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Sains Malaysiana 52(7)(2023):
http://doi.org/10.17576/jsm-2023-5207-08
Seed Germination
Characteristics as Affected by Interaction of Moisture Stress and Temperature
in Sethoxydim-Resistant Biotype of Goosegrass (Eleusine indica (L.) Gaertn.) from Malaysia
(Pencirian Percambahan Benih yang Dipengaruhi oleh Interaksi Tekanan dan Suhu Lembapan dalam Biotip Rumput Sambau Rintangan Sethoxydim (Eleusine indica (L.) Gaertn.) dari Malaysia)
CHUAH TSE
SENG1*, HIEW CHEE NAM2, NURSYAFIQAH IZZATI NORZAIDI3 & SUNNY GOH ENG GIAP4
1Faculty of Plantation and
Agro-technology, University of Technology MARA, Perlis Branch, 02600 Arau,
Perlis, Malaysia
2,3Faculty of Fisheries and Food
Science, University of Malaysia Terengganu, 21030 Kuala
Terengganu, Terengganu, Malaysia
4Faculty of Ocean Engineering
Technology and Informatics, University of Malaysia Terengganu, 21030 Kuala Terengganu,
Terengganu, Malaysia
Received: 3 January
2023/Accepted: 7 July 2023
Abstract
Understanding
temperature and moisture stress that influence sethoxydim-resistant
(R) goosegrass (Eleusine indica)
germination is crucial for effective weed control, but little research has been done on the
impact of these environmental factors on germination of the R goosegrass biotype. This research aims to confirm sethoxydim resistance in goosegrass and to examine interaction effects of different temperatures and water
potentials on germination of the R goosegrass biotype. Dose–response tests showed that the R goosegrass biotype exhibited high resistance level to sethoxydim with 17-fold. In laboratory bioassays, the R goosegrassbiotype germinated by 88-100% at 35 °C with water potentials ranging
from 0 to -0.80 MPa, but no seed germination occurred at 10 °C and 40 °C under all water
potential treatments. With
rising water potentials from 0 to -0.80 MPa, seed germination at 15 to 30 °C decreased markedly. The time
it took to achieve 50% seed germination (T50) increased drastically
when decreasing temperature from 35 to 15 °C. The T50 at 20 to 30 °C
also increased as the water potential increased from -0.20 to -0.80 MPa. At 35
°C, however, the water potential level had no impact on T50,
implying that the R goosegrass biotype seed is water
stress tolerant at 35 °C. The base temperature and base water potentials
estimated were 10.6 °C and -1.28 MPa, respectively. These findings can help in determining the optimal time
to apply pre-emergent and early post-emergent controls when a large proportion of R goosegrass biotype have already germinated or emerged.
Keywords:
Base temperature; base water potential; post-emergence
control; pre-emergent control
Abstrak
Pemahaman terhadap tekanan suhu dan kelembapan yang mempengaruhi percambahan rumput sambau(Eleusine indica) yang rintang terhadap setoksidim (R) adalah penting untuk mengawal rumpai ini dengan berkesan, namun tidak sedikit kajian dilakukan mengenai kesan faktor persekitaran ini terhadap percambahan rumput sambau biotip R. Penyelidikan ini bertujuan untuk mengesahkan kerintangan rumput sambau terhadap setoksidim dan untuk mengkaji kesan interaksi suhu dan potensi air yang berbeza terhadap percambahan rumput sambau biotip R. Ujian gerak balas dos mendedahkan bahawa rumput sambau biotip R menunjukkan aras kerintangan yang tinggi terhadap setoksidim dengan 17 kali ganda. Pengasaian makmal menunjukkan bahawa rumput sambau biotip R bercambah sebanyak 88 hingga 100% pada suhu 35 °C dengan potensi air antara 0 hingga -0.80 MPa, tetapi tiada percambahan berlaku pada suhu 10 dan 40 °C di bawah semua rawatan potensi air. Dengan potensi air yang meningkat daripada 0 hingga -0.80 MPa, percambahan biji benih pada 15 hingga 30 °C menurun dengan ketara. Masa yang diambil untuk mencapai 50% percambahan biji benih (T50) meningkat secara drastik apabila suhu menurun daripada 35 hingga 15 °C. T50 pada 20 hingga 30 °C juga meningkat apabila potensi air meningkat daripada -0.20 kepada -0.80 MPa. Walau bagaimanapun, aras potensi air tidak memberi kesan kepada T50 pada 35 °C. Ini membayangkan bahawa rumput sambau biotip R adalah toleran terhadap tekanan air pada 35 °C. Suhu asas dan potensi air asas dianggarkan masing-masing pada 10.6 °C dan -1.28 MPa. Penemuan ini dapat membantu dalam menentukan masa yang optimum untuk memberi kawalan pra-muncul dan pasca-muncul pada peringkat awal apabila sebahagian besar rumpai sambau biotip R telah bercambah atau muncul.
