Transient expression of human adenosine deaminase cDNAs: identification of a nonfunctional clone resulting from a single amino acid substitution

Repair of some active genes in Cockayne syndrome cells is at the genome overall rate

Repair of UV (254 nm)-induced DNA damage in cells from patients with the genetic disease Cockayne syndrome (CS; CS3BE, CS2BE) has been examined in several different genomic regions. These regions include those that contain the actively transcribed beta-actin and adenosine deaminase (ADA) genes and the inactive insulin and 754 loci. The beta-actin, ADA and insulin regions are repaired at about the same rate, one which is equal to the genome overall repair rate. The 754 locus is repaired considerably more slowly. The insulin region is repaired at the same rate in both CS and normal cells as is the 754 locus. The only difference from normal is that the active genes, while repaired well, are not preferentially repaired relative to the genome overall. Our results are consistent with the hypothesis that the repair defect in CS is due to an inactive transcription-repair coupling factor (TRCF). However, the results also indicate that factors other than TRCF and active transcription must also promote repair of some regions relative to others in both normal and CS cells.

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)

Adenosine deaminase deficiency due to heterozygous abnormality consisting of a deletion of exon 7 and the absence of enzyme mRNA

An adenosine deaminase (ADA;EC 3.5.4.4)-deficient B lymphoblastoid cell line BADO5 derived from a Japanese patient with severe combined immunodeficiency disease and two B lymphoblastoid cell lines, BAMO5 from his mother and BAFO5 from his father, were characterized. To identify mutations affecting ADA activity, we prepared cDNAs to ADA mRNAs of the BADO5 cell line for nucleotide sequencing. Sequence analysis of one of the BADO5 ADA cDNA clones revealed deletion of exon 7, and one point mutation of base 629 from G to A that did not affect the amino acid sequence. All clones of the BADO5 cell line so far examined showed the absence of exon 7 by Southern blotting analysis. Ribonuclease protection assay with an RNA probe spanning from exon 5 to exon 11 showed that the BADO5 ADA mRNA had a deletion of exon 7, the BAMO5 mRNA had normal length, and the BAFO5 mRNA had two species with a deletion of exon 7 and with normal length. Consequently, the patient's ADA genes resulted from one allele of the BAMO5 ADA gene that did not produce a detectable mRNA, and the other allele of the BAFO5 ADA gene producing an aberrant mRNA without exon 7.

Identification of the base-pair substitution responsible for a human acid alpha glucosidase allele with lower "affinity" for glycogen (GAA 2) and transient gene expression in deficient cells

The lysosomal enzyme termed acid alpha glucosidase (GAA), or acid maltase, is genetically polymorphic, with three alleles segregating in the normal population. The rarer GAA 2 allozyme has a lower affinity for glycogen and starch but not for lower-molecular-weight substrates. The GAA 2 allozyme can be detected by "affinity" electrophoresis in starch gel, since the lower affinity for the starch matrix results in a more rapid migration to the anode. Previously, we have isolated and sequenced the cDNA for GAA and transiently expressed the cDNA in deficient fibroblasts. In order to determine the molecular basis for the GAA 2 allozyme, we constructed a cDNA and a genomic DNA library from a GAA 2 cell line and determined the nucleotide sequence of the coding region. Only a single base-pair substitution of an A for a G at base-pair 271 was found, resulting in substitution of asparagine for aspartic acid at codon 91. This amino acid substitution is consistent with the more basic pI of the GAA 2 enzyme. The base-pair substitution also abolishes a Taq-I site, predicting the generation of a larger DNA fragment. This larger Taq-I fragment was also seen in two other individuals expressing the GAA 2 allozyme. A 5' fragment containing the base-pair substitution was ligated to the remaining 3' cDNA from a GAA 1 allele and cloned into an expression vector, and the hybrid cDNA was transiently expressed in SV40-transformed GAA-deficient fibroblasts. The enzyme activity exhibited the altered mobility of the GAA 2 allozyme, as demonstrated by electrophoresis in starch gel.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification and characterization of nine RFLPs at the adenosine deaminase (ADA) locus

