Your search keyword '"Ayub, M"' showing total 5 results

1. Population genetic differentiation and phenotypic plasticity of Ambrosiaartemisiifolia under different nitrogen levels.

Author

Xiong, Yunqi, Oduor, Ayub M. O., and Zhao, Caiyun

Subjects

POPULATION differentiation, PHENOTYPIC plasticity, BIOLOGICAL evolution, RAGWEEDS, INTRODUCED plants, INVASIVE plants, RAPESEED

Abstract

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Published

2024

2. Herbivory and elevated levels of CO2 and nutrients separately, rather than synergistically, impacted biomass production and allocation in invasive and native plant species.

Author

Shan, Liping, Oduor, Ayub M. O., and Liu, Yanjie

Subjects

*INVASIVE plants, *NATIVE plants, *ATMOSPHERIC carbon dioxide, *PLANT species, *PLANT invasions, *BIOMASS production, *GRAZING

Abstract

Large parts of the Earth are experiencing environmental change caused by alien plant invasions, rising atmospheric concentration of carbon dioxide (CO2), and nutrient enrichments. Elevated CO2 and nutrient concentrations can separately favour growth of invasive plants over that of natives but how herbivory may modulate the magnitude and direction of net responses by the two groups of plants to simultaneous CO2 and nutrient enrichments remains unknown. In line with the enemy release hypothesis, invasive plant species should reallocate metabolites from costly anti‐herbivore defences into greater growth following escape from intense herbivory in the native range. Therefore, invasive plants should have greater growth than native plants under simultaneous CO2 and nutrient enrichments in the absence of herbivory. To test this prediction, we grew nine congeneric pairs of invasive and native plant species that naturally co‐occurred in grasslands in China under two levels each of nutrient enrichment (low‐nutrient vs. high‐nutrient), herbivory (with herbivory vs. without herbivory) and under ambient (412.9 ± 0.6 ppm) and elevated (790.1 ± 6.2 ppm) levels of CO2 concentrations in open top chambers in a common garden. Elevated CO2 and nutrient enrichment separately increased total plant biomass, while herbivory reduced it regardless of the plant invasive status. High‐nutrient treatment caused the plants to allocate a significantly lower proportion of total biomass to roots, while herbivory induced an opposite pattern. Herbivory suppressed total biomass production more strongly in native plants than invasive plants. The plants exhibited significant interspecific and intergeneric variation in their responses to the various treatment combinations. Overall, these results suggest that elevated CO2 and nutrients and herbivory may separately, rather than synergistically, impact productivity of the invasive and co‐occurring native plant species in our study system. Moreover, interspecific variation in resource‐use strategies was more important than invasive status in determining plant responses to the various treatment combinations. [ABSTRACT FROM AUTHOR]

Published

2023

3. Directional and stabilizing selection shaped morphological, reproductive, and physiological traits of the invader Solidago canadensis.

Author

Du, Leshan, Oduor, Ayub M. O., Zuo, Wei, Liu, Haiyan, and Li, Jun‐Min

Subjects

*NATURAL selection, *GOLDENRODS, *GENETIC variation, *INVASIVE plants, *PHENOTYPIC plasticity

Abstract

Trait evolution in invasive plant species is important because it can impact demographic parameters key to invasion success. Invasive plant species often show phenotypic clines along geographic and climatic gradients. However, the relative contributions of natural selection and neutral evolutionary processes to phenotypic trait variation among populations of invasive plants remain unclear. A common method to assess whether a trait has been shaped by natural selection or neutral evolutionary processes is to compare the geographical pattern for the trait of interest to the divergence in neutral genetic loci (i.e., QST–FST comparisons). Subsequently, a redundancy analysis (RDA) can facilitate identification of putative agents of natural selection on the trait. Here, we employed both a QST–FST comparisons approach and RDA to infer whether natural selection shaped traits of invasive populations of Solidago canadensis in China and identify the potential environmental drivers of natural selection. We addressed two questions: (1) Did natural selection drive phenotypic trait variation among S. canadensis populations? (2) Did climatic, latitudinal, longitudinal, and altitudinal gradients drive patterns of genetic variation among S. canadensis populations? We found significant directional selection for several morphological and reproductive traits (i.e., QST > FST) and stabilizing selection for physiological traits (i.e., QST < FST). The RDA showed that stem biomass of S. canadensis was strongly positively correlated with longitude, while leaf width ratio and specific leaf area were significantly positively correlated with the mean diurnal range. Stem biomass had a strong negative correlation with annual precipitation. Moreover, height of S. canadensis individuals was strongly positively correlated with altitude and precipitation of the wettest quarter. A longitudinal shift in precipitation seasonality likely selected for larger stem biomass in S. canadensis. Overall, these results suggest that longitudinal and altitudinal clines in climate exerted strong selection pressures that shaped the phenotypic traits of S. canadensis. [ABSTRACT FROM AUTHOR]

Published

2023

4. Older populations of the invader Solidago canadensis exhibit stronger positive plant‐soil feedbacks and competitive ability in China.

