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1. Physiological, biochemical and proteomics analysis reveals the ada.. [490]
2. Comparative Physiological and Proteomic Analyses of Poplar (Populu.. [454]
3. Comparative proteomics exploring the molecular mechanism of eutrop.. [453]
4. 温度对高山植物紫花针茅种子萌发特性的影响 [427]
5. Molecular cloning and characterization of a novel SK3-type dehydri.. [423]
6. Comparing the relationship between seed germination and temperatur.. [411]
7. A novel perspective on seed yield of broad bean (Vicia faba L.): d.. [409]
8. Physiological and Proteomic Adaptation of the Alpine Grass Stipa p.. [378]
9. Molecular cloning and functional analysis of a novel phytoglobin g.. [373]
10. Isolation and Functional Analysis of SpWOX13 from Stipa purpurea [369]
11. Physiological and Proteomics Analyses Reveal the Mechanism of Eich.. [359]
12. Comparative Proteomics Analyses of Kobresia pygmaea Adaptation to .. [343]
13. Cadmium phytoremediation potential of turnip compared with three c.. [343]
14. Genome-Wide Identification and Expression Analysis of the Cation D.. [343]
15. Transcriptome analysis reveals diversified adaptation of Stipa pur.. [340]
16. 霜冻对昆明植物园维管植物危害的调查分析 [332]
17. Enzymatic cyclization of linear peptide to plant cyclopeptide hete.. [326]
18. Selenium Accumulation Characteristics and Biofortification Potenti.. [319]
19. 不同居群紫花针茅响应干旱胁迫的生理和分子差异分析(英文) [317]
20. Overexpression of SpCBL6, a calcineurin B-like protein of Stipa pu.. [314]
21. 丝颖针茅ScTIP1;1基因的克隆及对非生物胁迫的应答 [309]
22. Uncovering the role of a positive selection site of wax ester synt.. [302]
23. A novel Ap2/ERF transcription factor from Stipa purpurea leads to .. [294]
24. Variations in seed characteristics among and within Stipa purpurea.. [288]
25. Cadmium Accumulation Characteristics in Turnip Landraces from Chin.. [278]
26. 高山嵩草和紫花针茅对高山环境的适应性研究——基于生理生化和蛋白质组.. [278]
27. Expression of Stipa purpurea SpCIPK26 in Arabidopsis thaliana Enha.. [266]
28. Comparative Physiological and Proteomic Analysis Reveals the Leaf .. [265]
29. Comparative transcriptome analysis reveals ecological adaption of .. [243]
30. 蛋白质水平解析高山嵩草对青藏高原昼夜环境的响应(英文) [233]
31. Comparative expression analysis of heavy metal ATPase subfamily ge.. [232]
32. Effects of soil properties on accumulation characteristics of copp.. [232]
33. Quantitative NMR Studies of Multiple Compound Mixtures [223]
34. Physiological and biochemical analysis of mechanisms underlying ca.. [221]
35. Proteome response of wild wheat relative Kengyilia thoroldiana to .. [216]
36. Effects of Foliar Selenite on the Nutrient Components of Turnip (B.. [209]
37. Preliminary study on Cd accumulation characteristics in Sansevieri.. [201]
38. 5年研究生期间的问题和收获 [194]
39. Combined transcriptomic, proteomic and biochemical approaches to i.. [188]
40. Activation of secondary cell wall biosynthesis by miR319-targeted .. [160]
41. Characterisation of flower colouration in 30 Rhododendron species .. [156]
42. Fire-prone Rhamnaceae with South African affinities in Cretaceous .. [142]
43. Phytoremediation potential evaluation of three rhubarb species and.. [132]
44. Body color evolution in predators and prey [127]
45. Polyaspartic acid enhances the Cd phytoextraction efficiency of Bi.. [127]
46. 芜菁BrrHMA2.1和BrrHMA2.2基因的克隆与表达 [126]
47. Physiological and rhizospheric response characteristics to cadmium.. [117]
48. Quantitative Succinyl-Proteome Profiling of Turnip (Brassica rapa .. [116]
49. Cd accumulation characteristics of Salvia tiliifolia and changes o.. [111]
50. Comparative transcriptomics analysis reveals differential Cd respo.. [110]
51. Comparative Transcriptomics Analysis of Roots and Leaves under Cd .. [108]
52. Mapping Forest Aboveground Biomass with MODIS and Fengyun-3C VIRR .. [106]
53. 蛋白质水平解析高山嵩草对青藏高原昼夜环境的响应 [104]
54. Comparative proteomics analyses of intraspecific differences in th.. [100]
55. Paraphlomis hsiwenii (Lamiaceae), a new species from the limestone.. [97]
56. Cadmium Accumulation Characteristics of Four Herbs [87]
57. Response strategies of woody seedlings to shading and watering ove.. [86]
58. 不同居群紫花针茅响应干旱胁迫的生理和分子差异分析 [80]
59. Gamma-Aminobutyric Acid Enhances Cadmium Phytoextraction by Coreop.. [71]
60. Paraphlomis caloneura (Lamiaceae), A New Species From Guangxi, Chi.. [71]
