Animal medical genetics: a historical perspective on more than 50 years of research into genetic disorders of animals at Massey University.

Over the last 50 years, there have been major advances in knowledge and technology regarding genetic diseases, and the subsequent ability to control them in a cost-effective manner. This review traces these advances through research into genetic diseases of animals at Massey University (Palmerston North, NZ), and briefly discusses the disorders investigated during that time, with additional detail for disorders of major importance such as bovine α-mannosidosis, ovine ceroid-lipofuscinosis, canine mucopolysaccharidosis IIIA and feline hyperchylomicronaemia. The overall research has made a significant contribution to veterinary medicine, has provided new biological knowledge and advanced our understanding of similar disorders in human patients, including testing various specific therapies prior to human clinical trials.

Phospholipid fatty acids in brains of normal sheep and sheep with ceroid-lipofuscinosis.

The ceroid-lipofuscinoses are a group of inherited diseases of humans and animals characterised by brain atrophy and the storage of a fluorescent lipopigment. Brain grey matter phospholipid fatty acids of diseased sheep are compared with those of normal sheep. Phosphatidylethanolamine of diseased sheep contains more 18:1(n-9) and less 22:6(n-3) than normal and their phosphatidylcholine less 16:0. Other differences are minor. All differences are in the same direction as those reported for the infantile form of human ceroid-lipofuscinosis, but are smaller. Normal sheep grey matter phosphatidylinositol contains 8.5% 20:4(n-6) and 24.6% 22:6(n-3), in contrast to 28.5 and 4.6%, respectively, in humans. The other sheep phospholipids have similar fatty acid profiles to those from humans. Apart from low levels of 20:3(n-9) and 22:3(n-9) they contain no additional non-essential fatty acid derived species. No sign of essential fatty acid deficiency occurs in either diseased or normal sheep. It is concluded that sheep must conserve their restricted essential fatty acid supply for structural functions, and that an abnormality in fatty acid metabolism is not primarily involved in the pathogenesis of ceroid-lipofuscinosis. The results also call into question the primary role of peroxidation of polyunsaturated fatty acids in lipopigment formation in this disease.

Analysis of dolichyl pyrophosphoryl oligosaccharides in purified storage cytosomes from ovine ceroid-lipofuscinosis.

Ovine ceroid-lipofuscinosis is an inherited neurodegenerative disorder characterised by the accumulation of storage cytosomes in brain and visceral organs. Phosphorylated dolichol-containing compounds, largely in the form of dolichyl pyrophosphoryl oligosaccharides, have been shown to constitute 1-2% of the dry weight of storage cytosomes isolated from brain and pancreas, and 0.5 and 0.1% respectively of storage cytosomes isolated from liver and kidney. The carbohydrate portion of these glyconjugates in storage cytosomes isolated from brain, pancreas and liver consisted of a series of oligosaccharides of composition Man2-9GlcNAc2, with Man5-8GlcNAc2 predominating. The concentrations of dolichyl pyrophosphoryl oligosaccharides in storage cytosomes from ovine ceroid-lipofuscinosis are much higher than has been reported for endoplasmic reticulum, their normal functional location.

Storage of saposins A and D in infantile neuronal ceroid-lipofuscinosis.

We have isolated storage cytosomes from brain tissue of patients with infantile neuronal ceroid-lipofuscinosis. The purified storage bodies were subjected to compositional analysis which revealed a high content of proteins, accounting for 43% of dry weight. Saposins A and D, also known as sphingolipid activator proteins (SAPs), were shown to constitute a major portion of the accumulated protein using gel electrophoresis and sequence analysis. This is the first time that saposins have been found to be stored in any form of neuronal ceroid-lipofuscinosis.

Sheep and other animals with ceroid-lipofuscinoses: their relevance to Batten disease.

