Analysis of the closely linked adult chicken alpha-globin genes in recombinant DNAs

TMEM8 - a non-globin gene entrapped in the globin web

For more than 30 years it was believed that globin gene domains included only genes encoding globin chains. Here we show that in chickens, the domain of α-globin genes also harbor the non-globin gene TMEM8. It was relocated to the vicinity of the α-globin cluster due to inversion of an ∼170-kb genomic fragment. Although in humans TMEM8 is preferentially expressed in resting T-lymphocytes, in chickens it acquired an erythroid-specific expression profile and is upregulated upon terminal differentiation of erythroblasts. This correlates with the presence of erythroid-specific regulatory elements in the body of chicken TMEM8, which interact with regulatory elements of the α-globin genes. Surprisingly, TMEM8 is not simply recruited to the α-globin gene domain active chromatin hub. An alternative chromatin hub is assembled, which includes some of the regulatory elements essential for the activation of globin gene expression. These regulatory elements should thus shuttle between two different chromatin hubs.

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

BACKGROUND

Vertebrate alpha (alpha)- and beta (beta)-globin gene families exemplify the way in which genomes evolve to produce functional complexity. From tandem duplication of a single globin locus, the alpha- and beta-globin clusters expanded, and then were separated onto different chromosomes. The previous finding of a fossil beta-globin gene (omega) in the marsupial alpha-cluster, however, suggested that duplication of the alpha-beta cluster onto two chromosomes, followed by lineage-specific gene loss and duplication, produced paralogous alpha- and beta-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.

RESULTS

The platypus alpha-globin cluster (chromosome 21) contains embryonic and adult alpha- globin genes, a beta-like omega-globin gene, and the GBY globin gene with homology to cytoglobin, arranged as 5'-zeta-zeta'-alphaD-alpha3-alpha2-alpha1-omega-GBY-3'. The platypus beta-globin cluster (chromosome 2) contains single embryonic and adult globin genes arranged as 5'-epsilon-beta-3'. Surprisingly, all of these globin genes were expressed in some adult tissues. Comparison of flanking sequences revealed that all jawed vertebrate alpha-globin clusters are flanked by MPG-C16orf35 and LUC7L, whereas all bird and mammal beta-globin clusters are embedded in olfactory genes. Thus, the mammalian alpha- and beta-globin clusters are orthologous to the bird alpha- and beta-globin clusters respectively.

CONCLUSION

We propose that alpha- and beta-globin clusters evolved from an ancient MPG-C16orf35-alpha-beta-GBY-LUC7L arrangement 410 million years ago. A copy of the original beta (represented by omega in marsupials and monotremes) was inserted into an array of olfactory genes before the amniote radiation (>315 million years ago), then duplicated and diverged to form orthologous clusters of beta-globin genes with different expression profiles in different lineages.

Organisation of the Hb 1 genes of the Antarctic skate Bathyraja eatonii: new insights into the evolution of globin genes

An extensive investigation of the organisation of globin genes has greatly contributed to the understanding of universal mechanisms of gene evolution and expression. Cartilaginous fish are the first organisms that have evolved the tetrameric form of hemoglobin (Hb). So far, there has been absolute lack of data about globin genes in chondrichthyans. Bathyraja is the dominant rajid south of 60 degrees S. In the framework of the investigations on globin genes of Antarctic red-blooded and Hb-less fish we obtained the cloning of the alpha- and beta-globin cDNAs of the main Hb (Hb 1) of the skate Bathyraja eatonii. Then, a genomic fragment of 6.2 kb was isolated where the Hb 1 alpha and beta genes are linked in a tail-to-head (3' to 5') orientation. The beta-globin gene promoter region and the chromosomal organisation of the Hb 1 genes of B. eatonii have been compared to their homologues in other vertebrates. The finding of a tail-to-head linkage of the Hb 1 alpha- and beta-globin genes in B. eatonii is the first characterisation of the organisation of globin genes in chondrichthyes; such finding offers a novel contribution to the understanding of the evolution of this class of genes. Moreover, the characterisation of chondrichthyan genes is very important for gaining insight into the ancestral state of vertebrate genomes.

