Mutation analysis and description of sixteen RSH/Smith‐Lemli‐Opitz syndrome patients: Polymerase chain reaction–based assays to simplify genotyping

We report the clinical and molecular data of 16 patients with RSH/Smith‐Lemli‐Opitz syndrome (RSH/SLOS) with varying phenotypic severity, for which we have identified mutations in both alleles. RSH/SLOS is an autosomal recessive malformation syndrome caused by mutations in the gene encoding the sterol Δ⁷‐reductase. This protein catalyzes the reduction of 7‐dehydrocholesterol to cholesterol in the last step of cholesterol biosynthesis via the Kandutsch‐Russell pathway. In addition to previously reported mutations (T93M, L109P, G147D, W151X, T154M, R242C, A247V, T289I, IVS8‐1G→C, Y408H, and E448K), we have identified six previously undescribed mutations (321G→C, W177R, R242H, Y318N, L341P, and C444Y). We also report rapid polymerase chain reaction (PCR)–based assays developed to detect four of the recurring mutations (T93M, W151X, V326L, and R404C) and six other RSH/SLOS mutations (321G→C, L109P, T154M, T289I, Y318N, and L341P). The purpose of this article is to correlate detailed clinical information with molecular data in order to improve our understanding of the genotype–phenotype correlation of RSH/SLOS and to report the development of PCR‐based assays that will allow more rapid mutation analysis. Am. J. Med. Genet. 94:214–227, 2000. Published 2000 Wiley‐Liss, Inc.     

Spectrum of Delta(7)-dehydrocholesterol reductase mutations in patients with the Smith-Lemli-Opitz (RSH) syndrome

The Smith-Lemli-Opitz syndrome (SLOS; also known as the RSH syndrome) is an autosomal recessive genetic disorder, leading to characteristic multi-organ developmental abnormalities, dysmorphic facies, limb malformations and mental retardation. Mutations in the gene for Delta(7)-dehydrocholesterol reductase (Delta(7)-reductase), which catalyzes the last step in cholesterol biosynthesis, cause the disease. We screened 32 patients with SLOS, 28 from the USA and four from Sweden. Twenty-two different nucleotide changes, predicted to be disease-causing mutations, were identified; 20 missense mutations, one nonsense mutation and one splice-site mutation involving the exon 9 acceptor site (IVS8 -1G-->C) were detected. All probands were heterozygous for mutations. Twelve of these mutations have not been reported previously, including missense mutations L148R, F168I, D175H, P179L, P243R, F284L, N287K, F302L, R404S, Y462H, R469P and one nonsense mutation W37X [corrected]. Coupled with previously reported mutations, these findings bring the total of different Delta(7)-reductase mutations to 36. These are distributed throughout the coding sequence of the Delta(7)-reductase gene except exons 3 and 5, with a clustering in exon 9. Three mutations account for 54% of those observed in our cohort, the splice acceptor site mutation IVS8 -1G-->C (22/64 alleles, 34%), T93M (8/64, 12.5%) and V326L (5/64, 7.8%). Severity of SLOS was negatively correlated with both plasma cholesterol and relative plasma cholesterol, but not with 7-dehydrocholesterol, the immediate precursor, confirming previous observations. However, no correlation was observed between mutations and phenotype, suggesting that the degree of severity may be affected by other factors. We estimate that between 33 and 42% of the variation in the SLOS severity score is accounted for by variation in plasma cholesterol. Thus, factors other than plasma cholesterol are additionally involved in determining severity.     

Frequency gradients of DHCR7 mutations in patients with Smith-Lemli-Opitz syndrome in Europe: evidence for different origins of common mutations

