Jan Kwiatowski

Phylogeny of Drosophila and related genera inferred from the nucleotide sequence of the Cu,Zn Sod gene.

The phylogeny and taxonomy of the drosophilids have been the subject of extensive investigations. Recently, Grimaldi (1990) has challenged some common conceptions, and several sets of molecular data have provided information not always compatible with other taxonomic knowledge or consistent with each other. We present the coding nucleotide sequence of the Cu,Zn superoxide dismutase gene (Sod) for 15 species, which include the medfly Ceratitis capitata (family Tephritidae), the genera Chymomyza and Zaprionus, and representatives of the subgenera Dorsilopha, Drosophila, Hirtodrosophila, Scaptodrosophila, and Sophophora. Phylogenetic analysis of the Sod sequences indicates that Scaptodrosophila and Chymomyza branched off the main lineage before the major Drosophila radiations. The presence of a second intron in Chymomyza and Scaptodrosophila (as well as in the medfly) confirms the early divergence of these two taxa. This second intron became deleted from the main lineage before the major Drosophila radiations. According to the Sod sequences, Sophophora (including the melanogaster, obscura, saltans, and willistoni species groups) is older than the subgenus Drosophila; a deep branch splits the willistoni and saltans groups from the melanogaster and obscura groups. The genus Zaprionus and the subgenera Dorsilopha and Hirtodrosophila appear as branches of a prolific “bush” that also embraces the numerous species of the subgenus Drosophila. The Sod results corroborate in many, but not all, respects Throckmortons (King, R.C. (ed) Handbook of Genetics. Plenum Press, New York, pp. 421–469, 1975) phylogeny; are inconsistent in some important ways with Grimaldis (Bull. Am. Museum Nat. Hist.197:1–139, 1990) cladistic analysis; and also are inconsistent with some inferences based on mitochondrial DNA data. The Sod results manifest how, in addition to the information derived from nucleotide sequences, structural features (i.e., the deletion of an intron) can help resolve phylogenetic issues.

ON THE EVOLUTION OF DOPA DECARBOXYLASE (DDC) AND DROSOPHILA SYSTEMATICS

Abstract. We have sequenced most of the coding region of the gene Dopa decarboxylase (Ddc) in 24 fruitfly species. The Ddc gene is quite informative about Drosophila phylogeny. Several outstanding issues in Drosophila phylogeny are resolved by analysis of the Ddc sequences alone or in combination with three other genes, Sod, Adh, and Gpdh. The three species groups, melanogaster, obscura, and willistoni, are each monophyletic and all three combined form a monophyletic group, which corresponds to the subgenus Sophophora. The Sophophora subgenus is the sister group to all other Drosophila subgenera (including some named genera, previously considered outside the Drosophila genus, namely, Scaptomyza and Zaprionus, which are therefore downgraded to the category of subgenus). The Hawaiian Drosophila and Scaptomyza are a monophyletic group, which is the sister clade to the virilis and repleta groups of the subgenus Drosophila. The subgenus Drosophila appears to be paraphyletic, although this is not definitely resolved. The two genera Scaptodrosophila and Chymomyza are older than the genus Drosophila. The data favor the hypothesis that Chymomyza is older than Scaptodrosophila, although this issue is not definitely resolved. Molecular evolution is erratic. The rates of nucleotide substitution in 3rd codon position relative to positions 1 + 2 vary from one species lineage to another and from gene to gene.

Reconstructing euglenoid evolutionary relationships using three genes: nuclear SSU and LSU, and chloroplast SSU rDNA sequences and the description of Euglenaria gen. nov. (Euglenophyta).

Using Maximum Likelihood and Bayesian analyses of three genes, nuclear SSU (nSSU) and LSU (nLSU) rDNA, and chloroplast SSU (cpSSU) rDNA, the relationships among 82 plastid-containing strains of euglenophytes were clarified. The resulting tree split into two major clades: clade one contained Euglena, Trachelomonas, Strombomonas, Colacium, Monomorphina, Cryptoglena and Euglenaria; clade two contained Lepocinclis, Phacus and Discoplastis. The majority of the members of Euglena were contained in clade A, but seven members were outside of this clade. Euglena limnophila grouped with, and was thus transferred to Phacus. Euglena proxima was a single taxon at the base of clade one and is unassociated with any subclade. Five members of Euglena grouped together within clade one and were transferred into the newly erected genus Euglenaria. The monophyly of the remaining genera was supported by Bayesian and Maximum Likelihood analyses. Combining datasets resolved the relationships among ten genera of photosynthetic euglenoids.

