Secondary structural modeling of the second internal transcribed spacer (ITS2) from Pfiesteria-like dinoflagellates (Dinophyceae)

Pfiesteria piscicida is a harmful bloom-forming alga that has received a great deal of attention due to its potential association with large fish kills and neurological problems in humans. Since the discovery of Pfiesteria, several other Pfiesteria-like dinoflagellates (PLDs) have also been identified. Genetic identification and phylogenetic relationships among the PLDs commonly utilize sequence data from the genes and spacers of the ribosomal DNA (rDNA) operon. Of these, the internal transcribed spacers (ITSs) have been previously shown to fold into secondary structures that are critical for proper ribosomal processing. In this study, we modeled the secondary structure of the second internal transcribed spacer (ITS2) from 16 PLDs (as well as an outgroup taxon) using phylogenetic comparative methods and minimum free energy. The secondary structural models predicted for these dinoflagellates consisted of four paired helices separated by five unpaired regions, consistent with those reported from many eukaryotes. All of the structures were highly stable (ΔG = ?66.1 to ?122.3 kcal·mol at 37 °C) and several structural characters were found to be conserved either across the PLDs or were specific to monophyletic subgroups, strengthening previously inferred phylogenetic relationships among taxa. Additionally, an 18 bp motif was identified in the PLDs whose position corresponds to a ribosomal processing site described from other eukaryotes. Potential applications of these ITS2 secondary structures include utility in strain and species identification, phylogenetic inference and serving as a tool for identifying and excluding rDNA pseudogenes when assessing biodiversity within the PLDs.     

The mitochondrial genome sequence analysis of Ophidascaris baylisi from the Burmese python (Python molurus bivittatus)

Ophidascaris species are parasitic roundworms that inhabit the python gut, resulting in severe granulomatous lesions or even death. However, the classification and nomenclature of these roundworms are still controversial. Our study aims to identify a snake roundworm from the Burmese python (Python molurus bivittatus) and analyze the mitochondrial genome. We identified this roundworm as Ophidascaris baylisi based on the morphology and cytochrome c oxidase subunit I (cox1) sequence. Ophidascaris baylisi complete mitochondrial genome was 14,784 bp in length, consisting of two non-coding regions and 36 mitochondrial genes (12 protein-coding genes, 22 tRNA genes, and two rRNA genes). The protein-coding genes used TTG, ATG, ATT, or TTA as start codons and TAG, TAA, or T as stop codons. All tRNA genes showed a TV-loop structure, except trnS1^AGN and trnS2^UCN revealed a D-loop structure. The mitochondrial large ribosomal subunit 16S (rrnL) and small ribosomal subunit 12S (rrnS) were 956 bp and 700 bp long, respectively. Phylogenetic analysis based on O. baylisi mitochondrial protein-coding genes demonstrated that O. baylisi clustered with the family Ascarididae members and was most closely related to Ophidascaris wangi. These results may enhance the nematode mitochondrial genome database and provide valuable molecular markers for further research on the taxonomy, phylogeny, and genetic relationships of Ophidascaris nematodes.     

Anonymous nuclear markers for cetacean species

Here we report the development and characterization of 17 anonymous nuclear markers for cetacean species. These markers were isolated from a genomic library built from a common dolphin (genus Delphinus), and tested across several families within Cetacea. An average of 1 SNP per 272 bp was found in 10 anonymous markers screened for polymorphism within the genus Delphinus (total of 6,537 bp sequenced). These markers represent a significant addition to the set of tools used in genetic studies of cetaceans where population and species boundaries have to be inferred in order to implement proper conservation strategies.     

Sequencing and analysis of the Thermus thermophilus ribosomal protein gene cluster equivalent to the spectinomycin operon

To assess the organization of the Thermus thermophilus ribosomal protein genes, a fragment of DNA containing the complete S10 region and ten ribosomal protein genes of the spc region was cloned, using an oligonucleotide coding for the N-terminal amino acid (aa) sequence of T. thermophilus S8 protein as hybridization probe. The nucleotide sequence of a 4290 bp region between the rps17 and rpl15 genes was determined. Comparative analysis of this gene cluster showed that the gene arrangement (S17, L14, L24, L5, S14, S8, L6, L18, S5, L30 and L15) is identical to that of eubacteria. However, T. thermophilus ribosomal protein genes corresponding to the Escherichia coli S10 and spc operons are not resolved into two clusters: the stop codon of the rps17 gene (the last gene of the S10 operon in E. coli) and the start codon of the rpl14 gene (the first gene of the spc operon in E. coli) overlap. Most genes, except the rps14-rps8 intergenic spacer (69 bp), are separated by very short (only 3–7 bp) spacer regions or partially overlapped. The deduced aa sequences of T. thermophilus proteins share about 51–100% identities with the sequences of homologous proteins from thermophile Thermus aquaticus and Thermotoga maritima and 27–70% identities with the sequences of their mesophile counterparts.     