Smith-Lemli-Opitz syndrome/RSH (SLOS) is a multiple congenital anomaly syndrome caused by mutations in the gene for Delta7-sterol reductase (DHCR7) which catalyses the last step in the biosynthesis of cholesterol. SLOS is among the common recessive disorders in Europeans but almost absent in most other populations. More than 40 mutations in the DHCR7 gene some of which are frequent have been described in SLOS patients of various origins. Here we report mutation analysis of the DHCR7 gene in SLOS patients from Poland (n = 15), Germany/Austria (n = 22) and Great Britain (n = 22). Altogether 35 different mutations were identified and the two null mutations IVS8-1G > C and W151X were the most frequent in the total sample. In all three populations three mutations accounted for >0.5 of SLOS chromosomes. The mutational spectra were, however, significantly different across these populations with each of the common mutations showing an east-west gradient (W151X, V326L) or vice versa (IVS8-1G > C). W151X is the most frequent (0.33) mutation in Polish SLOS patients. It has an intermediate frequency in German/Austrian patients (0.18) and is rare among British patients (0.02). V326L shows the same distribution pattern (Poland 0.23, Germany/Austria 0.18, Britain 0.02). In contrast IVS8-1G > C is most frequent in Britain (0.34) intermediate in Germany/Austria (0.20) and rare in Poland (0.03). All analysed IVS8-1G > C and V326L alleles shared the same DHCR7 haplotype, whereas the W151X mutation occurred on different haplotypes. There is evidence for both recurrent mutations and founder effects. Together this suggests that the common SLOS mutations in Europe have different geographic and historic origins and spread across the continent in opposite directions.     

DHCR7 genotypes of cousins with Smith-Lemli-Opitz syndrome

Smith-Lemli-Opitz syndrome (SLOS) is an autosomal recessive disorder of cholesterol biosynthesis caused by mutations of the 7-dehydrocholesterol reductase gene (DHCR7). We report on three cousins with SLOS, all of whom were found to be compound heterozygotes for the common splice site mutation IVS8-1G-->C and the missense mutation T289I. DNA analysis of one set of parents demonstrated that the father carried the missense mutation and the mother carried the IVS8-1G-->C mutation. By extension, the two unrelated mothers were both heterozygous for IVS8-1G-->C. This finding supports the notion of a high carrier frequency of the IVS8-1G-->C null mutation in Northern European Caucasians.     

Mutations of the phenylalanine hydroxylase (PAH) gene in Brazilian patients with phenylketonuria

In the present study, 115 Brazilian families with phenylketonuria (PKU), mainly from the Southeast of the country, were studied using three laboratory methods (DGGE, SSCP, and sequencing). All 13 exons of the PAH gene were analyzed, including the splicing sites and the promoter region. We identified 50 distinct mutations and characterized 91% of the mutant alleles. The five most prevalent mutations of the 50 mutations identified (50% of the PKU alleles) were IVS10nt-11G-->A (17.4%), followed by R261Q (12.2%), V388M (9.1%), R252W (6.5%), and R270K (4.8%). The other mutations were rare. The mutation spectrum included 10 novel mutations (IVS5nt-54A-->G, IVS6nt17G-->T, E205A, F240S, K274E, I318T, L321L, C357G, IVS11nt17G-->A, and S411X). To characterize the origin and distribution of the PAH alleles we determined the association between the detected mutations and the PCR/RFLP haplotypes and VNTR alleles located on the PAH gene. For those patients whose mutant alleles were detected, we calculated the correlation with pretreatment phenylalanine levels, thus establishing a genotype/phenotype correlation. The present results confirm the marked heterogeneity observed at the PAH locus and contribute to the understanding of the distribution and frequency of PKU mutations in the Brazilian population.     

Characterization of eleven novel mutations (M45L, R119H, 544delG, G145V, H154Y, C184Y, D289V, 862+5A, 1172delC, R411X, E459K) in the tissue-nonspecific alkaline phosphatase (TNSALP) gene in patients with severe hypophosphatasia. Mutations in brief no. 217. Online

Hypophosphatasia is a rare inherited disorder characterized by defective bone mineralization and deficiency of serum and tissue liver/ bone/kidney tissue alkaline phosphatase (L/B/K ALP) activity. We report the characterization of tissue-nonspecific alkaline phosphatase (TNSALP) gene mutations in a series of 9 families affected by severe hypophosphatasia. Fourteen distinct mutations were found, 3 of which were previously reported in the North American or Japanese populations. Seven of the 11 new mutations were missense mutations (M45L, R119H, G145V, C184Y and H154Y, D289V, E459K), the four others were 2 single nucleotide deletions (544delG and 1172delC), a mutation affecting donor splice site (862 + 5A) and a nonsense mutation (R411X).     

