Analysis and classification of 304 mutant alleles in patients with type 1 and type 3 Gaucher disease

Reciprocal and nonreciprocal recombination at the glucocerebrosidase gene region: implications for complexity in Gaucher disease

Gaucher disease results from an autosomal recessive deficiency of the lysosomal enzyme glucocerebrosidase. The glucocerebrosidase gene is located in a gene-rich region of 1q21 that contains six genes and two pseudogenes within 75 kb. The presence of contiguous, highly homologous pseudogenes for both glucocerebrosidase and metaxin at the locus increases the likelihood of DNA rearrangements in this region. These recombinations can complicate genotyping in patients with Gaucher disease and contribute to the difficulty in interpreting genotype-phenotype correlations in this disorder. In the present study, DNA samples from 240 patients with Gaucher disease were examined using several complementary approaches to identify and characterize recombinant alleles, including direct sequencing, long-template polymerase chain reaction, polymorphic microsatellite repeats, and Southern blots. Among the 480 alleles studied, 59 recombinant alleles were identified, including 34 gene conversions, 18 fusions, and 7 downstream duplications. Twenty-two percent of the patients evaluated had at least one recombinant allele. Twenty-six recombinant alleles were found among 310 alleles from patients with type 1 disease, 18 among 74 alleles from patients with type 2 disease, and 15 among 96 alleles from patients with type 3 disease. Several patients carried two recombinations or mutations on the same allele. Generally, alleles resulting from nonreciprocal recombination (gene conversion) could be distinguished from those arising by reciprocal recombination (crossover and exchange), and the length of the converted sequence was determined. Homozygosity for a recombinant allele was associated with early lethality. Ten different sites of crossover and a shared pentamer motif sequence (CACCA) that could be a hotspot for recombination were identified. These findings contribute to a better understanding of genotype-phenotype relationships in Gaucher disease and may provide insights into the mechanisms of DNA rearrangement in other disorders.

Gaucher disease associated with parkinsonism: four further case reports

Type 1 Gaucher disease is considered the non-neuronopathic form of this autosomal recessively inherited lysosomal storage disease. We report the simultaneous occurrence of Gaucher disease with parkinsonian in four adult patients. The patients had a relatively early onset of parkinsonian manifestations, and their disease was rapidly progressive and refractory to therapy. Each had a different Gaucher genotype, although four alleles carried the common N370S mutation. No mutations were identified in the genes for parkin or alpha-synuclein. The concurrence of these two phenotypes, both in this series of patients and in others in the literature, suggests a shared pathway, modifier, or other genetic etiology.

Enzyme therapy of gaucher disease: clinical and biochemical changes during production of and tolerization for neutralizing antibodies

The clinical impact of neutralizing antibodies directed against the therapeutic enzyme was investigated in patients with Gaucher disease. Two patients with Gaucher disease type 1 were followed for their clinical progression during antibody development and clinical changes during tolerization. Patient 1 developed neutralizing antibodies to imiglucerase (GCase) at the 10th month of enzyme therapy. Tolerization was achieved within a 42-month period with a short course of cyclophosphamide and then higher dose enzyme (60 IU/kg/week) alone. Patient 1 continues to improve up to 100 months of enzyme therapy despite the presence of low level in vitro neutralizing antibodies. Patient 2 developed neutralizing antibodies to GCase at the 29th month of enzyme therapy that correlated with clinical deterioration. Clinical stabilization has been observed with increased enzyme therapy (60 IU/kg/week) even in the presence of the neutralizing antibodies. Patient 2 is the first to develop neutralizing antibodies after 12 months of enzyme therapy. Plasma chitotriosidase activities were not well correlated with the clinical course in either patient. The presence of neutralizing antibodies should be suspected in Gaucher disease patients on enzyme therapy who experience diminished response or deterioration. The persistence of minimal amounts of in vitro neutralizing antibodies does not interfere with the therapeutic effectiveness. Chitotriosidase is not a sensitive marker for the severity of disease or disease progression.

