The Sarcophagidae (Diptera) of the Middle East

A list of 285 species of Sarcophagidaе in the Middle East countries is presented with distributional data, including Bahrain (3 species), Cyprus (46), Egypt (both African and Asian parts) (114), Iran (83), Iraq (17), Israel (113), Jordan (14), Kuwait (3), Lebanon (13), Oman (2), Gaza Strip (5), Palestinian Authority (42), Quatar (1), Saudi Arabia (37), Syria (42), Turkey (both European and Asian parts) (157), United Arab Emirates (14) and Yemen (15). Three new synonyms are established: Blaesoxipha delilah Lehrer, 2006 = Agriella setosa Salem, 1938, syn. n.; Blaesoxipha nahaliana Lehrer, 2008 = Blaesoxipha popovi Rohdendorf, 1937, syn. n.; and Liosarcophaga daccanella Lehrer, 2008 = Liosarcophaga (s. str.) dux (Thomson, 1869), syn. n. Four new combinations for species names are proposed: Liopygia (Engelisca) adhamae (Lehrer & Abou-Ziad, 2008), comb. n.; Liosarcophaga (s. str.) pedestris (Villeneuve, 1910), comb. n.; Liosarcophaga (Pandelleisca) theodori (Lehrer, 1998), comb. n., and Liosarcophaga (Pharaonops) tewfiki (Salem, 1940), comb. n.     

Italian Dermestidae: notes on some species and?an?updated checklist (Coleoptera)

An up-to-date checklist of the Italian Dermestidae is provided. The presence of 95 species in Italy is confirmed, while further 5 species (Dermestes (Dermestes) vorax Motschulsky, 1860, Thorictuspilosus Peyron, 1857, T. wasmanni Reitter, 1895, Attagenus (Attagenus) simonis Reitter, 1881 and Globicornis (G.) breviclavis (Reitter, 1878)) and 1 subspecies (A. (A.) tigrinus pulcher Faldermann, 1835) are excluded from the Italian fauna.Attagenus (Attagenus) calabricus Reitter, 1881 and A. (A.) lobatus Rosenhauer, 1856 are for the first time recorded from Abruzzi and Tuscany respectively; A. (A.) silvaticus Zhantiev, 1976 is recorded for the first time from mainland Italy (Apulia); Anthrenus (Anthrenus) angustefasciatus Ganglbauer, 1904 is new to northern Italy (Friuli-Venezia Giulia), central Italy (Tuscany), Apulia and Basilicata; A. (A.) munroi Hinton, 1943 is new to central Italy (Elba Island); A. (A.) delicatus Kiesenwetter, 1851 is for the first time recorded from Apulia; Globicornis (Globicornis) fasciata (Fairmaire & Brisout de Barneville, 1859) is new to southern Italy (Basilicata); G. (Hadrotoma) sulcata (C.N.F. Brisout de Barneville, 1866) is for the first time recorded from central Italy (Abruzzi), Campania and Sicily, whileTrogoderma inclusum LeConte, 1854 is new to Apulia.Seven species (Dermestes (Dermestes) peruvianus Laporte de Castelnau, 1840, D. (Dermestinus) carnivorus Fabricius, 1775, D. (Dermestinus) hankae Háva, 1999, D. (Dermestinus) intermedius intermedius Kalík, 1951, D. (Dermestinus) szekessyi Kalík, 1950, Anthrenus (Anthrenops) coloratus Reitter, 1881 and Trogodermaangustum (Solier, 1849)) recently recorded from Italy (without further details) are discussed.The lectotype and a paralectotype are designated forAttagenus (A.) calabricus Reitter, 1881 from Calabria.Attagenus pellio (Linnaeus, 1758) var. pilosissimus Roubal, 1932 is removed from synonymy with A. (A.) pellio and recognized as a valid species (stat. prom.); it is known from Lombardy, Apulia and Calabria.     

Monogènes Dactylogyridae parasites de Cyprinidae du genreBarbus d'Afrique du Nord