Mutational analysis of mucopolysaccharidosis type VI patients undergoing a trial of enzyme replacement therapy

Mucopolysaccharidosis type VI (MPS VI), or Maroteaux-Lamy syndrome, is a lysosomal storage disorder caused by a deficiency of N-acetylgalactosamine-4-sulfatase (ARSB). Seven MPS VI patients were chosen for the initial clinical trial of enzyme replacement therapy. Direct sequencing of genomic DNA from these patients was used to identify ARSB mutations. Each individual exon of the ARSB gene was amplified by PCR and subsequently sequenced. Nine substitutions (c.289C>T [p.Q97X], c.629A>G [p.Y210C], c.707T>C [p.L236P], c.936G>T [p.W312C], c.944G>A [p.R315Q], c.962T>C [p.L321P], c.979C>T [p.R327X], c.1151G>A [p.S384N], and c.1450A>G [p.R484G]), two deletions (c.356_358delTAC [p.Y86del] and c.427delG), and one intronic mutation (c.1336+2T>G) were identified. A total of 7 out of the 12 mutations identified were novel (p.Y86del, p.Q97X, p.W312C, p.R327X, c.427delG, p.R484G, and c.1336+2T>G). Two of these novel mutations (p.Y86del and p.W312C) were expressed in Chinese hamster ovary cells and analyzed for residual ARSB activity and mutant ARSB protein. The two common polymorphisms c.1072G>A [p.V358M] and c.1126G>A [p.V376M] were identified among the patients, along with the silent mutation c.1191A>G. Cultured fibroblast ARSB mutant protein and residual activity were determined for each patient, and, together with genotype information, were used to predict the expected clinical severity of each MPS VI patient.     

Fabry disease: 45 novel mutations in the alpha-galactosidase A gene causing the classical phenotype

The nature of the molecular lesions in the alpha-galactosidase A (alpha-Gal A) gene causing Fabry disease was determined in 50 unrelated families with the classic phenotype of this X-linked recessive lysosomal storage disease. Genomic DNA was isolated from affected males or obligate carrier females, and the entire alpha-Gal A coding region as well as the flanking and intronic sequences were analyzed by PCR amplification and automated sequencing. Forty-five new mutations were identified including 38 single base substitutions (32 missense and four nonsense) and nine gene rearrangements: MIR, M42T, G43D, G43V, H46Y, F50C, L68F, G132R, T141I, Y152X, K168R, G183S, V199M, P205R, Y207S, Q221X, C223R, C223Y, D234Y, G271C, A288P, P293A, R301G, I303N, I317T, E341D, P362L, R363C, R363H, G373D, I384N, T385P, Q396X, E398K, S401X, P409A, g7325insC, g7384del13, g8341delG, g8391del4/ins3, g10511delTAGT, g10704delACAG, g11019insG, g11021insG, and g11048delAGG. In the remaining five Fabry families, four previously reported mutations were detected (W81X, R112C, g11011delTC, and g11050delGAG) of which the R112C substitution was found in two families who were unrelated by haplotyping. These studies further define the heterogeneity of mutations in the alpha-Gal A gene causing the classical Fabry disease phenotype, and permit precise carrier detection and prenatal diagnosis in these families.     

Smith-Lemli-Opitz (RHS) syndrome: holoprosencephaly and homozygous IVS8-1G-->C genotype

Smith-Lemli-Opitz syndrome (RHS) (SLOS, OMIM 270400) is an autosomal recessive disorder of cholesterol biosynthesis caused by mutations of the 3beta-hydroxysterol Delta(7)-Delta(8)-reductase gene, DHCR7. We report a fetus with holoprosencephaly and multiple congenital anomalies who was homozygous for the IVS8-1G-->C mutation. Following termination of pregnancy, both the elevated amniotic fluid 7-dehydrocholesterol level and the DHCR7 mutations were demonstrated. Two other newborn infants with IVS8-1G-->C/IVS8-1G-->C genotype are described. This report illustrates a severe phenotypic extreme of SLOS associated with a null genotype, underscores the complex relationship between SLOS and holoprosencephaly, and discusses the possible pathogenetic mechanisms of the development of holoprosencephaly in SLOS.     

Detection of a common mutation in the RSH or Smith-Lemli-Opitz syndrome by a PCR-RFLP assay: IVS8-G-->C is found in over sixty percent of US propositi

The RSH or Smith-Lemli-Opitz syndrome (SLOS) is a relatively common autosomal recessive disorder of cholesterol biosynthesis resulting from a deficiency of the enzyme 7-dehydrocholesterol delta7-reductase (7-DHCR). Mutations in 7-DHCR gene cause SLOS. Among these, a G-->C transversion in the splice acceptor site of exon 9 (IVS8-1G-->C) was suspected to be a frequent mutation, having been detected in about 18% of SLOS patients so far. This mutation results in the elimination of a AlwN1 restriction endonuclease site. We report a simple PCR-RFLP assay to detect the IVS8-1G-->C mutation. Using this method, we identified the IVS8-1G-->C mutation in 21 of 33 SLOS propositi. This mutation was detected in one of 90 normal adult Caucasian Americans; but not among 121 Africans from Sierra Leone, 120 Caucasians from Finland, 95 Chinese or 103 Japanese adults. The results of this study provide further evidence that IVS8-1G-->C transversion is a very common mutation in SLOS patients from the US and that the carrier rate in US caucasians may be high. The simple PCR-RFLP assay developed makes identification of this mutation convenient for diagnosis and for carrier detection.     