Phylogeny and systematics of Anatolian mountain frogs

Anatolian mountain frogs (Rana macrocnemis, Rana camerani, Rana holtzi, and Rana tavasensis) are one of the most specious amphibian groups in Turkey containing two endemic taxa (R. holtzi and R. tavasensis). The taxonomy of this group remains controversial as there are several unresolved issues.In the present study, we aimed to resolve the taxonomic uncertainty of the Anatolian mountain frogs through two mitochondrial genes (CYTB, 481 bp and COI, 743 bp) and two protein-coding nuclear genes (POMC, 401 bp and RAG1, 717 bp). The mitochondrial DNA (mtDNA) markers were found to be highly polymorphic in this group. Haplotype network analysis revealed that R. tavasensis was different for at least 33 and 52 mutational steps according to CYTB and COI gene regions, respectively. High bootstrap and posterior probability values obtained from the mtDNA genes support the idea that Anatolian mountain frogs are represented by two distinct species in Anatolia: R. macrocnemis and R. tavasensis. However, no genetic variation was detected according to nuclear DNA (nDNA) markers.The analysis of molecular variance (AMOVA) revealed no differences among the groups of R. macrocnemis, R. camerani, and R. holtzi. Despite the low genetic distance among R. macrocnemis, R. camerani, and R. holtzi species, the pairwise distances estimated from R. tavasensis were higher compared with other Anatolian mountain frog lineages.     

Complete mitochondrial genomes of three sea basses Lateolabrax (Perciformes,Lateolabracidae) species: Genome description and phylogenetic considerations

Genus Lateolabrax consists of three species, Japanese sea bass Lateolabrax japonicus, spotted sea bass Lateolabrax maculatus and blackfin sea bass Lateolabrax latus. The complete mitochondrial DNA (mtDNA) of the three sea basses were amplified and sequenced to characterize and discuss their phylogenetic relationships. The length of mitogenomes was 16,593 bp, 16,479 bp and 16,600 bp, respectively, and all of them consisted of 13 protein-coding genes, 2 ribosomal RNA (rRNA), 22 transfer RNA (tRNA) and a control region, which are typical for mtDNA of vertebrate. Most genes were encoded on the H-strand, except for the ND6 and eight tRNA genes encoding on the L-strand. A significant variation among the three species was detected in length of the control region. Phylogenetic relationship among the three species was constructed based on the datasets, including the 12 protein-coding genes (except ND6 gene), 22 tRNA and 2 rRNA sequences. The results supported the sister taxon between L. japonicus and L. maculatus. The genetic resources reported here are useful for further studies in taxonomy and phylogeny of the three sea basses and related species.     

The Mitochondrial Genome of Paramphistomum cervi (Digenea), the First Representative for the Family Paramphistomidae

We determined the complete mitochondrial DNA (mtDNA) sequence of a fluke, Paramphistomum cervi (Digenea: Paramphistomidae). This genome (14,014 bp) is slightly larger than that of Clonorchis sinensis (13,875 bp), but smaller than those of other digenean species. The mt genome of P. cervi contains 12 protein-coding genes, 22 transfer RNA genes, 2 ribosomal RNA genes and 2 non-coding regions (NCRs), a complement consistent with those of other digeneans. The arrangement of protein-coding and ribosomal RNA genes in the P. cervi mitochondrial genome is identical to that of other digeneans except for a group of Schistosoma species that exhibit a derived arrangement. The positions of some transfer RNA genes differ. Bayesian phylogenetic analyses, based on concatenated nucleotide sequences and amino-acid sequences of the 12 protein-coding genes, placed P. cervi within the Order Plagiorchiida, but relationships depicted within that order were not quite as expected from previous studies. The complete mtDNA sequence of P. cervi provides important genetic markers for diagnostics, ecological and evolutionary studies of digeneans.     

