Molecular evidence for human alpha2-HS glycoprotein (AHSG) polymorphism

Alpha2-HS glycoprotein (AHSG) is a human plasma glycoprotein that exhibits genetic polymorphism on isoelectric focusing (IEF). To identify the origin of two common alleles, AHSG*1 and *2, we examined nucleotide exchanges in the gene. AHSG cDNA was obtained by RT-PCR from poly(A) RNA of seven liver tissue samples and subcloned into a plasmid vector. After sequencing, we found six single nucleotide differences in comparison with the originally reported sequence. In particular, the nucleotide substitutions of C to T at amino acid position 230 and C to G at position 238 were common among the samples exhibiting phenotype 2–1 or 2. Since these substitutions might give rise to a NlaIII site and a SacI site, respectively, for the potential AHSG*2, we analyzed these substitutions by PCR-RFLP using genomic DNA of 68 individuals. The result was consistent with the IEF analysis of the corresponding serum, indicating that AHSG*1 was characterized by ACG (Thr) at position 230 in exon 6 and ACC (Thr) at position 238 in exon 7, and that AHSG*2 was characterized by ATG (Met) at position 230 and AGC (Ser) at position 238. Received: 5 March 1996 / Revised: 25 June 1996     

Functional polymorphisms in the mineralocorticoid receptor and amirolide-sensitive sodium channel genes in a patient with sporadic pseudohypoaldosteronism

Pseudohypoaldosteronism (PHA) is characterized by urinary salt-wasting in infancy resulting from a congenital resistance to aldosterone involving the genes for the mineralocorticoid receptor (MR) and the amiloride-sensitive sodium channel (ENaC). We identified, in a Japanese patient with sporadic PHA, three homozygous substitutions in the MR gene: G215-->C215, A754-->G754 (Ile180-->Val180), C938-->T938 (Ala241-->Val241), which had previously been reported to occur in healthy populations. Luciferase activities induced by MR with either G215-->C215, Ile180-->Val180, or Ala241-->Val241 substitution were significantly lower than those for wild-type MR with aldosterone at concentrations ranging from 10(-11) to 10(-9) M, 10(-8) M, or 10(-11) to 10(-6) M, respectively. A homozygous A-->G substitution of the donor splice site of alphaENaC intron 4 was found in the patient. The corresponding cDNA exhibited a normal structure, suggesting that this substitution does not alter the splice. The results suggest that each of three MR polymorphisms identified in our patient is functionally and structurally heterogeneous. We hypothesize that two or more "functional" polymorphisms, any of which exhibits only slight effects on MR or ENaC function and is alone incapable causing PHA, may in the right allelic combination induce the negative salt-conservation characteristic of PHA.     

A:T --> G:C base pair substitutions occur at a higher rate than other substitution events in Pms2 deficient mouse cells

The mismatch repair pathway involves multiple proteins that are required to correct DNA polymerase generated mismatches before they become mutations. It has been shown recently, that the predominant base-pair substitution events leading to loss of endogenous Aprt activity in Pms2 null mouse cells are A:T --> G:C mutations (Oncogene 21 (2002) 1768, Oncogene 21 (2002) 2840). To determine if this observation could be explained by an increased rate of A:T --> G:C mutations relative to other base-pair substitutions, we developed a reversion assay to examine G:C --> A:T, C:G --> A:T, and A:T --> G:C mutations within mouse Aprt in a Pms2 null mouse kidney cell line. The results demonstrated a 6-50-fold increase in the rate of the A:T --> G:C mutations relative to the other base-pair substitutions. Additional work demonstrated that growth of the Pms2 null cells in antioxidant containing medium reduced the rate of the A:T --> G:C mutations. The results are discussed with regards to the role of mismatch repair proteins in preventing base-pair substitutions, including those induced by oxidative stress.     

