Peter Mobbs

Bidirectional control of CNS capillary diameter by pericytes

Neural activity increases local blood flow in the central nervous system (CNS), which is the basis of BOLD (blood oxygen level dependent) and PET (positron emission tomography) functional imaging techniques. Blood flow is assumed to be regulated by precapillary arterioles, because capillaries lack smooth muscle. However, most (65%) noradrenergic innervation of CNS blood vessels terminates near capillaries rather than arterioles, and in muscle and brain a dilatory signal propagates from vessels near metabolically active cells to precapillary arterioles, suggesting that blood flow control is initiated in capillaries. Pericytes, which are apposed to CNS capillaries and contain contractile proteins, could initiate such signalling. Here we show that pericytes can control capillary diameter in whole retina and cerebellar slices. Electrical stimulation of retinal pericytes evoked a localized capillary constriction, which propagated at ∼2 µm s-1 to constrict distant pericytes. Superfused ATP in retina or noradrenaline in cerebellum resulted in constriction of capillaries by pericytes, and glutamate reversed the constriction produced by noradrenaline. Electrical stimulation or puffing GABA (γ-amino butyric acid) receptor blockers in the inner retina also evoked pericyte constriction. In simulated ischaemia, some pericytes constricted capillaries. Pericytes are probably modulators of blood flow in response to changes in neural activity, which may contribute to functional imaging signals and to CNS vascular disease.

ATP Released via Gap Junction Hemichannels from the Pigment Epithelium Regulates Neural Retinal Progenitor Proliferation

The retinal pigment epithelium (RPE) plays an essential role in the normal development of the underlying neural retina, but the mechanisms by which this regulation occurs are largely unknown. Ca2+ transients, induced by the neurotransmitter ATP acting on purinergic receptors, both increase proliferation and stimulate DNA synthesis in neural retinal progenitor cells. Here, we show that the RPE regulates proliferation in the underlying neural retina by the release of a soluble factor and identify that factor as ATP. Further, we show that this ATP is released by efflux through gap junction connexin 43 hemichannels, the opening of which is evoked by spontaneous elevations of Ca2+ in trigger cells in the RPE. This release mechanism is localized within the RPE cells to the membranes facing the neural retina, a location ideally positioned to influence neural retinal development. ATP released from RPE hemichannels speeds both cell division and proliferation in the neural retina.

Spontaneous Ca2+ transients and their transmission in the developing chick retina

The development of the central nervous system is dependent on spontaneous action potentials and changes in [Ca2+]i occurring in neurons [1-4]. In the mammalian retina, waves of spontaneous electrical activity spread between retinal neurons, raising [Ca2+]i as they pass [5-7]. In the ferret retina, the first spontaneous Ca2+ waves have been reported at postnatal day 2 and are thought to result from the Ca2+ influx associated with bursts of action potentials seen in ganglion cells at this time [5-7]. These waves depend on depolarisation produced by voltage-gated sodium channels, but their initiation and/or propagation also depends upon nicotinic cholinergic synaptic transmission between amacrine cells and ganglion cells [8]. Here, we report contrasting results for the chick retina where Ca2+ transients are seen at times before retinal synapse formation but when there are extensive networks of gap junctions. These Ca2+ transients do not require nicotinic cholinergic transmission but are modulated by acetylcholine (ACh), dopamine and glycine. Furthermore, they propagate into the depth of the retina, suggesting that they are not restricted to ganglion and amacrine cells. The transients are abolished by the gap-junctional blocker octanol. Thus, the Ca2+ transients seen early in chick retinal development are triggered and propagate in the absence of synapses by a mechanism that involves several neurotransmitters and gap junctions.

