Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

At a glance: The STEP trials

A round-up of the STEP phase 3 clinical trials evaluating semaglutide for weight loss in people with overweight or obesity.
ADVANCED SEARCH
Log in
Top
Brain Structure and Function
Published in: Brain Structure and Function 1/2015

01-01-2015 | Original Article

Retrograde transneuronal degeneration in the retina and lateral geniculate nucleus of the V1-lesioned marmoset monkey

Authors: A. Hendrickson, C. E. Warner, D. Possin, J. Huang, W. C. Kwan, J. A. Bourne

Published in: Brain Structure and Function | Issue 1/2015

Login to get access

Abstract

Retrograde transneuronal degeneration (RTD) of retinal ganglion cells and dorsal lateral geniculate (LGN) neurons are well described following a lesion of the primary visual cortex (V1) in both Old World monkeys and humans. Based on previous studies of New World monkeys and prosimians, it was suggested that these species displayed no RTD following a lesion of V1. In this study of the New World marmoset monkey, 1 year after a unilateral V1 lesion either in adults or at 14 days after birth, we observed ~20 % ganglion cell (GC) loss in adult but ~70 % in infants. This finding is similar to the RTD previously described for Old World Macaca monkeys. Furthermore, in infants we find a similar amount of RTD at 3 weeks and 1 year following lesion, demonstrating that RTD is very rapid in neonates. This highlights the importance of trying to prevent the rapid onset of RTD following a lesion of V1 in early life as a strategy for improved functional recovery. Despite differences in GC loss, there was little difference between LGN degeneration in infant versus adult lesions. A wedge on the horizontal meridian corresponding to the LGN foveal representation revealed extensive neuronal loss. Retinal afferent input was labeled by cholera toxin B subunit. Input to the degenerated parvocellular layers was difficult to detect, while input to magnocellular and koniocellular layers was reduced but still apparent. Our demonstration that the New World marmoset monkey shares many of the features of neuroplasticity with Old World Macaca monkeys and humans emphasizes the opportunity and benefit of marmosets as models of visual cortical injury.
Literature
Bourne JA, Warner CE, Rosa MGP (2005) Topographic and laminar maturation of striate cortex in early postnatal marmoset monkeys, as revealed by neurofilament immunohistochemistry. Cereb Cortex 15:740–748PubMedCrossRef
Bridge H, Thomas O, Jbabdi S, Cowey A (2008) Changes in connectivity after visual cortical brain damage underlie altered visual function. Brain 131:1433–1444PubMedCrossRef
Bridge H, Jindahra P, Barbur J, Plant GT (2011) Imaging reveals optic tract degeneration in hemianopia. Invest Ophthalmol Vis Sci 52:382–388PubMedCrossRef
Chan TL, Martin PR, Glunas N, Grünert U (2001) Bipolar cell diversity in the primate retina: morphologic and immunocytochemical analysis of a New World monkey, the marmoset Callithrix jacchus. J Comp Neurol 437:219–239PubMedCrossRef
Cowey A (1974) Atrophy of retinal ganglion cells after removal of striate cortex in a rhesus monkey. Perception 3:257–260PubMedCrossRef
Cowey A, Stoerig P, Perry VH (1989) Transneuronal retrograde degeneration of retinal ganglion cells after damage to striate cortex in macaque monkeys: selective loss of Pβ cells. Neuroscience 29:65–80PubMedCrossRef
Cowey A, Stoerig P, Bannister M (1994) Retinal ganglion cells labelled from the pulvinar nucleus in macaque monkeys. Neuroscience 61:691–705PubMedCrossRef
Cowey A, Alexander I, Stoerig P (2011) Transneuronal retrograde degeneration of retinal ganglion cells and optic tract in hemianopic monkeys and humans. Brain 134:2149–2157PubMedCrossRef