The mammalian αD-globin gene lineage and a new model for the molecular evolution of α-globin gene clusters at the stem of the mammalian radiation

We have explored the evolution of the alpha-globin gene family by comparative sequence and phylogenetic analyses of mammalian alpha-globin genes. Our analyses reveal the existence of a new alpha-globin gene lineage in mammals that is related to the alpha(D)-globin genes of birds, squamates and turtles. The gene is located in the middle of the alpha-globin gene cluster of a marsupial, Sminthopsis macroura and of humans. It exists in a wide variety of additional mammals, including pigs, cows, cats, and dogs, but is a pseudogene in American marsupials. Evolutionary analyses suggest that the gene has generally evolved under purifying selection, indicative of a functional gene. The presence of mRNA products in humans, pigs, and cows also suggest that the gene is expressed and likely to be functional. The analyses support the hypothesis that the alpha(D)-globin gene lineage has an ancient evolutionary origin that predates the divergence of amniotes. The structural similarity of alpha-globin gene clusters of marsupials and humans suggest that an eight gene cluster (5'-zeta2-zeta1-alpha(D)-alpha3-alpha2-alpha1-theta-omega-3'), including seven alpha-like genes and one beta-like globin gene (omega-globin) existed in the common ancestor of all marsupial and eutherian mammals. This basic structure has remained relatively stable in marsupials and in the lineage leading to humans, although omega-globin has been lost from the alpha-globin gene cluster of humans.

Annotation of cis-regulatory elements by identification, subclassification, and functional assessment of multispecies conserved sequences

An important step toward improving the annotation of the human genome is to identify cis-acting regulatory elements from primary DNA sequence. One approach is to compare sequences from multiple, divergent species. This approach distinguishes multispecies conserved sequences (MCS) in noncoding regions from more rapidly evolving neutral DNA. Here, we have analyzed a region of approximately 238kb containing the human alpha globin cluster that was sequenced and/or annotated across the syntenic region in 22 species spanning 500 million years of evolution. Using a variety of bioinformatic approaches and correlating the results with many aspects of chromosome structure and function in this region, we were able to identify and evaluate the importance of 24 individual MCSs. This approach sensitively and accurately identified previously characterized regulatory elements but also discovered unidentified promoters, exons, splicing, and transcriptional regulatory elements. Together, these studies demonstrate an integrated approach by which to identify, subclassify, and predict the potential importance of MCSs.

Mapping of alpha- and beta-globin genes on Antarctic fish chromosomes by fluorescence in-situ hybridization

The pathways and mechanisms of genomic change that have led to the peculiar haemoglobinless phenotype of the white-blooded Antarctic icefishes (16 species in the family Channichthyidae) constitute an important model for understanding the rapid diversification of the Antarctic notothenioid fish flock. To provide complementary structural information on genomic change at globin-gene loci in Antarctic fish species, cytogenetic studies and in-situ chromosomal mapping have been undertaken. Using a DNA probe containing one alpha- and one beta-globin gene from the embryonic/juvenile globin gene cluster of the red-blooded species Notothenia coriiceps, we mapped the cluster on the chromosomes of Antarctic teleosts by fluorescence in-situ hybridization. As anticipated on the basis of its molecular organization, the cluster was located on a single chromosome pair in all of the red-blooded fish species probed (N. coriiceps, N. angustata, Trematomus hansoni, T. pennellii). In contrast, the alpha/beta-globin probe did not recognize complementary sequences on the chromosomes of the white-blooded species Chionodraco hamatus and Channichthys rhinoceratus. These results represent the first example of chromosomal mapping of embryonic/juvenile globin genes in teleostean fishes. Beyond its relevance to the evolutionary history of Antarctic notothenioids, this work contributes to our understanding of the evolution of the chromosomal loci of globin genes in fishes and other vertebrates.

The 33 kb transcript of the chicken ?-globin gene domain is part of the nuclear matrix

Giant nuclear transcripts, and in particular the RNAs of the globin gene domains which are much larger than their canonical pre-mRNAs, have been an enigma for many years. We show here that in avian erythroblastosis virus (AEV)-transformed chicken erythroleukaemic cells, where globin gene expression is abortive, the whole domain of alpha-globin genes is transcribed for about 33 kb in the globin direction and that this RNA is part of the nuclear matrix. Northern blot hybridisation with strand-specific riboprobes, recognising genes and intergenic sequences, and RT-PCR with downstream primers, show that the continuous full domain transcript (FDT) starts in the vicinity of a putative LCR and includes all the genes as well as known regulatory sites, the replication origin, and the DNA loop anchorage region in the upstream area. Absent in chicken fibroblasts, the globin FDT overlaps the major part of the ggPRX housekeeping gene that is transcribed in the opposite direction. RT-PCR and in situ hybridisation with genic and extra-genic globin probes demonstrated that the globin FDT is a component of the nuclear matrix. We suggest that the globin FDTs keep the domain in an active state, and the globin RNAs on the processing pathway are a component of the nuclear matrix. They may take part in the dynamic nuclear architecture when productively processed, or turn over slowly when globins are not synthesised.

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.

