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.     

Embryonic β-globin in the non-Antarctic notothenioid fish Cottoperca gobio (Bovichtidae)

Haemoglobins are sensitive to temperature and their properties mirror the thermal conditions encountered by species during their evolutionary histories. This paper provides data on molecular phylogeny of the haemoglobin chains of Cottoperca gobio, a notothenioid fish of sub-Antarctic latitudes, belonging to the basal family Bovichtidae. Unlike most Antarctic notothenioids, C. gobio has two major haemoglobins sharing the β chain. In the molecular phylogenetic analysis, the β chain is included in the clade of the “embryonic” or minor Antarctic globins. Although, in the majority of notothenioids, “embryonic” (minor) α and β globins are expressed in traces or small amounts in the adult stage, in C. gobio the present analysis supports the occurrence of a complete “switch” to exclusive expression of the embryonic β-globin gene in adult fish. The α and β chains sequences have been used to expand our knowledge of the evolution of notothenioid haemoglobins.The protein sequence data reported in this paper will appear in the UniProt Knowledge base under the accession number: P84652 (β chain), P84653 (α ¹ chain).     

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     

Genomic organization of zebra finch alpha and beta globin genes and their expression in primitive and definitive blood in comparison with globins in chicken

How alpha and beta globin genes are organized and expressed in amniotes is of interest to researchers in a wide variety of fields. Data regarding this from avian species have been scarce. Using genomic and proteomic approaches, we present here our analysis of alpha and beta globins of zebra finch, a passerine bird. We show that finch alpha globin gene cluster has three genes (alphas 1–3), each orthologous to its chicken counterpart. Finch beta globin gene cluster has three genes (betas 1–3), with an additional pseudogene at the 3′ end. Finch beta3 is orthologous to chicken betaA, but the orthology of beta1 and beta2 to chicken counterparts is less clear. All six finch globins are confirmed to encode functional proteins. Gene expression in both globin gene clusters is regulated developmentally. Adult finch blood has a globin profile similar to that of adult chicken, with high levels of beta3 and alpha3 and moderate levels of alpha2. Finch embryonic primitive blood exhibits a globin profile very different from that of equivalent stage chick embryos, with all six globins expressed at high levels. Overall, our data provide a valuable resource for future studies in avian globin gene evolution and globin switching during erythropoietic development.     

Platypus globin genes and flanking loci suggest a new insertional model for beta-globin evolution in birds and mammals

Background  

Vertebrate alpha (α)- and beta (β)-globin gene families exemplify the way in which genomes evolve to produce functional complexity. From tandem duplication of a single globin locus, the α- and β-globin clusters expanded, and then were separated onto different chromosomes. The previous finding of a fossil β-globin gene (ω) in the marsupial α-cluster, however, suggested that duplication of the α-β cluster onto two chromosomes, followed by lineage-specific gene loss and duplication, produced paralogous α- and β-globin clusters in birds and mammals. Here we analyse genomic data from an egg-laying monotreme mammal, the platypus (Ornithorhynchus anatinus), to explore haemoglobin evolution at the stem of the mammalian radiation.     

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.     

A Dual Reporter Mouse Model of the Human β-Globin Locus: Applications and Limitations

The human β-globin locus contains the β-like globin genes (i.e. fetal γ-globin and adult β-globin), which heterotetramerize with α-globin subunits to form fetal or adult hemoglobin. Thalassemia is one of the commonest inherited disorders in the world, which results in quantitative defects of the globins, based on a number of genome variations found in the globin gene clusters. Hereditary persistence of fetal hemoglobin (HPFH) also caused by similar types of genomic alterations can compensate for the loss of adult hemoglobin. Understanding the regulation of the human γ-globin gene expression is a challenge for the treatment of thalassemia. A mouse model that facilitates high-throughput assays would simplify such studies. We have generated a transgenic dual reporter mouse model by tagging the γ- and β-globin genes with GFP and DsRed fluorescent proteins respectively in the endogenous human β-globin locus. Erythroid cell lines derived from this mouse model were tested for their capacity to reactivate the γ-globin gene. Here, we discuss the applications and limitations of this fluorescent reporter model to study the genetic basis of red blood cell disorders and the potential use of such model systems in high-throughput screens for hemoglobinopathies therapeutics.     

