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1. Phylogenetic relationships, host associations, and three new species of a poorly known group of “tetraphyllidean” tapeworms from elasmobranchs

   https://doi.org/10.11646/zootaxa.5254.1.2  

   BUENO, VERONICA M. ; CAIRA, JANINE N. ( March 2023 , Zootaxa)

   This paper aims to expand understanding of a poorly known group of cestodes that parasitize an intriguingly diverse suite of elasmobranchs. The group’s three currently described members (i.e., Pentaloculum macrocephalum, Pentaloculum hoi, and Zyxibothrium kamienae) parasitize an electric ray, a carpet shark, and a skate, respectively. Pentaloculum grahami n. sp. is described from a second genus of carpet shark, specifically Parascyllium collare, in Australia. Zyxibothrium duffyi n. sp. and Zyxibothrium healyae n. sp. are described from the deep-sea skates Brochiraja asperula and Brochiraja spinifera, respectively off New Zealand. The three new species share distinctive bothridia that bear a small number of large, circular, facial loculi and lateral bands of vitelline follicles that converge posterior to the ovary—features which are found in all other members of these genera. Zyxibothrium healyae n. sp. is unique in possessing three, rather than four or five, facial loculi. Zyxibothrium duffyi n. sp. possesses a combination of five facial loculi and vitelline follicles that stop short of the anterior margin of the proglottid. Pentaloculum grahami n. sp. is the largest member of the group with the greatest number of proglottids. Based on striking similarities in scolex morphology, Pentaloculum and Zyxibothrium have been hypothesized to belong to a distinct subgroup of “tetraphyllideans” provisionally designated as Clade 1. Based on sequence data for the D1–D3 region of the 28S rDNA gene generated for species of Zyxibothrium for the first time, we confirm the reciprocal monophyly of both genera as well as the monophyly of Clade 1 and its status as a distinct lineage among the “Tetraphyllidea”. This work also suggests that the presence of five facial loculi is homoplasious given this character state is found in members of both genera. The new species expand the host associations of Clade 1 to include additional skate and carpet shark genera. Moving forward we would expect to find additional members of this group parasitizing other species of parascyliid carpet sharks as well as other species of the rajid genus Malacoraja and the arhynchobatid genus Brochiraja. Here we have doubled the number of described species in the taxon referred to as Clade 1 while simultaneously expanding our understanding of the morphology and anatomy of its members. This additional information will help inform the ultimate revision of the ordinal classification of the cestodes to address the highly polyphyletic nature of the order “Tetraphyllidea” as it is currently configured. 

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2. A catalogue of the tribe Sepidiini Eschscholtz, 1829 (Tenebrionidae, Pimeliinae) of the world

   https://doi.org/10.3897/zookeys.844.34241  

   Kamiński, Marcin J. ; Kanda, Kojun ; Lumen, Ryan ; Ulmer, Jonah M. ; Wirth, Christopher C. ; Bouchard, Patrice ; Aalbu, Rolf ; Mal, Noël ; Smith, Aaron D. ( May 2019 , ZooKeys)

