Localization and characterization of members of a family of repetitive sequences in the goat beta globin locus.

We have characterized a family of repetitive DNA elements in the beta-globin locus of the goat. These sequences are structurally analogous to the Alu families of repeats of other mammals. Repetitive elements are located both in the intervening sequences and in the intergenic regions of the goat beta-globin locus. Nucleotide sequence analysis of five repetitive elements located within the large intervening sequence of the beta-like globin genes, and four repeats located 5' to the major developmentally regulated beta-globin genes has resulted in the definition of a consensus sequence for this family of repeats.     

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.     

Assignment of orthologous relationships among mammalian alpha-globin genes by examining flanking regions reveals a rapid rate of evolution

In order to study the relationships among mammalian alpha-globin genes, we have determined the sequence of the 3' flanking region of the human alpha 1 globin gene and have made pairwise comparisons between sequenced alpha-globin genes. The flanking regions were examined in detail because sequence matches in these regions could be interpreted with the least complication from the gene duplications and conversions that have occurred frequently in mammalian alpha-like globin gene clusters. We found good matches between the flanking regions of human alpha 1 and rabbit alpha 1, human psi alpha 1 and goat I alpha, human alpha 2 and goat II alpha, and horse alpha 1 and goat II alpha. These matches were used to align the alpha-globin genes in gene clusters from different mammals. This alignment shows that genes at equivalent positions in the gene clusters of different mammals can be functional or nonfunctional, depending on whether they corrected against a functional alpha-globin gene in recent evolutionary history. The number of alpha-globin genes (including pseudogenes) appears to differ among species, although highly divergent pseudogenes may not have been detected in all species examined. Although matching sequences could be found in interspecies comparisons of the flanking regions of alpha- globin genes, these matches are not as extensive as those found in the flanking regions of mammalian beta-like globin genes. This observation suggests that the noncoding sequences in the mammalian alpha-globin gene clusters are evolving at a faster rate than those in the beta-like globin gene clusters. The proposed faster rate of evolution fits with the poor conservation of the genetic linkage map around alpha-globin gene clusters when compared to that of the beta-like globin gene clusters. Analysis of the 3' flanking regions of alpha-globin genes has revealed a conserved sequence approximately 100-150 bp 3' to the polyadenylation site; this sequence may be involved in the expression or regulation of alpha-globin genes.      

The DNA sequence of the 5' flanking region of the human beta-globin gene: evolutionary conservation and polymorphic differences.

We have determined the DNA sequence of a 1464 bp segment immediately flanking the 5' side of the human beta-globin gene. The sequence shows little similarity to the corresponding regions of the epsilon- or gamma-globin genes. There is about 75% homology, however, between the 5' extragenic regions of the beta-globin genes of man, goat and rabbit respectively. The mouse beta minor globin gene, but not the mouse beta major globin gene, also shares this extensive homology. A short segment of simple sequence DNA is found from about 1418 to 1388 bp upstream from the human beta-globin gene which consists of repeats of the sequence (TTTTA). Similar DNA sequences are also found at several sites in the large intron of the beta-globin gene. We have compared the DNA sequence of the 5' extragenic region of the normal beta-globin gene with the same segment of the beta-globin gene of a patient with beta thalassaemia. Of the two nucleotide differences observed, one generates a polymorphic HinfI site present 990 bp upstream from the beta-globin gene in the thalassaemic beta-globin and absent in the normal gene. A second beta thalassemic beta-globin gene which has the same molecular defect as the above mentioned case, however, lacks this HinfI site. It is therefore not yet clear whether this HinfI site will have any value in prenatal diagnosis of beta thalassaemia.     

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.     

Hemoglobin switching in sheep. Cloning and characterization of the beta A and beta-like embryonic globin genes from genomic DNA

Genomic DNA from a fetal sheep homozygous for the beta A gene was used to construct a library of one million cloned DNA fragments using the bacteriophage vector, Charon 4A. Screening of 150,000 plaques from this library using radioactive beta-globin gene sequences resulted in the isolation of two recombinant bacteriophage containing globin genes. One of these, S beta AG-21, contains the complete adult beta A-globin gene as demonstrated by hybridization and restriction endonuclease analysis. In common with adult globin genes from other species, the beta A gene contains small (105 base pairs) and large (900 base pairs) intervening sequences. The second recombinant bacteriophage, SG-4, contains a complete embryonic beta-like globin gene which is expressed in the sheep embryo as demonstrated by hybridization analysis with cDNA made from sheep embryonic globin mRNA. Although differing in its restriction endonuclease map from the adult beta-globin genes, SG-4 appears to contain a large intervening sequence of at least 750 base pairs in length. Finally, preliminary evidence is discussed which indicates that a Pvu II site just 5' to the Cap site may be a common feature of sheep globin genes.     