Gaucher disease: in vivo evidence for allele dose leading to neuronopathic and nonneuronopathic phenotypes

Gaucher disease, a common lysosomal storage disorder, is associated with mutations at the acid beta-glucosidase (GCase) locus. Two affected individuals are described to share a common mutant allele, but manifest different clinical categorical phenotypes. A 57-year-old female, with Gaucher disease type 1 and Cherokee ancestry, was homozygous for a rare mutant allele encoding Lys79Asn (K79N). A 2-year-old Caucasian male, with Gaucher disease type 3 and Cherokee ancestry, was a heteroallelic homozygote for this same allele (K79N) and a novel complex mutation (null allele). The shared alleles were identical as determined by complete gene sequencing, suggesting a founder effect. The discrepant phenotypes (types 1 and 3) in these two patients provide support for a threshold of residual activity necessary to "protect" the central nervous system (CNS) from the pathogenic effects of Gaucher disease, indicating an allele dose-effect. Designation of genotype associations with specific phenotypes must be assessed with this perspective.

Molecular mechanisms for genomic disorders

Genomic rearrangements play a major role in the pathogenesis of human genetic diseases. Nonallelic homologous recombination (NAHR) between low-copy repeats (LCRs) that flank unique genomic segments results in changes of genome organization and can cause a loss or gain of genomic segments. These LCRs appear to have arisen recently during primate speciation via paralogous segmental duplication, thus making the human species particularly susceptible to genomic rearrangements. Genomic disorders are defined as a group of diseases that result from genomic rearrangements, mostly mediated by NAHR. Molecular investigations of genomic disorders have revealed genome architectural features associated with susceptibility to rearrangements and the recombination mechanisms responsible for such rearrangements. The human genome sequence project reveals that LCRs may account for 5% of the genome, suggesting that many novel genomic disorders might still remain to be recognized.

Skeletal aspects of Gaucher disease: a review

In Gaucher disease, a genetic deficiency in the activity of the lysosomal enzyme beta-glucocerebrosidase (acid beta-glucosidase) causes monocytes and macrophages to store excessive amounts of glucocerebroside in lysosomes. The resulting distended cells are called Gaucher cells, and the pathology associated with this condition stems from the accumulation of Gaucher cells in organ systems. The skeletal manifestations are probably the most disabling aspect of the disease. Patients commonly experience bone pain, some suffer bone crises, and up to 20% have impaired mobility. Radiological findings include Erlenmeyer flask deformity, osteopenia, osteosclerosis, osteonecrosis, fractures and bone marrow infiltration. Findings from the Gaucher Registry show that nearly all patients with Gaucher disease have radiological evidence of skeletal involvement, and the majority have a history of serious skeletal complications. Skeletal involvement follows three basic processes: focal disease (irreversible lesions such as osteonecrosis and osteosclerosis), local disease (reversible abnormalities adjacent to heavily involved marrow such as cortical thinning and long bone deformity) and generalized osteopenia. Infarctions are involved in some of the skeletal manifestations, but the mechanisms causing high rates of bone turnover and failure of remodelling are not known. The availability of a beta-glucocerebrosidase-deficient mouse model of Gaucher disease with long-term survival should help elucidate the skeletal pathology in Gaucher disease and may ultimately lead to improved management of skeletal complications.

Gaucher disease in Romanian patients: incidence of the most common mutations and phenotypic manifestations

Gaucher disease (GD) is an inherited glycolipid storage disorder resulting from the deficiency of glucocerebrosidase. It is the most frequent lysosomal storage disease in Romania, accounting for 70% of all lysosomal disorders diagnosed since 1997 in this country. The prevalence of six common mutations (N370S, L444P, R463C, 84GG, recNciI and recTL) and their phenotypic impact were studied in 20 type 1 GD patients of non-Jewish origin. Mutation analysis identified 77.8% of the GD alleles. The N370S mutation had the highest prevalence (50%), followed by the L444P (22.2%) and the recNciI (5.6%) alleles. Mutations R463C, 84GG and recTL have not been found in our patients. Rare or novel mutations likely accounted for 22.2% of the disease-producing uncharacterised alleles. Our study indicates a high prevalence of type 1 among Romanian GD patients. Clinical phenotype and disease severity were evaluated according to the standardised severity score index. Genotype-phenotype correlations were similar to those reported for other Caucasian non-Jewish populations. The absence of neuronopathic disease in patients presenting at least one copy of the N370S allele was confirmed, but the relative mildness of N370S homozygotes was not a constant feature among our patients. The presence of the L444P or of uncharacterised sporadic mutations was always associated with severe clinical manifestations, even in compound heterozygotes with the N370S allele. A large degree of phenotypic variability was observed in patients displaying the same genotype. The particularities of genotype-phenotype correlations may suggest the impact of other genetic or non-genetic factors on the clinical picture.

