Complex events in the evolution of the haptoglobin gene cluster in primates

Southern blot analyses of genomic DNA show that new world monkeys have only one haptoglobin gene but that chimpanzees, gorillas, orangutans, and old world monkeys have three. Humans have two: haptoglobin (Hp) and haptoglobin-related (Hpr). These observations suggest that a triplication of the haptoglobin locus occurred after the divergence of the new world monkeys, followed by a deletion of one locus in humans. To investigate these events, we have cloned the haptoglobin gene cluster in chimpanzee. The organization of the Hp and Hpr genes in chimpanzees is the same as in humans, including a retrovirus-like sequence in the first intron of Hpr. The third gene, which we name Hpp for haptoglobin primate, is 16 kilobases downstream of Hpr. A second copy of the retrovirus-like sequence occurs between Hpr and Hpp. The nucleotide sequence of the chimpanzee Hpp gene suggests that it may code for a functional protein, but the chimpanzee Hpr gene has a single base deletion in exon 5 that causes a frameshift. Comparison of the human and chimpanzee sequences suggests that the human Hpr gene was generated by a homologous unequal crossover between ancestral Hpr and Hpp genes. The crossover point lies within a 1.3-kilobase region containing exon 5 and 500 nucleotides 3' to the genes, but the exact point is obscured by a subsequent gene conversion event.     

Structure and expression of the human haptoglobin locus.

Human genomic clones of the haptoglobin Hp1F and the "haptoglobin related' gene (Hpr) have been isolated. The two genes are adjacent, spanning a region of approximately 21 kb. A comparison of their coding sequences shows that Hpr differs from Hp1F at 28 codons. Northern blot and primer elongation analyses with human liver RNA show that the haptoglobin gene Hp1F appears to be transcribed some 1000-fold less in fetal than in adult liver. In adult liver the amount of Hpr mRNA is at the lower limit of detection, therefore the extent of its expression is at most less than 1000-fold that of the Hp1F gene. No Hpr mRNA can be detected in fetal liver.     

Junctions between genes in the haptoglobin gene cluster of primates.

To investigate the nature of the recombination that generated the haptoglobin three-gene cluster in Old World primates, we sequenced the region between the second gene (HPR) and the third gene (HPP) in chimpanzees (15 kb), as well as the region 3' to the cluster in humans (14 kb). Comparison to the previously sequenced human haptoglobin (HP) and HPR genes showed that the junction point between HP and HPR in humans (junction 1) was not identical to the junction point between the HPR and HPP genes of the chimpanzee (junction 2). An Alu sequence was found at each junction, but both Alu sequences lacked short direct repeats of the flanking genomic DNA. The lack of direct repeats implies that both junction Alu sequences are the products of recombination between different Alu elements. In addition, other insertion and deletion events are clustered in the regions near the junction Alu sequences. The observation that Alu sequences define the junctions between genes in the haptoglobin gene cluster emphasizes the importance of Alu sequences in the evolution of multigene families.     

Molecular structure and flanking nucleotide sequences of the natural chicken ovomucoid gene

Five independent clones containing the natural chicken ovomucoid gene have been isolated from a chicken gene library. One of these clones, CL21, contains the complete ovomucoid gene and includes more than 3 kb of DNA sequences flanking both termini of the gene. Restriction endonuclease mapping, electron microscopy and direct DNA sequencing analyses of this clone have revealed that the ovomucoid gene is 5.6 kb long and codes for a messenger RNA of 821 nucleotides. The structural gene sequence coding Ifor the mature messenger RNA is split into at least eight segments by a minimum of seven intervening sequences of various sizes. The shortest structural gene segment is only 20 nucleotides long. All seven intervening sequences are located within the peptide coding region of the gene, and the sequences at the 5' and 3' untranslated regions of the mRNA are not interrupted by intervening sequences. The DNA sequences of the regions flanking the 5' and 3' termini of the gene have been determined. Thirty nucleotides before the start of the messenger RNA coding sequence is the heptanucleotide TATATAT, which is also present in a similar location relative to the chicken ovalbumin gene and other unique sequence eucaryotic genes. This sequence resembles that of the Pribnow box in procaryotic genes where a promoter function has been implicated. Seven nucleotides past the 3' end of the gene is the tetranucleotide TTGT, a sequence found to be present at identical locations as either TTTT or TTGT in other eucaryotic genes that have been sequenced. These conserved DNA sequences flanking eucaryotic genes may serve some regulator function in the expression of these genes.     