Dacey DM (1999) Primate retina: cell types, circuits and color opponency. Prog Retin Eye Res 8:737–763CrossRef
Dineen JT, Hendrickson AE (1981) Age correlated differences in the amount of retinal degeneration after striate cortex lesions in monkeys. Investig Ophthalmol Vis Sci 21:749–752
Fritsches KA, Rosa MGP (1996) Visutopic organization of striate cortex in the marmoset monkey (Callithrix jacchus). J Comp Neurol 371:264–282CrossRef
Goldshmit Y, Bourne JA (2010) Upregulation of EphA4 on astrocytes potentially mediates astrocytic gliosis after cortical lesion in the marmoset monkey. J Neurotrauma 27:1321–1332PubMedCrossRef
Harting JK, Huerta MF, Hashikawa T, van Lieshout DP (1991) Projection of the mammalian superior colliculus supon the dorsal lateral geniculate nucleus: organization of tectogeniculate pathways in nineteen species. J Comp Neurol 304:275–306PubMedCrossRef
Hendrickson A, Troilo D, Possin D, Springer A (2006) Development of the neural retina and its vasculature in the marmoset Callithrix jacchus. J Comp Neurol 497:270–286PubMedCrossRef
Hendrickson A, Yan YH, Erickson A, Possin D, Pow D (2007) Expression patterns of calretinin, calbindin and parvalbumin and their colocalization in neurons during development of Macaca monkey retina. Exp Eye Res 85:587–601PubMedCrossRef
Hendry SHC, Yoshioka T (1994) A neurochemically distinct third channel in the macaque dorsal lateral geniculate nucleus. Science 264:575–577PubMedCrossRef
Homman-Ludiye J, Bourne JA (2013) The guidance molecule semaphorin3A is differentially involved in the arealization of the mouse and primate neocortex. Cereb Cortex. doi:10.​1093/​cercor/​bht141
Innocenti GM, Kiper DC, Knyazeva MG, Deonna TW (1999) On nature and limits of cortical developmental plasticity after an early lesion, in a child. Restor Neurol Neurosci 15:219–227PubMed
Jindahra P, Petrie A, Plant GT (2009) Retrograde trans-synaptic retinal ganglion cell loss identified by optical coherence tomography. Brain 132:628–634PubMedCrossRef
Jindahra P, Petrie A, Plant GT (2012) The time course of retrograde trans-synaptic degeneration following occipital lobe damage in humans. Brain 135:534–541PubMedCrossRef
Kisvárday ZF, Cowey A, Stoerig P, Somogyi P (1991) Direct and indirect retinal input into degenerated dorsal lateral geniculate nucleus after striate cortical removal in monkey: implications for residual vision. Exp Brain Res 86:271–292PubMedCrossRef
Lund JS (1988) Anatomical organization of macaque monkey striate visual cortex. Annu Rev Neurosci 11:253–288PubMedCrossRef
Mashiko H, Yoshida AC, Kikuchi SS, Niimi K, Takahashi E, Aruga J, Okano H, Shimogori T (2012) Comparative anatomy of marmoset and mouse cortex from genomic expression. J Neurosci 32:5039–5053PubMedCrossRef
Newman JD, Kenkel WM, Aronoff EC, Bock NA, Zametkin MR, Silva AC (2009) A combined histological and MRI brain atlas of the common marmoset monkey, Callithrix jacchus. Brain Res Rev 62:1–18PubMedCentralPubMedCrossRef
Park HY, Park YG, Cho AH, Park CK (2013) Transneuronal retrograde degeneration of the retina ganglion cells in patients with cerebral infarction. Ophthalmology 120:1292–1299PubMedCrossRef
Paxinos G, Watson C, Petrides M, Rosa MGP, Tokuno H (2012) The marmoset brain in stereotaxic coordinates, 1st edn. Academic Press, New York
Rodman H (2006) Behavioral and neural alternations following V1 damage in immature primates. In: Lomber ST, Eggermont J (eds) Reprogramming the cerebral cortex. Oxford Press, Oxford, pp 92–113
Rodman H, Sorenson KM, Shim AJ, Hexter DP (2001) Calbindin immunoreactivity in the geniculo-extrastriate system of the macaque: implications for heterogeneity in the koniocellular pathway and recovery from cortical damage. J Comp Neurol 431:168–181PubMedCrossRef
