Michael Kalloniatis

Separate Progenitors for Radial and Tangential Cell Dispersion during Development of the Cerebral Neocortex

Cell lineage analyses suggest that cortical neuroblasts are capable of undertaking both radial and tangential modes of cell movement. However, it is unclear whether distinct progenitors are committed to generating neuroblasts that disperse exclusively in either radial or tangential directions. Using highly unbalanced mouse stem cell chimeras, we have identified certain progenitors that are committed to one mode of cell dispersion only. Radially dispersed neurons expressed glutamate, the neurochemical signature of excitatory pyramidal cells. In contrast, tangential progenitors gave rise to widely scattered neurons that are predominantly GABAergic. These results suggest lineage-based mechanisms for early specification of certain progenitors to distinct dispersion pathways and neuronal phenotypes.

Amino acid neurochemistry of the vertebrate retina.

The dominant neurochemicals involved in encoding sensory information are the amino acid neurotransmitters, glutamate, gamma-aminobutyrate (GABA) and glycine, which mediate fast point-to-point synaptic transmission in the retina and other parts of the central nervous system. The relative abundance of these neurochemicals and the existence of neuronal and glial uptake mechanisms as well as a plethora of receptors support the key role these neurochemicals play in shaping neural information. However, in addition to subserving neurotransmitter roles, amino acids subserve normal metabolic,cellular functions, may be precursors for other amino acids, and may also be associated with protein synthesis. Post-embedding immunocytochemistry of small molecules has allowed the characterization of multiple amino acid profiles within subpopulations of neurons in the vertebrate retina. The general theme emerging from these studies is that the retinal through pathway uses glutamate as its neurotransmitter, and the lateral elements, GABA and/or glycine. Co-localization studies using quantitative immunocytochemistry have shown that virtually all neuronal space can be accounted for by the three dominant amino acids. In addition, co-localization studies have demonstrated that there are no purely aspartate, glutamine, alanine. leucine or ornithine immunoreactive neurons and thus these amino acids are likely to act as metabolites and may sustain glutamate production through a multitude of enzymatic pathways. The mapping of multiple cellular metabolic profiles during development or in degenerating retinas has shown that amino acid neurochemistry is a sensitive marker for metabolic activity. In the degenerating retina, (RCS retina), neurochemical anomalies were evident early in development (from birth), even before photoreceptors mature at PND6-8 implying a generalized metabolic dysfunction. Identification of metabolic anomalies within subpopulation of neurons is now possible and can be used to investigate a multitude of retinal functions including amino acid metabolic and neurochemical changes secondary to external insult as well as to expand our understanding of the intricate interrelationship between neurons and glia.

Endogenous IGF-1 regulates the neuronal differentiation of adult stem cells.

Stem cells from the adult forebrain of mice were stimulated to form clones in vitro using fibroblast growth factor‐2 (FGF‐2). At concentrations above 10 ng/ml of FGF‐2, very few clones gave rise to neurons; however, if FGF‐2 was removed after 5 days, 20–30% of clones subsequently gave rise to neurons. The number of neuron‐containing clones and the number of neurons per clone was significantly enhanced, if insulin‐like growth factor (IGF)‐1 or heparin were added subsequent to FGF‐2 removal. The spontaneous production of neurons after FGF‐2 removal was shown to be due to endogenous IGF‐1, since antibodies to IGF‐1 and an IGF‐1 binding protein totally inhibited neuronal production. Similarly, these reagents also abrogated the neuron‐promoting effects of heparin. Thus, it appears that endogenous IGF‐1 may be a major regulator of stem cell differentiation into neurons. Furthermore, it was found that high levels of IGF‐1 or insulin promoted the maturation and affected the neurotransmitter phenotype of the neurons generated. J. Neurosci. Res. 59:332–341, 2000

Localisation of amino acid neurotransmitters during postnatal development of the rat retina.