Multiple amino acid substitutions in hemagglutinin are necessary for wild-type measles virus to acquire the ability to use receptor CD46 efficiently

Measles virus (MV) possesses two envelope glycoproteins, namely, the receptor-binding hemagglutinin (H) and fusion proteins. Wild-type MV strains isolated in B-lymphoid cell lines use signaling lymphocyte activation molecule (SLAM), but not CD46, as a cellular receptor, whereas MV vaccine strains of the Edmonston lineage use both SLAM and CD46 as receptors. Studies have shown that the residue at position 481 of the H protein is critical in determining the use of CD46 as a receptor. However, the wild-type IC-B strain with a single N481Y substitution in the H protein utilizes CD46 rather inefficiently. In this study, a number of chimeric and mutant H proteins, and recombinant viruses harboring them, were generated to determine which residues of the Edmonston H protein are responsible for its efficient use of CD46. Our results show that three substitutions (N390I and E492G plus N416D or T446S), in addition to N481Y, are necessary for the IC-B H protein to use CD46 efficiently as a receptor. The N390I, N416D, and T446S substitutions are present in the H proteins of all strains of the Edmonston lineage, whereas the E492G substitution is found only in the H protein of the Edmonston tag strain generated from cDNAs. The T484N substitution, found in some of the Edmonston-lineage strains, resulted in a similar effect on the use of CD46 to that caused by the E492G substitution. Thus, multiple residues in the H protein that have not previously been implicated have important roles in the interaction with CD46.     

Reverse polarization in amino acid and nucleotide substitution patterns between human-mouse orthologs of two compositional extrema.

Genome-wide analysis of sequence divergence patterns in 12,024 human-mouse orthologous pairs reveals, for the first time, that the trends in nucleotide and amino acid substitutions in orthologs of high and low GC composition are highly asymmetric and polarized to opposite directions. The entire dataset has been divided into three groups on the basis of the GC content at third codon sites of human genes: high, medium, and low. High-GC orthologs exhibit significant bias in favor of the replacements, Thr --> Ala, Ser --> Ala, Val --> Ala, Lys --> Arg, Asn --> Ser, Ile --> Val etc., from mouse to human, whereas in low-GC orthologs, the reverse trends prevail. In general, in the high-GC group, residues encoded by A/U-rich codons of mouse proteins tend to be replaced by the residues encoded by relatively G/C-rich codons in their human orthologs, whereas the opposite trend is observed among the low-GC orthologous pairs. The medium-GC group shares some trends with high-GC group and some with low-GC group. The only significant trend common in all groups of orthologs, irrespective of their GC bias, is (Asp)(Mouse) --> (Glu)(Human) replacement. At the nucleotide level, high-GC orthologs have undergone a large excess of (A/T)(Mouse) --> (G/C)(Human) substitutions over (G/C)(Mouse) --> (A/T)(Human) at each codon position, whereas for low-GC orthologs, the reverse is true.     

Targeted gene correction of hprt mutations by 45 base single-stranded oligonucleotides

Targeted correction of a single base in a gene of an eucaryotic cell by specific oligonucleotides is a yet controversial technique. Here, we introduce the correction of point mutations in the hypoxanthine-guanine-phosphoribosyl-transferase (HPRT) gene as an additional model system to test targeted gene correction. In human, Hprt mutations cause Lesch-Nyhan syndrome. Using hamster V79 cells, we generated three cell lines with one hprt point mutation each. These cell lines were treated with specific single-stranded 45 base phosphothioate modified oligonucleotides and selected by HAT medium. The surviving clones were investigated for the correction of the respective hprt mutation. Treatment with the oligonucleotides was successful in repairing all three hprt mutations (hprt cDNA position 74, C --> T; position 151, C --> T; and position 400, G --> A). The correction efficiency was very low but reproducible. We suggest that this system allows one to investigate targeted gene correction in dependence on the target sequence and the oligonucleotides used.     

Novel mutational spectrum induced by N-methyl-N'-nitro-N-nitrosoguanidine in the coding region of the hypoxanthine (guanine) phosphoribosyltransferase gene in diploid human fibroblasts