Pharmacological rescue of carnitine transport in primary carnitine deficiency

Primary carnitine deficiency is a recessive disorder caused by heterogeneous mutations in the SLC22A5 gene encoding the OCTN2 carnitine transporter. Here we extend mutational analysis to eight new families with this disorder. To determine the mechanism by which missense mutations impaired carnitine transport, the OCTN2 transporter was tagged with the green fluorescent protein and expressed in CHO cells. Analysis by confocal microscopy indicated that several missense mutants (M1I, R169W, T232 M, G242 V, S280F, R282Q, W283R, A301D, W351R, R399Q, T440 M, E452 K, and T468R) matured normally to the plasma membrane. By contrast, other mutations (including R19P, DeltaF22, R83L, S280F, P398L, Y447C, and A142S/R488 H) caused significant retention of the mutant OCTN2 transporter in the cytoplasm. Failed maturation to the plasma membrane is a common mechanism in disorders affecting membrane transporters/ion channels, including cystic fibrosis. To correct this defect, we tested whether drugs reducing the efficiency of protein degradation in the endoplasmic reticulum (ER) (phenylbutyrate, curcumin) or capable of binding the OCTN2 carnitine transporter (verapamil, quinidine) could improve carnitine transport. Prolonged incubation with phenylbutyrate, quinidine, and verapamil partially stimulated carnitine transport, while curcumin was ineffective. These results indicate that OCTN2 mutations can affect carnitine transport by impairing maturation of transporters to the plasma membrane. Pharmacological therapy can be effective in partially restoring activity of mutant transporters.     

DHCR7 mutations and genotype-phenotype correlation in 37 Polish patients with Smith-Lemli-Opitz syndrome

Smith-Lemli-Opitz syndrome (SLOS) is an autosomal recessive disorder of cholesterol biosynthesis caused by mutations in the DHCR7 gene. Thirty-seven ethnic Polish patients with SLOS underwent mutation analysis. The mutation frequencies in Polish patients were significantly different from those observed in Western European populations. Two mutations, W151X (22/68 alleles, 32%) and V326L (19/68 alleles, 28%), accounted for 60% of all observed in our cohort. Two missense mutations L68P and L360P have not been reported previously. In total, we report 15 DHCR7 mutations identified in Polish patients. By comparing clinical severity scores and the biochemical and molecular data, a genotype-phenotype correlation was attempted. In compound heterozygotes with one null mutation, the phenotype severity depends on the localization and type of the second mutation: mild phenotypes are correlated with mutations affecting the putative transmembrane domains TM1-TM6 or CT regions and severe phenotypes with mutations localized in TM7 and 4L region. The phenotypic differences of patients with the same genotype suggest that severity of the disease may be affected by other factors.     

Population genetics of hyperphenylalaninaemia resulting from phenylalanine hydroxylase deficiency in Portugal.

In order to elucidate the molecular basis of phenylketonuria (PKU) in Portugal, a detailed study of the Portuguese mutant phenylalanine hydroxylase (PAH) genes was performed. A total of 222 mutant alleles from 111 PKU families were analysed for 26 mutations and restriction fragment length polymorphismlvariable number tandem repeat (RFLP/VNTR) haplotypes. It was possible to characterise 55% of the mutant alleles, in which 14 different mutations (R261Q, V388M, IVS10nt-11, I65T, P281L, R252W, R158Q, L348V, Y414C, L311P, Y198fsdel22bp, R408W, R270K, and R261X) and three polymorphisms (Q232Q, V245V, and L385L) were identified. A total of 14 different haplotypes were observed, with a high prevalence of haplotype 1 among mutant and normal alleles. The results reported in this study show considerable genetic heterogeneity in the Portuguese PKU population, as has also been described for other southern European populations.     