   This catalogue includes all valid family-group (six subtribes), genus-group (55 genera, 33 subgenera), and species-group names (1009 species and subspecies) of Sepidiini darkling beetles (Coleoptera: Tenebrionidae: Pimeliinae), and their available synonyms. For each name, the author, year, and page number of the description are provided, with additional information (e.g., type species for genus-group names, author of synonymies for invalid taxa, notes) depending on the taxon rank. Verified distributional records (loci typici and data acquired from revisionary publications) for all the species are gathered. Distribution of the subtribes is illustrated and discussed. Several new nomenclatural acts are included. The generic names Phanerotomea Koch, 1958 [= Ocnodes Fåhraeus, 1870] and Parmularia Koch, 1955 [= Psammodes Kirby, 1819] are new synonyms (valid names in square brackets). The following new combinations are proposed: Ocnodesacuductusacuductus (Ancey, 1883), O. acuductusufipanus (Koch, 1952), O. adamantinus (Koch, 1952), O. argenteofasciatus (Koch, 1953), O. arnoldiarnoldi (Koch, 1952), O. arnoldisabianus (Koch, 1952), O.barbosai (Koch, 1952), O.basilewskyi (Koch, 1952), O.bellmarleyi (Koch, 1952), O. benguelensis (Koch, 1952), O. bertolonii (Guérin-Méneville, 1844), O. blandus (Koch, 1952), O. brevicornis (Haag-Rutenberg, 1875), O. brunnescensbrunnescens (Haag-Rutenberg, 1871), O. brunnescensmolestus (Haag-Rutenberg, 1875), O. buccinator (Koch, 1952), O. bushmanicus (Koch, 1952), O. carbonarius (Gerstaecker, 1854), O. cardiopterus (Fairmaire, 1888), O. cataractus (Koch, 1952), O. cinerarius (Koch, 1952), O. complanatus (Koch, 1952), O. confertus (Koch, 1952), O. congruens (Péringuey, 1899), O. cordiventris (Haag-Rutenberg, 1871), O. crocodilinus (Koch, 1952), O. dimorphus (Koch, 1952), O. distinctus (Haag-Rutenberg, 1871), O. dolosus (Péringuey, 1899), O. dorsocostatus (Gebien, 1910), O. dubiosus (Péringuey, 1899), O. ejectus (Koch, 1952), O. epronoticus (Koch, 1952), O. erichsoni (Haag-Rutenberg, 1871), O. ferreiraeferreirae (Koch, 1952), O. ferreiraezulu (Koch, 1952), O. fettingi (Haag-Rutenberg, 1875), O. fistucans (Koch, 1952), O. fraternus (Haag-Rutenberg, 1875), O. freyi (Koch, 1952), O. freudei (Koch, 1952), O. fulgidus (Koch, 1952), O. funestus (Haag-Rutenberg, 1871), O. gemmeulus (Koch, 1952), O. gibberosulus (Péringuey, 1908), O. gibbus (Haag-Rutenberg, 1879), O. globosus (Haag-Rutenberg, 1871), O. granisterna (Koch, 1952), O. granulosicollis (Haag-Rutenberg, 1871), O.gridellii (Koch, 1960), O. gueriniguerini (Haag-Rutenberg, 1871), O. guerinilawrencii (Koch, 1954), O. guerinimancus (Koch 1954), O. haemorrhoidalishaemorrhoidalis (Koch, 1952), O. haemorrhoidalissalubris (Koch, 1952), O. heydeni (Haag-Rutenberg, 1871), O. humeralis (Haag-Rutenberg, 1871), O. humerangula (Koch, 1952), O. imbricatus (Koch, 1952), O.imitatorimitator (Péringuey, 1899), O. imitatorinvadens (Koch, 1952), O. inflatus (Koch, 1952), O. janssensi (Koch, 1952), O. javeti (Haag-Rutenberg, 1871), O. junodi (Péringuey, 1899), O. kulzeri (Koch, 1952), O. lacustris (Koch, 1952), O. laevigatus (Olivier, 1795), O. lanceolatus (Koch, 1953), O. licitus (Peringey, 1899), O. luctuosus (Haag-Rutenberg, 1871), O. luxurosus (Koch, 1952), O. maputoensis (Koch, 1952), O. marginicollis (Koch, 1952), O. martinsi (Koch, 1952), O. melleus (Koch, 1952), O. mendicusestermanni (Koch, 1952), O. mendicusmendicus (Péringuey, 1899), O. miles (Péringuey, 1908), O. mimeticus (Koch, 1952), O. misolampoides (Fairmaire, 1888), O. mixtus (Haag-Rutenberg, 1871), O. monacha (Koch, 1952), O. montanus (Koch, 1952), O. mozambicus (Koch, 1952), O. muliebriscurtus (Koch, 1952), O. muliebrismuliebris (Koch, 1952), O. muliebrissilvestris (Koch, 1952), O. nervosus (Haag-Rutenberg, 1871), O.notatum (Thunberg, 1787), O. notaticollis (Koch, 1952), O. odorans (Koch, 1952), O. opacus (Solier, 1843), O. osbecki (Billberg, 1815), O. overlaeti (Koch, 1952), O. ovulus (Haag-Rutenberg, 1871), O. pachysomaornata (Koch, 1952), O. pachysomapachysoma (Péringuey, 1892), O. papillosus (Koch, 1952), O. pedator (Fairmaire, 1888), O. perlucidus (Koch, 1952), O. planus (Koch, 1952), O. pretorianus (Koch, 1952), O. procursus (Péringuey, 1899), O. protectus (Koch, 1952), O. punctatissimus (Koch, 1952), O. puncticollis (Koch, 1952), O. punctipennisplanisculptus (Koch, 1952), O. punctipennispunctipennis (Harold, 1878), O. punctipleura (Koch, 1952), O. rhodesianus (Koch, 1952), O. roriferus (Koch, 1952), O. rufipes (Harold, 1878), O. saltuarius (Koch, 1952), O.scabricollis (Gerstaecker, 1854), O. scopulipes (Koch, 1952), O. scrobicollisgriqua (Koch, 1952), O. scrobicollissimulans (Koch, 1952), O. semirasus (Koch, 1952), O. semiscabrum (Haag-Rutenberg, 1871), O. sericicollis (Koch, 1952), O.similis (Péringuey, 1899), O. sjoestedti (Gebien, 1910), O. spatulipes (Koch, 1952), O. specularis (Péringuey, 1899), O. spinigerus (Koch, 1952), O. stevensoni (Koch, 1952), O. tarsocnoides (Koch, 1952), O. temulentus (Koch, 1952), O. tenebrosusmelanarius (Haag-Rutenberg, 1871), O. tenebrosustenebrosus (Erichson, 1843), O. tibialis (Haag-Rutenberg, 1871), O. torosus (Koch, 1952), O. transversicollis (Haag-Rutenberg, 1879), O. tumidus (Haag-Rutenberg, 1871), O. umvumanus (Koch, 1952), O. vagus (Péringuey, 1899), O. vaticinus (Péringuey, 1899), O. verecundus (Péringuey, 1899), O. vetustus (Koch, 1952), O. vexator (Péringuey, 1899), O. virago (Koch, 1952), O. warmeloi (Koch, 1953), O. zanzibaricus (Haag-Rutenberg, 1875), Psammophanesantinorii (Gridelli, 1939), and P.mirei (Pierre, 1979). The type species [placed in square brackets] of the following genus-group taxa are designated for the first time, Ocnodes Fåhraeus, 1870 [ Ocnodesscrobicollis Fåhraeus, 1870], Psammodophysis Péringuey, 1899 [ Psammodophysisprobes Péringuey, 1899], and Trachynotidus Péringuey, 1899 [ Psammodesthoreyi Haag-Rutenberg, 1871]. A lectotype is designated for Histrionotusomercooperi Koch, 1955 in order to fix its taxonomic status. Ulamus Kamiński is introduced here as a replacement name for Echinotus Marwick, 1935 [ Type species. Aviculaechinata Smith, 1817] (Mollusca: Pteriidae) to avoid homonymy with Echinotus Solier, 1843 (Coleoptera: Tenebrionidae). 

