Arrested development of embryonic red cell precursors in mouse embryos lacking transcription factor GATA-1.

The X chromosome-linked transcription factor GATA-1 is expressed specifically in erythroid, mast, megakaryocyte, and eosinophil lineages, as well as in hematopoietic progenitors. Prior studies revealed that gene-disrupted GATA-1- embryonic stem cells give rise to adult (or definitive) erythroid precursors arrested at the proerythroblast stage in vitro and fail to contribute to adult red blood cells in chimeric mice but did not clarify a role in embryonic (or yolk sac derived) erythroid cells. To examine the consequences of GATA-1 loss on embryonic erythropoiesis in vivo, we inactivated the GATA-1 locus in embryonic stem cells by gene targeting and transmitted the mutated allele through the mouse germ line. Male GATA-1- embryos die between embryonic day 10.5 and 11.5 (E10.5-E11.5) of gestation. At E9.5, GATA-1- embryos exhibit extreme pallor yet contain embryonic erythroid cells arrested at an early proerythroblast-like stage of their development. Embryos stain weakly with benzidine reagent, and yolk sac cells express globin RNAs, indicating globin gene activation in the absence of GATA-1. Female heterozygotes (GATA-1+/-) are born pale due to random inactivation of the X chromosome bearing the normal allele. However, these mice recover during the neonatal period, presumably as a result of in vivo selection for progenitors able to express GATA-1. Our findings conclusively establish the essential role for GATA-1 in erythropoiesis within the context of the intact developing mouse and further demonstrate that the block to cellular maturation is similar in GATA-1- embryonic and definitive erythroid precursors. Moreover, the recovery of GATA-1+/- mice from anemia seen at birth provides evidence indicating a role for GATA-1 at the hematopoietic progenitor cell level.

Purification of the human NF-E2 complex: cDNA cloning of the hematopoietic cell-specific subunit and evidence for an associated partner.

The human globin locus control region-binding protein, NF-E2, was purified by DNA affinity chromatography. Its tissue-specific component, p45 NF-E2, was cloned by use of a low-stringency library screen with murine p45 NF-E2 cDNA (N. C. Andrews, H. Erdjument-Bromage, M. B. Davidson, P. Tempst, and S. H. Orkin, Nature [London] 362:722-728, 1993). The human p45 NF-E2 gene was localized to chromosome 12q13 by fluorescent in situ hybridization. Human p45 NF-E2 and murine p45 NF-E2 are highly homologous basic region-leucine zipper (bZIP) proteins with identical DNA-binding domains. Immunoprecipitation experiments demonstrated that p45 NF-E2 is associated in vivo with an 18-kDa protein (p18). Because bZIP proteins bind DNA as dimers, we infer that native NF-E2 must be a heterodimer of 45- and 18-kDa subunits. Although AP-1 and CREB copurified with NF-E2, no evidence was found for heterodimer formation between p45 NF-E2 and proteins other than p18. Thus, p18 appears to be the sole specific partner of p45 NF-E2 in erythroid cells. Cloning of human p45 NF-E2 should permit studies of the role of NF-E2 in globin gene regulation and erythroid differentiation.

Beta-thalassemia due to two novel nucleotide substitutions in consensus acceptor splice sequences of the beta-globin gene.

We have identified two novel RNA-splicing mutations affecting a critical nucleotide (nt) in the acceptor consensus sequences at both the IVS-1/exon 2 and IVS-2/exon 3 junctions of the human beta-globin gene. Both mutations are single nt substitutions, T to G and C to A, at position -3 adjacent to the invariant AG dinucleotide. For the IVS-2/exon 3 mutation abnormal splicing into the cryptic splice site at IVS-2 nt 579 is documented. Identification of these two mutations provides further support for the importance of the location of specific nucleotides within the consensus sequences in splice site selection and RNA processing.

On the origin and spread of beta-thalassemia: recurrent observation of four mutations in different ethnic groups.