Genetics of epilepsy: current status and perspectives

Epilepsy affects more than 0.5% of the world's population and has a large genetic component. The most common human genetic epilepsies display a complex pattern of inheritance and the susceptibility genes are largely unknown. However, major advances have recently been made in our understanding of the genetic basis of monogenic inherited epilepsies. Progress has been particularly evident in familial idiopathic epilepsies and in many inherited symptomatic epilepsies, with the discovery that mutations in ion channel subunits are implicated, and direct molecular diagnosis of some phenotypes of epilepsy is now possible. This article reviews recent progress made in molecular genetics of epilepsy, focusing mostly on idiopathic epilepsy, and some types of myoclonus epilepsies. Mutations in the neuronal nicotinic acetylcholine receptor alpha4 and beta2 subunit genes have been detected in families with autosomal dominant nocturnal frontal lobe epilepsy, and those of two K(+) channel genes were identified to be responsible for underlying genetic abnormalities of benign familial neonatal convulsions. The voltage-gated Na(+) -channel (alpha1,2 and beta1 subunit), and GABA receptor (gamma2 subunit) may be involved in the pathogenesis of generalized epilepsy with febrile seizure plus and severe myoclonic epilepsy in infancy. Mutations of Ca(2+)-channel can cause some forms of juvenile myoclonic epilepsy and idiopathic generalized epilepsy. Based upon these findings, pathogenesis of epilepsy as a channelopathy and perspectives of molecular study of epilepsy are discussed.

Variant Gaucher disease characterized by dysmorphic features, absence of cardiovascular involvement, laryngospasm, and compound heterozygosity for a novel mutation (D409H/C16S)

A 20-month-old girl with developmental delay, dysmorphic features, horizontal supranuclear gaze palsy, retrocollis, and episodes of laryngospasm was diagnosed with variant neuronopathic Gaucher disease. The diagnosis was made enzymatically. Mutation analysis showed compound heterozygosity for D409H and a previously unreported mutation C16S. The presence of dysmorphic features, laryngospasm, absent cardiac findings, and the severe clinical phenotype distinguishes our case from other cases of variant neuronopathic Gaucher disease. We therefore propose to extend the spectrum of variant Gaucher disease.

Biochemical markers of bone turnover as tools in the evaluation of skeletal involvement in patients with type 1 Gaucher disease

Gaucher disease is caused by the inherited deficiency of glucocerebrosidase, a lysosomal enzyme responsible for the cleavage of glucosylceramide. In addition to organomegaly and hematological abnormalities, type 1 (nonneuronopathic) disease is characterized by insidiously progressive and often severe skeletal involvement. We investigated the applications of biochemical markers of bone turnover in the evaluation of skeletal lesions in type 1 Gaucher disease patients. Serum osteocalcin, a marker of osteoblastic bone formation, and type I collagen C-terminal telopeptide, a marker of osteoclastic bone resorption, were measured in 16 type 1 Gaucher disease patients and in 29 age-matched controls. Our results indicate a significant decrease of both osteocalcin (11.13 +/- 2.27 ng/ml) and type I collagen C-terminal telopeptide (3617.62 +/- 536.69 ng/ml) values in patients with Gaucher disease, compared to the unaffected controls (38.67+/-6.24 ng/ml and 6808.57 ng/ml +/- 865.66, respectively). These low values were observed in all patients, irrespective of their age, indicating a marked failure of both osteoblastic and osteoclastic functions in Gaucher disease. Significant differences in the mean serum values of biochemical bone turnover markers were found in different evolutional stages of bone involvement. We conclude that measurement of serum biochemical markers of bone turnover can be used as an auxiliary tool in the diagnosis, staging, and monitoring the skeletal lesions in Gaucher disease, in conjunction with imaging methods and bone densitometry measurements.

The E326K mutation and Gaucher disease: mutation or polymorphism?

Gaucher disease is caused by mutations in the gene for human glucocerebrosidase, a lysosomal enzyme involved in the intracellular hydrolysis of glucosylceramide. While over 150 different glucocerebrosidase mutations have been identified in patients with Gaucher disease, not all reported mutations have been fully characterized as being causative. One such mutation is the E326K mutation, which results from a G to A nucleotide substitution at genomic position 6195 and has been identified in patients with type 1, type 2 and type 3 Gaucher disease. However, in each instance, the E326K mutation was found on the same allele with another glucocerebrosidase mutation. Utilizing polymerase chain reaction (PCR) screening and restriction digestions of both patients with Gaucher disease and normal controls, we identified the E326K allele in both groups. Of the 310 alleles screened from patients with Gaucher disease, the E326K mutation was detected in four alleles (1.3%). In addition, screening for the E326K mutation among normal controls from a random population revealed that three alleles among 316 screened (0.9%) also carried the E326K mutation. In the normal controls with the E326K allele, the glucocerebrosidase gene was completely sequenced, but no additional mutations were found. Because the E326K mutation may be a polymorphism, we caution that a careful examination of any allele with this mutation should be performed to check for the presence of other glucocerebrosidase mutations.

