Register      Login
Australian Journal of Botany Australian Journal of Botany Society
Southern hemisphere botanical ecosystems
Shopping Cart: ( empty )
You are here: Home > Journals > BT > BT13017
RESEARCH ARTICLE
Contents Vol 61(4)

Season and timing of moisture availability predict composition of montane shrub-dominated wetlands at distributional limits in eastern Australia

John T. Hunter A C and Dorothy M. Bell B
+ Author Affiliations
- Author Affiliations

A School of Behavioural Cognitive and Social Sciences, University of New England, Armidale, NSW 2351, Australia.

B Botany, School of Environmental Sciences and Natural Resources Management, University of New England, Armidale, NSW 2351, Australia.

C Corresponding author. Email: jhunter8@bigpond.com

Australian Journal of Botany 61(4) 243-253 https://doi.org/10.1071/BT13017
Submitted: 22 January 2013  Accepted: 4 March 2013   Published: 18 April 2013

Abstract

We explore the environmental effects on variation in floristic compositional among montane shrub-dominated wetlands at the edge of their geographic distribution within the New England Batholith of eastern Australia. Canonical Correspondence and Redundancy Analyses revealed patterns and gradients in vascular plant species and families of bog communities. Variance partitioning quantified the relative contributions to variation in: (1) species composition; and (2) family composition due to climate, space, and landscape variables. Eleven of the 55 explanatory variables explained 29.2% of the total variance in the species dataset. Climatic factors were overall the best explanatory variables followed by spatial and then landscape characteristics. We found that climate variables were of most importance in determining whether shrub-dominated wetlands will occur at all and also their composition, which is in contrast to results from other studies not conducted at the edge of community distribution. Climate variables associated with seasonality were found to be highly significant correlates of composition as has been found for montane shrub-dominated wetlands in other parts of Australia. The season in which moisture availability becomes critical varies across different rainfall climatic zones. Under current predicated changes in regional climate, it is likely that an increase in variability and seasonality of climate will cause a retraction in the distribution of Australian montane bogs.

Additional keywords: climate change, fire, ordination, seasonality, spatial context, summer-dominant rainfall, variance partitioning.


References

Aerts R, Wallen B, Malmer N, De Caluwe H (2001) Nutritional constraints on Sphagnum-growth and potential decay in northern peatlands. Journal of Ecology 89, 292–299.
Nutritional constraints on Sphagnum-growth and potential decay in northern peatlands.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3MXktVGqu7c%3D&md5=2cf0767d991e2421fa92b1b424b9d028CAS |

Beadle NCW (1981) ‘The vegetation of Australia.’ (Cambridge University Press: Cambridge)

Bell DB, Hunter JT, Haworth RJ (2008) Montane lagoons of the New England Tablelands Bioregion: vegetation, landuse and dynamics. Cunninghamia 10, 475–492.

Benson JB, Ashby EM (2000) Vegetation of the Guyra 1: 100 000 map sheet New England Bioregion, New South Wales. Cunninghamia 6, 747–872.

Benson DB, Baird RC (2012) Vegetation, fauna and groundwater interrelations in low nutrient temperate montane peat swamps in the upper Blue Mountains, New South Wales. Cunninghamia 12, 267–307.
Vegetation, fauna and groundwater interrelations in low nutrient temperate montane peat swamps in the upper Blue Mountains, New South Wales.Crossref | GoogleScholarGoogle Scholar |

Böhning-Gaese K (1997) Determinants of avian species richness at different spatial scales. Journal of Biogeography 24, 49–60.
Determinants of avian species richness at different spatial scales.Crossref | GoogleScholarGoogle Scholar |

Borcard D, Legendre P, Drapeau P (1992) Partialling out the spatial component of ecological variation. Ecology 73, 1045–1055.
Partialling out the spatial component of ecological variation.Crossref | GoogleScholarGoogle Scholar |

Bragazza L, Rydin H, Gerdol R (2005) Multiple gradients in mire vegetation: a comparison of a Swedish and an Italian bog. Plant Ecology 177, 223–236.
Multiple gradients in mire vegetation: a comparison of a Swedish and an Italian bog.Crossref | GoogleScholarGoogle Scholar |

