Adaptation of acaricide stress facilitates Tetranychus urticae expanding against Tetranychus cinnabarinus in China

The two‐spotted spider mite, Tetranychus urticae, and the carmine spider mite, Tetranychus cinnabarinus, are invasive and native species in China, respectively. Compared with T. cinnabarinus, T. urticae has expanded into most parts of China and has become the dominant species of spider mite since 1983, when it was first reported in China. However, the mechanism of the demographic conversion has not been illuminated. In this study, one T. urticae field population and one T. cinnabarinus field population were isolated from the same plant in the same field, and the toxicological characteristics were compared between these two species. Laboratory bioassays demonstrated that T. urticae was more tolerant to commonly used acaricides than T. cinnabarinus. The activities of detoxification enzymes were significantly greater in T. urticae, and the fold changes of enzymes activities in T. urticae were also greater following exposure to acaricides. Furthermore, more metabolism‐related genes were upregulated at a basal level, and more genes were induced in T. urticae following exposure to acaricides. The comparison of proteins and genes between both species led credence to the hypothesis that T. urticae was more resistant to acaricides, which was the reason explaining the expansion of invasive T. urticae against native T. cinnabarinus. Laboratory simulation experiments demonstrated that following the application of acaricides, the composition of a mixed T. urticae/T. cinnabarinus population would change from a T. cinnabarinus‐dominant to a T. urticae‐dominant population. This study not only reveals that T. urticae possesses stronger detoxification capacity than its sibling species T. cinnabarinus, which facilitated its persistent expansion in China, but also points to the need to accurately identify Tetranychus species and to develop species‐specific management strategies for these pests.     

On gene flow between Tetranychus urticae Koch, 1836 and Tetranychus cinnabarinus (Boisduval) Boudreaux, 1956 (Acari: Tetranychidae): Sononomy between the two species

It was found that the reproductive separation between the two-spotted spider mite (Tetranychus urticae Koch) and the carmine spider mite (Tetranychus cinnabarinus (Boisduval) is far from complete. Hybrid strains were established which possessed the morphological characteristics of T. cinnabarinus, but which were homozygous for a marker gene originating from T. urtica. In addition, short-day treatment leads to diapause not only in the species from cold climates (T. urticae), but also in a population of T. cinnabarinus. It is questioned whether T. cinnabarinus deserves ranking at species level.

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Résumé Ce travail montre que l'isolement reproductif entre Tetranychus uriticae Koch et Tetranychus cinnabarinus (Boisduval), est loin d'être complet. L'auteur a obtenu des souches hybrides présentant les caractéristiques morphologiques de T. cinnabarinus, mais homozygotes pour un gêne marqueur provenant de T. urticae. De plus, une diminution de la photopériode entraîne l'entrée en diapause des espèces provenant de régions à climat froid (T. urticae), mais aussi d'une population de T. cinnabarinus.Il est finalemant proposé de considérer Tetranychus cinnabarinus (Boisduval) Boudreaux, 1956, comme un synonyme de Tetranychus urticae Koch, 1836.

     

Molecular approach in spider mites (Acari: Tetranychidae): Preliminary data on ribosomal DNA sequences

DNA sequence data were used to examine phylogenetic relationships between six species of economically important Tetranychidae mites:Eotetranychus carpini (Oudemans),E. pruni (Reck),Tetranychus pacificus McGregor,T. mcdanieli McGregor,T. turkestani Ugarov & Nikolski andT. urticae Koch. With primers directed toward conserved elements flanking the target region, the Polymerase Chain Reaction was used to amplify the ITS2 spacer of the ribosomal DNA molecule. The nucleotide sequence of a 300-bp fragment of the ITS2 was determined by direct sequencing and nucleotide divergence used for intra-generic comparison in mites. The resulting phylogenetic tree expressing interspecific relationships in genusTetranychus agrees with morphological data. The study demonstrates the usefulness of the approach in the assessment of the systematics and evolution of the group.     

