G to A substitution in the distal CCAAT box of the A gamma-globin gene in Greek hereditary persistence of fetal haemoglobin

The sequence 5'TTGGPyCAAT 3' (the 'CCAAT box') is a constituent of the promoter region of many eukaryotic and prokaryotic genes and is believed to play a part in promoter function. A characteristic of the two fetal human globin genes (A gamma and G gamma) is a duplication of a 12-base pair (bp) sequence containing the CCAAT box. Here we report a G----A substitution in the TTG sequence of the distal CCAAT box of the A gamma-globin gene in an individual with the A gamma (Greek) type of hereditary persistence of fetal haemoglobin (HPFH). This represents the first report of a natural mutation of the CCAAT box in a eukaryotic gene. The fact that this transition is associated with inappropriate expression of the A gamma gene in adult life suggests that the CCAAT box (or its surrounding sequences) may have a role in the developmental control of gamma-globin genes.     

Sequence organization and genomic complexity of primate theta 1 globin gene, a novel alpha-globin-like gene

The alpha-like and beta-like globin genes have provided a paradigm for the study of molecular evolution and regulation of multigene families in eukaryotes. The human alpha-globin gene cluster, which is on chromosome 16 (ref. 1), consists of six genes arranged in the order 5'-zeta(embryonic)-psi zeta-psi alpha 2-psi alpha 1-alpha 2(adult)-alpha 1(adult)-3'. DNA sequencing data have demonstrated that zeta (ref. 6) and alpha 2 (or alpha 1, refs 7-9) are the embryonic and adult genes, respectively, while psi zeta (ref. 6), psi alpha 2 (ref. 5) psi alpha 1 (ref. 10) are all inactive pseudogenes. Restriction mapping analysis has shown that the structure of this locus in several anthropoid primates is nearly identical to that of the human. Recently, we have isolated the adult alpha-globin gene region from orang-utan, olive baboon and rhesus macaque by molecular cloning. We report here the complete nucleotide sequence of a gene located immediately downstream from the adult alpha 1-globin gene of the orang-utan, along with its flanking DNA. We designate this gene as theta 1, and show that it contains the essential sequence elements required for an expressive gene. The putative polypeptide is 141 amino acids long, identical to that of the alpha- or zeta-globin, but its predicted amino-acid sequence is nearly as different from the orang-utan alpha-globin (55 differences) as the human zeta-globin is from the human alpha-globin (59 differences), suggesting an ancient history for the theta 1-globin gene. Results of blot hybridization experiments using the cloned orang-utan theta 1 gene sequence as probe demonstrate a similar alpha 2-alpha 1-theta 1 linkage map existing in the human genome. Furthermore, multiple copies of sequences homologous to the theta 1 gene are detected in both human and orang-utan. These results cast a new light on the primate alpha-globin gene family, and have intriguing implications for the existence of previously unreported, functional globin-like gene(s) in the primate genomes.     

Evidence that the recently discovered theta 1-globin gene is functional in higher primates

A new subfamily of the alpha-globin-like family has recently been identified in higher primates, rabbit, galago and possibly the horse. One member of this subfamily, theta 1, is downstream from the adult alpha 1-globin gene. In orang-utan, but not in rabbit or galago, the theta 1-gene appears to be structurally intact, suggesting that it may be functional in this species. The orang-utan theta 1-gene possesses initiation and termination codons, and the predicted polypeptide differs from the orang-utan alpha 1-globin by 55 amino acids. The upstream promoter boxes CCAAT and ATA are present, although approximately 150 base pairs (bp) farther upstream than in the alpha 1-gene. This structural difference in the promoter between the orang-utan theta 1- and alpha 1-genes has led Proudfoot to speculate that the theta 1-gene may be inactive. We have now cloned the theta 1- and alpha 1-globin genes from the olive baboon, and have compared their sequences with those of orang-utan. The unique promoter structure of the orang-utan theta 1-gene is highly conserved in baboon, although the orang-utan and baboon diverged nearly 30 million years ago. The coding sequences of the two theta 1-genes differ by only 6.3% with 22 out of 27 nucleotide substitutions being codon third position silent changes. These data support the view that the theta 1-gene has been functional in the baboon, orang-utan, and by implication, in man. We also estimate that the duplication event generating the theta 1- and alpha-globin-like subfamilies may have occurred as much as 260 million years ago.     