Resumé Quinze nouvelles espèces de Monogènes Dactylogyridae sont décrites chez quinze espèces deBarbus (Teleostei, Cyprinidae) appartenant aux sous-genresB. (Barbus) etB. (Labeobarbus) en Afrique du Nord. Les barbeaux examinés proviennent des différents bassins hydrographiques du Maroc et d'une localité nommée Hamman Bourgiba en Tunisie. Dans cette dernière région, le genreBarbus n'est représenté que par une seule espèce:Barbus (B.) callensis. Au Maroc, on en dénombre actuellement quatorze dont quatre appartiennent au sous-genreLabeobarbus: il s'agit deBarbus (L.) fritschii; B. (L.) harteti; B. (L.) paytonii etB. (L.) reinii. Les dix espèces appartenant au sous-genreBarbus sont:Barbus (B.) figuiensis; B. (B.) ksibi; B. (B.) lepineyi; B. (B.) magniatlantis; B. (B.) massaensis; B. (B.) moulouyensis; B. (B.) nasus; B. (B.) pallaryi; B. (B.) setivemensis etB. (B.) issenensis.Chaque sous-genre possède son propre pool parasitaire, à l'exception deDactylogyrus marocanus n. sp., recontré sur des espèces appartenant aux deux sous-genres (B. (L.) fritschii, B. (L.) paytonii, B. (L.) harteti, B. (L.) reinii, B. (L.) nasus, B. (B.) setivimensis, B. (B.) ksibi). Sur les cinqDactylogyrus parasitant lesLabeobarbus, trois présentent une spécificité stricte vis à vis de leur hôte. Il s'agit deDactylogyrus reinii n. sp. surB. (L.) reinii; D. volutus n. sp. etD. zatensis n. sp. surB. (L.) fritschii. Les espècesD. oumiensis n. sp. etD. kulindrii n. sp. présentent une spécifité stenoxène et parasitent respectivementB. (L.) harteti, B. (L.) paytonii, B. (L.) reinii etB. (L.) fritschii, B. (L.) reinii.Nous avons recontré neufDactylogyrus chez les poisson-hôtes appartenent au sous-genreBarbus. Six d'entre eux ont une spécificité oïoxène; ce sont:D. guirensis n. sp.,D. atlasensis n. sp. etD. draaensis n. sp. surB. (B.) pallaryi; D. borjensis n. sp. surB. (B.) nasus etD. heteromorphus n. sp. etD. tunisiensis n. sp. surB. (B.) callensis. Les trois autres parasites ont un spectre d'hôtes plus large. Il s'agit deD. ksibii n. sp. recontré chezB. (B.) ksibi, B. (B.) setivimensis etB. (B.) magniatlantis; D. ksibioïdes n. sp. recontré chezB. (B.) setivimensis etB. (B.) moulouyensis. L'espèceD. fimbriphallus n. sp. stenoxène, se recontre chez les poisson-hôtes du versant Sud de l'Atlas et de la façade méditerranéenne à savoir:B. (B.) figuiensis, B. (B.) lepineyi, B. (B.) massaensis, B. (B.) moulouyensis, B. (B.) pallaryi etB. (B.) issenensis.Le rôle des Dactylogyridae en tant que marqueurs biogéographiques, phylogénétiques et taxonomiques est discuté à partir de la composition spécifique des communautés de Monogènes rencontrés et de leurs différents types morphologiques.

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Fifteen new species of the Dactylogyridae (Monogenea) parasitic on fifteen species of barbels (Barbus) from North Africa (Teleostei, Cyprinidae) are described. The fishes studied belong to two subgenera,B. (Labeobarbus) andB. (Barbus), collected from various hydrographical basins of Morocco and from the Hamman Bourgiba locality in Tunisia. In the latter area, the genusBarbus is represented by onlyBarbus (Barbus) callensis. In Morocco, fourteen species are listed, four of which belong to the subgenusLabeobarbus; these areBarbus (L.) fritschii; B. (L.) harteti; B. (L.) paytonii andB. (L.) reinii. The other ten species belong to the subgenusBarbus: these areBarbus (B.) figuiensis; B. (B.) ksibi; B. (B.) lepineyi; B. (B.) magniatlantis; B. (B.) massaensis; B. (B.) moulouyensis; B. (B.) nasus; B. (B.) pallaryi; B. (B.) setivimensis andB. (B.) issenensis. Each of the two subgenera has its unique parasitic fauna, except forDactylogyrus marocanus n. sp. collected on species belonging to both subgenera (B. (L.) fritschii, B. (L.) paytonii, B. (L.) harteti, B. (L.) reinii, B. (B.) nasus, B. (B.) setivimensis andB. (B.) ksibi). Of the five monogeneans found onLabeobarbus, three appear to be specific to one host: they areDactylogyrus reinii n. sp. onB. (L.) reinii, andD. volutus n. sp. andD. zatensis n. sp. onB. (L.) fritschii. D. kulindrii n. sp. parasitisedB. (L.) reinii andB. (L.) fritschii; andD. oumiensis n. sp. occurred onB. (L.) reinii, B. (L.) paytonii andB. (L.) harteti. NineDactylogyrus species were found in fishes belonging to the subgenusBarbus. Six of them have an oïoxenous specificity: these areD. guirensis n. sp.,D. atlasensis n. sp. andD. draaensis n. sp. onB. (B.) pallaryi; D. borjensis n. sp. onB. (B.) nasus andD. heteromorphus n. sp. andD. tunisiensis n. sp. on(B.) callensis. These other three have a wider range of hosts: they areD. ksibii n. sp. collected fromB. (B.) ksibi, B. (B.) setivimensis andB. (B.) magniatlantis, andD. ksibioïdes n. sp. found onB. (B.) setivimensis andB. (B.) moulouyensis. D. fimbriphallus n. sp. is a characteristic parasite of fishes from the southern side of the Atlas mountains and the Mediterranean coast (B. (B.) figuiensis, B. (B.) lepineyi, B. (B.) massaensis, B. (B.) moulouyensis, B. (B.) pallaryi andB. (B.) issenensis).The role of dactylogyrids as biogeographical phylogenetic and taxonomic indicators is discussed in relation to the specific structure of the monogenean communities and the different morphological types found.

     

Evaluation of species composition and seasonal dynamics of mosquito larvae in the Košice Basin during 2010 and 2011

In six sites in the Ko?ice Basin we collected 17,520 larvae of 15 mosquito species during the seasons (April–August) of 2010 and 2011. They were: Aedes vexans (Meigen, 1830), Ae. cinereus (Meigen, 1818) [or Ae. rossicus (Dolbeskin, Gorickaja & Mitrofanova, 1930], Ochlerotatus geniculatus (Olivier, 1791), Oc. refiki (Medschid, 1928), Oc. rusticus (Rossi, 1790), Oc. sticticus (Meigen, 1838), Oc. punctor (Kirby, 1837), Oc. cataphylla (Dyar, 1916), Oc. cantans (Meigen, 1818)[or Oc. annulipes (Meigen, 1830)], Oc. communis (De Geer, 1776), Oc. flavescens (Müller, 1764), Oc. leucomelas (Meigen, 1804), Culiseta annulata (Schrank, 1776), Culex pipiens (L., 1758) [or Cx. torrentium (Martini, 1925)] and Anopheles maculipennis s.l. The objective of the present research was to identify the mosquito larvae species diversity and compare their distribution and density in urban and suburban localities of the monitored territory.     

