An inactive cytochrome P450 CYP2D6 allele containing a deletion and a base substitution

The cytochrome P450 CYP2D6 is a polymorphic enzyme, for which 5%–10% of Caucasians (poor metabolizers) lack activity. The majority of mutations giving rise to the deficiency have now been identified but some individuals show anomalous phenotype-genotype relationships when screened for the common mutant alleles. We have sequenced all nine exons and intron-exon boundaries in a subject who was phenotypically a poor metabolizer but genotypically heterozygous when screened for the common alleles. A single base-pair deletion (T₁₇₉₅) was detected in exon 3 and a base substitution (G₂₀₆₄A) resulting in an amino acid substitution (G₂₁₂E) in exon 4. The deletion results in premature termination of translation and a truncated protein. In a group of 50 white Americans, the allele frequency for the new mutant allele was 0.01. The new allele explains some cases of anomalous genotype/phenotype relationships for CYP2D6.     

Spontaneous splicing mutations at the dihydrofolate reductase locus in Chinese hamster ovary cells.

We isolated and characterized three spontaneous mutants of Chinese hamster ovary cells that were deficient in dihydrofolate reductase activity. All three mutants contained no detectable enzyme activity and produced dihydrofolate reductase mRNA species that were shorter than those of the wild type by about 120 bases. Six exons are normally represented in this mRNA; exon 5 was missing in all three mutant mRNAs. Nuclease S1 analysis of the three mutants indicated that during the processing of the mutant RNA, exon 4 was spliced to exon 6. The three mutant genes were cloned, and the regions around exons 4 and 5 were sequenced. In one mutant, the GT dinucleotide at the 5' end of intron 5 had changed to CT. In a second mutant, the first base in exon 5 had changed from G to T. In a revertant of this mutant, this base was further mutated to A, a return to a purine. Approximately 25% of the mRNA molecules in the revertant were spliced correctly to produce an enzyme with one presumed amino acid change. In the third mutant, the AG at the 3' end of intron 4 had changed to AA. A mutation that partially reversed the mutant phenotype had changed the dinucleotide at the 5' end of intron 4 from GT to AT. The splicing pattern in this revertant was consistent with the use of cryptic donor and acceptor splice sites close to the original sites to produce an mRNA with three base changes and a protein with two amino acid changes. These mutations argue against a scanning model for the selection of splice site pairs and suggest that only a single splice site need be inactivated to bring about efficient exon skipping (a regulatory mechanism for some genes). The fact that all three mutants analyzed exhibited exon 5 splicing mutations indicates that these splice sites are hot spots for spontaneous mutation.     

Functional Differences between Ultrabithorax Protein Isoforms in Drosophila Melanogaster: Evidence from Elimination, Substitution and Ectopic Expression of Specific Isoforms

The homeotic selector gene Ultrabithorax (Ubx) specifies regional identities in multiple tissues within the thorax and abdomen of Drosophila melanogaster. Ubx encodes a family of six developmentally specific homeodomain protein isoforms translated from alternatively spliced mRNAs. The mutant allele Ubx(195) contains a stop codon in exon mII, one of three differential elements, and consequently produces functional UBX protein only from mRNAs of type IVa and IVb, which are expressed mainly in the central nervous system. Although it retains activity for other processes, Ubx(195) behaves like a null allele with respect to development of the peripheral nervous system, indicating that UBX-IVa and IVb alone do not contribute detectable Ubx function for this tissue. The mutant allele Ubx(MX17) contains an inversion of exon mII. We find that this allele only produces mRNAs of type IVa, but the expression pattern of the resulting UBX-IVa protein is indistinguishable from that of total UBX protein expression in wild-type embryos. The phenotype of homozygous Ubx(MX17) embryos indicates that UBX-IVa cannot substitute functionally for other isoforms to promote normal development of the peripheral nervous system. This functional limitation is confirmed by a detailed analysis of the peripheral nervous system in embryos that express specific UBX isoforms ectopically under control of a heat shock promoter. Additional observations suggest that UBX isoforms also differ in their ability to function in other tissues.     

Deletion of RB exons 24 and 25 causes low-penetrance retinoblastoma.

