236 related articles for article (PubMed ID: 29756639)
1. The carboxylate-releasing phosphorus-mobilizing strategy can be proxied by foliar manganese concentration in a large set of chickpea germplasm under low phosphorus supply.
Pang J; Bansal R; Zhao H; Bohuon E; Lambers H; Ryan MH; Ranathunge K; Siddique KHM
New Phytol; 2018 Jul; 219(2):518-529. PubMed ID: 29756639
[TBL] [Abstract][Full Text] [Related]
2. Leaf transpiration plays a role in phosphorus acquisition among a large set of chickpea genotypes.
Pang J; Zhao H; Bansal R; Bohuon E; Lambers H; Ryan MH; Siddique KHM
Plant Cell Environ; 2018 Sep; 41(9):2069-2079. PubMed ID: 29315636
[TBL] [Abstract][Full Text] [Related]
3. Carboxylate concentrations in the rhizosphere of lateral roots of chickpea (Cicer arietinum) increase during plant development, but are not correlated with phosphorus status of soil or plants.
Wouterlood M; Cawthray GR; Scanlon TT; Lambers H; Veneklaas EJ
New Phytol; 2004 Jun; 162(3):745-753. PubMed ID: 33873771
[TBL] [Abstract][Full Text] [Related]
4. Plant phosphorus status has a limited influence on the concentration of phosphorus-mobilising carboxylates in the rhizosphere of chickpea.
Wouterlood M; Lambers H; Veneklaas EJ
Funct Plant Biol; 2005 Apr; 32(2):153-159. PubMed ID: 32689119
[TBL] [Abstract][Full Text] [Related]
5. Rhizosphere carboxylate concentrations of chickpea are affected by soil bulk density.
Wouterlood M; Lambers H; Veneklaas EJ
Plant Biol (Stuttg); 2006 Mar; 8(2):198-203. PubMed ID: 16547864
[TBL] [Abstract][Full Text] [Related]
6. Interactive effects of phosphorus and Pseudomonas putida on chickpea (Cicer arietinum L.) growth, nutrient uptake, antioxidant enzymes and organic acids exudation.
Israr D; Mustafa G; Khan KS; Shahzad M; Ahmad N; Masood S
Plant Physiol Biochem; 2016 Nov; 108():304-312. PubMed ID: 27485620
[TBL] [Abstract][Full Text] [Related]
7. Root carboxylate exudation capacity under phosphorus stress does not improve grain yield in green gram.
Pandey R; Meena SK; Krishnapriya V; Ahmad A; Kishora N
Plant Cell Rep; 2014 Jun; 33(6):919-28. PubMed ID: 24493254
[TBL] [Abstract][Full Text] [Related]
8. Leaf manganese accumulation and phosphorus-acquisition efficiency.
Lambers H; Hayes PE; Laliberté E; Oliveira RS; Turner BL
Trends Plant Sci; 2015 Feb; 20(2):83-90. PubMed ID: 25466977
[TBL] [Abstract][Full Text] [Related]
9. Carboxylate composition of root exudates does not relate consistently to a crop species' ability to use phosphorus from aluminium, iron or calcium phosphate sources.
Pearse SJ; Veneklaas EJ; Cawthray G; Bolland MD; Lambers H
New Phytol; 2007; 173(1):181-90. PubMed ID: 17176404
[TBL] [Abstract][Full Text] [Related]
10. Sex-specific strategies of phosphorus (P) acquisition in Populus cathayana as affected by soil P availability and distribution.
Xia Z; He Y; Yu L; Lv R; Korpelainen H; Li C
New Phytol; 2020 Jan; 225(2):782-792. PubMed ID: 31487045
[TBL] [Abstract][Full Text] [Related]
11. Mobilization and acquisition of sparingly soluble P-Sources by Brassica cultivars under P-starved environment II. Rhizospheric pH changes, redesigned root architecture and pi-uptake kinetics.
Akhtar MS; Oki Y; Adachi T
J Integr Plant Biol; 2009 Nov; 51(11):1024-39. PubMed ID: 19903224
[TBL] [Abstract][Full Text] [Related]
12. Moderating mycorrhizas: arbuscular mycorrhizas modify rhizosphere chemistry and maintain plant phosphorus status within narrow boundaries.
Nazeri NK; Lambers H; Tibbett M; Ryan MH
Plant Cell Environ; 2014 Apr; 37(4):911-21. PubMed ID: 24112081
[TBL] [Abstract][Full Text] [Related]
13. Enhanced nodulation and phosphorus acquisition from sparingly-soluble iron phosphate upon treatment with arbuscular mycorrhizal fungi in chickpea.
Pang J; Ryan MH; Wen Z; Lambers H; Liu Y; Zhang Y; Tueux G; Jenkins S; Mickan B; Wong WS; Yong JWH; Siddique KHM
Physiol Plant; 2023 Mar; 175(2):e13873. PubMed ID: 36762694
[TBL] [Abstract][Full Text] [Related]
14. Peppermint trees shift their phosphorus-acquisition strategy along a strong gradient of plant-available phosphorus by increasing their transpiration at very low phosphorus availability.
Huang G; Hayes PE; Ryan MH; Pang J; Lambers H
Oecologia; 2017 Nov; 185(3):387-400. PubMed ID: 28924626
[TBL] [Abstract][Full Text] [Related]
15. Tradeoffs among root morphology, exudation and mycorrhizal symbioses for phosphorus-acquisition strategies of 16 crop species.
Wen Z; Li H; Shen Q; Tang X; Xiong C; Li H; Pang J; Ryan MH; Lambers H; Shen J
New Phytol; 2019 Jul; 223(2):882-895. PubMed ID: 30932187
[TBL] [Abstract][Full Text] [Related]
16. Association mapping of magnesium and manganese concentrations in the seeds of C. arietinum and C. reticulatum.
Karaca N; Ates D; Nemli S; Ozkuru E; Yilmaz H; Yagmur B; Kartal C; Tosun M; Ocak OO; Otles S; Kahriman A; Tanyolac MB
Genomics; 2020 Mar; 112(2):1633-1642. PubMed ID: 31669504
[TBL] [Abstract][Full Text] [Related]
17. Acid phosphatase role in chickpea/maize intercropping.
Li SM; Li L; Zhang FS; Tang C
Ann Bot; 2004 Aug; 94(2):297-303. PubMed ID: 15238349
[TBL] [Abstract][Full Text] [Related]
18. Microbial consortium inoculant increases pasture grasses yield in low-phosphorus soil by influencing root morphology, rhizosphere carboxylate exudation and mycorrhizal colonisation.
Tshewang S; Rengel Z; Siddique KH; Solaiman ZM
J Sci Food Agric; 2022 Jan; 102(2):540-549. PubMed ID: 34146349
[TBL] [Abstract][Full Text] [Related]
19. Convergence of a specialized root trait in plants from nutrient-impoverished soils: phosphorus-acquisition strategy in a nonmycorrhizal cactus.
Abrahão A; Lambers H; Sawaya AC; Mazzafera P; Oliveira RS
Oecologia; 2014 Oct; 176(2):345-55. PubMed ID: 25135179
[TBL] [Abstract][Full Text] [Related]
20. Adaptive shoot and root responses collectively enhance growth at optimum temperature and limited phosphorus supply of three herbaceous legume species.
Suriyagoda LD; Ryan MH; Renton M; Lambers H
Ann Bot; 2012 Oct; 110(5):959-68. PubMed ID: 22847657
[TBL] [Abstract][Full Text] [Related]
[Next] [New Search]