Brose U, Tielbörger K (2005) Subtle differences in environmental stress along a flooding gradient affect the importance of interspecific competition in an annual plant community. Plant Ecology 178, 51–59.
Subtle differences in environmental stress along a flooding gradient affect the importance of interspecific competition in an annual plant community.Crossref | GoogleScholarGoogle Scholar |

Costin AB (1954) ‘A study of the ecosystems of the Monaro Region of New South Wales with special reference to soil erosion.’ (Government Printer: Sydney)

Cowling RM, Lombard AT (2002) Heterogeneity, speciation/extinction history and climate: explaining regional plant diversity patterns in the Cape Floristic Region. Diversity & Distributions 8, 163–179.
Heterogeneity, speciation/extinction history and climate: explaining regional plant diversity patterns in the Cape Floristic Region.Crossref | GoogleScholarGoogle Scholar |

Cowling RM, Ojeda R, Lamont BB, Rundel PW, Lechmere-Oertel R (2005) Rainfall reliability, a neglected factor in explaining convergence and divergence of plant traits in fire-prone Mediterranean-climate ecosystems. Global Ecology and Biogeography 14, 509–519.
Rainfall reliability, a neglected factor in explaining convergence and divergence of plant traits in fire-prone Mediterranean-climate ecosystems.Crossref | GoogleScholarGoogle Scholar |

CRES (2000) ‘ANUCLIM version 5.1.’ (Centre for Resource and Environmental Studies: Canberra)

Croft P, Hofmayer D, Hunter JT (2006) Fire responses in four rare plant species of Gibraltar Range National Park, Northern Tablelands, NSW. Proceedings of the Linnean Society of New South Wales 127, 57–62.

Croft P, Hunter JT, Reid N (2007) Depletion of regenerative bud resources during cyclic drought. What are the implications for fire management? Ecological Management & Restoration 8, 187–192.
Depletion of regenerative bud resources during cyclic drought. What are the implications for fire management?Crossref | GoogleScholarGoogle Scholar |

Division of National Mapping (1986) ‘Atlas of Australian resources. Third Series. Vol. 4: climate.’ (Commonwealth of Australia: Canberra)

El-Kahloun M, Boeye D, Van Haesebroeck V, Verhagen B (2003) Different recovery of above- and below-ground rich fen vegetation following fertilization. Journal of Vegetation Science 14, 451–458.
Different recovery of above- and below-ground rich fen vegetation following fertilization.Crossref | GoogleScholarGoogle Scholar |

Ellis CJ, Tallis JH (2000) Climate control of blanket mire development at Kentra Moss, north-west Scotland. Journal of Ecology 88, 869–889.
Climate control of blanket mire development at Kentra Moss, north-west Scotland.Crossref | GoogleScholarGoogle Scholar |

Gavin DG, Hu FS (2006) Spatial variation of climatic and non-climatic controls on species distribution: the range limit of Tsuga heterophylla. Journal of Biogeography 33, 1384–1396.
Spatial variation of climatic and non-climatic controls on species distribution: the range limit of Tsuga heterophylla.Crossref | GoogleScholarGoogle Scholar |

Gignac LD, Halsey LA, Vitt DH (2000) A bioclimatic model for the distribution of Sphagnum-dominated peatlands in North America under present climatic conditions. Journal of Biogeography 27, 1139–1151.
A bioclimatic model for the distribution of Sphagnum-dominated peatlands in North America under present climatic conditions.Crossref | GoogleScholarGoogle Scholar |

Godwin H (1941) The factors which differentiate marsh, fen, bog and heath. Chronica Botanica 6, 11

Guo Q, Taper M, Schoenberger M, Brandle J (2005) Spatial-temporal population dynamics across species range: from centre to margin. Oikos 108, 47–57.
Spatial-temporal population dynamics across species range: from centre to margin.Crossref | GoogleScholarGoogle Scholar |