Nucleotide sequence of the goat embryonic alpha globin gene (zeta) and linkage and evolutionary analysis of the complete alpha globin cluster

In previous studies we identified and sequenced clones containing two adult alpha globin genes of the goat. Additional studies have revealed the presence of an embryonic alpha globin gene termed zeta. Sequence analysis of the gene shows that it is the largest mammalian or avian globin gene cloned to date. Its unusual size is mainly due to a 14 base-pair tandem repeat sequence in its first intron. A similar sequence is also found in the first intron of the human zeta gene. The goat zeta coding sequence differs greatly from that of the adult alpha, particularly at amino acid position 38, where it codes for the amino acid replacement of Gln for Thr. This change may confer a higher intrinsic O2 affinity on the zeta globin protein, ensuring a sufficient O2 supply for the developing goat embryo. The cloning and sequencing of this gene completes the alpha globin locus of the goat, composed of three genes in the following order 5'-zeta-I alpha-II alpha-3'. Evolutionary comparisons of the goat alpha locus with other amphibian, avian and mammalian loci reveal several interesting features. Statistical analysis confirms the hypothesis that the embryonic alpha gene is much older (400 million years) than the embryonic beta gene (200 million years), and that it is descended from a primordial gene, whose present-day counterpart is the Xenopus larval alpha globin gene. Our results also suggest that after the divergence of the avian line, the alpha A gene converted the alpha D gene during the evolution of the pre-mammalian line. The alpha D globin gene remains unconverted in the avian line, potentially because of insertion/deletion sequences that may prevent any gene conversion event. The divergence rates of specific globin genes have been analyzed and found to form an essentially straight line, in agreement with the neutralist view of evolution.     

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 nucleotide sequence of rabbit embryonic globin gene beta 3

The nucleotide sequence of a rabbit embryonic globin gene, beta 3, has been determined from 161 base pairs (bp) on the 5' side of the mRNA cap site to 209 base pairs beyond the 3' poly A addition site. The 5' and 3' ends of mRNA from both embryonic globin genes beta 3 and beta 4 have been determined by an S1 protection assay. Sequences that are highly conserved in the 5' flanking region of eukaryotic structural genes, AATAAAA and CCAAT, are located -25 to -31 nucleotides and -81 to -85 nucleotides, respectively, before the cap site. The CCAAT sequence is duplicated at -108 to -112 nucleotides, as it is in the human fetal gamma-globin genes. Small (124 bp) and large (817 bp) intervening sequences are located between codons 30 and 31 and between 104 and 105, respectively. The sequence AATAAA precedes the predominant poly(A) addition site by 19 nucleotides. Although rabbit globin gene beta 3 is transcribed and translated almost exclusively in embryonic erythrocytes, it shares striking homology with the human gamma-globin genes which are expressed in erythrocytes from fetal liver. The evolutionary conservation of rabbit beta 3 and human gamma correlates well with their similar chromosomal positions in the two genes families.     

