The secondary structure of the unusually long 18S ribosomal RNA of the myxozoan Sphaerospora truttae and structural evolutionary trends in the Myxozoa

The nearly complete 18S rRNA sequence of the myxozoan parasite Sphaerospora truttae shows an extraordinary length (2,552bp) in comparison with other myxozoans and with metazoans in general (average 1,800-1,900bp). The sequence shows nucleotide insertions in most variable regions of the 18S rRNA (V2, V4, V5 and V7), with especially large expansion segments in V4 and V7. In the myxozoans, nucleotide insertions and specific secondary structures in these regions of the gene were found to be strongly related to large scale phylogenetic clustering and thus with the invertebrate host type. Whereas expansion segments were generally found to be absent in the malacasporeans and the clade of primary marine myxozoan species, they occur in all taxa of the clade containing freshwater species, where they showed a consistent secondary structure throughout. The longest expansion segments occur in S. truttae, Sphaerospora elegans and Leptotheca ranae, which represent a clade that has emerged after the malacosporeans and before the radiation of all other myxozoan genera. These three species demonstrate structural links to the malacosporeans as well as other unique features. A smaller number of nucleotide insertions in different subhelices and specific secondary structures appear to have evolved independently in two marine genera, i.e. Ceratomyxa and Parvicapsula. The secondary structural elements of V4 and V7 of the myxozoan 18S rRNAs were found to be highly informative and revealed evolutionary trends of various regions of the gene hitherto unknown, since previous analyses have been based on primary sequence data excluding these regions. Furthermore, the unique features of the V4 region in S. truttae allowed for the design of a highly specific PCR assay for this species.     

Hypervariable regions (V1–V9) of the dinoflagellate 18S rRNA using a large dataset for marker considerations

DNA sequencing methods have been used for the molecular taxonomic discrimination of dinoflagellate protists, particularly using partial 18S rRNA sequences. This study evaluated the taxonomic discrimination power of rRNA gene hypervariable regions (V1 to V9) in dinoflagellates from a large dataset. These included 77 dinoflagellate species (9 orders, 17 families, 40 genera). The complete 18S rRNA sequences of the dinoflagellates ranged from 1,787 to 1,813?bp in length, and consisted of eight V regions with a total combined length of 678 to 699?bp. Regions longer than 100?bp were recoded for V2, V4, and V8 regions; high nucleotide divergences were detected in V1, V2, and V4 regions. Statistic tests showed that the divergences of individual V regions were significantly different (t-test, P?<?0.05) compared with the complete 18S rRNA. The V2 region showed the highest score (83.5%) for PI sites. Moreover, intra-genus DNA similarities of the V2 were considerably low (<93%). Neighbor-joining analyses showed that phylogenetic resolution in the V2–V4 region was 1.32-fold higher than that of the complete 18S rRNA. These results demonstrate that V2 has the highest taxonomic resolving power within the 18S rRNA gene of dinoflagellates, suggesting the V2 and adjacent regions (e.g., V1 to V4) may be the best for marker considerations.     

Genotypic variations in field isolates of Theileria species infecting giraffes (Giraffa camelopardalis tippelskirchi and Giraffa camelopardalis reticulata) in Kenya

Recently, mortalities among giraffes, attributed to infection with unique species of piroplasms were reported in South Africa. Although haemoparasites are known to occur in giraffes of Kenya, the prevalence, genetic diversity and pathogenicity of these parasites have not been investigated.In this study, blood samples from 13 giraffes in Kenya were investigated microscopically and genomic DNA extracted. PCR amplicons of the hyper-variable region 4 (V4) of Theileria spp. small subunit ribosomal RNA (18S rRNA) gene were hybridized to a panel of genus- and species-specific oligonucleotide probes by reverse line blot (RLB). Two newly designed oligonucleotide probes specific for previously identified Theileria spp. of giraffes found single infections in eight of the specimens and mixed infections in the remaining five samples.Partial 18S rRNA genes were successfully amplified from 9 samples and the PCR amplicons were cloned. A total of 28 plasmid clones representing the Kenyan isolates were analyzed in the present study and compared with those of closely-related organisms retrieved from GenBank. In agreement with RLB results, the nucleotide sequence alignment indicated the presence of mixed infections in the giraffes. In addition, sequence alignment with the obtained 18S rRNA gene sequences revealed extensive microheterogeneities within and between isolates, characterized by indels in the V4 regions and point mutations outside this region. Phylogeny with 18S rRNA gene sequences from the detected parasites and those of related organisms places Theileria of giraffes into two major groups, within which are numerous clades that include the isolates reported in South Africa. Collectively, these data suggest the existence of at least two distinct Theileria species among giraffes, and extensive genetic diversity within the two parasite groups.     