Author

Oduor, Ayub M. O., Adomako, Michael Opoku, Yuan, Yongge, and Li, Jun‐Min

Subjects

*GOLDENRODS, *PLANT invasions, *INVASIVE plants, *SOIL microbiology, *SOLANUM nigrum, *TALL buildings

Abstract

Premise: The enemy release hypothesis predicts that release from natural enemies, including soil‐borne pathogens, liberates invasive plants from a negative regulating force. Nevertheless, invasive plants may acquire novel enemies and mutualists in the introduced range, which may cause variable effects on invader growth. However, how soil microorganisms may influence competitive ability of invasive plants along invasion chronosequences has been little explored. Methods: Using the invasive plant Solidago canadensis, we tested whether longer residence times are associated with stronger negative plant‐soil feedbacks and thus weaker competitive abilities at the individual level. We grew S. canadensis individuals from 36 populations with different residence times across southeastern China in competition versus no competition and in three different types of soils: (1) conspecific rhizospheric soils; (2) soils from uninvaded patches; and (3) sterilized soil. For our competitor treatments, we constructed synthetic communities of four native species (Bidens parviflora, Solanum nigrum, Kalimeris indica, and Mosla scabra), which naturally co‐occur with Solidago canadensis in the field. Results: Solidago canadensis populations with longer residence times experienced stronger positive plant‐soil feedbacks and had greater competitive responses (i.e., produced greater above‐ground biomass and grew taller) in conspecific rhizospheric soils than in sterilized or uninvaded soils. Moreover, S. canadensis from older populations significantly suppressed above‐ground biomass of the native communities in rhizospheric and uninvaded soils but not in sterilized soil. Conclusions: The present results suggest that older populations of S. canadensis experience stronger positive plant‐soil feedbacks, which may enhance their competitive ability against native plant communities. [ABSTRACT FROM AUTHOR]

Published

2022

5. Can polyploidy confer invasive plants with a wider climatic tolerance? A test using Solidago canadensis.

Author

Wan, Jizhong, Oduor, Ayub M. O., Pouteau, Robin, Wang, Beilei, Chen, Luxi, Yang, Beifen, Yu, Feihai, and Li, Junmin

Subjects

*POLYPLOIDY, *INVASIVE plants, *ARID regions, *GOLDENRODS, *PHYLOGEOGRAPHY, *PLANT variation, *CLIMATIC zones, *HORDEUM

Abstract

Polyploidy can cause variation in plant functional traits and thereby generate individuals that can adapt to fluctuating environments and exploit new environments. However, few empirical studies have tested for an association between ploidy level and climatic tolerance of invasive cytotypes relative to conspecific native‐range cytotypes. Here, we used an invasive plant Solidago canadensis to test whether invasive populations had a higher proportion of polyploids, greater height and stem‐base diameter, and occupied a wider range of climatic conditions than conspecific native‐range populations. We also tested whether the invasive populations had overcome genetic founder effects. We sampled a total of 80 populations in parts of the invaded range in China and native range in North America for in situ measurements of plant height and stem‐base diameter in the field and for population genetic and cytotype analyses. To examine climatic correlates, we augmented our field‐sampled data with occurrence records obtained from Global Biodiversity Information Facility. All, except one, of the populations that we sampled in China occurred in a humid subtropical climate. In contrast, the North American populations occurred in humid continental, humid subtropical, and semi‐arid climatic zones. All populations of S. canadensis in China were purely hexaploid, while the North American populations were diploid, tetraploid, and hexaploid. The invasive hexaploids were significantly taller and had a larger stem‐base diameter than native hexaploids. Native hexaploids were significantly taller and had larger stem‐base diameter than native diploids. Climatic correlate assessment found that invasive and native populations occupied different climatic envelopes, with invasive populations occurring in warmer and less seasonal climates than native populations. However, there was no significant correlation between ploidy level and climatic envelope of S. canadensis. Molecular phylogeography data suggest reduced genetic founder effects in the invaded range. Overall, these results suggest that polyploidy does not influence S. canadensis climatic tolerance. [ABSTRACT FROM AUTHOR]

Published

2020