Organization of human δ- and β-globin genes in cellular DNA and the presence of intragenic inserts

We have analyzed human cellular DNA for its δ- and β-globin gene sequence content by separation of restriction enzyme fragments by agarose gel electrophoresis; transfer of the DNA fragments to nitrocellulose filters; hybridization of filters with ³²P-β-globin cDNA; and analysis by autoradiography. A short cDNA has been used to identify specifically the 3′ end of the genes and to orient the fragments. A comparison of the globin gene fragments generated by normal and Lepore DNA has been used to distinguish fragments representing DNA sequences between the δ and β genes and those containing sequences flanking either 5′ to the δ gene or 3′ to the β gene. The results indicate that unique restriction fragments are presented in normal DNA and absent in Lepore DNA, and allow preliminary ordering of these fragments on a restriction enzyme map. In addition, the Lepore, δ- and β-globin genes have been found to contain at least one inserted nucleotide sequence of about 1000 bases which is not represented in mature globin mRNA.     

Linkage of adult α- and β-globin genes in X. laevis and gene duplication by tetraploidization

We have used cloned adult X. laevis α- and β-globin cDNAs to analyze globin genes in X. laevis DNA. We detected α¹- and β¹-globin genes which contain intervening sequences and code for the major adult globins, plus additional diverged α²- and β²-globin genes of unknown coding potential. Unlike the case in mammals, the X. laevis α¹- and β¹-globin genes are closely linked and occur in the sequence 5′-α¹-9 kb-β¹-3′. The α²- and β²-globin genes are also linked, and analysis of globin genes in X. tropicalis suggests that this duplication of an α-β-globin gene pair in X. laevis is the result of chromosome duplication by tetraploidization. The close linkage of α- and β-globin genes in Xenopus provides evidence that vertebrate α- and β-globin genes evolved by tandem duplication of a single primordial globin gene.     

DNA sequence variants in the G gamma-, A gamma-, delta- and beta-globin genes of man

DNA prepared from 60 unrelated individuals was cleaved with one of eight different restriction endonucleases and the resulting DNA fragments were separated by agarose gel electrophoresis. DNA fragments containing G gamma-, A gamma-, delta- or beta-globin genes were detected by Southern blot hybridization, using as probe either a 32P-labeled cloned DNA copy of rabbit beta-globin messenger RNA or labeled human beta- and G gamma- globin cDNA plasmids. Three types of variant restriction enzyme patterns of globin DNA fragments were detected in otherwise normal individuals. One variant pattern, found in only one person, was caused by an additional restriction endonuclease Pst I cleavage site in the center of the delta- globin gene intervening sequence; the subject was heterozygous for the presence of this cleavage site and was shown to have inherited it from her mother. Another variant pattern resulted from the appearance of an endonuclease Hind III cleavage site in the intervening sequence of the A gamma-globin gene; this variant is polymorphic, with a gene frequency for the presence of the intragenic Hind III site of 0.23. This Hind III cleavage site polymorphism is also found in the G gamma-globin gene intervening sequence and thus the polymorphism itself appears to be duplicated over the pair of gamma-globin loci. These variants can be used to derive an approximate estimate of the total number of different DNA sequence variants in man.     

Amino Acid Sequence of Kalinowaski's Tinamou (Nothoprocta Kalinowskii) Hemoglobin and the Rate of Evolution of Bird αD-Globin

Two hemoglobin components are recognized in erythrocytes of the adult Tinamou. We determined the amino acid sequences of Tinamou α^D-, α^A-, and β-globins from intact globin chains and several chemically cleaved fragments. A remarkable feature of Tinamou hemoglobin was a deletion in the α^D-globin chain. This has not been reported in the literature, except in pigeon embryonic α^D-globin. The amino acid sequences of Tinamou globin were highly similar to those of Ostrich and Rhea hemoglobin. Comparison between Tinamou, Ostrich, and Rhea that suggested the evolution speed of globin, α^D = α^A > β, was related with the early appearance birds. The important residues in Tinamou hemoglobin as the heme contact and oxygen binding regions were highly conserved in other species.     

