Real time PCR assays to detect common mutations in the biotinidase gene and application of mutational analysis to newborn screening for biotinidase deficiency

Biotinidase deficiency is an autosomal recessive disorder of biotin metabolism caused by defects in the biotinidase gene. Symptoms of biotinidase deficiency are resolved or prevented with oral biotin supplementation and as such newborn screening is performed to prospectively identify affected individuals prior to the onset of symptoms. Biotinidase deficiency is detected by determining the activity of the biotinidase enzyme utilizing the newborn dried blood spot and colorimetric end point analysis. While newborn screening by enzyme analysis is effective, external factors may compromise results of the enzyme analysis and difficulty is encountered in distinguishing between complete and partial enzyme deficiencies. In the United States, the four mutations most commonly associated with complete biotinidase deficiency are c98:d7i3, Q456H, R538C, and the double mutation D444H:A171T. Partial biotinidase deficiency is almost universally attributed to the D444H mutation. To more effectively distinguish between profound and partial biotinidase deficiency, a panel of assays utilizing real time PCR and melting curve analysis using Light Cycler technology was developed. Employing DNA extracted from the original dried blood specimens from newborns identified through prospective newborn screening as presumptive positive for biotinidase deficiency, the specimens were analyzed for the presence of the five common mutations. Using this approach it was possible to separate newborns with partial and complete deficiency from each other as well as from many of those with false positive results. In most cases it was also possible to correlate the genotype with the degree of residual enzyme activity present. In newborn screening for biotinidase deficiency, we have shown that the analysis of common mutations is useful in distinguishing between partial and complete enzyme deficiency as well as improving specificity. Combining biotinidase enzyme analysis with genotypic data also increases the sensitivity of screening for biotinidase deficiency and provides information useful to clinicians earlier than would otherwise be possible.     

Double mutation (A171T) and (D444H) is a common cause of profound biotinidase deficiency in children ascertained by newborn screening in the United States

Biotinidase deficiency is inherited as an autosomal recessive trait that, unless treated with pharmacologic doses of biotin, can result in neurologic and cutaneous symptoms. We have identified two new mutations in exon D of the biotinidase gene of children with profound biotinidase deficiency ascertained by newborn screening. Transition 511G→A near the 5′ end of exon D results in a substitution of threonine for alanine171 (A171T) and transversion 1330G→C occurs close to the 3′ end of exon D causing a substitution of histidine for aspartic acid 444 (D444H). The D444H mutation was detected in four individuals from our normal population whose mean serum biotinidase activity is 5.25 nmol/min/ml, which is significantly lower than the mean normal activity (7.1 nmol/min/ml). We calculated that this mutation causes a 52% loss of activity in the aberrant enzyme. Twenty-three individuals with the D444H mutation were found by allele specific oligonucleotide analysis of DNA from 296 randomly-selected, anonymous dried-blood spots. We estimate the frequency of this allele in the general population to be 0.039. In contrast, no individuals in 376 have the A171T mutation. Fourteen children (eleven probands and three siblings) out of 31 enzyme-deficient children have both the A171T and D444H mutations. Both mutations are inherited from a single parent as a double mutation allele. The nine families in which this allele was identified are of mostly European ancestry, although the mutation cannot be attributed to a specific nationality or ethnic group. The serum of a child who is homozygous for the double mutation allele has very little CRM and the aberrant enzyme has very low biotinyl-hydrolase activity and no biotinyl-transferase activity. This double mutation allele (A171T and D444H) is a common cause of profound biotinidase deficiency in children ascertained by newborn screening in the United States. Hum Mutat 11:410, 1998. © 1998 Wiley-Liss, Inc.     