The coordination chemistry of N-(2-aminophenyl)- and N-(3-aminophenyl)quinoline-2′-carboxamide; two potentially tridentate ligands containing secondary amide and N-donor groups

New complexes of the general formulae Co(o-LH)₂X₂ (XCl, NCS), Co(o-LH)₂Br₂·EtOH (EtOHethanol), M(o-LH)(NO₃)₂ (MCo, Ni), Ni(o-LH)₂X₂ (XCl, Br, NCS), Cu(o-L)X (XCl, Br), Zn(o-LH)X₂ (XCl, Br), Pd(o-L)Cl, Pt(o-LH)₂Cl₂·H₂O, M(m-LH)Cl₂·nH₂O (MCo, Ni, Pd; n=0, 0.5, 1), Cu(m-LH)Cl₂·EtOH, M(m-LH)₂Cl₂·nH₂O (MCo, Zn, Pt; n=0, 1), M(m-LH)Br₂ (MCu, Zn), M(m-LH)₂Br₂ (MCo, Ni), Co(m-LH)(NCS)₂ and Co(m-LH)₂(NCS)₂, where o-LH=N-(2-aminophenyl)quinoline-2′-carboxamide and m-LH=N-(3-aminophenyl)quinoline-2′-carboxamide, have been prepared. The complexes were characterised by elemental analyses, conductivity measurements, X-ray powder patterns, thermogravimetric analyses, magnetic moments and spectral (¹H NMR, IR, and electronic) studies. Copper(II) and palladium(II) promote amide deprotonation at nearly acidic pH on coordination with o-LH. A variety of stereochemistries is assigned for the complexes prepared. The deprotonated copper(II) and the nickel(II) and palladium(II) complexes of m-LH appear to be polymeric. The neutral amide group of the ligands is coordinated to the metal ions through oxygen, while N(amide)-coordination is observed for the deprotonated complexes. Coordination of the secondary amide group is not observed for Zn(m-LH)₂Cl₂, Pd(m-LH)Cl₂·0.5H₂O and platinum(II) complexes. The neutral ligand o-LH shows bidentate N(ring), O-behaviour, while the anion o-L⁻ exhibits tridentate N,N,N-coordination. m-LH acts as a monodentate, bidentate and tridentate ligand depending on the metal ion, the anion and the preparative conditions.     

Aerobiology of Vigo, North-Western Spain: atmospheric pollen spectrum and annual dynamics of the most important taxa, and their clinical importance for allergy

Vigo is a city located in the northwest of the Iberian Peninsula. Influenced by the Atlantic climate, it is surrounded by a Eurosiberian-type vegetation, modified by the introduction of forestry and ornamental species. Different ruderal vegetation types, resulting from human influence, grow in the area. The study of the pollen content of the air of Vigo started in 1989, with a Cour trap. Average results for the period 1989–1995 are presented in this paper, together with the lowest and highest values found. The representativeness of the mean values is analysed by calculating the coefficient of variation of the data series. Most pollen types in the atmosphere of Vigo are from tree species (54.2%); an important proportion comes from herb species (43.9%) and very few (1.8%) correspond to shrub species. A total of 73 different pollen types have been identified. The most abundant, listed in decreasing order of mean annual values for the period, are:Pinus (25.1%), Poaceae (21.1%), Urticaceae (14.6%),Quercus (8.5%),Castanea (3.7%),Betula (3.6%),Eucalyptus (3.4%),Plantago (3.2%),Alnus (2.1%), Cupressaceae (2.1%), Oleaceae (1.6%;Olea 1.3%),Platanus (1.3%),Rumex (1.3%), Chenopodiaceae/Amaranthaceae (1.0%), Ericaceae (0.8%), Asteraceae (0.6%;Artemisia 0.1% andTaraxacum type 0.2%) andMercurialis (0.5%). A pollen calendar showing the annual dynamics of all these pollen types is presented in this paper. A parallel study of the clinical importance of respiratory allergies in Vigo was also conducted. From a sample of 2750 patients, 87.2% suffered from rhinoconjunctivitis, 26.0% of these due to pollen, and 78.3% from asthma, 17.2% due to pollen. The pollen types responsible for these allergies, listed in decreasing order, are: Poaceae (78%),Parietaria (12%),Chenopodium (11%),Plantago (9%), Oak (4%),Artemisia (3%),Pinus (3%),Eucalyptus (3%),Olea (2%),Platanus (2%),Castanea (2%),Taraxacum (2%),Rumex (2%),Betula (1%),Cupressus (1%) andMercurialis (1%).     