The kinds and locations of mutations in the coding region of the hypoxanthine (guanine) phosphoribosyltransferase (hprt) gene of 75 independent mutants, derived from N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-treated normal human fibroblasts, were characterized by direct sequencing of mRNA-polymerase chain reaction (mRNA-PCR)-amplified cDNA. Treatment of human cells with low (6 or 8 microM) or high (10 or 12 microM) doses of MNNG resulted in 35-fold or 150-fold average increases in mutation frequency, respectively. A high frequency of mutants lacking a complete exon was observed in both groups. Further characterization of half of these mutants by DNA-PCR amplification of intron-exon boundaries showed that they contained base substitutions. The kinds of base substitutions differed distinctly between these two groups. In the low dose group, a broad mutational spectrum was observed: ten out of the 31 base substitutions were A.T to G.C transitions, six contained G.C to A.T transitions, and the other 15 exhibited transversions. In contrast, the majority (84%) of base substitutions among the high dose group were G.C to A.T transitions; the others (16%) were transversions. All of the 32 G.C to A.T transitions were located on the non-transcribed strand, assuming that the causative premutational lesion was O6-methylguanine. These results indicate preferential repair of lesions located on the transcribed strand. In addition, G.C to A.T and A.T to G.C transitions preferentially occurred at positions with guanine and thymine at the adjacent 5' position, respectively.     

Role of conserved transmembrane cationic amino acids in the prostaglandin transporter PGT

The prostaglandin transporter "PGT" interacts electrostatically with its anionic substrate, based on inhibition by the disulfonic stilbenes [Chan, B. S. (1998) J. Biol. Chem. 273, 6689-6697], inhibition by the thiol-reactive anion sodium (2-sulfonatoethyl)methanethiosulfonate (MTSES) [Chan, B. S. (1999) J. Biol. Chem. 274, 25564-25570], and the requirement for a negatively charged 1-position carboxyl on the substrate [Itoh, S. (1996) Mol. Pharm. 50, 736-742]. Here we found that modification of positively charged residues on wild-type PGT by arginine- and lysine-specific reagents significantly inhibited transport. We previously found that the binding site of PGT is formed, at least in part, by its membrane-spanning segments [Chan, B. S. (1999) J. Biol. Chem. 274, 25564-25570]. Three charged residues within predicted transmembrane spans (E78, R560, and K613) are conserved in PGT and in related transporters. Substitution of the anionic residue E78 (E78D and E78C) produced an essentially functional transporter, whereas substitution of the cationic residues with neutral residues (R560N and K613Q) resulted in poorly functional transporters. Immunoblotting revealed similar expression levels of wild-type and mutant transporters, and immunostaining indicated correct targeting. Conservative charge substitutions (R560K, K613R, and K613H) resulted in generally functional transporters. In contrast, R560N was nonfunctional, whereas the substrate affinity of K613G decreased greater than 50-fold. Conservative substitutions retaining the charge at position 613 (K613R and K613H) restored the substrate affinity, suggesting a direct role of K613 in substrate binding. Double-neutral mutants E78G/R560C and E78G/K613C were inactive, indicating that these residues are not simply charge-paired. Our results suggest that an arginine at position 560 is critical for maximal substrate translocation, and that a positively charged side chain at position 613 contributes to electrostatic binding of the anionic substrate.     

Detecting gradients of asymmetry in site-specific substitutions in mitochondrial genomes

During mitochondrial replication, spontaneous mutations occur and accumulate asymmetrically during the time spent single stranded by the heavy strand (DssH). The predominant mutations appear to be deaminations from adenine to hypoxanthine (A --> H, which leads to an A --> G substitution) and cytosine to thymine (C --> T). Previous findings indicated that C --> T substitutions accumulate rapidly and then saturate at high DssH, suggesting protection or repair, whereas A --> G accumulates linearly with DssH. We describe here the implementation of a simple hidden Markov model (HMM) of among-site rate correlations to provide an almost continuous profile of the asymmetry in substitution response for any particular substitution type. We implement this model using a phylogeny-based Bayesian Markov chain Monte Carlo (MCMC) approach. We compare and contrast the relative asymmetries in all 12 possible substitution types, and find that the observed transition substitution responses determined using our new method agree quite well with previous predictions of a saturating curve for C --> T transition substitutions and a linear accumulation of A --> G transitions. The patterns seen in transversion substitutions show much lower among-site variation, and are nonlinear and more complex than those seen in transitions. We also find that, after accounting for the principal linear effect, some of the residual variation in A --> G/G --> A response ratios is explained by the average predicted nucleic acid secondary structure propensity at a site, possibly due to protection from mutation when secondary structure forms.     

