Clinical and molecular aspects of nephropathic cystinosis.

Nephropathic cystinosis, an autosomal recessively inherited lysosomal storage disease, results from impaired transport of the disulfide amino acid cystine out of cellular lysosomes. The consequent accumulation and crystallization of cystine destroys tissues, causing growth retardation in infancy, renal failure at 10 years of age, and a variety of other complications. Early oral therapy with the cystine-depleting agent cysteamine prevents renal deterioration and enhances growth. Although the lysosomal cystine carrier has been extensively studied, its molecular structure remains unknown. The lysosomal cystine transporter gene has been mapped by linkage analysis to human chromosome 17p between polymorphic microsatellite markers D17S1583 and D17S1584. Pertinent recombination events and homozygosity by descent has verified that the cystinosis gene lies in the 3.6 cM genetic interval between these two markers. The cystinosis region has been substantially reduced in size by the observation of recombination events in cystinosis patients between markers D17S1828 and D17S2167. According to radiation hybrid analysis, these two markers are separated by 10.2 cR8000 (centirad using 8000 rad radiation hybrids). Estimates of the physical size of this interval range from 187 to 510 kb. Four yeast artificial chromosomes have been identified which form a contig covering the original cystinosis region. Two P1 clones together may span the new, smaller interval, meaning that the cystinosis gene would lie on one of them. Current efforts are being directed toward using these P1 clones to isolate candidate cDNAs by a variety of methods. The ultimate cloning of the cystinosis gene will reveal how functional lysosomal porters are synthesized, targeted, processed, and integrated into the lysosomal membrane.

Intrafamilial variability in Hurler syndrome and Sanfilippo syndrome type A: implications for evaluation of new therapies.

Intrafamilial variability has not been reported previously in Hurler syndrome or Sanfilippo syndrome type A. We describe two families in which sibs with comparable deficiencies of alpha-iduronidase (Hurler) or sulfamidase (Sanfilippo type A) activities in vitro nonetheless have divergence in clinical severity and disease progression. These cases underscore the need for caution in counseling as well as the limitations of using sibs as controls in evaluating the outcome of treatment.

The presence of two different infantile Tay-Sachs disease mutations in a Cajun population.

A study was undertaken to characterize the mutation(s) responsible for Tay-Sachs disease (TSD) in a Cajun population in southwest Louisiana and to identify the origins of these mutations. Eleven of 12 infantile TSD alleles examined in six families had the beta-hexosaminidase A (Hex A) alpha-subunit exon 11 insertion mutation that is present in approximately 70% of Ashkenazi Jewish TSD heterozygotes. The mutation in the remaining allele was a single-base transition in the donor splice site of the alpha-subunit intron 9. To determine the origins of these two mutations in the Cajun population, the TSD carrier status was enzymatically determined for 90 members of four of the six families, and extensive pedigrees were constructed for all carriers. A single ancestral couple from France was found to be common to most of the carriers of the exon 11 insertion. Pedigree data suggest that this mutation has been in the Cajun population since its founding over 2 centuries ago and that it may be widely distributed within the population. In contrast, the intron 9 mutation apparently was introduced within the last century and probably is limited to a few Louisiana families.

Tay-Sachs disease as a model for screening inborn errors.

In the absence of treatments for most inborn errors of metabolism, the goal of both geneticists and health care providers has been the prevention of disease through identification of at-risk couples. When the enzyme deficiency responsible for a disorder is known, heterozygotes can frequently be identified by enzyme assay. The presence or absence of specific mutations in the genes coding for these enzymes may be determined directly if the gene of interest has been identified and characterized. Because the inherited metabolic disorders are rare, these approaches are useful only for individuals with a family history of a specific disease or for populations in which the gene frequency for a specific disease is increased. Tay-Sachs disease is a fatal, autosomal recessive, metabolic disease caused by deficient activity of the lysosomal enzyme Hex A. Although it is rare in the general population, in which the heterozygote frequency is approximately 1/167, it is elevated in a few populations, including the Ashkenazi Jewish community, in which the heterozygote frequency is 1/30. The ability to detect TSD heterozygotes reliably and to diagnose TSD prenatally using a simple and rapid enzyme assay has made prevention of this disorder possible through education and carrier screening. The identification of specific TSD mutations at the DNA level enables laboratories to provide more accurate screening and diagnosis in some families. The success of TSD screening in the Ashkenazi Jewish population has made it the prototype for screening among the inborn errors of metabolism. The TSD example becomes increasingly relevant as heterozygote detection becomes possible for other genetic disorders that are increased in well-defined populations. Cystic fibrosis is such a disease in the caucasian population.