白毫早茶园3种害虫与其捕食性天敌的数量、时间和空间关系

为了合理利用和保护天敌进行卵形短须螨、双斑长跗萤叶甲和假眼小绿叶蝉的综合防治,用灰色系统分析方法和生态位分析法对合肥地区白毫早茶园3种主要害虫与其捕食性天敌在数量、时间、空间等方面关系进行分析,利用害虫与天敌关系密切指数之和综合评判9种天敌与3种害虫关系密切的前四位天敌。2015年卵形短须螨的前四位天敌是鳞纹肖蛸(5.3079)、三突花蟹蛛(5.1716)、锥腹肖蛸(4.8367)和草间小黑蛛(4.7869);2016年前四位天敌依次是三突花蟹蛛(5.3975)、鳞纹肖蛸(4.9414)、茶色新圆蛛(4.8757)、锥腹肖蛸(4.6815)。对两年结果综合分析,卵形短须螨的前四位天敌依次是三突花蟹蛛(10.5691)、鳞纹肖蛸(10.2493)、茶色新圆蛛(9.6353)和锥腹肖蛸(9.5182)。2015年双斑长跗萤叶甲的前四位天敌依次是锥腹肖蛸(5.6926)、异色瓢虫(5.6976)、八斑球腹蛛(5.5101)和斜纹猫蛛(5.4552);2016年依次是茶色新圆蛛(5.2909)、锥腹肖蛸(5.2710)、鳞纹肖蛸(5.1063)和斜纹猫蛛(5.0703)。对两年结果综合评判,双斑长跗萤叶甲的前四位天敌是锥腹肖蛸(10.9636)、茶色新圆蛛(10.6578)、异色瓢虫(10.7580)和鳞纹肖蛸(10.5437)。2015年假眼小绿叶蝉的前四位天敌依次是锥腹肖蛸(5.3614)、粽管巢蛛(5.2259)、斜纹猫蛛(5.1300)和茶色新圆蛛(4.7472);2016年是锥腹肖蛸(5.2666)、粽管巢蛛(5.2561)、草间小黑蛛(4.9376)和斜纹猫蛛(4.8335)。对两年结果综合评判,假眼小绿叶蝉的前四位天敌依次是锥腹肖蛸(10.6280)、粽管巢蛛(10.4820)、斜纹猫蛛(9.9635)和茶色新圆蛛(8.6137)。该研究结果为白毫早茶园3种害虫防治时合理保护和利用自然界的天敌的种类提供了科学依据。     

Antimicrobial Resistance, Virulence Genes, and Genetic Lineages of Staphylococcus pseudintermedius in Healthy Dogs in Tunisia

Nasal swabs of 100 healthy dogs were obtained in 2011 in Tunisia and tested for Staphylococcus pseudintermedius recovery. Antimicrobial resistance profile and virulence gene content were determined. Multilocus-sequence-typing (MLST) and SmaI-pulsed-field gel electrophoresis (PFGE) were investigated. S. pseudintermedius was recovered in 55 of the 100 tested samples (55 %), and one isolate per sample was further studied. All 55 S. pseudintermedius isolates were susceptible to methicillin (MSSP) but showed resistance to the following antimicrobials (% resistant isolates/resistance gene): penicillin (56.4/blaZ), tetracycline (40/tetM), trimethoprim-sulfamethoxazole (23.7), fusidic acid (9), kanamycin (3.7/aph(3´)-Ia), erythromycin-clindamycin (1.8/erm(B)), streptomycin (1.8/ant(6)-Ia), chloramphenicol (1.8) and ciprofloxacin (1.8). The following toxin genes were identified (% of isolates): lukS/F-I (98.2), expA (5.5), se-int (98.2), sec _canine (1.8), siet (100), sea (5.5), seb (3.6), sec (10.9), sed (54.5), sei (5.5), sej (29.1), sek (3.6), ser (9.1), and hlg _v (38.2). Ten different sequence-types were detected among 11 representative MSSP isolates: ST20, ST44, ST69, ST70, ST78, ST100, ST108, ST160, ST161, and ST162, the last three ones revealing novel alleles or allele combinations. Eleven different PFGE-patterns were identified in these isolates. The nares of healthy dogs could be a reservoir of antimicrobial resistant and virulent MSSP, highlighting the presence of the recently described exfoliating gene expA and several enterotoxin genes.     

Immunohistological investigations of PAS-negative globular intracisternal hyalin in human liver biopsy specimens

Eight liver biopsy specimens from five patients with PAS-negative intracisternal hyalin were investigated by immunofluorescence for: (1) immunoglobulins (Ig) G, A, M, D, E; (2) light chains (kappa and lambda); (3) complement components C1q, C4, C3c, C5, C9; (4) C1-inactivator; (5) C3-activator; (6) alpha 1-antitrypsin; (7) alpha 1-antichymotrypsin; (8) plasminogen; (9) fibrinogen; (10) fibrinogen breakdown products D and E; (11) fibronectin; (12) prealbumin; (13) albumin; (14) betalipoprotein; (15) apolipoprotein; (16) alpha 1- and alpha 2-glycoprotein; (17) cholinesterase; (18) ceruloplasmin; (19) haemopexin; (20) myoglobin; (21) placenta lactogen; (22) transferrin; (23) actin; (24) myosin; (25) cathepsin D; and (26) hepatitis B surface and core antigens (HBsAg and HBcAg). The globules reacted significantly with antisera against C3c (three patients), C4 (three patients), C3-activator (one patient) and fibrinogen (two patients). The cause of the protein accumulation is not clear. Serial studies indicate the possibility of a disturbance of protein secretion and an as yet unidentified immune complex disorder.     

