Functional and structural properties of stannin: roles in cellular growth, selective toxicity, and mitochondrial responses to injury.

Stannin (Snn) was discovered using subtractive hybridization methodology designed to find gene products related to selective organotin toxicity and apoptosis. The cDNAs for Snn were first isolated from brain tissues sensitive to trimethyltin, and were subsequently used to localize, characterize, and identify genomic DNA, and other gene products of Snn. Snn is a highly conserved, 88 amino acid protein found primarily in vertebrates. There is a minor divergence in the C-terminal sequence between amphibians and primates, but a nearly complete conservation of the first 60 residues in all vertebrates sequenced to date. Snn is a membrane-bound protein and is localized, in part, to the mitochondria and other vesicular organelles, suggesting that both localization and conservation are significant for the overall function of the protein. The structure of Snn in a micellar environment and its architecture in lipid bilayers have been determined using a combination of solution and solid-state NMR, respectively. Snn structure comprised a single transmembrane domain (residues 10-33), a 28-residue linker region from residues 34-60 that contains a conserved CXC metal binding motif and a putative 14-3-3xi binding region, and a cytoplasmic helix (residues 61-79), which is partially embedded into the membrane. Of primary interest is understanding how this highly-conserved peptide with an interesting structure and cellular localization transmits both normal and potentially toxic signals within the cell. Evidence to date suggests that organotins such as trimethyltin interact with the CXC region of Snn, which is vicinal to the putative 14-3-3 binding site. In vitro transfection analyses and microarray experiments have inferred a possible role of Snn in several key signaling systems, including activation of the p38-ERK cascade, p53-dependent pathways, and 14-3-3xi protein-mediated processes. TNFalpha can induce Snn mRNA expression in endothelial cells in a PKC-epsilon dependent manner. Studies with Snn siRNA suggest that this protein may be involved in growth regulation, since inhibition of Snn expression alone leads to reduced endothelial cells growth and induction of COP-1, a negative regulator of p53 function. A key piece of the puzzle, however, is how and why such a highly-conserved protein, localized to mitochondria, interacts with other regulatory proteins to alter growth and apoptosis. By knowing the structure, location, and possible signaling pathways involved, we propose that Snn constitutes an important sensor of mitochondrial damage, and plays a key role in the mediation of cross-talk between mitochondrial and nuclear compartments in specific cell types.

Two phases of increased cell death in the inner retina following early elimination of the ganglion cell population.

Neurons in the inner nuclear layer (INL) of the vertebrate retina undergo considerable programmed cell death during development, but the determinants of this cell death remain largely unknown. The present study examines the role of retinal ganglion cells in support of INL neurons in the developing ferret retina. The retinal ganglion cell population was eliminated by optic nerve transection at postnatal day (P) 2, and the incidence of cell death was examined using terminal deoxytransferase dUTP nick-end labelling (TUNEL) at various ages during the first 3 postnatal weeks. Significant increases in TUNEL-positive cells were observed in the neuroblast layer (NBL) as early as P3, prior to synapse formation within the inner plexiform layer (IPL), and again in the INL at P22, the normal peak of naturally occurring cell death within the ferret's INL. A decrease in TUNEL-positive cells was found in the NBL at P8. These results show three phases of response to the loss of retinal ganglion cells and suggest that cells in the NBL/INL are normally dependent on retinal ganglion cells for their survival. Recent studies have shown that certain populations of retinal neurons are reduced in adult animals that had lost the population of ganglion cells during early development, so the present study also examined when this reduction could first be detected. The number of parvalbumin-immunoreactive amacrine cells was decreased significantly in the NBL of the manipulated eye as early as P8, when we could first label this population, and this difference persisted through adulthood. The fact that cell death in the NBL has already increased within 24 hours of ganglion cell elimination, coupled with the specificity of this effect on the adult complement of INL cell types, shows that cell-cell interactions controlling survival are already highly specific for particular types of retinal neuron early in development

Organization of the inner retina following early elimination of the retinal ganglion cell population: effects on cell numbers and stratification patterns.