Non-clonability correlates with genomic instability: a case study of a unique DNA region

Instability of eukaryotic DNA in constructs propagated in prokaryotic hosts is a frequently observed phenomenon. With the exception of a very high A+T-content and the presence of multiple repetitions, no general rule at the basis of this phenomenon is actually known. The intergenic spacer located between the pi and alpha(D) chicken alpha-type globin genes is frequently deleted from recombinant phages and plasmids. Here we have cloned this DNA fragment using a specially designed bacterial strain (SURE competent cells, Stratogene). Comparative analysis of DNA of recombinant clones bearing deletions and clones containing the intact genomic DNA fragment has revealed two important DNA sequence motifs that contribute to the unclonability of eukaryotic DNA in prokaryotic cells. First, the similarity to bacterial transposons (i.e. the presence of repeats flanking a several kilobase DNA fragment) may cause the loss of the fragment during propagation of the recombinant DNA in E. coli. Second, a high content of rotationally correlated kinkable elements (TG*CA steps) may result in non-clonability of the DNA sequence. Interestingly, the latter type of "unclonable" DNA sequence motifs identified in the globin gene domain is unstable (frequently rearranged) also in the eukaryotic chromosome resulting in a local polymorphism. In the chicken domain of alpha globin genes this unstable DNA sequence seems to be partially protected by interaction with nuclear matrix proteins.

Mechanism of developmental regulation of alpha pi, the chicken embryonic alpha-globin gene

The chicken alpha pi-globin gene is expressed during development only in the primitive erythrocyte lineage and not in the definitive lineage. We show that stage-specific expression is maintained when plasmids containing the alpha pi promoter are transfected into primitive and definitive lineage primary erythroid cells and that the information contained in the promoter is sufficient to confer this specificity. Detailed analysis of binding sites in the promoter for trans-acting factors, together with studies of the effects of mutagenesis on expression, reveals that the factors critical to stage-specific expression are all present in both primitive and definitive lineages, but at various concentrations. We identify three proteins, an NF1 family member, a Y-box factor, and an Sp1-like factor, which interact to stimulate or inhibit transcription. We propose that the concentration-dependent action of these factors, together with the general erythroid factor GATA-1, is responsible for the stage-specific expression of the alpha pi-globin gene.

Mechanism of developmental regulation of alpha pi, the chicken embryonic alpha-globin gene

The chicken alpha pi-globin gene is expressed during development only in the primitive erythrocyte lineage and not in the definitive lineage. We show that stage-specific expression is maintained when plasmids containing the alpha pi promoter are transfected into primitive and definitive lineage primary erythroid cells and that the information contained in the promoter is sufficient to confer this specificity. Detailed analysis of binding sites in the promoter for trans-acting factors, together with studies of the effects of mutagenesis on expression, reveals that the factors critical to stage-specific expression are all present in both primitive and definitive lineages, but at various concentrations. We identify three proteins, an NF1 family member, a Y-box factor, and an Sp1-like factor, which interact to stimulate or inhibit transcription. We propose that the concentration-dependent action of these factors, together with the general erythroid factor GATA-1, is responsible for the stage-specific expression of the alpha pi-globin gene.

Organization of specific DNA sequence elements in the region of the replication origin and matrix attachment site in the chicken alpha-globin gene domain

The distribution of specific DNA sequence elements in a 2.9 kb HindIII fragment of chicken DNA containing the replication origin and the upstream matrix attachment site (MAR) of the alpha-globin gene domain was investigated. The fragment was shown to contain a CR1-type repetitive element and two stably bent DNA sequences. One of them colocalizes with the previously described MAR element and with the recognition site for a proliferating-cell-specific, DNA-binding protein. The melting pattern of a set of subfragments of the region proved to be non random. No correlation between the distribution of readily melting sequences and bent DNA was found. The possible importance of curved, low-melting and repetitive DNA sequences for the organization of the upstream boundary of the alpha-globin gene domain and the function of the replication origin is discussed.

Precise localization of the alpha-globin gene cluster within one of the 20- to 300-kilobase DNA fragments released by cleavage of chicken chromosomal DNA at topoisomerase II sites in vivo: evidence that the fragments are DNA loops or domains