Absence of messenger RNA and gene DNA for β-globin chains in hereditary persistence of fetal hemoglobin

The relative amounts of α- and β-globin mRNA and globin gene DNA were measured in reticulocyte RNA and lymphocyte DNA of an individual with homozygous hereditary persistence of fetal hemoglobin whose red blood cells contain 100% fetal hemoglobin (Hb F: α₂γ₂). Molecular hybridization assays used as probes full-length DNA copies of human α- and β-globin messenger RNA. The results of these hybridization assays demonstrated the expected amounts of α-globin mRNA and gene DNA, but absence of β-globin mRNA and absence of β-globin gene DNA. In the individual studied, hereditary persistence of fetal hemoglobin is associated with total deletion of the β-globin structural gene.     

Localization of the human alpha-globin structural gene to chromosome 16 in somatic cell hybrids by molecular hybridization assay

We have used 16 human × mouse somatic cell hybrids containing a variable number of human chromosomes to demonstrate that the human α-globin gene is on chromosome 16. Globin gene sequences were detected by annealing purified human α-globin complementary DNA to DNA extracted from hybrid cells. Human and mouse chromosomes were distinguished by Hoechst fluorescent centromeric banding, and the individual human chromosomes were identified in the same spreads by Giemsa trypsin banding. Isozyme markers for 17 different human chromosomes were also tested in the 16 clones which have been characterized. The absence of chromosomal translocation in all hybrid clones strongly positive for the α-globin gene was established by differential staining of mouse and human chromosomes with Giemsa 11 staining. The presence of human chromosomes in hybrid cell clones which were devoid of human α-globin genes served to exclude all human chromosomes except 6, 9, 14 and 16. Among the clones negative for human α-globin sequences, one contained chromosome 2 (JFA 14a 5), three contained chromosome 4 (AHA 16E, AHA 3D and WAV R4D) and two contained chromosome 5 (AHA 16E and JFA14a 13 5) in >10% of metaphase spreads. These data excluded human chromosomes 2, 4 and 5 which had been suggested by other investigators to contain human globin genes. Only chromosome 16 was present in each one of the three hybrid cell clones found to be strongly positive for the human α-globin gene. Two clones (WAIV A and WAV) positive for the human α-globin gene and chromosome 16 were counter-selected in medium which kills cells retaining chromosome 16. In each case, the resulting hybrid populations lacked both human chromosome 16 and the α-globin gene. These studies establish the localization of the human α-globin gene to chromosome 16 and represent the first assignment of a nonexpressed unique gene by direct detection of its DNA sequences in somatic cell hybrids.     

Identification of the Hind III polymorphic site in the PAI-1 gene: analysis of the PAI-1 Hind III polymorphism by PCR

The identification of the Hind III polymorphic site in the 3' end of the plasminogen activator inhibitor 1 (PAI-1) gene and a simple method to identify the Hind III polymorphism rapidly in the PAI-1 gene using PCR is described. The Hind III restriction site was identified by restriction site mapping and sequence analysis from a cosmid DNA clone. Genomic DNA was isolated from individual human umbilical cords and a 754-bp fragment of the human PAI-1 gene was amplified by PCR. Aliquots of the PCR products were digested with Hind III and analyzed by agarose gel electrophoresis. The presence of two fragments, 754 and 567 bp, was identified, and they were designated as 1/1 (750-bp band), 1/2 (754- and 567-bp bands), and 2/2 (567-bp band). The PCR method is considerably less time consuming than the conventional DNA genotyping using Southern blot analysis. To ensure that this new method identified the same PAI-1 genotypes as previously identified by Hind III restriction fragment length polymorphism (RFLP), samples were simultaneously genotyped by PCR and Southern blot analysis. Both methods identified the same Hind III genotypes in all the samples, confirming the reliability of this new PCR method for the rapid identification of the Hind III polymorphism in the human PAI-1 gene.     