A deletion in the tumor-suppressor gene, RB, discovered by quantitative multiplex PCR, shows low penetrance (LP), since only 39% of eyes at risk in this family develop retinoblastoma. The 4-kb deletion spanning exons 24 and 25 (delta24-25) is the largest ever observed in an LP retinoblastoma family. Unlike the usual RB mutations, which cause retinoblastoma in 95% of at-risk eyes and yield no detectable protein, the delta24-25 allele transcribed a message splicing exon 23 to exon 26, resulting in a detectable protein (pRBdelta24-25) that lacks 58 amino acids from the C-terminal domain, proving that this domain is essential for suppression of retinoblastoma. Two functions were partially impaired by delta24-25-nuclear localization and repression of E2F-consistent with the idea that LP mutations generate "weak alleles" by reducing but not eliminating essential activities. However, delta24-25 ablated interaction of pRB with MDM2. Since a homozygous LP allele is considered nontumorigenic, the pRB/MDM2 interaction may be semi- or nonessential for suppressing retinoblastoma. Alternatively, some homozygous LP alleles may not cause tumorigenesis because an additional event is required (the "three-hit hypothesis"), or the resulting imbalance in pRB function may cause apoptosis (the "death allele hypothesis"). pRBdelta24-25 was also completely defective in suppressing growth of Saos-2 osteosarcoma cells. Targeting pRBdelta24-25 to the nucleus did not improve Saos-2 growth suppression, suggesting that C-terminal domain functions other than nuclear localization are essential for blocking proliferation in these cells. Since delta24-25 behaves like a null allele in these cells but like an LP allele in the retina, pRB may use different mechanisms to control growth in different cell types.     

A single nucleotide polymorphism in an exon dictates allele dependent differential splicing of episialin mRNA

The episialin gene (MUC1) encodes an epithelial mucin containing a variable number of repeats with a length of twenty amino acids, resulting in many different alleles that can be subdivided into two size classes. The episialin pre-mRNA uses either one of two neighbouring splice acceptor sites for exon 2, which mainly encodes the repeats. Using the genetic polymorphism of the episialin gene to identify different alleles, we show here that the splice site recognition is allele dependent and is based on a single A/G nucleotide difference in exon 2 eight nucleotides downstream of the second splice acceptor site. Transfection experiments confirm that this polymorphic nucleotide regulates the splice site selection. The identity of this nucleotide is in most cases correlated with one of the size classes of the alleles, indicating that mutations altering the number of repeats seldom arise by unequal cross-over between the repeat regions.     

Grey, a novel mutation in the murine Lyst gene, causes the beige phenotype by skipping of exon 25

The murine beige mutant phenotype and the human Chediak-Higashi syndrome are caused by mutations in the murine Lyst (lysosomal trafficking regulator) gene and the human CHS gene, respectively. In this report we have analyzed a novel murine mutant Lyst allele, called Lyst(bg-grey), that had been found in an ENU mutation screen and named grey because of the grey coat color of affected mice. The phenotype caused by the Lyst(bg-grey) mutation was inherited in a recessive fashion. Melanosomes of melanocytes associated with hair follicles and the choroid layer of the eye, as well as melanosomes in the neural tube-derived pigment epithelium of the retina, were larger and irregularly shaped in homozygous mutants compared with those of wild-type controls. Secretory vesicles in dermal mast cells of the mutant skin were enlarged as well. Test crosses with beige homozygous mutant mice (Lyst(bg)) showed that double heterozygotes (Lyst(bg)/Lyst(bg-grey)) were phenotypically indistinguishable from either homozygous parent, demonstrating that the ENU mutation was an allele of the murine Lyst gene. RT-PCR analyses revealed the skipping of exon 25 in Lyst(bg-grey) mutants, which is predicted to cause a missense D2399E mutation and the loss of the following 77 amino acids encoded by exon 25 but leave the C-terminal end of the protein intact. Analysis of the genomic Lyst locus around exon 25 showed that the splice donor at the end of exon 25 showed a T-to-C transition point mutation. Western blot analysis suggests that the Lyst(bg-grey) mutation causes instability of the LYST protein. Because the phenotype of Lyst(bg) and Lyst(bg-grey) mutants is indistinguishable, at least with respect to melanosomes and secretory granules in mast cells, the Lyst(bg-grey) mutation defines a critical region for the stability of the murine LYST protein.     