We have mapped the position of the alpha-globin gene cluster in the 20- to 300-kilobase fragments of chromosomal DNA isolated from growing chicken HD3 erythroblastoid cells exposed to 4'-demethylepipodophyllotoxinthenylidene beta-D-glucoside. This epipodophyllotoxin traps functioning topoisomerase II molecules, the denaturation of which cleaves DNA and reveals their reaction sites. The DNA fragments, prepared by centrifugation in sucrose gradients, bind selectively to glass-fiber filters and are protected from lambda 5'-exonuclease, properties compatible with the presence of a topoisomerase II subunit bound to their 5' ends. Restriction enzyme cleavage of the fragments and hybridization with cloned alpha-globin-region probes reveal additional distinctive bands not seen in control DNA, allowing the localization of fragment ends near this gene cluster. The terminal regions of fragments from sucrose gradients or from field-inversion electrophoresis gels were also used to probe cloned regions of the gene cluster. Both approaches show that this cluster of three genes, which is not expressed in these cells, is located at a specific position in a approximately 20-kilobase DNA fragment. The upstream end of this fragment lies in a region that contains a site of DNA attachment to the nuclear matrix mapped by both in vivo and in vitro methods, and its downstream end is flanked by approximately 80% A + T sequences characteristic of matrix-attachment regions. These observations suggest that the DNA fragments are formed because topoisomerase II molecules can specifically and readily integrate into DNA at matrix-attachment regions and that the fragments represent entire DNA loops or domains.

Specific cleavage of chicken alpha A-globin and human c-Ha-ras genes by two molecular forms of calf thymus topoisomerase I

Two molecular forms of topoisomerase I differing in size and sensitivity to camptothecin were isolated from calf thymus. Mapping of topo I cleavage sites of the cloned chicken alpha A-globin and human c-Ha-ras genes was carried out. Camptothecin was shown to affect site specificity of the topoisomerases.

Mapping of structural and transcription-related matrix attachment sites in the alpha-globin gene domain of avian erythroblasts and erythrocytes

The positions of preferential DNA interaction with the nuclear matrix were mapped within the domain of the chicken alpha-globin genes in transcriptionally active erythroblast nuclei and inactive nuclei of mature erythrocytes. In the latter, only two major distinct attachment sites were observed, close to the A + T-rich sequences previously found at the boundaries of the domain. Sequencing of these structural matrix attachment points revealed several known DNA motifs; some of them were present on both sides of the domain. In actively transcribing erythroblast nuclei of adult animals, a large fraction of the transcribed area was represented in nuclear matrix DNA, including upstream and downstream elements. In particular, adult alpha A- and alpha D-globin genes were found in matrix DNA, while the transcribed but translationally unexpressed embryonic pi gene was underrepresented. The data are discussed in terms of the existence of stable or structural and expression-related matrix attachment sites; correlations to the origin of replication and the units of transcription of the domain are shown.

Mapping of structural and transcription-related matrix attachment sites in the alpha-globin gene domain of avian erythroblasts and erythrocytes

The positions of preferential DNA interaction with the nuclear matrix were mapped within the domain of the chicken alpha-globin genes in transcriptionally active erythroblast nuclei and inactive nuclei of mature erythrocytes. In the latter, only two major distinct attachment sites were observed, close to the A + T-rich sequences previously found at the boundaries of the domain. Sequencing of these structural matrix attachment points revealed several known DNA motifs; some of them were present on both sides of the domain. In actively transcribing erythroblast nuclei of adult animals, a large fraction of the transcribed area was represented in nuclear matrix DNA, including upstream and downstream elements. In particular, adult alpha A- and alpha D-globin genes were found in matrix DNA, while the transcribed but translationally unexpressed embryonic pi gene was underrepresented. The data are discussed in terms of the existence of stable or structural and expression-related matrix attachment sites; correlations to the origin of replication and the units of transcription of the domain are shown.

Organization of the 3'-boundary of the chicken alpha globin gene domain and characterization of a CR 1-specific protein binding site

The sequence of a DNA fragment about 1 Kbp long located at the 3' boundary of the chicken alpha globin gene domain, including the 3'-side matrix attachment point and the site of transcription termination, was determined. It contains a repetitive DNA element and the AT-rich (easily denaturable) DNA segment conserved at the same position in the duck genome. The repetitive sequence was identified by computer analysis as being a member of the CR1 family. Within the non-repetitive part of the AT-rich DNA fragment, four topoisomerase II recognition sites were found which might be indicative of matrix attachment. Furthermore, two distinct regions were identified, possessing strong homology to a number of noncoding consensus sequences, one of them to a limited part of the LTR of HTLVIII, and the other to the replication origin of Polyoma virus JC. DNA shift experiments showed that the CR1 repeat binds specifically an abundant nuclear protein factor. The binding site for this factor was identified by footprinting and turned out to be closely related to the previously described recognition site for the TGGCA-binding protein, the chicken analog of nuclear factor 1 (NF-1). Finally, the CR1 repeats within the chicken alpha and beta globin gene domains were mapped. All these observations are discussed in terms of the organization of the 5' and 3' boundaries of the functional genomic domains forming a chromatin loop including all avian alpha type globin genes.