Double mutation (A171T and D444H) is a common cause of profound biotinidase deficiency in children ascertained by newborn screening the the United States. Mutations in brief no. 128. Online

Biotinidase deficiency is inherited as an antosomal recessive trait that, unless treated with pharmacologic doses of biotin, can result in neurologic and cutaneous symptoms. We have identified two new mutations in exon D of the biotinidase gene of children with profound biotinidase deficiency ascertained by newborn screening. Transition 511G->A near the 5' end of exon D results in a substitution of threonine for alanine 171 (A171T) and transversion 1330G->C occurs close to the 3' end of exon D causing a substitution of histidine for aspartic acid 444 (D444H). The D444H mutation was detected in four individuals from our normal population whose mean serum biotinidase activity is 5.25 nmol/min/ml, which is significantly lower than the mean normal activity (7.1 nmol/min/ml). We calculated that this mutation causes a 52% loss of activity in the aberrant enzyme. Twenty-three individuals with the D444H mutation were found by allele specific oligonucleotide analysis of DNA from 296 randomly-selected, anonymous dried-blood spots. We estimate the frequency of this allele in the general population to be 0.039. In contrast, no individuals in 376 have the A171T mutation. Fourteen children (eleven probands and three siblings) out of the 31 enzyme-deficient children have both the A171T and D444H mutations. Both mutations are inherited from a single parent as a double mutation allele. The nine families in which this allele was identified are of mostly European ancestry, although the mutation cannot be attributed to a specific nationality or ethnic group. The serum of a child who is homozygous for the double mutation allele has very little CRM and the aberrant enzyme has very low biotinylhydrolase activity and no botinyl-transferase activity. This double mutation allele (A171T and D444H) is a common cause of profound biotinidase deficience in children ascertained by newborn screening in the United States.     

The neurology of biotinidase deficiency

Biotinidase deficiency is an autosomal recessively inherited metabolic disorder in which the enzyme, biotinidase, is defective and the vitamin, biotin, is not recycled. Individuals with biotinidase deficiency, if not treated with biotin, usually exhibit neurological and cutaneous abnormalities. Biotin treatment can ameliorate or prevent symptoms. Biotinidase deficiency meets the major criteria for inclusion in newborn screening programs. With the advent of universal newborn screening for the disorder, the "window-of-opportunity" to characterize the consequences of the untreated disease is essentially gone. To understand the neurology of biotinidase deficiency, we must depend on what is already known about symptomatic individuals with the disorder. Therefore, in this review, the neurological findings of symptomatic individuals with profound biotinidase deficiency have been compiled to catalog the characteristic features of the disorder and the consequences of biotin treatment on these findings. In addition, based on the available evidence, I have speculated on the cause of neurological problems associated with the disorder. Future studies in biotinidase-deficient animals should allow us to demonstrate more definitively if these speculations are correct.     

Biotinidase deficiency: "if you have to have an inherited metabolic disease, this is the one to have"

Biotinidase recycles the vitamin biotin. Biotinidase deficiency is an autosomal recessively inherited neurocutaneous disorder. The symptoms of the disorder can be successfully treated or prevented by administering pharmacological doses of biotin. The biotinidase gene (BTD) has been cloned and sequenced; its genomic organization has been determined and more than 150 mutations have been identified. The disorder meets the major criteria for newborn screening and is being universally adopted in the United States and in many countries around the world. Newborn screening will limit our understanding about the natural history of the disorder. Regardless, the disorder is an ideal example of an inherited metabolic disorder that if untreated can result in major disabilities, but if identified early can be readily treated by the oral administration of a vitamin.     

Outcomes of individuals with profound and partial biotinidase deficiency ascertained by newborn screening in Michigan over 25 years

PurposeBiotinidase deficiency, if untreated, usually results in neurological and cutaneous symptoms. Biotin supplementation markedly improves and likely prevents symptoms in those treated early. All states in the United States and many countries perform newborn screening for biotinidase deficiency. However, there are few studies about the outcomes of the individuals identified by newborn screening.MethodsWe report the outcomes of 142 children with biotinidase deficiency identified by newborn screening in Michigan over a 25-year period and followed in our clinic; 22 had profound deficiency and 120 had partial deficiency.ResultsIndividuals with profound biotinidase and partial deficiency identified by newborn screening were started on biotin therapy soon after birth. With good compliance, these children appeared to have normal physical and cognitive development. Although some children exhibited mild clinical problems, these are unlikely attributable to the disorder. Biotin therapy appears to prevent the development of neurological and cutaneous problems in our population.ConclusionIndividuals with biotinidase deficiency ascertained by newborn screening and treated since birth appeared to exhibit normal physical and cognitive development. If an individual does develop symptoms, after compliance and dosage issues are excluded, then other causes must be considered.     