Structural and biochemical basis for novel mutations in homozygous Israeli maple syrup urine disease patients: a proposed mechanism for the thiamin-responsive phenotype

Maple syrup urine disease (MSUD) results from mutations affecting different subunits of the mitochondrial branched-chain alpha-ketoacid dehydrogenase complex. In this study, we identified seven novel mutations in MSUD patients from Israel. These include C219W-alpha (TGC to TGG) in the E1alpha subunit; H156Y-beta (CAT to TAT), V69G-beta (GTT to GGT), IVS 9 del[-7:-4], and 1109 ins 8bp (exon 10) in the E1beta subunit; and H391R (CAC to CGC) and S133stop (TCA to TGA) affecting the E2 subunit of the branched-chain alpha-ketoacid dehydrogenase complex. Recombinant E1 proteins carrying the C219W-alpha or H156Y-beta mutation show no catalytic activity with defective subunit assembly and reduced binding affinity for cofactor thiamin diphosphate. The mutant E1 harboring the V69G-beta substitution cannot be expressed, suggesting aberrant folding caused by this mutation. These E1 mutations are ubiquitously associated with the classic phenotype in homozygous-affected patients. The H391R substitution in the E2 subunit abolishes the key catalytic residue that functions as a general base in the acyltransfer reaction, resulting in a completely inactive E2 component. However, wild-type E1 activity is enhanced by E1 binding to this full-length mutant E2 in vitro. We propose that the augmented E1 activity is responsible for robust thiamin responsiveness in homozygous patients carrying the H391R E2 mutation and that the presence of a full-length mutant E2 is diagnostic of this MSUD phenotype. The present results offer a structural and biochemical basis for these novel mutations and will facilitate DNA-based diagnosis for MSUD in the Israeli population.     

Alternate use of divergent forms of an ancient exon in the fructose-1,6-bisphosphate aldolase gene of Drosophila melanogaster.

The fructose-1,6-bisphosphate aldolase gene of Drosophila melanogaster contains three divergent copies of an evolutionarily conserved 3' exon. Two mRNAs encoding aldolase contain three exons and differ only in the poly(A) site. The first exon is small and noncoding. The second encodes the first 332 amino acids, which form the catalytic domain, and is homologous to exons 2 through 8 of vertebrates. The third exon encodes the last 29 amino acids, thought to control substrate specificity, and is homologous to vertebrate exon 9. A third mRNA substitutes a different 3' exon (4a) for exon 3 and encodes a protein very similar to aldolase. A fourth mRNA begins at a different promoter and shares the second exon with the aldolase messages. However, two exons, 3a and 4a, together substitute for exon 3. Like exon 4a, exon 3a is homologous to terminal aldolase exons. The exon 3a-4a junction is such that exon 4a would be translated in a frame different from that which would produce a protein with similarity to aldolase. The putative proteins encoded by the third and fourth mRNAs are likely to be aldolases with altered substrate specificities, illustrating alternate use of duplicated and diverged exons as an evolutionary mechanism for adaptation of enzymatic activities.     

Characterization of two new point mutations in the low density lipoprotein receptor genes of an English patient with homozygous familial hypercholesterolemia.

Two new point mutations have been detected in the low density lipoprotein (LDL) receptor gene of a patient with a clinical diagnosis of homozygous familial hypercholesterolemia (FH). The patient is a compound heterozygote, in whom the mutant allele inherited from his English father has a single base substitution of A for G in exon 3, changing the codon for residue 80 in the mature protein from glutamic acid to lysine. The mutant allele inherited from his mother, who is of Irish origin, has a single base pair deletion in the codon for residue 743 in exon 15 that causes a frameshift and introduces a new stop codon in the adjacent position. The glu80 to lys mutation results in a transport-defective phenotype and a mature protein that migrates abnormally slowly on nonreduced SDS-PAGE, but normally under reducing conditions; this was confirmed by site-directed mutagenesis and expression in vitro. The deletion in exon 15 results in a null phenotype in which the putative truncated receptor protein cannot be detected in cultured skin fibroblasts and the amount of mRNA derived from the allele is reduced. The glu80 to lys mutation was found in a further five unrelated individuals in a sample of 200 FH patients from the London area and in 11 from a sample of 77 FH patients from Manchester. Haplotype analysis suggested that all the patients had inherited this allele from a common ancestor. The deletion in exon 15 was not found in the London sample, nor in any unrelated individuals in the Manchester sample.     

Modulation of the phenotype in dominant erythropoietic protoporphyria by a low expression of the normal ferrochelatase allele.