Transcription of the alpha globin gene domain in normal and AEV-transformed chicken erythroblasts: mapping of giant globin-specific RNA including embryonic and adult genes

The genomic domain of about 20 kbp of the chicken alpha-type globin genes, framed by AT-rich linkers (ATRLs; Moreau et al. 1982) and repetitive sequences (Broders et al. 1986), was cut into 13 fragments and subcloned. The in vitro labelled individual restriction fragments were used to test the extent of the transcribed domain by blot-hybridization of nuclear RNA in large excess from normal adult chicken and Avian Erythroblastosis Virus (AEV)-transformed erythroblasts. In both these types of cells, the AT-rich segments situated 6 kbp upstream of the first gene as well as all the domain including the embryonic pi and the adult alpha D and alpha A genes down to the AT-rich segment placed 3 kbp downstream were found to be transcribed. Electrophoresis of nuclear RNA, Northern blotting and hybridization with most of the nick-translated DNA probes revealed in all cases the presence of heterogeneous globin RNA molecules in the 3-12 kb range, as well as some distinct RNA bands. Single-stranded RNA probes of some genomic segments indicated asymmetrical transcription of the minus strand. A 12 kb globin-specific RNA including the pi and alpha A genes but not the intervening alpha D gene was observed in AEV-transformed cells: it includes sequences located far upstream and downstream from the alpha globin genes and might represent a processing product of a full length transcript spanning the whole domain. Reverse transcription by extension of primers placed in the first exon of each of the three globin genes confirmed the presence of continuous transcripts of the domain including the two adult and the embryonic globin genes.

Varied interactions between proviruses and adjacent host chromatin

Retroviruses integrated at unique locations in the host genome can be expressed at different levels. We have analyzed the preintegration sites of three transcriptionally competent avian endogenous proviruses (evs) to determine whether the various levels of provirus expression correlate with their location in active or inactive regions of chromatin. Our results show that in three of four cell types, the chromatin conformation (as defined by relative nuclease sensitivity) of virus preintegration sites correlates with the level of expression of the resident provirus in ev+ cells: two inactive proviruses (ev-1 and ev-2) reside in nuclease-resistant chromatin domains and one active provirus (ev-3) resides in a nuclease-sensitive domain. Nuclear runoff transcription assays reveal that the preintegration sites of the active and inactive viruses are not transcribed. However, in erythrocytes of 15-day-old chicken embryos (15d RBCs), the structure and activity of the ev-3 provirus is independent of the conformation of its preintegration site. In this cell type, the ev-3 preintegration site is organized in a nuclease-resistant conformation, while the ev-3 provirus is in a nuclease-sensitive conformation and is transcribed. In addition, the nuclease sensitivity of host sequences adjacent to ev-3 is altered in ev-3+ 15d RBCs relative to that found in 15d RBCs that lack ev-3. These data suggest that the relationship between preintegration site structure and retrovirus expression is more complex than previously described.

Varied interactions between proviruses and adjacent host chromatin

Retroviruses integrated at unique locations in the host genome can be expressed at different levels. We have analyzed the preintegration sites of three transcriptionally competent avian endogenous proviruses (evs) to determine whether the various levels of provirus expression correlate with their location in active or inactive regions of chromatin. Our results show that in three of four cell types, the chromatin conformation (as defined by relative nuclease sensitivity) of virus preintegration sites correlates with the level of expression of the resident provirus in ev+ cells: two inactive proviruses (ev-1 and ev-2) reside in nuclease-resistant chromatin domains and one active provirus (ev-3) resides in a nuclease-sensitive domain. Nuclear runoff transcription assays reveal that the preintegration sites of the active and inactive viruses are not transcribed. However, in erythrocytes of 15-day-old chicken embryos (15d RBCs), the structure and activity of the ev-3 provirus is independent of the conformation of its preintegration site. In this cell type, the ev-3 preintegration site is organized in a nuclease-resistant conformation, while the ev-3 provirus is in a nuclease-sensitive conformation and is transcribed. In addition, the nuclease sensitivity of host sequences adjacent to ev-3 is altered in ev-3+ 15d RBCs relative to that found in 15d RBCs that lack ev-3. These data suggest that the relationship between preintegration site structure and retrovirus expression is more complex than previously described.

Replication origins are attached to the nuclear skeleton

DNA fragments containing replication origins (oriDNA) were isolated from a chicken erythroblast cell line by a modified procedure of Zannis-Hadjopoulos et al. and studied in the renaturation reaction driven by either total or nuclear matrix DNA (nmDNA) from the same cells or from mature erythrocytes. We found that the unique sequences of nmDNA from erythroblasts (5 kb long) represented a specific subset of sequences constituting about a quarter of total DNA unique sequences, while the erythrocyte nmDNA 5 kb fragments constitute only about one tenth of total unique DNA and all are recovered among erythroblast nmDNA. Virtually all oriDNA sequences are present in the fraction of erythrocyte nmDNA. Thereafter, the putative positions of replication origins within the alpha-globine gene domain have been mapped by hybridization experiments. They were found to coincide with the previously established positions of permanent sites of DNA attachment to the nuclear matrix.