Biotinidase deficiency: novel mutations and their biochemical and clinical correlates

Biotinidase deficiency is a defect in the recycling of the vitamin biotin. Biotin supplementation can markedly improve the neurological and cutaneous symptoms of affected children and prevent symptoms in children identified by newborn screening or treated since birth. We have determined thirteen novel mutations in children with the disorder. Two nonsense mutations, eight single missense mutations, three allelic double missense mutations, and two are polymorphisms were identified in the biotinidase gene (BTD). One of the missense mutations, c.734G>A (p. C245Y), is the first to be reported that alters the cysteine in the putative location crucial for ester formation and binding of the biotinyl-moiety in the active site of the enzyme. These mutations add to the growing list of mutations that are helping to delineate structure/function relationships of the enzyme.     

Novel mutations causing biotinidase deficiency in individuals identified by the newborn screening program in Minas Gerais,Brazil

Biotinidase deficiency is an autosomal recessive inherited metabolic disorder caused by mutations in the BTD gene. Clinical manifestations can be treated and effectively prevented with pharmacological doses of biotin. Nine novel mutations in BTD are reported in 14 children diagnosed by the newborn screening program in Minas Gerais, Brazil, from June 2013 to December 2017. Serum BTD enzyme activity was determined for all cases and some parents. Two of the mutations are deletions and seven missense mutations located in the exonic region of the BTD gene, mostly in exon 4. Two newborns were profoundly biotinidase‐deficient (one homozygous p.A534V [c.1601C > T] and another, double heterozygous for a novel mutation p.R211S [c.631C > A] co‐inherited with an already described mutation p.T532 M [c.1595C > T]). Two mutations were associated with a partial deficiency of biotinidase (p.F361 V [c.1081 T > G] in two homozygous children, and p.S311 T [c.932G > C] in a compound heterozygous child who co‐inherited a known severe mutation p.Y438X [c.1314 T > A]). The remaining five mutations were found in compound heterozygous children. Hence, a definitive conclusion about the degree of biotinidase deficiency is not possible yet. These results emphasize the importance of sequencing the BTD gene as an important tool to gain a better understanding of the correlation between biochemical phenotype and genotype.     

Profound biotinidase deficiency in two asymptomatic adults

Biotinidase deficiency is an autosomal-recessive disorder of biotin recycling. Children with profound biotinidase deficiency usually have neurological and cutaneous symptoms in early childhood, but they may not develop symptoms until adolescence. We now report on a man and a woman with profound biotinidase deficiency who are asymptomatic and who were diagnosed only because their biotinidase-deficient children were identified by newborn screening. These adults have never exhibited symptoms of the disorder and are homozygous for two different mutations resulting in different aberrant enzymes. There is no evidence of an increased dietary intake of biotin to explain why they have remained asymptomatic. Although these adults may still be at risk for developing symptoms, they could represent a small group of individuals with profound biotinidase deficiency who will never develop clinical problems. Their lack of symptoms suggests that there are probably epigenetic factors that protect some enzyme-deficient individuals from developing symptoms. These individuals broaden the spectrum of expression of biotinidase deficiency. Am. J. Med. Genet. 73:5–9, 1997. © 1997 Wiley-Liss, Inc.     