We used postembedding immunocytochemistry to determine the localisation of the amino acid neurotransmitters glutamate, γ‐aminobutyrate (GABA), and glycine, potential neurotransmitter precursors (aspartate and glutamine), and taurine in the rat retina during postnatal development. All amino acids investigated were present at birth; however, only the inhibitory neurotransmitters GABA and glycine displayed neuronal localisation. GABA was localised in a sparse population of amacrine cells, and glycine immunoreactivity was found in cells within the ventricular zone that appeared to migrate through the neuroblastic layer. Glutamate labelling was diffuse across the retina until postnatal day (PND) 8. Localisation of glutamine was evident within Müllers cells by PND 6, in agreement with the known age of onset of glutamine synthetase activity. Based on the findings of uptake of radiolabelled glutamate and GABA by PND 8 and changes in immunoreactivity, we propose that Müllers cells evolve at PND 6–8 from their precursor cells, the radial glial cells. Evidence for differences in glutamate turnover in the infant retina was seen on examination of aspartate and glutamine immunoreactivity. Aspartate labelling was weak until PND 11, when ganglion cells and some amacrine cells were labelled. Unlike the mature retina, a large number of amacrine cells were glutamine immunoreactive in the PND 6 retina. One reason for the observed differences in precursor pooling may be a lack of neuronal neurotransmitter release and overall low metabolic activity. We also investigated the response of the developing retina to ischaemic insult to test the physiological hypoxia model of vascular development. Our findings are consistent with the hypothesis that the developing retina has increased tolerance to ischaemic insult. Our findings suggest that, although the retina is morphologically adult like by PND 8, there are differences in neurotransmitter turnover in the immature rat retina. J. Comp. Neurol. 380:449–471, 1997.

Neurochemical architecture of the normal and degenerating rat retina

We used post‐embedding immunocytochemistry to determine the cellular localization of glutamate, γ‐amino butyric acid (GABA), glycine, aspartate, glutamine, arginine, and taurine in the normal and degenerating rat retina. Müllers cell function was also evaluated by determining the uptake and degradation characteristics for glutamate. Immunocytochemical localization of amino acids in adult Royal College of Surgeons (RCS) and control rat retinas were similar with respect to cell classes. Differences in the intensity of labelling for glutamate, aspartate, glutamine, and glycine were observed in several classes of neurons, but the most prominent differences were shown by bipolar cells of the adult RCS rat retina. In addition, glutamine labelling within Müllers cells was higher in the RCS rat than the control. These changes may have occurred because of alterations in the glutamate production or degradation pathways. We tested this hypothesis by determining Müllers cells glutamate uptake and degradation characteristics in adult and postnatal day 16 RCS retinas. High affinity uptake of 3[H]‐glutamate revealed an accumulation of grains over Müllers cell bodies in the adult RCS retina implying glutamate degradation anomalies. We confirmed anomalies in glutamate metabolism in RCS Müllers cells by showing that exogenously applied glutamate was degraded over a longer time course in postnatal day 16 RCS retinas, compared to control retinas. Differences in arginine immunoreactivity in adult and immature RCS retinas conform to the presumed dysfunction of Müllers cells in these degenerating retinas. The anomalies of amino acid localization, uptake and degradation lead us to conclude that Müllers cells in the RCS retina show abnormal function by postnatal day 16; an earlier time to previously reported anatomical and functional changes in this animal model of retinal degeneration.

Retinitis pigmentosa: understanding the clinical presentation, mechanisms and treatment options

Retinitis pigmentosa (RP) is a leading cause of human blindness due to degeneration of retinal photoreceptor cells. Causes of retinal degeneration include defects in the visual pigment, defects in the proteins important for photoreceptor function or in enzymes involved in initiating visual transduction. Despite the diversity of genetic mutations identified in inherited forms of retinal dystrophy, there is a common end result of photoreceptor death and functional blindness. In this review, pertinent anatomical and physiological pathways involved in RP and the underlying genetic mutations are outlined, including a discussion on the inheritance patterns revealed by advances in molecular biological techniques. Characteristics of progression rates of visual field loss and current management options will provide useful clinical guidelines for the management of patients with RP.

Localization of NMDA receptor subunits and mapping NMDA drive within the mammalian retina

Glutamate is a major neurotransmitter in the retina and other parts of the central nervous system, exerting its influence through ionotropic and metabotropic receptors. One ionotropic receptor, the N-methyl-D-aspartate(NMDA) receptor, is central to neural shaping, but also plays a major role during neuronal development and in disease processes. We studied the distribution pattern of different subunits of the NMDA receptor within the rat retina including quantifying the pattern of labelling for all the NRI splice variants, the NR2A and NR2B subunits. The labelling pattern for the subunits was confined predominantly in the outer two-thirds of the inner plexiform layer. We also wanted to probe NMDA receptor function using an organic cation, agmatine (AGB); a marker for cation channel activity. Although there was an NMDA concentration-dependent increase in AGB labelling of amacrine cells and ganglion cells, we found no evidence of functional NMDA receptors on horizontal cells in the peripheral rabbit retina, nor in the visual streak where the type A horizontal cell was identified by GABA labelling. Basal AGB labelling within depolarizing bipolar cells was also noted. This basal bipolar cell AGB labelling was not modulated by NMDA and was completely abolished by the use of L-2-amino-4-phosphono-butyric acid,which is known to hyperpolarize retinal depolarizing bipolar cells. AGB is therefore not only useful as a probe of ligand-gated drive, but can also identify neurons that have constitutively open cationic channels. In combination,the NMDA receptor subunit distribution pattern and the AGB gating experiments strongly suggests that this ionotropic glutamate receptor is functional in the cone-driven pathway of the inner retina.