Replacement variant histone genes contain intervening sequences

The nucleotide sequences of two chicken histone genes encoding replacement variant H3.3 polypeptides are described. Unlike the replication variant genes of chickens (and almost all other organisms), these genes contain intervening sequences; introns are present in both genes in the 5' noncoding and coding sequences. Furthermore, the replacement variant histone mRNAs are post-transcriptionally polyadenylated. The locations, but not the sizes, of the two introns within the coding segments of the two genes have been exactly conserved, whereas the intron positions in their respective 5' flanking regions differ. Although both H3.3 genes predict the identical histone polypeptide sequence, they are as different from one another as each of them is from a more common replication variant H3.2 gene in silent base substitutions within the coding sequences. Thus, the H3.3 polypeptide sequence has been precisely maintained over a great evolutionary period, suggesting that this class of histones performs a strongly selected biological function. Although replacement variant histones can account for more than 50% of the total H3 protein in the nuclei of specific chicken tissues, the steady-state level of H3.3 mRNA is nearly the same (and is quite low) in all tissues and ages of animals examined. These properties suggest novel mechanisms for the control of the basal histone biosynthesis which takes place outside of the S phase of the cell cycle.

Replacement variant histone genes contain intervening sequences

The nucleotide sequences of two chicken histone genes encoding replacement variant H3.3 polypeptides are described. Unlike the replication variant genes of chickens (and almost all other organisms), these genes contain intervening sequences; introns are present in both genes in the 5' noncoding and coding sequences. Furthermore, the replacement variant histone mRNAs are post-transcriptionally polyadenylated. The locations, but not the sizes, of the two introns within the coding segments of the two genes have been exactly conserved, whereas the intron positions in their respective 5' flanking regions differ. Although both H3.3 genes predict the identical histone polypeptide sequence, they are as different from one another as each of them is from a more common replication variant H3.2 gene in silent base substitutions within the coding sequences. Thus, the H3.3 polypeptide sequence has been precisely maintained over a great evolutionary period, suggesting that this class of histones performs a strongly selected biological function. Although replacement variant histones can account for more than 50% of the total H3 protein in the nuclei of specific chicken tissues, the steady-state level of H3.3 mRNA is nearly the same (and is quite low) in all tissues and ages of animals examined. These properties suggest novel mechanisms for the control of the basal histone biosynthesis which takes place outside of the S phase of the cell cycle.

Hemoglobin I mutation encoded at both alpha-globin loci on the same chromosome: concerted evolution in the human genome

Genetic analysis of an individual expressing an unexpectedly high level of hemoglobin I, an alpha-globin structural mutant, reveals that the mutation is present at both the alpha 1- and the alpha 2-globin gene loci. Kindred analysis confirms that the two affected genes are located in cis. The most likely explanation for this finding is that a recent conversion event occurred within the human alpha-globin gene cluster.

An unusual 5' splice sequence is efficiently utilized in vivo

The minor adult chicken alpha-globin gene (alpha D) has an intron splicing sequence at the 5' end of the second intron that begins with the dinucleotide G-C rather than the usual G-T. To understand what role this splice sequence plays in the processing and maturation of nuclear RNA to cytoplasmic RNA, we have analyzed the intron processing of the alpha D-globin transcript in both heterologous (monkey) and homologous (chicken) cells using simian virus 40 and retrovirus vectors, respectively. In both cell types, both introns of the alpha D-globin gene are efficiently and precisely removed.

Structural and evolutionary analysis of the two chimpanzee alpha-globin mRNAs

Two distinct alpha-globin mRNAs were detected in chimpanzee reticulocyte mRNA using a primer extension assay. DNA copies of these two mRNAs were cloned in the bacterial plasmid pBR322, and their sequence was determined. The two alpha-globin mRNAs have obvious structural homology to the two human alpha-globin mRNAs, alpha 1 and alpha 2. Comparison of the two chimpanzee alpha-globin mRNAs to each other and to their corresponding human counterparts revealed evidence of a recent gene conversion in the human alpha-globin complex and a marked heterogeneity in the rate of structural divergence within the alpha-globin gene.

