Structure and evolution of the horse zeta globin locus

The equine zeta globin gene locus consists of an intact 5' gene and a truncated 3' pseudogene (psi zeta) that has only 5' control sequences and a first exon and intron. Nevertheless, the psi zeta gene has retained almost perfect homology with its neighbour, presumably by gene conversion. The first introns of both zeta and psi zeta genes contain a number of degenerate tandem repeats of a 14 base-pair sequence that has been found in the zeta genes of goats and humans and that is related to a family of human minisatellite sequences. Comparisons of sequences flanking the zeta and psi zeta genes reveal areas of considerable interspecies homology, which can be explained by a zeta gene duplication that pre-dated the mammalian radiation.     

The isolation of the beta A-, beta C-, and gamma-globin genes and a presumptive embryonic globin gene from a goat DNA recombinant library

As an approach to understand how the expression of globin genes are regulated during development, clones containing globin DNA sequences were selected from a recombinant library of goat genomic DNA. The type of globin gene present in each of the recombinants was determined by cross-hybridization to the DNA of mouse alpha- and beta-globin cDNA-containing plasmids. Of 11 clones isolated, eight hybridized specifically to the DNA of the mouse beta-globin plasmid, while one clone hybridized only to the DNA of the alpha globin plasmid. The location of each globin sequence within its DNA insert was determined by a combination of restriction enzyme mapping and Southern transfer-hybridizations. Selected fragments were sequenced; comparisons of the amino acids coded for by these regions with those of the goat globins identified clones carrying beta A-, beta C-, and gamma-globin genes. Another recombinant coded for amino acid sequences resembling, but not identical with, the known goat globins, and was identified tentatively as containing an embryonic or epsilon-gene. Detailed analysis of the clone containing the beta C gene and an overlapping clone revealed that three other beta-like sequences are located 6, 12, and 21 kilobases on the 5'-side of the beta C gene. The globin sequence of the locus nearest to the beta C gene has an altered translation termination codon and, if transcribed and translated, would give a globin chain seven amino acids longer than the normal goat beta C-globin. In addition, the sequence following this termination codon is very AT-rich, unlike that of other globin genes. The recombinants described contain extensive regions of DNA surrounding the globin genes, making them useful for identifying regulatory sequences as well as determining the sequence organization of the goat globin genes.     

The organization of the tadpole and adult alpha globin genes of Xenopus laevis

Adult erythrocytes of X. laevis contain six electrophoretically resolvable globin polypeptides while tadpole erythrocytes contain four polypeptides, none of which comigrates with an adult protein. We show that three of the adult proteins are alpha globin polypeptides (alpha 1, alpha 2, alpha 3) and three are beta globin polypeptides (beta 1, beta 2, beta 3). We find that a tadpole alpha globin gene (alpha T1) is linked to the major adult locus in the sequence 5'-alpha T1-alpha 1-beta 1-3' with 5.2 kb separating alpha T1 from alpha 1. Another tadpole alpha globin gene (alpha T2) is linked to the minor adult locus in the sequence 5'-alpha T2-alpha 2-beta 2-3' with 10.7 kb separating alpha T2 from alpha 2. These linkage relationships are consistent with the major and minor loci having arisen by tetraploidization but the different separation of larval and adult globin genes at the two loci indicates the occurrence of some additional chromosomal rearrangement. Two alternative models are presented.     

Isolation of the chicken beta-globin gene and a linked embryonic beta-like globin gene from a chicken DNA recombinant library.

A library of random chicken DNA fragments, 15-22 kb long, has been prepared in the vector lambda Charon 4A. This library was screened with combined adult and embryonic globin cDNA, and several independent globin gene-containing recombinants were isolated. One of these recombinants, lambda Chicken beta-globin 1 (lambda C beta G1), contains the adult chicken beta-globin gene and a closely linked embryonic beta-like globin gene. Both genes are transcribed in the same direction with the adult gene located 5' to the embryonic gene. Electron microscopic visualization of R loop structures generated by hybridization of globin RNA to lambda C beta G1 demonstrates that both globin genes contain major intervening sequences about 800 bp long, similar to those present in mammalian beta-globin genes. The adult beta-globin gene also contains a minor (approximately 100 bp long) intervening sequence analogous to the one observed in mammalian beta-globin genes. Restriction enzyme analysis of the adult beta-globin gene on lambda C beta G1 is consistent with the hypothesis that its two intervening sequences occur in the same positions with respect to the beta-globin amino acid sequence as do the corresponding mammalian intervening sequences.     

Developmental regulation of the human zeta globin gene in transgenic mice.

