Ui Wook Hwang

Mitochondrial protein phylogeny joins myriapods with chelicerates

The animal phylum Arthropoda is very useful for the study of body plan evolution given its abundance of morphologically diverse species and our profound understanding of Drosophila development. However, there is a lack of consistently resolved phylogenetic relationships between the four extant arthropod subphyla, Hexapoda, Myriapoda, Chelicerata and Crustacea. Recent molecular studies have strongly supported a sister group relationship between Hexapoda and Crustacea, but have not resolved the phylogenetic position of Chelicerata and Myriapoda. Here we sequence the mitochondrial genome of the centipede species Lithobius forficatus and investigate its phylogenetic information content. Molecular phylogenetic analysis of conserved regions from the arthropod mitochondrial proteome yields highly resolved and congruent trees. We also find that a sister group relationship between Myriapoda and Chelicerata is strongly supported. We propose a model to explain the apparently parallel evolution of similar head morphologies in insects and myriapods.

Phylogenetic position of the ciliates Phacodinium (Order Phacodiniida) and Protocruzia (Subclass Protocruziidia) and systematics of the spirotrich ciliates examined by small subunit ribosomal RNA gene sequences

Summary The small subunit rRNA (SSrRNA) genes were sequenced for Protocruzia sp2, Phacodinium metchnicoffi, Holosticha multistylata, and Halteria grandinella. All four genera are placed within the Class Spirotrichea with strong bootstrap support in both distance matrix and parsimony tree construction methods and by maximum likelihood analysis using quartet puzzling. Protocruzia sp2 groups with Protocruzia sp1 with 100% bootstrap support, and the 5.6% genetic difference between them strongly argues that they are different species although they are morphologically quite similar. The Protocruzia species branch first in the spirotrich clade at a deep level, supporting their recognition as a Subclass Protocruziidia. Phacodinium branches after Euplotes at a deep level, confirming the conclusion that others have reached that this genus is related to the hypotrich and stichotrich spirotrichs. Phacodinium is assigned to its own family and order, and we conclude that the deep branching within the spirotrichs argues for its own subclass, the Subclass Phacodiniidia. Consistent with the partial SSrRNA sequences and with the sequence of a polymerase gene, Halteria groups within the stichotrich clade, supporting the argument that the oligotrichs are not monophyletic as currently conceived. Finally, Holosticha, which has been assigned to the Order Urostylida, groups outside the stichotrichs with parsimony analysis, which is consistent with this ordinal assignment. However, it is associated with Halteria and Oxytricha granulifera in the other analyses. Additional stichotrich sequences obviously are required before we can confidently begin revision of the Subclass Stichotrichia.

IDENTIFICATION OF TAENIA ASIATICA IN CHINA: MOLECULAR, MORPHOLOGICAL, AND EPIDEMIOLOGICAL ANALYSIS OF A LUZHAI ISOLATE

Multiple analysis has characterized a recently described tapeworm of people, Taenia asiatica, in mainland China. Six adult tapeworms collected from people of the Zhuang minority residing in the southern part of China (Luzhai isolate) were comparatively analyzed with other tapeworms from people: T. asiatica (n = 2, South Korea), T. saginata (n = 1, Poland; n = 1, Korea), and T. solium (n = 1, Peoples Republic of China). Experimental infections with eggs from the Luzhai isolate in pigs and cattle produced cysticerci, each with a hookletless scolex and with wartlike formations on the external surface of the bladder wall. There were rostellar protrusions in the scolices of adult worms. Random amplified polymorphic DNA analysis using 3 arbitrary primers produced bands identical to those of the Korean T. asiatica. Conversely, T. saginata and T. solium exhibited different banding patterns. Phylogenetic relationships inferred from the complete nucleotide sequences of the internal transcribed spacer 2 placed the Chinese tapeworms consistently within the T. asiatica clade by 96% bootstrapping value in the maximum likelihood analysis, 96% in maximum parsimony, and 100% in neighbor joining. These collective data demonstrate that T. asiatica is sympatrically distributed with the other 2 species of Taenia in the human host in mainland China.