Sequence variation in nuclear ribosomal small subunit,internal transcribed spacer and large subunit regions of Rhizophagus irregularis and Gigaspora margarita is high and isolate‐dependent

Arbuscular mycorrhizal (AM) fungi are known to exhibit high intra‐organism genetic variation. However, information about intra‐ vs. interspecific variation among the genes commonly used in diversity surveys is limited. Here, the nuclear small subunit (SSU) rRNA gene, internal transcribed spacer (ITS) region and large subunit (LSU) rRNA gene portions were sequenced from 3 to 5 individual spores from each of two isolates of Rhizophagus irregularis and Gigaspora margarita. A total of 1482 Sanger sequences (0.5 Mb) from 239 clones were obtained, spanning ~4370 bp of the ribosomal operon when concatenated. Intrasporal and intra‐isolate sequence variation was high for all three regions even though variant numbers were not exhausted by sequencing 12–40 clones per isolate. Intra‐isolate nucleotide variation levels followed the expected order of ITS > LSU > SSU, but the values were strongly dependent on isolate identity. Single nucleotide polymorphism (SNP) densities over 4 SNP/kb in the ribosomal operon were detected in all four isolates. Automated operational taxonomic unit picking within the sequence set of known identity overestimated species richness with almost all cut‐off levels, markers and isolates. Average intraspecific sequence similarity values were 99%, 96% and 94% for amplicons in SSU, LSU and ITS, respectively. The suitability of the central part of the SSU as a marker for AM fungal community surveys was further supported by its level of nucleotide variation, which is similar to that of the ITS region; its alignability across the entire phylum; its appropriate length for next‐generation sequencing; and its ease of amplification in single‐step PCR.     

A competition mechanism regulates the translation of the Escherichia coli operon encoding ribosomal proteins L35 and L20

Escherichia coli ribosomal protein (r-protein) L20 is essential for the assembly of the 50S ribosomal subunit and is also a translational regulator of its own rpmI-rplT operon, encoding r-proteins L35 and L20 in that order. L20 directly represses the translation of the first cistron and, through translational coupling, that of its own gene. The translational operator of the operon is 450 nt in length and includes a long-range pseudoknot interaction between two RNA sequences separated by 280 nt. L20 has the potential to bind both to this pseudoknot and to an irregular hairpin, although only one site is occupied at a time during regulation. This work shows that the rpmI-rplT operon is regulated by competition between L20 and the ribosome for binding to mRNA in vitro and in vivo. Detailed studies on the regulatory mechanisms of r-protein synthesis have only been performed on the rpsO gene, regulated by r-protein S15, and on the alpha operon, regulated by S4. Both are thought to be controlled by a trapping mechanism, whereby the 30S ribosomal subunit, the mRNA, and the initiator tRNA are blocked as a nonfunctional preternary complex. This alternative mode of regulation of the rpmI-rplT operon raises the possibility that control is kinetically and not thermodynamically limited in this case. We show that the pseudoknot, which is known to be essential for L20 binding and regulation, also enhances 30S binding to mRNA as if this structure is specifically recognised by the ribosome.     

Characterization of the chloroplast genome sequence of oil palm (Elaeis guineensis Jacq.)

Oil palm (Elaeis guineensis Jacq.) is an economically important crop, which is grown for oil production. To better understand the molecular basis of oil palm chloroplasts, we characterized the complete chloroplast (cp) genome sequence obtained from 454 pyrosequencing. The oil palm cp genome is 156,973 bp in length consisting of a large single-copy region of?85,192 bp flanked on each side by inverted repeats of 27,071 bp with a small single-copy region of 17,639 bp joining the?repeats. The genome contains 112 unique genes: 79 protein-coding genes, 4 ribosomal RNA genes and 29 tRNA genes. By aligning the cp?genome sequence with oil palm cDNA sequences, we observed 18 non-silent and 10 silent RNA editing events among 19 cp protein-coding genes. Creation of an initiation codon by RNA editing in rpl2 has been reported in several monocots and was also found in the oil palm cp genome. Fifty common chloroplast protein-coding genes from 33 plant taxa were used to construct ML and MP?phylogenetic trees. Their topologies are similar and strongly support for the position of E. guineensis as the sister of closely related species Phoenix dactylifera in Arecaceae (palm families) of monocot subtrees.     

Genome Sequence of a Cellulose-Producing Bacterium,Gluconacetobacter hansenii ATCC 23769

