Are New Zealand's Nothofagus species in equilibrium with their environment?

Are New Zealand's Nothofagus species in equilibrium with their environment? Abstract. Past explanations of the large disjunctions in the distribution of New Zealand's four Nothofagus species have emphasized displacement during glacial cycles followed by slow re‐occupation of suitable sites, or the effects of plate tectonics coupled with ecological and/or environmental limitations to further spread. In this study the degree of equilibrium between Nothofagus distribution and environment was compared with that of other widespread tree species by statistical analysis. Generalized additive regression models were used to relate species distribution data to estimates of temperature, solar radiation, soil water deficit, atmospheric humidity, lithology and drainage. For each species, the amount of spatial patterning remaining unexplained by environment was assessed by adding a variable describing species presence/absence on adjacent plots. Results indicate that Nothofagus species occur more frequently in environments suboptimal for tree growth, i.e. having various combinations of cool temperatures, low winter solar radiation, high root‐zone water deficit, low humidity, and infertile granitic substrates. Despite these demonstrated preferences, they exhibit substantially more spatial clustering which is unexplained by environment, than most other widespread tree species. Predictions formed from regressions using environment alone confirm that several major Nothofagus disjunctions are not explicable in terms of the environmental factors used in this analysis, but more likely reflect the effects of historic displacement coupled with slowness to invade forest dominated by more rapidly dispersing endomycorrhizal species. The technique used in this study for detecting residual spatial autocorrelation after fitting explanatory variables has potentially wide application in other studies where either regression or ordination techniques are used for analysis of compositional data. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Journal of Vegetation Science Wiley

Are New Zealand's Nothofagus species in equilibrium with their environment?

Leathwick, John R.
Journal of Vegetation Science, Volume 9 (5) – Oct 1, 1998
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Publisher
Wiley
Copyright
1998 IAVS ‐ the International Association of Vegetation Science
ISSN
1100-9233
eISSN
1654-1103
DOI
10.2307/3237290
Publisher site
See Article on Publisher Site

Abstract

Abstract. Past explanations of the large disjunctions in the distribution of New Zealand's four Nothofagus species have emphasized displacement during glacial cycles followed by slow re‐occupation of suitable sites, or the effects of plate tectonics coupled with ecological and/or environmental limitations to further spread. In this study the degree of equilibrium between Nothofagus distribution and environment was compared with that of other widespread tree species by statistical analysis. Generalized additive regression models were used to relate species distribution data to estimates of temperature, solar radiation, soil water deficit, atmospheric humidity, lithology and drainage. For each species, the amount of spatial patterning remaining unexplained by environment was assessed by adding a variable describing species presence/absence on adjacent plots. Results indicate that Nothofagus species occur more frequently in environments suboptimal for tree growth, i.e. having various combinations of cool temperatures, low winter solar radiation, high root‐zone water deficit, low humidity, and infertile granitic substrates. Despite these demonstrated preferences, they exhibit substantially more spatial clustering which is unexplained by environment, than most other widespread tree species. Predictions formed from regressions using environment alone confirm that several major Nothofagus disjunctions are not explicable in terms of the environmental factors used in this analysis, but more likely reflect the effects of historic displacement coupled with slowness to invade forest dominated by more rapidly dispersing endomycorrhizal species. The technique used in this study for detecting residual spatial autocorrelation after fitting explanatory variables has potentially wide application in other studies where either regression or ordination techniques are used for analysis of compositional data.