A role for Pms2 in the prevention of tandem CC --> TT substitutions induced by ultraviolet radiation and oxidative stress

DNA mismatch repair (MMR) is important for preventing base-pair substitutions caused by spontaneous or damage-related DNA polymerase errors. We have used a reversion assay based on mouse Aprt to investigate the role of MMR in preventing ultraviolet radiation (UV) and oxidative stress induced tandem CC --> TT base pair substitutions in cultured mammalian cells. The reversion construct used for this assay can detect both C --> T and CC --> TT mutational events. Most spontaneous mutations in Pms2-deficient cells were single C --> T substitutions (88%), with the remainder being tandem CC --> TT substitutions (12%). The percentage of tandem CC --> TT substitutions rose to 64% and 94% for Pms2-deficient cells exposed to UV and a mixture of hydrogen peroxide and metals (Cu/Fe), respectively. Exposure to hydrogen peroxide alone or metals alone did not induce the tandem substitutions, nor did treatment of the cells with the alkylating agent ethylmethane sulfonate, which induces G --> A substitutions on the opposite strand. Tandem CC --> TT substitutions were also induced by UV irradiation and the hydrogen peroxide/metal mixture in Pms2-proficient cells, but at frequencies significantly lower than those observed in the Pms2-deficient cells. We conclude that mismatch repair plays an important role in preventing tandem CC --> TT substitutions induced by certain genotoxin exposures.     

Cell type-specific enhancement of hepatitis C virus internal ribosome entry site-directed translation due to 5' nontranslated region substitutions selected during passage of virus in lymphoblastoid cells

Low-level replication of hepatitis C virus (HCV) in cultured lymphoblastoid cells inoculated with H77 serum inoculum led to the appearance of new virus variants containing identical substitutions at three sites within the viral 5' nontranslated RNA (5'NTR): G(107)-->A, C(204)-->A, and G(243)-->A (N. Nakajima, M. Hijikata, H. Yoshikura, and Y. K. Shimizu, J. Virol. 70:3325-3329, 1996). These results suggest that virus with this 5'NTR sequence may have a greater capacity for replication in such cells, possibly due to more efficient cap-independent translation, since these nucleotide substitutions reside within the viral internal ribosome entry site (IRES). To test this hypothesis, we examined the translation of dicistronic RNAs containing upstream and downstream reporter sequences (Renilla and firefly luciferases, respectively) separated by IRES sequences containing different combinations of these substitutions. The activity of the IRES was assessed by determining the relative firefly and Renilla luciferase activities expressed in transfected cells. Compared with the IRES present in the dominant H77 quasispecies, an IRES containing all three nucleotide substitutions had significantly greater translational activity in three of five human lymphoblastoid cell lines (Raji, Bjab, and Molt4 but not Jurkat or HPBMa10-2 cells). In contrast, these substitutions did not enhance IRES activity in cell lines derived from monocytes or granulocytes (HL-60, KG-1, or THP-1) or hepatocytes (Huh-7) or in cell-free translation assays carried out with rabbit reticulocyte lysates. Each of the three substitutions was required for maximally increased translational activity in the lymphoblastoid cells. The 2- to 2.5-fold increase in translation observed with the modified IRES sequence may facilitate the replication of HCV, possibly accounting for differences in quasispecies variants recovered from liver tissue and peripheral blood mononuclear cells of the same patient.     

A mutation generating a stop codon in the alpha-L-fucosidase gene of a fucosidosis patient.

Fucosidosis is an autosomal recessive, lysosomal storage disease featured by deficient activity of alpha-L-fucosidase. Lymphoid cell lines from a fucosidosis patient (JT) and a healthy individual (control) contained alpha-L-fucosidase mRNA of the same size, 2.3 Kb, as determined by Northern blot analysis. cDNA was prepared from alpha-L-fucosidase mRNA of JT and control cells and each cDNA was amplified by the polymerase chain reaction. Direct DNA sequencing of the amplified products revealed a single mutation in JT, a G1141-->T transition. This changed the codon (GAA) for Glu-375 to a stop codon (UAA). Amplification and sequencing of the area containing the G1141-->T transition in genomic DNA of JT and control cells demonstrated that the mutation was homozygous in JT. Analysis of cDNA and genomic DNA derived from lymphoid cells of mother JT revealed her to be heterozygous (G and T) at position 1141. The G1141-->T mutation is probably responsible for disease in JT.     

