First record of the ectoparasitic nematode Amplimerlinius macrurus (Nematoda: Tylenchida) on the perennial grass Miscanthus × giganteus (Angiosperms: Poaceae) in Ukraine
Status PubMed-not-MEDLINE Jazyk angličtina Země Polsko Médium electronic-ecollection
Typ dokumentu časopisecké články
PubMed
33860243
PubMed Central
PMC8039982
DOI
10.21307/jofnem-2021-024
PII: e2021-24
Knihovny.cz E-zdroje
- Klíčová slova
- Genetic analysis, Morphological description, Plant-parasitic nematode, Taxonomy, Ukraine,
- Publikační typ
- časopisecké články MeSH
The growing interest in biomass production of Miscanthus × giganteus (M × g) (Poaceae) on agricultural and marginal lands has prompted researches to identify plant pathogens and diseases affecting this crop which has a great potential for production of biofuels and different bioproducts. A soil survey of nematodes in the M × g rhizosphere and a report on the collection of the plant-parasitic nematode Amplimerlinius macrurus (Belonolaimidae) were accomplished in two locations in Ukraine. It is known that this family of nematodes can reduce the root system and biomass of Poaceae family plants. Both molecular and morphological characters were used to identify the nematodes; measurements and photomicrographs of the species were presented. This is the first documentation and description of A. macrurus in Ukraine to the best of our knowledge. Further investigation is underway to confirm the pathogenicity of this species on perennial grasses plantations.
Department of Entomology National University of Life and Environmental Sciences Kiev Kyiv
Department of Plant Protection Czech University of Life Sciences Prague Czech Republic
Department of Plant Protection Research Institute of Horticulture Skierniewice Poland
Museum and Institute of Zoology Polish Academy of Sciences Warsaw Poland
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Almasary, Z., Todd, T., Hettiarachchi, G. M., Stefanovska, T., Pidlisnyuk, V., Roozeboom, K., Erickson, L., Davis, L. and Zhukov, O.. 2020. Effect of soil treatments and amendments on the nematode community growing in a Lead contaminated military site. Agronomy 10:1727, doi: 103390/agronomy10111727.
Andrássy, I. 2007. Free-living nematodes of Hungary (Nematoda errantia), II. Hungarian Natural History Museum and Systematic Zoology Research Group of the Hungarian Academy of Sciences, Budapest, p. 496.
Bahmani, J., Khozeini, F., Barooti, S., Rezaee, S. and Ghaderi, R.. 2013. Plant-parasitic nematodes associated with walnut in the Sanandej region of west Iran. Journal of Plant Protection Research 53:404–408, available at:10.2478/jppr-2013-0060. DOI
Bello, A., Mahajan, R. and Zancada, M. G.. 1987. Amplimerlinius hornensis sp. n. (Nematoda: Merliniinae) with notes on A. siddiqii from Spain. Revue de Nématologie 10:295–298.
Bert, W., Coomans, A., Claerbout, F., Geraert, E. and Borgonie, G.. 2003. Tylenchomorpha (Nematoda: Tylenchina) in Belgium, an updated list. Nematology 5:435–440, available at: 10.1163/156854103769224412 DOI
Brzeski, M. W. 1998. Nematodes of Tylenchina in Poland and temperate Europe Museum and Institute of Zoology PAS, Warszawa, p. 396.
Carta, L. K., Skantar, A. M. and Handoo, Z. A.. 2010. Molecular rDNA phylogeny of Telotylenchidae Siddiqi, 1960 and evaluation of tail termini. Journal of Nematology 42:359–369. PubMed PMC
Clifton-Brown, J. 2017. Environmental costs and benefits of growing Miscanthus for bioenergy in UK. Global Change Biology Bioenergy 3:489–507, available at: 10.1111/gcbb.12294. PubMed DOI PMC
Cosentino, S. L., Scordia, D., Testa, G., Monti, A., Alexopoulou, E. and Christou, M.. 2018. “The importance of perennial grasses as a feedstock for bioenergy and bioproducts”, In Alexopouloued, E. (Ed.), Perennial grasses for bioenergy and bioproducts Academic Press, Amsterdam, pp. 1–33.
Filipjev, I. N. 1936. On the classification of the Tylenchinae. Proceedings of the Helminthological Society of Washington 3:80–82.
