Detection of a restriction site polymorphism within the human α-globin gene complex

Summary A mutant RsaI restriction endonuclease site of high frequency has been identified in individuals of German, Greek, Italian, and Turkish origin. The mutation was found within the -globin gene complex and is located 0.7 kb 5 to the -globin gene. In individuals of central European origin 34 out of 58 chromosomes exhibited the -gene linkage to the presence of the polymorphic site, and thus a preliminary estimate of the gene frequency for this allele would be 0.59. DNA analysis data of individuals derived from Mediterranean populations indicate a distribution of this polymorphic marker in similar frequencies.     

Nucleotide sequence of the humanθ 1-globin gene

We have cloned and sequenced the human ₁-globin gene. The nucleotide sequence and organization of the human ₁ gene (exons, introns, promoter, and polyadenylation signals) are similar to those reported for the orangutan ₁-globin gene. If these genes are functional, the sequences of their ₁-globin chains would differ by only one amino acid residue (at position 137).This research was supported by USPHS Research Grants HLB-05168 and HLB-15158. This is contribution No. 1085 from the Department of Cell and Molecular Biology at the Medical College of Georgia in Augusta.     

The primary structure of the human ϵ-globin gene

We describe the complete nucleotide sequence of the human ?-globin gene including 387 nucleotides of 5′ flanking sequence and 301 nucleotides of 3′ flanking sequence. The arrangement of coding, noncoding and intervening sequences in this gene is entirely consistent with its identification as the embryonic β-like globin gene.     

The evolution of the α- and β-globin gene clusters in human populations

Summary DNA analysis of the - and -globin gene clusters has revealed substantial variability between individuals and populations. As well as restriction enzyme site and length polymorphisms, variation in gene copy number and type is observed. Because of this extensive polymorphism DNA analysis offers a highly informative method of studying genetic affinities between human populations. Haplotypes, consisting of a set of restriction enzyme polymorphisms distributed along the cluster, have been developed for both loci. Analysis of the molecular basis of numerous -thalassaemia alleles has revealed, in general, different sets of mutations in different populations, indicating that these postdate the racial divergence. Recent microepidemiological studies on the distribution of -thalassaemia support the hypothesis that this condition, like the {ie16-1}, has been selected because it confers protection against malaria. Population-specific DNA polymorphisms at these and other loci promise to be of considerable value to genetic anthropology.     

Contribution of gene conversion in the evolution of the human β-like globin gene family

Gene conversion is referred to as one of two types of mechanisms known to act on gene families, mainly to maintain their sequence homogeneity or, in certain cases, to produce sequence diversity. The concept of gene conversion was established 20 years ago by researchers working with fungi. A few years later, gene conversion was also observed in the human genome, i.e. the γ-globin locus. The aim of this article is to emphasize the role of genetic recombination, particularly of gene conversion, in the evolution of the human β-like globin genes and further to summarize its contribution to the convergent evolution of the fetal globin genes. Finally, this article attempts to re-examine the origin and spread of specific mutations of the β-globin cluster, such as the sickle cell or β-thalassemia mutations, on the basis of repeated gene conversion events. Received: 13 February 1997 / Accepted: 15 May 1998     

Heterogeneity of the α-globin gene defects in German α-thalassemia affected families

Summary Analysis of -thalassemia syndromes in several German families revealed DNA deletion as well as nondeletion forms as the molecular basis for the defects. Thus, the -thalassemia haplotype was identified as the (–)^3.7 rightward deletion form, and the region of the putative recombination process generating such a deletion was further characterized. In addition three different ° haplotypes, (--)^MED, (--)^>26, and ()^T, could be detected using -and -globin gene-specific probes.     

Electrophoretic and chromatographic evidence for allelic polymorphisms in the river buffalo α-globin gene complex

Isoelectric focusing in the ultranarrow immobilized (7.1–7.5) pH gradient (IPG) of hemoglobin and high-performances liquid chromatography (HPLC) of globin chains were used to investigate Hb polymorphism in Italian river buffalo. Six different phenotypes, each characterized by two or four different Hbs, were detected by IPG, whereas two different^IIα-globin chains were separated from two different^Iα-chains by HPLC. Two α-chains (^Iα¹ and^IIα³), and Hbs with similar mobilities (Hb1 andHb3), were associated with the AA Hb phenotype: two α-chains (^Iα² and^IIα⁴), and Hbs with different mobilities (Hb2 andHb4), were associated with the BB phenotype: two sets of doublet Hbs were associated with the AB phenotype, thus suggesting allelic polymorphisms at the two α loci. An allele at the β locus is responsible for increasing to as many as eight the number of different Hbs, thus further complicating the notable Hb polymorphism of the river buffalo.     

Genomic rearrangement of the α-globin gene complex during mammalian evolution

In man, the gene for hydroxyacyl glutathione hydrolase (HAGH; glyoxalase II) is closely linked to the α-globin locus (HBα) on Chromosome 16. HAGH polymorphism in the mouse has now enabled the mapping of the murine homologue. Deletion mapping, congenic strain studies, and characterization of 41 recombinant inbred strains establish that the mouseHagh locus lies very close to the α-globin pseudogene (Hba-ps4) in the vicinity of the major histocompatibility locus (H-2) on chromosome 17. Several other loci have been identified previously that are also closely linked to the human α-globin locus but near the α-globin pseudogeneHba-ps4 in the mouse. These linkage relationships suggest that during the evolution of mice a translocation occurred that subdivided the α-globin locus, leaving one inactive α-globin gene still associated with theHagh locus and linked sequences, while moving and inserting the active α-globin locus and all distal sequences into an internal location on another autosome, the predecessor to mouse chromosome 11.     

