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Cerebello-Olivary and Lateral (Accessory) Cuneate Degeneration in a Juvenile American Miniature Horse

Abstract

A 12-month-old American Miniature horse colt was presented to the Virginia Tech Veterinary Teaching Hospital with a 7-month history of progressive ataxia. Physical examination revealed a head intention tremor, base-wide stance, and ataxia. Necropsy findings were confined to the brain. There were bilateral areas of liquefactive necrosis and cavitation corresponding to the dorsal accessory olivary and lateral (accessory) cuneate nuclei. Cerebellar folia of the dorsal vermis were thin. Microscopically, the cerebellar cortex was characterized by patchy areas of Purkinje cell loss with associated variable thinning of the molecular and granule cell layers and astrogliosis. Dorsal accessory olivary and lateral cuneate nuclei were cavitated and had mild glial response around their periphery. Additionally, a focus of necrosis and neuropil vacuolization was found in the right putamen. These findings indicate the presence of a neurodegenerative disorder centered, but not confined to, the cerebellum and its connections in this American Miniature horse colt.

Key words: American Miniature horses; cerebellar disease; equid; neurodegeneration.

There are numerous reports in the veterinary literature of juvenile-onset degenerative conditions of the cerebellum (cerebellar abiotrophies), and these have been reported in a variety of species, including dogs,^5,20 cats,² cattle,^10,13,21,22 sheep^7,17,19 and horses.^4,6,16 In these diseases lesions predominate within the cerebellar cortex where Purkinje cell loss is usually the most common finding. In some cases neurodegeneration within the cerebellum and its connections may be associated with neuronal loss at other sites functionally unrelated to the cerebellum. In domestic animals, these disorders are called multiple system abiotrophies, while in human neuropathology the general term systems degenerations is used.¹⁸ There are few reports of multiple systems abiotrophies in the veterinary literature, and most of these are in dogs.^8,14,15 Here we describe the clinical and morphologic findings in a yearling American Miniature horse that presented clinically with cerebellar signs and at necropsy was found to have neuronal loss in the cerebellar cortex, dorsal accessory olivary nuclei, lateral cuneate nuclei, and right putamen.

A 12-month-old American Miniature horse colt was presented to the Virginia Tech Veterinary Teaching Hospital with a history of progressive neurologic disease that began when the animal was weaned at 5 months of age. Reported clinical signs were loss of balance, head tremor, and falling over. There was no history of trauma or previous illness. The animal was from a closed breeding herd of American Miniature horses with a history of two similar cases in the previous 10 years, both exhibiting progressive neurologic abnormalities consistent with cerebellar disease first noticed at weaning. The parentage of all three affected horses was unknown because multiple stallions were used in an unobserved, random pasture-mating program. Physical examination revealed the colt to be alert and responsive but exhibiting an intention head tremor and a base-wide stance in the forelimbs. The pulse rate, respiratory rate, and temperature were within normal limits. A cranial nerve examination was normal except for an absent menace response with normal vision. There were proprioceptive deficits, hypermetria (grade II/IV forelimbs, grade I/IV hindlimbs), truncal sway, ataxia (grade III/IV hindlimbs, II/IV forelimbs), a tendency to fall to the side or back, and spastic hyperextension of the forelimbs when the colt was startled. There was no evidence of neuromuscular weakness. Clinical signs were consistent with a cerebellar lesion. Hematologic values were normal. Serum vitamin E concentration was 2.8 µg/ml (normal: 1.7–9.5 µg/ml). Cerebrospinal fluid (CSF) analysis was unremarkable. Western immunoblot and polymerase chain reaction tests for Sarcocystis neurona performed on CSF were negative. The colt was euthanatized. Postmortem computed tomographic scan of the brain identified no abnormalities. The brain was removed and fixed whole. Spinal cord was not examined. Serial transverse brain sections revealed thinning of the cerebellar cortex within the vermis (midline cerebellum), especially dorsally. Bilaterally symmetric regions of lacunar-like cavitation were noted within the medulla oblongata corresponding to the dorsal accessory olivary nuclei (DAON) and lateral (accessory) cuneate nuclei (LCN)²³ (Fig. 1). There were no other macroscopic findings. Histologic examination of the brain revealed patchy moderate to marked Purkinje cell loss within the cerebellar vermis that was associated with cortical thinning (Fig. 2). Immunohistochemical staining of cerebellar cortex for glial fibrillary acidic protein (GFAP) revealed a prominent increase in Bergmann astroglial process number and thickness that was spatially associated with regions of Purkinje cell loss (Fig. 3). Associated with this astrogliosis were frequent focal areas of mild Bergmann astrocyte proliferation mainly confined to the deeper parts of the molecular layer. Some Purkinje neurons had slightly shrunken and vacuolated cytoplasm suggesting degeneration. Microscopic examination of DAON and LCN confirmed the presence of large regions of cavitation containing cellular debris and low numbers of activated macrophages characterized by abundant cytoplasm (gitter cells). Parenchyma immediately surrounding regions of necrosis was characterized by a mild glial response and vacuolization (Fig. 4). There were increased numbers of astrocytes with hypertrophied processes (GFAP stain). Activated microglial cells with rod-shaped nuclei were present in low numbers. Capillaries were congested and contained swollen endothelial cells. Occasional swollen axons were present in adjoining parenchyma. There was a narrow crescenteric region of neuropil vacuolization and liquefactive necrosis that measured about 0.8 cm in greatest dimension within the right putamen. It contained low numbers of activated microglial cells with abundant cytoplasm. A similar lesion was not identified in the left putamen despite examining multiple sections from this region. Other brain regions, including the substantia nigra and pontine and cerebellar nuicroscopically unremarkable. Staining of sections of affected brain for ubiquitin using an antibody known to cross-react with equine ubiquitin⁹ failed to identify increased staining of neurons or glial cells when compared with horse control brain.