Can the product of the theta gene be a real globin?

A new member (theta 1, or psi alpha) of the alpha-globin gene family has recently been identified in a number of species. In higher primates the theta 1 gene has all the structural features apparently necessary for expression, and it appears to have long been under strong selective constraints which suggests that it could still be, or recently have been, a functional gene. No corresponding 'globin' has yet been identified, however. In some other species, galago and rabbit for example, the theta 1 and psi alpha genes have accumulated enough inactivating mutations for them to be considered genuine pseudogenes. Horses also have an alpha-like gene (psi alpha), in a 3' position identical to the other species in relation to the functional alpha genes, and this also appears to have the elements required for a functional gene. The predicted amino-acid sequence, however, suggests that any 'globin' product is likely to be non-viable because it has a number of seriously deleterious amino-acid replacements. Some of these amino-acid changes are shared with the rabbit and primate sequences, indicating that they predate the mammalian radiation, and that if indeed any of these genes are still functional, they are unlikely to be making haemoglobin.     

An embryonic pattern of expression of a human fetal globin gene in transgenic mice

During the evolution of the beta-globin family gene in vertebrates, different globin genes acquired different developmental patterns of expression. In mammals, specific 'embryonic' beta-like globins are synthesized in the earliest erythroid cells, which differentiate in the yolk sac of the embryo. In most mammals the embryonic globin chains are replaced by 'adult' beta-globins in fetal and adult erythrocytes, which arise in the liver and bone marrow, respectively. However, in simian primates (including humans), a distinct 'fetal' type of beta-like globin chain predominates in fetal erythroid cells. Based on the pattern of DNA sequence homologies between different mammalian species, these fetal globin genes, G gamma and A gamma, are thought to have descended from an ancestral gene, 'proto-gamma', which was embryonic in its pattern of expression. In the mouse, as well as in most other mammalian species, the descendants of the proto-gamma gene continue to function as embryonic genes. To investigate the evolutionary changes that led to the 'fetal recruitment' of the gamma-globin genes in primates, we have introduced the cloned human G gamma-globin gene into the mouse germ line. We report here that the human G gamma gene reverts to an embryonic pattern of expression in the developing mouse. This observation suggests that during evolution a shift occurred in the timing of expression of a trans-acting signal controlling the proto-gamma gene.     

Effects of point mutation C→T at - 64 of human δ globin gene promoter on DNA binding proteins

By electrophoretic mobility shift assay (EMSA), the effect of point mutation C→T at - 64 of human δ-globin gene on its binding proteins has been studied. Two segments of 36 bp from - 83- - 48 bp of the 6 globin gene promoter, named WOG and MOG, were synthesized. WOG includes wild type CAAT-like box (CCAAC), while MOG includes the mutant CAAT-like box (CCAAT, -64 C→T). Results indicate that: ( i ) in erythroid cell lines MEL, K562 and Hemin induced K562, the affinity of MOG with CCAAT binding protein (CBF) and GATA-1 was greatly increased; ( ii ) in Hemin induced K562 cell line, there were another two novel specific DNA binding proteins, named C and D temporarily, besides the above two factors. The former was combined with WOG and MOG, likely indicating its relation with the increased gene expression after induction. The latter was only combined with MOG, which had possible relationship with the point mutation of - 64 C→T; ( iii ) EMSA also indicates that the suppression mechanisms of the expression of 6 globin gene is different in various periods of human developments. The result evidently supports the hypothesis that the defect CAAT-like box in human 6 globin gene contributes the main reason of its low level expression. The defect c/s-acting element CAAT-like box affects gene expression by its combination with the frans-acting element CBF and GATA-1.     