Erythropoietic protoporphyria (EPP) is a monogenic inherited disorder of the heme biosynthetic pathway due to ferrochelatase (FC) deficiency. EPP is generally considered to be transmitted as an autosomal dominant disease with incomplete penetrance, although autosomal recessive inheritance has been documented at the enzymatic and molecular level in some families. In the dominant form of EPP, statistical analysis of FC activities documented a significantly lower mean value in patients than in asymptomatic carriers, suggesting a more complex mode of inheritance. To account for these findings, we tested a multiallelic inheritance model in one EPP family in which the enzymatic data were compatible with this hypothesis. In this EPP family, the specific FC gene mutation was an exon 10 skipping (delta Ex10), resulting from a G deletion within the exon 10 consensus splice donor site. The segregation of all FC alleles within the family was followed using the delta Ex10 mutation and a new intragenic dimorphism (1520 C/T). mRNAs transcribed from each FC allele were then subjected to relative quantification by a primer extension assay and to absolute quantification by a ribonuclease protection assay. The data support the hypothesis that in this family the EPP phenotype results from the coinheritance of a low output normal FC allele and a mutant delta Ex10 allele.     

A highly sensitive quantitative real-time PCR assay for determination of mutant JAK2 exon 12 allele burden

Mutations in the Janus kinase 2 (JAK2) gene have become an important identifier for the Philadelphia-chromosome negative chronic myeloproliferative neoplasms. In contrast to the JAK2V617F mutation, the large number of JAK2 exon 12 mutations has challenged the development of quantitative assays. We present a highly sensitive real-time quantitative PCR assay for determination of the mutant allele burden of JAK2 exon 12 mutations. In combination with high resolution melting analysis and sequencing the assay identified six patients carrying previously described JAK2 exon 12 mutations and one novel mutation. Two patients were homozygous with a high mutant allele burden, whereas one of the heterozygous patients had a very low mutant allele burden. The allele burden in the peripheral blood resembled that of the bone marrow, except for the patient with low allele burden. Myeloid and lymphoid cell populations were isolated by cell sorting and quantitative PCR revealed similar mutant allele burdens in CD16+ granulocytes and peripheral blood. The mutations were also detected in B-lymphocytes in half of the patients at a low allele burden. In conclusion, our highly sensitive assay provides an important tool for quantitative monitoring of the mutant allele burden and accordingly also for determining the impact of treatment with interferon-α-2, shown to induce molecular remission in JAK2V617F-positive patients, which may be a future treatment option for JAK2 exon 12-positive patients as well.     

DNA-PKcs mutations in dogs and horses: allele frequency and association with neoplasia

Previously, spontaneous genetic immunodeficiencies in mice, Arabian foals, and recently in Jack Russell terriers have been ascribed to defects in DNA-PKcs (catalytic subunit of the DNA dependent protein kinase) expression. In severe combined immunodeficiency (SCID) foals, a 5 bp deletion at codon 9480 results in a frameshift and a 967 amino acid deletion from the C terminus (including the entire PI3 kinase domain) and an unstable mutant protein. In SCID mice, a single base pair mutation results in a premature stop codon and deletion of 83 amino acids; as in SCID foals, the mutant protein is unstable. Here, we define the mutation within the canine DNA-PKcs gene that results in SCID. In this case, a point mutation results in a stop codon at nucleotide 10,828 and premature termination at a position 517 amino acids before the normal C terminus resulting in a functionally null allele. Thus, this is the third documentation of a spontaneous germline mutation in the C terminus of DNA-PKcs. Emerging data implicate DNA repair factors as potential tumor suppressors. Here, we have ascertained the carrier frequency of the defective DNA-PKcs genes in Arabian horses and in Jack Russell terriers. Our data indicate (in good agreement with a previous report) that the carrier frequency of the equine SCID allele is approximately 8%; in contrast, the carrier frequency of the canine SCID allele is less than 1.1%. We also assessed the frequency of the equine SCID allele in a series of 295 tumors from Arabian horses. We find a statistically significant correlation between the development of a virally induced tumor (sarcoid) and heterozygosity for the equine SCID allele. These data provide further support for an emerging consensus: that DNA-PK may normally act as a tumor suppressor through its caretaker role in maintaining chromosomal stability.     