TBX22 mutations are a frequent cause of non-syndromic cleft palate in the Thai population

Mutations in the TBX22 gene underlie an X-linked malformation syndrome with cleft palate (CP) and ankyloglossia. Its mutations also result in non-syndromic CP in some populations. To investigate whether mutations in TBX22 play a part in the formation of non-syndromic CP in the Thai population, we performed mutation analysis covering all the coding regions of the TBX22 gene in 53 unrelated Thai patients with non-syndromic CP. We identified four potentially pathogenic mutations, 359G-->A (R120Q), 452G-->T (R151L), 1166C-->A (P389Q), and 1252delG in four different patients. All mutations were not detected in at least 112 unaffected ethnic-matched control chromosomes and had never been previously reported. R120Q and R151L, found in two sporadic cases, were located in the DNA binding T-box domain. P389Q and 1252delG, found in two familial cases, were at the carboxy-terminal region, which has never been described. Our study indicates that TBX22 mutations are responsible for a significant proportion of Thai non-syndromic CP cases confirming its importance as a frequent cause of non-syndromic CP across different populations.     

Identification of four novel mutations of the XLRS1 gene in Japanese patients with X-linked juvenile retinoschisis. Mutation in brief no. 234. Online

The XLRS1 gene (HUGO-approved symbol, RS1) has been found to cause X-linked recessive retinoschisis (RS) which is characterized by splitting of the superficial layer of the retina. Recent mutation analysis of this gene revealed 82 different mutations in 214 patients with RS. We have now identified 10 mutations of the XLRS1 gene in 11 unrelated Japanese males with RS. Mutations found in these patients were; 1) a 20-kb deletion in exon 1 region; 2) mutations in the initiation sequence (M1V); 3) mutations in the splice donor site (IVS1 + 1 g-->a); 4) two nonsense mutations (Q88X, W163X); and 5) five missense mutations (E72K, Y89C, R182C, G109E, P203L). Four (M1V, Q88X, G109E, and W163X) of the 10 mutations were novel. The R182C mutation was identified in 2 unrelated patients. The 3 mutations found between exons 1 and 3 cause premature translation termination in the XLRS1 protein. The rest of the 7 mutations were clustered between exons 4 and 6. This region of the protein is homologous to the proteins implicated in cell-cell adhesion.     

Novel mutations in the 7-dehydrocholesterol reductase gene of 13 patients with Smith–Lemli–Opitz syndrome

Smith–Lemli–Opitz syndrome (SLOS) is caused by mutations in the DHCR7 gene leading to deficient activity of 7-dehydrocholesterol reductase (DHCR7; EC 1.3.1.21), the final enzyme of the cholesterol biosynthetic pathway, resulting in low cholesterol and high concentrations of its direct precursor 7-dehydrocholesterol in plasma and tissues. We here report mutations identified in the DHCR7 gene of 13 children diagnosed with SLOS by clinical and biochemical criteria. We found a high frequency of the previously described IVS8–1 G > C splice acceptor site mutation (two homozygotes, eight compound heterozygotes). In addition, 13 missense mutations and one splice acceptor mutation were detected in eleven patients with a mild to moderate SLOS-phenotype. The mutations include three novel missense mutations (W182L, C183Y, F255L) and one novel splice acceptor site mutation (IVS8–1 G > T).
Two patients, homozygous for the IVS8–1 G > C mutation, presented with a severe clinical phenotype and died shortly after birth. Seven patients with a mild to moderate SLOS-phenotype disclosed compound heterozygosity of the IVS8–1 G > C mutation in combination with different novel and known missense mutations.     

RSH/Smith-Lemli-Opitz syndrome: a multiple congenital anomaly/mental retardation syndrome due to an inborn error of cholesterol biosynthesis

The RSH/Smith-Lemli-Opitz syndrome (RSH/SLOS) is an autosomal recessive multiple congenital anomaly/mental retardation syndrome caused by an inborn error of cholesterol biosynthesis. The RSH/SLOS phenotypic spectrum is broad; however, typical features include microcephaly, ptosis, a small upturned nose, micrognathia, postaxial polydactaly, second and third toe syndactaly, genital anomalies, growth failure, and mental retardation. RSH/SLOS is due to a deficiency of the 3beta-hydroxysterol Delta(7)-reductase, which catalyzes the reduction of 7-dehydrocholesterol (7-DHC) to cholesterol. This inborn error of cholesterol biosynthesis results in elevated serum and tissue 7-DHC levels. The 3beta-hydroxysterol Delta(7)-reductase gene (DHCR7) maps to chromosome 11q12-13, and to date 66 different mutations of this gene have been identified in RSH/SLOS patients. Identification of the biochemical basis of RSH/SLOS has led to development of therapeutic regimens based on dietary cholesterol supplementation and has increased our understanding of the role cholesterol plays during embryonic development.     