Systematics of Old World Odontacolus Kieffer s.l. (Hymenoptera,Platygastridae s.l.): parasitoids?of?spider?eggs

The genera Odontacolus Kieffer and Cyphacolus Priesner are among the most distinctive platygastroid wasps because of their laterally compressed metasomal horn; however, their generic status has remained unclear. We present a morphological phylogenetic analysis comprising all 38 Old World and four Neotropical Odontacolus species and 13 Cyphacolus species, which demonstrates that the latter is monophyletic but nested within a somewhat poorly resolved Odontacolus. Based on these results Cyphacolus syn. n. is placed as a junior synonym of Odontacolus which is here redefined. The taxonomy of Old World Odontacolus s.str. is revised; the previously known species Odontacolus longiceps Kieffer (Seychelles), Odontacolus markadicus Veenakumari (India), Odontacolus spinosus (Dodd) (Australia) and Odontacolus hackeri (Dodd) (Australia) are re-described, and 32 new species are described: Odontacolus africanus Valerio & Austin sp. n. (Congo, Guinea, Kenya, Madagascar, Mozambique, South Africa, Uganda, Zimbabwe), Odontacolus aldrovandii Valerio & Austin sp. n. (Nepal), Odontacolus anningae Valerio & Austin sp. n. (Cameroon), Odontacolus australiensis Valerio & Austin sp. n. (Australia), Odontacolus baeri Valerio & Austin sp. n. (Australia), Odontacolus berryae Valerio & Austin sp. n. (Australia, New Zealand, Norfolk Island), Odontacolus bosei Valerio & Austin sp. n. (India, Malaysia, Sri Lanka), Odontacolus cardaleae Valerio & Austin sp. n. (Australia), Odontacolus darwini Valerio & Austin sp. n. (Thailand), Odontacolus dayi Valerio & Austin sp. n. (Indonesia), Odontacolus gallowayi Valerio & Austin sp. n. (Australia), Odontacolus gentingensis Valerio & Austin sp. n. (Malaysia), Odontacolus guineensis Valerio & Austin sp. n. (Guinea), Odontacolus harveyi Valerio & Austin sp. n. (Australia), Odontacolus heratyi Valerio & Austin sp. n. (Fiji), Odontacolus heydoni Valerio & Austin sp. n. (Malaysia, Thailand), Odontacolus irwini Valerio & Austin sp. n. (Fiji), Odontacolus jacksonae Valerio & Austin sp. n. (Cameroon, Guinea, Madagascar), Odontacolus kiau Valerio & Austin sp. n. (Papua New Guinea), Odontacolus lamarcki Valerio & Austin sp. n. (Thailand), Odontacolus madagascarensis Valerio & Austin sp. n. (Madagascar), Odontacolus mayri Valerio & Austin sp. n. (Indonesia, Thailand), Odontacolus mot Valerio & Austin sp. n. (India), Odontacolus noyesi Valerio & Austin sp. n. (India, Indonesia), Odontacolus pintoi Valerio & Austin sp. n. (Australia, New Zealand, Norfolk Island), Odontacolus schlingeri Valerio & Austin sp. n. (Fiji), Odontacolus sharkeyi Valerio & Austin sp. n. (Thailand), Odontacolus veroae Valerio & Austin sp. n. (Fiji), Odontacolus wallacei Valerio & Austin sp. n. (Australia, Indonesia, Malawi, Papua New Guinea), Odontacolus whitfieldi Valerio & Austin sp. n. (China, India, Indonesia, Sulawesi, Malaysia, Thailand, Vietnam), Odontacolus zborowskii Valerio & Austin sp. n. (Australia), and Odontacolus zimi Valerio & Austin sp. n. (Madagascar). In addition, all species of Cyphacolus are here transferred to Odontacolus: Odontacolus asheri (Valerio, Masner & Austin) comb. n. (Sri Lanka), Odontacolus axfordi (Valerio, Masner & Austin) comb. n. (Australia), Odontacolus bhowaliensis (Mani & Mukerjee) comb. n. (India), Odontacolus bouceki (Austin & Iqbal) comb. n. (Australia), Odontacolus copelandi (Valerio, Masner & Austin) comb. n. (Kenya, Nigeria, Zimbabwe, Thailand), Odontacolus diazae (Valerio, Masner & Austin) comb. n. (Kenya), Odontacolus harteni (Valerio, Masner & Austin) comb. n. (Yemen, Ivory Coast, Paskistan), Odontacolus jenningsi (Valerio, Masner & Austin) comb. n. (Australia), Odontacolus leblanci (Valerio, Masner & Austin) comb. n. (Guinea), Odontacolus lucianae (Valerio, Masner & Austin) comb. n. (Ivory Coast, Madagascar, South Africa, Swaziland, Zimbabwe), Odontacolus normani (Valerio, Masner & Austin) comb. n. (India, United Arab Emirates), Odontacolus sallyae (Valerio, Masner & Austin) comb. n. (Australia), Odontacolus tessae (Valerio, Masner & Austin) comb. n. (Australia), Odontacolus tullyae (Valerio, Masner & Austin) comb. n. (Australia), Odontacolus veniprivus (Priesner) comb. n. (Egypt), and Odontacolus watshami (Valerio, Masner & Austin) comb. n. (Africa, Madagascar). Two species of Odontacolus are transferred to the genus Idris Förster: Idris longispinosus (Girault) comb. n. and Idris amoenus (Kononova) comb. n., and Odontacolus doddi Austin syn. n. is placed as a junior synonym of Odontacolus spinosus (Dodd). Odontacolus markadicus, previously only known from India, is here recorded from Brunei, Malaysia, Sri Lanka, Thailand and Vietnam. The relationships, distribution and biology of Odontacolus are discussed, and a key is provided to identify all species.     