We have identified and/or characterized at least nine RFLPs at the adenosine deaminase (ADA) locus, detected by digestion of DNA with MspI, BanII, PstI, BalI, and PvuII. The RFLPs were distributed over approximately 15 kb of the gene, from IVS 2 to IVS 10. They exhibited Mendelian inheritance and were in Hardy-Weinberg equilibrium. For seven fully characterized RFLPs, the gene frequencies of the rare alleles in 90 chromosomes examined ranged from .33 to .04, the PIC from .34 to .07, and the heterozygosity from .09 to .58. In kindreds examined (58 independent chromosomes), a total of nine haplotypes could be defined on the basis of seven fully characterized RFLPs with a heterozygosity of .62 and PIC of .53. Because there was considerable linkage disequilibrium, only three haplotypes accounted for 90% of individuals. Similar heterozygosity and PIC values (.59 and .51, respectively) could be obtained on the basis of haplotypes defined by the two sites that were the most polymorphic and that were in the least degree of linkage disequilibrium. A strategy for use of the RFLPs in linkage studies is suggested. We have also examined DNA from 17 patients with complete genetic deficiency of ADA (resulting in severe combined immunodeficiency [ADA-SCID] and from 10 patients with partial ADA deficiency (deficient in erythrocytes, with varying levels of ADA in other cells and normal immune function). Although the RFLPs detected genetic compounds among both types of patients, there was, as expected, a decreased incidence of heterozygosity (ADA-SCIDs, .29; partial ADA deficients, .20). Two additional haplotypes not found in the normal population were identified in homozygous form in patients. This information should be useful in developing a rational approach to delineation of mutations at the ADA locus as well as in distinguishing recurrent mutations of independent origin from those derived from a common progenitor.

Initiation of protein synthesis by internal entry of ribosomes into the 5' nontranslated region of encephalomyocarditis virus RNA in vivo

Expression vectors that yield mono-, di-, and tricistronic mRNAs upon transfection of COS-1 cells were used to assess the influence of the 5' nontranslated regions (5'NTRs) on translation of reporter genes. A segment of the 5'NTR of encephalomyocarditis virus (EMCV) allowed translation of an adjacent downstream reporter gene (CAT) regardless of its position in the mRNAs. A deletion in the EMCV 5'NTR abolishes this effect. Poliovirus infection completely inhibits translation of the first cistron of a dicistronic mRNA that is preceded by the capped globin 5'NTR, whereas the second cistron preceded by the EMCV 5'NTR is still translated. We conclude that the EMCV 5'NTR contains an internal ribosomal entry site that allows cap-independent initiation of translation. mRNA containing the adenovirus tripartite leader is also resistant to inhibition of translation by poliovirus.

Normal and mutant human adenosine deaminase genes

Adenosine deaminase (ADA) deficiency in humans is one cause of severe combined immunodeficiency. When ADA fails to catalyze the deamination of adenosine and deoxyadenosine, the levels of deoxyadenosine that accumulate are toxic to lymphoid cells. Patients with complete ADA deficiency (e.g., with less than 5% normal ADA catalytic activity) lack both B- and T-lymphocyte function. B-lymphoblast cell lines derived from patients with ADA deficiency have been analyzed at multiple levels. Blot hybridization and S1 nuclease analysis of ADA messenger RNA (mRNA) indicates that the majority of ADA-deficient cell lines have ADA mRNA in the same abundance and size as in normal cell lines. Sequence analysis of ADA cDNAs derived from these mRNAs shows that the majority of mutations are single base changes that alter the amino acid sequence. Expression analysis proves that these point mutations lead to deficiency of ADA catalytic activity. Several cell lines have mutations that alter mRNA transcription or processing. These include a point mutation in one allele of an ADA-deficient cell line that leads to deletion of exon 4 during mRNA splicing. In addition, two cell lines are homozygous for large deletions of the gene that are the result of homologous recombination. Subjects with partial ADA deficiency have undetectable ADA activity in their erythrocytes, variable activity in their lymphoid cells, and normal immunological function. Analysis of the ADA catalytic activity of partially deficient cell lines indicates that the mutations involved affect protein stability. However, the mutations causing partial ADA deficiency are as yet undefined.

Hypomethylation and ADA gene expression in mouse CAK cells

The adenosine deaminase (ADA) locus appears to be under complex transcriptional control since levels of ADA enzyme activity vary greatly between different tissues and stages of development. Evidence that a trans-acting factor may be involved with the regulation of this locus came from previous experiments where fusion of ADA-negative human JEG cells and mouse ADA-positive cells led to the trans-activation of human ADA in a hybrid nucleus. Here, we demonstrate that the near euploid mouse embryo fibroblast cell line, CAK, also lacks detectable ADA enzyme activity due to altered gene regulation. We further demonstrate that ADA in CAK cells is not amenable to activation by somatic cell fusion. Following treatment with 5-azacytidine and Xyl-A selection (for ADA), however, CAK clones were obtained that stably express the ADA gene. Molecular analysis of the parental CAK cells and the ADA-positive derivative clones demonstrated that both 5' and 3' regions of the ADA gene had become hypomethylated in the ADA+ clones. We conclude that methylation is another element involved with the transcriptional control of the ADA gene and that ADA might serve as a useful model for studying the interaction of cis- and trans-acting regulational elements.