NEUROTRANSMITTER-INDUCED CURRENTS IN RETINAL BIPOLAR CELLS OF THE AXOLOTL, AMBYSTOMA-MEXICANUM

1. Whole‐cell patch clamping was used to study the membrane properties of isolated bipolar cells and the currents evoked in them by putative retinal neurotransmitters. 2. Isolated bipolar cells show an approximately ohmic response to voltage steps over most of the physiological response range, with an average input resistance of 1.3 G omega and resting potential of ‐35 mV. These values are underestimates because of the shunting effect of the seal between the patch electrode and the cell membrane. Depolarization beyond ‐30 mV produces rapid activation (10‐100 ms) of an outward current (carried largely by potassium ions), which then inactivates slowly (0.5‐2 s). 3. Of five candidates for the photoreceptor transmitter, four (aspartate, N‐acetylhistidine, cadaverine, putrescine) had no effect on bipolar cells. The fifth substance, L‐glutamate, opened ionic channels with a mean reversal potential of ‐12 mV in some cells (presumed hyperpolarizing bipolar cells), and closed channels with a mean reversal potential of ‐13 mV in other cells (presumed depolarizing bipolar cells). 4. The conductance increase induced by glutamate in presumed hyperpolarizing bipolar cells was associated with an increase in membrane current noise. Noise analysis suggested a single‐channel conductance for the glutamate‐gated channel of 5.4 pS. The power spectrum of the noise increase required the sum of two Lorentzian curves to fit it, suggesting that the channel can exist in three states. 5. The conductance decrease induced by glutamate in presumed depolarizing bipolar cells was associated with a decrease in membrane current noise that could be described as the sum of two Lorentzian spectra, and which suggested a single‐channel conductance of 11 pS. The noise decrease implies that the channels closed by glutamate are not all open in the absence of the transmitter. 6. GABA (gamma‐aminobutyric acid) and glycine, transmitters believed to mediate lateral inhibition in the retina, open chloride channels in isolated bipolar cells, and increase the membrane current noise. Noise analysis suggested that the channels gated by GABA and glycine have conductances of 4.4 and 7.5 pS respectively. The noise spectra required the sum of two Lorentzian curves to fit them. 7. By whole‐cell patch clamping cells in retinal slices, the synaptic transmitter released by photoreceptors was shown to close channels with an extrapolated reversal potential around ‐3 mV in depolarizing bipolar cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Modulation by zinc of the glutamate transporters in glial cells and cones isolated from the tiger salamander retina

1 Zinc may be released from some presynaptic glutamatergic neurons, including hippocampal mossy fibres and retinal photoreceptors. We whole‐cell‐clamped glial (Müller) cells isolated from the salamander retina to investigate the effect of zinc on glutamate transporters in these cells. Glutamate‐evoked currents in these cells are generated largely by carriers homologous to the mammalian GLAST/EAAT1 transporter. 2 Zinc inhibited both glutamate uptake into the cells, and glutamate release by reversal of the uptake process. The IC50 for inhibition of uptake (< 1 μM) was similar to or below the values for zinc modulating NMDA, α‐amino‐3‐hydroxy‐5‐methylisoxazole‐4‐propionate (AMPA) and GABA receptors, and 100‐fold less than the calculated value for the rise in extracellular zinc concentration evoked by depolarization with potassium in area CA3 of the hippocampus. 3 Although zinc altered the apparent affinity of the transporter for glutamate and Na+, it did not act simply by binding competitively to the glutamate‐, Na+‐, K+‐ or H+‐binding sites on the transporter. Zinc inhibited both forward and reversed glutamate transport from the outside of the cell membrane, but not from the inside. The inhibitory action of zinc on uptake was voltage independent, indicating a zinc‐binding site outside the membrane field. 4 As well as inhibiting glutamate transport, zinc potentiated activation of the anion conductance in the Müller cell glutamate transporter. However, zinc reduced the current mediated by the anion conductance in the cone synaptic terminal glutamate transporter (homologous to the mammalian EAAT5), indicating that zinc has different actions on different glutamate transporter subtypes. 5 By acting on glutamate transporters, zinc may have a neuromodulatory role during synaptic transmission and a neuroprotective role during transient ischaemia.

Gap Junctions Modulate Interkinetic Nuclear Movement in Retinal Progenitor Cells

During early retinal development, progenitor cells must divide repeatedly to expand the progenitor pool. During G1 and G2 of the cell cycle, progenitor cell nuclei migrate back-and-forth across the proliferative zone in a process termed interkinetic nuclear movement. Because division can only occur at the ventricular surface, factors that affect the speed of nuclear movement could modulate the duration of the cell cycle. Gap-junctional coupling and gap junction-dependent Ca2+ activity are common features of proliferating cells in the immature nervous system. Furthermore, both gap-junctional coupling and changes in [Ca2+]i have been shown to be positively correlated with the migration of a number of immature cell types. Using time-lapse confocal microscopy, we describe the nature and rate of progenitor cell interkinetic nuclear movement. We show that nuclear movement is usually, but not always, associated with Ca2+ transients and that buffering of these transients with BAPTA slows movement. Furthermore, we show for the first time that gap-junctional communication is an important requirement for the maintenance of normal nuclear movement in retinal progenitor cells. Conventional blockers of gap junctions and transfection of cells with dominant-negative constructs of connexin 43 (Cx43) and Cx43-specific antisense oligodeoxynucleotides (asODNs) all act to slow interkinetic nuclear movement. The gap junction mimetic peptide Gap26 also acts to slow movement, an effect that we show may be attributable to the blockade of gap junction hemichannels.