Seven beta-thalassemia genes were characterized after they were identified as candidates for previously undescribed mutations based upon the close association of DNA polymorphism haplotypes in the beta-globin gene cluster with specific ethnic mutations. The molecular defect in four of these genes was identical, a frameshift deletion of four nucleotides (-CTTT) within codons 41 and 42. This gene represents a common Southeast Asian mutation shared by a Laotian beta-thalassemia gene, [framework 1 (FR1)], a Vietnamese (FR1), and two Chinese patients (FR3 Asian and FR1). The deletion has been observed previously in Chinese (FR1) and Asian Indians (FR2) and is an example of independent origins of the same molecular defect, possible interallelic gene conversion (as it is seen on two different beta-globin gene frameworks in Chinese), and mutant gene migration in the Asian countries. A second example of mutant gene migration was identified in an Iranian patient with a nucleotide insertion (G) between codons 8 and 9, the same mutation previously found in an Asian Indian in the same chromosomal background. The last two genes examined represent further strong evidence for independent origins of mutation. A C-to-T substitution at position -88 in an Asian Indian has been identified previously in an American Black on a different beta-globin gene framework, and a G-to-A transition at nucleotide 1 of intervening sequence 2 found in an American Black has been observed previously on a different chromosome background in Mediterraneans. This study suggests that there are not many common beta-thalassemia mutations remaining to be discovered. It also suggests that certain sequences in the beta-globin gene are relatively mutation sensitive.

Cloning the gene for an inherited human disorder--chronic granulomatous disease--on the basis of its chromosomal location.

The gene that is abnormal in the X-linked form of the phagocytic disorder chronic granulomatous disease has been cloned without reference to a specific protein by relying on its chromosomal map position. The transcript of the gene is expressed in the phagocytic lineage of haematopoietic cells and is absent or structurally abnormal in four patients with the disorder. The nucleotide sequence of complementary DNA clones predicts a polypeptide of at least 468 amino acids with no homology to proteins described previously.

Characterization of a spontaneous mutation to a beta-thalassemia allele.

We have studied a nuclear family containing a single child with severe beta-thalassemia intermedia, a Greek-Cypriot mother with hematological findings of beta-thalassemia trait, and a Polish father who is hematologically normal. Since both the child and her father were heterozygous for a DNA polymorphism within the beta-globin gene, it was possible to clone and sequence the beta-globin gene identical by descent from both the child and her father. A nonsense mutation in codon 121 (GAA----TAA) was found in the beta-globin gene of the child, while the same gene from her father lacked this mutation and was normal. This mutation has not been previously observed among over 200 beta-thalassemia genes characterized in Caucasians. Since the mutation eliminates an EcoRI site in the beta-globin gene, we could show that the mutation is not present in genomic DNA of the father. To rule out germinal mosaicism, sperm DNA of the father was also digested with EcoRI, and the mutant EcoRI fragment was not observed under conditions that would detect the mutation if it were present in at least 2% of sperm cells. Routine HLA and blood group testing supported stated paternity. In addition, studies with 17 DNA probes that detect multiple allele polymorphisms increased the probability of stated paternity to at least 10(8):1. These data provide evidence that the G----T change in codon 121 of the beta-globin gene in the child is the result of a spontaneous mutation that occurred during spermatogenesis in a paternal germ cell.

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

Human adenosine deaminase (ADA) is an important purine catabolic enzyme which irreversibly deaminates adenosine and deoxyadenosine. Severe genetic deficiency of ADA leads to an immunological deficiency state in which T-lymphoid cells are selectively destroyed by the accumulation of toxic levels of deoxyadenosine and deoxy-ATP. In preparation for transfer of ADA sequences into a variety of cell types, we explored expression of ADA cDNAs transfected into cultured cells within a simian virus 40-based expression vector. After transfection into monkey kidney (COS) cells, ADA cDNA encompassing the entire coding region of the protein generated human ADA activity. An unexpected finding, however, was the identification of a cDNA clone that failed to produce either human enzyme activity or immunoreactive ADA protein. As this pattern is typical of many naturally occurring mutant ADA alleles, we characterized the molecular defect in this clone. DNA sequence analysis revealed a single nucleotide substitution in amino acid position 50 (glycine-valine). Northern blotting with a unique 17-mer oligonucleotide demonstrated the absence of the mutant sequence in the mRNA from which the cDNA library giving rise to the mutant cDNA was constructed. Therefore, the substitution in the variant cDNA was created during cloning. These data define one critical region of the human ADA protein molecule and suggest a convenient strategy for characterization of the phenotypes associated with naturally occurring mutant alleles.

Molecular characterization of seven beta-thalassemia mutations in Asian Indians.