View larger version (171K): [in this window] [in a new window]   Fig. 1. Cerebellum and medulla oblongata; horse. Bilateral foci of cavitation are present within the lateral (accessory) cuneate nuclei (arrow head) and dorsal accessory olivary nuclei (curved arrow). The dorsal cerebellum vermis shows subtle cortical thinning (straight arrow). Fig. 2. Cerebellar cortex of vermis; horse. Purkinje cells are marked by their absence; only one is noted (curved arrow). The molecular layer shows variable thickness. Bielschowsky stain. Bar = 200 µm. Fig. 3. Cerebellar cortex; horse. Within a region of molecular layer Bergmann glial processes are increased in number and thickness (between straight arrows). Note the absence of Purkinje cells. Avidin-biotin complex immunoperoxidase with anti-GFAP antibodies. Bar = 50 µm. Fig. 4. Medulla oblongata, dorsal accessory olivary nucleus; horse. There is cavitation (asterisk) and more peripheral neuropil vacuolization (arrow). HE. Bar = 50 µm.

The possibility of inbreeding and historical information suggesting previously encountered cases in this herd of horses could be consistent with an inherited condition, most likely autosomal recessive. In humans, cerebellar ataxias can be inherited by autosomal recessive or dominant modes, and for several conditions the genetic defect has been identified.¹¹ Much less is known about the genes involved in similar diseases in domestic animals. Unfortunately, pedigree analysis was not possible as breeding histories were not known. Other possible causes such as neurotoxicity, nutritional deficiency, or a spontaneous dominant mutation cannot be ruled out.