The present study has examined the effects of early ganglion cell elimination upon the organization of the inner retina in the ferret. The population of retinal ganglion cells was removed by optic nerve transection on the second postnatal day, and retinas were subsequently studied in adulthood. Numbers of amacrine and bipolar cells were compared in the nerve-transected and nerve-intact retinas of operated ferrets, while stratification patterns within the inner plexiform layer were compared in these and in normal ferret retinas. Early ganglion cell elimination was found to produce a 25% reduction in the population of glycine transporter-immunoreactive amacrine cells, and 18 and 15% reductions in the populations of parvalbumin and calbindin-immunoreactive amacrine cells, respectively. GABAergic amacrine cells were also reduced by 34%. The number of calbindin-immunoreactive displaced amacrine cells, by contrast, had increased in the ganglion cell-depleted retina, being three times their normal number. Other amacrine and bipolar cell types were unaffected. Despite these changes, the stratification patterns associated with these cell types remained largely intact within the inner plexiform layer. The present results demonstrate a class-specific dependency of inner retinal neurons upon the ganglion cell population in early postnatal life, but the ganglion cells do not appear to provide any critical signals for stratification within the inner plexiform layer, at least not after birth. Since they themselves do not produce stratified dendritic arbors until well after birth, the signals for stratification of the bipolar and amacrine cell processes should arise from other sources.

Developmental patterns of protein expression in photoreceptors implicate distinct environmental versus cell-intrinsic mechanisms.

The present study has examined the spatial and temporal expression patterns of various proteins associated with the structure and function of mature photoreceptor outer segments in the developing ferret's retina using immunocytochemistry and RT-PCR. One set of proteins, including rod opsin, arrestin, and recoverin, was detected progressively in photoreceptors as they became postmitotic, being expressed well before the differentiation of outer segments. A second set of proteins, including beta- and gamma-transducin, cGMP-phosphodiesterase, phosducin, rhodopsin kinase, rod cGMP-gated cation channel protein, and peripherin, displayed a contrasting temporal onset and pattern of spatial emergence. These latter proteins first became detectable either shortly before or coincident with outer segment formation, and were expressed simultaneously in both older and younger photoreceptor cells. A third set, the short wavelength-sensitive (SWS) and medium wavelength-sensitive (MWS) cone opsin proteins, was the last to be detected, but materialized in a spatio-temporal pattern reminiscent of the neurogenetic gradient of the cones. These different spatial and temporal patterns indicate that cellular maturation must play a primary role in regulating the onset of expression of some of these proteins, while extrinsic signals must act to coordinate the expression of other proteins across photoreceptors of different ages.

Disruption of transient photoreceptor targeting within the inner plexiform layer following early ablation of cholinergic amacrine cells in the ferret.

Photoreceptors in the ferret's retina have been shown to project transiently to the inner plexiform layer (IPL) prior to their differentiation of an outer segment. On postnatal day 15 (P-15), when this projection achieves maximal density, the photoreceptors projecting into the IPL extend primarily to one of two depths, coincident with the processes of cholinergic amacrine cells. The present study has used an excitotoxic approach employing subcutaneous injections of L-glutamate to ablate these cholinergic amacrine cells on P-7, in order to see whether their elimination alters this targeting of photoreceptor terminals within the IPL. The near-complete elimination of cholinergic amacrine cells at P-15 was confirmed, although the population of retinal ganglion cells was also affected, being depleted by roughly 50%. The rod opsin-immunopositive terminals in such treated ferrets no longer showed a stratified distribution, being found throughout the depth of the IPL, as well as extending into the ganglion cell layer. This effect should not be due to the partial loss of retinal ganglion cells, however, since optic nerve transection at P-2, which eliminates the ganglion cells entirely while leaving the cholinergic amacrine cell population intact, was shown not to affect the stratification pattern of the photoreceptors within the IPL. These results strongly suggest that the targeting of the photoreceptor terminals to discrete strata within the IPL is dependent upon the cholinergic amacrine cell processes.

Development of cholinergic amacrine cell stratification in the ferret retina and the effects of early excitotoxic ablation.

The present study has examined the emergence of cholinergic stratification within the developing inner plexiform layer (IPL), and the effect of ablating the cholinergic amacrine cells on the formation of other stratifications within the IPL. The population of cholinergic amacrine cells in the ferret's retina was identified as early as the day of birth, but their processes did not form discrete strata until the end of the first postnatal week. As development proceeded over the next five postnatal weeks, so the positioning of the cholinergic strata shifted within the IPL toward the outer border, indicative of the greater ingrowth and elaboration of processes within the innermost parts of the IPL. To examine whether these cholinergic strata play an instructive role upon the development of other stratifications which form within the IPL, one-week-old ferrets were treated with L-glutamate in an attempt to ablate the population of cholinergic amacrine cells. Such treatment was shown to be successful, eliminating all of the cholinergic amacrine cells as well as the alpha retinal ganglion cells in the central retina. The remaining ganglion cell classes as well as a few other retinal cell types were partially reduced, while other cell types were not affected, and neither retinal histology nor areal growth was compromised in these ferrets. Despite this early loss of the cholinergic amacrine cells, which are eliminated within 24 h, other stratifications within the IPL formed normally, as they do following early elimination of the entire ganglion cell population. While these cholinergic amacrine cells are present well before other cell types have differentiated, apparently neither they, nor the ganglion cells, play a role in determining the depth of stratification for other retinal cell types.