Structural organization of the beta-globin locus of B-haplotype sheep

Goats and some sheep synthesize a juvenile hemoglobin, Hb C (alpha 2 beta C2), at birth and produce this hemoglobin exclusively during severe anemia. Sheep that synthesize this juvenile hemoglobin are of the A haplotype. Other sheep, belonging to a separate group, the B haplotype, do not synthesize hemoglobin C and during anemia continue to produce their adult hemoglobin. To understand the basis for this difference we have determined the structural organization of the beta- globin locus of B-type sheep by constructing and isolating overlapping genomic clones. These clones have allowed us to establish the linkage map 5' epsilon I-epsilon II-psi beta I-beta B-epsilon III-epsilon IV- psi beta II-beta F3' in this haplotype. Thus, B sheep lack four genes, including the BC gene, and have only eight genes, compared with the 12 found in the goat globin locus. The goat beta-globin locus is as follows: 5' epsilon I-epsilon II-psi beta X-beta C-epsilon III-epsilon IV-psi beta Z-beta A-epsilon V-epsilon VI-psi beta Y-beta F3'. Southern blot analysis of A-type sheep reveals that these animals have a beta- globin locus similar to that of goat, i.e., 12 globin genes. Thus, the beta-globin locus of B-haplotype sheep resembles that of cows and may have retained the duplicated locus of the ancestor of cows and sheep. Alternatively, the B-sheep locus arrangement may be the result of a deletion of a four-gene set from the triplicated locus.      

Five nucleotide changes in the large intervening sequence of a beta globin gene in a beta+ thalassemia patient.

A beta globin gene from a patient with homozygous beta+ thalassemia has been cloned and completely sequenced. No changes from normal are found in the 200 nucleotides 5' to the cap site, in the 3' untranslated region up to the poly A addition site, in the small intervening sequence (IVS 1), or in the coding sequence except for a third base change in codon 2. The only other differences are in the large intervening sequence (IVS 2). One of these, at a position 16 nucleotides from the 5' end of IVS 2, has been reported previously in normal individuals, and is probably a polymorphism. Four other changes, at positions 74, 81, 666, and 705 are also seen in IVS 2. Abnormal beta globin mRNA precursors detected in the bone marrow cells of this patient, and abnormal beta globin RNA splicing observed when this gene is transcribed in a tissue culture system taken together with these IVS 2 changes, suggest that the beta+ thalassemia phenotype is produced by a decrease in normal beta globin mRNA processing.     

DNA sequences regulating human beta globin gene expression.

Human delta globin is expressed at approximately 1-2% of the level of human beta globin in erythroid cells despite the marked homology between these two globins. To determine the DNA sequences responsible for this effect, delta and beta globin genes and fusion products of these genes constructed in vitro were transfected and expressed in HeLa cells. The results indicate that when the small intervening sequence of the beta gene (beta IVS 1) is replaced by delta IVS 1, expression of the chimeric gene is the same as that of the normal beta globin gene. By contrast, when the large intervening sequence of the beta gene (beta IVS 2) is replaced by delta IVS 2, expression of the chimeric gene is markedly reduced. These results suggest that there are signals within IVS 2 of the delta and beta genes which affect their relative expression.     

Beta thalassemic mutations recognized by DNA mapping with Hph I and Rsa I in the Algerian population

By using Hph I and Rsa I restriction enzymes and beta globin large intervening sequence as a probe, we have investigated the DNA of 20 Algerian patients with beta(0) or beta(+) thalassemia. In any of them, we detected the nucleotide change which is known to generate an additional Hph I site at the 5' splice junction of the beta globin large intervening sequence and which yields a beta(0) phenotype. In one of them, we detected the nucleotide change which is known to generate an additional Rsa I site within the beta globin large intervening sequence and which is supposed to yield a beta(+) phenotype. These results indicate that these two types of mutation are relatively rare in the Algerian population.     

Rabbit globin pseudogene psi beta 2 is a hybrid of delta- and beta-globin gene sequences

The evolutionary history of the rabbit globin pseudogene psi beta 2 was studied by completing its nucleotide sequence and aligning the sequence with that of the rabbit adult globin gene beta 1 and the human minor adult globin gene delta. The 5' flanking region and exon 1 of psi beta 2 were most similar to rabbit beta 1, but the large intervening sequence and the 3' untranslated region were most similar to human delta. Intron 1 and exon 2 were equally similar to both delta and beta 1. This pattern indicates that psi beta 2 was originally a delta-like gene that acquired the 5' portion of gene beta 1 by intrachromosomal gene conversion. The presence of a delta-globin gene sequence in both rabbits and humans shows that it is an ancient gene, predating the mammalian radiation that occurred over 85 Myr ago. Delta has shown a pronounced tendency to be altered in its 5' end during the course of mammalian evolution. Quantitative divergence analysis shows that the ancestor to rabbit psi beta 2 was active until 20-30 Myr ago, during which time the lagomorph beta-globin gene family apparently functioned without a pseudogene.