Elevated erythrocyte adenosine deaminase activity in a patient with primary acquired sideroblastic anemia

We report a case of primary acquired sideroblastic anemia (PASA) associated with elevated erythrocyte adenosine deaminase (ADA) activity. The patient was an 85-year-old Japanese male. Analysis of the peripheral blood revealed pancytopenia, and the bone marrow findings showed marked ringed sideroblasts and chromosomal deletion (46XY, 11q-). The erythrocyte ADA activity was 17 times higher than that of normal control, the leukocyte ADA activity was within the normal range, and the plasma ADA activity was 2 times higher than the normal mean. The adenine nucleotides in the patient's erythrocytes were within normal range. According to starch gel electrophoresis, ADA isozyme of the patient was ADA 1. Western blotting showed an increased amount of ADA protein in the patient's erythrocytes. Southern blotting revealed no gene amplification or large structural change. Dot blot analysis of the reticulocyte mRNA showed no increase in the amount of ADA mRNA in the patient's reticulocytes compared with those of reticulocyte-rich controls. We considered that the mechanism of elevated ADA activity in this acquired defect was similar to that found in hereditary hemolytic anemia associated with ADA overproduction.

Mild hemophilia A associated with a cryptic donor splice site mutation in intron 4 of the factor VIII gene

Hemophilia A, an X-linked disease caused by deficiency of factor VIII, is characterized by variation in clinical severity and coagulation activity. This variation is though to reflect heterogeneity of mutations in the factor VIII gene. Here we describe a CG-to-CA mutation within a potential cryptic donor splice site in intron 4 of the factor VIII gene from a patient with mild disease. This mutation makes the cryptic sequence resemble more closely the consensus sequence for donor splice sites. We infer that the mutation activates the cryptic donor splice site, which in turn causes a defect in RNA processing.

Separation of human from mouse and monkey adenosine deaminase by ion-exchange chromatography following retroviral-mediated gene transfer

A method for the chromatographic separation of human adenosine deaminase (ADA) from murine and monkey ADA is described. This procedure was developed in order to detect the expression of low or moderate levels of human ADA following retroviral-mediated gene transfer of cloned human ADA gene sequences into both mouse and monkey cells. Protein separation was achieved on a Mono Q (HR 5/5) anion-exchange column using the Pharmacia fast protein liquid chromatography system and was found to be a highly reproducible method yielding enzymatically active protein. An increasing linear gradient extending from 0.05 to 0.5 M potassium chloride (pH 7.5) was used to elute the enzyme. Under these conditions, most human ADA does not bind to the column and elutes in the low-salt buffer (0.05 M KCl), while murine ADA elutes at 0.12 M KCl and monkey ADA at 0.15 M KCl. The column fractions were assayed for ADA activity, and the characteristic isozyme banding patterns for human, mouse, and monkey ADA were confirmed by starch gel electrophoresis. This procedure allows the rapid and reproducible separation of human ADA from that of other species and yields partially purified enzymatically active protein.

Structure of pre-pro-von Willebrand factor and its expression in heterologous cells

Von Willebrand factor (vWF), a multifunctional haemostatic glycoprotein derived from endothelial cells and megakaryocytes, mediates platelet adhesion to injured subendothelium and binds coagulation factor VIII in the circulation. Native vWF is a disulphide-bonded homopolymer; the monomeric subunits, of apparent relative molecular mass (Mr) 220,000 (220K) are derived from an intracellular precursor estimated at 260-275K. Multimer assembly is preceded by the formation of dimers, linked near their C-termini, which then assemble into filamentous polymers. The importance of the removal of the large vWF pro-polypeptide during multimer assembly, and whether this or other stages of the complex post-translational processing require components specific to endothelial cells or megakaryocytes, is unknown. Here we report an analysis of the complete sequence of pre-pro-vWF and expression of the molecule in heterologous cells. The vWF precursor is composed of several repeated subdomains. When expressed in COS and CHO cells, it is cleaved and assembled into biologically active high relative molecular mass disulphide bonded multimers. This suggests that the information for assembly of this complex molecule resides largely within its primary structure.

Isolation of mutant adenosine deaminase by coformycin affinity chromatography

Adenosine deaminase is a purine salvage enzyme that catalyzes the deamination of adenosine and deoxyadenosine. Deficiency of the enzyme activity is associated with T-cell and B-cell dysfunction. Mutant adenosine deaminase has been isolated from heterozygous and homozygous deficient lymphoblast cell lines with the aid of an affinity matrix consisting of coformycin (a potent inhibitor of the enzyme) as the affinity ligand, bound to 3,3'-iminobispropylamine-derivatized Sepharose. Routinely, 80-90% of adenosine deaminase in crude cell homogenates could be bound to the material. Adenosine deaminase was specifically eluted by enzyme inhibitors or less efficiently by high substrate concentrations. Protein preparations isolated from several different deficient cell lines were highly purified and exhibited molecular weights identical to wild-type adenosine deaminase. This method produces a protein that is suitable for structural studies.