Harden GJ (1990–1993) (Ed.) ‘Flora of New South Wales’, Vol. 1–4. (New South Wales University Press: Kensington)

Hennessy K, Page C, McInnes K, Jones R, Bathols A (2004) ‘Climate change in New South Wales. Part 1: past climate variability and projected changes in average climate.’ (CSIRO, Australian Government Bureau of Meteorology: Canberra)

Hilbert DW, Roulet N, Moore T (2000) Modelling and analysis of peatlands as dynamical. Journal of Ecology 88, 230–242.
Modelling and analysis of peatlands as dynamical.Crossref | GoogleScholarGoogle Scholar |

Holt RD, Keitt TH (2005) Species’ borders: a unifying theme in ecology. Oikos 108, 3–6.
Species’ borders: a unifying theme in ecology.Crossref | GoogleScholarGoogle Scholar |

Hope G, Kershaw P (2005) Montane swamps of eastern Australian. Stapfia 85, 412–413.

Houlder D, Hutchinson M, Nix H, McMahon J (2000) ‘ANUCLIM. Version 5.1. User’s guide.’ (Centre for Resource and Environmental Studies, Australian National University: Canberra)

Hughes L (2003) Climate change and Australia: trends, projections and impacts. Austral Ecology 28, 423–443.
Climate change and Australia: trends, projections and impacts.Crossref | GoogleScholarGoogle Scholar |

Hunter JT (2002) How insular are ecological ‘islands’? An example from the granitic outcrops of the New England Batholith of Australia. Proceedings of the Royal Society of Queensland 110, 1–13.

Hunter JT (2003) Persistence on inselbergs: the role of obligate seeders and resprouters. Journal of Biogeography 30, 497–510.
Persistence on inselbergs: the role of obligate seeders and resprouters.Crossref | GoogleScholarGoogle Scholar |

Hunter JT (2005) Geographic variation in plant species richness patterns within temperate eucalypt woodlands of eastern Australia. Ecography 28, 505–514.
Geographic variation in plant species richness patterns within temperate eucalypt woodlands of eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Hunter JT, Bell D (2007) The vegetation of montane bogs in eastern flowing catchments of the New England Batholith, New South Wales. Cunninghamia 10, 77–82.

Hunter JT, Bell D (2009) The Carex fen vegetation of northern New South Wales. Cunninghamia 11, 49–65.

Ingram HAP (1983) Hydrology. In ‘Ecosystems of the world 4A. Mires: swamp, bog, fen and moor. General studies’. (Ed. AJP Gore) pp. 67–158. (Elsevier Scientific Publishers: New York)

Jarman SJ, Kantvilas G, Brown MJ (1988) Buttongrass Moorland in Tasmania. Research Report No. 2. Tasmanian Forest Research Council Inc., Hobart.

Keith D (2004) ‘Ocean shores to desert dunes.’ (New South Wales Government: Sydney)

Lamont BB, Markey A (1995) Biogeography of fire-killed and resprouting Banksia species in south-western Australia. Australian Journal of Botany 43, 283–303.
Biogeography of fire-killed and resprouting Banksia species in south-western Australia.Crossref | GoogleScholarGoogle Scholar |

Leps J, Smilauer P (2003) ‘Multivariate analysis of ecological data using CANOCO.’ (Cambridge University Press: Cambridge)

Millington RJ (1954) Sphagnum bogs of the New England Plateau, New South Wales. Journal of Ecology 42, 328–344.
Sphagnum bogs of the New England Plateau, New South Wales.Crossref | GoogleScholarGoogle Scholar |

Mitchell EAD, Buttler A Grosvernier P, Rydin H, Siegenthaler A, Gobat JM (2002) Contrasting effects of increased N and CO2 supply on two keystone species in peatland restoration and implications for global change. Journal of Ecology 90, 529–533.
Contrasting effects of increased N and CO2 supply on two keystone species in peatland restoration and implications for global change.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD38Xlt1yrtL4%3D&md5=d1dfaab87a91e8c7390e16d66c123f1bCAS |