Extrinsic modulation of retinal ganglion cell projections: analysis of the albino mutation in pigmentation mosaic mice.

Tyrosinase is a key enzyme involved in the synthesis of melanin in the retinal pigment epithelium (RPE). Mice that are homozygous for the albino allele at the tyrosinase locus have fewer retinal ganglion cells with uncrossed projections at the optic chiasm. To determine the site of the albino gene action we studied the projections of retinal ganglion cells in two types of pigmentation mosaic mice. First, we generated mosaic mice that contain a translocated allele of the wild-type tyrosinase on one X chromosome but that also have the lacZ reporter transgene on the opposite X chromosome. In these lacZ/tyrosinase mice, which are homozygous for the albino allele on chromosome 7, X-inactivation ensures that tyrosinase cannot be functional within 50% of the retinal ganglion cells and that these individual cells can be identified by their expression of the lacZ reporter gene product, beta-galactosidase. The proportion of uncrossed retinal ganglion cells expressing beta-galactosidase was found to be identical to the proportion that did not express it, indicating that the albino mutation associated with axonal behavior at the optic chiasm must affect ganglion cells in a cell-extrinsic manner. Second, to determine whether the RPE is the source of the extrinsic signal, we generated aggregation chimeras between pigmented and albino mice. In these mosaic mice, the extent of the uncrossed projection corresponded with the amount of pigmented cells within the RPE, but did not correspond with the genotypes of neural retinal cells. These studies demonstrate that the albino mutation acts indirectly upon retinal ganglion cells, which in turn respond by making axonal guidance errors at the optic chiasm.

Rods and cones project to the inner plexiform layer during development.

Mature rod and cone photoreceptor cells extend terminals to the outer plexiform layer (OPL), where they form characteristic spherules or pedicles, synapsing with the second-order neurons of the inner nuclear layer (INL). The present study demonstrates that, prior to the formation of this connectivity, immature rods and cones in the ferret extend processes beyond the level of the horizontal cells and future OPL, reaching the inner plexiform layer (IPL). The number of processes extending to the IPL increases steadily as the population of photoreceptor cells expands postnatally, reaching a maximum 2 weeks after birth. These processes are immunopositive for synaptophysin, and they terminate in two strata occupied by the dendrites of amacrine cells and ganglion cells. The frequency of these processes declines rapidly during the third postnatal week, and they are no longer detectable by the fourth postnatal week. Their loss is neither a consequence of photoreceptor cell death nor is it due to selective protein trafficking mechanisms that render them immunonegative. Rather, these processes retract to the level of the OPL during this period, coincident with the maturation of bipolar and horizontal cell processes. These results demonstrate that, despite the clear presence of environmental signals presaging the formation of the OPL, photoreceptor terminals initially ignore them to grow beyond this level of the retina. Rather, they detect and respond to signals within the IPL during this period, terminating in proximity to the processes of other cells in the inner retina, where they may contribute to transient retinal circuitry during early development.

Rational use of cholinesterase activity testing in pesticide poisoning.

BACKGROUND: The use of acetylcholinesterase (AChE) activity testing in pesticide poisoning often falls on family physicians when evaluating a suspected poisoning or when monitoring the health of pesticide applicators. METHODS: A review of the literature and consideration of three illustrative cases shows misunderstandings in the pathophysiology of the enzyme and in procedures for effective testing and monitoring of AChE levels. RESULTS AND CONCLUSIONS: The physiologic characteristics of acetylcholine neurotransmission are described and related to carbamate and organophosphate poisoning. Pre-exposure monitoring is described using the California plan. A 23 percent variance in AChE levels exists among normal patients. It is necessary, therefore, to establish baseline levels to overcome individual variance. The practice of measuring of AChE levels in acute poisoning is limited. In employees who have been monitored and for whom baseline AChE levels have been established, a diagnosis of poisoning can be made by comparing postexposure AChE levels with baseline levels. If there is no baseline level recorded, and if the offending chemical is in question, the clinician must base treatment on the clinical signs and symptoms.