We have characterized the expression of the human zeta (zeta) gene, which encodes an embryonic alpha-like globin, in transgenic mice. We find that a 777 base pair fragment spanning erythroid specific hypersensitive site II (HSII) from the distal 5. region of the human beta globin gene cluster potentiates expression of the zeta globin gene. In the absence of the HSII fragment, no zeta expression is observed. Expression of the human zeta gene in mice parallels expression of a murine embryonic alpha-like globin gene (x). Thus, expression of the human zeta gene in mice requires linkage to an erythroid-specific enhancer sequence, but the presence of the enhancer does not affect the developmental regulation of the transgene. Our results indicate that the factors involved in switching from embryonic to adult alpha globin gene expression during development are evolutionarily conserved, and suggest that the transgenic mouse is an in vivo system in which the requirements for the developmental switch in alpha globin gene expression can be analyzed in detail.     

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.     

Chromosomal arrangement of the duck alpha-globin genes and primary structure of the embryonic alpha-globin gene pi

A recombinant lambda Charon 4A bacteriophage, D alpha G-1, carrying the genes coding for the duck embryonic (pi') and adult (alpha A, alpha D) alpha-like globins was isolated from a previously constructed duck DNA recombinant library. The three globin genes are transcribed from the same DNA strand and are arranged in the order of their expression during development: 5'-pi'-alpha D-alpha A-3'. We have determined the complete nucleotide sequence of the duck pi'-globin gene, including the flanking regions. Due to the unusual length of intron 1 (963 bp) and intron 2 (568 bp) the 2167-bp duck pi'-globin gene is by far the largest among all known mammalian or avian alpha- and beta-globin genes. For instance, the duck pi'-globin gene introns are almost twice as long as those of the chicken pi'-globin genes. A surprisingly high degree of nucleotide sequence homology (88%) has been found for the 5' flanking region (positions -1 to -223) of the duck and chicken pi'-globin gene.     

Duplication of a four-gene set during the evolution of the goat beta-globin locus produced genes now expressed differentially in development

Genomic clones which link the goat preadult (beta C) and adult (beta A) beta-globin genes have been isolated. These overlapping clones contain a previously unidentified embryonic like globin gene (epsilon III) and establish the following linkage map of eight genes in the goat beta-globin locus: epsilon I-epsilon II-psi beta X-beta C-epsilon III-epsilon IV-psi beta Z-beta A. This linkage map and the nucleotide sequence of the eight genes document a relatively recent duplication of a four-gene set: epsilon-epsilon-psi beta-beta. This duplication produced two genes (beta C and beta A) which are now expressed differentially during development. An embryonic like globin gene located downstream from beta A has also been isolated. The embryonic nature of this gene as well as the adult beta-like sequence of the goat fetal globin gene (gamma) suggest that a duplication of the four-gene set also produced the globin gene now expressed during fetal development.     

Concerted evolution led to high expression of a prosimian primate delta globin gene locus

The delta globin gene in simian primates is either weakly expressed (in hominoids and New World monkeys) or silent (in Old World monkeys). In prosimian primates, however, an unequal homologous crossover between the psi eta and delta loci of lemurs produced a hybrid psi eta delta pseudogene locus, whereas in tarsier the delta locus encodes a beta-type chain found in 18% of adult tarsier hemoglobin molecules. In the present study, the nucleotide and amino acid sequences of the galago delta and beta globin genes and their encoded peptides were determined, and evidence is provided showing that the galago delta locus encodes a beta-type chain (beta 2) found in 40% of the galago fetal and postnatal hemoglobin molecules, whereas the beta locus encodes the remaining 60% of the beta-type chain (beta 1). Galago beta 1 and beta 2 chains differ from each other by only one amino acid residue. The homology between the galago delta and beta loci extends from 800 base pairs 5' of the proximal CCAAT element to near the end of exon 3 as a result of a recombination event in which beta sequence replaced delta sequence. After this initial recombination event, concerted evolution between the loci continued over their conserved coding, intron 1, and promoter regions but failed to occur between the two loci in their intron 2 and distal 5'-flanking sequences where the two loci have now diverged by 20%. Calculations based on this divergence value and on a rate of noncoding sequence evolution of 4.2 x 10(-9) to 5.5 x 10(-9) substitutions/site/year for the lorisiform lineage to galago yielded a date of 18-24 million years ago for the initial recombination event. The fact that the promoter sequences of the galago delta locus are the same as that of the galago beta locus may account for the high level of expression of the galago delta gene.     

Intergenic DNA sequences flanking the pseudo alpha globin genes of human and chimpanzee.