The Gram-negative bacterium Gluconacetobacter hansenii is considered a model organism for studying cellulose synthesis. We have determined the genome sequence of strain ATCC 23769.Plants produce cellulose, an unbranched chain of β-1,4-linked glucose units, as a structural polysaccharide. It is the most abundant polymer on earth, recently receiving much interest due to its potential use as a feedstock for bioethanol. Bacteria also produce cellulose. Among these, Gluconacetobacter hansenii (previously named Acetobacter xylinus) (4) has been extensively characterized and is a model system for cellulose biosynthesis (1, 2, 7). G. hansenii produces extracellular cellulose that is devoid of lignin or hemicellulose, making it an excellent source for pure cellulose. A lack of a completely sequenced genome for this organism has been a limiting factor in identifying other key proteins involved in cellulose synthesis.The whole-genome sequencing of G. hansenii ATCC 23769 was performed using the 454 FLX-Titanium pyrosequencing technology (5). A combinatorial sequencing approach using 489,201 reads obtained from the shotgun library and 195,088 reads from an 8-kb pair end library (3) produced a total of 221,294,116 bp. These reads were assembled using the Newbler assembler, producing 88 large contigs (>500 bp) and a chromosome-sized scaffold of 3,646,142 bp with an average coverage of ×50.5. This scaffold contained exclusively chromosomal DNA and no plasmid sequences. The gaps in the large scaffold were filled by primer walking and subsequent sequencing of the PCR products. The resulting high-quality draft assembly, consisting of a large scaffold with 71 contigs, was annotated using the Prokaryotic Genomes Automatic Annotation Pipeline (PGAAP) service of the National Institute of Biotechnology Information (NCBI).The chromosomal sequence of G. hansenii 23769 contains 3,547,122 bp, with a G+C content of 59%. The genome contains 3,351 genes, of which 3,308 are protein-encoding genes, accounting for 84% of the genome. There are 43 genes for tRNAs and 2 rRNA loci. The genes encoding proteins involved in cellulose synthesis are in an operon consisting of acsAB (GXY_04277), acsC (GXY_04282), and acsD (GXY_04292), as previously shown by Saxena et al. (7). Interestingly, there are two additional copies of acsAB, GXY_08864 and GXY_14452, which share 69% and 72% sequence identity, respectively, with the acsAB genes in the operon; the deduced amino acid sequences are 40% and 46% identical, respectively, with that deduced from acsAB in the operon. There are also two additional copies of acsC, GXY_08869 and GXY_014472, which share 72% and 65% DNA sequence identity, respectively, with the acsC gene in the operon; the deduced amino acid sequences share 28% and 30% amino acid identity, respectively, with that deduced from acsC. acsAB (GXY_08864) and acsC (GXY_08869) are only 17 bp apart, less than the distance (66 bp) between the acsAB and acsC genes in the operon. acsAB (GXY_14452) and acsC (GXY_14472) are separated by 3,299 bp, with three genes in between. However, acsD is present only in the operon, not duplicated elsewhere in the genome. The genome also contains three genes encoding diguanylate cyclase, as previously reported by Tal et al. (8). Diguanylate cyclase catalyzes the formation of cyclic di-GMP, a second messenger in bacteria that functions as an allosteric activator of cellulase synthase AcsAB (6).     

Meanderella rijsii,a new opportunist in the fungal order Pleosporales

Subcutaneous phaeohyphomycosis is an implantation disease caused by melanized fungi and affect both immunocompetent as well as immunocompromised individuals. Diagnosis and treatment require proper isolation and accurate identification of the causative pathogen. We isolated a novel fungus from a case of subcutaneous phaeohyphomycosis in an immunocompetent patient. The 56-year-old patient suffered from a slowly progressive swelling on the metatarsophalangeal join of the left food. The isolated fungus lacked sporulation and sequences of the ribosomal operon did not match with any known species. In a multi-locus phylogenetic analysis involving five markers, the fungus formed a unique lineage in the order Pleosporales, family Trematosphaeriaceae. A new genus, Meanderella and a new species, Meanderella rijsii are here proposed to accommodate the clinical isolate. Whole genome analysis of M. rijsii revealed a number of genes that can be linked to pathogenicity and virulence. Further studies are however needed to understand the role of each gene in the pathogenic process and to determine the origin of pathogenicity in the family of Trematosphaeriaceae.     

Complete mitochondrial genome of spined sleeper Eleotris oxycephala (Perciformes,Eleotridae) and phylogenetic consideration

The complete mitochondrial genome of Eleotris oxycephala was determined to be 16,527 bp in length with (A + T) content of 53%, and it consists of 13 protein-coding genes, 22 tRNAs, 2 ribosomal RNAs, and a control region. The gene composition and the structural arrangement of the E. oxycephala complete mtDNA were identical to most of other vertebrates. Phylogenetic analysis based on different sequences of species of the Gobioidei suborder and different methods showed that E. oxycephala formed a cluster with Eleotris acanthopoma and Eleotridae were divided into two clades. Furthermore, extensive taxon sampling and more molecular information are needed to confirm the phylogenetic relationships among the Gobioidei.     