On the composition of talassobathyal ichthyofauna and commercial productivity of Mozambique Seamount (the Indian Ocean)

Ichthyofauna of the Mozambique Seamount of the Indian Ocean, judging from the results of YugNIRO from the 1970s to the 1980s numbers about 130 species of bathyal and bathyal-pelagic fish that belong to 44 families. Most species belong to the families Macrouridae (16), Alepocephalidae (14), Ophidiidae (13), Squalidae (8), and Gempylidae (6). Among them, the greatest numbers and prospects of commercial importance, as over other seamounts, have about ten species: Centroscymnus coelolepis (Somniosidae), Etmopterus granulosus (Etmopteridae), Diastobranchus capensis and Synaphobranchus oregoni (Synaphobranchuidae), Alepocephalus australis, A. productus, and Rouleina attrita (Alepocephalidae), Cetonurus globiceps (Macrouridae), and Allocyttus verrucosus (Oreosomatidae); to the number of potential items of fishery one can also assign Hydrolagus africanus (Chimaeridae), Chlamydoselachus anguinus (Chlamydoselachidae), Apristurus indicus (Scyliorhinidae), Halosaurospis microchir (Halosauridae), Bathytyphlops marionae (Ipnopidae), Coelorhinchus acanthiger, and Coryphaenoides striatura (Macrouridae), Antimora rostrata (Moridae), Lamprogrammus niger and Selachophidium guentheri (Ophidiidae), and Holostethus atlanticus (Trachichthyidae). Pelagic deep-water fish (Gonostomatidae, Sternoptychidae, Myctophidae, etc.) apparently do not form aggregations having a commercial importance.     

Some Species of <Emphasis Type="Italic">Centrorhynchus</Emphasis> Lühe, 1911 (Acanthocephala: Centrorhynchidae) from the Collection of the Natural History Museum,London

Seven species of Centrorhynchus Lühe, 1911 are present in the Parasitic Worms Collection of The Natural History Museum, London: C. aluconis (Müller, 1780) Lühe, 1911 from Strix aluco Linnaeus in Great Britain; C. buteonis (Schrank, 1788) Kostylev, 1914 from Accipiter virgatus (Temminck) (new host record) in Sri Lanka (new geographical record); C. clitorideus (Meyer, 1931) Golvan, 1956 from Athene brama (Temminck) (new host record) in India; C. crotophagicola Schmidt & Neiland, 1966 (encysted juveniles in the stomach wall) from Anolis lineatopus Grey (new host record) and A. sagrei Duméril & Bibron (new host record) from Jamaica (new geographical record); C. falconis (Johnston & Best, 1943) Golvan, 1956 from Spilornis cheela (Latham) in Sri Lanka (new geographical record); C. globocaudatus (Zeder, 1800) Lühe, 1911 from Falco ardosiaceus Vieillot (new host record) in West Africa; and C. milvus Ward, 1956 from Milvus migrans (Boddaert) in India. The species are described and figured on the basis of this material.     

Description of new species of the genus Ctenochira Förster, 1855 (hymenoptera,ichneumonidae: Tryphoninae) from the Eurasian Subarctic subzone and Siberia,with remarks on the Ichneumonid fauna of the Chukchi Peninsula

13 new species of Ctenochira (Hymenoptera, Ichneumonidae, Tryphoninae) from the Eurasian Subarctic subzone and Siberia are described: C. albosignata sp. n., C. anabar sp. n., C. epipleuralis sp. n., C. gracilicornis sp. n., C. hyperborea sp. n., C. kerzhneri sp. n., C. laticauda sp. n., C. minuta sp. n., C. nigronitens sp. n., C. pallistigma sp. n., C. tixi sp. n., C. trochanterata sp. n., and C. uzon sp. n. A key to the Subarctic and northern Siberian species is given. Quantitative occurrence of different ichneumonid subfamilies in the Subarctic subzone is considered based on analysis of 827 specimens of ichneumonids collected in yellow plates in the Chukchi Autonomous Area in July 2012. Idiobiont (polyphagous) subfamilies (36.5%): Cryptinae, 294 spms. (35.5%); Pimplinae, 8 (1%). Koinobiont parasitoids, 10 subfamilies (63.5%): parasitoids of Symphyta, 313 spms. (37.9%): Tryphoninae, 225 (27.2%); Adelognathinae, 14 (1.7%); Ctenopelmatinae, 59 (7.2%); Campopleginae (Olesicampe; Lathrostizus), 15 (1.8%); parasitoids of Diptera, 169 spms. (20.5%): Diplazontinae, 8 (1%); Orthocentrinae s. l., 161 (19.5%); parasitoids of Lepidoptera, 29 spms. (3.5%): Campopleginae (part), 18 (2.2%) (Campoletis; Hyposoter; Tranosema; Diadegma; etc.); Ichneumoninae, 2 (0.2%); Banchinae, 3 (0.4%) (Glypta; Lissonota); Metopiinae, 6 (0.7%) (Exochus); parasitoids of Coleoptera (0.3%): Tersilochinae, 3 spms. (Barycnemis); hyperparasitoids (1.3%): Mesochorinae, 11 spms.     

25‐Hydroxyvitamin D Concentration Correlates With Insulin‐Sensitivity and BMI in Obesity

The prevalence of hypovitaminosis D is high among obese subjects. Further, low 25‐hydroxyvitamin D (25(OH)D) concentration has been postulated to be a risk factor for type 2 diabetes, although its relation with insulin‐sensitivity is not well investigated. Thus, we aimed to investigate the relationship between 25(OH)D concentration and insulin‐sensitivity, using the glucose clamp technique. In total, 39 subjects with no known history of diabetes mellitus were recruited. The association of 25(OH)D concentration with insulin‐sensitivity was evaluated by hyperinsulinemic euglycemic clamp. Subjects with low 25(OH)D (<50 nmol/l) had higher BMI (P = 0.048), parathyroid hormone (PTH) (P = 0.040), total cholesterol (P = 0.012), low‐density lipoprotein (LDL) cholesterol (P = 0.044), triglycerides (P = 0.048), and lower insulin‐sensitivity as evaluated by clamp study (P = 0.047). There was significant correlation between 25(OH)D and BMI (r = ?0.58; P = 0.01), PTH (r = ?0.44; P < 0.01), insulin‐sensitivity (r = 0.43; P < 0.01), total (r = ?0.34; P = 0.030) and LDL (r = ?0.40; P = 0.023) (but not high‐density lipoprotein (HDL)) cholesterol, and triglycerides (r = 0.45; P = 0.01). Multivariate analysis using 25(OH)D concentration, BMI, insulin‐sensitivity, HDL cholesterol, LDL cholesterol, total cholesterol, and triglycerides, as the cofactors was performed. BMI was found to be the most powerful predictor of 25(OH)D concentration (r = ?0.52; P < 0.01), whereas insulin‐sensitivity was not significant. Our study suggested that there is no cause–effect relationship between vitamin D and insulin‐sensitivity. In obesity, both low 25(OH)D concentration and insulin‐resistance appear to be dependent on the increased body size.     