Distinct pathological and histopathological changes distinguish the ceroid-lipofuscinoses from other storage diseases of humans and animals. These various disease entities likely reflect a variety of mutations of the same gene, or mutations of different genes associated with metabolism of the same or similar substrates. The disease in sheep most closely resembles the juvenile human disease. In it 50% of the lipopigment consists of subunit c of mitochondrial ATP synthase while the remaining constituents are considered normal for a lysosomal derived cytosome. The same subunit c has been shown to be also stored in affected English Setter, Border Collie, and Tibetan Terrier dogs, the Devon cow, and in the late infantile and juvenile human forms of disease but not in the infantile form. Thus it gives a chemical unity to at least some members of the group and allows a major conceptual change in regard to further directions of research.

Batten disease and the ATP synthase subunit c turnover pathway: raising antibodies to subunit c.

Analysis of storage bodies in the ceroid-lipofuscinoses (Batten disease) has demonstrated a high protein content suggestive of a proteinosis. Direct N-terminal sequencing has shown that subunit c of mitochondrial ATP synthase is specifically stored in the disease in sheep and cattle, and in the human late infantile and juvenile diseases, as well as in 3 breeds of dogs. No differences have been found between the stored subunit c and that in normal mitochondria. No other mitochondrial components are stored. Different proteins, sphingolipid activator proteins (SAPs or saposins) A and D, are stored in the infantile disease. Linkage studies have shown that different forms of ceroid-lipofuscinosis are coded for on different genes on different chromosomes. The genes for subunit c, its production, its insertion into mitochondria, and mitochondrial function are normal. This suggests that underlying the various forms of the disease is a family of lesions in the normal pathway of subunit c turnover, after its normal insertion into the ATP synthase complex. Antibodies to subunit c offer one way of mapping that pathway and detecting the sites of lesions. Specific antibodies have been raised against stored subunit c, using a liposomal adjuvant system which proved superior to classical adjuvants. These antibodies are also useful diagnostically, both in Western blotting and in immunocytochemistry.

Immunocytochemical studies in the ceroid-lipofuscinoses (Batten disease) using antibodies to subunit c of mitochondrial ATP synthase.

Immunocytochemistry, using antibodies against subunit c of mitochondrial ATP synthase, has been carried out in the ovine, canine, late infantile, and adult forms of ceroid-lipofuscinosis. Intensity of staining varied depending on the particular disease, species, fixation regime, and the antibody used. Differential staining of storage cytosomes in neurons of affected sheep and those in the late infantile patient suggested exposure of different epitopes. This was supported by the variable staining using two different antibodies in ovine, late infantile, and adult onset (Kufs) diseases. Immunostaining of muscle in the late infantile, and muscle and ear cartilage in affected sheep can assist diagnosis but positive results may depend on the age of the patient, at least in the latter species. In these tissues there was immunostaining of structures not identified by histochemical or fluorescence microscopy in addition to storage cytosomes that could be identified by these means. Poor or no immunostaining occurred with canine tissues. At the ultrastructural level, storage cytosomes but not other organelles stained with the immunogold method.

Tissue culture loading test with storage granules from animal models of neuronal ceroid-lipofuscinosis (Batten disease): testing their lysosomal degradability by normal and Batten cells.

Storage granules (SGs) from ovine and canine models of Batten disease were found to be easily phagocytosed by four cell types studied. The cell types tested were human fibroblasts and peripheral monocytes (control and from a late infantile Batten disease patient), rat C6 cell line, and neonatal cardiomyocytes. The phagocytosed SGs elicited an increase in acid phosphatase activity which was localized in the phagolysosome. After phagocytosis SGs were followed for various times ranging from 7 to 21 days and were found to be of unchanged density (phase contrast), autofluorescence, and ultrastructural appearance. These findings point to their undergradability, or very low degree of degradability, in phagolysosomes in both normal or Batten cultured cells. The Batten disease SGs are not toxic and did not cause any adverse affect on the host cells. Either the normal clearance rate from lysosomes is too slow to be measured by this technique or subunit c accumulation in lysosomes need not result from a primary lysosomal protease defect. Subunit c may aggregate, because of the lack of some normally preventive factor, resulting in a physical barrier to the degradation of this highly apolar molecule.

