Intraocular tetrodotoxin reduces axonal transport and transcellular transfer of adenosine and other nucleosides in the visual system of goldfish

Ambient Air Pollution Associations with Retinal Morphology in the UK Biobank

Purpose

Because air pollution has been linked to glaucoma and AMD, we characterized the relationship between pollution and retinal structure.

Methods

We examined data from 51,710 UK Biobank participants aged 40 to 69 years old. Ambient air pollution measures included particulates and nitrogen oxides. SD-OCT imaging measured seven retinal layers: retinal nerve fiber layer, ganglion cell–inner plexiform layer, inner nuclear layer, outer plexiform layer + outer nuclear layer, photoreceptor inner segments, photoreceptor outer segments, and RPE. Multivariable regression was used to evaluate associations between pollutants (per interquartile range increase) and retinal thickness, adjusting for age, sex, race, Townsend deprivation index, body mass index, smoking status, and refractive error.

Results

Participants exposed to greater particulate matter with an aerodynamic diameter of <2.5 µm (PM_2.5) and higher nitrogen oxides were more likely to have thicker retinal nerve fiber layer (β = 0.28 µm; 95% CI, 0.22–0.34; P = 3.3 × 10⁻²⁰ and β = 0.09 µm; 95% CI, 0.04–0.14; P = 2.4 × 10⁻⁴, respectively), and thinner ganglion cell–inner plexiform layer, inner nuclear layer, and outer plexiform layer + outer nuclear layer thicknesses (P < 0.001). Participants resident in areas of higher levels of PM_2.5 absorbance were more likely to have thinner retinal nerve fiber layer, inner nuclear layer, and outer plexiform layer + outer nuclear layers (β = –0.16 [95% CI, –0.22 to –0.10; P = 5.7 × 10⁻⁸]; β = –0.09 [95% CI, –0.12 to –0.06; P = 2.2 × 10⁻¹²]; and β = –0.12 [95% CI, –0.19 to –0.05; P = 8.3 × 10⁻⁴], respectively).

Conclusions

Greater exposure to PM_2.5, PM_2.5 absorbance, and nitrogen oxides were all associated with apparently adverse retinal structural features.

Uptake of waterborne tributyltin in the brain of fish: axonal transport as a proposed mechanism

In previous studies, it was shown that waterborne Hg(II), Cd(II), and Mn(II) enter nerves innervating water-exposed sensory organs of fish and are transported to the brain by axonal transport. However, it is not known if organometals, such as tributyltin (TBT), can reach the brain of fish via the same route. In this work, we exposed rainbow trout (Oncorhynchus mykiss) to waterborne [113Sn]-TBT (4.2 kBq/L). Three fish were sampled after a 2-week exposure, and three others were sampled after a 2-week depuration period. Another group of four fish received an intravenous injection of [113Sn]-TBT and were sampled after 2 and 14 d. Distribution of the radiolabel was visualized and quantified by quantitative whole-body autoradiography. The brain accumulated a significant amount of 113Sn, with hot spots being found in parts receiving sensory nerves from water-exposed sensory organs, such as eminentia granulares (lateral lines organs). Labeling of the brain was also seen for i.v.-injected fish, indicating that the blood-brain barrier is not impervious to TBT or its metabolites. Nevertheless, the distribution of radioactivity in the brain was much more uniform, with no evident hot spot. Though the transfer [water --> gills --> blood stream --> blood-brain barrier --> brain] may account for a certain proportion of the radiolabel accumulation in fish brain, exposure to [113Sn]-TBT via water resulted in higher accumulation in some areas of the brain, of which the specific location strongly suggests that it was taken up in different water-exposed sensory nerve terminals and transported directly to the brain by axonal transport, as the parent compound or as a metabolite. The resulting local enhancement of the accumulation of butyltins might jeopardize the integrity of nervous system. Further work is needed to assess the toxicological significance of this process.

Postnatal development of the visual corpus callosum: the influence of activity of the retinofugal projections

Visual callosal projections were studied in normal adult rabbits, and in adult rabbits in which normal development was manipulated by monocular enucleation on the first or seventh postnatal day, or by abolition of retinal physiological activity by repeated application of tetrodotoxin (TTX) beginning on postnatal day 7. Animals given control vehicle injections, and animals enucleated on postnatal day 7 did not differ from normal in the tangential extent of their callosal zone which is limited to the lateral one-third of area 17. In contrast, animals enucleated on the day of birth and animals given TTX vitreous injections beginning on postnatal day 6-7 are similar in that the tangential extent of their callosal cell zone extends approximately through the lateral two-thirds of area 17. The results suggest that different mechanisms underly the effects of removal of the eye, and abolition of retinal activity, and that the critical period for the effective manipulation of these two mechanisms is different.

