Deoxynucleotide sequence of an insect cDNA codes for an unreported member of the Chironomus thummi globin family

Synthetic oligonucleotides served as probes to isolate insect globin clones from a Chironomus thummi cDNA bank. The cDNA insert of one clone (pC-S9) was completely sequenced by the dideoxy termination procedure. Beginning at the 5' end of the coding region, the 584 base pair sequence encodes most of an N-terminal hydrophobic signal sequence and the complete sequence for a mature secreted globin, and contains a polyadenylation recognition site 3' to an appropriate stop codon. The inferred amino acid sequence is that of an unreported variant of hemoglobin VIIB. Based on the number of differences between Hb VIIB chains, the pC-S9 gene has been evolutionarily independent longer than the other (two) members of the globin VIIB subfamily.     

Genomic organization and primary structure of five homologous pairs of intron-less genes encoding secretory globins from the insect Chironomus thummi thummi

From a Chironomus thummi thummi genomic library we have isolated two distinct recombinant phages, CttG-1 and CttG-3, each carrying a cluster of five homologous globin genes. In addition to the previously reported nucleotide sequence of globin gene D (Antoine and Niessing, 1984) we present the chromosomal arrangement, primary structure and predicted amino acid sequence of nine globin genes. The divergently transcribed globin genes all lack introns, they encode secretory preglobins each containing a highly conserved signal peptide. The amino acid sequences deduced from the globin genes correspond to globin III and variants thereof, to globin IV, and to a novel globin, whose direct amino acid sequence has not yet been reported.     

Hemoglobins. XXVI. Analysis of the primary structure of the dimeric insect haemoglobin CTT VIIB (Erythrocruorin) from Chironomus thummi thummi, Diptera]

The dimeric haemoglobin CTT VIIB (Erythrocruorin) of Chironomus thummi thummi, Diptera, has been sequenced. Either globin or globin with maleic acid blocked lysines were cleaved with trypsin. The separation of peptides and the sequence analysis are given in detail.     

The nucleotide sequence and in situ localization of a gene for a dimeric haemoglobin from the midge Chironomus thummi piger

A cluster containing at least four globin genes was isolated by screening an lambda EMBL3 genomic DNA library of the midge Chironomus thummi piger (Ctp) with a heterologous haemoglobin (Hb) gene IV (HbIV) probe from Chironomus thummi thummi (Ctt). This globin gene cluster was localized by in situ hybridization to chromosome II. One globin gene together with its 5'- and 3'-flanking regions has been sequenced. It can be deduced from the sequence that it is a new member of the dimeric HbVIIB family. The Ctp HbVIIB-5 gene displays 91.8% nucleotide sequence homology to a HbVIIB cDNA sequence, reported previously. There is no evidence for intron/exon structure in the Ctp HbVIIB-5 gene.     

Molecular evolutionary analysis of theywvz/7B globin gene cluster of the insectChironomus thummi

We report the sequence of 8.1 kb of DNA containing the 3 end of one and seven other complete intronless globin genes from theywvz/7B locus of the dipteranChironomus thummi thummi. One of these (cttv) appears to be a pseudogene by virtue of a premature termination codon, whereas the others encode apparently functional globin polypeptides. Taken together with previously published data, theC. th. thummi ywvz/7B locus codes for at least 11 globins, five of which differ from one another by no more than two amino acids. In contrast, only nine globin genes are found in a comparable genomic clone isolated fromC. th. piger. As indicated by sequence alignment, this difference in copy number can be attributed to a loss of one gene (fusion of globin genes 7B8 and 7B10) in thepiger lines, coupled with a gain (globin gene 7139) in thethummi lineage. Comparisons between thethummi andpiger sequences showed thatywvz/713 intergenic regions have maintained a level of 91 % similarity since thethummi/piger divergence: most differences are simply due to single base substitutions or insertion/deletion events in either thethummi or thepiger DNA, but three instances of partially overlapping deletions were also detected. A phylogenetic analysis ofywvz/713 gene products was conducted, from which a plausible reconstruction of the evolutionary history of the locus was obtained. In addition, alignment of globin 7B amino acid sequences suggested that globin genes 7B2 and 7B3 (reported at the protein and cDNA level, respectively, but not contained on theC. th. thummi orC. th. piger genomic clones) are possibly chimeric genes. Given the trend toward expansion of theC. thummi globin gene family in general and of the globin 7B subfamily in particular, we propose that increased copy number of these genes has been positively selected as a mechanism to achieve a high Hb concentration in the larval hemolymph. Correspondence to: G. Bergtrom     