Variant proteins in ovine ceroid-lipofuscinosis.

Two-dimensional polyacrylamide gel electrophoresis has been used to search for disease-related protein variation in South Hampshire sheep with ovine ceroid-lipofuscinosis. Several hundred proteins in homogenates and subcellular fractions from livers have been examined, using isoelectric focusing as the first dimension separation, and SDS PAGE in the second dimension. Under these circumstances it was not possible to detect subunit c of the Fo region of ATP synthase, as this protein did not enter the isoelectric focusing gels. However, our studies emphasize the selective nature of misprocessing of subunit c, as we have not been able to detect any other consistent variation between affected and control animals for over 200 mitochondrial fraction proteins. Comparison of the presence or absence, and abundance, of proteins from isolated storage bodies with their counterparts in subcellular fractions from normal liver indicated that storage bodies contained a small subset of mitochondrial proteins, in addition to subunit c, with possible minor contributions from lysosomal, microsomal, and soluble proteins. Analysis of extramitochondrial proteins showed greater than 10-20-fold accumulation of ferritin light chains in microsomes, and partial loss of a putatively lysosomal protein, in ovine ceroid-lipofuscinosis. In addition, senescence marker protein was more abundant in the cytosolic fraction of controls, compared with affected individuals. We are currently investigating the basis and significance of these differences.

Diagnoses of neuronal ceroid-lipofuscinosis by immunochemical methods.

The neuronal ceroid-lipofuscinoses (NCL), also known as Batten disease, are a not uncommon group of disorders affecting infants, children, and young adults. The abnormal ultrastructural profiles seen in NCL are used for standard diagnosis; however, they can be missed, and are also found in other neurodegenerative conditions. Furthermore, there is an overlap between the types of inclusion profiles among the different forms of NCL. Therefore, a more specific and biochemically-based marker is necessary to confirm the diagnosis of NCL. Antibodies raised against the storage material from the ovine form of NCL (mitochondrial ATP synthase subunit c) were utilized to determine whether NCL could be distinguished from other metabolic-neurodegenerative disorders. By immunoblotting and immunohistochemistry, several brain samples of well-evaluated NCL cases confirmed increased accumulations in all NCL cases except in the brain of an infantile-onset NCL patient. The immunoblot studies of skin fibroblasts and brain were sensitive but not highly specific to NCL, due to the recognition of this material in normal controls as well as in other neurogenetic diseases. Immunocytochemistry of skin fibroblasts clearly distinguished LINCL and JNCL cases from controls, and with further refinement has the potential for becoming a diagnostic tool.

Mitochondrial ATP synthase subunit c storage in the ceroid-lipofuscinoses (Batten disease).

The ceroid-lipofuscinoses (Batten disease) are neurodegenerative inherited lysosomal storage diseases of children and animals. A common finding is the occurrence of fluorescent storage bodies (lipopigment) in cells. These have been isolated from tissues of affected sheep. Direct protein sequencing established that the major component is identical to the dicyclohexylcarbodiimide (DCCD) reactive proteolipid, subunit c, of mitochondrial ATP synthase and that this protein accounts for at least 50% of the storage body mass. No other mitochondrial components are stored. Direct sequencing of storage bodies isolated from tissues of children with juvenile and late infantile ceroid-lipofuscinosis established that they also contain large amounts of complete and normal subunit c. It is also stored in the disease in cattle and dogs but is not present in storage bodies from the human infantile form. Subunit c is normally found as part of the mitochondrial ATP synthase complex and accounts for 2-4% of the inner mitochondrial membrane protein. Mitochondria from affected sheep contain normal amounts of this protein. The P1 and P2 genes that code for it are normal as are mRNA levels. Oxidative phosphorylation is also normal. These findings suggest that ovine ceroid-lipofuscinosis is caused by a specific failure in the degradation of subunit c after its normal inclusion into mitochondria, and its consequent abnormal accumulation in lysosomes. This implies a unique pathway for subunit c degradation. It is probable that the human late infantile and juvenile diseases and the disease in cattle and dogs involve lesions in the same pathway.