Lack of physiological stimulation induces decreased proteolytic activity in nerve terminals

The effect of optic nerve transsection on proteolytic degradation of axonally transported proteins in the superior colliculus of the rabbit was studied. Proteolysis of labeled proteins was determined in vitro in small pieces of the superior colliculus. Within 2 hours after sectioning the optic nerve there was a decreased degradation of slowly transported labeled proteins in the nerve terminals in the superior colliculus.

Neural activity in the regenerating optic nerve of the goldfish

1. Retinal ganglion cells of one eye were axotomized in goldfish either by sectioning the contralateral optic tract or by ablating the contralateral lobe of the optic tectum. Between 2 and 40 days later, multiunit activity in response to diffuse light flashes was recorded from the axotomized and normal optic nerves, and from the optic tectum. 2. Two days after tract section, the amplitude of the integrated multiunit response of the axotomized nerve was normal. By 16 days it had fallen to 15% of control values, at which time visual responses carried by the regenerating tract were first recorded in tectum. Activity in the axotomized nerve then recovered gradually. 3. After ablation of one tectal lobe, multiunit responses in the axotomized nerve had not recovered by 40 days. 4. Integrated spontaneous activity in the axotomized nerve was depressed with a similar time course to the depression of light-evoked activity, both after tract section and tectal ablation. 5. Retinal ganglion cell nuclear size, a morphological indicator of the cell body reaction, varied inversely with evoked activity, whether axotomy was by tract section or by tectal ablation. 6. Electrically evoked compound action potentials of normal amplitude could be recorded from an axotomized nerve despite depressed responses to light flashes. 7. It is concluded that optic nerve axotomy in goldfish reduces the number of optic fibres carrying impulses and/or the frequency of their discharge. The effect is closely linked to morphological changes occurring in the retinal ganglion cell bodies. Recovery of impulse activity and morphology depends upon the regenerating optic fibres innervating an appropriate target.

Development of adenosine-dependent cyclic AMP accumulation in the avian optic tectum

The present work shows the existence of adenosine-dependent cyclic adenosine monophosphate (AMP) accumulation in the chick optic tectum. When tecta from 18-day-old embryos were incubated with the phosphodiesterase inhibitor IBMX and RO 20-1724, the cyclic AMP level increased from 39.2 to 73.3 and 285.5 pmol/mg protein, respectively. The high level obtained with RO 20-1724 could be inhibited by increasing concentrations of IBMX or by adenosine deaminase, but not by dipyridamole. 2-Chloroadenosine promoted a dose-dependent cyclic AMP accumulation in tecta incubated with RO 20-1724 and adenosine deaminase. This effect was blocked by IBMX and varied substantially during the development of the tissue. The degree of stimulation increased after day 11 of incubation, attaining maximal levels on day 14. The effect of 2-chloroadenosine remained constant until day 18, a period when both the protein content and the basal cyclic AMP levels are increasing in the developing tectum. The cyclic AMP increase elicited by 2-chloroadenosine was greatly reduced in tecta from 20-day-old embryos and 2-day-old chicks. The putative transmitters glutamate and glycine and the neurotransmitter analogs isoproterenol and carbachol had no stimulatory effect on the cyclic AMP accumulation of tecta from 10- and 17-day-old embryos.

Fast axonally transported proteins in regenerating goldfish optic nerve: effect of abolishing electrophysiological activity with TTX

Blocking neural activity with intraocular tetrodotoxin (TTX) hinders regeneration of goldfish optic axons, and prevents the refinement of the retinotopic map that is formed in the optic tectum. The latter effect is not observed with TTX treatment confined to the first two weeks of regeneration, but is produced when the TTX treatment is delayed until after this time. In the present study, 2-dimensional gel electrophoresis was used to analyse the effects of two different schedules of TTX treatment (0-9 days or 14-32 days) on incorporation of [3H]proline into individual proteins conveyed by fast axonal transport in the optic nerve. The labelling of many of these proteins was somewhat reduced by either schedule of TTX treatment, but a number of proteins showed a larger reduction as a result of the delayed treatment. These included some glycoproteins, as well as a protein of about 45 kDa and pI 4.5, which shows greatly increased synthesis during regeneration, and which is probably identical to the 'growth-associated protein' GAP-43. By contrast, cytoskeletal proteins (alpha- and beta-tubulin and actin) were unaffected by the delayed TTX treatment. It is possible that the differential effects of the early and delayed TTX treatments on various transported proteins may account for differences in the effect of these treatments on the retinotectal projection.