Taxonomic Resolutions Based on 18S rRNA Genes: A Case Study of Subclass Copepoda

Biodiversity studies are commonly conducted using 18S rRNA genes. In this study, we compared the inter-species divergence of variable regions (V1–9) within the copepod 18S rRNA gene, and tested their taxonomic resolutions at different taxonomic levels. Our results indicate that the 18S rRNA gene is a good molecular marker for the study of copepod biodiversity, and our conclusions are as follows: 1) 18S rRNA genes are highly conserved intra-species (intra-species similarities are close to 100%); and could aid in species-level analyses, but with some limitations; 2) nearly-whole-length sequences and some partial regions (around V2, V4, and V9) of the 18S rRNA gene can be used to discriminate between samples at both the family and order levels (with a success rate of about 80%); 3) compared with other regions, V9 has a higher resolution at the genus level (with an identification success rate of about 80%); and 4) V7 is most divergent in length, and would be a good candidate marker for the phylogenetic study of Acartia species. This study also evaluated the correlation between similarity thresholds and the accuracy of using nuclear 18S rRNA genes for the classification of organisms in the subclass Copepoda. We suggest that sample identification accuracy should be considered when a molecular sequence divergence threshold is used for taxonomic identification, and that the lowest similarity threshold should be determined based on a pre-designated level of acceptable accuracy.     

Barcoding marine nematodes: an improved set of nematode 18S rRNA primers to overcome eukaryotic co-interference

Nematodes form an important component of many benthic marine ecosystems and DNA barcoding approaches could provide an insight into nematode community composition from different environments globally. We have amplified nematode 18S rRNA sequences using standard nematode18S rRNA primers from environmental DNA extracted from intertidal sediment collected from New Jersey coast, USA to test whether the published marine nematode 18S rRNA sequences from GenBank and EMBL databases can effectively assign unknown nematode sequences into genus or species level. Most of the sequenced clones showed some degree of identities with published marine nematode 18S rRNA sequences. However, relatively very few of the sequences could be assigned even to genus level based on sequence assignment rule. In addition, other eukaryotic 18S rRNA sequences were found to be co-amplified with commonly used nematode 18S rRNA primers. We found that the majority of the current nematode 18S rRNA primers will co-amplify other eukaryotes if environmental DNA is the target template. We therefore designed a new set of nematode 18S rRNA primers and evaluated them using environmental DNA in intertidal sediment from the New Jersey coast. In total, 40 clones were screened and subsequently sequenced and all the sequences showed varying degree of identities with published nematode 18S rRNA sequences from GenBank and EMBL databases, and no obvious eukaryotic co-amplicons were detected with new primers. Only 13 out of 40 clones amplified with the new primer set showed 100% identity to published Daptonema and Metachromadora 18S rRNA sequences. The current molecular databases for nematodes are dominated by sequences from NW Europe and need to be more extensively populated with new full length 18S rRNA nematode sequences collected from different biogeographic locations. The new primers developed in this study, in combination with an updated nematode 18S rRNA sequence database, would help us to better investigate and understand the diversity and community composition of free-living marine nematodes based on DNA barcoding approaches during biodiversity or biomonitoring surveys on a global-scale.     

Molecular Evolution and Diversity of Conus Peptide Toxins,as Revealed by Gene Structure and Intron Sequence Analyses

Cone snails, which are predatory marine gastropods, produce a cocktail of venoms used for predation, defense and competition. The major venom component, conotoxin, has received significant attention because it is useful in neuroscience research, drug development and molecular diversity studies. In this study, we report the genomic characterization of nine conotoxin gene superfamilies from 18 Conus species and investigate the relationships among conotoxin gene structure, molecular evolution and diversity. The I1, I2, M, O2, O3, P, S, and T superfamily precursors all contain three exons and two introns, while A superfamily members contain two exons and one intron. The introns are conserved within a certain gene superfamily, and also conserved across different Conus species, but divergent among different superfamilies. The intronic sequences contain many simple repeat sequences and regulatory elements that may influence conotoxin gene expression. Furthermore, due to the unique gene structure of conotoxins, the base substitution rates and the number of positively selected sites vary greatly among exons. Many more point mutations and trinucleotide indels were observed in the mature peptide exon than in the other exons. In addition, the first example of alternative splicing in conotoxin genes was found. These results suggest that the diversity of conotoxin genes has been shaped by point mutations and indels, as well as rare gene recombination or alternative splicing events, and that the unique gene structures could have made a contribution to the evolution of conotoxin genes.     

