"Cherry-red spot" or "perifoveal white patch"?

The color of the normal fovea, red in Caucasians, contrasts with the surrounding retina, whose colour is altered by accumulation of metabolic products, causing retinal pallor. In this photo-essay, we present the fundus photographs of 3 patients of different race, all with metabolic disease, each of whose fovea contrasts with the surrounding retina, and for whom the expression "cherry red spot" is not necessarily accurate. We suggest that the term "perifoveal white patch" describes this characteristic finding more accurately. We also discuss the pathological entities that may produce this striking appearance, along with its histological and anatomical basis.

Neurobiology and cellular pathogenesis of glycolipid storage diseases.

Disorders of lysosomal metabolism often involve the accumulation of specific types of glycolipid, particularly gangliosides, because of either degradative failure or other currently unknown mechanisms. Although the precise role of gangliosides in cells remains enigmatic, the presence of specific abnormalities secondary to ganglioside accumulation in lysosomal diseases has suggested important biological functions. Chief among these is the growth of new dendrites on particular classes of mature neurons secondary to an increase in GM2 ganglioside. That GM2 has also been shown to be elevated in normal immature neurons coincident with dendritic sprouting provides a compelling argument that this ganglioside plays a role in dendritic initiation. This discovery has led to the search for other regulators of dendritic differentiation that may in some way be linked to the expression and/or function of GM2 ganglioside. Principal candidates that have emerged include tyrosine kinase receptors, small GTPases and calcium/calmodulin-dependent protein kinase II. Understanding the mechanism underlying ectopic dendritogenesis in lysosomal diseases can be expected to generate significant insight into the control of dendritic plasticity in normal brain. The detrimental aspects of ganglioside accumulation in storage diseases as well as the potential link between gangliosides and dendritogenesis also provide a strong rationale for developing pharmacological means to manipulate ganglioside expression in neurons.

Central nervous system inflammation is a hallmark of pathogenesis in mouse models of GM1 and GM2 gangliosidosis.

Mouse models of the GM2 gangliosidoses [Tay-Sachs, late onset Tay-Sachs (LOTS), Sandhoff] and GM1 gangliosidosis have been studied to determine whether there is a common neuro-inflammatory component to these disorders. During the disease course, we have: (i) examined the expression of a number of inflammatory markers in the CNS, including MHC class II, CD68, CD11b (CR3), 7/4, F4/80, nitrotyrosine, CD4 and CD8; (ii) profiled cytokine production [tumour necrosis factor alpha (TNF alpha), transforming growth factor (TGF beta 1) and interleukin 1 beta (IL1 beta)]; and (iii) studied blood-brain barrier (BBB) integrity. The kinetics of apoptosis and the expression of Fas and TNF-R1 were also assessed. In all symptomatic mouse models, a progressive increase in local microglial activation/expansion and infiltration of inflammatory cells was noted. Altered BBB permeability was evident in Sandhoff and GM1 mice, but absent in LOTS mice. Progressive CNS inflammation coincided with the onset of clinical signs in these mouse models. Substrate reduction therapy in the Sandhoff mouse model slowed the rate of accumulation of glycosphingolipids in the CNS, thus delaying the onset of the inflammatory process and disease pathogenesis. These data suggest that inflammation may play an important role in the pathogenesis of the gangliosidoses.

AB variant of infantile GM2 gangliosidosis: deficiency of a factor necessary for stimulation of hexosaminidase A-catalyzed degradation of ganglioside GM2 and glycolipid GA2.

Human kidney extracts heated to 60 degrees and devoid of hexosaminidase activity (2-acetamido-2-deoxy-beta-D-glucoside acetamidodeoxyglucohydrolase EC 3.2.1.30) stimulate more than 20-fold the hexosaminidase A-catalyzed degradation of ganglioside GM2 and of glycolipid GA2, the neuronal storage compounds of GM2 gangliosidosis. The stimulating factor of this extract, which is labile at temperatures above 60 degrees, is also present in kidney extracts from patients with infantile GM2 gangliosidosis having a deficiency of hexosaminidase A (Tay-Sachs disease, variant B) and a deficiency of hexosaminidases A and B (variant 0). Evidence is presented that this factor is defective in the AB-variant of infantile GM2 gangliosidosis which is characterized by an accumulation of glycolipids GM2 and GA2 despite the fact that the degrading enzymes, hexosaminidases A and B, retain normal activity levels. Thus, variant AB is an example of a fatal lipid storage disease that is caused not by a defect of a degrading enzyme but rather by a defective factor necessary for the interaction of lipid substrates and the water-soluble hydrolase.

The cerebral lipidoses.

The disorders presented consist of those clinical entities in which a reasonably well defined lipid storage material accumulated within nervous tissue. Many other progressive, degenerative disorders are suspected of being storage disorders, but their chemical pathology remains unclear. Collectively this group could be designated the sphingolipidoses. In each case, the disease is a genetic disturbance and transmitted as an autosomal recessive. Sphingolipid storage in each disorder is associated with deficient activity of a specific degradative enzyme or enzyme system, and these deficient enzymes are all lysosomal hydrolases. Lysosomal hydrolases catalyze the breakdown of complex molecules in digestive vacuoles (phagocytic or autophagic) within the cells. Lysosomes show structural latency (requiring osmotic shock or freeze thawing in vitro); their enzymes show maximal activity at acidic pH ranges, and on electron microscopic examination they appear as small, electron-dense intracellular bodies. These hydrolytic enzymes seem to have some form of biological vulnerability in terms of their genetic expression, and this vulnerability underlies the sphingolipidoses. Diagnosis in each case is primarily a clinical problem. The presentation of these disorders, especially in intermediate or advanced forms, is sufficiently distinctive to permit a reasonably accurate diagnosis on the basis of history, physical examination, and routine laboratory data. Patients seen in early stages may be more difficult to recognize but follow-up evaluations usually clarify the problem. Specific enzyme assays are now available for confirmation of the diagnosis in these disorders. A frequent finding in this connection is an increase in the activities of noninvolved lysosomal hydrolases in the storage disorders. Once a case is clinically diagnosed, the clinician has the responsibility of ensuring that proper genetic counseling is made available to the affected families. Considerable supportive care is needed in each case. These patients can survive for prolonged periods, and great stress is placed on their families by these prolonged, hopeless illnesses. Since the disorders affect infants or young children, their parents are usually young adults in their early reproductive years. It is essential that they receive information concerning the risk of subsequent pregnancies. Specific diagnosis of the fetus in early pregnancy can be made now by amniocentesis and enzyme assays on cultured fibroblasts. If the fetus is a homozygote on the basis of enzyme assays, the option of therapeutic abortion should be discussed with the family. For many parents there will be considerable sensitivity to the ethical implications of this course and, if any doubt arises, ethical or pastoral consultation should be sought. Although there are no specific therapeutic approaches, a considerable degree of supportive care can and should be given. In the gangliosidoses and late in the course of the leukodystrophies, seizures will present management problems...