Banksia species (Proteaceae) from severely phosphorus-impoverished soils exhibit extreme efficiency in the use and re-mobilization of phosphorus

Banksia species (Proteaceae) occur on some of the most phosphorus (P)-impoverished soils in the world. We hypothesized that Banksia spp. maximize P-use efficiency through high photosynthetic P-use efficiency, long leaf lifespan (P residence time), effective P re-mobilization from senescing leaves, a...

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Published inPlant, cell and environment Vol. 30; no. 12; pp. 1557 - 1565
Main Authors DENTON, MATTHEW D, VENEKLAAS, ERIK J, FREIMOSER, FLORIAN M, LAMBERS, HANS
Format Journal Article
LanguageEnglish
Published Oxford, UK Oxford, UK : Blackwell Publishing Ltd 01.12.2007
Blackwell Publishing Ltd
Blackwell
Subjects
Adaptation, Physiological
Agronomy. Soil science and plant productions
analysis
Banksia
Biological and medical sciences
Economic plant physiology
Ecosystem
field experimentation
fires
Fundamental and applied biological sciences. Psychology
growth & development
interspecific variation
leaves
longevity
metabolism
Mineral nutrition
nutrient
nutrients
Nutrition. Photosynthesis. Respiration. Metabolism
phosphorus
Phosphorus - metabolism
photosynthesis
Photosynthesis - physiology
physiology
Plant Leaves
Plant Leaves - growth & development
Plant Leaves - metabolism
Proteaceae
Proteaceae - growth & development
Proteaceae - metabolism
P‐use efficiency
re‐mobilization
seeds
Seeds - metabolism
soil
Soil - analysis
translocation
Western Australia
Western Australia
Translocation
nutrient
Dicotyledones
banksia
Angiospermae
P-use efficiency
re-mobilization
Proteaceae
Spermatophyta
Photosynthesis
phosphorus
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Abstract Banksia species (Proteaceae) occur on some of the most phosphorus (P)-impoverished soils in the world. We hypothesized that Banksia spp. maximize P-use efficiency through high photosynthetic P-use efficiency, long leaf lifespan (P residence time), effective P re-mobilization from senescing leaves, and maximizing seed P concentration. Field and glasshouse experiments were conducted to quantify P-use efficiency in nine Banksia species. Leaf P concentrations for all species were extremely low (0.14-0.32 mg P g⁻¹ DM) compared with leaf P in other species reported and low relative to other plant nutrients in Banksia spp.; however, moderately high rates of photosynthesis (13.8-21.7 μmol CO₂ m⁻² s⁻¹), were measured. Some of the Banksia spp. had greater P proficiency (i.e. final P concentration in senesced leaves after re-mobilization; range: 27-196 μg P g⁻¹ DM) than values reported for any other species in the literature. Seeds exhibited significantly higher P concentrations (6.6-12.2 mg P g⁻¹ DM) than leaves, and species that sprout after fire ('re-sprouters') had significantly greater seed mass and P content than species that are killed by fire and regenerate from seed ('seeders'). Seeds contained only small amounts of polyphosphate (between 1.3 and 6 μg g⁻¹ DM), and this was not correlated with P concentration or fire response. Based on the evidence in the present study, we conclude that Banksia species are highly efficient in their use of P, explaining, in part, their success on P-impoverished soils, with little variation between species.
AbstractList ABSTRACT Banksia species (Proteaceae) occur on some of the most phosphorus (P)‐impoverished soils in the world. We hypothesized that Banksia spp. maximize P‐use efficiency through high photosynthetic P‐use efficiency, long leaf lifespan (P residence time), effective P re‐mobilization from senescing leaves, and maximizing seed P concentration. Field and glasshouse experiments were conducted to quantify P‐use efficiency in nine Banksia species. Leaf P concentrations for all species were extremely low (0.14–0.32 mg P g−1 DM) compared with leaf P in other species reported and low relative to other plant nutrients in Banksia spp.; however, moderately high rates of photosynthesis (13.8–21.7 µmol CO2 m−2 s−1), were measured. Some of the Banksia spp. had greater P proficiency (i.e. final P concentration in senesced leaves after re‐mobilization; range: 27–196 µg P g−1 DM) than values reported for any other species in the literature. Seeds exhibited significantly higher P concentrations (6.6–12.2 mg P g−1 DM) than leaves, and species that sprout after fire (‘re‐sprouters’) had significantly greater seed mass and P content than species that are killed by fire and regenerate from seed (‘seeders’). Seeds contained only small amounts of polyphosphate (between 1.3 and 6 µg g−1 DM), and this was not correlated with P concentration or fire response. Based on the evidence in the present study, we conclude that Banksia species are highly efficient in their use of P, explaining, in part, their success on P‐impoverished soils, with little variation between species.
