Sains Malaysiana 49(10)(2020): 2425-2432

http://dx.doi.org/10.17576/jsm-2020-4910-08

 

Glomus mosseae Promotes Xanthium italicumInvasion

(Glomus mosseae Menggalakkan Pencerobohan Xanthium italicum)

 

TANG JIE SHI, ZHAO ZHI LONG & MA MIAO*

 

Ministry of Education, Key Laboratory of Xinjiang Phytomedicine Resource Utilization, College of Life Sciences, Shihezi University, Shihezi, Xinjiang 832003, China

 

Diserahkan: 16 Jun 2019/Diterima: 13 April 2020

 

ABSTRACT

The relationship between mycorrhizal fungi and the invasiveness of alien plants is a controversial issue in plant invasion ecology. In this study, we investigated the influence of the mycorrhizal fungus Glomus mosseae on the physiological ecology, growth, and reproductive capacity of Xanthium italicum Moretti. We found that the relative chlorophyll content and net photosynthetic rate of the leaves of potted X. italicum whose rhizosphere soil was supplemented with G. mosseae was higher than those of the control group. Plants in the treatment group had longer root length and plant height; increased root, stem, and fruit biomass; and more male and female inflorescences and fruits relative to control plants. Additionally, the ratio of female to male inflorescence number was close to 2:1 in the treatment group as compared to 1:1 in the control group, suggesting an enhanced reproductive capacity in the former. G. mosseae applied to the soil also increased phosphorus absorption and accumulation in the roots, stems, and leaves of X. italicum. Thus, G. mosseae promotes the growth and reproduction of X. italicum and thereby enhances its competitiveness and capacity for colonizing a new habitat.

 

Keywords: Alien plant; biological invasion; Italian cocklebur; mycorrhizal fungi

 

ABSTRAK

Hubungan antara kulat mikoriza dan keserbuan tumbuhan asing adalah isu kontroversi dalam ekologi pencerobohan tumbuhan. Dalam kajian ini, kami mengkaji pengaruh kulat mikoriza Glomus mosseae pada ekologi fisiologi, pertumbuhan dan keupayaan pembiakan Xanthium italicum Moretti. Kami mendapati bahawa kandungan klorofil relatif dan kadar fotosintesis bersih daun X. italicum pot yang tanah rizosferanya dilengkapi dengan G. mosseae lebih tinggi daripada kumpulan kawalan. Tumbuhan dalam kumpulan rawatan mempunyai panjang akar dan ketinggian tanaman yang lebih panjang; peningkatan biojisim akar, batang dan buah; dan lebih banyak perbungaan dan buah jantan dan betina berbanding tanaman kawalan. Selain itu, nisbah bilangan perbungaan betina dan jantan mendekati 2:1 dalam kumpulan rawatan berbanding 1:1 pada kumpulan kawalan, menunjukkan peningkatan keupayaan pembiakan pada kumpulan rawatan. G. mosseae yang digunakan pada tanah juga meningkatkan penyerapan dan pengumpulan fosforus pada akar, batang dan daun X. italicum. Oleh itu, G. mosseae mendorong pertumbuhan dan pembiakan X. italicum dan dengan itu meningkatkan daya saing dan keupayaannya untuk menjajah habitat baru.

 

Kata kunci: Kerang Itali; kulat mikoriza; pencerobohan biologi; tumbuhan asing

 

RUJUKAN

Al-Hammadi, M.S., Rashid, A.S. & Maharachchikumbura, S.S.N. 2018. Molecular identification of fungal pathogens associated with date palm root diseases in the United Arab Emirates. Journal of Plant Pathology 101(2019): 141-147.

Aminah, H., Naimah, C.L., Barizan, R.S.R. & Noor, M.M. 2013. Effect of light intensity and fertiliser levels on the stock plants of Chengal (Neobalanocarpus heimii) and rooting of its subsequent cuttings. Sains Malaysiana 42(3): 257-263.

Brundrett, M.C. 2009. Mycorrhizal associations and other means of nutrition of vascular plants: Understanding the global diversity of host plants by resolving conflicting information and developing reliable means of diagnosis. Plant and Soil 320(2009): 37-77.

Bunn, R.A., Ramsey, P.W. & Lekberg, Y. 2015. Do native and invasive plants differ in their interactions with arbuscular mycorrhizal fungi? A meta-analysis. Journal of Ecology 103(6): 1547-1556.

Chaudhary, N., Narayan, R. & Sharma, D.K. 2015. Differential biomass allocation to plant organs and their allelopathic impact on the growth of crop plants: A case study on the invasibility of Ageratum conyzoides in Indian dry tropics. Indian Journal of Agricultural Sciences 85(11): 1405-1411.

Chmura, D. & Gucwa-Przepióra, E. 2012. Interactions between arbuscular mycorrhiza and the growth of the invasive alien annual Impatiens parviflora DC: A study of forest type and soil properties in nature reserves (S Poland). Applied Soil Ecology 62(2012): 71-80.

Cronin, J.T., Bhattarai, G.P., Allen, W.J. & Meyerson, L.A. 2016. Biogeography of a plant invasion: Plant-herbivore interactions. Ecology 96(4): 1115-1127.

Doidy, J., Grace, E., Kühn, C., Simon-Plas, F., Casieri, L. & Wipf, D. 2012. Sugar transporters in plants and in their interactions with fungi. Trends in Plant Science 17(7): 413-422.

Fumanal, B., Plenchette, C., Chauvel, B. & Bretagnolle, F. 2006. Which role can arbuscular mycorrhizal fungi play in the facilitation of Ambrosia artemisiifolia L. Invasion in France? Mycorrhiza 17(1): 25-35.

Harley, J.L. & Smith, S.E. 2008. Mycorrhizal symbiosis. Quarterly Review of Biology 3(3): 273-281.