Genomic organization of the complex α-gliadin gene loci in wheat

To better understand the molecular evolution of the large -gliadin gene family, a half-million bacterial artificial chromosome (BAC) library clones from tetraploid durum wheat, Triticum turgidum ssp. durum (2n=4x=28, genome AB), were screened for large genomic segments carrying the -gliadin genes of the Gli-2 loci on the group 6 homoeologous chromosomes. The resulting 220 positive BAC clones—each containing between one and four copies of -gliadin sequences—were fingerprinted for contig assembly to produce contiguous chromosomal regions covering the Gli-2 loci. While contigs consisting of as many as 21 BAC clones and containing up to 17 -gliadin genes were formed, many BAC clones remained as singletons. The accuracy of the order of BAC clones in the contigs was verified by Southern hybridization analysis of the BAC fingerprints using an -gliadin probe. These results indicate that -gliadin genes are not evenly dispersed in the Gli-2 locus regions. Hybridization of these BACs with probes for long terminal repeat retrotransposons was used to determine the abundance and distribution of repetitive DNA in this region. Sequencing of BAC ends indicated that 70% of the sequences were significantly similar to different classes of retrotransposons, suggesting that these elements are abundant in this region. Several mechanisms underlying the dynamic evolution of the Gli-2 loci are discussed.     

Altitudinal variation at duplicated β-globin genes in deer mice: effects of selection, recombination, and gene conversion

Spatially varying selection on a given polymorphism is expected to produce a localized peak in the between-population component of nucleotide diversity, and theory suggests that the chromosomal extent of elevated differentiation may be enhanced in cases where tandemly linked genes contribute to fitness variation. An intriguing example is provided by the tandemly duplicated β-globin genes of deer mice (Peromyscus maniculatus), which contribute to adaptive differentiation in blood-oxygen affinity between high- and low-altitude populations. Remarkably, the two β-globin genes segregate the same pair of functionally distinct alleles due to a history of interparalog gene conversion and alleles of the same functional type are in perfect coupling-phase linkage disequilibrium (LD). Here we report a multilocus analysis of nucleotide polymorphism and LD in highland and lowland mice with different genetic backgrounds at the β-globin genes. The analysis of haplotype structure revealed a paradoxical pattern whereby perfect LD between the two β-globin paralogs (which are separated by 16.2 kb) is maintained in spite of the fact that LD within both paralogs decays to background levels over physical distances of less than 1 kb. The survey of nucleotide polymorphism revealed that elevated levels of altitudinal differentiation at each of the β-globin genes drop away quite rapidly in the external flanking regions (upstream of the 5' paralog and downstream of the 3' paralog), but the level of differentiation remains unexpectedly high across the intergenic region. Observed patterns of diversity and haplotype structure are difficult to reconcile with expectations of a two-locus selection model with multiplicative fitness.     

Tetra-/di-nucleotide repeat polymorphism upstream of the human α2-globin gene locus at 16p13.3

A highly polymorphic tetra-/di-nucleotide repeat sequence was identified upstream of the human α2/α1-globin gene pair on chromosome 16p13.3. This microsatellite marker should be useful in α-thalassemia genotype phenotype correlations and in respective population genetics studies.     

Locus assignment of human α-globin structural mutants by selective enzymatic amplification of α1 and α2-globin cDNAs

Summary We have used the powerful methodology of DNA enzymatic amplification in order to assign human -globin structural mutants to one of the two highly homologous -globin genes. Selectively amplified 1 and 2-globin cDNAs were dot-blotted and further hybridized to synthetic oligonucleotides encompassing either the normal or the mutated sequences. The generated signals corresponded specifically to one of the two -globin genes. Using this approach the -globin structural mutants J-Buda and G-Pest were found to be encoded by the 2 and the 1-globin genes, respectively. Furthermore, the exact nucleotide changes were determined. We propose this technique to serve as a simple and definitive method for assigning -globin structural mutants.     

The association of the human ε-globin gene with the nuclear matrix: a reconsideration

The association of the human -globin gene with the nuclear matrix was studied in erythroid and non-erythroid cell lines. Using a high salt method to prepare histone depleted nuclei we studied the association of variety of fragments covering a 7.8 kb region which contains the human -globin gene. We furthermore studied the association of a set of DNA fragments covering the 13 kb human G/A-globin gene domain, the 16 kb /-globin gene domain and the 10 kb -globin gene domain with the nuclear matrix of K562 and Raji cells. The results show that all fragments studied are easily released from the nuclear matrix, indicating no specific association.Summarizing our results we could say that a region starting 5.7 kb 5 to the human -globin gene and ending 4 kb 3 to the human -globin gene seems to contain no attachment sites with the nuclear matrix of both erythroid and non-erythroid cells.