A factor IX mutation, verified by direct genomic sequencing, causes haemophilia B by a novel mechanism.

A novel factor IX gene mutation (factor IX London 2) has been characterized. This causes severe crm+ haemophilia B as the patient's plasma shows normal factor IX antigen level and less than 1% clotting activity. Sequence analysis of the entire cloned coding and promoter regions revealed a single point mutation: a G----A transition at position 31,119. This region of the patient's DNA was amplified in vitro by the polymerase chain reaction and the nucleotide change was confirmed by direct sequencing of the amplified products. The mutation results in the substitution of the arginine at position 333 by glutamine. This arginine residue is absolutely conserved in the catalytic domain of normal human and bovine factor IX, X and prothrombin. The substitution by glutamine causes the loss of a positive charge from the surface of the factor IX London 2 protein. This mutation pinpoints a previously unknown, functionally critical feature of factor IX which may be involved in substrate or co-factor binding.     

Subunit interactions and glutamine utilization by Escherichia coli imidazole glycerol phosphate synthase

A selection strategy has been developed to identify amino acid residues involved in subunit interactions that coordinate the two half-reactions catalyzed by glutamine amidotransferases. The protein structures known for this class of enzymes have revealed that ammonia is shuttled over long distances and that each amidotransferase evolved different molecular tunnels for this purpose. The heterodimeric Escherichia coli imidazole glycerol phosphate (IGP) synthase was probed to assess if residues in the substrate amination subunit (HisF) are critical for the glutaminase activity in the HisH subunit. The activity of the HisH subunit is dependent upon binding of the nucleotide substrate at the HisF active site. This regulatory function has been exploited as a biochemical selection of mutant HisF subunits that retain full activity with ammonia as a substrate but, when constituted as a holoenzyme with wild-type HisH, impair the glutamine-dependent activity of IGP synthase. The steady-state kinetic constants for these IGP synthases with HisF alleles showed three distinct effects depending upon the site of mutation. For example, mutation of the R5 residue has similar effects on the glutamine-dependent amidotransfer reaction; however, k(cat)/K(m) for the glutaminase half-reaction was increased 10-fold over that for the wild-type enzyme with nucleotide substrate. This site appears essential for coupling of the glutamine hydrolysis and ammonia transfer steps and is the first example of a site remote to the catalytic triad that modulates the process. The results are discussed in the context of recent X-ray crystal structures of glutamine amidotransferases that relate the glutamine binding and acceptor binding sites.     

Maize Glutamine Synthetase Cdnas: Isolation by Direct Genetic Selection in Escherichia Coli

Maize glutamine synthetase cDNA clones were isolated by genetic selection for functional rescue of an Escherichia coli delta glnA mutant growing on medium lacking glutamine. The Black Mexican Sweet cDNA library used in this study was constructed in pUC13 such that cDNA sense strands were transcribed under the control of the lac promoter. E. coli delta glnA cells were transformed with cDNA library plasmid DNA, grown briefly in rich medium to allow phenotypic expression of the cDNAs and the pUC13 ampr gene, and challenged to grow on agar medium lacking glutamine. Large numbers of glutamine synthetase cDNA clones have been identified in individual 150-mm Petri dishes; all characterized cDNA clones carry complete coding sequences. Two cDNAs identical except for different 5' and 3' termini have been sequenced. The major open reading frame predicts a protein with an amino acid sequence that exhibits striking similarity to the amino acid sequences of the predicted products of previously sequenced eukaryotic glutamine synthetase cDNAs and genes. In addition, the maize glutamine synthetase cDNAs were shown to contain a 5' mini-ORF of 29 codons separated by 37 nucleotide pairs from the major ORF. This mini-ORF was shown not to be essential for the functional rescue of the E. coli delta glnA mutant. Expression of the cDNAs in E. coli is presumed to be due to the function of a polycistronic hybrid lac messenger RNA or translational fusions encoded by the pUC plasmids. Proteins of the expected sizes encoded by two different pUC clones were shown to react with antibodies to tobacco glutamine synthetase.     