Development of species‐specific primers for rapid diagnosis of Tetranychus urticae,T. kanzawai,T. phaselus and T. truncatus (Acari: Tetranychidae)

Species diagnosis is of the utmost importance to both pest management and plant quarantine services. Because of difficulties in the morphological diagnosis of spider mites, molecular techniques are of great value to rapidly and accurately diagnose closely related species. We examined four species of genus Tetranychus (the green and red forms of T. urticae, and T. kanzawai, T. phaselus and T. truncatus), which are found in Korea and are of significance to plant quarantine services. DNA samples isolated from a single egg, larva or adult weighed 64–188 ng. We designed species‐specific primers by performing sequence alignment for 107 sequences of the ribosomal internal transcribed spacer 2 (ITS2) region, which we obtained from GenBank, and sequences generated in this study. Specific nucleotides of each species were selected for designing primers specific for each species. Each species‐specific primer pair, when used to perform PCR analyses, detected only the species from which it originated. However, a T. urticae‐specific primer pair did not discriminate between the green and red forms of this species. These species‐specific primers can be applied in practice for the rapid and accurate diagnosis of spider mite species in plant quarantine and in agricultural fields.     

Sequence analysis of the ribosomal internal transcribed spacers region in spider mites (Prostigmata: Tetranychidae) occurring in citrus orchards in Eastern Spain: use for species discrimination

Tetranychus urticae is a polyphagous mite which is an important pest of citrus worldwide. This mite can be found feeding on many plant species occurring in the citrus agrosystem moving from weeds to trees. Because field samples consist of a mixture of different Tetranychidae species, as a first step necessary to further implement population characterisation of T. urticae, species‐discriminating criteria based on molecular techniques are needed. In this study, the nucleotide variation of the internal transcribed spacers (ITS) 1 and 2 and the intergenic 5.8S fragment of nuclear rDNA of T. urticae, Tetranychus turkestani, Tetranychus evansi, Tetranychus ludeni and Panonychus citri have been determined. Results demonstrate that for these species, the rDNA ITS2 regions are much more conserved than the corresponding rDNA ITS1. The high homogeneity of the ITS2 sequence observed among the specimens of T. urticae obtained from the same ecoregion makes this DNA sequence an excellent tool for species discrimination. ITS sequences differentiate not only species but also specimens from different geographical origin. Furthermore, polymerase chain reaction–restriction fragment length polymorphism analysis of the ITS2 proved adequate for a quick screening of high numbers of field samples.     

Identification of Internal Transcribed Spacer Sequence Motifs in Truffles: a First Step toward Their DNA Bar Coding

This work presents DNA sequence motifs from the internal transcribed spacer (ITS) of the nuclear rRNA repeat unit which are useful for the identification of five European and Asiatic truffles (Tuber magnatum, T. melanosporum, T. indicum, T. aestivum, and T. mesentericum). Truffles are edible mycorrhizal ascomycetes that show similar morphological characteristics but that have distinct organoleptic and economic values. A total of 36 out of 46 ITS1 or ITS2 sequence motifs have allowed an accurate in silico distinction of the five truffles to be made (i.e., by pattern matching and/or BLAST analysis on downloaded GenBank sequences and directly against GenBank databases). The motifs considered the intraspecific genetic variability of each species, including rare haplotypes, and assigned their respective species from either the ascocarps or ectomycorrhizas. The data indicate that short ITS1 or ITS2 motifs (≤50 bp in size) can be considered promising tools for truffle species identification. A dot blot hybridization analysis of T. magnatum and T. melanosporum compared with other close relatives or distant lineages allowed at least one highly specific motif to be identified for each species. These results were confirmed in a blind test which included new field isolates. The current work has provided a reliable new tool for a truffle oligonucleotide bar code and identification in ecological and evolutionary studies.     

Two new species of <Emphasis Type="Italic">Trichoderma</Emphasis> from Yunnan,China

Two new species of the fungal genus Trichoderma, Trichoderma compactum and Trichoderma yunnanense, isolated from rhizosphere of tobacco in Yunnan Province, China are described based on morphological characters and phylogenetic analyses of nucleotide sequences. Our DNA sequences included the internal transcribed spacer (ITS) regions of the rDNA cluster (ITS1 and ITS2), and partial sequences of the translation elongation factor 1-alpha (tef1) and a fragment of the gene coding for endochitinase 42 (ech42). The analyses show that T. compactum belongs to the Harzianum clade, and T. yunnanense belongs to the Hamatum clade.     