Cloning and expression of mouse Cadherin-7, a type-II cadherin isolated from the developing eye.

We report the molecular cloning of Cadherin-7 from the embryonic mouse eye. The deduced amino acid sequence shows it to be a type-II cadherin similar to Xenopus F-cadherin and chick Cadherin-7. The mouse Cadherin-7 gene maps to chromosome 1, outside the conserved linkage group of cadherin genes on chromosome 8. Cadherin-7 is expressed throughout the entire period of neural development and mRNA levels are developmentally regulated in both the embryonic and the postnatal central nervous system (CNS). In adult mice, Cadherin-7 expression is restricted to the CNS, with highest levels in the retina. In the developing eye, Cadherin-7 mRNA is found only in the neural retina. It is expressed by all retinal neuroblasts from E11 onward, but becomes progressively restricted to neurons in the inner neuroblast and developing ganglion cell layers (GCL). In the adult retina it is confined to subpopulations of cells in the GCL and to amacrine cells in the inner part of the inner nuclear layer. This expression pattern suggests a role for Cadherin-7 in mouse retinal development, particularly in the formation and maintenance of the GCL.

Clonal expansion and cell dispersion in the developing mouse retina.

The present study has used two different approaches for labelling progenitor cells at the optic vesicle stage in order to examine patterns of clonal expansion and cellular dispersion within the developing retina. X-inactivation transgenic mice and chimeric mice expressing the lacZ reporter transgene were examined during development and in adulthood to study the radial and tangential dispersion of proliferating neuroepithelial cells and postmitotic retinal cells of known identities. Chimeric retinas were used to measure tangential dispersion distances, while transgenic retinas were used to assess the frequency of tangential dispersion for individual populations of retinal neurons. Tangential dispersion is shown to be a universal feature of particular retinal cell types, being contrasted with the strictly radial dispersion of other cells. Tangential dispersion is a relatively short-distance phenomenon, with distinct dispersion distances characteristic for cone, horizontal, amacrine and ganglion cells. Embryonic and postnatal retinas show that tangential dispersion occurs at different times for these distinct cell types, associated with their times of differentiation rather than their neurogenetic periods. These developmental results rule out the possibility that tangential dispersion is due to a passive displacement produced by the proliferation of later-born cells, or to the lateral dispersion of a dividing sibling; rather, they are consistent with the hypothesis that tangential dispersion plays a role in the establishment of the orderly spatial distribution of retinal mosaics.

Modelling the mosaic organization of rod and cone photoreceptors with a minimal-spacing rule.

The mosaic of photoreceptors is regarded as a prime example of the precise control of cellular positioning in the vertebrate nervous system. This study was undertaken with the idea that understanding the intrinsic geometrical features of photoreceptor mosaics is a necessary step to unveil the biological mechanisms governing their formation. We show in the retina of the ground squirrel that the arrays of both the rods and S cones are non-random, but that nothing more than a simple minimal-spacing rule constraining receptor positioning is sufficient to account for the spatial organization of both mosaics. The size of this 'exclusion zone' is an intrinsic characteristic of each cell type, and it is simply the difference in the size of this domain that accounts for the regularity of the S cone array and the irregularity of the rod array at identical density. Consequently, regularity in receptor mosaics is produced by two independent biological events, one embodying the exclusion zone, and another specifying the local density of a given receptor type.

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.

The topography of rod and cone photoreceptors in the retina of the ground squirrel.

The distributions of rod and cone photoreceptors have been determined in the retina of the California ground squirrel, Spermophilus beecheyi. Retinas were fixed by perfusion and the rods and cones were detected with indirect immunofluorescence using opsin antibodies. Local densities were determined at 2-mm intervals across the entire retina, from which total numbers of each receptor type were estimated and isodensity distributions were constructed. The ground squirrel retina contains 7.5 million cones and 1.27 million rods. The peak density for the cones (49,550/mm2) is found in a horizontal strip of central retina 2 mm ventral to the elongated optic nerve head, falling gradually to half this value in the dorsal and ventral retinal periphery. Of the cones, there are 14 M cones for every S cone. S cone density is relatively flat across most of the retina, reaching a peak (4500/mm2) at the temporal end of the visual streak. There is one exception to this, however: S cone density climbs dramatically at the extreme dorso-nasal retinal margin (20,000/mm2), where the local ratio of S to M cones equals 1. Rod density is lowest in the visual streak, where the rods comprise less than 5% of the local photoreceptor population, increasing conspicuously in the ventral retina, where the rods achieve 30% of the local photoreceptor population (13,000/mm2). The functional importance of the change in S to M cone ratio at the dorsal circumference of the retina is compromised by the extremely limited portion of the visual field subserved by this retinal region. The significance for vision, if any, remains to be determined. By contrast, the change in rod/cone ratio between the dorsal and ventral halves of the retina indicates a conspicuous asymmetry in the ground squirrel's visual system, suggesting a specialization for maximizing visual sensitivity under dim levels of illumination in the superior visual field.