Reduced glutamate uptake by retinal glial cells under ischemic/hypoxic conditions

The high-affinity uptake of glutamate by glial cells and neurons of the central nervous system, including the retina, serves to inactivate synaptically released glutamate and maintains glutamate at low concentrations in the extracellular space. This uptake prevents accumulation of glutamate extracellularly and thus minimizes the possibility of glutamate neurotoxicity secondary to ischemic insult. One mechanism whereby glutamate neurotoxicity may occur in ischemic/hypoxic insult is through increased extracellular K+ reversing the electrogenic glutamate uptake into retinal glial (Müller) cells. We investigated glial uptake of the amino acids glutamate, GABA, and D-aspartate in the intact isolated rat retina under high extracellular K+ conditions and under conditions simulating ischemia. Immunocytochemical findings showed that uptake of glutamate and GABA by MIller cells in the intact isolated rat retina continues under conditions simulating ischemia and high extracellular K+ conditions, and uptake of D-aspartate also continues under high K+ conditions. However, under high K+ conditions, the glutamate uptake system saturates at a lower concentration of exogenous glutamate than in the normal K+ condition. These findings provide evidence that disruption of glutamate uptake by Müller cells is likely to be a significant contributing factor to excess glutamate accumulation in the extracellular space which can lead to neurotoxicity.

Functional remodeling of glutamate receptors by inner retinal neurons occurs from an early stage of retinal degeneration

Retinitis pigmentosa reflects a family of diseases that result in retinal photoreceptor death and functional blindness. The natural course of retinal changes secondary to photoreceptor degeneration involves anatomical remodeling (cell process alterations and soma displacement) and neurochemical remodeling. Anatomical remodeling predominantly occurs late in the disease process and cannot explain the significant visual deficits that occur very early in the disease process. Neurochemical remodeling includes modified glutamate receptor disposition and altered responses secondary to functional activation of glutamate receptors. We investigated the neurochemical remodeling of retinal neurons in the rd/rd (rd1) mouse retina by tracking the functional activation of glutamate receptors with a cation probe, agmatine. We provide evidence that bipolar cells and amacrine cells undergo selective remodeling of glutamate receptors during the early phases of retinal degeneration. These early neurochemical changes in the rd/rd mouse retina include the expression of aberrant functional ionotropic glutamate receptors on the cone ON bipolar cells from postnatal day 15 (P15), poor functional activation of metabotropic glutamate receptors on both rod and cone ON bipolar cells throughout development/degeneration, and poor functional activation of N‐methyl‐D‐aspartate receptors on amacrine cells from P15. Our results suggest that major neurochemical remodeling occurs prior to anatomical remodeling, and likely accounts for the early visual deficits in the rd/rd mouse retina. J. Comp. Neurol. 514:473–491, 2009.

Spectral sensitivity and adaptation characteristics of cone mechanisms under white-light adaptation.

Increment-threshold spectral-sensitivity (ITSS) functions and threshold-versus-intensity (tvi) curves were measured under white-light adaptation in rhesus monkeys. The tvi curves showed shape and test wavelength invariance, implying that three cone mechanisms were mediating detection. In general, the results were in agreement with the differential adaptation hypothesis proposed by Stiles that predicted spectral shape invariance of the cone mechanisms but overall changes in the shape of the spectral-sensitivity function with increases in the intensity of the adapting field. The principal changes occurring in the ITSS function as the level of adaptation increased involved a smaller loss in sensitivity of the short-wavelength and the long-wavelength peaks compared with the corresponding loss in sensitivity of the middle-wavelength peak. A three-channel model with an opponent L-M mechanism and a nonopponent L-M mechanism (both with S-cone input) and an independent S-cone mechanism described the ITSS data as well as other increment-threshold and suprathreshold data. The model values for the ITSS functions, along with parameters derived from the transformation of these data to cone-contrast coordinates, permitted the factoring out of first-site adaptation, second-site adaptation, and the relative strengths of contribution of the L and M cones within the opponent and nonopponent L-M channels.