Structure of the mouse 3-Methyladenine DNA Glycosylase gene and exact localization upstream of the α-globin gene cluster on Chromosome 11

In this paper we describe the genomic organization of the mouse 3-Methyladenine DNA Glycosylase (MPG) gene and localize three putative regulatory elements around this gene. The MPG gene plays a key role in the excision repair of methylated adenine residues and has been localized upstream of the -globin gene cluster in human and mouse. The human MPG gene has been fully characterized, whereas up to now only the cDNA sequence of the mouse MPG gene had been published. Here, we describe a detailed restriction map, the intron/exon structure, the CpG-rich putative promoter sequence, and the exact localization of the mouse MPG gene with respect to the murine -globin gene cluster. Our analysis reveals a remarkable different exon/intron structure of the mouse MPG gene compared with its human homolog. Two prominent DNase hypersensitive sites (HSS) were found 0.1 and 1.5 kb upstream of the coding sequence. In addition to these elements, an erythroid prominent HSS was mapped at the intron/exon boundary of the last exon. The characterization and localization of the MPG gene in mouse makes it now possible to carry out transgenic and gene targeting experiments and are essential to understand the control of gene expression of the MPG gene in particular and of the whole region in general.The nucleotide sequence data reported in this paper will be submitted to Genbank.     

Anti-ζ Antibody Screening for α-Thalassemia Using Dried Filter Paper Blood

The most common α-thalassemia in Southeast Asian or Southern Chinese populations is the (- -^SEA) double α-globin deletion. Couples heterozygous for (- - ^SEA) have 25% risk for hydrops fetalis from loss of all four α-globin genes. The (- -^SEA) deletion spares the embryonic ζ-globin genes and causes traces of ζ-peptide to persist throughout life. A colorimetric monoclonal anti-ζ antibody test for raised ζ-peptide has detected the (- -^SEA) deletion in liquid blood samples, but not deletions of the entire α-globin region with loss of the ζ-globin genes. Eluates from dried blood spots had the same anti-ζ antibody color reaction as whole blood, even after storage at 4°C for up to 77 days. The anti-ζ antibody test was positive in 24 of 91 microcytic samples (mean corpuscular hemoglobin <24 pg), including four with iron deficiency; it was negative in 26 provisionally diagnosed α-thalassemia-1 heterozygotes and all 32 nonmicrocytic samples. Southern blot analysis and a specific SEA-polymerase chain reaction test confirmed that 18 anti-ζ antibody-positive samples and 1 anti-ζ antibody-negative sample had the (- -^SEA) deletion. Two anti-ζ antibody-negative microcytic samples had the (- -^Fil) total α-globin region deletion, 2 had single α-gene deletions, 22 others may also have had a total α-region deletion. Hence specificity was very high and sensitivity was 95%. The anti-ζ antibody test can detect the (- -^SEA) deletion in dried blood samples, even after prolonged storage. This simple inexpensive test can conveniently screen samples collected at a distance from a central laboratory.     

Main regulatory element (MRE) of the <Emphasis Type="Italic">Danio rerio</Emphasis> α/β-globin gene domain exerts enhancer activity toward the promoters of the embryonic-larval and adult globin genes

In warm-blooded vertebrates, the α- and β-globin genes are organized in domains of different types and are regulated in different fashion. In cold-blooded vertebrates and, in particular, the tropical fish Danio rerio, the α- and β-globin genes form two gene clusters. A major D. rerio globin gene cluster is in chromosome 3 and includes the α- and β-globin genes of embryonic-larval and adult types. The region upstream of the cluster contains c16orf35, harbors the main regulatory element (MRE) of the α-globin gene domain in warm-blooded vertebrates. In this study, transient transfection of erythroid cells with genetic constructs containing a reporter gene under the control of potential regulatory elements of the domain was performed to characterize the promoters of the embryonic-larval and adult α- and β-globin genes of the major cluster. Also, in the 5th intron of c16orf35 in Danio rerio was detected a functional analog of the warm-blooded vertebrate MRE. This enhancer stimulated activity of the promoters of both adult and embryonic-larval α- and β-globin genes.     