Kata kunci: Kawalan pasca-muncul; kawalan pra-muncul; potensi air asas; suhu asas
REFERENCES
Abdullah H.S.T.S.H, Chia, P.W., Omar, D. & Chuah T.S. 2021. Herbicidal properties of antihypertensive drugs: calcium channel blockers. Scientific Reports 11(1): 14227-14227. Amirul, M.D., Diplikumar, M. & Chuah, T.S. 2019. Different imazethapyr placements and rainfall amounts affect phytotoxic activity of imazethapyr in combination with oil palm frond residue
mulches against common weeds in landscape. Sains Malaysiana 47(4): 671-682.
Amirul, M.D., Diplikumar, M., Ismail, S. & Chuah, T.S. 2019. Effects of imazethapyr treated oil palm frond residue mulch on weed control and ornamental plant
quality in nurseries. Indian Journal Horticulture 76(1): 148-154.
Bakhshandeh, E. & Gholamhossieni, M. 2019. Modelling the effects of water stress and temperature on seed
germination of radish and cantaloupe. Journal of Plant Growth
Regulation 38: 1402-1411.
Bewley, J.D., Bradford, K., Hilhorst, H. & Nonogaki, H. 2013. Seeds:
Physiology of Development, Germination and Dormancy. 3rd ed. New York: Springer. p. 407.
Bidgoly, R.O., Balouchi,
H., Soltani, E. & Moradi,
A. 2018. Effect of temperature and water potential on Carthamus tinctorius L. seed germination: Quantification of
the cardinal temperatures and modelling using hydrothermal time. Industrial
Crops and Products 113: 121-127.
Cha, T.S., Najihah, M.G., Sahid,
I.B. & Chuah, T.S. 2014. Molecular basis for
resistance to ACCase-inhibiting fluazifop in Eleusine indica from Malaysia. Pesticide Biochemistry and Physiology 111: 7-13.
Chauhan, B.S. &
Johnson, D.E. 2009. Influence of tillage systems on weed seedling emergence pattern in rainfed rice. Soil and Tillage Research 106(1): 15-21.
Chauhan, B.S. &
Johnson, D.E. 2008. Germination ecology of goosegrass (Eleusine indica): An
important grass weed of rainfed rice. Weed Science 56(5): 699-706.
Chuah, T.S. & Lim, W.K. 2021a. Effect
of selected pre-emergence herbicide-treated oil palm residues on goosegrass emergence and growth. Advanced Weed Science 39:
1-7.
Chuah, T.S. & Lim, W.K. 2021b.
Combination ration affects synergistic activity of oil palm frond residue and
s-metolachlor on goosegrass (Eleusine indica). Pakistan Journal of Botany 53: 1473-1478.
Chuah, T.S., Lim, W.K. & Ismail, B.S. 2018. Potential of oil palm frond
residues in combination with S-metolachlor for the
inhibition of selected herbicide-resistant biotypes of goosegrass emergence and seedling growth. Sains Malaysiana 47(4): 671-682.
Chuah, T.S., Salmijah, S.
& Ismail, B.S. 2004. Changes in seed bank size and dormancy characteristics
of the glyphosate- resistant biotype of goosegrass (Eleusine indica(L.) Gaertn.). Weed Biology and Management 4:
114-121.
Dilipkumar, M., Chuah, T.S., Goh, S.S. & Ismail, B.S. 2020a. Weed
management issues, challenges, and opportunities in Malaysia. Crop
Protection 134: 10434.
Dilipkumar, M., Nordin, M.A., Norhafizah, M.Z., Ismail, B.S. & Chuah,
T.S. 2020b. Phytotoxic activity of oil palm frond mulch in combination with
selected pre-emergence herbicide. Sains Malaysiana 49(10): 2403-2410.
Dumur, D., Pilbeam, C.J. & Craigon, J.
1990. Use of the Weibull function to calculate cardinal temperatures in faba bean. Journal of Experimental Botany 41:
1423-1430.
Ellis, R.H.,
Simon, G. & Covell,
S. 1987. The influence of temperature on seed germination rate in grain
legumes. III. A comparative of five faba bean
genotypes at constant temperatures using a new screening method. Journal of
Experimental Botany 38: 1033-1043.
