Accelerated Evolution of Mitochondrial but Not Nuclear Genomes of Hymenoptera: New Evidence from Crabronid Wasps

Kaltenpoth, Martin; Corneli, Patrice Showers; Dunn, Diane M.; Weiss, Robert B.; Strohm, Erhard; Seger, Jon

doi:10.1371/journal.pone.0032826

Cited by 59 publications

(43 citation statements)

References 90 publications

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“…We found that the mean d S of mt genes was about 7–9 times higher than that of nu genes. This magnitude is consistent with the well-established pattern of high d S in animal mt genes (Brown et al 1979; Johnson et al 2003; Caccone et al 2004; Lynch 2007; Kaltenpoth et al 2012). Although the products of nu OXHPOS genes are transported into mitochondria where they function, they are expected to show mean d S similar to the non-OXPHOS genes because the coding sequences reside in the nu genome.…”

Section: Discussionsupporting

confidence: 89%

“…Despite the fundamental importance of OXPHOS to aerobic life, mt protein-coding genes are not highly conserved and evolve at rates that is 5–50 times that of typical nu genes in vertebrates (Lynch 2007). This increased rate has been observed in a range of animal species, including primates (Brown et al 1979), Galapagos tortoises (Caccone et al 2004), lice (Johnson et al 2003), Drosophila (Haag-Liautard et al 2008), wasps (Kaltenpoth et al 2012), and nematodes (Denver et al 2000). The rapid evolutionary rate of mt genomes may be due to their cell cycle-independent replication of mtDNA (Bogenhagen and Clayton 1977), increased exposure to mutagenic oxygen radical species (Beal 1996), lack of protective histones, and limited DNA repair capacity (Croteau and Bohr 1997).…”

Section: Introductionmentioning

confidence: 96%

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Mitochondrial–Nuclear Interactions: Compensatory Evolution or Variable Functional Constraint among Vertebrate Oxidative Phosphorylation Genes?

Zhang

Broughton

2013

Genome Biology and Evolution

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Oxidative phosphorylation (OXPHOS), the major energy-producing pathway in aerobic organisms, includes protein subunits encoded by both mitochondrial (mt) and nuclear (nu) genomes. How these independent genomes have coevolved is a long-standing question in evolutionary biology. Although mt genes evolve faster than most nu genes, maintenance of OXPHOS structural stability and functional efficiency may involve correlated evolution of mt and nu OXPHOS genes. The nu OXPHOS genes might be predicted to exhibit accelerated evolutionary rates to accommodate the elevated substitution rates of mt OXPHOS subunits with which they interact. Evolutionary rates of nu OXPHOS genes should, therefore, be higher than that of nu genes that are not involved in OXPHOS (nu non-OXPHOS). We tested the compensatory evolution hypothesis by comparing the evolutionary rates (synonymous substitution rate dS and nonsynonymous substitution rate dN) among 13 mt OXPHOS genes, 60 nu OXPHOS genes, and 77 nu non-OXPHOS genes in vertebrates (7 fish and 40 mammal species). The results from a combined analysis of all OXPHOS subunits fit the predictions of the hypothesis. However, results from two OXPHOS complexes did not fit this pattern when analyzed separately. We found that the dN of nu OXPHOS genes for “core” subunits (those involved in the major catalytic activity) was lower than that of “noncore” subunits, whereas there was no significant difference in dN between genes for nu non-OXPHOS and core subunits. This latter finding suggests that compensatory changes play a minor role in the evolution of OXPHOS genes and that the observed accelerated nu substitution rates are due largely to reduced functional constraint on noncore subunits.

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Section: Discussionsupporting

confidence: 89%

Section: Introductionmentioning

confidence: 96%

Mitochondrial–Nuclear Interactions: Compensatory Evolution or Variable Functional Constraint among Vertebrate Oxidative Phosphorylation Genes?

Zhang

Broughton

2013

Genome Biology and Evolution

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“…Heraty et al., ; Sharkey et al., ; Klopfstein et al., ). The uncertainty near the base of the Vespina could also be explained by the comparatively long terminal branches (Figs and ), which may be indicative of elevated rates of molecular evolution within Apocrita, as has been demonstrated for mitochondrial sequences (Dowton and Austin, ; Castro et al., ; Kaltenpoth et al., ).…”