KpnI families of long, interspersed repetitive DNAs associated with the human β-globin gene cluster

KpnI families of long, interspersed repetitive DNAs are ubiquitous repetitive elements that occur in tens of thousands of copies in primate genomes. KpnI 1.2, 1.5 and two different KpnI 1.8-kb families were found within and flanking a 6.4-kb repeat beginning at 3 kb, 3' from the human β-globin gene. Thus, six different types of KpnI families have now been identified, and four of these are found next to each other in a specific 6.4-kb repeat. Clones of the distinct KpnI families were hybridized to clones of the 6.4-kb repeat and adjacent sequences encompassed within some 17.6 kb of DNA lying 3' to the β-globin gene cluster. The four KpnI families appear to make up the entire length of the 6.4-kb repeat. The linear order of the various cloned KpnI sequences in the repeat is 5'-pBK(1.8)26-pBK.(1.5)54-pBK(1.2)11-pBK(1.8)11-3'. KpnI 1.2-kb sequences were also detected downstream from the 6.4-kb repeat. As in the case of the KpnI 1.2 and 1.5-kb families, the two KpnI 1.8-kb sequence families described here each hybridized with about 15% of all plaques in two independently generated human genome libraries.     

Cloned embryonic DNA sequences flanking the mouse immunoglobulin C gamma 3 and C gamma 1 genes

To investigate the DNA surrounding genes for immunoglobulin heavy chain constant (CH) regions, we have isolated two clones bearing a C gamma 3 gene and two bearing a C gamma 1 gene from a library of mouse embryo DNA fragments. The C gamma 3 clones span 8.6 kilobase pairs (kb) on the 5' side of the gene and 6.7 kb on its 3' side, while the C gamma 1 clones together span 13 kb of 5' flanking sequence and 2.5 kb of 3' flanking sequence. Restriction mapping of the C gamma 3 gene indicates that intervening sequences divide the gene into segments of domain size, as in other CH genes. Hybridization of clone fragments to restriction digests of mouse DNA indicates that both the C gamma 1 and C gamma 3 genes probably occur as single copies in the genome. Moreover, the entire cloned sequences on the 5' side of both genes appear to be unique in the genome, indicating that no large common sequences flank CH genes. Restriction data suggest that the C gamma 3 gene is 37-40 kb 5' to the C gamma 1 gene.     

Transcriptional regulation of the human TATA binding protein gene

The human TATA binding protein (TBP) locus consists of a functional domain of three closely linkedhousekeeping genes (TBP, PSMB1 (proteasomal C5 subunit), and PDCD2 (programmed cell death-2)) within a 50-kb interval at chromosome position 6q27. Here we demonstrate that a genomic clone spanning the 20-kb TBP gene, with 12 kb 5' and 3' flanking sequences, was fully functional in stable, transfected L-cells harboring a single copy of this transgene, including after long-term (60 day) culture in the absence of drug selective pressure. Furthermore, we were only able to detect DNaseI hypersensitive sites at the TBP and PSMB1 promoters present within this 44-kb fragment. Our data suggest that this 44-kb genomic region possesses genetic regulatory elements that not only drive ubiquitous expression of TBP but also negate chromatin and DNA methylation induced silencing, which is normally associated with transgenes stably integrated into tissue culture cells.     

Evolution of a D. melanogaster glutamate tRNA gene cluster

We have determined the DNA sequence of a cloned cluster of essentially identical glutamate tRNA genes of D. melanogaster. The cluster consists of five genes: a gene triplet spanning approximately 0.55 kb followed by a 0.45 kb gene doublet 3.0 kb downstream. The genes are all arranged with the same polarity, do not encode the tRNA CCA end and contain no intervening sequences. Examination of the 5' and 3' sequences immediately flanking each gene reveals a striking pattern of sequence homologies between certain of the genes, which suggests a possible evolutionary history of this gene cluster. We propose that two ancestral genes each gave rise to gene doublets by duplication, while one of these gene pairs then gave rise, in turn, to a trio of genes as a result of unequal crossover.     