DNA barcoding of economically important freshwater fish species from north‐central Nigeria uncovers cryptic diversity

This study examines the utility of morphology and DNA barcoding in species identification of freshwater fishes from north‐central Nigeria. We compared molecular data (mitochondrial cytochrome c oxidase subunit I (COI) sequences) of 136 de novo samples from 53 morphologically identified species alongside others in GenBank and BOLD databases. Using DNA sequence similarity‐based (≥97% cutoff) identification technique, 50 (94.30%) and 24 (45.30%) species were identified to species level using GenBank and BOLD databases, respectively. Furthermore, we identified cases of taxonomic problems in 26 (49.00%) morphologically identified species. There were also four (7.10%) cases of mismatch in DNA barcoding in which our query sequence in GenBank and BOLD showed a sequence match with different species names. Using DNA barcode reference data, we also identified four unknown fish samples collected from fishermen to species level. Our Neighbor‐joining (NJ) tree analysis recovers several intraspecific species clusters with strong bootstrap support (≥95%). Analysis uncovers two well‐supported lineages within Schilbe intermedius. The Bayesian phylogenetic analyses of Nigerian S. intermedius with others from GenBank recover four lineages. Evidence of genetic structuring is consistent with geographic regions of sub‐Saharan Africa. Thus, cryptic lineage diversity may illustrate species’ adaptive responses to local environmental conditions. Finally, our study underscores the importance of incorporating morphology and DNA barcoding in species identification. Although developing a complete DNA barcode reference library for Nigerian ichthyofauna will facilitate species identification and diversity studies, taxonomic revisions of DNA sequences submitted in databases alongside voucher specimens are necessary for a reliable taxonomic and diversity inventory.     

Assaying three new fungi against citrus mites in the laboratory,and a field trial

The Basidiomycotine fungi Meira geulakonigii, Meira argovae and Acaromyces ingoldii were assayed in the laboratory against five species of herbivorous mites: Phyllocoptruta oleivora (Eriophyidae), Panonychus citri, Eutetranychus orientalis, Tetranychus urticae and Tetranychus cinnabarinus (all four Tetranychidae). All fungi caused significantly high mortality rates (as compared to controls) after 14 days, some after 1 week. Phyllocoptruta oleivora was the most susceptible, showing >80% mortality even after 1 week. In a field trial, grapefruits sprayed either once a month or once a season with M. geulakonigii had significantly fewer P. oleivora and less damage than unsprayed fruit. These results suggest that M. geulakonigii may protect grapefruits against the injurious P. oleivora.     

Phenotypic and genotypic identification and phylogenetic characterisation of <Emphasis Type="Italic">Taphrina</Emphasis> fungi on alder

All Taphrina species are dimorphic with a mycelium stage biotrophic on vascular plants and a saprophytic yeast stage. European species of Taphrina on Alnus species (Betulaceae) were identified using morphological, physiological and molecular characteristics, the latter including determination of PCR fingerprints and of nucleotide sequences from selected nuclear ribosomal DNA regions. PCR fingerprinting gives a good overview of species identification, as do nucleotide sequences, which in addition, help to clarify phylogenetic relationships. Taphrina alni is a homogeneous species that exhibited more than 50% similarity in PCR fingerprinting with three different primers. Morphologically, it produces tongue-like outgrowths from female catkins of Alnus incana. Taphrina robinsoniana from A. rugosa and A. serrulata in North America is phylogenetically closely related to T. alni, but the two species could be separated by their PCR fingerprints, partial sequences of 26S rDNA (D1/D2) and ITS1/ITS2 sequences. T. epiphylla and T. sadebeckii are two phylogenetically closely related species. T. epiphylla causes witches brooms in crowns of A. incana. In addition, T. epiphylla forms slightly yellow white-grey leaf spots in midsummer on A. incana. Yellow white-grey leaf spots up to 10 mm on A. glutinosa are characteristic for T. sadebeckii. Both species can be separated well by PCR fingerprinting. Different from T. epiphylla, T. sadebeckii is genotypically more heterogeneous. Only two out of three different primers showed similarity values above 50% in different European strains of T. sadebeckii. Although genetic variability was not detected in complete sequences of the 18S ribosomal DNA of T. sadebeckii, ITS1/ITS2 sequences appeared to be more heterogeneous, too. Taphrina tosquinetii is a genotypically homogeneous species causing leaf curl on Alnus glutinosa. It was not possible to distinguish the yeast phases from different Taphrina species on Alnus using morphological and physiological characteristics only. Dedicated to Prof. Dr. Hanns Kreisel on the occasion of his 70^th birthday     

