The impact of defoliation on nitrogen translocation patterns in the woody invasive plant, Buddleia davidii
Marc M. Thomas A E , Pete Millard B , Michael S. Watt C , Matthew H. Turnbull A , Duane Peltzer D and David Whitehead DA School of Biological Sciences, University of Canterbury, Private Bag 4800, Christchurch, New Zealand.
B Macaulay Institute, Craigiebuckler, Aberdeen AB15 8QH, UK.
C Ensis, PO Box 29237, Christchurch, New Zealand.
D Landcare Research, PO Box 40, Lincoln 7640, New Zealand.
E Corresponding author. Email: marc-merlin.thomas@gmx.de
F This paper originates from a presentation at EcoFIZZ 2007, Richmond, New South Wales, Australia, September 2007.
Functional Plant Biology 35(6) 462-469 https://doi.org/10.1071/FP08112
Submitted: 7 April 2008 Accepted: 17 June 2008 Published: 4 August 2008
Abstract
The influence of defoliation on nitrogen (N) re-translocation and the source for N remobilisation by the invasive shrub, Buddleia davidii Franch. (buddleia) was determined. Eighty plants were grown over two growing seasons, and half were repeatedly defoliated by removing 66% of their leaf area. During the second season, the N supply was labelled with 15N (10 atom% enrichment), to distinguish the use of stored N (unlabelled) from N taken up by roots (labelled) for growth. Defoliation significantly decreased root (39%) and total biomass (26%). Old leaves were the main source of N for remobilisation which was accelerated and increased (by 50% in the second season) in response to defoliation. In spring, root uptake of N increased by 57% in defoliated plants. Thus, defoliation induced changes in N remobilisation and uptake as compensatory growth increased the demand for N. Continued leaf removal decreased the pool of stored N and caused a significant decline in biomass production, especially in roots (39%) and flowers (31%). This has important implications for the efficacy of defoliation as a control measure, as smaller roots suggest a reduced capacity for uptake of nutrients from the soil and reduced flower production may assist in reducing the invasive spread of the species. These findings clearly show that, although the success of B. davidii is associated, in part, with efficient remobilisation of N from storage, this advantage can be overcome by continued defoliation.
Additional keywords: compensation, invasive shrub, 15N, remobilisation, semi-deciduous, uptake.
Acknowledgements
This research was funded by the Foundation for Research, Science and Technology under Contract No. C04X0202. We thank the University of Canterbury for granting a Doctoral Scholarship to MMT.
Bellingham P,
Peltzer D, Walker L
(2005) Contrasting impacts of a native and an invasive exotic shrub on floodplain succession. Journal of Vegetation Science 16, 135–142.
| Crossref | GoogleScholarGoogle Scholar |
[verified 25 June 2008]
Frak E,
Millard P,
Le Roux X,
Guillaumie S, Wendler R
(2002) Coupling sap flow velocity and amino acid concentrations as an alternative method to N-15 labeling for quantifying nitrogen remobilization by walnut trees. Plant Physiology 130, 1043–1053.
| Crossref | GoogleScholarGoogle Scholar | PubMed |
Grelet GA,
Alexander IJ,
Millard P, Proe MF
(2003) Does morphology or the size of the internal nitrogen store determine how Vaccinium spp. respond to spring nitrogen supply? Functional Ecology 17, 690–699.
| Crossref | GoogleScholarGoogle Scholar |
Hester AJ,
Millard P,
Baillie GJ, Wendler R
(2004) How does timing of browsing affect above- and below-ground growth of Betula pendula, Pinus sylvestris and Sorbus aucuparia? Oikos 105, 536–550.
| Crossref | GoogleScholarGoogle Scholar |
Hulme PE
(2008) Phenotypic plasticity and plant invasions: is it all Jack? Functional Ecology 22, 3–7.
Humphries RN, Guarino L
(1987) Soil nitrogen and the growth of birch and buddleia in abandoned chalk quarries. Reclamation & Revegetation Research 6, 55–61.
Jonasson S
(1995) Resource allocation in relation to leaf retention time of the wintergreen Rhododendron lapponicum. Ecology 76, 475–485.
| Crossref | GoogleScholarGoogle Scholar |
Kim TH,
Ourry A,
Boucaud J, Lemaire G
(1991) Changes in source-sink relationship for nitrogen during regrowth of lucerne (Medicago sativa L.) following removal of shoots. Australian Journal of Plant Physiology 18, 593–602.