A rearranged DNA sequence possibly related to the translocation of immunoglobulin gene segments.

A 5.3 kb EcoRI fragment (T3, abbreviations in ref. 2) has been cloned from DNA of a kappa light chain producing mouse myeloma. The fragment hybridizes to the k' flanking sequences of the J1 gene segment but not to C gene sequences of kappa light chain DNA. Restriction nuclease mapping and partial nucleotide sequencing showed that the fragment consists of sequences from the 5' side of the J1 and form the 3' side of a V gene segment, which apparently had been linked in a genomic rearrangement process. These rearranged flanking sequences are not the flanking sequences of the V and J gene segments which had been joined to form the two kappa light chain genes of the myeloma. Fragments with the hybridization properties of T3 have been found also in two other kappa and one lambda chain producing myelomas. The linking of flanking sequences in the myeloma genome is discussed with respect to the mechanism of recombination between V and J gene segments.     

The haptoglobin-gene deletion responsible for anhaptoglobinemia.

We have found an allelic deletion of the haptoglobin (Hp) gene from an individual with anhaptoglobinemia. The Hp gene cluster consists of coding regions of the alpha chain and beta chain of the haptoglobin gene (Hp) and of the alpha chain and beta chain of the haptoglobin-related gene (Hpr), in tandem from the 5' side. Southern blot and PCR analyses have indicated that the individual with anhaptoglobinemia was homozygous for the gene deletion and that the gene deletion was included at least from the promoter region of Hp to Hpr alpha but not to Hpr beta (Hpdel). In addition, we found seven individuals with hypohaptoglobinemia in three families, and the genotypes of six of the seven individuals were found to be Hp2/Hpdel. The phenotypes and genotypes in one of these three families showed the father to be hypohaptoglobinemic (Hp2) and Hp2/Hpdel, the mother to be Hp2-1 and Hp1/Hp2, one of the two children to be hypohaptoglobinemic (Hp2) and Hp2/Hpdel, and the other child to be Hp1 and Hp1/Hpdel, showing an anomalous inheritance of Hp phenotypes in the child with Hp1. The Hp2/Hpdel individuals had an extremely low level of Hp (mean+/-SD = 0.049+/-0. 043 mg/ml; n=6), compared with the level (1.64+/-1.07 mg/ml) obtained from 52 healthy volunteers having phenotype Hp2, whereas the serum Hp level of an individual with Hp1/Hpdel was 0.50 mg/ml, which was approximately half the level of Hp in control sera from the Hp1 phenotype (1.26+/-0.33 mg/ml; n=9), showing a gene-dosage effect. The other allele (Hp2) of individuals with Hp2/Hpdel was found to have, in all exons, no mutation, by DNA sequencing. On the basis of the present study, the mechanism of anhaptoglobinemia and the mechanism of anomalous inheritance of Hp phenotypes were well explained. However, the mechanism of hypohaptoglobinemia remains unknown.     

Gene organization in the multiple DNA inversion region min of plasmid p15B of E.coli 15T-: assemblage of a variable gene.

The bacteriophage P1-related plasmid p15B of E. coli 15T- contains a 3.5 kb long region which frequently undergoes complex rearrangements by DNA inversion. Site-specific recombination mediated by the Min DNA invertase occurs at six crossover sites and it eventually results in a population of 240 isomeric configurations of this region. We have determined 8.3-kb sequences of the invertible DNA and its flanking regions. The result explains how DNA inversion fuses variable 3' parts to a constant 5' part, thereby alternatively assembling one out of six different open reading frames (ORF). The resulting variable gene has a coding capacity of between 739 and 762 amino acids. A large portion of its constant part is composed of repeated sequences. The p15B sequences in front of the variable fusion gene encode a small ORF and a phage-specific late promoter and are highly homologous to P1 DNA. Adjacent to the DNA invertase gene min, we have found a truncated 5' region of a DNA invertase gene termed psi cin which is highly homologous to the phage P1 cin gene. Its recombinational enhancer segment is inactive, but it can be activated by the substitution of two nucleotides.