Changes in GABAergic neuron distribution in situ and in neuron cultures in ovine (OCL6) Batten disease.

The neuronal ceroid lipofuscinoses (NCLs) are a group of inherited human and animal diseases characterized by progressive brain atrophy. A form in sheep is syntenic to the human CLN6 disease. Cell type specific neurodegeneration in these sheep was indicated by the distribution of GABAergic interneurons in coronal sections of normal and CLN6 affected sheep brains. A reduction of parvalbumin immunoreactive neurons in NCL cerebral cortex was the most striking feature. This was most pronounced in parietal cortex where very few positive cells remained. Calretinin immunoreactive somata in infragranular layers of the neocortex were also reduced while the number of calbindin positive cells was similar in affected and normal brains. There were fewer GAD immunoreactive neurons in the deeper layers of all NCL cortical areas examined. The parietal lobe was relatively more affected than frontal or temporal lobes while the cerebellum and the basal ganglia showed no signs of selective neuron loss. Since horizontally extending basket cells are mainly labelled by parvalbumin, the loss of these interneurons in the neocortex may render pyramidal neurons more excitable and compromise their co-ordinated output. In vitro, cultures of control and affected neurons from 60 to 70-day-old fetal brain hemispheres were examined for the presence of GABAergic and glutamatergic neurons. Different neurons developed distinct immunoreactivity to glutamate or GABA but the overall distribution was similar in normal and affected cultures. This culture system may provide a useful model to compare GABAergic cell function of normal and NCL affected neurons.

Glycoconjugates in storage cytosomes from ceroid-lipofuscinosis (Batten's disease) and in lipofuscin from old-age brain.

The ceroid-lipofuscinoses (CL) are a group of inherited diseases characterised by the accumulation, in brain, of autofluorescent storage cytosomes which have similar histochemical staining properties to lipofuscin, the neuronal wear and tear pigment of old-age brain. The storage cytosomes stain strongly with periodic acid-Schiff reagent (PAS), indicating the presence of carbohydrate. In brain from each childhood form of CL, concentrations of phosphorylated dolichol (Dol-P) are 10- to 20- fold higher than in age-matched controls. Brain Dol-P concentrations are also increased between 2 and 5- fold in several different lipidoses and in elderly subjects. Much of the Dol-P which accumulates is located within the storage cytosomes. Dol-P constitutes 2-3% of the dry weight of storage cytosomes from juvenile and late-infantile CL, and 0.3-0.7% of storage cytosomes from infantile CL, ovine CL and of lipofuscin isolated from old age brain. The bulk of the Dol-P in CL brain and in isolated storage cytosomes is present as dolichyl pyrophosphoryl oligosaccharides (Dol-PP-OS). The constitutions of the oligosaccharide moieties differ in the various forms of the disease. Histochemical analysis of frozen sections of unfixed brain after extraction by various lipid solvents indicates that the major part of the PAS positive intraneuronal material in CL brain and in old-age brain has the extraction properties of Dol-PP-OS. Carbohydrate represents 4-7% of the dry weight of CL storage cytosomes and of lipofuscin. The major monosaccharide components are mannose, N-acetyl glucosamine, glucose and galactose. Depending on the form of the disease studied, up to 40% of this material can be accounted for by Dol-PP-OS. Polyacrylamide gel electrophoresis of storage cytosomes followed by lectin blotting demonstrates several low molecular weight components which bind concanavalin A. These do not coelute with the major protein components and may well be Dol-PP-OS. We conclude that Dol-PP-OS are concentrated in storage cytosomes in CL and are one of their major glycoconjugate components.

Lysosomal storage of the DCCD reactive proteolipid subunit of mitochondrial ATP synthase in human and ovine ceroid lipofuscinoses.