DNA barcoding of genus Toxoptera Koch (Hemiptera: Aphididae): Identification and molecular phylogeny inferred from mitochondrial COI sequences

Abstract Identification of aphid species is always difficult due to the shortage of easily distinguishable morphological characters. Aphid genus Toxoptera consists of species with similar morphology and similar to Aphis in most morphological characters except the stridulatory apparatus. DNA barcodes with 1 145 bp sequences of partial mitochondrial cytochrome‐coxidase I (COI) genes were used for accurate identification of Toxoptera. Results indicated mean intraspecific sequence divergences were 1.33%, whereas mean interspecific divergences were greater at 8.29% (0.13% and 7.79% if T. aurantii 3 and T. aurantii 4 are cryptic species). Sixteen samples were distinguished to four species correctly by COI barcodes, which implied that DNA barcoding was successful in discrimination of aphid species with similar morphology. Phylogenetic relationships among species of this genus were tested based on this portion of COI sequences. Four species of Toxoptera assembled a clade with low support in maximum‐parsimony (MP) analysis, maximum‐likelihood (ML) analysis and Bayesian phylogenetic trees, the genus Toxoptera was not monophyletic, and there were two sister groups, such as T. citricidus and T. victoriae, and two clades of T. aurantii which probably presented cryptic species in the genus.     

The Complete Mitochondrial Genomes of Six Species of Tetranychus Provide Insights into the Phylogeny and Evolution of Spider Mites

Many spider mites belonging to the genus Tetranychus are of agronomical importance. With limited morphological characters, Tetranychus mites are usually identified by a combination of morphological characteristics and molecular diagnostics. To clarify their molecular evolution and phylogeny, the mitochondrial genomes of the green and red forms of Tetranychus urticae as well as T. kanzawai, T. ludeni, T. malaysiensis, T. phaselus, T. pueraricola were sequenced and compared. The seven mitochondrial genomes are typical circular molecules of about 13,000 bp encoding and they are composed of the complete set of 37 genes that are usually found in metazoans. The order of the mitochondrial (mt) genes is the same as that in the mt genomes of Panonychus citri and P. ulmi, but very different from that in other Acari. The J-strands of the mitochondrial genomes have high (∼84%) A+T contents, negative GC-skews and positive AT-skews. The nucleotide sequence of the cox1 gene, which is commonly used as a taxon barcode and molecular marker, is more highly conserved than the nucleotide sequences of other mitochondrial genes in these seven species. Most tRNA genes in the seven genomes lose the D-arm and/or the T-arm. The functions of these tRNAs need to be evaluated. The mitochondrial genome of T. malaysiensis differs from the other six genomes in having a slightly smaller genome size, a slight difference in codon usage, and a variable loop in place of the T-arm of some tRNAs by a variable loop. A phylogenic analysis shows that T. malaysiensis first split from other Tetranychus species and that the clade of the family Tetranychoidea occupies a basal position in the Trombidiformes. The mt genomes of the green and red forms of T. urticae have limited divergence and short evolutionary distance.     

ITS sequence variation and concerted evolution in the natural hybrid species Malus toringoides

The internal transcribed spacer (ITS) region of nuclear ribosomal DNA (nrDNA) is one of the most used molecular characters in plant systematics. Our previous studies based on morphological analysis and ITS sequence variation suggested that Malus toringoides (Rehd.) Hughes is derived from hybridization between M. transitoria (Batal.) Schneid. and M. kansuensis (Batal.) Schneid. To further understand the variation pattern of ITS sequences in M. toringoides, and to elucidate the evolutionary processes that affect ITS sequence variation after hybridization, we sampled 99 accessions from multiple populations of the hybrid and parental species, and then obtained totally 254 ITS sequences by cloning and sequencing. Our ITS variation data demonstrates three outcomes of ITS repeats after hybrid speciation. ～ 27–41% of M. toringoides have only M. transitoria type ITS sequence, ～ 40–70% have M. transitoria type ITS sequence plus one or two chimeric ITS sequences generated by recombination between parental ITS sequences, and six accessions retain both parental type ITS sequences. The plausible evolutionary processes that created the observed ITS variations were inferred to be the joint actions of recombination, concerted evolution, pseudogenization and backcrossing. Our study provides further understandings of the variation model of ITS repeats after hybridization as well as the evolution of M. toringoides after its hybrid speciation.     