Erratic Evolution of Glycerol-3-Phosphate Dehydrogenase in Drosophila, Chymomyza, and Ceratitis

Abstract. We have studied the evolution of Gpdh in 18 fruitfly species by sequencing 1,077 nucleotides per species on average. The region sequenced includes four exons coding for 277 amino acids and three variable-length introns. Phylogenies derived by a variety of methods confirm that the nominal genus Zaprionus belongs within the genus Drosophila, whereas Scaptodrosophila and Chymomyza are outside. The rate of GPDH evolution is erratic. The rate of amino acid replacements in a lineage appears to be 1.0 × 10−10/site/year when Drosophila species are considered (diverged up to 55 million years ago), but becomes 2.3 × 10−10 when they are compared to Chymomyza species (divergence around 60 My ago), and 4.6 × 10−10 when species of those two genera are compared with the medfly Ceratitis capitata (divergence around 100 My ago). In order to account for these observations, the rate of amino acid replacement must have been 15 or more times greater in some lineages and at some times than in others. At the nucleotide level, however, Gpdh evolves in a fairly clockwise fashion.

Structure and sequence of the Cu,Zn Sod gene in the Mediterranean fruit fly, Ceratitis capitata: Intron insertion/deletion and evolution of the gene

We have cloned a 4-kb region encompassing the Cu,Zn superoxide dismutase (Sod) gene from a genomic library of the Mediterranean fruit fly, Ceratitis capitata, using a cDNA probe from Drosophila melanogaster. The coding sequence of 462 bases is equally as long as that in Drosophila species. The rate of amino acid replacement over the past 100 million years is approximately the same in the Diptera and in mammals, thus excluding the hypothesis (proposed to account for an apparent acceleration in rate of evolution of Sod over geological time) that the evolution of the SOD protein is much higher in the mammals than in other organisms. The coding region is interrupted by two introns in Ceratitis, whereas only one occurs in Drosophila. Phylogenetic comparisons indicate that the second intron was present in the common dipteran ancestor, but was lost shortly after the divergence of the Drosophila lineage from other Diptera. Analysis of the exon/intron structure of Sod in various animal phyla, plants, and fungi indicates that intron insertions as well as deletions have occurred in the evolution of the Sod gene.

THE RATE OF Cu,Zn SUPEROXIDE DISMUTASE EVOLUTION

The rate of amino acid replacement in Cu,Zn SOD greatly departs from the expectations of the molecular clock. We examine 27 Cu,Zn SOD sequences available and conclude that: (1) the SOD enzymes from different mammal families differ from each other by roughly the same number of replacements, which is consistent with a simultaneous mammalian radiation; (2) over the most recent 60 million years (MY) the rate of SOD evolution is fairly high (15 aa/100 aa/100 MYR) and may be considered constant; (3) the rate of accumulation of amino acid replacements since the divergence of fungi, plants and animals to the present is inconstant along different branches of the evolutionary tree; moreover it steadily decreases with time, to the same extent in all lineages; (4) some comparisons exhibit divergences that are in any case greater than expected from a Poisson process on the assumption of a molecular clock; (5) plant chloroplast enzymes display fewer differences from each other than cytoplasmic ones; (6) bacteriocuprein (from Photobacterium leiognathi), fluke and human extracellular SOD are all three extremely remotely related to one another and to the SOD of other eukaryotes. The process of consistent decline of the rate of evolution of Cu, Zn SOD can be described by a number of mathematical functions. We explore simple models that assume constant rates and might be applicable to other proteins or genes that apparently evolve at disparate rates.

Structure and sequence of the Cu, Zn superoxide dismutase gene of Chymomyza amoena: phylogeny of the genus and codon‐use evolution

We have cloned and sequenced the Cu, Zn superoxide dismutase gene of Chymomyza amoena. The coding sequence has the same length as in Drosophila species and in Ceratitis capitata. There are two introns, located at the same sites as in Ceratitis. The second intron is absent in Drosophila: this places Chymomyza outside the Drosophila lineage, contrary to proposals based on anatomical and other evidence. The nucleotide or amino acid distances support a phylogeny in which Ceratitis first branches off the common stem, then Chymomyza splits before the divergence of the two major Drosophila subgenera. The estimated divergence times are 58 million for Chymomyza‐Drosophila; 48 million years for the Drosophila subgenera. During the intervening 10 million years, the Drosophila lineage lost the second intron and evolved distinct codon‐preferences: the G + C use in the third coding positions is increased by 69% in Drosophila relative to Chymomyza or Ceratitis.

Characterization of a Cu/Zn Superoxide dismutase-encoding gene region in Drosophila willistoni ☆

A Cu/Zn superoxide dismutase-encoding gene (Sod) from Drosophila willistoni was cloned and sequenced. The gene shows a typical structure for a fruit-fly Sod gene, with a coding region of 462 bp in two exons separated by a 417-bp intron. Comparison of the Sod sequences from D. willistoni and D. melanogaster suggests that these species are only remotely related. Downstream from the Sod gene, there is an ORF on the opposite strand that putatively encodes the last exon of an unidentified gene. The polyadenylation signals of the two genes are separated by only 61 bp in D. willistoni, conforming to the common picture of compact dipteran genomes.