Julie H. Sandell

Amyloid precursor protein is synthesized by retinal ganglion cells, rapidly transported to the optic nerve plasma membrane and nerve terminals, and metabolized.

Abstract: We have investigated the synthesis, axonal transport, and processing of the β‐amyloid precursor protein (APP) in in vivo rabbit retinal ganglion cells. These CNS neurons connect the retina to the brain via axons that comprise the optic nerve. APP is synthesized in retinal ganglion cells and is rapidly transported into the optic nerve in small transport vesicles. It is then transferred to the axonal plasma membrane, as well as to the nerve terminals and metabolized with a f1/2 of less than 5 h. A significant accumulation of C‐terminal amyloidogenic or nonamyloidogenic fragments is seen in the optic nerve 5 h after [35S]‐ methionine, [35S]cysteine injection, which disappears by 24 h. The major molecular mass species of APP in the optic nerve is ∼110 kDa, and is an APP isoform that does not contain a Kunitz protease inhibitor domain. Higher molecular mass species containing this sequence are seen mostly in the retina. A protease(s) that can potentially cleave APP to generate an amyloidogenic fragment is present in the same optic nerve membrane compartment as APP.

Disrupted myelin and axon loss in the anterior commissure of the aged rhesus monkey.

This study assesses the effects of age on the composition of the anterior commissure of the rhesus monkey. The anterior commissures of nine young (5–10 years), five middle‐aged (15–20 years), and eight old (25–35 years) monkeys were examined by light and electron microscopy. In all, 90–95% of the nerve fibers in the anterior commissure are myelinated. With age, the structure of the myelin sheaths of some nerve fibers is altered. Some of the axons also show signs of degeneration and this leads to a loss of nerve fibers. Thus, in young and the middle‐aged monkeys the mean number of myelinated nerve fibers in the anterior commissure is 2.2 × 106, while in the old monkeys the mean is 1.2 × 106. Increasing age is correlated with a reduction in the number of myelinated nerve fibers in the anterior commissure, an increase in the frequency of structural alterations in myelin sheaths, and an increase in the frequency of occurrence of degenerating axons. However, the number of myelinated nerve fibers is the only variable that correlates with cognition: in monkeys 5–20 years of age the fewer the number of nerve fibers the poorer the cognitive performance, as measured by our Cognitive Impairment Index (CII). The most common neuroglial cells in the anterior commissure are oligodendrocytes. They account for 86% of all neuroglial cell profiles, while astrocytes account for 9%, and microglial cells for 5% of profiles. There is no apparent change with age in the total numbers of neuroglial cells, although as they age each of the neuroglial cell types acquires some inclusions in their cytoplasm. The data, together with those from previous studies, support the concept that in aging there is a ubiquitous loss of myelinated nerve fibers from the brain and that fiber loss is preceded by alterations in the structure of many of the myelin sheaths. J. Comp. Neurol. 466:14–30, 2003.

Effects of age on nerve fibers in the rhesus monkey optic nerve

During normal aging there is a reduction in white matter volume in the cerebral hemispheres and structural abnormalities in myelin in some parts of the central nervous system, but whether nerve fibers are lost with age and whether the myelin changes are ubiquitous is not known. Studying the optic nerve, which is a circumscribed bundle of nerve fibers, offers an opportunity to gain further insight into the effects of normal aging on white matter. The present study examined the optic nerves from young (4–10 years) and old (27–33 years) rhesus monkeys using light and electron microscopy. These nerves had been perfused transcardially to obtain optimal preservation of the tissue. Varying degrees of degeneration were encountered in all the optic nerves from the old monkeys. The changes included myelin abnormalities, similar to those reported in other parts of the central nervous system; the presence of degenerating axons and their sheaths; changes in neuroglial cells; and thickening of the trabeculae of connective tissue in the nerve. The total number of nerve fibers was reduced from an average of 1.6 × 106 in the young optic nerves to as few as 4 × 105 in one old monkey, and with one exception in all of the old optic nerves the packing density of nerve fibers was less than in any of the young optic nerves. The degenerative changes were most marked in those optic nerves that contained the fewest nerve fibers. J. Comp. Neurol. 429:541–553, 2001.