Determination of the primary sequence of the duck alpha D globin mRNA and comparison of all adult duck and chick globin mRNA sequences

The nucleotide sequence of the duck alpha D globin mRNA was determined. Its main feature is an exceptionally short 3' non-coding segment of only 46 nucleotides, placed after the coding sequence of 141 codons. The last of the 6 adult globin mRNA of duck and chicken being thus sequenced, a comparison of all their features has become possible. Comparing the duck alpha D mRNA to the related sequence in the chicken, we found greater homology than comparing it to the linked alpha A globin sequence in the same species. Extensive homology can be found for a same globin chain alpha A, alpha D or beta in between different avian species including also the goose and the ostrich; the avian alpha globin chains show a lower degree of sequence conservation in between species than the beta chains. In contrast, within one species the three globin sequences have further diverged. The divergence between the alpha A and alpha D globin within a same species point to individual functional specificity and hence independent evolution and suggest that a mechanism of 'gene conversion' did not operate in between the avian alpha globin genes. Two segments of the amino acid sequence which we named 'A alpha' and 'B alpha' remain homologous in all avian alpha globins; two other regions 'A beta' and 'B beta' are identical in between the beta globins. Segment A is placed at the 5' end of exon II, and segment B at the 3' end of the same exon; some amino acids in those segments are involved in the Heme binding site. Being almost identical in all know mammalian and avian globins of the alpha respectively the beta type, regions A and B seem to represent the best conserved sequences in adult globin mRNA maintained during the divergence of species.

Unusual structure of the chicken embryonic alpha-globin gene, pi'

We report the DNA sequence of the globin locus encoding the chicken embryonic alpha-globin, pi'. The structure differs significantly from that of the two chicken adult alpha-globin genes, alpha A and alpha D, as well as from that of previously studied adult alpha-globin genes in that the introns of the pi' gene are substantially larger than those in adult alpha-globin loci. In contrast, the pi' introns are structurally similar to the only other expressed embryonic alpha-globin gene reported to date, the human zeta gene. While completing the sequence of the pi' gene, we determined that only one chromosomal locus within the chicken genome hybridizes to a pi' central exon probe. These data lead to the conclusion that if the equimolar chicken embryonic alpha-globin polypeptides, called pi and pi', are indeed independently transcribed, then that transcription occurs from alleles of the same gene; however, we favor the possibility that the pi gene does not actually exist. This conclusion is drawn from the observation that the two chromosomal alleles of embryonic alpha-globins (represented by recombinant bacteriophage lambda CaG5 and lambda CaG7) both encode pi'.

Relationship between the total size of exons and introns in protein-coding genes of higher eukaryotes

We have attempted to ascertain the correlation between the genetic information content in the exons and the surrounding intron sequences with regard to their spatial arrangement within a gene. A comparison is made of the sizes, taken from recent publications, of exons and introns of approximately equal to 80 different protein-coding chromosomal genes, mostly from higher eukaryotes. The exons of these genes do not show very marked variation in size and can be classified into three major discrete and two minor additional size groups, whereas individual introns vary considerably in size within and between genes. Notwithstanding, the overall length of all introns present within a given gene is a function of the total size, mostly corresponding to the total genetic information content, of the exons. Three cases that violate this exon-size dependency of introns are genes coding for (i) histone H1, feather keratin, and interferons, (ii) tubulin and actin, and (iii) silk fibroin. The exons of these genes are larger than 0.7 kilobase pair in total size and the genes show a strong sequence homogeneity among the repetitious family members or internal repeats of coding sequences within the gene. We propose that conservation of sequences, which is required by the family members, internal repeats, or the entire gene, would actually motivate the removal of introns.

Translocation of immunoglobulin VH genes in Burkitt lymphoma

We have produced cell hybrids between mouse myeloma cells, which do not produce immunoglobulin chains, and Burkitt lymphoma cells (Daudi), which express surface IgM. Daudi Cells carry a reciprocal chromosome translocation between chromosomes 8 and 14, described as (8;14)(q24;q32). The hybrids were studied for the expression of human immunoglobulin chains and human isozyme markers, for the presence of human chromosomes, and for the presence of the human genes for heavy chain variable regions (VH) and mu and gamma chain constant (C) regions. The results indicate that the expressed mu chain gene is on normal chromosome 14 in Daudi cells. We have also determined that the chromosome 14 involved in the translocation (14q+) carries the gene for C mu and C gamma 1-4 and probably several genes for the variable region (V). Certain hybrids had lost both the chromosomes 14 but had retained the abnormal chromosome 8 (8q-) that carries the terminal end of the long arm of chromosome 14. These hybrids were studied for the presence of human VH, C mu,, and C gamma DNA sequences, and the results indicated that the hybrid cells with the 8q- chromosome contained VH genes that not C genes. Therefore, we conclude that, in the Daudi Burkitt lymphoma, the break in chromosome 14 occurred within the chromosome segment containing V region genes. As a result of the translocation some of these VH genes became associated with chromosome 8. It is possible that the expression of malignancy in Burkitt lymphoma is caused by immunoglobulin V region gene translocation resulting in activation of a gene on the long arm of human chromosome 8.