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3. A new mode of NPR1 action via an NB‐ARC–NPR1 fusion protein negatively regulates the defence response in wheat to stem rust pathogen

   https://doi.org/10.1111/nph.16748  

   Wang, Xiaojing ; Zhang, Hongtao ; Nyamesorto, Bernard ; Luo, Yi ; Mu, Xiaoqian ; Wang, Fangyan ; Kang, Zhensheng ; Lagudah, Evans ; Huang, Li ( August 2020 , New Phytologist)

   NPR1 has been found to be a key transcriptional regulator in some plant defence responses. There are nineNPR1homologues (TaNPR1) in wheat, but little research has been done to understand the function of thoseNPR1‐like genes in the wheat defence response against stem rust (Puccinia graminisf. sp.tritici) pathogens.

   We used bioinformatics and reverse genetics approaches to study the expression and function of eachTaNPR1.

   We found six members ofTaNPR1located on homoeologous group 3 chromosomes (designated asTaG3NPR1) and three on homoeologous group 7 chromosomes (designated asTaG7NPR1). The group 3 NPR1 proteins regulate transcription of SA‐responsivePRgenes. Downregulation of all theTaNPR1homologues via virus‐induced gene co‐silencing resulted in enhanced resistance to stem rust. More specifically downregulatingTaG7NPR1homeologues orTa7ANPR1expression resulted in stem rust resistance phenotype. By contrast, knocking downTaG3NPR1alone did not show visible phenotypic changes in response to the rust pathogen. Knocking outTa7ANPR1enhanced resistance to stem rust. TheTa7ANPR1locus is alternatively spliced under pathogen inoculated conditions.

   We discovered a new mode of NPR1 action in wheat at theTa7ANPR1locus through an NB‐ARC–NPR1 fusion protein negatively regulating the defence to stem rust infection.