Clonal boundary analysis in the developing retina using X-inactivation transgenic mosaic mice.

Transgenic mice harboring the lacZ reporter gene on one X chromosome have been used to mark 50% of all retinal progenitors. The distribution of clones arising from this population of marked progenitors reveals a conspicuous columnar segregation of clonally related cells, indicating that most retinal neuroblasts migrate exclusively radially. Against this columnar background of the transgenic retina, single cone, horizontal, amacrine and ganglion cells are observed to transgress clonal borders, mixing freely with cells derived from different precursors. This tangential dispersion is due to the lateral movement of postmitotic neuroblasts around the time of their differentiation, rather than to the dispersion of a proliferative sibling at the time of cell birth. Tangential dispersion is suggested to play a significant role in creating the functional architecture of the mature retina, being the means by which the orderly spacing, or regularity, of retinal mosaics is established during development.

Distribution, size and number of axons in the optic pathway of ground squirrels.

The present study has examined the distribution of axons of differing sizes in the optic pathway of the ground squirrel. Axon diameters were measured from electron micrographs at various locations across sections of the optic nerve and tract, and total distributions and numbers were estimated. In both the nerve and tract, roughly 1.2 million optic axons were present. The population of optic axons had a unimodal size distribution, peaking at 0.9 microm in diameter and having an extended tail toward larger diameters. Local axon diameter distributions in the optic tract indicated distinct (though partially overlapping) axon diameter classes, including one of fine sizes peaking at 0.8-0.9 microm, a second of medium sizes peaking around 1.7-1.8 microm, and a third composed of the larger fibers with diameters up to 4.8 microm. The fine-caliber axons were found at all locations in the tract, and were the only axons present immediately adjacent to the pia, while the medium- and coarse-caliber axons were found at deeper locations. Curiously, the larger axons were found primarily in the medial parts of the tract, where axons from the dorsal retina normally course. A similarly restricted distribution of the larger axons was observed in the dorsotemporal parts of the optic nerve, suggesting that this difference in the tract may relate to an asymmetric distribution of ganglion cells on the retina giving rise to these axons. Measurements of axonal size taken within the optic fiber layer in dorsal and ventral parts of the retina confirmed this asymmetry, consistent with previous demonstrations of soma size differences in the dorsal versus ventral retina. The partial segregation of axons by size in the optic tract of the ground squirrel then reflects both the asymmetric distribution of retinal ganglion cell classes and the chronotopic reordering of optic axons that occurs within the chiasmatic region.

Localization of protein kinase C to UV-sensitive photoreceptors in the mouse retina.

The present study has identified a population of cone photoreceptors in the murine retina that are uniquely immunoreactive for protein kinase C (PKC). Wavelength-sensitive cone subtypes are segregated along the dorso-ventral axis in the mouse retina with ventral retina occupied exclusively by ultraviolet wavelength-sensitive (UVWS) cones, and dorsal retina dominated by middle wavelength-sensitive cones. PKC-positive cones are found primarily in the ventral retina, and double-label immunocytochemistry using a short wavelength-sensitive opsin antibody confirms that they specifically correspond to the UVWS cone subtype. The PKC antibody, as documented in other mammals, also identifies rod bipolar cells in the mouse retina. UVWS cones and bipolar cells have previously been shown to share transcriptional regulatory elements, as observed in transgenic mice encoding a portion of the human SWS-opsin promoter controlling the lacZ reporter gene. In such mice, the transgene product, beta-galactosidase, is expressed in populations of both cones and bipolar cells. The present study confirms that lacZ-expressing photoreceptors are indeed PKC-positive photoreceptors, but that the lacZ-expressing bipolar cells are not the PKC-positive rod bipolar cells. These cells must correspond to a type of cone bipolar cell.