Correlation among genotype, phenotype, and biochemical markers in Gaucher disease: implications for the prediction of disease severity

Gaucher disease is a lysosomal storage disorder characterized by a deficiency of the enzyme acid beta-glucosidase. The clinical manifestations of Gaucher disease are highly variable, and although certain genotypes are often associated with mild or severe symptoms, a defined correlation between genotype and phenotype does not exist. Identification of biochemical markers characteristic of pathology may be of use in predicting the progression of the disease state. In this study the relationship among genotype, glycolipid substrates, lysosomal proteins, and the clinical manifestations of Gaucher disease has been evaluated. Plasma glycolipids were analyzed using electrospray ionization-tandem mass spectrometry. Lysosomal-associated membrane protein-1 (LAMP-1) and saposin C were determined by immunoquantification. Patients with Gaucher disease were shown to have an increased 16:0-glucosylceramide/16:0-lactosylceramide ratio and elevated concentrations of LAMP-1 and saposin C in plasma. A general relationship was found to exist among the 16:0-glucosylceramide/16:0-lactosylceramide ratio, LAMP-1 and saposin C levels, and patient phenotype, providing a refinement of the genotype-phenotype correlation. These findings have major implications for the diagnosis, prediction of disease severity, and monitoring of therapy in patients with Gaucher disease.

Cholelithiasis in patients with Gaucher disease

Gaucher disease, the inherited deficiency of the lysosomal enzyme glucocerebrosidase, manifests with a continually expanding range of clinical features. Noting that a number of adult patients with type 1 Gaucher disease also had gallstones, we reviewed the clinical records of 66 adult patients evaluated at the National Institutes of Health with type 1 Gaucher disease. Twenty-one patients were identified who had either gallstones or a history of cholecystectomy. Of the 21 patients, 6 were male. The age at which stones were noted ranged from 19 to 70 years (mean 39 years). Thirteen of the patients had a cholecystectomy performed. Several different factors may contribute to the development of gallstones in these patients, including anemia, prior splenectomy, and hepatic involvement. Eleven of the patients were found to have chronic anemia. Fifteen of the patients underwent splenectomy. An increased biliary excretion of glucosylceramide could also contribute to cholelithiasis. To determine whether our findings were specific to our referral population, the medical records of a second series of 80 adult patients of Ashkenazi Jewish ancestry with type 1 Gaucher disease followed in Northern Israel were reviewed. Sixteen of these patients (5 male, 11 female) were also noted to have gallstones. Thus, the frequency of gallbladder involvement in patients with Gaucher disease appears to be greater than previously appreciated.

Heterologous expression and characterization of a rare Gaucher disease mutation (c.481C > T) from a Canadian aboriginal population using archival tissue samples

Gaucher disease is an inherited sphingolipidosis resulting from deleterious mutations in the glucocerebrosidase gene. Through direct sequence analysis of genomic DNA from whole blood, fibroblast cultures, and formalin-fixed archival tissue samples, we have identified a rare homozygous C > T transition at cDNA nucleotide 481 of the glucocerebrosidase gene that results in a proline to serine amino acid substitution (p.P122S) in an aboriginal family of Cree descent in northern Alberta, Canada. A 13-month-old boy (JB) presented with severe visceral Gaucher disease and was treated with enzyme replacement. Currently, at 11 years he is developmentally delayed, with oculomotor apraxia. A cousin (MS) had previously died at age 7 from complications of severe Gaucher disease, before enzyme replacement therapy was available. She was also developmentally delayed. Heterologous expression of this allele using a baculovirus expression system revealed 19.2% of normal enzyme activity on the artificial substrate 4-methylumbelliferyl beta-d-glucopyranoside (4MUGP). Genotype/phenotype correlation is complicated by incomplete clinical details, enzyme replacement therapy, and the difficulty in excluding other genetic and environmental causes of developmental delay. However the development of oculomotor apraxia in JB suggests a Type 3 Gaucher phenotype. The only previous report of this mutation was also from a member of the Cree Nation, who has had a rather similar clinical course. A protocol is described for the isolation of genomic DNA from formalin-fixed bone marrow aspirate archival specimens obtained from the deceased for subsequent PCR-based sequence analysis and mutation detection. This technique will be applicable to the screening of this and other populations for the frequency of known Gaucher mutations where traditional DNA sources are unavailable.