Molecular characterization of two galactosemia mutations: correlation of mutations with highly conserved domains in galactose-1-phosphate uridyl transferase.

Galactosemia is an autosomal recessive disorder of human galactose metabolism caused by deficiency of the enzyme galactose-1-phosphate uridyl transferase (GALT). The molecular basis of this disorder is at present not well understood. We report here two missense mutations which result in low or undetectable enzymatic activity. First, we identified at nucleotide 591 a transition which substitutes glutamine 188 by arginine. The mutated glutamine is not only highly conserved in evolution (conserved also in Escherichia coli and Saccharomyces cerevisiae), but is also two amino acid residues downstream from the active site histidine-proline-histidine triad and results in about 10% of normal enzymatic activity. The arginine 188 mutation is the most common galactosemia mutation characterized to date. It accounts for one-fourth of the galactosemia alleles studied. Second, we report the substitution of arginine 333 by tryptophan, caused by a transition at nucleotide 1025. The area surrounding this missense mutation is the most highly conserved domain in the homologous enzymes from E. coli, yeast, and humans, and this mutation results in undetectable enzymatic activity, suggesting that this is a severe mutation. This second mutation appears to be rare, since it was found only in the patient we sequenced. Our data provide further evidence for the heterogeneity of galactosemia at the molecular level, heterogeneity which might be related to the variable clinical outcome observed in this disorder.     

Synthetase competition and tRNA context determine the in vivo identify of tRNA discriminator mutants.

The discriminator nucleotide (position 73) in tRNA has long been thought to play a role in tRNA identity as it is the only variable single-stranded nucleotide that is found near the site of aminoacylation. For this reason, a complete mutagenic analysis of the discriminator in three Escherichia coli amber suppressor tRNA backgrounds was undertaken; supE and supE-G1C72 glutamine tRNAs, gluA glutamate tRNA and supF tyrosine tRNA. The effect of mutation of the discriminator base on the identity of these tRNAs in vivo was assayed by N-terminal protein sequencing of E. coli dihydrofolate reductase, which is the product of suppression by the mutated amber suppressors, and confirmed by amino acid specific suppression experiments. In addition, suppressor efficiency assays were used to estimate the efficiency of aminoacylation in vivo. Our results indicate that the supE glutamine tRNA context can tolerate multiple mutations (including mutation of the discriminator and first base-pair) and still remain predominantly glutamine-accepting. Discriminator mutants of gluA glutamate tRNA exhibit increased and altered specificity probably due to the reduced ability of other synthetases to compete with glutamyl-tRNA synthetase. In the course of these experiments, a glutamate-specific mutant amber suppressor, gluA-A73, was created. Finally, in the case of supF tyrosine tRNA, the discriminator is an important identity element with partial to complete loss of tyrosine specificity resulting from mutation at this position. It is clear from these experiments that it may not be possible to assign a specific role in tRNA identity to the discriminator. The identity of a tRNA in vivo is determined by competition among aminoacyl-tRNA synthetases, which is in turn modulated by the nucleotide substitution as well as the tRNA context.     

Three different mutations in codon 61 of the human N-ras gene detected by synthetic oligonucleotide hybridization

The activation of ras genes in naturally occurring tumors has, thus far, been found to be due to mutations in codon 12 or 61 resulting in single amino acid substitutions. We have used highly labeled synthetic oligonucleotides to detect mutations in these codons and to determine the exact position of the mutation. Using this approach we have found three different mutations in codon 61 of the N-ras gene of various human tumor cell lines. In the fibrosarcoma line HT1080 the first nucleotide of the codon is mutated; in the promyelocytic line HL60 the second and in the rhabdomyosarcoma line RD301 the third nucleotide. For RD301 this implies that the normal glutamine residue at position 61 is replaced by histidine. In addition to the mutated N-ras gene the three cell lines have a normal N-ras gene which is indicative of the dominant character of the mutations.     

Site-directed mutagenesis of the GTP-binding domain of beta-tubulin.