To characterize systematically the mutations which produce beta-thalassemia in Asian Indians, we first determined the DNA polymorphism haplotype in the beta-globin gene cluster of 44 beta-thalassemia chromosomes in the ethnic group. Nine different haplotypes were observed. Upon molecular cloning and partial DNA sequencing of one beta-gene from each of eight haplotypes and two from the ninth, seven different mutations were found. None of these have been identified in Mediterranean patients, even among the five haplotypes which appeared identical in the two groups. Asian Indian mutations included one nonsense and three frameshift mutations, one deletion affecting an acceptor splice site, and two mutations affecting a donor splice site. The correlation of a specific mutation with a specific haplotype was high but not invariant. Two mutations were associated with more than one haplotype but, in each instance, the mutation spread to a new haplotype could be explained most simply by recombination 5' to the beta-globin gene. In addition, four mutations, one reported here and three others previously reported, have been observed on two chromosome backgrounds that are identical except for the status of a polymorphic HinfI site 5' to the beta gene. This HinfI site does not show significant linkage disequilibrium with markers both 5' and 3' to it, suggesting that it lies within a region of relative sequence randomization.

Molecular cloning of human adenosine deaminase gene sequences.

Using a mixture of synthetic 17-mer oligonucleotides encoding the 64 possible sequences for a peptide of adenosine deaminase as probe, we have isolated a clone for adenosine deaminase mRNA sequences from a collection of T-cell cDNA recombinants. This cDNA clone, phADA-1, contains an insert of 0.8 kilobase. In addition to the peptide chosen for synthesis of the oligonucleotide probe, the complete DNA sequence predicts 16 other experimentally determined peptides. Mapping of total cellular human DNAs with several restriction enzymes revealed relatively simple patterns of hybridization with phADA-1 as probe, including a polymorphism for PvuII cleavage. In agreement with previous studies, the adenosine deaminase gene was localized by blot hybridization to chromosome 20 in a hybrid cell mapping panel. Using the cDNA as probe, an 18-kilobase EcoRI fragment of human cellular DNA was also cloned in bacteriophage Charon 4A. These adenosine deaminase clones will prove valuable in the full characterization of the cellular gene, molecular analysis of inherited enzyme deficiency associated with immunodeficiency, and regional mapping of human chromosome 20.

ATA box transcription mutation in beta-thalassemia.

DNA sequence analysis of a cloned beta-globin gene from a Chinese patient with beta-thalassemia revealed a single nucleotide substitution (A leads to G) within the ATA box homology and 28 base pairs upstream from the cap site. The patient was homozygous for this particular allele based on restriction mapping at nine different polymorphic sites in the beta-globin gene cluster. Upon transient expression in HeLa cells this gene directed the production of 3-5-fold less beta-globin mRNA than the normal beta-gene. In RNA isolated from the patient's erythroid cells beta-RNA was 10-fold less abundant relative to alpha-RNA than normal, indicating close approximation of the heterologous cell expression results and the in vivo state. These findings support the validity of such transient expression assays for analysis of phenotypes associated with naturally occurring mutant genes and establish the functional significance of nucleotide substitutions at position -28 for human beta-globin gene transcription.

Inactivation of an acceptor RNA splice site by a short deletion in beta-thalassemia.

The cloned beta-globin gene of an Indian patient with beta-thalassemia revealed a 25-nucleotide deletion at the 3'-end of the first intervening sequence, including the acceptor RNA splicing site. RNA transcripts of this mutant gene produced following transfection into HeLa cells remained unspliced at both the first intervening sequence donor and acceptor sites. This beta-thalassemic gene is the first in which critical sequences of an acceptor splice junction are mutated and associated with abnormal RNA processing.

Abnormal RNA processing due to the exon mutation of beta E-globin gene.

As is typical of all beta-thalassaemias, the erythroid cells of individuals with the variant haemoglobin E (alpha 2 beta 2(26Glu leads to Lys)) exhibit a quantitative deficiency in their content of beta-globin (in this case beta E-globin) and its messenger RNA2,3. To determine the molecular basis of this phenotype, we have investigated the structure and expression of cloned beta E-globin genes. We report here that the complete nucleotide sequence of a beta E-gene revealed the expected GAG leads to AAG change in codon 26 but no other mutations. Expression of beta E-globin genes introduced into HeLa cells revealed two abnormalities of RNA processing: slow excision of intervening sequence-1 (IVS-1) and alternative splicing into exon-1 at a cryptic donor sequence within which the codon 26 nucleotide substitution resides. These results demonstrate a disturbance in the expression of the beta E-gene attributable solely to the exon mutation-a novel mechanism for gene dysfunction.

Evidence for multiple origins of the beta E-globin gene in Southeast Asia.