Sequence and evolution of the gene for the monomeric globin I and its linkage to genes coding for dimeric globins in the insect Chironomus thummi

We isolated genomic clones containing sequences encoding globins I and IA from a Chironomus thummi thummi genomic library. Three clones contain globin IA (ctt-1A) genes, while one contains a globin I (ctt-1) gene. The coding regions of the four genes are identical except for the single base substitution accounting for the globin I/IA polymorphism. The noncoding DNA flanking the coding region is more than 98% similar, confirming a previous hypothesis that the globin ctt-1 and ctt-1A genes are alleles. Hemoglobins I and IA are monomeric in the insect hemolymph. Earlier in situ hybridization studies suggested that monomeric and dimeric globin genes are clustered at different chromosomal loci. In situ hybridization of ctt-1 DNA to polytene salivary gland chromosomes places the ctt-1 gene on the same band as genes for the dimeric globins II and VIIB, forcing revision of the earlier hypothesis that genes for monomeric and dimeric globin genes are at different loci. The evolution of the ctt-1 and ctt-1A alleles and of the two globin gene loci are discussed. Correspondence to: G. Bergtrom     

Structure of a hemoglobin gene cluster and nucleotide sequence of three hemoglobin genes from the midge Chironomus thummi piger (Diptera, Insecta)

The aquatic larvae of the genus Chironomus (Diptera, Insecta) contain at least 12 different hemoglobin (Hb) variants in their hemolymph. In the present study we have analysed the structure and part of the nucleotide sequence of a Hb gene cluster cloned from the genomic DNA of Chironomus thummi piger. The cluster contains probably 6 different genes, separated by intergenic regions of various lengths. The nucleotide sequence of three putative Hb genes including the intergenic regions is presented. The inferred amino-acid sequences show clearly that two of these putative genes code for subvariants of the Hb variant VIIB. The third gene codes for a so far unknown Hb protein. As known already for other chironomid Hb genes, there are no intron sequences present in the coding regions.     

Hemoglobins of Kiefferulus,sister genus of Chironomus (Diptera: Insecta): Evolution of the Hb VIIB cluster

A genomic clone containing hemoglobin genes was isolated from a species of the chironomid genus Kiefferulus. Eight genes, including an apparent pseudogene, were sequenced and the amino acid sequences of the putative proteins were determined. By comparison to the previously described hemoglobins in the sister-genus Chironomus, they were identified as members of the dimeric Hb VIIB group. The results indicate that the existence of clusters of hemoglobin genes may be a common feature in chironomids and not just confined to Chironomus. The Kiefferulus genes show greatest similarity of amino acid sequence to Hb VIIB-7 from the Chironomus cluster. The results suggest that the ancestral cluster contained at least two gene types, one of which gave rise to VIIB-7 and the Kiefferulus genes while the other gave rise to the other Chironomus VIIB genes. Both clusters appear to have increased in size by duplication or unequal crossing over since the separation of the genera. It also appears that an unrelated gene present in the Chironomus cluster, Hb-Y, arose from a completely independent origin with no apparent equivalent gene anywhere in the genome of Kiefferulus or some other Chironomus species. Correspondence to: J. Martin     

Functional multiplicity and structural correlations in the hemoglobin system of larvae of Chironomus thummi thummi (Insecta, Diptera): Hb components CTT I, CTT II beta, CTT III, CTT IV, CTT VI, CTT VIIB, CTT IX and CTT X

Larvae of the dipteran insect Chironomus thummi thummi that burrow in fresh-water muds, contain at least 12 hemoglobin (Hb) components of which the functional properties have not been systematically documented, although their amino acid sequences have been elucidated, showing mutually distinct primary structures. We isolated eight components (the monomeric Hbs CTT I, CTT III and CTT IV and the dimeric Hbs CTT II beta, CTT VI, CTT VIIB, CTT IX and CTT X) and measured in each O2 affinity and cooperativity and their pH dependence, and the effects of temperature, NaCl and ATP. The O2 affinities, Bohr- and temperature effects of the isohemoglobins are discussed in relation to mode of life and the microenvironmental conditions to which the larvae are subjected in nature, and with regard to the molecular mechanisms underlying the Hb-oxygenation reactions.     

The primary structure of a dimeric hemoglobin (erythrocruorin); component CTT VI of Chironomus thummi thummi, Diptera (author's transl)]

The complete amino acid sequence of 147 residues was determined automatically for a major dimeric component (CTT VI) of the insect larva Chironomus thummi thummi (Diptera). The molweight was found to be 32411. All tryptic, maleylated tryptic and cyanogen bromide peptides were isolated. The handling of some large fragments was facilitated by maleylation and subsequent ion exchange chromatography. Some details of the primary structure are discussed. The alignment of the amino acid sequence with that of human alpha-chains shows only 29 identical positions.     