Tubulin binds guanine nucleotides with high affinity and specificity. GTP, an allosteric effector of microtubule assembly, requires Mg2+ for its interaction with beta-tubulin and binds as the MgGTP complex. In contrast, GDP binding does not require Mg2+. The structural basis for this difference is not understood but may be of fundamental importance for microtubule assembly. We investigated the interaction of beta-tubulin with guanine nucleotides using site-directed mutagenesis. Acidic amino acid residues have been shown to interact with nucleotide in numerous nucleotide-binding proteins. In this study, we mutated seven highly conserved aspartic acid residues and one highly conserved glutamic acid residue in the putative GTP-binding domain of beta-tubulin (N-terminal 300 amino acids) to asparagine and glutamine, respectively. The mutants were synthesized in vitro using rabbit reticulocyte lysates, and their affinities for nucleotide determined by an h.p.l.c.-based assay. Our results indicate that the mutations can be placed in six separate categories on the basis of their effects on nucleotide binding. These categories range from having no effect on nucleotide binding to a mutation that apparently abolishes nucleotide binding. One mutation at Asp224 reduced the affinity of beta-tubulin for GTP in the presence but not in the absence of Mg2+. The specific effect of this mutation on nucleotide binding is consistent with an interaction of this amino acid with the Mg2+ moiety of MgGTP. This residue is in a region sharing sequence homology with the putative Mg2+ site in myosin and other ATP-binding proteins. As a result, tubulin belongs to a distinct class of GTP-binding proteins which may be evolutionarily related to the ATP-binding proteins.     

Construction of a specific amber codon in the simian virus 40 T-antigen gene by site-directed mutagenesis.

The site-directed bisulfite mutagenesis technique has been used to construct a specific mutation, am404, at nucleotide position 3124 in the simian virus 40 genome. The mutation was contained within a PstI restriction site (map position 0.27) and prevented cleavage by PstI at that position. Nucleotide sequence analysis of the mutagenized region indicated that only a single base pair change had occurred: a guanosine x cytosine leads to adenine x thymine transition. Comparison of the nucleotide sequence of am404 with the known DNA sequence of simian virus 40 indicted that the mutation in am404 resulted in the conversion of a glutamine codon to an amber codon. am404 could not replicate autonomously when transfected into monkey cells (BSC-40) but did replicate when it was cotransfected with the late deletion helper virus dl1007. On the basis of its position in the T-antigen, gene am404 should produce a T-antigen 24% shorter than the wild-type protein.     

Molecular cloning and nucleotide sequence of cDNA for murine senile amyloid protein: nucleotide substitutions found in apolipoprotein A-II cDNA of senescence accelerated mouse (SAM).

cDNA clones encoding the murine senile amyloid protein (ASSAM) have been isolated from animal models of accelerated senescence (SAM-P/1) and from normal aging (SAM-R/1). Immunochemical and protein sequence studies revealed that apolipoprotein (apo) A-II is a serum precursor of ASSAM. A 17-base synthetic oligonucleotide based on residues 39-44 of ASSAM was used as a hybridization probe for screening newly constructed SAM-P/1 and SAM-R/1 liver cDNA libraries. The structure of murine apo A-II cDNA is of interest because of the amino acid substitution found in ASSAM and serum apo A-II of SAM-P; in SAM-R or other random bred slc:ICR mice, amino acid residue 5 of mature apo A-II is proline but, in SAM-P, this amino acid is changed to glutamine. This amino acid replacement is caused by two nucleotide substitutions (CCA for proline codon to CAG for glutamine codon). The third base mutation may not be relevant to the substitution of amino acid. Attention is directed to the relation of this amino acid substitution to the specific deposition of apo A-II, as a tissue amyloid fibril.     