Nakamura T, Uemura S, Yabe K (2002) Hydrochemical regime of fen and bog in north Japanese mires as an influence on habitat and above-ground biomass of Carex species. Journal of Ecology 90, 1017–1023.
Hydrochemical regime of fen and bog in north Japanese mires as an influence on habitat and above-ground biomass of Carex species.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXlt1Slsw%3D%3D&md5=e7acb99565958c999c3a2c90ff169629CAS |

Navrátilová J, Navrátil J, Hájec M (2006) Relationship between environmental factors and vegetation in nutrient-enriched fens at fishpond margins. Folia Geobotanica 41, 353–376.
Relationship between environmental factors and vegetation in nutrient-enriched fens at fishpond margins.Crossref | GoogleScholarGoogle Scholar |

Nekola JC (2004) Vascular plant compositional gradients within and between Iowa fens. Journal of Vegetation Science 15, 771–780.

Nix HA, Busby J (1986) BIOCLIM – a bioclimatic analysis and prediction system. Research Report No. 1983–85. Division of Water and Land Resources, Canberra.

Ohlemüller R, Gritti ES, Sykes MT, Thomas CD (2006) Towards European climate risk surfaces: the extent and distribution of analogous and non-analagous climates 1931–2100. Global Ecology and Biogeography 15, 395–405.
Towards European climate risk surfaces: the extent and distribution of analogous and non-analagous climates 1931–2100.Crossref | GoogleScholarGoogle Scholar |

Ojeda F (1998) Biogeography of seeder and resprouter Erica species in the Cape Floristic Region – where are the resprouters? Biological Journal of the Linnaean Society 63, 331–347.

Økland RH, Økland T, Rydgren K (2001) A Scandinavian perspective on ecological gradients in north-west European mires: reply to Wheeler and Proctor. Journal of Ecology 89, 481–486.
A Scandinavian perspective on ecological gradients in north-west European mires: reply to Wheeler and Proctor.Crossref | GoogleScholarGoogle Scholar |

Olde Venterink H, Wassen MJ, Belgers JDM, Verhoeven JTA (2001) Control of environmental variables on species density in fens and meadows: importance of direct effects and effects through community biomass. Journal of Ecology 89, 1033–1040.
Control of environmental variables on species density in fens and meadows: importance of direct effects and effects through community biomass.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD38XmtVSlsA%3D%3D&md5=9101654d25361e207d37d6ef2c30776aCAS |

Parmesan C, Gaines S, Gonzalez L, Kaufman DM, Kingsolver J, Peterson AT, Sagarin R (2005) Empirical perspectives on species borders: from traditional biogeography to global change. Oikos 108, 58–75.
Empirical perspectives on species borders: from traditional biogeography to global change.Crossref | GoogleScholarGoogle Scholar |

PMSEIC Independent Working Group (2007) ‘Climate change in Australia: regional impacts and adaptation–managing risk for Australia.’ Report prepared for the Prime Minister’s Science, Engineering and Innovation Council (PMSEIC), Canberra.

Pohlman CL, Nicotra AB, Murray BR (2005) Geographic range size, seedling ecophysiology and phenotypic plasticity in Australian Acacia species. Journal of Biogeography 32, 341–351.
Geographic range size, seedling ecophysiology and phenotypic plasticity in Australian Acacia species.Crossref | GoogleScholarGoogle Scholar |

Reino L, Beja P, Heitor AC (2006) Modelling spatial and environmental effects at the edge of the distribution: the red-backed shrike Lanius collurio in Northern Portugal. Journal of Biogeography 12, 379–387.