The ceroid lipofuscinoses (Batten's disease) are a group of neuro-degenerative lysosomal storage diseases of children and animals that are recessively inherited. In the diseased individuals fluorescent storage bodies accumulate in a wide variety of cells, including neurons. The material stored in the cells of sheep affected with ceroid lipofuscinosis is two-thirds protein. The stored material does not arise from lipid peroxidation or a defect in lipid metabolism, and the lipid content is consistent with a lysosomal origin for the storage bodies. The major protein stains poorly with Coomassie blue dye and is soluble in organic solvents. It has an apparent molecular weight of 3,500 and its amino acids sequence is identical to that of the dicyclohexylcarbodiimide (DCCD) reactive proteolipid, subunit c, of mammalian mitochondrial ATP synthases. Apart from removal of mitochondrial import sequences, it has not been modified post-translationally. At least 50% of the mass of the storage bodies is composed of this protein. A minor protein sequence related to the 17-kDa subunit of vacuolar H(+)-ATPase is also found in storage bodies isolated from pancreas. As in humans and cattle, the ovine protein is the product of two expressed genes named P1 and P2. In normal and diseased animals there are no differences in sequences between P1 cDNAs or P2 cDNAs, nor do levels of mRNAs in liver for P1 or P2 differ substantially between normal and diseased animals. Both normal and diseased sheep also express a spliced pseudogene encoding amino acids 1 to 31 of the mitochondrial import presequence. The peptides they encode differ by one amino acid; arginine-23 is changed to glutamine in the diseased sheep. Storage bodies isolated from brains and pancreas of children affected with the juvenile and late infantile forms of ceroid lipofuscinosis also contain large amounts of material that is identical to subunit c of ATP synthase. However, the protein is not present in storage bodies isolated from brains of patients affected with the infantile form of the disease, and these storage bodies contain other unidentified proteins. It is possible that the cause of ovine, juvenile and late infantile ceroid lipofuscinoses is related to a defect in degradation of the subunit c of mitochondrial ATP synthase.

The frequent occurrence of thyroid tumours in aged horses.

Thyroid tumours have been described as "moderately common" in horses, but diseases associated with them are rare and the actual incidence has not been reported. A survey of thyroids from 29 horses aged 12 to 32 years revealed gross lesions in 11 animals, all older than 17. Most lesions were microfollicular adenomas. There was no evidence that the horses suffered from long-standing iodine deficiency or diffuse hyperplasia. Adenomas were more common than hyperplastic nodules and it is unlikely that the former arose from the latter. One thyroid adenocarcinoma was discovered. Progression from thyroid hyperplasia to adenomas and thence to adenocarcinomas has been reported in rodent species, but this study suggests that such progression does not occur in horses. As evidence of its occurrence in man is also lacking, the horse may be a more appropriate model than the rodent for human thyroid neoplasia.

Lipofuscin and abnormalities in colloid in the equine thyroid gland in relation to age.

Lipofuscin accumulation and other histological changes in thyroid tissue, previously reported to be age-related, were studied in 31 horses aged up to 35 years. The number of lipofuscin granules relative to thyrocytes increased from birth to 5 years of age. There was a wide individual variation in the number of lipofuscin granules in thyrocytes in mature horses, but this was not directly related to age. Several abnormalities were identified in thyroid colloid. The prevalence of spherites, lipofuscin granules, nucleated cells and shreds of colloid increased with age, but the prevalence of calcium oxalate crystals, erythrocytes, basophilic zones and solid fragments of colloid did not. In horses younger than 7 years, particularly large lipofuscin granules were found in thyrocytes of a small proportion of follicles which also contained abnormal colloid. Such follicles became more common in older horses without being accompanied by large lipofuscin granules. No correlation was found between granule numbers and frequency of colloid abnormalities. These results cast doubt on the traditional assumption that lipofuscin is indigestible cellular residue, since there was little evidence for excretion of granules. It is postulated that lipofuscin in this tissue may be a normal stage in lysosomal catabolism.

Ovine ceroid-lipofuscinosis is a proteolipid proteinosis.