Molecular systematics of threadfin breams and relatives (Teleostei,Nemipteridae)

Threadfin breams and relatives of the family Nemipteridae comprise 69 currently recognized species in five genera. They are found in the tropical and subtropical Indo‐West Pacific and most are commercially important. Using recently developed molecule‐based approaches exploiting DNA sequence variation among species/specimens, this study reconstructed a comprehensive phylogeny of the Nemipteridae, examined the validity of species and explored the cryptic diversity of the family, and tested previous phylogenetic hypotheses. A combined data set (105 taxa from 41 morphospecies) with newly determined sequences from two nuclear genes (RAG1 and RH) and one mitochondrial gene (COI), and a data set with only COI gene sequences (329 newly obtained plus 328 from public databases from a total of 53 morphospecies) were used in the phylogenetic analysis. The latter was further used for species delimitation analyses with two different tools to explore species diversity. Our phylogenetic results showed that all the currently recognized genera were monophyletic. The monotypic genus Scaevius is the sister group of Pentapodus and they together are sister to Nemipterus. These three genera combined to form the sister group of the clade comprising Parascolopsis and Scolopsis. The validity of most of the examined species was confirmed except in some cases. The combined evidence from the results of different analyses revealed a gap in our existing knowledge of species diversity in the Nemipteridae. We found several currently recognized species contain multiple separately evolving metapopulation lineages within species; some lineages should be considered as new species for further assignment. Finally, some problematic sequences deposited in public databases (probably due to misidentification) were also revised in this study to improve the accuracy for prospective DNA barcoding work on nemipterid fishes.     

Molecular identification of four Panonychus species (Acari: Tetranychidae) in Korea,including new records of P. caglei and P. mori

Four species of the genus Panonychus are identified in Korea including two previously known species P. citri (McGregor) and P. ulmi (Koch) and two newly identified species P. mori Yokoyama and P. caglei Mellot. Morphological diagnostics were observed among the four species in the color of dorsal tubercles and in the shape of male aedeagus. The dorsal tubercles of P. citri, P. ulmi, P. mori and P. caglei are red, white, whitish red and light red, respectively. The aedeagi of male adults are diagnostic in sigmoid‐shaped at the distal end and its shape and length was different among four species. Molecular comparison of the internal transcribed spacer 2 (ITS2) sequence of nuclear DNA and cytochrome‐c oxidase subunit I (COI) nucleotide sequence of mitochondrial DNA among the four species showed divergences 8–12% and 9–12%, respectively. Molecular analysis of the ITS2 and COI sequences revealed their divergences were slightly different among four species. In addition, species‐specific primer sets were designed at the base on ITS2 sequences to precisely diagnose these four species at the molecular level.     

Systematics of Cladophora spp. (Chlorophyta) from North Carolina,USA, based upon morphology and DNA sequence data with a description of Cladophora subtilissima sp. nov.

Identification of Cladophora species is challenging due to conservation of gross morphology, few discrete autapomorphies, and environmental influences on morphology. Twelve species of marine Cladophora were reported from North Carolina waters. Cladophora specimens were collected from inshore and offshore marine waters for DNA sequence and morphological analyses. The nuclear‐encoded rRNA internal transcribed spacer regions (ITS) were sequenced for 105 specimens and used in molecular assisted identification. The ITS1 and ITS2 region was highly variable, and sequences were sorted into ITS Sets of Alignable Sequences (SASs). Sequencing of short hyper‐variable ITS1 sections from Cladophora type specimens was used to positively identify species represented by SASs when the types were made available. Secondary structures for the ITS1 locus were also predicted for each specimen and compared to predicted structures from Cladophora sequences available in GenBank. Nine ITS SASs were identified and representative specimens chosen for phylogenetic analyses of 18S and 28S rRNA gene sequences to reveal relationships with other Cladophora species. Phylogenetic analyses indicated that marine Cladophorales were polyphyletic and separated into two clades, the Cladophora clade and the “Siphonocladales” clade. Morphological analyses were performed to assess the consistency of character states within species, and complement the DNA sequence analyses. These analyses revealed intra‐ and interspecific character state variation, and that combined molecular and morphological analyses were required for the identification of species. One new report, Cladophora dotyana, and one new species Cladophora subtilissima sp. nov., were revealed, and increased the biodiversity of North Carolina marine Cladophora to 14 species.     