Resource & Conservation Assessment Council (1996) ‘Regional report of Upper North East New South Wales Vol. 2. Physical attributes.’ (Resource & Conservation Assessment Council: Sydney)

Roberts DW (1986) Ordination on the basis of fuzzy set theory. Vegetatio 66, 123–131.
Ordination on the basis of fuzzy set theory.Crossref | GoogleScholarGoogle Scholar |

Schröder HK, Andersen HE, Kiehl K (2005) Rejecting the mean: estimating the response of fen plant species ton environmental facts by non-linear quantile regression. Journal of Vegetation Science 16, 373–382.
Rejecting the mean: estimating the response of fen plant species ton environmental facts by non-linear quantile regression.Crossref | GoogleScholarGoogle Scholar |

Southall EJ, Dale MP, Kent M (2003) Spatial and temporal analysis of vegetation mosaics for conservation: poor fen communities in a Cornish Valley mire. Journal of Biogeography 30, 1427–1443.
Spatial and temporal analysis of vegetation mosaics for conservation: poor fen communities in a Cornish Valley mire.Crossref | GoogleScholarGoogle Scholar |

Stevens GC (1996) Extending Rapoport’s rule to Pacific marine fishes. Journal of Biogeography 23, 149–154.
Extending Rapoport’s rule to Pacific marine fishes.Crossref | GoogleScholarGoogle Scholar |

ter Braak CJF (1988) Partial canonical correspondence analysis. In ‘Classification and related methods of data analysis; proceedings of the first conference of the International Federation of Classification Societies (IFCS)’. (Ed. HH Bock) pp. 551–558. (Microcomputer Power: Amsterdam)

ter Braak CJF, Smilauer P (1998) ‘CANOCO reference manual and user’s guide to Canoco for Windows: software for canonical community ordination (version 4).’ (Microcomputer Power: Ithaca, NY)

Thuiller W, Lavorel S, Araujo MB (2005) Niche properties and geographical extent as predictors of species sensitivity to climate change. Global Ecology and Biogeography 14, 347–357.
Niche properties and geographical extent as predictors of species sensitivity to climate change.Crossref | GoogleScholarGoogle Scholar |

Travis JMJ, Dytham C (2004) A method for simulating patterns of habitat availability at static and dynamic range margins. Oikos 104, 410–416.
A method for simulating patterns of habitat availability at static and dynamic range margins.Crossref | GoogleScholarGoogle Scholar |

Vanderpuye AW, Elvebakk A, Nilsen L (2002) Plant communities along environmental gradients of high-arctic mires in Sassendalen, Svalbard. Journal of Vegetation Science 13, 875–884.
Plant communities along environmental gradients of high-arctic mires in Sassendalen, Svalbard.Crossref | GoogleScholarGoogle Scholar |

Virgona S, Vaughton G, Ramsay M (2006) Habitat segregation of Banksia shrubs at Gibraltar Range National Park. Proceedings of the Linnean Society of New South Wales 127, 39–47.

Westhoff V, Maarel VD (1978) The Braun-Blanquet approach. In ‘Classification of plant communities’. (Ed. RH Whittaker) pp. 617–726. (Junk: The Hague)

Wheeler BD, Proctor MCF (2000) Ecological gradients, subdivisions and terminology of north-west European mires. Journal of Ecology 88, 187–203.
Ecological gradients, subdivisions and terminology of north-west European mires.Crossref | GoogleScholarGoogle Scholar |

Whinam J, Chilcott N (2002) Floristic description and environmental relationships of Sphagnum communities in NSW and the ACT and their conservation management. Cunninghamia 7, 463–500.

Whinam J, Hope G (2005) The peatlands of the Australasian region. Stapfia 85, 397–400.

Whinam J, Barmuta LA, Chilcott N (2001) Floristic description and environmental relationships of Tasmanian Sphagnum communities and their conservation management. Australian Journal of Botany 49, 673–685.
Floristic description and environmental relationships of Tasmanian Sphagnum communities and their conservation management.Crossref | GoogleScholarGoogle Scholar |

Whinam J, Chilcott NM, Morgan JW (2003) Floristic composition and environmental relationships of Sphagnum dominated communities in Victoria. Cunninghamia 8, 162–174.

Williams PR, Clarke PJ (2006) Fire history and soil gradients generate floristic patterns in montane sedgelands and wet heaths of Gibraltar Range National Park. Proceedings of the Linnean Society of New South Wales 127, 27–38.