Ruohang Xu’s research while affiliated with Tarim University and other places

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Publications (3)


Differences in Physiological and Agronomic Traits and Evaluation of Adaptation of Seven Maize Varieties
  • Article
  • Full-text available

November 2024

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13 Reads

Biology

Shuqi Ding

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Dan Zhang

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Ying Hao

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[...]

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Wentao Du

To better understand the growth adaptability of various maize varieties to the climate of the Alar region in Southern Xinjiang Province, an experiment was conducted using seven distinct maize varieties as test materials. A one-way randomized block design was applied to both experimental groups. In 2021 and 2022, a total of 19 indicators were observed for comparative analysis, including antioxidant enzyme activities and agronomic traits. Principal component analysis and cluster analysis were used to evaluate the adaptability of the maize varieties. The findings revealed that: (1) All seven maize varieties exhibited robust growth, with notable differences in their respective trait profiles. Specifically, the yield traits of Jin’ai 588 and Denghai 3672 showed relatively consistent performance over the two-year period. (2) Five principal components (100-kernel weight, bald tip length, catalase (CAT), number of leaves, and angle of leaf pinch at the ear) were extracted from the 19 traits via principal component analysis, with a cumulative contribution rate of 84.689%. This represented the majority of the information regarding the seven maize varieties. After calculating the comprehensive index F value, the results indicated that Xinyu 66 and Denghai 3672 had high composite scores, suggesting high production potential and suitability for cultivation in this region. Conversely, Xinyu 24 showed the lowest composite score, indicating that it is not suitable for planting in this area. (3) Ultimately, the seven maize varieties were categorized into three groups through cluster analysis; this is the same as the result of principal component analysis. This classification provides a reference for the promotion and utilization of different varieties in the southern border region and aims to optimize the comprehensive trait selection of the varieties studied.

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General flow of testing and analysis.
Morphology of maize plants under NaHCO3 preconcentration screening. CK, 20, 40, 60, 80, 100 denote concentrations of 0, 20, 40, 60, 80, 100 mM NaHCO3, respectively; Z1, Z2, Z3, Z4, Z5, Z6 are the varieties, and specific names are provided in Table S1.
Correlation analysis of individual indices at the maize seedling stage under alkali stress. **Represents a very significant correlation (p < 0.01); *Represents a significant correlation (p < 0.05).
Plant morphology under alkali stress in selected maize varieties. Figures (A) and (B) depict Gan Xin 2818 and Ken Yu 90 maize plants under control (left) and alkali stress (right), respectively. Figure (C) shows maize root morphology under alkali stress, and Figure (D) shows maize leaf morphology under the same conditions.
Cluster analysis of maize alkali tolerance based on alkali tolerance‐related indices. Clusters I, II, III, and IV denote highly alkali‐tolerant, alkali‐tolerant, weakly alkali‐tolerant, and alkali‐sensitive germplasms, respectively.

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Sodium Bicarbonate Tolerance During Seedling Stages of Maize (Zea mays L.) Lines

October 2024

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37 Reads

1) Soil alkalinization and salinization represent a growing global challenge. Maize (Zea mays L.), with its relatively low tolerance to salt and alkali, is increasingly vulnerable to saline‐alkali stress. Identifying maize genotypes that can withstand salinity and alkalinity is crucial to broaden the base of salt‐alkali‐tolerant maize germplasm. (2) In this study, we screened 65 maize germplasm resources for alkali stress using a 60 mM NaHCO3 solution. We measured fifteen morphological and physiological indices, including seedling height, stem thickness, and leaf area. Various analytical methods—correlation analysis, principal component analysis, subordinate function analysis, cluster analysis, stepwise discriminant analysis, and ridge regression analysis—were used to assess the seedling alkali tolerance of these maize germplasm resources. The physiological indices of six tested maize varieties were analyzed in greater detail. (3) The findings revealed complex correlations among traits, particularly strong negative associations between conductivity and root traits such as length, volume, surface area, diameter, and number of branches. The 15 evaluation indices were reduced to 7 principal components, explaining 77.89% of the variance. By applying affiliation functions and weights, we derived a comprehensive evaluation of maize seedling alkali tolerance. Notably, three germplasms—Liang Yu 99, Bi Xiang 638, and Gan Xin 2818—demonstrated significant comprehensive seedling alkali tolerance. Cluster analysis grouped the 65 maize germplasm resources into four distinct categories (I, II, III, and IV). The results of the cluster analysis were confirmed by multiclass stepwise discriminant analysis, which achieved a correct classification rate of 92.3% for 60 maize genotypes regarding alkalinity tolerance. Using principal component and ridge regression analyses, we formulated a regression equation for alkali tolerance: D‐value = −1.369 + 0.002 * relative root volume + 0.003 * relative number of root forks + 0.006 * relative chlorophyll SPAD + 0.005 * relative stem thickness + 0.005 * relative plant height + 0.001 * relative conductivity + 0.002 * relative dry weight of underground parts. Under sodium bicarbonate stress, morphological indices and germination rates were significantly reduced, germination was inhibited, photosynthetic pigment levels in maize leaves decreased to varying degrees, and the activities of peroxidase (POD), superoxide dismutase (SOD), and catalase (CAT) significantly increased. Alkali stress markedly enhanced the antioxidant enzyme activities in maize varieties, with alkali‐resistant varieties exhibiting a greater increase in antioxidant enzyme activities than alkali‐sensitive varieties under such stress. (4) By screening for alkali tolerance in maize seedlings, the identified alkali‐tolerant genotypes can be further utilized as suitable donor parents, thereby enhancing the use of alkali‐tolerant germplasm resources and providing theoretical guidance for maize cultivation in saline‐alkaline environments.


Comprehensive Evaluation and Selection of 192 Maize Accessions from Different Sources

May 2024

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50 Reads

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3 Citations

Plants

In the period 2022–2023, an analysis of fourteen phenotypic traits was conducted across 192 maize accessions in the Aral region of Xinjiang. The Shannon–Wiener diversity index was employed to quantify the phenotypic diversity among the accessions. Subsequently, a comprehensive evaluation of the index was performed utilizing correlation analysis, principal component analysis (PCA) and cluster analysis. The results highlighted significant findings: (1) A pronounced diversity was evident across the 192 maize accessions, accompanied by complex interrelationships among the traits. (2) The 14 phenotypic traits were transformed into 3 independent indicators through principal component analysis: spike factor, leaf width factor, and number of spikes per plant. (3) The 192 materials were divided into three groups using cluster analysis. The phenotypes in Group III exhibited the best performance, followed by those in Group I, and finally Group II. The selection of the three groups can vary depending on the breeding objectives. This study analysed the diversity of phenotypic traits in maize germplasm resources. Maize germplasm was categorised based on similar phenotypes. These findings provide theoretical insights for the study of maize accessions under analogous climatic conditions in Alar City, which lay the groundwork for the efficient utilization of existing germplasm as well as the development and selection of new varieties.

Citations (1)


... Varieties in the region often show instability in agronomic and genetic traits, and there is a pronounced lack of high-quality, multi-resistant, and broadly adaptable varieties. Additionally, the genetic base of available germplasm resources is narrow, with limited diversity, which restricts the genetic foundation essential for both research and breeding [71]. The effective evaluation of germplasm resources is critical for advancing germplasm innovation and developing new varieties, as comprehensive assessments form a key step in improving the existing varieties [72]. ...

Reference:

Differences in Physiological and Agronomic Traits and Evaluation of Adaptation of Seven Maize Varieties
Comprehensive Evaluation and Selection of 192 Maize Accessions from Different Sources

Plants