Severe growth retardation and short life span of double-mutant mice lacking Xpa and exon 15 of Xpg

In addition to xeroderma pigmentosum (XP), mutations in the human XPG gene cause an early onset of Cockayne syndrome (CS) in some patients (XP-G/CS) with characteristics, such as growth retardation and a short life span. In the previous studies, we generated four Xpg mutant mice with two different C-terminal truncations, null, or a base substitution mutation to identify the protein region that causes the onset of CS, and found that the CS-causing mutations, null or a deletion of the last 360 amino acids, completely inhibited the NER activity of mouse XPG (Xpg), but the non-CS-causing mutations, XpgD811A (base substitution that eliminates the nuclease activity of Xpg) or XpgDeltaex15 (deletion of the exon 15 corresponding to the last 183 amino acids), resulted in the retention of residual NER activity. To understand why mutations that completely eliminate the NER activity of Xpg cause CS but those that abolish the nuclease activity without totally eliminating the NER activity of Xpg do not result in CS, we made a series of Xpg mutant mice with Xpa-null mutant allele and found that mice with the non-CS-causing deletion mutation (XpgDeltaex15) exhibited the CS phenotype when XPA was also absent but the base substitution mutation (XpgD811A) that eliminated the Xpg nuclease activity did not. These results indicate that Xpg has a second function, beside NER, and that the disruption of this second function (deletion of the last 183 amino acids) when combined with an NER defect causes CS. When we compared amino acid sequences corresponding to the exon 15 of Xpg, a significant homology was conserved among vertebrates, but not in Drosophila and Saccharomyces cerevisiae. These observations suggest that the second function of XPG may be conserved only in vertebrates and CS symptoms may occur in its absence.     

Altered acyltransferase activity in Escherichia coli associated with mutations in acyl coenzyme A synthetase

Growth of a temperature-sensitive general fatty acid synthesis mutant of Escherichia coli K12 at its restrictive temperature in the presence of exogenous palmitate results in lysis of the bacterium. Under these conditions, palmitate is incorporated into membrane phospholipid to a high level. Mutants of bacteria restricting this incorporation (having a palmitate-resistant phenotype) have been isolated and one such mutant, strain L8-2/3, has been further characterized. This mutant has lowered acyl-CoA synthetase (fadD) activity (25-33% of normal) and consequently is defective in fatty acid uptake. This lowered uptake could explain the palmitate-resistant phenotype of strain L8-2/3. However, both in vivo (fatty acid composition and positional distribution data) and in vitro (acyltransferase activity measurements) experiments suggest that this mutant is also altered in its acyltransferase activities. The mutation(s) of strain L8-2/3 appears to allow increased (approximately 2-fold) incorporation of myristate (and possible unsaturated fatty acids) into position 2 of 1-acyl-sn-glycerol 3-phosphate but normal palmitate incorporation into the same position. The incorporation of palmitate, myristate, and oleate into position 1 of sn-glycerol 3-phosphate by strain L8-2/3 is also higher than that observed with the parent, strain L8-2. Replacing the partially defective fadD gene of strain L8-2/3 with a wild type allele conferred on this strain the palmitate sensitivity and the acyltransferase activity of the parent strain L8-2. This finding, taken together with other data, suggests that acyl-CoA synthetase interacts with the acyltransferase(s) in some manner to influence the fatty acid specificity of the acyltransferase.     

Molecular basis of apparent isolated 17,20-lyase deficiency: compound heterozygous mutations in the C-terminal region (Arg(496)----Cys, Gln(461)----Stop) actually cause combined 17 alpha-hydroxylase/17,20-lyase deficiency.

The molecular defect in a reported case of isolated 17,20-lyase deficiency in a 46XY individual has been elucidated. The patient was found to be a compound heterozygote, carrying two different mutant alleles in the CYP17 gene. One allele contains a point mutation of arginine (CGC) to cysteine (TGC) at amino acid 496 in exon 8. The second allele contains a stop codon (TAG) in place of glutamine (CAG) at position 461 in exon 8 which is located 19 amino acids to the carboxy-terminal side of the P-450(17) alpha heme binding cysteine. COS-1 cells transfected with cDNAs containing one or the other of these mutations showed dramatically reduced 17 alpha-hydroxylase and 17,20-lyase activities relative to cells transfected with the wild type P-450(17) alpha cDNA. While the in vitro data in COS 1 cells can explain the patient's physical phenotype, with female external genitalia, it was somewhat discordant with the clinical expression of isolated 17,20-lyase deficiency with relative preservation of 17 alpha-hydroxylase activity in vivo. In addition to the expression studies of these two examples of mutants in the C-terminal region of cytochrome P-450(17) alpha, a third mutant cDNA construct containing a 4-base duplication at codon 480 previously found in patients with combined 17 alpha-hydroxylase/17,20-lyase deficiency was also expressed in COS-1 cells. This expressed protein was completely inactive with respect to both activities, supporting the biochemical findings in serum and in vitro biochemical data obtained using a testis from the patient. The results from these patients clearly indicate the importance of the C-terminal region of human P-450(17) alpha in its enzymatic activities.     