Ghaderi, R. and Karegar, A.. 2014. Description of Amplimerlinius uramanatiensis sp. n. (Nematoda: Merliniidae) and observations on three other species of the genus from Iran. Zootaxa 3869 1:17–32, available at: http://Dx.Doi.Org/10.11646/Zootaxa.3869. PubMed DOI
Ghaderi, R., Habiballah, H. and Akba, K.. 2017. Numerical taxonomy helps identification of Merliniidae and Telotylenchidae (Nematoda: Tylenchoidea) from Iran. Journal of Nematology 49:207–222, doi: 10.21307/jofnem-2017-065. PubMed DOI PMC
Ghaderi, R., Karegar, A. and Niknam, G.. 2014. An updated and annotated checklist of the Dolichodoridae (Nematoda: Tylenchoidea) of Iran. Zootaxa 3784:445–468, available at: http://Dx.Doi.Org/10.11646/Zootaxa.3784.4.5 PubMed DOI
Goodey, T. 1932. The genus Anguillulina Gerv. and v. Ben., 1859, vel Tylenchus Bastian, 1865. Journal of Helminthology 10:75–180, available at: 10.1017/S0022149X00001346. DOI
Goodey, T. 1943. A note on the feeding of nematode Anguillulina macrura. Journal of Helminthology 21:17–19, 10.1017/S0022149X00031849. DOI
Háněl, L. and Čerevková, A.. 2006. Diversity of soil nematodes in meadows of the White Carpathians. Helminthologia 43:109–116, available at: 10.2478/s11687-006-0021-1 . DOI
Hashim, Z. 1982. Distribution, pathogenicity and control of nematodes associated with olive. Revue de Nematologie 5:169–181.
Hashim, Z. 1983. Plant-parasitic nematodes associated with pomegranate (Punica granatum L.) in Jordan and an attempt to chemical control. Nematologia Mediterranea 11:199–200.
Holterman, M., Wurff, A., van der Elsen, S., van den Megen, H., Bongers, T., Holovachov, O., Bakker, J. and Helder, J.. 2006. Phylum-wide analysis of SSU rDNA reveals deep phylogenetic relationships among nematodes and accelerated evolution toward crown clades. Molecular Biology and Evolution 23:1792–1800, available at: 10.1093/molbev/msl044 . PubMed DOI
Ivanova, T. S. 1982. New species of Nematoda of the subfamily Merliniinae Siddiqi 1972. Izviestija Academii Nauk Tadzhiskoi Ssr. Biologiczeskiye Nauki 1 86:21–25 (in Russian).
Kharytonov, M., Pidlisnyuk, V., Stefanovska, T., Babenko, M., Martynova, V. and Rula, M.. 2019. The estimation of Miscanthus x giganteus adaptive potential for cultivation on the mining and post-mining lands in Ukraine. Environmental Science and Pollution Research 26:2974–2986, 10.1007/s11356-018-3741-0. PubMed DOI
Kheiri, A., Barooti, S. and Karimipour, H.. 2002. Tylenchida associated with field crops in Tehran and Central Provinces of Iran. Mededelingen Faculteit Landbouwkundige en Toegepaste Biologische Wetenschappen Universiteit Gent 67:707–713. PubMed
Lamberti, F. and Vovlas, N.. 1993. Plant parasitic nematodes associated with olive. EPPO Bulletin 23:481–488, available at: 10.1111/j.1365-2338.1993.tb01356.x. DOI
Lewandowski, I., Clifton-Brown, J., Kiesel, A., Hastings, A. and Iqbal, Y.. 2018. “Miscanthus”, In Alexopoulou, E. (Ed.), Perennial grasses for bioenergy and bioproducts Academic Press, London, pp. 35–59, 10.1016/B978-0-12-812900-5.00002-3 . DOI
Mekete, T., Gray, M. E. and Niblack, T. L.. 2009. Distribution, morphological description, and molecular characterization of Xiphinema and Longidorus spp. associated with plants (Miscanthus spp. and Panicum virgatum) used for biofuels. GCB Bioenergy 1:257–266, available at: 10.1111/j.1757-1707.2009.01020.x . DOI
Mekete, T., Reynolds, K., Lopez-Nicora, H. D., Gray, M. E. and Niblack, T. L.. 2011. Plant-parasitic nematodes are potential pathogens of Miscanthus × giganteus and Panicum virgatum used for biofuels. Plant Disease 95:41–418, 10.1094/PDIS-05-10-0335 . PubMed DOI
Navas, A. and Talavera, M.. 2002. Incidence of plant-parasitic nematodes in natural and semi-natural mountain grassland and the host status of some common grass species. Nematology 4:541–552, 10.1163/156854102760290518. DOI
Niknam, G., Jabbari, H., Chenari, G., Eskandari, S. and Pedram, M.. 2008. Some belonolaimid nematodes from lucerne farms of East Azerbaijan province. Agricultural Science 18:187–197, (in Persian with English summary).
Norton, D., Donald, P., Kempinski, J., Meyers, R., Noel, G., Noffsinger, E., Robbins, R., Schmitt, D., Sosa-Moss, C. and Vrain, T.. 1984. Distribution of plant-parasitic nematode species in North America Society of Nematologists Hyattsville, MD, p. 205.