To investigate whether recurrent mutation has contributed to the high frequency of the beta E-globin gene in Southeast Asia, we used the haplotypes at three polymorphic restriction sites within and to the 3' side of the beta-globin gene to predict the framework of 23 beta E-globin genes. These haplotypes suggested that beta E-globin genes are present in two different beta-globin gene frameworks. DNA sequence determination of one gene representing each framework demonstrated that the same mutation (GAG leads to AAG at codon 26) was present in both frameworks. Moreover, the frameworks differed at three nucleotide positions known to be polymorphic in Mediterraneans. These polymorphic sites are located 70 nucleotides to the 5' side of the beta E mutation and 382 and 1032 nucleotides to the 3' side of it. The existence of the beta E mutation in these two beta-globin gene frameworks can be explained by (i) recurrent mutation giving rise to beta E-globin, (ii) a double crossing-over event, or (iii) two single crossing-over events. Mathematical analysis suggests that the first alternative, recurrent mutation of G leads to A at the first nucleotide of codon 26, is most likely.

Nonsense and frameshift mutations in beta 0-thalassemia detected in cloned beta-globin genes.

The molecular basis for deficiency of beta-globin synthesis in beta-thalassemia was investigated by gene cloning and DNA sequencing. beta-Globin genes of two patients with beta 0-thalassemia were cloned in a phage lambda vector. Both beta-genes transcribed normally in vitro. The gene of an Italian individual had a single nucleotide substitution (C leads to T) in the codon for amino acid 39 that resulted in formation of a nonsense codon. In a Turkish individual, the cloned beta-globin gene had a dinucleotide deletion in the codon for amino acid 8. This frameshift mutation produced a termination codon at the position of the new 21st codon. Mutations that lead to premature termination of beta-globin synthesis appear to be among the common causes of beta 0-thalassemia in man.

Mutation in an intervening sequence splice junction in man.

The alpha 2-globin gene of an individual with alpha-thalassemia associated with the absence of alpha 2 mRNA was cloned in bacteriophage. This mutant globin gene was normally active in transcription in vitro. The DNA sequence of the gene, however, revealed a pentanucleotide deletion within the 5' splice junction of the first intervening sequence. Following the G of the invariant G-T dinucleotide normally located within such junctions, a deletion of T-G-A-G-G was found. No other sequence abnormalities within the mutant gene were present. We speculate therefore that this deletion within the splice junction is the primary genetic defect in this individual with thalassemia and that loss of a functional splice junction results in failure of stable mRNA formation.

The duplicated human alpha-globin genes: their relative expression as measured by RNA analysis.

The human alpha-globin genes are duplicated and encode identical polypeptides. Recently we detected in cloned genomic DNAs characteristic sequence differences between the 3' untranslated regions of the 5' (alpha 2) and 3' (alpha 1) genes, not previously recognized by direct analysis of mRNA and cDNA transcripts. Based on these untranslated region differences, we have now used S1 nuclease mapping of RNA to detect and quantitate the two predicted alpha-mRNA species. With this assay we have examined the relative expression of the alpha-globin genes during normal development and in alpha-thalassemia syndromes. In normal adult reticulocytes, alpha 2 RNA is slightly more abundant than the alpha 1 species (ratio 60:40). This relative abundance of the alpha RNAs was consistently observed in fetal blood and liver RNA samples from 10 weeks of gestation to birth. In both deletion and nondeletion forms of alpha thalassemia, only the alpha 1 RNA and establish the normal pattern of relative alpha-gene expression during development independent of protein variants. RNA analysis also permits for the first time identification of the mutant genes in nondeletion forms of thalassemia.

Heterogeneity of DNA deletion in gamma delta beta-thalassemia.

By restriction endonuclease mapping, gene cloning, and DNA sequencing we have determined the region of DNA that is deleted in a family with gamma delta beta-thalassemia. The deletion removes the linked epsilon, gamma-, and delta-globin structural genes and terminates within the coding portion of the beta-globin gene. Since the extent of DNA deletion in this family differs from that reported in another family, we conclude that gamma delta beta-thalassemia is heterogeneous at the molecular level.

Chemical evidence for the separation of G gamma and A gamma globin chains by polyacrylamide gel electrophoresis in urea and Triton X-100.

Polyacrylamide gel electrophoresis in urea and Triton X-100 of a hemolysate from human fetal blood cells produces four major protein bands: alpha, beta, and 2 gamma globin chains. We have verified that the latter two are the G gamma and A gamma globin chains which have respectively glycine or alanine at position 136. After incorporation of either [3H] alanine or [3H] glycine into newly synthesized globin each gamma chain was isolated by preparative electrophoresis. The chains were cleaved with cyanogen bromide at methionines 55 and 133, then subjected to automated sequencing and the residues from each sequencer turn counted. Glycine incorporation was detected for the third turn (position 136) of the G gamma chain and alanine for the A gamma. Substantial metabolic conversion of [3H] glycine to serine and proline was also noted.