High-resolution analysis of cis-acting regulatory networks at the α-globin locus

We have combined the circular chromosome conformation capture protocol with high-throughput, genome-wide sequence analysis to characterize the cis-acting regulatory network at a single locus. In contrast to methods which identify large interacting regions (10–1000 kb), the 4C approach provides a comprehensive, high-resolution analysis of a specific locus with the aim of defining, in detail, the cis-regulatory elements controlling a single gene or gene cluster. Using the human α-globin locus as a model, we detected all known local and long-range interactions with this gene cluster. In addition, we identified two interactions with genes located 300 kb (NME4) and 625 kb (FAM173a) from the α-globin cluster.     

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.     

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.     

pAO1 of Arthrobacter nicotinovorans and the Spread of Catabolic Traits by Horizontal Gene Transfer in Gram-Positive Soil Bacteria

The 165-kb megaplasmid pAO1 of Arthrobacter nicotinovorans carries two large gene clusters, one involved in nicotine catabolism (nic-gene cluster) and one in carbohydrate utilization (ch-gene cluster). Here, we propose that both gene clusters were acquired by A. nicotinovorans by horizontal gene transfer mediated by pAO1. Protein–protein blast search showed that none of the published Arthrobacter genomes contains nic-genes, but Rhodococcus opacus carries on its chromosome a nic-gene cluster highly similar to that of pAO1. Analysis of the nic-genes in the two species suggested a recombination event between their nic-gene clusters. Apparently, there was a gene exchange between pAO1, or a precursor plasmid, and a nic-gene cluster of an as yet unidentified Arthrobacter specie or other soil bacterium, possibly related to Rhodococcus, leading to the transfer by pAO1 of this catabolic trait to A. nicotinovorans. Analysis of the pAO1 ch-gene cluster revealed a virtually identical counterpart on the chromosome of Arthrobacter phenanthrenivorans. Moreover, the sequence analysis of the genes flanking the ch-gene cluster suggested that it was acquired by pAO1 by Xer-related site directed recombination and transferred via the plasmid to A. nicotinovorans. The G+C content, the level of sequence identity, gene co-linearity of nic- and ch-gene clusters as well as the signs of recombination events clearly supports the notion of pAO1 and its precursor plasmids as vehicles in HGT among Gram + soil bacteria.     

Complete nucleotide sequence of a chicken α-globin cDNA

The entire sequence of a 541 bp insert in recombinant plasmid pHb1003 has been determined. This plasmid, which was shown to carry a cloned cDNA copy of the chicken α-globin mRNA, contains the complete structural gene as well as 19 bp of the 5'-untranslated region and 99 bp of the 3'-untranslated region. This sequence may encode a non-adult α-globin gene, especially since the cDNA clones were generated from phenylhydrazine-induced, globin-specific mRNA extracted from anemic white leghorns. The possibility that this α-globin might represent a stress globin is considered.     

Genome scan identifies a locus affecting gamma-globin level in human beta-cluster YAC transgenic mice

Genetic factors affecting postnatal γ-globin expression—a major modifier of the severity of both β-thalassemia and sickle cell anemia—have been difficult to study. This is especially so in mice, an organism lacking a globin gene with an expression pattern equivalent to that of human γ-globin. To model the human β-cluster in mice, with the goal of screening for loci affecting human γ-globin expression in vivo, we introduced a human β-globin cluster YAC transgene into the genome of FVB/N mice. The β-cluster contained a Greek hereditary persistence of fetal hemoglobin (HPFH) γ allele, resulting in postnatal expression of human γ-globin in transgenic mice. The level of human γ-globin for various F₁ hybrids derived from crosses between the FVB/N transgenics and other inbred mouse strains was assessed. The γ-globin level of the (C3HeB/FeJ × FVB/N)F₁ transgenic mice was noted to be significantly elevated. To map genes affecting postnatal γ-globin expression, we performed a 20-centiMorgan (cM) genome scan of a (C3HeB/FeJ × FVB/N)F₁ transgenics × FVB/N backcross, followed by high-resolution marker analysis of promising loci. From this analysis we mapped a locus within an 18-cM interval of mouse Chromosome (Chr) 1 (LOD = 4.3) that contributes 10.9% of variation in γ-globin level. Combining transgenic modeling of the human β-globin gene cluster with quantitative trait analysis, we have identified and mapped a murine locus that impacts on human γ-globin level in vivo. Received: 26 January, 2000 / Accepted: 2 May 2000