Development and characterization of a mouse with profound biotinidase deficiency: a biotin-responsive neurocutaneous disorder

Biotinidase deficiency is the primary enzymatic defect in biotin-responsive, late-onset multiple carboxylase deficiency. Untreated children with profound biotinidase deficiency usually exhibit neurological symptoms including lethargy, hypotonia, seizures, developmental delay, sensorineural hearing loss and optic atrophy; and cutaneous symptoms including skin rash, conjunctivitis and alopecia. Although the clinical features of the disorder markedly improve or are prevented with biotin supplementation, some symptoms, once they occur, such as developmental delay, hearing loss and optic atrophy, are usually irreversible. To prevent development of symptoms, the disorder is screened for in the newborn period in essentially all states and in many countries. In order to better understand many aspects of the pathophysiology of the disorder, we have developed a transgenic biotinidase-deficient mouse. The mouse has a null mutation that results in no detectable serum biotinidase activity or cross-reacting material to antibody prepared against biotinidase. When fed a biotin-deficient diet these mice develop neurological and cutaneous symptoms, carboxylase deficiency, mild hyperammonemia, and exhibit increased urinary excretion of 3-hydroxyisovaleric acid and biotin and biotin metabolites. The clinical features are reversed with biotin supplementation. This biotinidase-deficient animal can be used to study systematically many aspects of the disorder and the role of biotinidase, biotin and biocytin in normal and in enzyme-deficient states.     

Mutations in BTD causing biotinidase deficiency

Biotinidase (BTD) is the only enzyme that can cleave biocytin, a product of the proteolytic digestion of holocarboxylases. Profound BTD deficiency (less than 10% mean normal activity in serum) is an autosomal recessive disorder that can result in neurological and cutaneous abnormalities. Both the cDNA and the genomic DNA of normal BTD gene have been isolated and characterized. The BTD gene is localized to chromosome 3p25. Thus far 61 mutations in three of the four exons of the BTD and one mutation in an intron gene that cause profound BTD deficiency have been reported. Mutations occur at different frequencies in symptomatic children than they do in children ascertained by newborn screening. Two mutations, 98‐104del7ins3 and R538C, were present in 52% or 31 of 60 alleles found in symptomatic patients. Three other mutations, A755G, Q456H, and 511 G>A; 1330G>C (double mutation), accounted for 52% of the alleles detected by newborn screening in the United States. Two asymptomatic adults, parents of children with profound BTD deficiency detected by newborn screening, have been described. Additional different mutations have been found in Turkish, Saudi Arabian, and Japanese children with profound BTD deficiency. Partial BTD deficiency (10–30% of mean normal serum activity) is predominantly caused by the single 1330G>C mutation that results in D444H on one allele in combination with one of the mutations causing profound deficiency on the other allele. Four intragenic polymorphisms, three neutral and one amino acid change, have also been found. Although a preponderance of mutations causing the production of truncated BTD protein occurs in symptomatic children with profound deficiency, preliminary studies fail to demonstrate clear genotype–phenotype correlations. Hum Mutat 18:375–381, 2001. © 2001 Wiley‐Liss, Inc.     

Successful outcomes of older adolescents and adults with profound biotinidase deficiency identified by newborn screening

PurposeWe began screening newborns for biotinidase deficiency disorder in 1984, and now all states in the United States and many countries perform this screening. The purpose of this study was to determine the outcomes of older adolescent and adult individuals with the disorder identified by newborn screening.Subjects and methodsWe located and surveyed, by questionnaire and telephone interviews, 44 individuals with profound biotinidase deficiency identified by newborn screening with a mean age of 23.1 years.ResultsAll individuals had successfully completed high school, and many were attending or had completed college or graduate school. Compliance in using biotin has been excellent. Several individuals developed a variety of symptoms when they discontinued biotin for days or weeks. These features readily resolved when biotin was resumed. In addition, five treated women had nine uneventful pregnancies and deliveries.ConclusionsNewborn screening for profound biotinidase deficiency and early treatment with biotin result in excellent outcomes for older adolescents and adults with the disorder. In addition, mothers with profound biotinidase deficiency who were treated with biotin had pregnancies with good outcomes. These outcome results indicate that newborn screening for biotinidase deficiency is one of the most successful newborn screening programs.Genet Med 19 4, 396–402.     