Fyfield, T.P. &
Gregory, P.J. 1989. Effects of temperature and water potential on germination,
radicle elongation and emergence of mung- bean. Journal of Experimental
Botany 40: 667-674.
Garcia, A.L., Recasens, J., Forcella, F., Torra, J. & Royo-Esnal, A.
2013. Hydrothermal emergence model for ripgut brome (Bromus diandrus). Weed
Science 61(1): 146-153.
Forcella, F., Benech Arnold,
R.L., Sanchez, R. & Ghersa, C.M. 2000. Modeling
seedling emergence. Field Crops Research 67(2): 123-139.
Heap, I. 2023. The International Survey of
Herbicide Resistant Weeds. http://www. weedscience.com/.
Accessed on 25 June 2023.
Holm L.G., Plucknett D.L., Pancho J.V. & Herberger J.P. 1977. The World’sWorstWeeds – Distribution and Biology. The University Press of Hawaii, Honolulu, HI. pp. 47-53.
Ismail, B.S., Chuah, T.S., Salmijah, S., Teng, Y.T. & Schumacher, R.W. 2002. Germination and
seedling emergence of glyphosate-resistant and susceptible biotypes of goosegrass (Eleusine indica [L.] Gaertn.). Weed
Biology and Management 2: 177-185.
Kanzler, A. & Van Staden, J.
1984. Seed germination in goosegrass (Eleusine indica). South
African Journal of Botany 3(2): 108-110.
Kuk, I.Y., Kwon, O.O., Jung, H.I., Burgos, N.R.
& Guh, O.J. 2002. Cross-resistance pattern and
alternative herbicides for Rotala indica resistant to imazosulfuron in Korea. Pesticide Biochemistry and Physiology 74: 129-138.
Masin, R., Zuin, M.C., Archer,
D.V., Forcella, F. & Zanin,
G. 2005. WeedTurf: A predictive model to aid control
of annual summer weeds in turf. Weed Science 53: 193-201.
Ma, X-Y., Wu, H.W.,
Jiang, W.L., Ma, Y.J. & Ma, Y. 2015. Goosegrass (Eleusine indica) density effects on cotton (Gossypium hirsutum). Journal of Integrative Agriculture 14(9): 1778-1785.
Ma, X.Y., Ma, Y., Xi, J.P., Jiang, W.L., Ma, Y.J.
& Li, X.F. 2012. Mixed weeds and competition with directly seeded cotton,
north Henan province China. Cotton Science 24: 91-96 (in Chinese).
McCullough, P., Yu, J., Raymer, P. & Chen, Z. 2016. First report of ACCase-resistant goosegrass (Eleusine indica) in
the United States. Weed Science 64(3): 399-408.
Michel, B.E.
1983. Evaluation of the water potentials of solutions of polyethylene glycol
8000 both in the absence and presence of other solutes. Plant Physiology 72: 66-70.
Norhafizah, M.Z, Wan Nur Suzani S. & Chuah, T.S. 2020. Herbicidal activity of allelochemical 2,4-di-tert-butylphenol on weeds (Asystasia gangetica, Eleusine indica, Leptochloa chinensis and Oldenlandia verticillata). Allelopathy Journal 51(2): 195-208.
Piskurewicz, U., Sentandreu,
M., Iwasaki, M., Glauser, G. & Lopez-Molina, L. 2023.
The Arabidopsis endosperm is a temperature-sensing tissue that implements seed thermoinhibition through phyB. Natural
Communications 14: 1202.
Shekoofa, A., Brosnan, J.T., Vargas, J.J., Tuck, D.P. & Elmore, M.T.
2020. Environmental effects on efficacy of herbicides for postemergence goosegrass (Eleusine indica) control. Scientific Reports 10:
20579.
Sim, K.C.
2021. Goosegrass resistance. Personal communication. Shared on poor control of mature goosegrass in an oil palm plantation, Pekan Nanas, Johor, 30 Dec
2021.
Jaya Suria, A.S.M., Juraimi A.S.,
Rahman, M.M., Man, A.B. & Selamat, A. 2011. Efficacy and economics of different
herbicides in aerobic rice system. African Journal of Biotechnology 10(41): 8007-8022.
Takano, H.K., Olivera, Jr., R.S., Constantin, J., Braz,
G.B.P. & Padovese, J.C. 2016. Growth, development
and seed production of goosegrass. Planta Daninha 34(2): 249-257.
Tobe, K., Zhang,
L., Qiu, G.Y., Shimizu, H. & Omasa,
K. 2001. Characteristics of seed germination in five non-halophytic
Chinese desert shrub species. Journal of Arid Environments 47: 191-201.
*Corresponding
author; email: chuahts@uitm.edu.my
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