    

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4. Chromosome-level genome of Schistosoma haematobium underpins genome-wide explorations of molecular variation

   https://doi.org/10.1371/journal.ppat.1010288  

   Stroehlein, Andreas J. ; Korhonen, Pasi K. ; Lee, V. Vern ; Ralph, Stuart A. ; Mentink-Kane, Margaret ; You, Hong ; McManus, Donald P. ; Tchuenté, Louis-Albert Tchuem ; Stothard, J. Russell ; Kaur, Parwinder ; et al ( February 2022 , PLOS Pathogens)

   Zamanian, Mostafa (Ed.)

   Urogenital schistosomiasis is caused by the blood fluke Schistosoma haematobium and is one of the most neglected tropical diseases worldwide, afflicting > 100 million people. It is characterised by granulomata, fibrosis and calcification in urogenital tissues, and can lead to increased susceptibility to HIV/AIDS and squamous cell carcinoma of the bladder. To complement available treatment programs and break the transmission of disease, sound knowledge and understanding of the biology and ecology of S . haematobium is required. Hybridisation/introgression events and molecular variation among members of the S . haematobium -group might effect important biological and/or disease traits as well as the morbidity of disease and the effectiveness of control programs including mass drug administration. Here we report the first chromosome-contiguous genome for a well-defined laboratory line of this blood fluke. An exploration of this genome using transcriptomic data for all key developmental stages allowed us to refine gene models (including non-coding elements) and annotations, discover ‘new’ genes and transcription profiles for these stages, likely linked to development and/or pathogenesis. Molecular variation within S . haematobium among some geographical locations in Africa revealed unique genomic ‘signatures’ that matched species other than S . haematobium , indicating the occurrence of introgression events. The present reference genome (designated Shae.V3) and the findings from this study solidly underpin future functional genomic and molecular investigations of S . haematobium and accelerate systematic, large-scale population genomics investigations, with a focus on improved and sustained control of urogenital schistosomiasis. 

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5. A revision of the Rhoptrobothriidae (Cestoda: “Tetraphyllidea”)

   https://doi.org/10.11646/zootaxa.4999.3.1  

   JENSEN, KIRSTEN ; PEN, ISABEL A. ; CAIRA, JANINE N. ( July 2021 , Zootaxa)

   The Rhoptrobothriidae are one of the more enigmatic families of cestodes of elasmobranchs. Opinions on the taxonomic status of the family’s three original genera (i.e., Myzophyllobothrium, Rhoptrobothrium, and Myzocephalus) have varied over the 115 years since they were erected. Some authors have considered all three valid, others have considered Rhoptrobothrium to be a synonym of Myzopyllobothrium or a genus inquirendum, yet others have considered Myzocephalus to be a synonym of the phyllobothriid genus Thysanocephalum. All three genera were established for specimens collected from eagle rays off Sri Lanka. The erection of Mixophyllobothrium for two specimens from a cowtail stingray off India three decades ago added additional confusion to the situation, with some authors considering it valid and others a synonym of Myzocephalus. These disagreements stem largely from differences in interpretation of the complex morphology of the scolex of members of these genera. Furthermore, with the exception of Rhoptrobothrium comprising four species, each genus is monotypic. All but Rhoptrobothrium has not been considered in detail for nearly a century, largely because of a lack of available material. The taxonomic status of these genera is assessed here based on light and scanning electron microscopy, and molecular data generated from new material collected from eagle rays off Indonesian and Malaysian Borneo, Japan, Sri Lanka, and Viet Nam. Morphological work indicates that the genera differ largely only in the degree of folding of the four remi that extend from the cephalic peduncle. A molecular phylogeny based on sequence data for the D1–D3 region of the 28S rRNA gene, which include new data for eight specimens of four species, indicates that Myzophyllobothrium, Myzocephalus, and Rhoptrobothrium are not mutually monophyletic. The latter two genera and Mixophyllobothrium are considered synonyms of Myzophyllobothrium and five species are transferred to that genus. Myzophyllobothrium okamuri n. comb. is considered a species inquirendum. Myzophyllobothrium nagasawai n. sp. is described from Aetobatus narutobiei off Japan. Myzophyllobothrium narinari n. comb. is re-described based on newly collected cestodes from the type host and locality (i.e., Aetobatus ocellatus off Sri Lanka). Despite consisting of only a single genus, the family status of the group is retained in recognition of the unusual configuration of the scolex, which bears four biloculate bothridia and four remi extending from the cephalic peduncle. The ordinal placement of the family remains uncertain, but affinities with the Phyllobothriidea, rather than “Tetraphyllidea” are considered. 

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