dye Calcium Green, was shown to disrupt motoneuron development in the spinal cord of embryos at 24 h postfertilisation. Loading the calcium buffer BAPTA, at an intracellular concentration of 1 mM, into the blastomeres of early embryos did not alter the resting levels of intracellular calcium, but significantly dampened transient rises in intracellular calcium in the cells of later stage embryos. Loading cells with 1 mM BAPTA significantly decreased the number of motoneurons present in the spinal cord at 24 h, indicating that calcium signals are important for normal motoneuron differentiation. Furthermore, in those BAPTA-filled cells that did adopt a motoneuron cell fate, axogenesis was found to be inhibited, suggestive of a role for calcium signalling in neurite initiation. This work provides evidence that calcium signals are necessary at several stages of motoneuron development in vivo.

Use of fluorescent Ca2+ dyes with green fluorescent protein and its variants: problems and solutions.

We have studied the degree to which fluorescent Ca(2+) indicator dyes, and green fluorescent protein and its variants, can be used together. We find that the most commonly used fluorescent protein, enhanced green fluorescent protein (EGFP), seriously contaminates fura 2 signals. We suggest two alternative combinations for which there is no detectable contamination of the Ca(2+) indicator signal by the fluorescent protein. Blue fluorescent protein can be used with the Ca(2+) indicator Fura Red; EGFP can be used with the Ca(2+) indicator X-Rhod 1. The use of these combinations will permit the accurate measurement of Ca(2+) signals in cells transfected with fluorescent proteins.