Developmental pattern and molecular identification of globin chains in Xenopus laevis

Summary High-resolution electrophoresis of larval and adult hemoglobins of Xenopus laevis reveals stage-specific differences in the number and mobility of the globin chains. To establish the relationship between the globin chains and the previously described globin genes, the corresponding mRNAs were hybrid-selected from total erythroblast RNA by representative cDNA clones, and translated in vitro. Electrophoretic separation of the translation products allowed identification of a major and a minor -globin chain in the larval and adult stages. This also holds for the adult -chains, however in the larval stage a difference in abundance is only detectable in the -mRNAs, but not in the translation products, because they comigrate. The fact that major and minor globin chains can be assigned to genes, which are located in two clusters, suggests that the related genes are expressed coordinately, but at different levels. Analysis of the globin patterns during development reveals that transition from the larval to the adult globin chains coincides with metamorphosis. Moreover, there is evidence of two globin chains that are only expressed in early larval stages and hence might be related to additional larval -globin genes of as yet unknown genomic location.     

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     

Molecular characterization of β-thalassemia intermedia: a report from Iran

Thalassemia intermedia is a clinical definition applied to patients whose clinical phenotype is milder than thalassemia major. To characterize different common mechanisms involving in pathogenesis of moderate to severe β-thalassemia intermedia, we have studied four factors in 38 Iranian patients with thalassemia intermedia: β-globin gene mutation, deletion in α-globin genes, presence of XmnI polymprphism and RFLP haplotype at β-globin gene cluster. The results showed that 84.4% of patients were associated with severe mutations in β-globin gene, mainly IVSII-1(G to A) (56.4%). The positive XmnI polymorphism was seen in 76.9% of the studied alleles which showed strong linkage to β° mutations and high level of fetal hemoglobin. Co-existence of α-globin gene deletions, β⁺ mutation and the most frequent of RFLP haplotype (−/−, +/+, −/+, +/+, +/+, +/+, −/−) were seen in 7.7, 12.8 and 17.9%, respectively. In this group of our study it seems the main ameliorating factor in the patients was co-inheritance of a positive XmnI polymorphism with β° mutation especially IVSII-1, which were associated with increased production of fetal hemoglobin. However, the other probable genetic factors should be investigated to describe genotype-phenotype correlation in thalassemia intermedia patients.     

Characterization of embryonic globin genes of the zebrafish

Hemoglobin switching is a complex process by which distinct globin chains are produced during stages of development. In an effort to characterize the process of hemoglobin switching in the zebrafish model system, we have isolated and characterized several embryonic globin genes. The embryonic and adult globin genes are found in clusters in a head-to-head configuration. One cluster of embryonic and adult genes is localized to linkage group 3, whereas another embryonic cluster is localized on linkage group 12. Several embryonic globin genes demonstrate an erythroid-specific pattern of expression early during embryogenesis and later are downregulated as definitive hematopoiesis occurs. We utilized electrospray mass spectroscopy to correlate globin genes and protein expression in developing embryonic red cells. The mutation, zinfandel, has a hypochromic microcytic anemia as an embryo, but later recovers in adulthood. The zinfandel gene maps to linkage group 3 near the major globin gene locus, strongly suggesting that zinfandel represents an embryonic globin defect. Our studies are the first to systematically evaluate the embryonic globins in the zebrafish and will ultimately be useful in evaluating zebrafish mutants with defects in hemoglobin production and switching.     

Linkage of the β-Like ω-Globin Gene to α-Like Globin Genes in an Australian Marsupial Supports the Chromosome Duplication Model for Separation of Globin Gene Clusters

The structure, function, and evolutionary history of globin genes have been the subject of extensive investigation over a period of more than 40 years, yet new globin genes with highly specialized functions are still being discovered and much remains uncertain about their evolutionary history. Here we investigate the molecular evolution of the -globin gene family in a marsupial species, the tammar wallaby, Macropus eugenii. We report the complete DNA sequences of two -like globin genes and show by phylogenetic analyses that one of these genes is orthologous to embryonically expressed -globin genes of marsupials and eutherians and the other is orthologous to adult expressed -globin genes of marsupials and eutherians. We show that the tammar wallaby contains a third functional -like globin gene, -globin, which forms part of the -globin gene cluster. The position of -globin on the 3 side of the -globin cluster and its ancient phylogenetic history fit the criteria, originally proposed by Jeffreys et al. (1980), of a fossil -globin gene and suggest that an ancient chromosome or genome duplication preceded the evolution of unlinked clusters of - and -globin genes in mammals and avians. In eutherian mammals, such as humans and mice, -globin has been silenced or translocated away from the -globin locus, while in marsupials -globin is coordinately expressed with the adult -globin gene just prior to birth to produce a functional hemoglobin (_{2 2}).     