Banksia species (Proteaceae) occur on some of the most phosphorus (P)-impoverished soils in the world. We hypothesized that Banksia spp. maximize P-use efficiency through high photosynthetic P-use efficiency, long leaf lifespan (P residence time), effective P re-mobilization from senescing leaves, and maximizing seed P concentration. Field and glasshouse experiments were conducted to quantify P-use efficiency in nine Banksia species. Leaf P concentrations for all species were extremely low (0.14-0.32 mg P g(-1) DM) compared with leaf P in other species reported and low relative to other plant nutrients in Banksia spp.; however, moderately high rates of photosynthesis (13.8-21.7 micromol CO2 m(-2) s(-1)), were measured. Some of the Banksia spp. had greater P proficiency (i.e. final P concentration in senesced leaves after re-mobilization; range: 27-196 microg P g(-1) DM) than values reported for any other species in the literature. Seeds exhibited significantly higher P concentrations (6.6-12.2 mg P g(-1 )DM) than leaves, and species that sprout after fire ('re-sprouters') had significantly greater seed mass and P content than species that are killed by fire and regenerate from seed ('seeders'). Seeds contained only small amounts of polyphosphate (between 1.3 and 6 microg g(-1) DM), and this was not correlated with P concentration or fire response. Based on the evidence in the present study, we conclude that Banksia species are highly efficient in their use of P, explaining, in part, their success on P-impoverished soils, with little variation between species.Banksia species (Proteaceae) occur on some of the most phosphorus (P)-impoverished soils in the world. We hypothesized that Banksia spp. maximize P-use efficiency through high photosynthetic P-use efficiency, long leaf lifespan (P residence time), effective P re-mobilization from senescing leaves, and maximizing seed P concentration. Field and glasshouse experiments were conducted to quantify P-use efficiency in nine Banksia species. Leaf P concentrations for all species were extremely low (0.14-0.32 mg P g(-1) DM) compared with leaf P in other species reported and low relative to other plant nutrients in Banksia spp.; however, moderately high rates of photosynthesis (13.8-21.7 micromol CO2 m(-2) s(-1)), were measured. Some of the Banksia spp. had greater P proficiency (i.e. final P concentration in senesced leaves after re-mobilization; range: 27-196 microg P g(-1) DM) than values reported for any other species in the literature. Seeds exhibited significantly higher P concentrations (6.6-12.2 mg P g(-1 )DM) than leaves, and species that sprout after fire ('re-sprouters') had significantly greater seed mass and P content than species that are killed by fire and regenerate from seed ('seeders'). Seeds contained only small amounts of polyphosphate (between 1.3 and 6 microg g(-1) DM), and this was not correlated with P concentration or fire response. Based on the evidence in the present study, we conclude that Banksia species are highly efficient in their use of P, explaining, in part, their success on P-impoverished soils, with little variation between species.
Banksia species (Proteaceae) occur on some of the most phosphorus (P)-impoverished soils in the world. We hypothesized that Banksia spp. maximize P-use efficiency through high photosynthetic P-use efficiency, long leaf lifespan (P residence time), effective P re-mobilization from senescing leaves, and maximizing seed P concentration. Field and glasshouse experiments were conducted to quantify P-use efficiency in nine Banksia species. Leaf P concentrations for all species were extremely low (0.14-0.32 mg P g(-1) DM) compared with leaf P in other species reported and low relative to other plant nutrients in Banksia spp.; however, moderately high rates of photosynthesis (13.8-21.7 micromol CO2 m(-2) s(-1)), were measured. Some of the Banksia spp. had greater P proficiency (i.e. final P concentration in senesced leaves after re-mobilization; range: 27-196 microg P g(-1) DM) than values reported for any other species in the literature. Seeds exhibited significantly higher P concentrations (6.6-12.2 mg P g(-1 )DM) than leaves, and species that sprout after fire ('re-sprouters') had significantly greater seed mass and P content than species that are killed by fire and regenerate from seed ('seeders'). Seeds contained only small amounts of polyphosphate (between 1.3 and 6 microg g(-1) DM), and this was not correlated with P concentration or fire response. Based on the evidence in the present study, we conclude that Banksia species are highly efficient in their use of P, explaining, in part, their success on P-impoverished soils, with little variation between species.
Banksia species (Proteaceae) occur on some of the most phosphorus (P)‐impoverished soils in the world. We hypothesized that Banksia spp. maximize P‐use efficiency through high photosynthetic P‐use efficiency, long leaf lifespan (P residence time), effective P re‐mobilization from senescing leaves, and maximizing seed P concentration. Field and glasshouse experiments were conducted to quantify P‐use efficiency in nine Banksia species. Leaf P concentrations for all species were extremely low (0.14–0.32 mg P g −1  DM) compared with leaf P in other species reported and low relative to other plant nutrients in Banksia spp.; however, moderately high rates of photosynthesis (13.8–21.7  µ mol CO 2 m −2  s −1 ), were measured. Some of the Banksia spp. had greater P proficiency (i.e. final P concentration in senesced leaves after re‐mobilization; range: 27–196  µ g P g −1  DM) than values reported for any other species in the literature. Seeds exhibited significantly higher P concentrations (6.6–12.2 mg P g −1  DM) than leaves, and species that sprout after fire (‘re‐sprouters’) had significantly greater seed mass and P content than species that are killed by fire and regenerate from seed (‘seeders’). Seeds contained only small amounts of polyphosphate (between 1.3 and 6  µ g g −1  DM), and this was not correlated with P concentration or fire response. Based on the evidence in the present study, we conclude that Banksia species are highly efficient in their use of P, explaining, in part, their success on P‐impoverished soils, with little variation between species.