References

1. Adel KA, Bergman RA: Functional Neuroanatomy. Text and Atlas McGraw-Hill, New York, NY 1998
2. Aye MM, Izumo S, Inada S, Isashiki Y, Yamanaka H, Matsumuro K, Kawasaki Y, Sawashima Y, Fujiyama J, Arimura K, Osame M: Histopathological and ultrastructural features of feline hereditary cerebellar cortical atrophy: a novel animal model of human spinocerebellar degeneration. Acta Neuropathol (Berl) 96:379-387, 1998[CrossRef][Medline]
3. Baird JD, MacKenzie CD: Cerebellar hypoplasia and degeneration in part-Arab horses. Aust Vet J 50:25-28, 1974[Medline]
4. Bjorck G, Everz KE, Hansen HJ, Henricson B: Congenital cerebellar ataxia in the Gotland pony breed. Zentralbl Veterinarmed [A] 20:341-354, 1973[Medline]
5. de Lahunta A, Fenner WR, Indrieri RJ, Mellick PW, Gardner S, Bell JS: Hereditary cerebellar cortical abiotrophy in the Gordon Setter. J Am Vet Med Assoc 177:538-541, 1980[Medline]
6. DeBowes RM, Leipold HW, Turner-Beatty M: Cerebellar abiotrophy. Vet Clin North Am Equine Pract 3:345-352, 1987[Medline]
7. Harper PA, Duncan DW, Plant JW, Smeal MG: Cerebellar abiotrophy and segmental axonopathy: two syndromes of progressive ataxia of Merino sheep. Aust Vet J 63:18-21, 1986[Medline]
8. Jaggy A, Vandevelde M: Multisystem neuronal degeneration in cocker spaniels. J Vet Intern Med 2:117-120, 1988[Medline]
9. Jortner BS, Scarratt WK, Modransky PD, Walton A, Perkins SK: Ubiquitin expression in degenerating axons of equine cervical compressive myelopathy. Vet Pathol 33:356-359, 1996[Abstract]
10. Kemp J, McOrist S, Jeffrey M: Cerebellar abiotrophy in Holstein Friesian calves. Vet Rec 136:198, 1995[Medline]
11. Klockgether T, Evert B: Genes involved in hereditary ataxias. Trends Neurosci 21:413-418, 1998[CrossRef][Medline]
12. McCormick DA, Thompson RF: Cerebellum: essential involvement in the classically conditioned eyelid response. Science 223:296-299, 1984[Abstract/Free Full Text]
13. Mitchell PJ, Reilly W, Harper PA, McCaughan CJ: Cerebellar abiotrophy in Angus cattle. Aust Vet J 70:67-68, 1993[Medline]
14. Montgomery DL, Storts RW: Hereditary striatonigral and cerebello-olivary degeneration of the Kerry blue terrier: I. gross and light microscopic central nervous system lesions. Vet Pathol 20:143-159, 1983[Abstract]
15. Palmer AC, Blakemore WF: A progressive neuronopathy in the young Cairn Terrier. J Small Anim Pract 30:101-106, 1989
16. Palmer AC, Blakemore WF, Cook WR, Platt H, Whitwell KE: Cerebellar hypoplasia and degeneration in the young Arab horse: clinical and neuropathological features. Vet Rec 93:62-66, 1973[Medline]
17. Scott PR, Henshaw CJ, Watt NJ: Cerebellar abiotrophy in a three-month-old Charollais lamb. Vet Rec 135:42-43, 1994[Medline]
18. Summers BA, Cummings JF, de Lahunta A: Degenerative diseases of the central nervous system. In: Veterinary Neuropathology, 1st ed., pp 301-307, Mosby, New York, NY 1995
19. Terlecki S, Richardson C, Bradley R, Buntain D, Young GB, Pampiglione G: A congenital disease of lambs clinically similar to "inherited cerebellar cortical atrophy" (daft lamb disease). Br Vet J 134:299-307, 1978[Medline]
20. Thomas JB, Robertson D: Hereditary cerebellar abiotrophy in Australian kelpie dogs. Aust Vet J 66:301-302, 1989[Medline]
21. White ME, Whitlock RH, Lahunta A: A cerebellar abiotrophy of calves. Cornell Vet 65:476-491, 1975[Medline]
22. Whittington RJ, Morton AG, Kennedy DJ: Cerebellar abiotrophy in crossbred cattle. Aust Vet J 66:12-15, 1989[Medline]
23. Yoshikawa T: The brain of the horse. In: Atlas of the Brains of Domestic Animals, 1st ed., pp H24-H26, University of Tokyo Press, Tokyo, Japan 1968

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