A taxonomic revision of Labiostrongylus (Labiostrongylus) (Yorke & Maplestone, 1926) and Labiostrongylus (Labiomultiplex) n. subg. (Nematoda: Cloacinidae) from macropodid and potoroid marsupials

The morphological characters used to differentiate species in the genus Labiostrongylus Yorke & Maplestone, 1926, parasitic in macropodid and potoroid marsupials, are discussed. The genus is divided into three subgenera Labiostrongylus (Labiostrongylus), L. (Labiomultiplex) n. subg. and L. (Labiosimplex) n. subg. on the basis of the presence or absence of interlabia and the morphology of the oesophagus. A key to the subgenera is given and a detailed revision of two of the subgenera is presented. Keys to each of the subgenera are given, the species discussed being: L. (L.) labiostrongylus) (type-species) (syn. L. (L.) insularis, L. (L.) grandis, L. (L.) macropodis sp. inq. and L. (L.) nabarlekensis n. sp., in the subgenus Labiostrongylus, and L. (Lm.) eugenii, L. (Lm.) novaeguineae, L. (Lm.) onychogale, L. (Lm.) uncinatus, L. (Lm.) billardierii n. sp., L. (Lm.) constrictis n. sp., L. (Lm.) kimberleyensis n. sp., L. (Lm.) thylogale n. sp., and L. (Lm.) potoroi, n. sp., in the subgenus Labiomultiplex.     

Further study on the phylogeny,taxonomy and distribution of the genus Veturius Kaup in Central and South America (Coleoptera: Passalidae)

This study provides data on the phylogeny, taxonomy and distribution of 14 known and five new species of the Neotropical genus Veturius Kaup (Proculini), belonging to various subgenera and species groups: V. (Veturius) latissimus n. sp. (Colombia, Central Andes) and V. (V.) calimanus n. sp. (Pacific slope of the Occidental Cordillera) are separated from V. (V.) caquetaensis Boucher, 1988, which seems restricted to the Amazonian slope of the Oriental Cordillera (Caquetá, Putumayo); V. (V.) sinuatomarginatus Luederwaldt, 1941 (Costa Rica), n. syn. of V. sinuatocollis Kuwert, 1890; V. sinuatocollis aculeatus Luederwaldt, 1941 (syntype from Costa Rica); V. (V.) aspina Kuwert, 1898 (located in Occidente of Ecuador, Guayaquil); V. (V.) yahua Boucher, 2006 (located in Occidente of Ecuador, Pichincha and SW Colombia, Nariño); V. (V.) guntheri Kuwert, 1898 (located in Peru, SE Puno and Colombia, W Putumayo); V. (V.) cephalotes (Le Peletier & Serville, 1825) (citation from Guyana); V. (V.) sinuatus (Eschscholtz, 1829) (previous synonymy); V. (V.) libericornis Kuwert, 1891 (located in Peru, Cuzco); V. (V.) lepidus Fonseca, 1999 (revision; located in Colombia, Amazonas, Putumayo and Peru, Loreto); V. (V.) transversus (Dalman, 1817) [syntype; previous synonymy of V. trituberculatus (Eschscholtz, 1829) with V. assimilis (Weber, 1801) and located in Brazil, Mato Grosso]; V. (V.) sinuosus (Drapiez, 1820) (corrected reference for Colombia); V. (Publius) crassus (Smith, 1852) (new syntype); V. (P.) danieli Boucher, 2006 (holotype deposit); V. (P.) vazdemelloi Boucher, n. sp. (Andes of Ecuador, Azuay); V. (Ouayana) unicornis Gravely, 1918 (located in Colombia, E Vaupés); V. (O.) costaianus Boucher, n. sp. (Venezuela, Amazonas, NW Pacaraima Massif); Ticoisthmus Boucher, n. subg., for the species group of V. (O.) laevior (Kaup, 1868), of southern Central America; and V. (T.) brachypterus Boucher, n. sp. (Costa Rica, Sierra Talamanca). Ticoisthmus is considered the sister group of Ouayana. It belongs to the Meso-American low mountain dispersion pattern and demonstrates, especially in the genus Veturius, but also more generally in the Neotropical passalids, the hot-spot characteristics, with diversity and endemism, of the narrow land between the Depression of Nicaragua and the Isthmus of Panama.     