Technical standards and guidelines for the diagnosis of biotinidase deficiency

Biotinidase deficiency is an autosomal recessively inherited disorder of biotin recycling that is associated with neurologic and cutaneous consequences if untreated. Fortunately, the clinical features of the disorder can be ameliorated or prevented by administering pharmacological doses of the vitamin biotin. Newborn screening and confirmatory diagnosis of biotinidase deficiency encompasses both enzymatic and molecular testing approaches. These guidelines were developed to define and standardize laboratory procedures for enzymatic biotinidase testing, to delineate situations for which follow-up molecular testing is warranted, and to characterize variables that can influence test performance and interpretation of results.     

Deletion/insertion mutation that causes biotinidase deficiency may result from the formation of a quasipalindromic structure

Biotinidase is responsible for recycling the vitamin biotin from biocytin that is formed after the proteolytic degradation of the biotin- dependent carboxylases. We have identified a deletion/insertion mutation within exon D of the human biotinidase gene in a child with biotinidase deficiency. The mutation causes a frame shift and premature termination which are predicted to result in a truncated protein. We propose that the mutation occurred during DNA replication by either of two mechanisms. Both mechanisms involve formation of a quasipalindromic hairpin loop in the template and dissociation of DNA polymerase alpha. This mutation supports the formation of palindromic structures as a possible cause of deletions in eukaryotes, and supports the proposal, derived from in vitro studies, that polymerase alpha may preferentially arrest or dissociate at specific template sequences.      

Examination of the signal peptide region of human biotinidase using a baculovirus expression system

Biotinidase deficiency is an autosomal recessive disorder of biotin recycling. Biotinidase cleaves the biotin from biocytin or short biotinyl-peptides to replenish the free biotin pool, or it can transfer the vitamin to specific proteins. The cDNA for human serum biotinidase has two in-frame start codons, potentially allowing for the synthesis of an enzyme with a signal peptide (SP) consisting of either 21 or 41 amino acids. In order to examine the requirements of the signal peptide region for the production and secretion of biotinidase, three different forms of the normal human serum biotinidase gene were constructed that encode either the 21-amino-acid SP (SP21-NL) or the 41-amino-acid SP (SP41-NL) or without a SP (NoSP-NL). These constructs were expressed in insect cells via a baculovirus expression system. Biotinidase from cells with SP41-NL and SP21-NL had immunoreactive and biotinyl-hydrolase-active enzyme in lysates and expression media. Cells with NoSP-NL had about 3% of the immunoreactive material and no enzyme activity in lysates and no immunoreactive protein or enzymatic activity in the expression medium. Lack of biotinidase from cells with NoSP-NL may be due to translation inefficiency or increased susceptibility of this species to protease degradation than the secreted forms. We have demonstrated that the 21-amino-acid signal peptide is sufficient to result in glycosylated, secreted biotinidase, but we cannot determine if the glycosylated biotinidase in the lysates or secreted in the medium of cells with SP41-NL use the first, second, or both ATGs in the SP region. Because this particular expression system has no mechanism for timing the movement of newly translated biotinidase protein, we cannot draw conclusions about the relative efficiency of SP41-NL versus SP21-NL, but it is possible that either is used in vivo depending on particular cellular conditions.     

Evolutionary conservation of biotinidase: implications for the enzyme's structure and subcellular localization

Biotinidases from various species ranging from fungi and insects to human have specific amino acids, and regions that are evolutionarily conserved. These specific amino acids and regions are further supported by their homology to a variety of amidases and nitrilases and by the location of missense mutations that cause biotinidase deficiency in humans. Glu-Lys-Cys residues from three of these regions are considered the catalytic triad involved in the catalysis of the amide linkage. The last one-third of the biotinidase sequence is lacking in nitrilases-amidases, which do not bind biocytin or biotin, therefore, it is likely that the biocytin-biotin-binding site of biotinidase is within this portion of the molecule. Although there are many missense mutations at the far C-terminus of the enzyme, the function of this region is still unclear. Biotinidase may have different functions in different cells or in different subcellular compartments. Using computer programs that predict the subcellular localization of proteins based on their N-terminal signal peptides, microsomal localization resulting in secretion was predicted for biotinidase from all species, whereas there is little consistent support for mitochondrial or nuclear localization of the enzymes. Additional immunohistochemical studies of various human tissues at different stages of development are necessary to resolve the ambiguity of subcellular localization of biotinidase.     