The pathogenesis of the ceroid-lipofuscinoses, inherited storage diseases of children, was studied in an ovine model. This was shown to have clinical and pathological features most in common with the late infantile and juvenile human forms of the disease. The ability to study sequential changes allowed the retinal lesions to be described as a dystrophy of photoreceptor outer segments which preceded loss of the photoreceptor cells. An early decrease in amplitude of the c-wave electroretinograph was attributed to a decrease in the transpigment epithelial component. The decreased a- and b-wave amplitudes were attributed to the changes in and loss of, photoreceptor cells. The chemical components of isolated storage cytosomes were analyzed and shown to consist mostly of protein. Sequence analysis of the dominantly stored protein showed that it was identical to the DCCD reactive proteolipid or subunit c of mitochondrial adenosine triphosphate synthase and that it comprised approximately 50% of storage material. Based on the adage that the dominantly stored species should reflect the underlying biochemical anomaly, it was concluded that it was of pathogenic significance. This highly hydrophobic protein tends to extract with lipids in chloroform/methanol and is thus known as a proteolipid. Some of the remainder of the stored proteins also had this characteristic. It was concluded that ovine ceroid-lipofuscinosis was a proteinosis, more specifically a proteolipid proteinosis and as such it forms the prototype of a new class of storage diseases. Recognition of the nature of the dominantly stored chemical species has helped understanding of a variety of chemical and physical characteristics attributed to the whole pigment.(ABSTRACT TRUNCATED AT 250 WORDS)

Neuronal ceroid lipofuscinosis in Merino sheep.

OBJECTIVE: To characterise neuronal ceroid lipofuscinosis (NCL) in Merino sheep. DESIGN: A prospective clinical, pathological, biochemical and genetic study. PROCEDURE: NCL cases were studied from a medium-wool Merino flock, the stud of origin of its replacement rams, and an experimental flock established at the University of Sydney. RESULTS: Behavioural changes and visual impairment were first detected at 7 to 12 months of age and progressed, with associated motor disturbances and at later stages seizures, to premature death by 27 months of age. At necropsy there was severe cerebrocortical atrophy associated with neuronal loss, astrocytosis and the presence in neurons of eosinophilic intracytoplasmic storage bodies with the characteristics of a lipopigment. In the retina there was progressive loss of photoreceptor cells. Storage bodies isolated from fresh brain, liver and pancreas formed electron-dense aggregates and coarse multilamellar and fine fingerprint profiles ultrastructurally, and consisted mainly of the hydrophobic protein, subunit c of mitochondrial ATP synthase. A homozygosity mapping approach localised the gene causing the disease in Merino sheep to the chromosomal region (OAR7q13-15) associated with NCL in South Hampshire sheep. CONCLUSION: NCL in Merino sheep is a subunit c-storing disease, clinically and pathologically similar to NCL in South Hampshire sheep. We propose that the disease in both breeds represents mutation at the same gene locus in chromosomal region OAR7q13-15.

Bovine ceroid-lipofuscinosis (Batten's disease): the major component stored is the DCCD-reactive proteolipid, subunit C, of mitochondrial ATP synthase.

The ceroid-lipofuscinoses (Batten's disease) are a group of recessively inherited lysosomal storage diseases of children and animals in which there is intracellular accumulation of a fluorescent lipopigment in a wide variety of cells. Lipopigment bodies isolated from pancreas, liver, kidney and brain tissue from a heifer affected with ceroid-lipofuscinosis contained between 55 and 62% protein. A dominant component comigrated on LDS-PAGE with the major low molecular weight protein stored in ovine ceroid-lipofuscinosis. It was identified by amino acid sequence and mass spectroscopy as the full subunit c of mitochondrial ATP synthase, normally found only in the inner mitochondrial membrane, where it is estimated to account for 2-4% of the membrane protein. In pancreatic lipopigment it accounted for at least 40% of the total lipopigment mass and this storage was considered specific to the disease. No other mitochondrial proteins were found in storage bodies. These results are similar to those found in studies on the ovine and the late infantile and juvenile human forms of the disease. It is concluded that bovine ceroid-lipofuscinosis is also a proteolipid proteinosis in which subunit c of mitochondrial ATP synthase is specifically stored in lysosome derived organelles.