Apolipoprotein E Is Synthesized in the Retina by Müller Glial Cells, Secreted into the Vitreous, and Rapidly Transported into the Optic Nerve by Retinal Ganglion Cells

We have investigated the synthesis and transport of apoE, the major apolipoprotein of the central nervous system, in the retina of the living rabbit. Four hours after the injection of [S]methionine/cysteine into the vitreous, 44% of [S]Met/Cys-labeled apoE is in soluble and membrane-enclosed retinal fractions, while 50% is in the vitreous. A significant amount of intact [S]Met/Cys-labeled apoE is rapidly transported into the optic nerve and its terminals in the lateral geniculate and superior colliculus within 3-6 h in two distinguishable vesicular compartments. Müller glia in cell culture also synthesize and secrete apoE. Taken together, these results suggest that apoE is synthesized by Müller glia and secreted into the vitreous. ApoE is also internalized by retinal ganglion cells and/or synthesized by these cells and rapidly transported into the optic nerve and brain as an intact molecule. We discuss the possible roles of retinal apoE in neuronal dynamics.

Effects of age on the glial cells in the rhesus monkey optic nerve.

The optic nerve is a circumscribed white matter tract consisting of myelinated nerve fibers and neuroglial cells. Previous work has shown that during normal aging in the rhesus monkey, many optic nerves lose some of their nerve fibers, and in all old optic nerves there are both myelin abnormalities and degenerating nerve fibers. The present study assesses how the neuroglial cell population of the optic nerve is affected by age. To address this question, optic nerves from young (4–10 years) and old (27–33 years) rhesus monkeys were examined by using both light and electron microscopy. It was found that with age the astrocytes, oligodendrocytes, and microglia all develop characteristic cytoplasmic inclusions. The astrocytes hypertrophy and fill space vacated by degenerated nerve fibers, and they often develop abundant glial filaments in their processes. Oligodendrocytes and microglial cells both become more numerous with age, and microglial cells often become engorged with phagocytosed debris. Some of the debris can be recognized as degenerating myelin, and in general, the greater the loss of nerve fibers, the more active the microglial cells become. J. Comp. Neurol. 445:13–28, 2002.

Long-term cellular and regional specificity of the photoreceptor toxin, iodoacetic acid (IAA), in the rabbit retina.

This study investigated the anatomical consequences of a photoreceptor toxin, iodoacetic acid (IAA), in the rabbit retina. Retinae were examined 2 weeks, 1, 3, and 6 months after systemic IAA injection. The retinae were processed using standard histological methods to assess the gross morphology and topographical distribution of damage, and by immunohistochemistry to examine specific cell populations in the retina. Degeneration was restricted to the photoreceptors and was most common in the ventral retina and visual streak. In damaged regions, the outer nuclear layer was reduced in thickness or eliminated entirely, with a concomitant loss of immunoreactivity for rhodopsin. However, the magnitude of the effect varied between animals with the same IAA dose and survival time, suggesting individual differences in the bioavailability of the toxin. In all eyes, the inner retina remained intact, as judged by the thickness of the inner nuclear layer, and by the pattern of immunoreactivity for protein kinase C-alpha (rod bipolar cells) and calbindin D-28 (horizontal cells). Müller cell stalks became immunoreactive for glial fibrillary acidic protein (GFAP) even in IAA-treated retinae that had no signs of cell loss, indicating a response of the retina to the toxin. However, no marked hypertrophy or proliferation of Müller cells was observed with either GFAP or vimentin immunohistochemistry. Thus the selective, long lasting damage to the photoreceptors produced by this toxin did not lead to a reorganization of the surviving cells, at least with survival as long as 6 months, in contrast to the remodeling of the inner retina that is observed in inherited retinal degenerations such as retinitis pigmentosa and retinal injuries such as retinal detachment.

Inherited retinal degeneration and apoptosis in mutant zebrafish

The mechanism of retinal cell death was studied in mutant zebrafish (Danio rerio) which undergo inherited degeneration of the retina and the brain. The shrunken head (shrm33) mutation was isolated as part of a large scale mutagenesis screen. The yellow head (yhd) mutation arose spontaneously among inbred wild type zebrafish. Although the mutants share many morphological features, including small eyes, a small brain and an enlarged pericardial sac, crossing shrm33 and yhd heterozygotes results in phenotypically normal fish.