Complete mitochondrial genome of Bugula neritina (Bryozoa, Gymnolaemata, Cheilostomata): phylogenetic position of Bryozoa and phylogeny of lophophorates within the Lophotrochozoa

BackgroundThe phylogenetic position of Bryozoa is one of the most controversial issues in metazoan phylogeny. In an attempt to address this issue, the first bryozoan mitochondrial genome from Flustrellidra hispida (Gymnolaemata, Ctenostomata) was recently sequenced and characterized. Unfortunately, it has extensive gene translocation and extremely reduced size. In addition, the phylogenies obtained from the result were conflicting, so they failed to assign a reliable phylogenetic position to Bryozoa or to clarify lophophorate phylogeny. Thus, it is necessary to characterize further mitochondrial genomes from slowly-evolving bryozoans to obtain a more credible lophophorate phylogeny.ResultsThe complete mitochondrial genome (15,433 bp) of Bugula neritina (Bryozoa, Gymnolaemata, Cheilostomata), one of the most widely distributed cheliostome bryozoans, is sequenced. This second bryozoan mitochondrial genome contains the set of 37 components generally observed in other metazoans, differing from that of F. hispida (Bryozoa, Gymnolaemata, Ctenostomata), which has only 36 components with loss of tRNAser(ucn) genes. The B. neritina mitochondrial genome possesses 27 multiple noncoding regions. The gene order is more similar to those of the two remaining lophophorate phyla (Brachiopoda and Phoronida) and a chiton Katharina tunicate than to that of F. hispida. Phylogenetic analyses based on the nucleotide sequences or amino acid residues of 12 protein-coding genes showed consistently that, within the Lophotrochozoa, the monophyly of the bryozoan class Gymnolaemata (B. neritina and F. hispida) was strongly supported and the bryozoan clade was grouped with brachiopods. Echiura appeared as a subtaxon of Annelida, and Entoprocta as a sister taxon of Phoronida. The clade of Bryozoa + Brachiopoda was clustered with either the clade of Annelida-Echiura or that of Phoronida + Entoprocta.ConclusionThis study presents the complete mitochondrial genome of a cheliostome bryozoan, B. neritina. The phylogenetic analyses suggest a close relationship between Bryozoa and Brachiopoda within the Lophotrochozoa. However, the sister group of Bryozoa + Brachiopoda is still ambiguous, although it has some attractions with Annelida-Echiura or Phoronida + Entoprocta. If the latter is a true phylogeny, lophophorate monophyly including Entoprocta is supported. Consequently, the present results imply that Brachiozoa (= Brachiopoda + Phoronida) and the recently-resurrected Bryozoa concept comprising Ectoprocta and Entoprocta may be refuted.

Analysis of the Primary Sequence and Secondary Structure of the Unusually Long SSU rRNA of the Soil Bug, Armadillidium vulgare

Abstract. The complete nucleotide sequence of the SSU rRNA gene from the soil bug, Armadillidium vulgare (Crustacea, Isopoda), was determined. It is 3214 bp long, with a GC content of 56.3%. It is not only the longest SSU rRNA gene among Crustacea but also longer than any other SSU rRNA gene except that of the strepsipteran insect, Xenos vesparum (3316 bp). The unusually long sequence of this species is explained by the long sequences of variable regions V4 and V7, which make up more than half of the total length. RT-PCR analysis of these two regions showed that the long sequences also exist in the mature rRNA and sequence simplicity analysis revealed the presence of slippage motifs in these two regions. The putative secondary structure of the rRNA is typical for eukaryotes except for the length and shape variations of the V2, V4, V7, and V9 regions. Each of the V2, V4, and V7 regions was elongated, while the V9 region was shortened. In V2, two bulges, located between helix 8 and helix 9 and between helix 9 and helix 10, were elongated. In V4, stem E23-3 was dramatically expanded, with several small branched stems. In V7, stem 43 was branched and expanded. Comparisons with the unusually long SSU rRNAs of other organisms imply that the increase in total length of SSU rRNA is due mainly to expansion in the V4 and V7 regions.

Evolution of hypervariable regions, V4 and V7, of insect 18S rRNA and their phylogenetic implications.