Hemoglobins, XXIX. Sequence analysis of a dimeric hemoglobin (erythrocruorin), CTT-X, of Chironomus thummi thummi (Diptera).

The amino acid sequences of one of the dimeric hemoglobin components, CTT-X, of Chironomus thummi thummi (Diptera) are given. The sequences were determined by automatic Edman degradation of tryptic peptides and peptides obtained by specific chemical cleavages. CTT-X has two different polypeptide chains, each with 151 amino acid residues. The two polypeptide chains differ only in one amino acid. The sequences are discussed in the light of the sequences of other related heme-proteins.     

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 primary structure of myoglobin from pacific green sea turtle (Chelonia mydas caranigra)

The amino acid sequence of the main component myoglobin from skeletal muscle of Pacific green sea turtle (Chelonia mydas caranigra) has been determined. The globin is 153 residues in length and has a free amino-terminus. The heme-binding and internal residues are as found in mammalian myoglobins. Ten substitutions are observed between this myoglobin and that from map turtle. About 38, 52, 47 and 86 substitutions are noted in comparison with the myoglobins of other reptiles, mammals, birds and fish, respectively. The inferred pattern of structural stabilization and conservation of two loci are typical of tetrapod myoglobin.     

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.     

Evolution of Orthologous Intronless and Intron-Bearing Globin Genes in Two Insect Species

While globin genes ctt-2β and ctt-9.1 in Chironomus thummi thummi each have a single intron, all of the other insect globin genes reported so far are intronless. We analyzed four globin genes linked to the two intron-bearing genes in C. th. thummi. Three have a single intron at the same position as ctt-2β and ctt-9.1; the fourth is intronless and lies between intron bearing genes. Finally, in addition to its intron, one gene (ctt-13RT) was recently interrupted by retrotransposition. Phylogenetic analyses show that the six genes in C. th. thummi share common ancestry with five globin genes in the distantly related species C. tentans, and that a 5-gene ancestral cluster predates the divergence of the two species. One gene in the ancestral cluster gave rise to ctn-ORFB in C. tentans, and duplicated in C. th. thummi to create ctt-11 and ctt-12. From parsimonious calculations of evolutionary distances since speciation, ctt-11, ctt-12, and ctn-ORFB evolved rapidly, while ctn-ORFE in C. tentans evolved slowly compared to other globin genes in the clusters. While these four globins are under selective pressure, we suggest that most chironomid globin genes were not selected for their unique function. Instead, we propose that high gene copy number itself was selected because conditions favored organisms that could synthesize more hemoglobin. High gene copy number selection to produce more of a useful product may be the basis of forming multigene families, all of whose members initially accumulate neutral substitutions while retaining essential function. Maintenance of a large family of globin genes not only ensured high levels of hemoglobin production, but may have facilitated the extensive divergence of chironomids into as many as 5000 species. Received: 31 December 1996 / Accepted: 16 May 1997     

Nucleotide sequence analysis of the lemur beta-globin gene family: evidence for major rate fluctuations in globin polypeptide evolution

Lemur beta-related globin genes have been isolated and sequenced. Orthology of prosimian and human epsilon-, gamma-, and beta-related globin genes was established by dot-matrix analysis. All of these lemur globin genes potentially encode functional beta-related globin polypeptides, though precisely when the gamma-globin gene is expressed remains unknown. The organization of the 18-kb brown lemur beta-globin gene cluster (5' epsilon-gamma-[psi eta-delta]-beta 3') is consistent with its evolution by contraction via unequal crossing-over from the putative ancestral mammalian beta-globin gene cluster (5' epsilon-gamma- eta-delta-beta 3'). The dwarf lemur nonadult globin genes are arranged as in the brown lemur. Similar levels of synonymous (silent) nucleotide substitutions and noncoding DNA sequence differences have accumulated between species in all of these genes, suggesting a uniform rate of noncoding DNA divergence throughout primate beta-globin gene clusters. These differences are comparable with those observed in the nonfunctional psi eta pseudogene and have therefore accumulated at the presumably maximal neutral rate. In contrast, nonsynonymous (replacement) nucleotide substitutions show a significant heterogeneity in distribution for both the same gene in different lineages and different genes in the same lineage. These major fluctuations in replacement but not silent substitution rates cannot be attributed to changes in mutation rate, suggesting that changes in the rate of globin polypeptide evolution in primates is not governed solely by variable mutation rates.