Banksia species (Proteaceae) occur on some of the most phosphorus (P)-impoverished soils in the world. We hypothesized that Banksia spp. maximize P-use efficiency through high photosynthetic P-use efficiency, long leaf lifespan (P residence time), effective P re-mobilization from senescing leaves, and maximizing seed P concentration. Field and glasshouse experiments were conducted to quantify P-use efficiency in nine Banksia species. Leaf P concentrations for all species were extremely low (0.14-0.32 mg P g⁻¹ DM) compared with leaf P in other species reported and low relative to other plant nutrients in Banksia spp.; however, moderately high rates of photosynthesis (13.8-21.7 μmol CO₂ m⁻² s⁻¹), were measured. Some of the Banksia spp. had greater P proficiency (i.e. final P concentration in senesced leaves after re-mobilization; range: 27-196 μg P g⁻¹ DM) than values reported for any other species in the literature. Seeds exhibited significantly higher P concentrations (6.6-12.2 mg P g⁻¹ DM) than leaves, and species that sprout after fire ('re-sprouters') had significantly greater seed mass and P content than species that are killed by fire and regenerate from seed ('seeders'). Seeds contained only small amounts of polyphosphate (between 1.3 and 6 μg g⁻¹ DM), and this was not correlated with P concentration or fire response. Based on the evidence in the present study, we conclude that Banksia species are highly efficient in their use of P, explaining, in part, their success on P-impoverished soils, with little variation between species.
Author VENEKLAAS, ERIK J
DENTON, MATTHEW D
LAMBERS, HANS
FREIMOSER, FLORIAN M
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  fullname: LAMBERS, HANS
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https://www.ncbi.nlm.nih.gov/pubmed/17944818$$D View this record in MEDLINE/PubMed
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IsPeerReviewed true
IsScholarly true
Issue 12
Keywords Translocation
nutrient
Dicotyledones
banksia
Angiospermae
P-use efficiency
re-mobilization
Proteaceae
Spermatophyta
Photosynthesis
phosphorus
Language English
License http://onlinelibrary.wiley.com/termsAndConditions#vor
CC BY 4.0
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Notes http://dx.doi.org/10.1111/j.1365-3040.2007.01733.x
Present address: Department of Primary Industries, Rutherglen Centre, RMB 1145 Chiltern Valley Road, Rutherglen, Victoria 3685, Australia.
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  doi: 10.1111/j.0269-8463.2005.00967.x
– ident: e_1_2_6_18_1
  doi: 10.1146/annurev.ecolsys.35.112202.130201
– volume: 3
  start-page: 239
  year: 1981
  ident: e_1_2_6_13_1
  article-title: The genus Banksia (Proteaceae)
  publication-title: Nuytsia
  doi: 10.58828/nuy00060
SSID ssj0001479
Score 2.2929254
Snippet Banksia species (Proteaceae) occur on some of the most phosphorus (P)-impoverished soils in the world. We hypothesized that Banksia spp. maximize P-use...
ABSTRACT Banksia species (Proteaceae) occur on some of the most phosphorus (P)‐impoverished soils in the world. We hypothesized that Banksia spp. maximize...
Banksia species (Proteaceae) occur on some of the most phosphorus (P)‐impoverished soils in the world. We hypothesized that Banksia spp. maximize P‐use...
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SubjectTerms Adaptation, Physiological
Agronomy. Soil science and plant productions
analysis
Banksia
Biological and medical sciences
Economic plant physiology
Ecosystem
field experimentation
fires
Fundamental and applied biological sciences. Psychology
growth & development
interspecific variation
leaves
longevity
metabolism
Mineral nutrition
nutrient
nutrients
Nutrition. Photosynthesis. Respiration. Metabolism
phosphorus
Phosphorus - metabolism
photosynthesis
Photosynthesis - physiology
physiology
Plant Leaves
Plant Leaves - growth & development
Plant Leaves - metabolism
Proteaceae
Proteaceae - growth & development
Proteaceae - metabolism
P‐use efficiency
re‐mobilization
seeds
Seeds - metabolism
soil
Soil - analysis
translocation
Western Australia
Title Banksia species (Proteaceae) from severely phosphorus-impoverished soils exhibit extreme efficiency in the use and re-mobilization of phosphorus
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fj.1365-3040.2007.01733.x
https://www.ncbi.nlm.nih.gov/pubmed/17944818
https://www.proquest.com/docview/47498923
https://www.proquest.com/docview/68489087
Volume 30
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