Gaucher disease and parkinsonism: a phenotypic and genotypic characterization

Among the many phenotypes associated with Gaucher disease, the inherited deficiency of glucocerebrosidase, are reports of patients with parkinsonian symptoms. The basis for this association is unknown, but could be due to alterations in the gene or gene region. The human glucocerebrosidase gene, located on chromosome 1q21, has a nearby pseudogene that shares 96% identity. Immediately adjacent to the glucocerebrosidase pseudogene is a convergently transcribed gene, metaxin, which has a pseudogene that is located just downstream to the glucocerebrosidase gene. We describe a patient with mild Gaucher disease but impaired horizontal saccadic eye movements who developed a tremor at age 42, followed by rapid deterioration of her gait. A pallidotomy at age 47 was unsuccessful. Her motor and cognitive deterioration progressed despite enzyme replacement therapy. Sequencing of the glucocerebrosidase gene identified mutations L444P and D409H. Southern blot analysis using the enzyme SspI showed that the maternal allele had an additional 17-kb band. PCR amplifications and sequencing of this fragment demonstrated a duplication which included the glucocerebrosidase pseudogene, metaxin gene, and a pseudometaxin/metaxin fusion. Gene alterations associated with this novel rearrangement, resulting from a crossover between the gene for metaxin and its pseudogene, could contribute to the atypical phenotype encountered in this patient.

Sequence variability of a human pseudogene

We have obtained haplotypes from the autosomal glucocerebrosidase pseudogene (psGBA) for 100 human chromosomes from worldwide populations, as well as for four chimpanzee and four gorilla chromosomes. In humans, in a 5420-nucleotide stretch analyzed, variation comprises 17 substitutions, a 3-bp deletion, and a length polymorphism at a polyadenine tract. The substitution rate on the pseudogene (1.23 +/- 0.22 x 10(-9) per nucleotide and year) is within the range of previous estimates considering phylogenetic estimations. Recombination within the pseudogene was recognized, although the low variability of this locus prevented an accurate measure of recombination rates. At least 13% of the psGBA sequence could be attributed to gene conversion from the contiguous GBA gene, whereas the reciprocal event has been shown to lead to Gaucher disease. Human psGBA sequences showed a recent coalescence time (approximately 200,000 yr ago), and the most ancestral haplotype was found only in Africans; both observations are compatible with the replacement hypothesis of human origins. In a deeper timeframe, phylogenetic analysis showed that the duplication event that created psGBA could be dated at approximately 27 million years ago, in agreement with previous estimates.

Metabolic liver disease

The discovery of novel metabolic pathways and the genetic basis for diseases of the liver continues to yield new insights into the pathogenesis of inherited metabolic diseases of the liver, whereas the application of new technologies to their treatment continues to advance therapeutic options. This review of selected articles covers a wide range of subjects, from the identification of novel proteins and transport pathways to disease diagnosis and treatment of acute liver failure. Four selected topics, Wilson disease, hemochromatosis and iron overload disorders, alpha-1 antitrypsin disease, and exciting new therapeutic options for lysosomal storage diseases are the focus of this review.

Glucocerebrosidase pseudogene variation and Gaucher disease: Recognizing pseudogene tracts in GBA alleles

We surveyed the genetic variability of the glucocerebrosidase pseudogene (psGBA) in a worldwide sample of 100 human chromosomes. psGBA is the non-functional duplicate of the gene responsible for Gaucher disease (GBA), the most common lipid storage disorder. The existence of only one psGBA allele described until now, together with the high homology between GBA and psGBA, often prevented recognition of the complex alleles formed by the combination of GBA and psGBA, because psGBA variants could be confused with GBA mutations. In order to determine the variability existent in psGBA, the whole psGBA DNA segment was PCR-amplified and sequenced, and the genotype for all samples was obtained. The ascertainment of the phase among the heterozygous sites was possible through cloning and sequencing a single allele. Eighteen variable sites were detected along psGBA. Two of the variants already have been reported as Gaucher-causing mutations when present in GBA alleles. The other variants were unknown. The knowledge of the psGBA variants described in this report will allow identification of psGBA-GBA complex alleles that may aid in understanding the intricate phenotype-genotype relationship in Gaucher disease.