New Isopropyl Chromone and Flavanone Glucoside Compounds from the Leaves of Syzygium cerasiforme (Blume) Merr. & L.M.Perry and Their Inhibition of Nitric Oxide Production

A new isopropyl chromone ( 1 ) and a new flavanone glucoside ( 2 ) together with eleven known compounds ( 3–13 ) were isolated from the leaves of Syzygium cerasiforme (Blume) Merr. & L.M.Perry. Their structures were elucidated as 5,7-dihydroxy-2-isopropyl-6,8-dimethyl-4H-chromen-4-one ( 1 ), 5,7-dihydroxyflavanone 7-O-β-D-(6′′-O-galloylglucopyranoside) ( 2 ), strobopinin ( 3 ), demethoxymatteucinol ( 4 ), pinocembrin-7-O-β-D-glucopyranoside ( 5 ), (2S)-hydroxynaringenin-7-O-β-D-glucopyranoside ( 6 ), afzelin ( 7 ), quercetin ( 8 ), kaplanin ( 9 ), endoperoxide G3 ( 10 ), grasshopper ( 11 ), vomifoliol ( 12 ), litseagermacrane ( 13 ) by the analysis of HR-ESI-MS, NMR, and CD spectral data. Compounds 1 , 2 , 5 , 6 and 10 inhibited NO production on LPS-activated RAW264.7 cells with IC₅₀ values of 12.28±1.15, 8.52±1.62, 7.68±0.87, 9.67±0.57, and 6.69±0.34 μM, respectively, while the IC₅₀ values of the other compounds ranging from 33.38±0.78 to 86.51±2.98 μM, compared to that of the positive control, N^G-monomethyl-L-arginine acetate (L-NMMA) with an IC₅₀ value of 32.50±1.00 μM.     

New Triterpenic Glucoside from Beesia calthaefolia  (Maxim.) Ulbr. Native to China

Five compounds (1-5) were isolated from the rhizome of Beesia calthaefolia (Maxim.) Ulbr. Based on chemical and spectral evidence, their structures were determined as beesic acid (9-phenyl-2E, 4E, 6E, 8E-nontetraenoic acid, 1), vanillic acid (2), oleanolic acid-3-O-α-L-arabinopyranosyl-28-O-α-L -rhamnopyranosyl-(1→4)-β-D-glucopyranosyl-(1→6)-β-D-glucopyranosyl ester (3), hederasaponin B (oleanolicacid-3-O-α-L-rhamnopyranosyl-(1→2)-α-L-arabinopyranosyl-28-O-α-L-rhamnopyranosyl-(1→4)-β-D-glucopyranosyl-(1→6)-β-D-glucopyranosyl ester, 4) and beesioside Q (oleanolic acid-3-O-β-D -glucopyranosyl-(1→3)-α-L-rhamnopyranosyl-(1→2)-α-L-arabinopyranosyl-28-O-α-L-rhamnopyranosyl-(1→4)-β-D-glucopyranosyl-(1→6)-β-D-glucopyranosyl ester, 5), respectively. Compound 1 was isolated from natural sources for the first time and compound 5 was a new compound.     

Synthesis and biological properties of 12-fluoroprostacyclins

The synthesis of the sodium salts of enantiomerically pure 12-fluoroPGI₂ (9), (±)-12-fluoroPGI₂ (9), (±)-15-epi-12-fluoroPGI₂ (10), (±)-12-fluoro-13,14-dihydroPGI₂ (11), (±)-12-fluoro-4(E)-isoPGI₂ (12), and (±)-5,6-dihydro-12-fluoroPGI₂ (13) is detailed starting from the corresponding derivatives of 12-fluoroPGF_2α methyl ester. Prostacyclins 9, (±)-9, (±)-10, (±)-11, (±)-12, and (±)-13 have been evaluated for their ability to inhibit human platelet aggregation and their effect on smooth muscle (isolated cat coronary artery).     

Enantioselective Uptake and Degradation of the Chiral Herbicide Dichlorprop [(RS)-2-(2,4-Dichlorophenoxy)propanoic acid] by Sphingomonas herbicidovorans MH

Sphingomonas herbicidovorans MH was able to completely degrade both enantiomers of the chiral herbicide dichlorprop [(RS)-2-(2,4-dichlorophenoxy)propanoic acid], with preferential degradation of the (S) enantiomer over the (R) enantiomer. These results are in agreement with the recently reported enantioselective degradation of mecoprop [(RS)-2-(4-chloro-2-methylphenoxy)propanoic acid] by this bacterium (C. Zipper, K. Nickel, W. Angst, and H.-P. E. Kohler, Appl. Environ. Microbiol. 62:4318–4322, 1996). Uptake of (R)-dichlorprop, (S)-dichlorprop, and 2,4-D (2,4-dichlorophenoxyacetic acid) was inducible. Initial uptake rates of cells grown on the respective substrate showed substrate saturation kinetics with apparent affinity constants (K_t) of 108, 93, and 117 μM and maximal velocities (V_max) of 19, 10, and 21 nmol min⁻¹ mg of protein⁻¹ for (R)-dichlorprop, (S)-dichlorprop, and 2,4-D, respectively. Transport of (R)-dichlorprop, (S)-dichlorprop, and 2,4-D was completely inhibited by various uncouplers and by nigericin but was only marginally inhibited by valinomycin and by the ATPase inhibitor N,N′-dicyclohexylcarbodiimine. Experiments on the substrate specificity of the putative transport systems revealed that (R)-dichlorprop uptake was inhibited by (R)-mecoprop but not by (S)-mecoprop, (S)-dichlorprop, or 2,4-D. On the other hand, the (S)-dichlorprop transport was inhibited by (S)-mecoprop but not by (R)-mecoprop, (R)-dichlorprop, or 2,4-D. These results provide evidence that the first step in the degradation of dichlorprop, mecoprop, and 2,4-D by S. herbicidovorans is active transport and that three inducible, proton gradient-driven uptake systems exist: one for (R)-dichlorprop and (R)-mecoprop, another for (S)-dichlorprop and (S)-mecoprop, and a third for 2,4-D.