The binding of exogenous DNA fragments to bovine spermatozoa

Abstract

The ability of mature, freeze‐thawed bovine sperm to bind exogenous end‐labelled or oligo‐labelled λ Hind III DNA restriction fragments was examined. Following 30 min. incubation of bovine sperm with P³² end‐labelled λ Hind III DNA and five washes with medium, approximately 5.8 ng DNA were bound to 10⁷ sperm. Agarose gel autoradiography revealed that all of the λ Hind III DNA bands were present following sperm washes except for the smaller 0.5 Kb and 0.125 Kb bands. Incubation of sperm with ³H oligo‐labelled λ Hind III DNA gave a much higher level of binding (138 ng/10⁷ sperm) than that found with end‐labelled DNA. This binding was entirely eliminated by DNase I. The separation of live and dead sperm fractions on Percoll gradients revealed that more oligo‐labelled λ Hind III DNA was found to be associated with the dead sperm fraction (31.2 ng/10⁷ sperm) rather than the live sperm fraction (2.7 ng/10⁷ sperm). Analysis of supravital stained, light microscopic autoradiographs confirmed that oligo‐labelled λ Hind III DNA bound to dead sperm in the post‐acrosomal region of the sperm head although other minor distribution patterns were observed.     

Synergistic effect of two β globin gene cluster mutations leading to the hereditary persistence of fetal hemoglobin (HPFH) phenotype

Co-inheritance of gamma and beta globin gene mutations in a compound heterozygous state is rare but of clinical interest as it provides an important data on understanding the HbF expression. Hematological analysis was carried out (Sysmex KX-21). F-cells were enumerated using flow cytometry. Beta globin gene was analysed by CRDB technique and by DNA sequencing. Gamma globin promoter region was sequenced and expression studies were carried out using real time Taqman assay. We report a family, where two inherited defects of the β globin gene cluster segregate. The proband and her sibling were compound heterozygotes for a novel ^Gγ promoter mutation and the 619 bp deletion a common Indian β thalassemia mutation. Molecular characterization revealed that the father (HbA₂ 5.1%, HbF 5.4%), proband (HbA₂ 3.6%, HbF 31.7%) and her brother (HbA₂ 3.9%, HbF 23.6%) were heterozygous for the 619 bp deletion. The mother (HbA₂ 2.1%, HbF 3.4%) had a normal β globin gene. As both the children showed high HbF levels, the γ globin gene work up was carried out. The ^Gγ-globin gene promoter analysis revealed that the mother and the two children were heterozygous for a 5 bp deletion -ATAAG (-533 to -529) that resides in the GATA binding site. These findings suggest that the 5 bp deletion in the ^Gγ globin promoter has a functional role in silencing the γ-globin gene expression in adults by disrupting GATA-1 binding and the associated repressor complex and results in the up-regulation of gamma globin gene expression. When co-inherited with β -thalassemia trait it leads to a phenotype of HPFH.     

Evolution of the β-globin gene cluster in man and the primates

The arrangement of primate β-related globin genes has been determined by restriction endonuclease mapping of genomic DNA from species ranging from prosimians to man. The arrangement of the entire ?γγδβ-globin gene cluster in the gorilla and the yellow baboon is indistinguishable from that of man. Restriction site differences between these species are consistent with a surprisingly low overall rate of intergenic DNA sequence divergence of approximately 1% in 5 million years. A new world monkey (owl monkey) has a single γ-globin gene, suggesting that the ^Gγ-^Aγ-globin gene duplication in man is ancient, and occurred about 20 to 40 million years ago. The β-globin gene cluster in the brown lemur, a prosimian, is remarkably short (about 20,000 base-pairs) and contains single ?-, γ- and β-globin genes. The γ- and β-globin genes in this animal are separated by a curious gene containing the 3′ end of a β-globin gene preceded by sequences related to the 5′ end of the ?-globin gene.     