61. Distinct rhizobacteria recruitment under copper stress contributes.. [70]
62. Differences in pseudogene evolution contributed to the contrasting.. [58]
63. Rhizospheric microbiomics integrated with plant transcriptomics pr.. [46]
64. Polyaspartic acid enhances the Cd phytoextraction efficiency of Bi.. [33]
65. Rhizospheric Lactobacillus spp. contribute to the high Cd-accumula.. [24]

Downloads

1. Enzymatic cyclization of linear peptide to plant cyclopeptide hete.. [139]
2. Physiological, biochemical and proteomics analysis reveals the ada.. [123]
3. Genome-Wide Identification and Expression Analysis of the Cation D.. [117]
4. 霜冻对昆明植物园维管植物危害的调查分析 [104]
5. Molecular cloning and functional analysis of a novel phytoglobin g.. [99]
6. Comparative Physiological and Proteomic Analyses of Poplar (Populu.. [90]
7. Preliminary study on Cd accumulation characteristics in Sansevieri.. [90]
8. 温度对高山植物紫花针茅种子萌发特性的影响 [87]
9. 丝颖针茅ScTIP1;1基因的克隆及对非生物胁迫的应答 [87]
10. Molecular cloning and characterization of a novel SK3-type dehydri.. [86]
11. Selenium Accumulation Characteristics and Biofortification Potenti.. [84]
12. Physiological and Proteomic Adaptation of the Alpine Grass Stipa p.. [83]
13. Comparative proteomics exploring the molecular mechanism of eutrop.. [83]
14. Isolation and Functional Analysis of SpWOX13 from Stipa purpurea [83]
15. Comparing the relationship between seed germination and temperatur.. [82]
16. Physiological and Proteomics Analyses Reveal the Mechanism of Eich.. [82]
17. Cadmium phytoremediation potential of turnip compared with three c.. [82]
18. Variations in seed characteristics among and within Stipa purpurea.. [81]
19. Quantitative NMR Studies of Multiple Compound Mixtures [81]
20. Comparative Physiological and Proteomic Analysis Reveals the Leaf .. [77]
21. 不同居群紫花针茅响应干旱胁迫的生理和分子差异分析(英文) [73]
22. Uncovering the role of a positive selection site of wax ester synt.. [72]
23. 蛋白质水平解析高山嵩草对青藏高原昼夜环境的响应(英文) [63]
24. Cadmium Accumulation Characteristics in Turnip Landraces from Chin.. [63]
25. Comparative Proteomics Analyses of Kobresia pygmaea Adaptation to .. [62]
26. 5年研究生期间的问题和收获 [59]
27. A novel Ap2/ERF transcription factor from Stipa purpurea leads to .. [58]
28. Effects of Foliar Selenite on the Nutrient Components of Turnip (B.. [58]
29. Proteome response of wild wheat relative Kengyilia thoroldiana to .. [57]
30. Transcriptome analysis reveals diversified adaptation of Stipa pur.. [55]
31. Overexpression of SpCBL6, a calcineurin B-like protein of Stipa pu.. [55]
32. Comparative expression analysis of heavy metal ATPase subfamily ge.. [55]
33. Effects of soil properties on accumulation characteristics of copp.. [54]
34. A novel perspective on seed yield of broad bean (Vicia faba L.): d.. [49]
35. Expression of Stipa purpurea SpCIPK26 in Arabidopsis thaliana Enha.. [45]
36. Comparative transcriptome analysis reveals ecological adaption of .. [44]
37. Comparative Transcriptomics Analysis of Roots and Leaves under Cd .. [41]
38. Body color evolution in predators and prey [40]
39. Polyaspartic acid enhances the Cd phytoextraction efficiency of Bi.. [35]
40. Phytoremediation potential evaluation of three rhubarb species and.. [33]
41. Fire-prone Rhamnaceae with South African affinities in Cretaceous .. [30]
42. Mapping Forest Aboveground Biomass with MODIS and Fengyun-3C VIRR .. [25]
43. Quantitative Succinyl-Proteome Profiling of Turnip (Brassica rapa .. [22]
44. 高山嵩草和紫花针茅对高山环境的适应性研究——基于生理生化和蛋白质组.. [21]
45. Physiological and rhizospheric response characteristics to cadmium.. [20]
46. Paraphlomis hsiwenii (Lamiaceae), a new species from the limestone.. [19]
47. Paraphlomis caloneura (Lamiaceae), A New Species From Guangxi, Chi.. [19]
48. Rhizospheric microbiomics integrated with plant transcriptomics pr.. [19]
49. Response strategies of woody seedlings to shading and watering ove.. [18]
50. Gamma-Aminobutyric Acid Enhances Cadmium Phytoextraction by Coreop.. [15]
51. Differences in pseudogene evolution contributed to the contrasting.. [12]
52. Distinct rhizobacteria recruitment under copper stress contributes.. [10]
53. Polyaspartic acid enhances the Cd phytoextraction efficiency of Bi.. [9]
54. Combined transcriptomic, proteomic and biochemical approaches to i.. [8]
55. Rhizospheric Lactobacillus spp. contribute to the high Cd-accumula.. [7]