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Variation patterns within 153 flax (Linum usitatissimum L.) genebank accessions based on evaluation for resistance to fusarium wilt, anthracnose and pasmo

Published online by Cambridge University Press:  01 April 2008

Axel Diederichsen ,
Tatiana A. Rozhmina  and
Ljudmilla P. Kudrjavceva
Axel Diederichsen*
Affiliation:
Plant Gene Resources of Canada (PGRC), Saskatoon Research Centre, Agriculture and Agri-Food Canada, 107 Science Place, Saskatoon, Saskatchewan, CanadaS7N 0X2
Tatiana A. Rozhmina
Affiliation:
All-Russian Flax Research Institute (VNIIL), Lunacharsky Str. 35, Torzhok 172060, Tver District, Russian Federation
Ljudmilla P. Kudrjavceva
Affiliation:
All-Russian Flax Research Institute (VNIIL), Lunacharsky Str. 35, Torzhok 172060, Tver District, Russian Federation
*
*Corresponding author. E-mail: [email protected]
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Abstract

Germplasm of 153 flax (Linum usitatissimum) accessions from 24 countries held at Plant Gene Resources of Canada (PGRC) was evaluated for resistance to fusarium wilt (Fusarium oxysporum), anthracnose (Colletotrichum lini) and pasmo (Septoria linicola). The screening was conducted at the All-Russian Flax Research Institute (VNIIL) at Torzhok, Russia, over 3 years for fusarium wilt and anthracnose, and over 2 years for pasmo. A disease severity index ranging from 0% (no infection) to 100% (heavy infection) was calculated based on observations after artificial inoculation with the pathogens in the greenhouse (fusarium wilt) or in field nurseries (anthracnose and pasmo). The average disease severity index for fusarium wilt was 56.6 ± 34.4% (range 0–100.0%), for anthracnose 59.8 ± 8.1% (range 43.8–83.9%) and for pasmo 74.2 ± 11.8% (range 27.3–100.0%). The variation of disease severity indices among the years and within each accession was highest for fusarium wilt. Higher than average resistance for all three diseases was found in accessions from East Asia, while germplasm from the Indian subcontinent showed considerably lower than average resistance. Germplasm from North America and South America (mostly linseed) displayed above average resistance to fusarium wilt, while European accessions (mostly fibre flax) showed lower than average resistance to this disease. The different resistance levels reflected the improvements made by plant breeding and differences in the environments under which the germplasm accessions evolved. Accessions with potential use in linseed and fibre flax breeding were identified.

Keywords

disease resistancefibre flaxgenetic resourcesgermplasm screeninglinseedLinum usitatissimum L.
Type
Research Article
Information
Plant Genetic Resources , Volume 6 , Issue 1 , April 2008 , pp. 22 - 32
Copyright
Copyright © NIAB 2008