Nunn, G. B. 1992. Nematode molecular evolution: an investigation of evolutionary patterns among nematodes based upon DNA sequences. PhD dissertation, University of Nottingham, Nottingham.
Panahandeh, Y. and Pourjam, E.. 2014. Some belonolaim species (Nematoda, Dolichodoridae) from Sabalan region, Northwest of Iran. Journal of Crop Protection 3:13–20.
Pidlisnyuk, V., Shapoval, P., Zgorelec, Z., Stefanovska, T. and Zhukov, O. V.. 2020. Multiyear phytoremediation and dynamic of foliar metal (loid) s concentration during application of Miscanthus × giganteus Greef et Deu to polluted soil from Bakar, Croatia. Environmental Science and Pollution Research 27:31446–31457, available at: 10.1007/s11356-020-09344-5 . PubMed DOI PMC
Poghossian, T. E. 1979. Two new species of nematodes (Nematoda: Tylenchorhynchidae) from Armenian SSR. Doklady Akademii Nauk Armyanskoi SSR 68:60–63 (in Russian).
Renčo, M. 2013. Plant parasitic and soil free-living nematodes of selected forest nurseries in Slovak Republic. Forestry Journal 59:264–275.
Saltukoglu, M. E., Geraert, E. and Coomans, A.. 1976. Some Tylenchida from the Istanbul area (Turkey). Nematologia Mediterranea 4:139–153.
Seinhorst, J. W. 1959. A rapid method for the transfer of nematodes from fixative to anhydrous glycerin. Nematologica 4:67–69, 10.1163/187529259x00381 . DOI
Siddiqii, M. R. 1976. New plant nematode genera Plesiodorus (Dolichodorinae), Meiodorus (Meiodorinae subfam. n.), Amplimerlinius (Merliniinae) and Gracilancea (Tylodoridae grad. n.). Nematologica 22:390–416.
Siddiqii, M. R. and Klingler, J.. 1980. Amplimerlinius dubius comb. n. for Aphelenchus dubius Steiner 1914. Nematologica 26:376–379.
Skwiercz, A. T. 1989. Plant parasitic nematodes in the peat soils in Poland, Part I. Biocenotic analyse. Roczniki nauk rolniczych Seria E – Ochrona Roślin 19:91–99.
Stefan, Z. A., Alwan, A. H. and Antone, B. G.. 1985. Occurrence of plant parasitic nematodes in vineyard soils in Iraq. Nematologia Mediterranea 13:261–264.
Stefanovska, T., Lewis, E., Pidlisnyuk, V. and Gorbatenko, A.. 2017. Herbivorous insects’ diversity at Miscanthus × giganteus in Ukraine. Agriculture (Pol’nohospodárstvo) 63:23–32, available at: 10.1515/agri-2017-0003 . DOI
Stefanovska, T., Skwiercz, A., Zouhar, M., Pidlisnyuk, V. and Zhukov, O.. 2020. Plant-feeding nematodes associated with Miscanthus × giganteus and their use as potential indicators of the plantations’ state. International Journal of Environmental Science and Technology, 18:57–72, 10.1007/s13762-020-02865-z . DOI
Steiner, G. 1914. Freilebende Nematoden aus Schweiz. I. Teil: einer vorlaufingen Mittelung. Archiv und Hydrobiologie 9:259–276.
Sturhan, D. 2014. Plant-parasitic nematodes in Germany – an annotated checklist. Soil Organisms 86: 177–198.
Szczygieł, A. 1971. Application of the centrifugal method for extraction of nematodes from soil. Journal of Progress in Agricultural Sciences 12:169–179.
Wallace, H. R. and Greet, D. N.. 1964. Observations on the taxonomy and biology of Tylenchorhynchus macrurus (Goodey, 1932) Filipjev, 1936 and Tylenchorhynchus icarus sp. nov. Parasitology 54:129–144, 10.1017/S0031182000074424 . DOI
Winiszewska, G., Dmowska, E., Chałańska, A., Dobosz, R., Kornobis, F., Makulec, K. I., Skwiercz, A., Wolny, S. and Ishaque, E.. 2012. Nematodes associated with plant growth inhibition in the Wielkopolska region. Journal of Plant Protection Research 52:440–446, 10.2478/v10045-012-007 . DOI
Yoder, M., De Ley, I. T., King, I. W., Mundo-Ocampo, M., Mann, J., Blaxter, M., Poiras, L. and De Ley, P.. 2006. DESS: a versatile solution for preserving morphology and extractable DNA of nematodes. Nematology 8:367–376, doi: 10.1163/156854106778493448. DOI