Alternative DNA-based newborn screening for glucose-6-phosphate dehydrogenase deficiency

Newborn screening for G6PD deficiency has been carried out in several countries for more than 25 years. A semi-quantitative enzymatic assay has been used in most laboratories, however, heat inactivation during the summer can cause a significant increase in the false positive rate for this assay. We have developed an alternative DNA-based newborn screening assay for the detection of common mutations within the G6PD gene. The panel of mutations includes the common African A- mutation (G202A;A376G), the common Mediterranean mutation (C563T), and two common Chinese mutations (G1376T and G1388A). A parallel study was performed through screening a total of 4245 neonatal specimens using both the enzymatic and the DNA-based assays. In this population, 49 newborns were identified as hemizygous or homozygous for the A- mutation with an average enzyme activity of 59 microM, 323 were identified as a carrier or unaffected with an average enzyme activity of 208 microM, and no mutation was detected for the remaining 3873 specimens with an average enzyme activity of 234 microM. With this panel of mutations, more than 90% of all affected infants can be identified in our population.     

Identification of alternatively spliced human biotinidase mRNAs and putative localization of endogenous biotinidase

Biotinidase is essential for recycling the vitamin biotin and for transferring biotin to proteins, such as histones, suggesting that the enzyme localizes to various cellular and extracellular sites. To better understand the functions of the enzyme, we examined its gene structure and subcellular localization. Using RACE-PCR and a BLAST search, we extended the 5' sequence of the biotinidase gene. Three novel, alternatively spliced variants of biotinidase, 1a, 1b, and 1c, were identified in multiple human tissues. Exon 1c is present only in testes. The sequence of the 5' splice variants, 1a and 1b, suggest that biotinidase localizes to the mitochondria and/or ER, respectively. Using indirect immunofluorescence studies, biotinidase localizes to organelles in the cytoplasm, but not nucleus, of human fibroblasts and Hep G2 cells. Endogenous expression was examined by isopycnic gradient centrifugation of rat liver organelles, which identified an 85kDa biotinidase protein with biotinyl-hydrolase and transferase activities in microsomes and possibly lysosomes. A 48kDa protein, which also reacts with anti-biotinidase, localizes to mitochondria. The 48kDa protein is not N-glycosylated but is biotinylated, is in the inner mitochondrial matrix, but has no biotinyl-hydrolase or transferase activities. The function and validation of the mitochondrial species remains to be determined. The 5' splice variants and organelle fractionation studies indicate that biotinidase is directed to the secretory pathway and perhaps mitochondria.     

Molecular characterisation of 34 patients with biotinidase deficiency ascertained by newborn screening and family investigation

This study characterises the spectrum of biotinidase mutations in 21 patients (17 families) with profound biotinidase deficiency (BD) and 13 unrelated patients with partial BD using a denaturing gradient gel electrophoretic mutation screening and selective sequencing approach. In 29 from 30 unrelated families we found biallelic mutations including four common mutations, D444H (frequency 23.3%), G98:d7i3(20.0%), Q456H(20.0%), T532M (15.0%) and nine rare mutations (V62M, R157H, A171T+D444H, C423W, D543H, L279W, N172S, V109G, 12236G-A) with frequencies less than 5.0%. Only three profound BD patients with G98:d7i3/G98:d7i3 and Q456H/Q456H genotypes and residual biotinidase activities of 0.0%, and 0.9% of normal activity developed clinical symptoms before biotin supplementation at 8 weeks of age. All other patients remained asymptomatic within the first months of life or even longer without treatment. Two patients homozygous for the frameshift mutation G98:d7i3 had no measurable residual enzyme activity. Twelve patients with partial BD had the D444H mutation in at least one allele. We conclude that, based on mutation analysis and biochemical examinations of the enzyme, it is currently not clearly predictable whether an untreated patient will develop symptoms or not, although it seems that patients with activities lower than 1% are at a high risk for developing symptoms of the disease early in life.