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References

Bačelis, K and Gruzdevienė, E (2001) Resistance of fibre flax varieties to Colletotrichum lini Manns et Bolley. Biologija 3: 49.Google Scholar
Brutch, NB (2002) The flax genetic resources collection held at the Vavilov Institute, Russian Federation. In: Maggioni, M, Pavelek, M, van Soest, LJM and Lipman, E (eds) Flax genetic Resources in Europe. Rome: IPGRI, pp. 6165.Google Scholar
Diederichsen, A, Raney, JP, Fu, YB and Richards, KW (2002) Diversity in the flax collection at Plant Gene Resources of Canada. In: Flax Institute, (ed.) Proceedings of the 59th Flax Institute of the United States, March 21–23, 2000. Fargo, North Dakota: Flax Institute, pp. 138143.Google Scholar
Diederichsen, A, Rozhmina, TA, Zhuchenko, AA Jr and Richards, KW (2006) Screening for broad adaptation in 96 flax (Linum usitatissimum L.) accessions under dry and warm conditions in Canada and Russia. FAO/IPGRI Plant Genetic Resources Newsletter 146: 916..Google Scholar
Grant, L, Rashid, K and Lamari, L (2004) The effects of pasmo (Septoria linicola) on yield, oil and protein content in oil seed flax. In: Flax Institute, (ed.) Proceedings of the 60th Flax Institute of the United States, March 17–19, 2004. Fargo, North Dakota: Flax Institute, pp. 142145.Google Scholar
Kenaschuk, EO and Rowland, GG (1995) Flax. In: Slinkard, AE and Knott, DR (eds) Harvest of Gold: The History of Field Crop Breeding in Canada. Saskatoon: University of Saskatchewan, pp. 173176.Google Scholar
Knowles, PF, Houston, BR and McOnie, JB (1956) Inheritance of resistance to fusarium wilt of flax in Punjab 53. Agronomy Journal 48: 135137.CrossRefGoogle Scholar
Kroes, GMLW, Rashid, KY, Hammond, J and Lange, W (1998) In: Flax Institute, (ed.) Papers and Proceedings of the 57th Flax Institute of the United States, March 26–28, 1998. Fargo, North Dakota: Flax Institute, pp. 118124.Google Scholar
Kroes, GMLW, Löffler, HJM, Parlevliet, JE and Keizer, LCP (1999) Interactions of Fusarium oxysporum f. sp. lini, the flax wilt pathogen, with flax and linseed. Plant Pathology 48: 491498.CrossRefGoogle Scholar
Krylova, TV (1994) Virulentnost' mestnoj populacii vozbuditelja ržavčiny l'na-dolgunca. [Virulence of the local population of the fibre flax rust pathogen.] Sbornik naučnych trudov VNIIL, vols 28–29. Torzhok: VNIIL, pp. 4756.Google Scholar
Kudrjavceva, LP (1993) Soveršenstvovanie metodiki selekcii l'na-dolgunca na ustoičivost' k pasmo, antraknozu, polisporozu. Avtoreferat na coiskanie učenyj stepen kandiadat selsko-chozjaistvennych nauk. [Improvement of the method of breeding fibre flax for resistance to pasmo, anthracnose and Polispora lini.] PhD thesis, TAA, Moscow.Google Scholar
Kudrjavceva, LP (1994) Ustojčivost' k antraknozu kollekcionnych obrazcov l'na. [Resistance to anthracnose in collection accessions of flax.] Sbornik naučnych trudov VNIIL, vols 28–29. Torzhok: VNIIL, pp. 57–62.Google Scholar
Kudrjavceva, LP (2002) K metodike ocenki i otbora l'na na gruppovuju ustojčivost' k pasmo i antraknosu. [On the method of rating and selecting flax for combined resistance to pasmo and athracnose.] Naučnye trudy VNIIL, vol. 30(1). Torzhok: VNIIL, pp. 62–66..Google Scholar
Kutuzova, SN (1994) Genetic bases of long-term resistance to rust in flax varieties. Russian Journal of Genetics 30: 11811190.Google Scholar
Kutuzova, SN (1998) Genetika l'na. In: Dragavcev, VA and Fadeeva, TS (eds) Genetika kul'turnych rastenij (len, kartofel', morkov', zelennye kul'tury, gladiolus, jablona, ljucerna). [Genetics of Cultivated Plants (Flax, Potato, Carrot, Greens, Gladiola, Apple, Alfalfa).] St. Petersburg: VIR, pp. 652.Google Scholar
Lokashova, NI and Kudrjavceva, LP (1998) Bank of strains of pathogens – activators of flax diseases and its use in breeding. In: VIR, (ed.) Proceedings of Conference: ‘Bast Fibrous Plants Today and Tomorrow; Breeding, Molecular Biology and Biotechnology Beyond the 20th Century’, St. Petersburg, Russia. St. Petersburg: VIR, pp. 169171.Google Scholar
Lokashova, NI, Krylova, TV and Kudrjavceva, LP (2000) Metodičeskie ukazanija po fitopatologičeskoj ocenke ustojčivosti l'na-dolgunca k boleznam. [Methodical Guidelines for Plant-Pathological Disease Resistance Ratings in Fibre Flax.] Moscow: Rossel'chozakademija.Google Scholar
Mpofu, SI and Rashid, KY (2000) Differentiation of Fusarium oxysporum f. sp. lini populations from flax wilt nurseries in western Canada based on vegetative compatibility. In: Flax Institute, (ed.) Proceedings of the 58th Flax Institute of the United States, March 23–25, 2000. Fargo, North Dakota: Flax Institute, pp. 118121.Google Scholar
Rashid, KY (2003a) Principal diseases of flax. In: Muir, A and Westcott, N (eds) Flax, the Genus Linum. London: Taylor & Francis, pp. 92124.Google Scholar
Rashid, KY (2003b) Diseases of flax. In: Bailey, KL, Gossen, BD, Gugel, RK and Morrall, RAA (eds) Diseases of Field Crops in Canada. 3rd edn.Saskatoon: The Canadian Phytopathological Society, pp. 147154.Google Scholar
Rozhmina, TA (2004) Genetičeskoe raznoobrazie l'na (Linum usitatissimum L.) i ego kompleksnoe ispol'zovanie v selekcii; avtoreferat. [The genetic diversity of flax (Linum usitatissimum L.) and its comprehensive use in breeding.] Thesis summary, VIR, St. Petersburg.Google Scholar
Vavilov, NI (1964) Problemy immuniteta kul'turnych rastenij. [The problem of disease resistance in cultivated plants.] In: Zhukovskij, PM and Bachteev, FCh (eds) Izbrannye trudy N.I. Vavilova v 5 tomach. [Selected Writings of N.I. Vavilov in five volumes], vol. 4. Moscow and Leningrad: Nauka, pp. 290300.Google Scholar
Zhuchenko, AA (1988) Adaptivnyj potencial kul'turnych rastenij (ekologo-geografičeskie osnovy). [Adaptive Potential of Cultivated Plants (Genetic and Ecological Bases).] Kishinev, Moldavia: ‘Shtiintsa’ Publishers.Google Scholar
Zhuchenko, A Jr and Rozhmina, T (2000) Mobilizacia genetičeskych resursov l'na. [Mobilization of Flax Genetic Resources.] Staritsa, Russia: VILAR and VNIIL.Google Scholar
Zhukovskij, PM (1968) Novye očagi proizchoždenija i gencentry kul'turnych rastenij i uskoendemičnye mikrocentry rodstvennych vidov. [New centres of the origin and new gene centres of cultivated plants including specifically endemic micro-centres of species closely allied to cultivated species.] Botaničeskij žurnal 53: 430460.Google Scholar