Connexin α1 and Cell Proliferation in the Developing Chick Retina

During the formation of the eye, high levels of connexin alpha1 (connexin 43) are expressed within the tissues of the cornea, lens, and neural retina. In order to determine whether connexin alpha1 plays a role in the regulation of cell proliferation we have used a novel antisense technique to reduce its expression early in development (embryonic days 2-4). Application of Pluronic gel, containing antisense oligodeoxynucleotides (ODNs) to connexin alpha1, to one eye of early chick embryos results in a rapid and significant reduction of alpha1 protein which lasts for 24-48 h. Embryos grown for 48 h, after ODN application to one eye, showed a marked reduction in the diameter of the treated, compared to that of the contralateral untreated, eye. Sections cut from the treated eyes showed that the retina was also reduced in size. TUNEL labeling and staining with propidium iodide showed that apoptosis within the retinae of both treated and untreated eyes was rare and thus that the reduction in the area of the retina brought about by antisense ODNs directed at connexin alpha1 was unlikely to be the result of increased cell death. However, the number of mitotic figures in the ventricular zone of the antisense-treated retinae revealed by propidium iodide staining was significantly reduced (P < 0.0001) to 53 +/- 3.5% (n = 5) of that in the contralateral untreated control eyes. Embryos in which one eye was sham operated, treated with pluronic gel, or treated with sense ODN showed no significant changes in eye size or in the number of mitotic figures within the neural retina. These results point to a role for connexin alpha1-mediated gap-junctional communication in controlling the early wave of neurogenesis in the chick retina.

Ca2+ signalling and gap junction coupling within and between pigment epithelium and neural retina in the developing chick

Development of the neural retina is controlled in part by the adjacent retinal pigment epithelium (RPE). To understand better the mechanisms involved, we investigated calcium signalling and gap junctional coupling within and between the RPE and the neural retina in embryonic day (E) 5 chick. We show that the RPE and the ventricular zone (VZ) of the neural retina display spontaneous Ca2+ transients. In the RPE, these often spread as waves between neighbouring cells. In the VZ, the frequency of both Ca2+ transients and waves was lower than in RPE, but increased two‐fold in its presence. Ca2+ signals occasionally crossed the boundary between the RPE and VZ in either direction. In both tissues, the frequency of propagating Ca2+ waves, but not of individual cell transients, was reduced by gap junction blockers. Use of the gap junction permeant tracer Neurobiotin showed that neural retina cells are coupled into clusters that span the thickness of the retina, and that RPE cells are both coupled together and to clusters of cells in the neural retina. Immunolabelling for Cx43 showed this gap junction protein is present at the junction between the RPE and VZ and thus could potentially mediate the coupling of the two tissues. Immunolabelling for β‐tubulin and vimentin showed that clusters of coupled cells in the neural retina comprised mainly progenitor cells. We conclude that gap junctions between progenitor cells, and between these cells and the RPE, may orchestrate retinal proliferation/differentiation, via the propagation of Ca2+ or other signalling molecules.

Development of functional calcium channels in cultured avian photoreceptors.

Vertebrate photoreceptors are unusual neurons in that they are capable of continuous calcium-mediated release of neurotransmitter (Trifonov, 1968; Hagins et al., 1970). In this study, we have examined the development and characteristics of calcium currents in chick cone cells placed in culture on embryonic day 8. Cone cells were identified by their lectin-binding properties, rhodopsin-like immunoreactivity, and the presence of an oil droplet. Using the whole-cell patch-clamp method, we have seen calcium currents in these cells after three days in culture, slightly before the appearance of synapses (Gleason & Wilson, 1989). Because cone calcium currents are blocked by cadmium and nifedipine but are enhanced by Bay K 8644, they most closely resemble L-type current (Nowycky et al., 1985). An unexpected feature of these currents is that their gating ranges varied widely between cells so that some cells showed the foot of their activation range at -70 mV and others as positive as -25 mV. Calcium imaging of fura-2 loaded cells was used to confirm the time course of calcium current development and describe the distribution of cytosolic calcium. As expected, depolarization of young cells failed to increase cytosolic calcium but in older cells an increase of threefold to fourfold was usually observed. Both at rest and during depolarization, most cone cells showed regional differences in internal calcium concentration. In the most mature cones, depolarization strongly elevated cytosolic calcium at the terminal end of the cell while producing a lesser change around the oil droplet and the ellipsoid region, suggesting that calcium channels are localized to the terminal.

CELL COUPLING IN THE RETINA : PATTERNS AND PURPOSE

Gap junction channels (electrical synapses) are a major component of the central nervous system mediating both electrical and metabolic coupling between neurons and glia. Their roles are as diverse as the cell types in which they are expressed and only some of these are reviewed here. In the adult the plastic nature of the gap junction channel allows for changes in the writing of the retinal circuitry that optimize visual processing to suit ambient lighting conditions. Gap junctional communication has been proposed to play a key role in embryonic development in general and in particular during the development of the retina where its roles may include control of neurogenesis, cell specification, synaptogenesis, and the synchronization of the spontaneous electrical activity required for the sharpening of central visual projections. Here we review gap junctional coupling within the retina and present data correlating gap junction expression with development events in the chick retina.