Rosa M, Tweedale R (2005) Brain maps, great and small: lessons from comparative studies of primate visual cortical organization. Philos T R Soc B 360:665–691CrossRef
Sabel BA (1999) Editorial: residual vision and plasticity after visual system damage. Restor Neurol Neurosci 15:73–79PubMed
Schmid MC, Mrowka SW, Turchi J, Saunders RC, Wilke M, Peters AJ, Ye FQ, Leopold DA (2010) Blindsight depends on the lateral geniculate nucleus. Nature 466:373–377PubMedCentralPubMedCrossRef
Striemer CL, Chapman CS, Goodale MA (2009) ‘Real-time’ obstacle avoidance in the absence of primary visual cortex. Proc Natl Acad of Sci (USA) 106:15996–16001CrossRef
Szmajda BAB, Grünert UU, Martin PRP (2008) Retinal ganglion cell inputs to the koniocellular pathway. J Comp Neurol 510:251–268PubMedCrossRef
Van Buren JM (1963) Trans-synaptic degeneration in the visual system of primates. J Neurol Neurosurg Psych 27:402–413CrossRef
Virley D, Hadingham SJ, Roberts JC, Farnfield B, Elliott H, Whelan G, Golder J, David C, Parsons AA, Hunter AJ (2004) A new primate model of focal stroke: endothelin-1-induced middle cerebral artery occlusion and reperfusion in the common marmoset. J Cereb Blood Flow Metab 24:24–41PubMedCrossRef
Warner CE, Goldshmit Y, Bourne JA (2010) Retinal afferents synapse with relay cells targeting the middle temporal area in the pulvinar and lateral geniculate nuclei. Front Neuroanat 4:8PubMedCentralPubMed
Warner CE, Kwan WC, Bourne JA (2012) The early maturation of visual cortical area MT is dependent on input from the retinorecipient medial portion of the inferior pulvinar. J Neurosci 32:17073–17085PubMedCrossRef
Weiskrantz L (2004) Roots of blindsight. Prog Brain Res 144:229–241PubMed
Weller RE, Kaas JH (1989) Parameters affecting the loss of ganglion cells of the retina following ablations of striate cortex in primates. Vis Neurosci 3:327–349PubMedCrossRef
Weller RE, Kaas JH, Wetzel AB (1979) Evidence for the loss of X-cells of the retina after long-term ablation of visual cortex in monkeys. Brain Res 160:134–138PubMedCrossRef
Weller RE, Kaas JH, Ward J (1981) Preservation of retinal ganglion cells and normal patterns of retinogeniculate projections in prosimian primates with long-term ablations of striate cortex. Investig Ophthalmol Vis Sci 20:139–148
Metadata
Title
Retrograde transneuronal degeneration in the retina and lateral geniculate nucleus of the V1-lesioned marmoset monkey
Authors
A. Hendrickson
C. E. Warner
D. Possin
J. Huang
W. C. Kwan
J. A. Bourne
Publication date
01-01-2015
Publisher
Springer Berlin Heidelberg
Published in
Brain Structure and Function / Issue 1/2015
Print ISSN: 1863-2653
Electronic ISSN: 1863-2661
DOI
https://doi.org/10.1007/s00429-013-0659-7

Other articles of this Issue 1/2015

Brain Structure and Function 1/2015 Go to the issue

Original Article

Direct targeting of peptidergic amygdalar neurons by noradrenergic afferents: linking stress-integrative circuitry

Original Article

An animal model mimicking pedunculopontine nucleus cholinergic degeneration in Parkinson’s disease

Original Article

Loss of hippocampal interneurons and epileptogenesis: a comparison of two animal models of acquired epilepsy

Original Article

Multivariate classification of social anxiety disorder using whole brain functional connectivity

Original Article

Dynamic brain functional connectivity modulated by resting-state networks

Original Article

Extracellular signal-regulated kinase1/2-dependent changes in tight junctions after ischemic preconditioning contributes to tolerance induction after ischemic stroke