Clustered genes require extragenic territorial DNA sequences

This paper is concerned with the basic question as to whether there exists a complex interaction between DNA sequences which have little specific function and functional genes regarding the spatial arrangement of the gene. Since gene clusters are a characteristic and basic feature of gene structure in higher eukaryotes, the size of extragenic DNA sequences surrounding the individual genes of various clustered gene families were compared. The size of the intergenic region, which is composed of the extragenic DNA sequences flanking the 3'-end of one gene and those flanking the 5'-end of the other gene, of the paired genes increases as the genes becomes larger. However, such a gene size-dependent increase is not seen if the total gene size of the paired genes is less than 0.3 kb or greater than 4 kb. The results suggests that a higher eukaryote gene requires extragenic territorial DNA sequences surrounding it, which presumably are necessary to maintain the gene's active functions.

Restriction patterns of adult chicken globin genes at early and late stages of embryonic development

Globin mRNA isolated from anemic chicken was transcribed into cDNA and integrated into the Pst I cleavage site of plasmid pBR 322. After cloning in E. coli strain HB 101 and colony hybridization with 125I-labelled globin mRNA the plasmids of individual clones were characterized by hybrid arrested cell-free translation. Thus we could isolate clones containing alpha or beta globin chain nucleotide sequences. DNA was isolated from chicken blastoderms incubated for 18-20 h and from 11 d chicken embryos. A comparison of the restriction maps of the DNA from the two developmental stages with labelled nick translated plasmids and labelled cDNA did not indicate any globin gene rearrangements between these two stages of embryonic development. We conclude, that the adult chicken globin genes show a constant genomic organization during embryonic development. However, the restriction patterns of the globin gene family of the chicken strain investigated revealed some differences after 2 generations of propagation.

Adult chicken alpha-globin genes alpha A and alpha D: no anemic shock alpha-globin exists in domestic chickens

Three alpha-type globin genes have been identified in the alpha-globin linkage group of chickens. No other alpha-type genes hae been directly shown to be within 10 kilobase pairs of any of these three closely linked genes. These three genes have been conclusively identified by DNA sequence analysis. The gene at the 5' end of the linkage group is an embryonic alpha-type globin gene, pi or pi', and the central gene corresponds to the minor adult alpha- globin, alpha D. The 3'-terminal gene sequence corresponds to the sequence of cDNA clones previously described as "alpha S", presumed anemic shock-induced alpha-globin gene [Salser, W. A., Cummings, I., Liu, A., Strommer, J., Padayatty, J. & Clarke, P. (1979) in Cellular and Molecular Regulation of Hemoglobin Switching, eds. Stamatoyannopoulos, G. & Nienheis, A. (Grune and Stratton, New York), pp. 621-643; Richards, R. I. & Wells, J. R. E. (1980) J. Biol. Chem. 255, 9306-9311]. Several groups of workers have isolated alpha S-type cDNA clones but no one has identified a cDNA clone corresponding to the published amino acid sequence of the major chicken alpha-globin, alpha A. We have identified the alpha S-type sequence as the only abundant alpha-like globin sequence in cDNA clones made from reticulocyte mRNA isolated from nonanemic chickens. Therefore, we suggest that the alpha S-type sequence corresponds to the true alpha A-globin species.

Mouse alpha-globin genes and alpha-globin-like pseudogenes are not syntenic

A genetic polymorphism for a Bgl I endonuclease site near the alpha-globin-like pseudogene alpha-4 of C57BL/6 and C3H/HeN mice was used to show that alpha-4 was not affected by three independent mutations in which the adult globin genes alpha-1 and alpha-2 were deleted. These results indicated that alpha-4 might not be located adjacent to the adult alpha-globin genes on chromosome 11. Restriction endonuclease analysis of DNA of a primary clone of a Chinese hamster--mouse somatic cell hybrid that had lost mouse chromosomes 11 and 18 showed that this clone lacked the adult murine globin genes alpha-1 and alpha-2 but it did contain the alpha-globin-like pseudogenes alpha-3 and alpha-4. These results indicated that the adult alpha-globin genes and alpha-globin-like pseudogenes are not located on the same chromosome. Similar analyses of several other Chinese hamster--mouse somatic cell hybrids that had segregated other mouse chromosomes indicated that the alpha-globin-like pseudogenes alpha-3 and alpha-4 are located on mouse chromosomes 15 and 17, respectively. These data explain why alpha-3 and alpha-4 were not affected by the three independently induced deletion-type mutations that cause alpha-thalassemia in the mouse.