| Literature DB >> 28379423 |
Qianqian Guo1, Matthew Hamish Turnbull1, Jiancheng Song1,2, Jessica Roche1, Ondrej Novak3, Jana Späth4, Paula Elizabeth Jameson1, Jonathan Love1.
Abstract
The mechanisms linking C/N balance toEntities:
Keywords: Carbohydrate; Lolium perenne; carbon; cytokinin; fructan; nitrate transporter (NRT); nitrate uptake; nitrogen; nitrogen use efficiency (NUE); perennial ryegrass.
Mesh:
Substances:
Year: 2017 PMID: 28379423 PMCID: PMC5444434 DOI: 10.1093/jxb/erx056
Source DB: PubMed Journal: J Exp Bot ISSN: 0022-0957 Impact factor: 6.992
Fig. 1.Growth parameters 48 h after defoliation of plants grown under low (0.05 mM) or high (5 mM) nitrate supply (LN versus HN). (A, B) Nitrogen (N) content before and 48 h after defoliation; (C) regrowth rate; (D) biomass 48 h after defoliation. Values in (A), (B), and (D) are means ±SE (n=5 pools of five plants each). Values in (C) are means ±SE (n=36 plants). Means were tested for significance using a two-tailed t-test. Asterisks denote significantly different means between LN plants (grey bars) and HN plants (black bars) at ***P<0.001.
Fig. 2.Abundance in carbon (C) units of water-soluble carbohydrates (WSCs). WSCs were measured in plants grown under high (HN) and low nitrate (LN) supply, 1 h and 48 h after defoliation. Relative abundance in C units was calculated by multiplying peak intensity by degree of polymerization (DP). WSCs with a DP from three to eight are referred to here as low molecular weight (LMW) WSCs, and DP9 to DP20 are referred to as high molecular weight (HMW) WSCs. The total concentrations of LMW and HMW WSCs are shown in (A) leaf sheaths and (B) roots after 1 h; (C) leaf sheaths and (D) roots after 48 h. Values are means ±SE (n=5 pools of five plants each). Means were tested for significance using a two-tailed t-test. Asterisks denote significantly different means between intact plants (grey) and defoliated plants (black) (*P<0.05, **P<0.01, ***P<0.001).
Fig. 3.The impact of defoliation on NO3– uptake in L. perenne. In order to investigate HATS and LATS uptake capacity, plants were grown under low NO3– (LN: 0.05 mM) or high NO3– (HN: 5 mM), and then defoliated (or left intact). Plants were then exposed for 1 h to either 0.05 mM or 5 mM 15N-labelled NO3– either immediately after defoliation or 48 h after defoliation. During the period of 15N labelling, the NO3– uptake rate was measured. Values are means ±SE (n=5 pools of five plants each). Means were tested for significance using a two-tailed t-test. Asterisks denote significantly different means between intact plants (grey bars) and defoliated plants (black bars) (*P<0.05, **P<0.01, ***P<0.001).
Fig. 4.Expression of putative low- and high-affinity (LpNRT1, LpNRT2, and LpNAR) NO3– transporter genes in roots of L.perenne. Plants were grown at either 0.05 mM (LN) or 5 mM (HN) NO3–, and then defoliated (or left intact). The expression level of LpNRT2.1b in HN roots is shown in the inserted bar graph in (B). Each data point is normalized against the reference genes eEF-1α and GAPDH. Values are means ±SE (n=3 pools of five plants each). Means were tested for significance using a two-tailed t-test. An asterisk denotes significantly different means between intact plants (grey bars) and defoliated plants (black bars) at P<0.05.
Fig. 5.Expression of putative nitrate reductase (LpNR) and nitrite reductase (LpNiR) genes in plants. Plants were grown at either 0.05 mM (LN) or 5 mM (HN) NO3–, and then defoliated (or left intact). Each data point is normalized against the reference genes eEF-1α and GAPDH. Values are means ±SE (n=3 pools of five plants each). Means were tested for significance using a two-tailed t-test. An asterisk denotes significantly different means between intact plants (grey bars) and defoliated plants (black bars) at P<0.05.
Fig. 6.WSC content, NO3– uptake, and Lp1-FEH, LpNRT1.1, and LpNRT2.1b expression in roots with 6 h of supplemental glucose. Plants were grown in HN conditions and supplied with 0.1% or 1% glucose 42 h after defoliation. After 6 h, the impact of supplemental 0.1% or 1% glucose treatment on: (A, B) the relative abundance (in carbon units) of water-soluble carbohydrate (WSC); (C) NO3– uptake rate; and (D–F) Lp1-FEH, LpNRT1.1, and LpNRT2.1 expression in roots. Values are means ±SE (n=5 pools of five plants each). Means were tested for significance using a two-tailed t-test. Asterisks denote significantly different means between mannitol (grey) and glucose (black) treatment (*P<0.05, **P<0.01, ***P<0.001).
Fig. 7.Cytokinin concentrations in high N (HN) roots and leaf sheaths 48 h after defoliation. Values are means ±SE (n=5 pools of five plants each). Asterisks denote significantly different means between intact plants (grey bars) and defoliated plants (black bars), or between defoliated plants (black bars) and defoliated plants supplemented with 1% glucose (white bars) or 1% mannitol (hatched bars) (*P<0.05, **P<0.01, ***P<0.001). Means were tested for significance using a two-tailed t-test.
Fig. 8.The impact of 48 h defoliation on the putative LpCKX and LpRR gene expression. Plants were grown at either 0.05 mM (LN) or 5 mM (HN) NO3-, and then defoliated (or left intact). Each data point is normalized against the reference genes eEF-1α and GAPDH. Values are means ±SE (n=3 pools of five plants each). Means were tested for significance using a two-tailed t-test. Asterisks denote significantly different means between intact plants (grey bars) and defoliated plants (black bars) (*P<0.05, **P<0.01).
Fig. 9.Effects of addition of 1% glucose on putative LpCKX and LpRR gene expression in plants grown in 5 mM NO3–, 48 h after defoliation. Each data point is normalized against the reference genes eEF-1α and GAPDH. Values are means ±SE (n=3 pools of five plants each). Means were tested for significance using a two-tailed t-test. Asterisks denote significantly different means between mannitol (grey bars) and glucose (black bars) treatment (*P<0.05, **P<0.01, ***P<0.001).