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.     

Chromosomal arrangement of the chicken β-type globin genes

We have isolated the chicken β-type globin genes from a library of chicken DNA-λ Charon 4A recombinant bacteriophage. There are four β-type genes within this segment of the genome; we believe this represents all of the β-type genes of the chicken. The recombinant λCβG1 contains the embryonic ?- and adult β-globin genes. The hatching β^H and embryonic p-globin genes are found in the recombinant λCβG2. Although λCβG1 and λCβG2 do not physically overlap, we present evidence that all four genes are closely linked and transcribed from the same DNA strand. These experiments demonstrate that the chromosomal regions represented by λCβG1 and λCβG2 lie approximately 1.6 kb apart in the chicken genome. A third recombinant λCβG3 extends the genomic locus studied in the vicinity of the β-type globin genes to approximately 39 kb. The physical order of the chicken β-type globin genes within this segment of the chromosome is 5′ … ?-β^H-β-? … 3′. This arrangement is unique among the vertebrate β-type globin gene clusters thus far examined, in that embryonic genes are located at the 5′ and 3′ ends of the cluster while the hatching and adult genes occupy central positions.     

Evolution of Orthologous Intronless and Intron-Bearing Globin Genes in Two Insect Species

While globin genes ctt-2β and ctt-9.1 in Chironomus thummi thummi each have a single intron, all of the other insect globin genes reported so far are intronless. We analyzed four globin genes linked to the two intron-bearing genes in C. th. thummi. Three have a single intron at the same position as ctt-2β and ctt-9.1; the fourth is intronless and lies between intron bearing genes. Finally, in addition to its intron, one gene (ctt-13RT) was recently interrupted by retrotransposition. Phylogenetic analyses show that the six genes in C. th. thummi share common ancestry with five globin genes in the distantly related species C. tentans, and that a 5-gene ancestral cluster predates the divergence of the two species. One gene in the ancestral cluster gave rise to ctn-ORFB in C. tentans, and duplicated in C. th. thummi to create ctt-11 and ctt-12. From parsimonious calculations of evolutionary distances since speciation, ctt-11, ctt-12, and ctn-ORFB evolved rapidly, while ctn-ORFE in C. tentans evolved slowly compared to other globin genes in the clusters. While these four globins are under selective pressure, we suggest that most chironomid globin genes were not selected for their unique function. Instead, we propose that high gene copy number itself was selected because conditions favored organisms that could synthesize more hemoglobin. High gene copy number selection to produce more of a useful product may be the basis of forming multigene families, all of whose members initially accumulate neutral substitutions while retaining essential function. Maintenance of a large family of globin genes not only ensured high levels of hemoglobin production, but may have facilitated the extensive divergence of chironomids into as many as 5000 species. Received: 31 December 1996 / Accepted: 16 May 1997     

Structural and functional characterization of <Emphasis Type="Italic">Delphinus delphis</Emphasis> hemoglobin system

Structural analysis of the hemoglobin (Hb) system of Delphinus delphis revealed a high globin multiplicity: HPLC–electrospray ionization-mass spectrometry (ESI-MS) analysis evidenced three major β (β1 16,022 Da, β2 16,036 Da, β3 16,036 Da, labeled according to their progressive elution times) and two major α globins (α1 15,345 Da, α2 15,329 Da). ESI-tandem mass and nucleotide sequence analyses showed that β2 globin differs from β1 for the substitution Val126 → Leu, while β3 globin differs from β2 for the isobaric substitution Lys65 → Gln. The α2 globin differs from the α1 for the substitution Ser15 → Ala. Anion-exchange chromatography allowed the separation of two Hb fractions and HPLC–ESI-MS analysis revealed that the fraction with higher pI (HbI) contained β1, β2 and both the α globins, and the fraction with lower pI (HbII) contained β3 and both the α globins. Both D. delphis Hb fractions displayed a lower intrinsic oxygen affinity, a decreased effect of 2,3-BPG and a reduced cooperativity with respect to human HbA₀, with HbII showing the more pronounced differences. With respect to HbA₀, either the substitution Proβ5 → Gly or the Proβ5 → Ala is present in all the cetacean β globins sequenced so far, and it has been hypothesized that position 5 of β globins may have a role in the interaction with 2,3-BPG. Regarding the particularly lowered cooperativity of HbII, it is interesting to observe that the variant human HbA, characterized by the substitution Lysβ65 → Gln (HbJ-Cairo) has a decreased cooperativity with respect to HbA₀.