HL60 cells halted in G1 or S phase differentiate normally

Differentiating agents regulate the proliferation and myeloid maturation of HL60 cells by mechanisms that are at least partly independent (Drayson et al., (2001), Exp. Cell Res. 266, 126-134). We have investigated whether halting HL60 cells in G1 or S phase influences their commitment to or maturation along the neutrophil and monocyte pathways. Early G1 and S phase cells were isolated separately by elutriation. Quinidine was used to block the cell cycle progression of G1 cells and aphidicolin to greatly retard the progression of S phase cells. Neutrophilic (in response to all-trans-retinoic acid) or monocytic (to 1 alpha,25-dihydroxyvitamin D(3)) differentiation were assessed by induction of CD11b, M-CSF receptor and CD14 expression, acquisition of granulocyte-colony stimulating factor responsiveness, capacities to phagocytose yeast and reduce nitroblue tetrazolium, and down-regulation of CD30 and transferrin receptor expression. The cell-cycle-blocked cells differentiated at normal rates, mostly without incorporating bromodeoxyuridine. These observations establish: (a) that neither transit through the cell cycle nor a cell's position in the cell cycle substantially influences execution of the neutrophilic and monocytic differentiation programs by HL60 cells; and (b) that individual HL60 cells are genuinely bipotent.     

Mutant barley (1-->3,1-->4)-beta-glucan endohydrolases with enhanced thermostability

The similar three-dimensional structures of barley (1-->3)-beta-glucan endohydrolases and (1-->3,1-->4)-beta-glucan endohydrolases indicate that the enzymes are closely related in evolutionary terms. However, the (1-->3)-beta-glucanases hydrolyze polysaccharides of the type found in fungal cell walls and are members of the pathogenesis-related PR2 group of proteins, while the (1-->3,1-->4)-beta-glucanases function in plant cell wall metabolism. The (1-->3)-beta-glucanases have evolved to be significantly more stable than the (1-->3,1-->4)-beta-glucanases, probably as a consequence of the hostile environments imposed upon the plant by invading microorganisms. In attempts to define the molecular basis for the differences in stability, eight amino acid substitutions were introduced into a barley (1-->3,1-->4)-beta-glucanase using site-directed mutagenesis of a cDNA that encodes the enzyme. The amino acid substitutions chosen were based on structural comparisons of the barley (1-->3)- and (1-->3,1-->4)-beta-glucanases and of other higher plant (1-->3)-beta-glucanases. Three of the resulting mutant enzymes showed increased thermostability compared with the wild-type (1-->3,1-->4)-beta-glucanase. The largest increase in stability was observed when the histidine at position 300 was changed to a proline (mutant H300P), a mutation that was likely to decrease the entropy of the unfolded state of the enzyme. Furthermore, the three amino acid substitutions which increased the thermostability of barley (1-->3,1-->4)-beta-glucanase isoenzyme EII were all located in the COOH-terminal loop of the enzyme. Thus, this loop represents a particularly unstable region of the enzyme and could be involved in the initiation of unfolding of the (1-->3,1-->4)-beta-glucanase at elevated temperatures.     

Identification of a missense mutation in an adult-onset patient with glycogenosis type II expressing only one allele.

The lysosomal enzyme acid alpha glucosidase (GAA) or acid maltase is deficient in glycogen storage disease type II. We sought to determine the molecular basis for the disease in an adult-onset patient, unusual for very low enzyme activity similar to that seen with the infantile-onset form and with a previously reported defect in phosphorylation. We constructed cDNA and genomic DNA libraries from the patient's cell line (GM 1935) and determined the nucleotide sequence of the coding region. There were three base-pair substitutions in one allele (C1935 to A; G2446 to A and C2780 to T), all predicting amino acid changes (Asp-645 to Glu; Val-816 to Ile and Thr-927 to Ile). To determine which of the three base-pair substitutions resulted in loss of enzyme activity, we next utilized primer-directed mutagenesis and transient gene expression in an SV40-immortalized GAA-deficient fibroblast cell line. Only the construct containing the G2446 to A mutation (Val-816 to Ile) lost GAA enzyme activity, while the other two substitutions (including the Thr-927 to Ile change that predicts a loss of a potential site for N-linked glycosylation and mannose phosphorylation) each resulted in enzyme activity equal to the control. Analysis of RFLPs in genomic DNA, as well as sequence analysis for the three base-pair alterations, indicated that the patient was a genetic compound. We next digested PCR-amplified cDNA (reverse-transcribed from RNA) with Aat II to detect the base-pair 1935 substitution and found that virtually all of the mRNA was derived from the allele with the three base-pair substitutions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synonymous nucleotide substitutions in the neonatal Fc receptor