Novel point mutation in the sodium channel gene of pyrethroid-resistant sea lice Lepeophtheirus salmonis (Crustacea: Copepoda)

Knockdown resistance (kdr) to pyrethroid insecticides is caused by point mutations in the pyrethroid target site, the para-type sodium channel of nerve membranes. This most commonly involves alterations within the domain II (S4-S6) region of the channel protein, where several different mutation sites have been identified across a range of insect species. To investigate the possibility that a kdr-type mechanism is responsible for pyrethroid resistance in sea lice, a domain II region of the Lepeophtheirus salmonis sodium channel gene was PCR amplified and sequenced. To our knowledge, this is the first published sodium channel sequence from a crustacean. Comparison of sequences from a range of samples, including several individuals from areas in which control failures had been reported, failed to identify any of the mutations within this region that have previously been linked with resistance. Instead, a novel glutamine to arginine mutation, Q945R, in transmembrane segment IIS5 was consistently found in the samples from areas of control failure and may therefore be associated with resistance to pyrethroids in this species.     

Characterization of SALMONELLA TYPHIMURIUM Mutants with Altered Glutamine Synthetase Activity

A number of glutamine auxotrophs of Salmonella typhimurium were isolated and characterized genetically. Three of the mutations appear to be closely linked and are complemented by episomes carrying the glnA region of Escherichia coli. The lesions in these strains are approximately 20% linked by P1 transduction with a mutation in the rha gene, but are unlinked to ilv. Another mutation causing glutamine auxotrophy in strain JB674 is genetically distinct from the others. Strain JB674 grown in glucose medium containing ammonia as the nitrogen source has reduced levels of glutamine synthetase that is more adenylylated than in the parent strain, suggesting that the enzyme can not be deadenylylated normally. The lesion causing glutamine auxotrophy in JB674 lies in the region corresponding to the glnB and glnE genes affecting glutamine synthetase modification in Klebsiella areogenes. Four Gln+ revertants of JB674 have glutamine synthetase activities 4 to 6 fold higher than normal. One mutation causing this increased enzyme synthesis has been shown by three-factor crosses with the glnA mutations to lie near or within the glnA gene.     

Temperature-sensitive poliovirus mutant fails to cleave VP0 and accumulates provirions.

A temperature-sensitive mutant of poliovirus, VP2-103, was isolated and characterized. A single nucleotide change, resulting in the substitution of glutamine for arginine at amino acid 76 of the capsid protein VP2, prevented the maturation of virions at the nonpermissive temperature. Particles indistinguishable from the previously elusive provirions were observed; these particles have been proposed to be penultimate in virion morphogenesis. Cleavage of VP0 into VP2 and VP4, the products found in mature virions, was not observed in VP2-103-infected cells at the nonpermissive temperature. The cleavage of VP0 in wild-type poliovirus-infected cells is dependent on RNA packaging; this reaction has been postulated to be autocatalytic. The existence of RNA-containing provirionlike particles in VP2-103-infected cells shows that RNA packaging can be uncoupled from VP0 cleavage.     

Involvement of the biosynthetic pathway of purine nucleotides in the repression of bacterial sporulation

Results reported here show that the repressive action of glutamine on sporulation described previously is brought about by those early steps of the purine nucleotide pathway in which glutamine is an amino group donor.     

Characterization of glutamine-requiring mutants of Pseudomonas aeruginosa.

Revertants were isolated from a glutamine-requiring mutant of Pseudomonas aeruginosa PAO. One strain showed thermosensitive glutamine requirement and formed thermolabile glutamine synthase, suggesting the presence of a mutation in the structural gene for glutamine synthetase. The mutation conferring glutamine auxotrophy was subsequently mapped and found to be located at about 15 min on the chromosomal map, close to and before hisII4. Furthermore, in transduction experiments, it appeared to be very closely linked to gln-2022, a suppressor mutation affecting nitrogen control. With immunological techniques, it could be demonstrated that the glutamine auxotrophs form an inactive glutamine synthetase protein which is regulated by glutamine or a product derived from it in a way similar to other nitrogen-controlled proteins.     

Construction and properties of a ribosome-binding site mutation in gene E of phi X174 bacteriophage.

Oligodeoxyribonucleotide mutagenesis has been used to produce a G----A mutation at nucleotide 557 of the phi X174 genome. This changes the ribosome-binding sequence GAGG of gene E to GAAG without affecting the amino acid, glutamine, encoded by the overlapping gene D. The phi X174rb(E)557 mutant does not lyse infected Escherichia coli C and therefore results in the accumulation of a large number intracellular mature phage particles. Thus, the mutation inactivates production of the gene E lytic product, presumably by blocking translation of gene E, without affecting other phage functions.     