Critical issues in bacterial phylogeny

To understand bacterial phylogeny, it is essential that the following two critical issues be resolved: (i) development of well-defined (molecular) criteria for identifying the main groups within Bacteria, and (ii) to understand how the different main groups are related to each other and how they branched off from a common ancestor. These issues are not resolved at present. We have recently described a new approach, based on shared conserved inserts and deletions (indels or signature sequences) found in various proteins, that provides a reliable means for understanding these issues. A large number of conserved indels that are shared by different groups of bacteria have been identified. Using these indels, and based simply on their presence or absence, all of the main groups within Bacteria can be defined in clear molecular terms and new species could be assigned to them with minimal ambiguity. The analysis of these indels also permits one to logically deduce that the various main bacterial groups have branched off from a common ancestor in the following order: Low G+C Gram-positive ==> High G+C Gram-positive ==> Clostridium-Fusobacteria-Thermotoga ==> Deinococcus-Thermus-Green nonsulfur bacteria ==> Cyanobacteria ==> Spirochetes ==> Chlamydia-Cytophaga-Bacteroides-Green sulfur bacteria ==> Aquifex ==> Proteobacteria 1 (epsilon and delta) ==> Proteobacteria-2. (alpha) ==> Proteobacteria-3 (beta) and ==> Proteobacteria-4 (gamma). The validity of this approach was tested using sequence data from bacterial genomes. By making use of 18 conserved indels, species from all 60 completed bacterial genomes were assigned to different groups. The observed distribution of these indels in different species was then compared with that predicted by the model. Of the 936 observations concerning the placement of these indels in various species, all except one were in accordance with the model. The placement of bacteria into different groups using this approach also showed excellent correlation with the 16S rRNA phylogenies with nearly all of the species assigned to the same groups by both methods. These results provide strong evidence that the genes containing these indels have not been affected by factors such as lateral gene transfers. However, such events are readily detected by this means and some examples are provided. The approach described here thus provides a reliable and internally consistent means for understanding various critical and long outstanding issues in bacterial phylogeny.     

Haptophyte Diversity and Vertical Distribution Explored by 18S and 28S Ribosomal RNA Gene Metabarcoding and Scanning Electron Microscopy

Haptophyta encompasses more than 300 species of mostly marine pico‐ and nanoplanktonic flagellates. Our aims were to investigate the Oslofjorden haptophyte diversity and vertical distribution by metabarcoding, and to improve the approach to study haptophyte community composition, richness and proportional abundance by comparing two rRNA markers and scanning electron microscopy (SEM). Samples were collected in August 2013 at the Outer Oslofjorden, Norway. Total RNA/cDNA was amplified by haptophyte‐specific primers targeting the V4 region of the 18S, and the D1‐D2 region of the 28S rRNA. Taxonomy was assigned using curated haptophyte reference databases and phylogenetic analyses. Both marker genes showed Chrysochromulinaceae and Prymnesiaceae to be the families with highest number of Operational Taxonomic Units (OTUs), as well as proportional abundance. The 18S rRNA data set also contained OTUs assigned to eight supported and defined clades consisting of environmental sequences only, possibly representing novel lineages from family to class. We also recorded new species for the area. Comparing coccolithophores by SEM with metabarcoding shows a good correspondence with the 18S rRNA gene proportional abundances. Our results contribute to link morphological and molecular data and 28S to 18S rRNA gene sequences of haptophytes without cultured representatives, and to improve metabarcoding methodology.     

Exploitation of archived marine nematodes — a hot lysis DNA extraction protocol for molecular studies

Museums and other research organizations around the world have large numbers of formalin-fixed marine invertebrates in their collections. These have the potential to be a valuable resource for molecular ecological studies, but the development of methodologies for the molecular analysis of formalin-fixed material has been slow. In this study, a hot lysis protocol accompanied by the use of a commercial DNA extraction kit has been employed for DNA recovery from archived marine nematodes, followed by PCR amplification and sequencing. In total, 25 specimens ranging from estuarine to deep sea environments were subjected to molecular analyses. Successful amplification and sequencing of the nuclear small subunit ribosomal RNA (18S rRNA) gene was achieved in all individuals. Additionally, some estuarine nematodes were tentatively identified to genus and species using a phylogenetic approach. In the future, this technique should prove to be profitable for the genetic study of a wide range of formalin-fixed marine invertebrates.