The neonatal Fc receptor (FcRn) is a key receptor involved in the transcytosis of IgG across the maternal-fetal barrier. The level of IgG varies considerably among newborn infants. Since other Fc gamma receptors show single nucleotide functional variants, we determined whether common variant alleles exist for the FcRn. Direct sequence analysis was performed on PCR-amplified complementary DNA (cDNA) isolated from ten placental mRNAs (20 alleles examined). Two synonymous nucleotide polymorphisms were detected from the same source. A G251T and C707T substitution, reflecting amino acid positions Pro19 and Arg171 of the mature polypeptide, did not alter the amino acid encoded. No other nucleotide substitutions or sequence variations were observed. Thus, the variation in IgG transport is not due to common variant alleles among the human population. Due to the limited number of samples tested (n=20), low-frequency alleles would go undetected by chance alone when q has a frequency < or = 0.14. It is unlikely that low-frequency variant alleles, if present, are responsible for the major variation seen in the transcytosis of IgG.     

Analysis of spontaneous base substitutions generated in mutator strains of Bacillus subtilis

In the current studies, we investigated base substitutions in the Bacillus subtilis mutT, mutM, and mutY DNA error-prevention system. In the wild type strain, spontaneous mutations were mainly transitions, either G:C --> A:T or A:T --> G:C. Although both transitions and transversions were observed in mutY and mutM mutants, mutM/mutY double mutants contain strictly G:C --> T:A transversions. In the mutT strain, A:T --> C:G transversion was not observed, and over-expression of the B. subtilis mutT gene had no effect on the mutation rate in the Escherichia coli mutT strain. Using 8-oxo-dGTP-induced mutagenesis, transitions especially A:T --> G:C were predominant in the wild type and mutY strains. In contrary, transversion was high on mutY and double mutant (mutM mutY). Finally, the opuBC and yitG genes were identified from the B. subtilis chromosome as mutator genes that prevented the transition base substitutions.     

Characterization of functional GTP binding proteins in Jurkat T cell mutants lacking either CD3-Ti or CD2 surface receptors

G proteins are membrane-bound molecules involved in coupling of surface receptors with signal transduction effector systems in multiple cell types including T lymphocytes. Given that mature T cells which lack antigen receptors (CDl-Ti) are refractory to stimulation through CD2 or other accessory molecules, T cell receptor components likely play a critical role in coupling surface receptors with signal transduction effectors. It has recently been proposed that modulation of T cell receptor components with MAbs results in a physical loss or functional inactivation of G protein(s). In view of the importance of the T cell activation process, we herein examined G proteins in untreated or antibody-modulated Jurkat T cells as well as in genetic variants lacking either CD3-Ti or CD2 surface receptors. 43- and 41-kDa G protein alpha chains are ADP ribosylated with cholera (CTX) and pertussis (PTX) toxins, respectively, in wild type and receptor minus cell populations. In the wild type Jurkat cell line as well as in CD3- and CD2- variants, AlF4- can activate the G protein(s) presumably associated with phospholipase C to generate polyphosphoinositide turnover as well as an increase in cytoplasmic free calcium ions. Furthermore, G protein(s) linked to adenylylcyclase, a pathway which inhibits T lymphocyte activation, can be directly activated with CTX in the absence of CD3-Ti or CD2 on the membrane. Importantly, AlF4- can also induce polyphosphoinositide turnover in Jurkat cells whose T cell receptor proteins have been modulated with anti-CD3 MAb. These data provide functional and biochemical evidence that at least certain G proteins are intact in the absence of surface expression of CD3-Ti or CD2 molecules and imply that CD3-Ti desensitization is not singularly due to G protein loss.