Identification of a 55-bp deletion in the glucocerebrosidase gene in Gaucher disease: phenotypic presentation and implications for mutation detection assays

A 55-bp deletion in exon 9 of the glucocerebrosidase gene was identified in a 28-year-old male affected with Gaucher disease. The diagnosis was established during an evaluation for mild pancytopenia and was confirmed by bone marrow histology and biochemical studies. The patient is of German ancestry. Initial DNA testing indicated homozygosity for the N370S mutation. However, subsequent testing of the patient's parents suggested that the patient and his mother carried a null allele by our assay for N370S. Further molecular studies identified a 55-bp deletion in exon 9 of the glucocerebrosidase gene (g.6767_6822del55). This deletion has been previously reported in a patient with severe Gaucher disease (1), and is present in the glucocerebrosidase pseudogene. In the previously reported case, initial DNA testing also suggested the genotype N370S/N370S, but further mutation studies were undertaken because clinical severity was greater than expected for that genotype. In contrast, our patient has an unusually mild clinical course. Thus, clinical severity cannot be reliably used to determine when to test for the presence of the 55-bp deletion. While the 55-bp deletion is not reported to be common, its actual frequency may be underestimated since it eludes detection by many standard clinical assays for Gaucher disease. This report points out the need to consider this deletion mutation which may cause erroneous interpretation of results in existing assays for the common mutations N370S and L444P. Furthermore, the importance of recommending parental analysis for individuals who test homozygous for autosomal mutations is highlighted.

Glucocerebrosidase mutations among African-American patients with type 1 Gaucher disease

While the inherited deficiency of the enzyme glucocerebrosidase (Gaucher disease) is panethnic in its distribution, there have not been studies of the mutations encountered in specific ethnic groups in the United States, other than those on Ashkenazi Jews. We present the clinical descriptions and genotypes of seven patients of African-American ancestry with type 1 Gaucher disease, and summarize the published literature regarding the genotypes encountered in this population. All seven of the patients had moderate-to-severe manifestations of the disease, and all developed symptoms by adolescence. Genotypic analyses revealed that no two probands shared the same genotype. The common mutations N370S, c.84-85insG, IVS2+1 G-->A, and R463C were not seen. Mutation L444P was present on one allele in each of the patients; but the same mutation was encountered as a single point mutation in three of the patients, and as part of a recombinant allele in four of the patients. Southern blot analyses revealed a glucocerebrosidase fusion allele in one patient, and a duplication resulting from recombination in the region downstream from the glucocerebrosidase gene in three of the patients. Five different point mutations (A90T, R48W, N117D, R170C, and V352L), one deletion mutation (c.222-224 delTAC), and one insertion mutation (c.153-154 insTACAGC) were encountered. Our results demonstrate that there is significant genotypic heterogeneity among African-American patients with type 1 Gaucher disease, and that recombinations in the glucocerebrosidase gene locus are particularly common in this patient group. Published 2001 Wiley-Liss, Inc.

A new gene-pseudogene fusion allele due to a recombination in intron 2 of the glucocerebrosidase gene causes Gaucher disease

Gaucher disease is the most prevalent sphingolipid storage disorder in humans caused by a recessively inherited deficiency of the enzyme glucocerebrosidase. More than 100 mutations have been described in the glucocerebrosidase gene causing Gaucher disease. Some of them are complex alleles with several mutations due to recombination events between the gene and its highly homologous pseudogene. The generation of these recombinant alleles involves, in most cases, a crossover in the 3' end of the gene, beyond exon 8. However, in a few cases recombination took place in a more upstream location. Here we describe the analysis of a patient with type I Gaucher disease who bears a new complex allele. This allele was originated by a crossover between the gene and the pseudogene at intron 2, the most upstream recombination site described so far, which gave rise to a fusion gene. The patient was first diagnosed as homozygous for the c.1226 A --> G (N370S) mutation but the early onset of the disease prompted us to perform parental DNA analysis which showed that the mother was not a N370S carrier, suggesting deletion of at least part of the gene. Molecular analysis of the complex allele was carried out by Southern blot, PCR, and sequencing. We were able to close down the region of the recombination event to an interval of 18 nucleotides, corresponding to the last 15 nucleotides of intron 2 and the first 3 nucleotides of exon 3 of the gene. These 18 nucleotides are identical between the gene and pseudogene making any further refinement impossible. An exhaustive list of published glucocerebrosidase complex alleles, describing their recombination points, is included for comparison.