Section: Discussionmentioning

confidence: 82%

“…PCR products were purified by adding 4 lL of a 1 : 4 mixture of Exonuclease I (Fermentas) and Fast Alcaline Phosphatase (Fermentas) to each sample, heating them at 37°C for 30 min, and then at 80°C for 15 min. Cleaned PCR products were sequenced in both directions with the original PCR primers and/or internal sequencing primers (Table 1), using the BigDye Ter- Table 1 Primers used for PCR and sequencing, with information provided on respective gene fragment, primer name, direction (forward, F or reverse, R) and location (internal, i or external, o) (Katoh et al, 2005) and/or by eye for determining exon and intron regions. Introns were identified in all nuclear genes, based on the presence of GT-AG splicing sites, and then deleted from the final alignments.…”

Section: Dna Extraction Pcr and Sequencingmentioning

confidence: 99%

Phylogeny of the symphytan grade of Hymenoptera: new pieces into the old jigsaw(fly) puzzle

2014

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The Hymenoptera constitutes one of the largest, and ecologically and economically most important, insect orders. During the past decade, a number of hypotheses on the phylogenetic relationships among hymenopteran families and superfamilies have been presented, based on analyses of molecular and/or morphological data. Nevertheless, many questions still remain, particularly concerning relationships within the hyperdiverse suborder Apocrita, but also when it comes to the evolutionary history of the ancestrally herbivorous "sawfly" lineages that form the basal, paraphyletic grade Symphyta. Because a large part of the uncertainty appears to stem from limited molecular and taxonomic sampling, we set out to investigate the phylogeny of Hymenoptera using nine protein-coding genes, of which five are new to analyses of the order. In addition, we more than tripled the taxon coverage across the symphytan grade, introducing representatives for many previously unsampled lineages. We recover a well supported phylogenetic structure for these early herbivorous hymenopteran clades, with new information regarding the monophyly of Xyelidae, the placement of the superfamily Pamphilioidea as sister to Tenthredinoidea + Unicalcarida, as well as the interrelationships among the tenthredinoid families Tenthredinidae, Cimbicidae, and Diprionidae. Based on the obtained phylogenies, and to prevent paraphyly of Tenthredinidae, we propose erection of the tribe Heptamelini to family status (Heptamelidae). In particular, our results give new insights into subfamilial relationships within the Tenthredinidae and other species-rich sawfly families. The expanded gene set provides a useful toolbox for future detailed analyses of symphytan subgroups, especially within the diverse superfamily Tenthredinoidea.

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“…The long branch leading to the Tantulocarida could be explained by a accelerated evolutionary tempo that might be typical for parasitic taxa (Dowton and Austin 1995;Page et al 1998). Although recent investigations show that this statement may be far from always true (Gilman et al 2012;Kaltenpoth et al 2012).…”

Section: Resultsmentioning

confidence: 99%

Tantulocarida versus Thecostraca: inside or outside? First attempts to resolve phylogenetic position of Tantulocarida using gene sequences

Petrunina

Neretina

Mugue

et al. 2013

J Zoolog Syst Evol Res

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Complete 18S rDNA sequences of two species of the Tantulocarida Arcticotantulus pertzovi (Basipodellidae) and Microdajus tchesunovi (Microdajidae) were obtained and used for estimating the relationship of the class with other Crustacea. This constitutes the first use of tantulocaridan gene sequences, and we conclude that the Tantulocarida are very close relatives of the class Thecostraca, which comprise cirripedes, ascothoracidans and the enigmatic facetotectans. With much lower confidence, the Tantulocarida are also indicated as nested within the Thecostraca, being sister group to the Cirripedia. We therefore discuss morphological similarities and differences between tantulocaridans and the thecostracans in search of potential synapomorphies, including a possible relation to the parasitic barnacles (Rhizocephala). We conclude that the cement gland of the tantulus larva and the cirripede cyprid might be homologous structures, but that similarities in host infection and root systems between the Tantulocarida and the Rhizocephala are, on present evidence, likely to be homoplasies evolved by convergent evolution into advanced parasitism. The precise position of the Tantulocarida in relation to or within the Thecostraca must be pursued by a more extensive database of genetic markers.

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Accelerated Evolution of Mitochondrial but Not Nuclear Genomes of Hymenoptera: New Evidence from Crabronid Wasps

Cited by 59 publications

References 90 publications

Mitochondrial–Nuclear Interactions: Compensatory Evolution or Variable Functional Constraint among Vertebrate Oxidative Phosphorylation Genes?

Mitochondrial–Nuclear Interactions: Compensatory Evolution or Variable Functional Constraint among Vertebrate Oxidative Phosphorylation Genes?

Phylogeny of the symphytan grade of Hymenoptera: new pieces into the old jigsaw(fly) puzzle

Tantulocarida versus Thecostraca: inside or outside? First attempts to resolve phylogenetic position of Tantulocarida using gene sequences

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