Mutations in the consensus helicase domains of the Werner syndrome gene. Werner's Syndrome Collaborative Group.

Werner syndrome (WS) is an autosomal recessive disease with a complex phenotype that is suggestive of accelerated aging. WS is caused by mutations in a gene, WRN, that encodes a predicted 1,432-amino-acid protein with homology to DNA and RNA helicases. Previous work identified four WS mutations in the 3' end of the gene, which resulted in predicted truncated protein products of 1,060-1,247 amino acids but did not disrupt the helicase domain region (amino acids 569-859). Here, additional WS subjects were screened for mutations, and the intron-exon structure of the gene was determined. A total of 35 exons were defined, with the coding sequences beginning in the second exon. Five new WS mutations were identified: two nonsense mutations at codons 369 and 889; a mutation at a splice-junction site, resulting in a predicted truncated protein of 760 amino acids; a 1-bp deletion causing a frameshift; and a predicted truncated protein of 391 amino acids. Another deletion is >15 kb of genomic DNA, including exons 19-23; the predicted protein is 1,186 amino acids long. Four of these new mutations either partially disrupt the helicase domain region or result in predicted protein products completely missing the helicase region. These results confirm that mutations in the WRN gene are responsible for WS. Also, the location of the mutations indicates that the presence or absence of the helicase domain does not influence the WS phenotype and suggests that WS is the result of complete loss of function of the WRN gene product.     

Autoregulation of yeast pyruvate decarboxylase gene expression requires the enzyme but not its catalytic activity.

In the yeast, Saccharomyces cerevisiae, pyruvate decarboxylase (Pdc) is encoded by the two isogenes PDC1 and PDC5. Deletion of the more strongly expressed PDC1 gene stimulates the promoter activity of both PDC1 and PDC5, a phenomenon called Pdc autoregulation. Hence, pdc1Delta strains have high Pdc specific activity and can grow on glucose medium. In this work we have characterized the mutant alleles pdc1-8 and pdc1-14, which cause strongly diminished Pdc activity and an inability to grow on glucose. Both mutant alleles are expressed as detectable proteins, each of which differs from the wild-type by a single amino acid. The cloned pdc1-8 and pdc1-14 alleles, as well as the in-vitro-generated pdc1-51 (Glu51Ala) allele, repressed expression of PDC5 and diminished Pdc specific activity. Thus, the repressive effect of Pdc1p on PDC5 expression seems to be independent of its catalytic activity. A pdc1-8 mutant was used to isolate spontaneous suppressor mutations, which allowed expression of PDC5. All three mutants characterized had additional mutations within the pdc1-8 allele. Two of these mutations resulted in a premature translational stop conferring phenotypes virtually indistinguishable from those of a pdc1Delta mutation. The third mutation, pdc1-803, led to a deletion of two amino acids adjacent to the pdc1-8 mutation. The alleles pdc1-8 and pdc1-803 were expressed in Escherichia coli and purified to homogeneity. In the crude extract, both proteins had 10% residual activity, which was lost during purification, probably due to dissociation of the cofactor thiamin diphosphate (ThDP). The defect in pdc1-8 (Asp291Asn) and the two amino acids deleted in pdc1-803 (Ser296 and Phe297) are located within a flexible loop in the beta domain. This domain appears to determine the relative orientation of the alpha and gamma domains, which bind ThDP. Alterations in this loop may also affect the conformational change upon substrate binding. The mutation in pdc1-14 (Ser455Phe) is located within the ThDP fold and is likely to affect binding and/or orientation of the cofactor in the protein. We suggest that autoregulation is triggered by a certain conformation of Pdc1p and that the mutations in pdc1-8 and pdc1-14 may lock Pdc1p in vivo in a conformational state which leads to repression of PDC5.