Developmental regulation of a cloned adult beta-globin gene in transgenic mice

At different stages of mammalian development, distinct embryonic, fetal and adult haemoglobins are synthesized in erythroid cells, a process termed haemoglobin switching. The cellular and molecular mechanisms controlling haemoglobin switching have been intensively studied, but remain poorly understood. To study the developmental regulation of globin gene expression, we have produced transgenic mice in which cloned globin genes are present in erythroid cells throughout development. Recently, we reported that adult mice in several transgenic lines carrying a hybrid mouse/human adult beta-globin gene, expressed the gene in a correct tissue-specific manner. This finding raised the question of whether an exogenous globin gene could also be subject to appropriate stage-specific regulation. We report here that the hybrid beta-globin gene, like the endogenous adult beta-globin genes, is inactive in yolk sac-derived embryonic erythroid cells and is expressed for the first time in fetal liver erythroid cells. Our results indicate that a stage-specific pattern of expression can be conferred by cis-acting regulatory elements closely linked to an adult beta-globin gene. They also suggest that the embryonic and adult beta-globin genes in the mouse are activated (or repressed) by distinct trans-acting regulatory factors present in embryonic, fetal and adult erythroid cells.     

Human gamma-globin genes silenced independently of other genes in the beta-globin locus.

Erythropoiesis during human development is characterized by switches in expression of beta-like globin genes during the transition from the embryonic through fetal to adult stages. Activation and high-level expression of the genes is directed by the locus control region (LCR), located 5' to the epsilon gene. The location of the LCR and its role in directing high-level expression of the globin genes has led to the suggestion that competition from the beta gene for interaction with the LCR has a major role in silencing the fetal gamma genes during adult life. We have now constructed lines of transgenic mice containing the human A gamma globin gene linked to the LCR. We observe high-level expression of the transgene in the embryonic stages but silencing of the gene in adult animals. We conclude that the gamma gene is not deregulated by the presence of the LCR and that competition from the beta gene is not required for silencing of the gamma genes in adult life. The silencing is therefore likely to be mediated by stage-specific factors binding to sequences immediately flanking the genes.     

A point mutation in the A gamma-globin gene promoter in Greek hereditary persistence of fetal haemoglobin

Hereditary persistance of fetal haemoglobin (HPFH) is a benign condition characterized by the production in adulthood of more than 1% fetal haemoglobin (HbF, alpha 2 gamma 2) in the absence of erythropoietic stress. Several genetic types have been discerned based on the level of HbF produced, the relative contributions of the duplicated fetal (G gamma and A gamma) globin genes, and the presence or absence of deletions involving the beta and delta genes in cis to the mutation. Greek HPFH is a non-deletion variety in which heterozygotes produce 10-20% HbF, predominantly due to overproduction of the A gamma chain. We have cloned a 40-kilobase (kb) region of the beta-globin cluster from a Greek HPFH allele and report here that a point mutation (G----A) occurs 117 base pairs (bp) 5' to the cap site of the A gamma-globin gene, just upstream of the distal CCAAT sequence. The corresponding region of the G gamma-globin gene is normal. We discuss the implications of this finding for the developmental regulation of globin gene expression.     

Specific expression of a foreign beta-globin gene in erythroid cells of transgenic mice

The globin gene family represents an attractive system for the study of gene regulation during mammalian development, as its expression is subject to both tissue-specific and temporal regulation. While many aspects of globin gene structure and expression have been described extensively, relatively little is known about the cis-acting DNA sequences involved in the developmental regulation of globin gene expression. To begin to experimentally define these regulatory sequences, we have taken the approach of introducing cloned globin genes into the mouse germ line and examining their expression in the resulting transgenic animals. Here we describe a series of transgenic mice carrying a hybrid mouse/human adult beta-globin gene, several of which express the gene exclusively or predominantly in erythroid tissues. These studies demonstrate that regulatory sequences closely linked to the beta-globin gene are sufficient to specify a correct pattern of tissue-specific expression in a developing mouse, when the gene is integrated at a subset of foreign chromosomal positions.     

Characterisation of deletions which affect the expression of fetal globin genes in man.