Complete mitochondrial genome of Coelomactra antiquata (Mollusca: Bivalvia): The first representative from the family Mactridae with novel gene order and unusual tandem repeats

The complete mitochondrial genome plays an important role in the accurate inference of phylogenetic relationships among metazoans. Mactridae, also known as trough shells or duck clams, is an important family of marine bivalve clams in the order Veneroida. Here we present the complete mitochondrial genome sequence of the Xishishe Coelomactra antiquata (Mollusca: Bivalvia), which is the first representative from the family Mactridae. The mitochondrial genome of C. antiquata is of 17,384 bp in length, and encodes 35 genes, including 12 protein-coding, 21 transfer RNA, and 2 ribosomal RNA genes. Compared with the typical gene content of animal mitochondrial genomes, atp8 and tRNAS₂ are missing. Gene order of the mitochondrial genome of C. antiquata is unique compared with others from Veneroida. In the mitochondrial genome of the C. antiquata, a total of 2189 bp of non-coding nucleotides are scattered among 26 non-coding regions. The largest non-coding region contains one section of tandem repeats (99 bp × 11), which is the second largest tandem repeats found in the mitochondrial genomes from Veneroida. The phylogenetic trees based on mitochondrial genomes support the monophyly of Veneridae and Lucinidae, and the relationship at the family level: ((Veneridae + Mactridae) + (Cardiidae + Solecurtidae)) + Lucinidae. The phylogenetic result is consistent with the morphological classification. Meanwhile, bootstrap values are very high (BP = 94–100), suggesting that the evolutionary relationship based on mitochondrial genomes is very reliable.     

Analysis of three leafminers' complete mitochondrial genomes

Liriomyza trifolii (Burgess), Liriomyza huidobrensis (Blanchard), and Liriomyza bryoniae (Kaltenbach), are three closely related and economically important leafminer pests in the world. This study examined the complete mitochondrial genomes of L. trifolii, L. huidobrensis and L. bryoniae, which were 16141 bp, 16236 bp and 16183 bp in length, respectively. All of them displayed 37 typical animal mitochondrial genes and an A + T-rich region. The genomes were highly compact with only 60–68 bp of non-coding intergenic spacer. However, considerable differences in the A + T-rich region were detected among the three species. Results of this study also showed the two ribosomal RNA genes of the three species had very limited variable sites and thus should not provide much information in the study of population genetics of these species. Data generated from three leafminers' complete mitochondrial genomes should provide valuable information in studying phylogeny of Diptera, and developing genetic markers for species identification in leafminers.     

Phylogenetic relationships among four species of Mullidae (Perciformes) inferred from DNA sequences of mitochondrial cytochrome b and 16S rRNA genes

DNA sequence comparisons of two mitochondrial DNA genes were used to infer phylogenetic relationships among four species of mullids. Approximately 238 bp of the mitochondrial 16S ribosomal RNA (rRNA) and 261 bp of the cytochrome b (cytb) genes were sequenced from representatives of three mullid genera (Mullus, Upeneus, Pseudopeneus), present in the Mediterranean Sea. Trees were constructed using three methods: maximum likelihood (ML), neighbor joining (NJ) and parsimony (MP). The results of the analyses of these data together with published data of the same mtDNA segments of two other perciform species (Sparus aurata, Perca fluviatilis), support the previous taxonomic classification of the three genera examined, as well as the classification of the two red mullet species in the same genus.     

Analysis of the complete plastid genome of the unicellular red alga Porphyridium purpureum

We determined the complete nucleotide sequence of the plastid genome of the unicellular marine red alga Porphyridium purpureum strain NIES 2140, belonging to the unsequenced class Porphyridiophyceae. The genome is a circular DNA composed of 217,694 bp with the GC content of 30.3 %. Twenty-nine of the 224 protein-coding genes contain one or multiple intron(s). A group I intron was found in the rpl28 gene, whereas the other introns were group II introns. The P. purpureum plastid genome has one non-coding RNA (ncRNA) gene, 29 tRNA genes and two nonidentical ribosomal RNA operons. One rRNA operon has a tRNA^Ala(UGC) gene between the rrs and the rrl genes, whereas another has a tRNA^Ile(GAU) gene. Phylogenetic analyses suggest that the plastids of Heterokontophyta, Cryptophyta and Haptophyta originated from the subphylum Rhodophytina. The order of the genes in the ribosomal protein cluster of the P. purpureum plastid genome differs from that of other Rhodophyta and Chromalveolata. These results suggest that a large-scale rearrangement occurred in the plastid genome of P. purpureum after its separation from other Rhodophyta.