We have determined the sequence of 2400 base pairs upstream from the human pseudo alpha globin (psi alpha) gene, and for comparison, 1100 base pairs of DNA within and upstream from the chimpanzee psi alpha gene. The region upstream from the promoter of the psi alpha gene shows no significant homology to the intergenic regions of the adult alpha 2 and alpha 1 globin genes. The chimpanzee gene has a coding defect in common with the human psi alpha gene, showing that the product of this gene, if any, was inactivated before the divergence of human and chimpanzee. However the chimpanzee gene contains a normal ATG initiation codon in contrast to the human gene which has GTG as the initiation codon. The psi alpha genes of both human and chimpanzee are flanked by the same Alu family member. The structure and position of this repeat have not been altered since the divergence of human and chimpanzee, and it is at least as well conserved as its immediate flanking sequence. Comparing human and chimpanzee, the 300 bp Alu repeat has accumulated only two base substitutions and one length mutation; the adjacent 300 bp flanking region has accumulated five base substitutions and twelve length mutations.     

Concerted evolution of the cow epsilon 2 and epsilon 4 beta-globin genes

The nucleotide sequences of the cow epsilon 2 and epsilon 4 globin genes were determined. The sequences were 95% identical. These genes arose via a four-gene block duplication that also gave rise to the bovine fetal (gamma) and adult (beta) genes. Their deduced amino acid sequences are unlike any previously reported fetal or adult globins; rather, comparison to other mammalian globin genes indicates that they are embryonic in nature. The sequence data indicate that these two genes have converted each other during evolution. Pairwise comparison to the corresponding goat genes shows greater similarity between paralogues than between more directly related orthologues. This is in direct contrast to the situation between the cow and goat fetal and adult genes. These observations suggest that the frequency of DNA conversion or the fixation of conversion events may vary in different locations of the cow beta-globin cluster.      

Evolution and molecular characterization of a beta-globin gene from the Australian Echidna Tachyglossus aculeatus (Monotremata).

Coinciding with a period in evolution when monotremes, marsupials, and eutherians diverged from a common ancestor, a proto-beta-globin gene duplicated, producing the progenitors of mammalian embryonic and adult beta-like globin genes. To determine whether monotremes contain orthologues of these genes and to further investigate the evolutionary relationships of monotremes, marsupials, and eutherians, we have determined the complete DNA sequence of an echidna (Tachyglossus aculeatus) beta-like globin gene. Conceptual translation of the gene and sequence comparisons with eutherian and marsupial beta-like globin genes and echidna adult beta-globin indicate that the gene is adult expressed. Phylogenetic analyses do not clearly resolve the branching pattern of mammalian beta-like globin gene lineages and it is therefore uncertain whether monotremes have orthologues of the embryonic beta-like globin genes of marsupials and eutherians. Four models are proposed that provide a framework for interpreting further studies on the evolution of beta-like globin genes in the context of the evolution of monotremes, marsupials, and eutherians.     

The primary structure of hemoglobin D from the Aldabra giant tortoise,Geochelone gigantea

The complete primary structures of alpha D-2- and beta-globin of hemoglobin D (Hb D) from the Aldabra giant tortoise, Geochelone gigantea, have been constructed by amino acid sequencing analysis in assistance with nucleotide sequencing analysis of PCR fragments amplified using degenerate oligonucleotide primers. Using computer-assisted sequence comparisons, the alpha D-2-globin shared a 92.0% sequence identity versus alpha D-globin of Geochelone carbonaria, a 75.2% versus alpha D-globin of Aves (Rhea americana) and a 62.4% versus alpha A-globin of Hb A expressed in adult red blood cells of Geochelone gigantea. Additionally, judging from their primary structures, an identical beta-globin was common to the two hemoglobin components, Hb A and Hb D. The alpha D-2- and beta-globin genes contained the three-exon and two-intron configurations and showed the characteristic of all functional vertebrate hemoglobin genes except an abnormal GC dinucleotide instead of the invariant GT at the 5' end of the second intron sequence. The introns of alpha D-2-globin gene were both small (224-bp/first intron, 227-bp/second intron) such that they were quite similar to those of adult alpha-type globins; the beta-globin gene has one small intron (approximately 130-bp) and one large intron (approximately 1590-bp). A phylogenetic tree constructed on primary structures of 7 alpha D-globins from Reptilia (4 species of turtles, 2 species of squamates, and 1 species of sphenodontids) and two embryonic alpha-like globins from Aves (Gullus gullus) and Mammals (Homo sapiens) showed the following results: (1) alpha D-globins except those of squamates were clustered, in which Sphenodon punctatus was a closer species to birds than turtles; (2) separation of the alpha A- and alpha D-globin genes occurred approximately 250 million years ago after the embryonic alpha-type globin-genes (pi' and zeta) first split off from the ancestor of alpha-type globin gene family.