Deletions in the DNA of individuals with hereditary persistence of fetal haemoglobin (HPFH) and 8 beta-thalassaemia have been mapped as a means of identifying regulatory sequences involved in the switch from fetal to adult globin gene expression. The end points of these deletions have been precisely located with respect to restriction endonuclease cleavage sites within and surrounding the gamma-, delta- and beta-globin genes in normal human DNA and the deletion maps were used to obtain definitive evidence for the physical linkage of the fetal and adult beta-like globin genes in the order 5'Ggamma-Agamma-delta-beta 3'. Correlation of haematological data and the location of deletions in two cases of HPFH and one case of deltabeta-thalassaemia suggest that a region of DNA located near the 5'-end of the delta-globin gene may be involved in the suppression in cis of gamma-globin gene expression in adults. The interpretation of a second case of deltabeta-thalassaemia is complicated by the fact that the deletion removes the Agamma-gene in addition to the region near the 5'-end of the delta-globin gene.     

Increased gamma-globin expression in a nondeletion HPFH mediated by an erythroid-specific DNA-binding factor

In man, a shift from gamma- to beta-globin gene expression in erythroblasts underlies a switch from fetal to adult haemoglobin during development. In hereditary persistence of fetal haemoglobin (HPFH), inappropriately high gamma-globin expression in adult life is associated with deletions in the beta-globin cluster or with single-base changes upstream of the gamma-globin genes. To account for enhanced gamma-gene expression in HPFH of the non-deletion type, we tested the nuclear proteins of human erythroleukaemia cells that bind gamma-promoter sequences in vitro by correlating specific mutations in their binding sites with promoter activity. An erythroid-specific factor (GF-1) binds as a single molecule to the -195 to -170 region and contacts two TATCT(AGATA) motifs, but not the conserved octamer (ATGCAAAT) that separates them. We observe that a single change (at -175, T----C) found in HPFH leads to increased promoter activity only in erythroid cells. This effect is mediated by GF-1, the human counterpart of the chicken erythroid factor Eryf 1. The form of HPFH we studied here is an inherited disorder which can be ascribed to the action of a cell-specific DNA-binding factor on a mutant promoter.     

A role for branchpoints in splicing in vivo

The nucleotides immediately surrounding intron/exon junctions of genes transcribed by RNA polymerase B can be derived from 'consensus' sequences for donor and acceptor splice sites by only a few base changes. Studies in vivo have underlined the importance of these junction nucleotides for splicing. In higher eukaryotes, no evidence has been found for specific internal intron sequences involved in splicing. However, the recent discovery that, in vitro, introns are excised in a lariat form where the 5' end of the intron is joined via a 2'-5'-phosphodiester linkage to an A residue (branchpoint acceptor) close to the 3' end of the intron, suggests that internal intron sequences may nonetheless be important for splicing. Indeed, in yeast nuclear genes, the internal sequence 5'-TACTAAC-3' (or close homologue) is essential for splicing in vivo. A proposed consensus sequence for branchpoints in mammalian introns is 5'-CT(A/G)A(C/T)-3'. This sequence resembles the essential yeast internal sequence. Are branchpoints involved in the splicing of introns of higher eukaryotes in vivo? We show here that a branchpoint sequence from a human globin gene (5'-CTGACTCTCTCTG-3') greatly enhances the efficiency of splicing of a 'synthetic' intron in HeLa cells. A mutated branchpoint sequence, 5'-CTCCTCTCTCTG-3', in which the branchpoint acceptor nucleotide A has been deleted and the neighbouring purine G mutated to a C, does not exhibit this enhancing capability. We conclude that branchpoints have an important function in the splicing process in vivo.     

Developmental regulation of human fetal-to-adult globin gene switching in transgenic mice

Transgenic mice containing a human fetal (gamma-) or adult (beta-) globin gene linked to the beta-globin gene locus activation region (LAR) express the gene throughout development. By contrast, transgenic mice containing LAR linked to both a fetal and an adult globin gene display the normal developmental switch from fetal to adult gene expression. This suggests that the human fetal-to-adult globin gene switch is controlled through a mutually exclusive interaction between LAR and either the gamma- or beta-globin gene, resulting in the expression of only one gene at any given moment.