Journal

Journal of Vegetation ScienceWiley

Published: Oct 1, 1998

References

  • Current approaches to modelling the environmental niche of eucalypts: implications for management of forest biodiversity
    Austin, Austin; Meyers, Meyers
    Bookmark
  • Measurement of the realized qualitative niche: environmental niches of five Eucalyptus species
    Austin, Austin; Nicholls, Nicholls; Margules, Margules
  • Mycorrhizas and the spread of beech
    Baylis, Baylis
  • Determining alternative models for vegetation response analysis: a non‐parametric method
    Bio, Bio; Alkemade, Alkemade; Barendregt, Barendregt
  • Environmental control and spatial structure in ecological communities: an example using oribatid mites (Acari, Oribatei)
    Borcard, Borcard; Legendre, Legendre
  • Plant functional types and climate at the global scale
    Box, Box
    Bookmark
  • Mycorrhizas in natural ecosystems
    Brundrett, Brundrett
  • Modelling impacts of climate change on the spatial distribution of zonal communities in Switzerland
    Brzeziecki, Brzeziecki; Kienast, Kienast; Wildi, Wildi
    Bookmark
  • Recent colonisation by Nothofagus fusca at Cass, Canterbury
    Burrows, Burrows; Lord, Lord
  • Low diversity tropical rain forests: some possible mechanisms for their existence
    Connell, Connell; Lowman, Lowman
  • Name changes in the indigenous New Zealand flora, 1960–1986 and nomina nova IV, 1983–1986
    Connor, Connor; Edgar, Edgar
  • Dispersal versus climate: Expansion of Fagus and Tsuga into the Upper Great Lakes region
    Davis, Davis; Woods, Woods; Webb, Webb; Futyma, Futyma
  • Plant functional types and ecosystem function in relation to global change
    Diaz, Diaz; Cabido, Cabido
    Bookmark
  • The contributions of mycorrhizal fungi to the determination of plant community structure
    Francis, Francis; Read, Read
  • A review of late Quaternary silicic and some other tephra formations from New Zealand: their stratigraphy, nomenclature, distribution, volume, and age
    Froggatt, Froggatt; Lowe, Lowe
  • Climatic discrimination of Mediterranean broad‐leaved sclerophyllous and deciduous forests in central Spain
    Gavilán, Gavilán; Fernández‐González, Fernández‐González
  • A review of the concept of sustainable management as applied to New Zealand
    Glasby, Glasby
  • Hyphal mats formed by two ectomycorrhizal fungi and their association with Douglas‐fir seedlings: A case study
    Griffiths, Griffiths; Castellano, Castellano; Caldwell, Caldwell
  • Ecology and distribution of Nothofagus in Deception Valley, Arthur's Pass National Park, New Zealand
    Haase, Haase
  • Environmental and floristic gradients in Westland, New Zealand, and the discontinuous distribution of Nothofagus
    Haase, Haase
  • Modelling present and potential future ranges of some European higher plants using climate response surfaces
    Huntley, Huntley; Berry, Berry; Cramer, Cramer; McDonald, McDonald
  • Splines – more than just a smooth interpolator
    Hutchinson, Hutchinson; Gessler, Gessler
  • Climatic relationships of some New Zealand forest tree species
    Leathwick, Leathwick
    Bookmark
  • Forest pattern, climate and vulcanism in central North Island, New Zealand
    Leathwick, Leathwick; Mitchell, Mitchell
    Bookmark
  • Predicting changes in the composition of New Zealand's indigenous forests in response to global warming: a modelling approach
    Leathwick, Leathwick; Whitehead, Whitehead; McLeod, McLeod
  • Spatial autocorrelation: Trouble of new paradigm
    Legendre, Legendre
  • Ecological response surfaces for North American boreal tree species and their use in forest classification
    Lenihan, Lenihan
    Bookmark
  • Plant biogeography and the late Cenozoic history of New Zealand
    McGlone, McGlone
  • The late Pleistocene and Holocene vegetation history of Taranaki, North Island, New Zealand
    McGlone, McGlone; Neal, Neal
  • Succession after forest fires in the southern Tararua Mountains
    McQueen, McQueen
  • Distribution of subfossil forest remains, eastern South Island, New Zealand
    Molloy, Molloy; Burrows, Burrows; Cox, Cox; Johnston, Johnston; Wardle, Wardle
  • A model for predicting continental‐scale vegetation distribution and water balance
    Neilson, Neilson
  • A global model based on plant physiology and dominance, soil properties and climate
    Prentice, Prentice; Cramer, Cramer; Harrison, Harrison; Leemans, Leemans; Monserud, Monserud; Solomon, Solomon
  • Realised niche spaces and func tional types: a framework for prediction of compositional change
    Rutherford, Rutherford; O'Callaghan, O'Callaghan; Hurford, Hurford; Powrie, Powrie; Schulze, Schulze; Kunz, Kunz; Davis, Davis; Hoffman, Hoffman; Mack, Mack
  • Autocorrelation in logistic regression modelling of species' distributions
    Smith, Smith
  • A predictive model relating North American plant formations and climate
    Sowell, Sowell
  • Nothofagus , key genus of plant geography, in time and space, living and fossil, ecology and phylogeny
    Steenis, Steenis
  • Evolution and distribution of the New Zealand flora, as affected by Quaternary climates
    Wardle, Wardle
  • Facets of the distribution of forest vegetation in New Zealand
    Wardle, Wardle
  • Ecology and distribution of silver beech ( Nothofagus menziesii) in the Paringa district, South Westland, New Zealand
    Wardle, Wardle
  • Pattern, process, and natural disturbance in vegetation
    White, White
  • Geomorphology of the central Southern Alps, New Zealand: The interaction of plate collision and atmospheric circulation
    Whitehouse, Whitehouse
  • The New Zealand Pleistocene snow line, climatic conditions, and suggested biological effects
    Willett, Willett
  • Caldera volcanoes of the Taupo Volcanic Zone, New Zealand
    Wilson, Wilson; Rogan, Rogan; Smith, Smith; Northey, Northey

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