The rabbit beta-globin gene contains a large large insert in the coding sequence

We have used the rabbit β-globin DNA plasmid PβG1 (Maniatis et al., 1976) labeled with ³²P as a filter hybridization probe for DNA fragments containing the β-globin gene in restriction endonuclease digests of rabbit liver DNA. The β-globin DNA fragments we detect appear to contain the gene, present in PβG1 DNA, which codes for adult rabbit β-globin. These fragments have been ordered into a physical map of cleavage sites within and neighboring the structural gene in the rabbit genome (Jeffreys and Flavell, 1977). A detailed analysis of β-globin DNA fragments produced by cleavage with restriction endonucleases which are known to cut the β-globin gene has now shown that the β-globin structural gene is not contiguous in rabbit liver DNA, but is interrupted by a 600 base pair DNA segment inserted somewhere within the coding sequence for amino acid residues 101–120 of the 146 residue β-globin chain. Otherwise, the map of cleavage sites within the gene is co-linear with that deduced from the sequence of rabbit β-globin messenger RNA. Preliminary analysis indicates that this insert is also present in the β-globin gene in rabbit brain, kidney, spleen, bone marrow and sperm, and in erythroid cells isolated from the marrow of an anemic rabbit. The insert appears, therefore, to be a general property of the rabbit β-globin gene, even in tissues in which this gene is active, which suggests that the insert is not involved in inactivating the gene in nonerythroid tissues.     

The Primary Structure of β<Superscript>I</Superscript>-Chain of Hemoglobin from Snake Sindhi Krait (<Emphasis Type="Italic">Bungarus sindanus sindanus</Emphasis>)

The amino acid sequence of β^I-globin chain from Sindhi Krait (Bungarus sindanus sindanus) was determined to study the molecular evolution among snakes. The hemoglobin was isolated from the red blood cells and was analyzed by ion-exchange chromatography (IEX). The crude globin was subjected to reversed phased-high performance liquid chromatography (RP-HPLC) using C4 column. The N-terminal sequences of intact globin chains and tryptic peptides were determined by Edman degradation in a pulsed liquid gas phase sequencer using an online Phenylthiohydantoin analyzer. Sindhi Krait is expected to express three hemoglobin components that are composed of β^II, β^I, α^D and α^A-globin chains, as apparent by IEX, RP-HPLC and N-terminal sequence analyses. Sequence alignment and phylogenetic analyses of β^I globin chain from Sindhi Krait showed closest relationship with β^I globin chain from Rattlesnake, Water snake and Indigo snake. Interestingly, comparison of primary sequence of β^I globin chain of Sindhi Krait with human β chain revealed 63 % similarity along with the retention of all heme contact points. Variations among the two sequences were prominent at αβ contact points and in regions directly not important for function.     

Molecular spectrum of α-thalassemia mutations in Erbil province of Iraqi Kurdistan

α-Thalassemia is a globally prevalent genetic disorder of hemoglobin (Hb) structure where the rate of α-globin chain synthesis is reduced or absent based on the underlying α-globin mutation(s). This study aimed to define the spectrum of α-globin gene mutations and assess their relative frequency within a group of α-thalassemia carriers. A total of 96 young subjects with unexplained hypochromia and microcytosis were recruited. They were referred from the premarital hemoglobinopathy screening and genetic counseling center in Erbil. All subjects were genetically tested for 21 common α-globin gene mutations using multiplex PCR and reverse hybridization. Six different α-globin gene mutations and nine different genotypes were detected in 84 carrier subjects. Their mean Hb was 12.9 (±?1.29) g/dL, of whom 49 subjects (58.3%) had a normal Hb level. The two most frequently encountered mutations were -α^3.7 deletion (62.86%) and α2^?5nt mutation (20%). Deletions were encountered in 71.43% of the mutated alleles. The most commonly observed genotype was -α^3.7/αα (46.43%), followed by -α^3.7/-α^3.7 and α^?5ntα/αα genotypes (10.72% each). Carriers of α^poly-A1α/αα and -α^3.7/-α^?5ntα genotypes showed significantly lower Hb, mean cell volume, and mean cell Hb values comparing to carriers of most other genotypes. In our population, the spectrum of α-globin mutations was confined to a limited number of mutations with deletions being mostly observed.