Investigations on the Tetranychus urticae complex in north west Europe (Acari: Tetranychidae)

Two species of spider mite occur in greenhouses in the Netherlands. Tetranychus urticae Koch is usually green, can live on many plants, but cannot build up large populations on carnations; it may have a diapausing stage which is very resistant to cold. No biological races of T. urticae were found. T. cinnabarinus Boisd. is carmine-coloured, often found on carnations, and does not have a diapause. It is not resistant to cold.The two species do not interbreed. Growers of carnations have only T. cinnabarinus to deal with, and can arrange control measures accordingly.

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Zusammenfassung Untersuchungen der Morphologie, der Wirtspflanzenwahl, der Überwinterungsweise und Kreuzingsexperimente haben gezeigt, daß in Gewächshäusern Hollands zwei Spinnmilben-Arten auftreten, nämlich Tetranychus urticae Koch und T. cinnabarinus Boids. Darüberhinaus wurde Material von Spinnmilben je einer Lokalität in Deutschland, der Schweiz und Belgien verwendet. T. urticae ist meistens grün gefärbt, lebt an einem großen Wirtspflanzenkreis, kann aber an Nelken (Dianthus caryophyllus L.) keine Populationen bilden. Diese Art geht unter dem Einfluß verschiedener biologischer Faktoren in Diapause. Während dieser Periode ist sie sehr kälteresistent. Der Winter wird an geschützten Orten verbracht. Kreuzungen zwischen Populationen verschiedener Herkunft ergaben stets eine normale Nachkommenschaft. Zucht-experimente mit diesen Populationen auf verschiedenen Wirtspflanzen ergaben keinen Hinweis für das Bestehen von biologischen Rassen bei T. urticae. T. cinnabarinus ist karminrot gefärbt und wird am häufigsten auf Nelken gefunden, obwohl in Laboratoriumsversuchen die Entwicklung an Buschbohnen (Phaseolus vulgaris L.) schneller verläuft. Diese Art tritt überhaupt nicht in Diapause ein, bleibt den Winter über an den Blättern und ist gegenüber Kältebedingungen entschieden weniger resistent als T. urticae. Kreuzungen zwischen Populationen verschiedener Herkunft ergaben immer eine normale Nachkommenschaft.Das Ausbleiben von Bastardierungen, das in Kreuzungsexperimenten zwischen den beiden Arten gefunden wurde, erbrachte den strengsten Nachweis, daß in den Gewächshäusern zwei verschiedene Arten vorkommen.Da T. cinnabarinus hauptsächlich auf Gewächshäuser mit Nelken beschränkt ist und T. urticae sich andererseits an diesen Pflanzen nicht vermehrt, haben es die Nelkenanbauer lediglich mit T. cinnabarinus zu tun, und es ergibt sich eine Möglichkeit, Nelken frei von Spinnmilbenbefall zu halten.

     

Hidden diversity of Ctenophora revealed by new mitochondrial COI primers and sequences

The mitochondrial gene cytochrome-c-oxidase subunit 1 (COI) is useful in many taxa for phylogenetics, population genetics, metabarcoding, and rapid species identifications. However, the phylum Ctenophora (comb jellies) has historically been difficult to study due to divergent mitochondrial sequences and the corresponding inability to amplify COI with degenerate and standard COI “barcoding” primers. As a result, there are very few COI sequences available for ctenophores, despite over 200 described species in the phylum. Here, we designed new primers and amplified the COI fragment from members of all major groups of ctenophores, including many undescribed species. Phylogenetic analyses of the resulting COI sequences revealed high diversity within many groups that was not evident from more conserved 18S rDNA sequences, in particular among the Lobata (Ctenophora; Tentaculata; Lobata). The COI phylogenetic results also revealed unexpected community structure within the genus Bolinopsis, suggested new species within the genus Bathocyroe, and supported the ecological and morphological differences of some species such as Lampocteis cruentiventer and similar undescribed lobates (Lampocteis sp. “V” stratified by depth, and “A” differentiated by colour). The newly designed primers reported herein provide important tools to enable researchers to illuminate the diversity of ctenophores worldwide via quick molecular identifications, improve the ability to analyse environmental DNA by improving reference libraries and amplifications, and enable a new breadth of population genetic studies.