Prenatal diagnosis of the RSH/Smith-Lemli-Opitz syndrome

The RSH/Smith-Lemli-Opitz syndrome (RSH/SLOS) is a relatively common, autosomal recessive malformation syndrome comprising distinctive facial, limb and genital anomalies, and mental retardation. Most patients with a clinical diagnosis of RSH/SLOS have a defect of cholesterol biosynthesis at the level of 3beta-hydroxysteroid-delta7-reductase, resulting in a decreased level of cholesterol and an increased level of 7-dehydrocholesterol (7DHC) in body fluids and tissues. We report on our experience with the prenatal diagnosis of RSH/SLOS by quantitative sterol chromatography in amniotic fluid (AF) and chorionic villus (CV). Of 76 AF and nine CV samples analyzed for various indications, 20 were diagnostic of RSH/SLOS based on an increased level of 7DHC in the fluid or tissue. Of 39 fetuses at a 25% risk for RSH/SLOS, 10(25.6%) were affected. Twenty-nine pregnancies not known to be at risk for RSH/SLOS were studied because of either a fetal abnormality characteristic of RSH/SLOS detected by ultrasound, a low maternal serum uE3 level (MSuE3), or both. None of the pregnancies tested, because of a low MSuE3 but lacking a sonographic abnormality characteristic of RSH/SLOS, was affected. However, three of four pregnancies with a low MSuE3 and an RSH/SLOS-type fetal abnormality were positive. RSH/ SLOS was diagnosed in two additional pregnancies on which MSuE3 data were not available but in which fetal anomalies were identified. Of these five RSH/SLOS fetuses identified in pregnancies not otherwise at risk for RSH/SLOS, the presenting sonographic anomaly was either polydactyly, ambiguous genitalia, or both. Evaluation of the biochemical parameters and clinical severity of RSH/SLOS showed that there was an inverse correlation between clinical severity and both the level of AF 7DHC and the level of MSuE3. Based on these earlier and more extensive studies, we conclude that accurate prenatal diagnosis of RSH/ SLOS is possible by sterol analysis of AF and, most likely, CV specimens as well. Furthermore, our findings suggest that MSuE3 levels in combination with sonography may provide useful diagnostic and prognostic information in the absence of a family history of RSH/SLOS.     

Variant RSH/Smith-Lemli-Opitz syndrome with atypical sterol metabolism

The RSH/Smith-Lemli-Opitz syndrome (RSH/SLOS) is an autosomal recessive malformation syndrome comprising microcephaly, developmental and growth retardation, characteristic facial anomalies, midline cleft palate, and genital and limb anomalies. Recently, biochemical evidence of an inborn error of cholesterol biosynthesis at the level of 7-dehydrocholesterol (7DHC) reductase was reported in children and adults with RSH/SLOS. We report on two sibs with a variant form of RSH/SLOS whose sterol metabolism in cultured lymphoblasts is abnormal but differs from that of patients with classical RSH/SLOS. The children have relatively mild physical and developmental abnormalities, but a phenotype still consistent with the diagnosis of RSH/SLOS. Their plasma cholesterol levels are only mildly depressed, and they have less markedly increased plasma levels of 7DHC than most patients with classical RSH/SLOS. Cultured lymphoblasts from our patients accumulated 7DHC to the same degree as classical RSH/SLOS lymphoblast when grown with cholesterol-depleted fetal calf serum. However, unlike other RSH/SLOS cells, the increase in cellular 7DHC levels was not suppressed when the cells were grown in the presence of cholesterol from untreated fetal calf serum. The parents' sterol metabolism was also strikingly abnormal in that the levels of 7DHC in their lymphoblasts were markedly elevated compared with those of lymphoblasts from other RSH/SLOS parents. Our findings suggest that these mildly affected RSH/SLOS sibs may have a genetic disorder of sterol metabolism that is related to but biochemically different from classical RSH/SLOS, possibly one affecting intracellular transport of sterols. Am. J. Med. Genet. 78: 413–418, 1998. © 1998 Wiley-Liss, Inc.