Legaz F,
Serna MD, Primomillo E
(1995) Mobilization of the reserve N in Citrus. Plant and Soil 173, 205–210.
| Crossref | GoogleScholarGoogle Scholar |
Malaguti D,
Millard P,
Wendler R,
Hepburn A, Tagliavini M
(2001) Translocation of amino acids in the xylem of apple (Malus domestica Borkh.) trees in spring as a consequence of both N remobilization and root uptake. Journal of Experimental Botany 52, 1665–1671.
| Crossref | GoogleScholarGoogle Scholar | PubMed |
Millard P
(1994) Measurement of the remobilization of nitrogen for spring leaf growth of trees under field conditions. Tree Physiology 14, 1049–1054.
| PubMed |
Millard P
(1996) Ecophysiology of the internal cycling of nitrogen for tree growth. Zeitschrift Fur Pflanzenernahrung Und Bodenkunde 159, 1–10.
Millard P, Neilsen GH
(1989) The influence of nitrogen supply on the uptake and remobilization of stored N for the seasonal growth of apple-trees. Annals of Botany 63, 301–309.
Millard P, Proe MF
(1991) Leaf demography and the seasonal internal cycling of nitrogen in sycamore (Acer pseudoplatanus L.) seedlings in relation to nitrogen supply. New Phytologist 117, 587–596.
| Crossref | GoogleScholarGoogle Scholar |
Millard P, Proe MF
(1993) Nitrogen uptake, partitioning and internal cycling in Picea sitchensis (Bong) Carr as influenced by nitrogen supply. New Phytologist 125, 113–119.
| Crossref | GoogleScholarGoogle Scholar |
Millard P,
Hester A,
Wendler R, Baillie G
(2001) Interspecific defoliation responses of trees depend on sites of winter nitrogen storage. Functional Ecology 15, 535–543.
| Crossref | GoogleScholarGoogle Scholar |
Millard P,
Wendler R,
Grassi G,
Grelet GA, Tagliavini M
(2006) Translocation of nitrogen in the xylem of field-grown cherry and poplar trees during remobilization. Tree Physiology 26, 527–536.
| PubMed |
Molvar EM,
Bowyer RT, Vanballenberghe V
(1993) Moose herbivory, browse quality and nutrient cycling in an Alaskan treeline community. Oecologia 94, 472–479.
| Crossref | GoogleScholarGoogle Scholar |
Nambiar E, Fife D
(1987) Growth and nutrients retranslocation in needles of radiata pine in relation to nitrogen supply. Annals of Botany 60, 147–156.
Raillard MC, Svoboda J
(1999) Exact growth and increased nitrogen compensation by the Arctic sedge Carex aquatilis var. stans after simulated grazing. Arctic, Antarctic, and Alpine Research 31, 21–26.
| Crossref | GoogleScholarGoogle Scholar |
Salifu KF, Timmer VR
(2003) Nitrogen retranslocation response of young Picea mariana to nitrogen-15 supply. Soil Science Society of America Journal 67, 309–317.
Sheppard AW,
Shaw RH, Sforza R
(2006) Top 20 environmental weeds for classical biological control in Europe: a review of opportunities, regulations and other barriers to adoption. Weed Research 46, 93–117.
| Crossref | GoogleScholarGoogle Scholar |
Stephens DW,
Millard P,
Turnbull MH, Whitehead D
(2001) The influence of nitrogen supply on growth and internal recycling of nitrogen in young Nothofagus fusca trees. Australian Journal of Plant Physiology 28, 249–255.
Tagliavini M,
Millard P,
Quartieri M, Marangoni B
(1999) Timing of nitrogen uptake affects winter storage and spring remobilisation of nitrogen in nectarine (Prunus persica var. nectarina) trees. Plant and Soil 211, 149–153.
| Crossref | GoogleScholarGoogle Scholar |
Thomas MM,
Watt MS,
Whitehead D,
Turnbull MH, Peltzer D
(2008) The impact of defoliation on seasonal leaf area dynamics and leaf longevity in Buddleia davidii Franch. Weed Research in press. ,
Watt MS,
Whitehead D,
Kriticos DJ,
Gous SF, Richardson B
(2007) Using a process-based model to analyse compensatory growth in response to defoliation: simulating herbivory by a biological control agent. Biological Control 43, 119–129.
| Crossref | GoogleScholarGoogle Scholar |
Weinbaum S, Van Kessel C
(1998) Quantitative estimates of uptake and internal cycling of 14N-labeled fertilizer in mature walnut trees. Tree Physiology 18, 795–801.
| PubMed |
Wendler R, Millard P
(1996) Impacts of water and nitrogen supplies on the physiology, leaf demography and nitrogen dynamics of Betula pendula. Tree Physiology 16, 153–159.
| PubMed |
Wendler R,
Carvalho PO,
Pereira JS, Millard P
(1995) Role of nitrogen remobilization from old leaves for new leaf growth of Eucalyptus globulus seedlings. Tree Physiology 15, 679–683.
| PubMed |