Iodoacetic acid, but not sodium iodate, creates an inducible swine model of photoreceptor damage

Our purpose was to find a method to create a large animal model of inducible photoreceptor damage. To this end, we tested in domestic swine the efficacy of two chemical toxins, known to create photoreceptor damage in other species: Iodoacetic Acid (IAA) and Sodium Iodate (NaIO(3)). Intravenous (IV) administration of NaIO(3) up to 90 mg/kg had no effect on retinal function and 110 mg/kg was lethal. IV administration of IAA (5-20 mg/kg) produced concentration-dependent changes in visual function as measured by full-field and multi-focal electroretinograms (ffERG and mfERG), and 30 mg/kg IAA was lethal. The IAA-induced effects measured at two weeks were stable through eight weeks post-injection, the last time point investigated. IAA at 7.5, 10, and 12 mg/kg produce a concentration-dependent reduction in both ffERG b-wave and mfERG N1-P1 amplitudes compared to baseline at all post-injection times. Comparisons of dark- and light-adapted ffERG b-wave amplitudes show a more significant loss of rod relative to cone function. The fundus of swine treated with ≥10 mg/kg IAA was abnormal with thinner retinal vessels and pale optic discs, and we found no evidence of bone spicule formation. Histological evaluations show concentration-dependent outer retinal damage that correlates with functional changes. We conclude that NaIO(3,) is not an effective toxin in swine. In contrast, IAA can be used to create a rapidly inducible, selective, stable and concentration-dependent model of photoreceptor damage in swine retina. Because of these attributes this large animal model of controlled photoreceptor damage should be useful in the investigation of treatments to replace damaged photoreceptors.

The development of neurotrophin receptor Trk immunoreactivity in the retina of the zebrafish (Brachydanio rerio)

The purpose of this study was to examine the cellular distribution of the Trk family of neurotrophin receptors in the retina and optic nerve of the zebrafish (Brachydanio rerio) during embryonic development. Semithin sections from zebrafish retinae were examined immunohistochemically for the presence of Trk polypeptides using commercially available antisera that cross-react with the fish. Cross-reactivity was confirmed by Western blot. Trk polypeptides were detected at about 1 day of age on the surfaces of retinal neuroblasts and faint Trk immunoreactivity was observed in the primordial optic nerve at 1.5 days. By 2 days the optic nerve was clearly positive for Trk and at 2.5 days Trk immunoreactivity was found in the outer plexiform, inner nuclear, inner plexiform and ganglion cell layers, as well as in the optic nerve. At 3 days and 4 days the location of Trk immunoreactivity was unchanged but by 4 days it had diminished in intensity. In the adult zebrafish retina Trk immunoreactivity was found in the same locations as in the embryonic fish, as well as in a population of cells in the middle of the inner nuclear layer and in photoreceptors. We conclude that Trk neurotrophin receptors are present in the zebrafish eye during development and that their persistence in the adult may support the continuous neural reorganization that accompanies the growth of the eye in the fish.

The distribution of neurotrophin receptor TrkC-like immunoreactive fibers and varicosities in the rhesus monkey brain

The distribution of immunoreactivity for the neurotrophin receptor tyrosine kinase TrkC was examined in the brain of the adult rhesus monkey. TrkC-like immunoreactivity was widespread and consisted primarily of varicose fibers. The most dense populations of fibers were in the basal forebrain (in the cholinergic cell groups Ch1, Ch2 and Ch4), in the raphé complex throughout its rostrocaudal extent, and in the locus coeruleus. Other fibers were present in the thalamus, hypothalamus, central gray matter of the midbrain, dorsal midline of the brainstem and the cerebral cortex. The only neuronal cell bodies with consistent labeling were located in the lateral hypothalamus. Purkinje cells in the cerebellum showed variable labeling. Specific labeling of varicosities and cell bodies was abolished by omission of the primary antiserum or by preabsorption with the TrkC peptide antigen. We conclude that TrkC-like immunoreactivity can be detected in a wide variety of subcortical locations in the adult rhesus monkey. Labeling was particularly prominent in the vicinity of the major cholinergic, serotonergic and adrenergic nuclei, known from other studies to be vulnerable in the ageing brain. This suggests that the ligand for TrkC, neurotrophin-3, may persist as a survival factor for critical neurons into adulthood.