He, Y. & Ma, M. 2018. Responses of seed germination of the invasive plant Xanthium italicum to environmental factors. Acta Ecology Sinica 38: 1226-1234

He, Y.J., Jiang, C.H., Yang, H., Wang, Y.J. & Zhong, Z.C. 2017. Arbuscular mycorrhizal fungal composition affects the growth and nutrient acquisition of two plants from a Karst area. Sains Malaysiana 46(10): 1701-1708.

He, Y.J., Zhong, Z.C., Liu, J.M., Liu, J.C., Song, H.X. & Jin, J. 2007. Growth response of Broussone tiapapyrifera seedlings to VA mycorrhizal fungi inoculation. Chinese Journal of Applied Ecology 18(10): 2209- 2213.

Johnson, S.D. & Raguso, R.A. 2016. The long-tongued hawkmoth pollinator niche for native and invasive plants in Africa. Annals of Botany 117(1): 25.

Kazinczi, G., Torma, M., Béres, I. & Horváth, J. 2009. Competition between Xanthium italicum and crops under field conditions. Cereal Research Communications 37: 77-80.

Lee, M.R., Tu, C., Chen, X. & Hu, S. 2014. Arbuscular mycorrhizal fungi enhance P uptake and alter plant morphology in the invasive plant Microstegium vimineum. Biological Invasions 16(2014): 1083-1093.

Li, B., Xu, B.S. & Chen, J.K. 2001. Perspectives on general trends of plant invasions with special reference to alien weed flora of Shanghai. Biodiversity Science 9(4): 446-457.

Li, J. & Ma, M. 2019. Seeds over-wintering characteristics of Italian Cocklebur and Stab Cocklebur: Two invasive plants in Xinjiang, China. South African Journal of Botany 121(2019): 216-218.

Lin, H., Zhang, M.L., Wang, P.P. & Ma, M. 2018. Study on the pollination biology of the invasive plant Xanthium italicum Moretti. Acta Ecology Sinica 38: 1810-1816.

Liu, R.J., Huang, Y. & Lin, X.G. 2009. Recent advances in the studies of mycorrhizology. Journal of Fungal Research 7(2): 116-124.

Liu, X.L., Xi, X.Y., Shen, H., Liu, B. & Guo, T. 2014. Influences of arbuscular mycorrhizal (AM) fungi inoculation on the resistance of tobacco to bacterial wilt. Tobacco Science and Technology 49: 23-30.

Marschner, H. & Dell, B. 1994. Nutrient uptake in mycorrhizal symbiosis. Plant and Soil 159: 89-102.

Nivelle, E., Verzeaux, J. & Amélie, C. 2018. Effects of glyphosate application and nitrogen fertilization on the soil and the consequences on aboveground and belowground interactions. Geoderma 311(2018): 45-57.

Peng, S.L. & Xiang, Y.C. 1999. The invasion of exotic plants and the effects of ecosystems. Acta Ecology Sinica 19: 560-568.

Qu, B., Xun, Z.F. & Xu, Y.F. 2015. The seeds ecological mechanism of Xanthium strumarium invasion. Pratacultural Science 32: 1801-1807.

Shao, H., Huang, X., Wei, X. & Zhang, C. 2012. Phytotoxic effects and a phytotoxin from the invasive plant Xanthium italicum Moretti. Molecules 17(4): 4037-4046.

Subramanian, K.S. & Charest, C. 2010. Arbuscular mycorrhizae and nitrogen assimilation in maize after drought and recovery. Physiologia Plantarum 102(2): 285-296.

Sun, X.X., Jin, W.J., Li, Y.S., Yan, Y., Yu, X.C. & He, C.X. 2016. Effects of two different AMF strains mixture inoculum inoculation on cucumber seedlings grown in the solar greenhouse. China Vegetables 4: 34-37.

Takakura, K.I. & Fujii, S. 2010. Reproductive interference and salinity tolerance differentiate habitat use between two alien cockleburs: Xanthium occidentale and X. italicum (Compositae). Plant Ecology 206(2): 309-319.

Wang, C.X., Qin, L., Feng, G. & Li, X.L. 2003. Effects of three arbuscular mycorrhizal fungi on the growth of cucumber seedlings. Journal of Agro-Environment Science 22: 301-303.

Wang, S.G., Lin, X.G. & Shi, Y.Q. 2001. Effects of arbuscular mycorrhiza on the resistance of plants to environmental stress. Chinese Journal of Ecology 20: 27-30.

Yang, S.Y., Guo, D.Y., Shen, H.M. & Zhang, X.H. 2006. Antifungal activity of 14 plants to phytopathogens. Plant Protection 32(3): 68-71.

Zai, X.M., Zhu, S.N., Qin, P., Wang, X.Y., Che, L. & Luo, F.X. 2012. Effect of Glomus mosseae on chlorophyll content, chlorophyll fluorescence parameters, and chloroplast ultrastructure of beach plum (Prunus maritima) under NaCl stress. Photosynthetica 50: 323-328.

Zhang, J.X., Bei, Z.G., Zhang, Y. & Cao, L.K. 2014. Growth characteristics, water and nitrogen use efficiencies of Spinach in different water and nitrogen levels. Sains Malaysiana 43(11): 1665-1671.

Zhang, Y. 2011. Comparative analysis of NPK uptake by different organs of eggplants during different growth stages. Acta Agriculturae Zhejiangensis 23: 1134-1139.

Zhi, G.Y., Chen, X. & Tang, J.J. 2003. Mediations of arbuscular mycorrhizal fungi on the plant community. Mycosystema 22: 678-682.

 

*Pengarang untuk surat-menyurat; email: mamiaogg@126.com

   

 

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