Mosaics of islet-1-expressing amacrine cells assembled by short-range cellular interactions.

The nervous system has a modular architecture with neurons of the same type commonly organized in nonrandom arrays or mosaics. Modularity is essential to parallel processing of sensory information and has provided a key element for brain evolution, but we still know very little of the way neuronal mosaics form during development. Here we have identified the immature elements of two retinal mosaics, the choline acetyltransferase (ChAT) amacrine cells, by their early expression of the homeodomain protein Islet-1, and we show that spatial ordering is an intrinsic property of the two Islet-1 mosaics, dynamically maintained while new elements are inserted into the mosaics. Migrating Islet-1 cells do not show this spatial ordering, indicating that they must move tangentially as they enter the mosaic, under the action of local mechanisms. Clonal territory analysis in X-inactivation transgenic mice confirms the lateral displacement of ChAT amacrine cells away from their clonal columns of origin, and mathematical models show how short-range cellular interactions can guide the assemblage of these mosaics via a simple biological rule.

Cellular retinaldehyde binding protein in developing retinal astrocytes.

Cellular retinaldehyde binding protein (CRALBP) is present in Müller glia and in cells of the retinal pigment epithelium, but we have recently observed CRALBP-like immunoreactivity near the inner limiting membrane in the newborn mouse retina. The present study has examined whether this protein is present in developing retinal astrocytes. Retinal tissue was collected at various embryonic and postnatal ages and in adulthood. Tissue for immunohistochemistry was fixed by immersion in 4% paraformaldehyde and immunostained using rabbit polyclonal antisera to CRALBP or glial fibrillary acidic protein (GFAP), while fresh tissue was homogenized for Western analysis. Specificity of the antiserum for the 33 kDa protein was shown in retinal homogenates by immunoblotting, with expression of the protein increasing steadily from E15.5 through adulthood. Immunostaining of sections from fetal eye-cups revealed faint labeling of cells in the optic nerve, with progressive migration of CRALBP-immunoreactive cells into the retina at the inner limiting membrane during the perinatal period. By the day of birth, these cells were intensely immunoreactive, showing a morphology characteristic of migrating astrocytes. These CRALBP-immunoreactive cells mimicked the progressive infiltration of GFAP-positive astrocytes which are known to migrate into the retina from the optic nerve head, many of which were double-labeled with GFAP. Their distribution across the retina is distinct from that of the lighter-staining Müller glial somata during these stages, and they are not misidentified Müller glial endfeet. Astrocytes are only transiently CRALBP-immunoreactive, no longer containing the protein after the second post-natal week. Preincubation of the antiserum with purified CRALBP abolished all staining of astrocytes. Coupled with the fact that only a single (approximately 33 kDa) molecular weight protein is labeled by the antiserum, it was concluded that retinal astrocytes contain CRALBP during a limited period of development.

Chronotopic fiber reordering and the distribution of cell adhesion and extracellular matrix molecules in the optic pathway of fetal ferrets.

We have examined the age-related reordering of optic axons as they pass through the chiasmatic region in fetal ferrets. Proportions of young and old optic axons were determined from electron micrographs taken sequentially through the prechiasmatic nerve, chiasm, and tract. This "chronotopic" reordering of axons was shown to emerge gradually, beginning rostral to the fusion of the two optic nerves, but continuing to develop caudal to the chiasmatic midline. Segregation of young from old optic axons was most pronounced within the optic tract. We then compared the emergence of this fiber reorganization to the distribution of cell adhesion and extracellular matrix molecules and to the glial architecture within the pathway. Using immunohistochemistry, the distributions of the cell adhesion molecules L1, NCAM, and TAG-1 and the extracellular matrix molecules laminin-1 and chondroitin sulfate proteoglycans (CSPGs) were determined. Among these, only the distribution of CSPGs was observed to change in a manner that complemented the segregation of young from old optic axons. CSPGs were densest in the deeper parts of the optic tract, coincident with radial glial fibers that turn to course within the region of the oldest optic axons. Both the glial architecture and the CSPG distribution form as a consequence of the invasion of the first optic axons, shown by the developmental sequence of each, and by the fact that these glial and molecular features fail to form in the absence of optic axons. The data suggest a model in which the gradient of CSPGs across the depth of the tract contributes to the formation of the chronotopic fiber reordering by providing a relatively unfavorable environment for subsequent axonal growth. The CSPGs may do so by interfering with adhesion molecules on optic axons that normally promote elongation.