Nucleotide alterations in the bacteriophage T4 glutamine transfer RNA that affect ochre suppressor activity

We have determined the nucleotide sequences of the glutamine transfer RNAs that are coded by wild-type and psu₂⁺ ochre-suppressor strains of bacteriophage T4. The two transfer RNAs have the same sequence except for their anticodons, where NUG in the wild-type species is mutated to NUA in the psu₂⁺ species (N is a modified residue of U). This mutation is believed to confer suppressor activity on the psu₂⁺ glutamine tRNA. Three mutants derived from psu₂⁺ by loss of suppressor activity have been characterized with respect to their sequence alterations. Each mutant specifies a transfer RNA differing from the psu₂⁺ species by a nucleotide substitution that occupies a base-paired region in the cloverleaf arrangement of the molecule. The mutants synthesize a reduced amount of tRNA that is defective in nucleotide modifications and processing at the 5′ and 3′ termini.     

A novel point mutation in congenital erythropoietic porphyria in two members of Japanese family

The molecular basis of the uroporphyrinogen III synthase (UROIIIS) deficiency was investigated in two members of a Japanese family. This defect in heme biosynthesis is responsible for a rare autosomal recessive disease: congenital erythropoietic porphyria (CEP) or Günther’s disease. The first patient was homoallelic for a novel missense mutation: a T to C transition of nucleotide 634 that predicted a serine to proline substitution at residue 212 (S212P). The second patient appeared heteroallelic, carrying the same missense mutation and a nonsense mutation: a C to T change at nucleotide 745, resulting in a premature stop at codon 249, instead of a glutamine (Q249X). The corresponding mutated proteins were expressed in Escherichia coli and no residual activity was observed. A family study was also performed to determine the carrier status. Received: 18 July 1995     

Hypoxanthine guanine phosphoribosyltransferase deficiency: nucleotide substitution causing Lesch-Nyhan syndrome identified for the first time among Japanese

Summary A previously undescribed nucleotide substitution at codon 51 (CGA to TGA) has been identified using the polymerase chain reaction technique in hypoxanthine guanine phosphoribosyltransferase (HPRT) cDNA; this is the first molecular evidence for a point mutation in a Japanese patient with Lesch-Nyhan syndrome. The present mutation is the 19th nucleotide substitution identified as a germ-line mutation at this locus and the second mutation generating a stop codon. The position of the nucelotide substitution is exactly the same as a previously described mutation HPRT_Toronto, indicating for the first time that nucleotide substitutions at the same position in the sequence of HPRT can generate different mutant alleles, one causing a partial deficiency and the other a complete deficiency. Although the type of nucleotide substitution is different between the two cases, a single base position has twice become the target of a mutation. However, the calculation of the probability of finding substitution mutations at the same base position in the coding region of hprt indicates that there is no evidence for the presence of a hot spot for substitution mutations in the human hprt germ line.     

A novel heteroplasmic tRNA(Leu(CUN)) mtDNA point mutation associated with chronic progressive external ophthalmoplegia

We have sequenced all mitochondrial tRNA genes from a patient with chronic progressive external ophthalmoplegia (CPEO) and mitochondrial myopathy, who had no detectable large mtDNA deletions. Direct sequencing failed to detect previously reported mutations and showed a heteroplasmic mutation at nucleotide 12,276 in the tRNA(Leu(CUN)) gene, in the dihydrouridine stem, which is highly conserved through the species during evolution. RFLP analyses confirmed that 18% of muscle mtDNA harbored the mutation, while it was absent from DNA of fibroblasts and lymphocytes of the proband and in 110 patients with other encephalomyopathies. To date, besides large and single nucleotide deletions, several point mutations on mitochondrial tRNA genes have been reported in CPEO patients, but only three were in the gene coding for tRNA(Leu(CUN)).