Abstract We compared primary and secondary structures of V4 (helices E23-2 to E23-5) and V7 (helix 43) regions of 18S rRNAs in insects and the other three major arthropod groups (crustaceans, myriapods, and chelicerates) known so far. We found that the lengths of primary sequences and the shapes of secondary structures of these two hypervariable regions of insect 18S rRNA even at infraclass levels are phylogenetically informative and reflect major steps in insect evolution. The long sequence insertion and bifurcated shape of helices E23-2 to E23-5 in the V4 region are unique synapomorphic characters for winged insects (Pterygota). The long sequence insertion and expanded stem length of helix 43 in the V7 region are synapomorphic characters for holometabolous insects which conduct complete metamorphosis. The strongly conserved secondary structures suggest the possibility that these hypervariable regions may be related with certain important cellular functions unknown thus far. The comparison with insect fossil records revealed that the pterygote synapomorphy (V4) and the holometabolous synapomorphy (V7) were established prior to the acquisition of insect wings (flight system) and prior to the development of complete metamorphosis, respectively. These synapomorphies have been also relatively stable over at least 300 Myr and 280 Myr, respectively as well. It implies that the expansion events of the V4 and V7 regions have not occurred simultaneously but independently at different periods during the insect evolution. Then this suggests that V4 and V7 regions are not functionally correlated as recently suggested by Crease and Coulbourn.

Mitochondrial genome phylogeny among Asiatic black bear Ursus thibetanus subspecies and comprehensive analysis of their control regions

The complete mitochondrial genome (16,824 bp) of an Asiatic black bear Ursus thibetanus ussuricus (Mammalia, Carnivora, Ursidae) was newly sequenced and characterized in detail. It is the second mitochondrial genome from this subspecies which has been completely sequenced. The two U. t. ussuricus individuals were compared with each other and then with individuals from the other four U. thibetanus subspecies and the other nine ursid species, focusing especially on the control regions in the 14 mitochondrial genomes. Within these control regions, tandem repeats of basically 10 bp (5′-ACGCACGTGT-3′ or its derivatives) were found in Domain II. Plausible secondary structures of the repeat region were compared between the North and South Korean individuals of U. t. ussuricus. According to the maximum likelihood and Bayesian inference trees inferred from the nucleotide sequences of 13 protein-coding and two rRNA genes, the ursine members within the monophyletic ursid clade can be divided into at least three groups: A, B, and C. According to this analysis, U. thibetanus subspecies were found with Ursus americanus and Ursus malayanus within Group A, showing the following relationships with nodal bootstrap values above 91% and Bayesian posterior probabilities of 1.00: ([(U. t. thibetanus, U. t. formosanus), U. t. spp.], U. t. ussuricus), U. t. mupinensis. In addition, we present a hypothetical scenario of the evolution of the major repeat motifs in the control region.

Complete mitochondrial genome of the Hodgson's bat Myotis formosus (Mammalia, Chiroptera, Vespertilionidae)

The first complete mitochondrial genome (17,159 bp) of the Hodgsons bat Myotis formosus, which is an endangered species in South Korea, was sequenced and characterized. The genome included 13 protein-coding, 22 tRNA, and 2 rRNA genes, and 1 control region. It has high AT content and the same gene arrangement pattern as those of typical vertebrate mitochondrial genome. Within the control region, a 80 bp tandem repeat unit was iterated five times which was found in Domain I. It has been observed only in the vespertilionid bat group, and could contribute to identifying the species or genus, and also distinguishing it from other bat families.

Complete mitochondrial genome of the black-headed snake Sibynophis collaris (Squamata, Serpentes, Colubridae)

The black-headed snake Sibynophis collaris (Reptilia, Squamata, Colubridae) is a least concern species in the world. Two universal and two specific polymerase chain reaction (PCR) primers were used for long PCRs to amplify the whole mitochondrial genome of S. collaris. The products were subjected to do sequencing reactions. The complete genome is 17,163 bp in size, containing 37 genes coding for 13 proteins, 2 rRNAs, 22 tRNAs, and 2 control regions (CRI and CRII). The results could play an important role in the preservation of genetic resources for helping conservation of the endangered species.

Complete mitochondrial genome of the Baikal teal Anas formosa (Aves, Anseriformes, Anatidae)

The Baikal teal Anas formosa (Aves, Anseriformes, Anatidae) is classified as “Vulnerable” on the IUCN Red List. Here, whole mitochondrial genome of A. formosa was amplified and sequenced. The total length of the Baikal teal mitochondrial genome is 16,594 bp, which consists of 13 protein-coding, 2 rRNA, 22 tRNA genes and 1 control region. The characteristics of the mitochondrial genomes were analyzed and discussed in detail.