Seed traits and seed bank longevity of wet sclerophyll forest shrubs
Monica L. Campbell A B , Peter J. Clarke A E and David A. Keith C DA Botany, University of New England, Armidale, NSW 2351, Australia.
B Biosis Research Pty Ltd, PO Box 238, Fortitude Valley, Qld 4006, Australia.
C Department of Environment, Cimate Change and Water, PO Box 1968, Hurstville, NSW 2220, Australia.
D Australian Wetlands and Rivers Centre, University of New South Wales, Kensington, NSW 2052, Australia.
E Corresponding author. Email: pclarke1@une.edu.au
Australian Journal of Botany 60(2) 96-103 https://doi.org/10.1071/BT11261
Submitted: 10 October 2011 Accepted: 23 January 2012 Published: 28 March 2012
Abstract
In wet sclerophyll forests seedling recruitment either occurs after intermittent fire events or continuously during intervals between fires in gaps created by small-scale disturbances. The dormancy and dispersal characteristics of seeds will influence how plant species exploit these contrasting recruitment opportunities. For example, long-lived seed banks may be crucial for persistence of species that are unable to recruit during intervals between fires if the length of fire intervals exceeds the life span of standing plants (senescence risk). To better understand mechanisms of population persistence during prolonged absence of fire in montane wet sclerophyll forests, we studied seed bank dynamics in four understorey species. We chose two species thought to have fire event-driven recruitment, Banksia integrifolia subsp. monticola (Proteaceae) and Goodia lotifolia (Fabaceae), and two species that are thought to have canopy gap-phase recruitment, Trochocarpa laurina (Ericaceae) and Tasmannia stipitata (Winteraceae). We measured seed rain, seed bank density and used seeds buried in nylon mesh bags to estimate rates of seed decay in the soil over time. All species produced a substantial seed crop on an annual basis. The annual seed crop in three species (G. lotifolia, T. stipitata and T. laurina) was released in a dormant state and developed a persistent seed bank, while one species (B. integrifolia) lacked dormancy and rapidly germinated under laboratory and field conditions. Seed bank characteristics of G. lotifolia appear to promote episodic recruitment after large landscape-scale fires, those of B. integrifolia appear to promote more continuous recruitment in response to smaller fires and other disturbances that avoid widespread mortality of established plants, while seed bank characteristics of T. stipitata and T. laurina may facilitate both episodic and continuous recruitment under respective types of disturbance. The four species appeared to have varied vulnerabilities and mechanisms for reducing immaturity risk and senescence risk to persistence of their populations under recurrent disturbance. Dormancy, seed bank longevity and seed rain are likely to be useful syndromes for predicting the response of wet sclerophyll forest understorey species to changed disturbance regimes.
References
Aitkin M, Anderson D, Francis B, Hinde J (1989) ‘Statistical modelling in GLIM.’ (Clarendon Press: Oxford)Ashton DH (2000) The Big Ash forest, Wallaby Creek, Victoria – changes during one lifetime. Australian Journal of Botany 48, 1–26.
| The Big Ash forest, Wallaby Creek, Victoria – changes during one lifetime.Crossref | GoogleScholarGoogle Scholar |
Ashton DH, Attiwill PM (1994) Tall open-forests. In ‘Australian vegetation’. (Ed. RH Groves) pp. 157–196. (Cambridge University Press: Cambridge)
Auld TD (1986) Post-fire demography in the resprouting shrub Angophora hispida (Sm.) Blaxell: flowering, seed production, dispersal, seedling establishment and survival. Proceedings of the Linnean Society of New South Wales 109, 259–269.
Auld TD (1987) Population dynamics of the shrub Acacia suaveolens (Sm.) Willd.: survivorship throughout the lifecycle, a synthesis. Australian Journal of Ecology 12, 139–151.
| Population dynamics of the shrub Acacia suaveolens (Sm.) Willd.: survivorship throughout the lifecycle, a synthesis.Crossref | GoogleScholarGoogle Scholar |
Auld TD, Keith DA, Bradstock RA (2000) Patterns of longevity of soil seedbanks in fire-prone communities of south-eastern Australia. Australian Journal of Botany 48, 539–548.
| Patterns of longevity of soil seedbanks in fire-prone communities of south-eastern Australia.Crossref | GoogleScholarGoogle Scholar |
Binns DL (1991) Vegetation dynamics of Eucalyptus microcorys – E. saligna wet sclerophyll forest in response to logging. Masters Thesis, University of New England, Armidale.
Campbell ML, Clarke PJ (2006) Response of montane wet sclerophyll forest understorey species to fire: evidence from high and low intensity fires. Proceedings of the Linnean Society of New South Wales 127, 63–73.
Chesterfield EA, Taylor SJ, Molnar CD (1991) Recovery after wildfire: warm temperate rainforest at Jones Creek, East Gippsland, Victoria. Australian Forestry 54, 157–173.
Clarke PJ, Copeland LM, Noble NE, Bale CL, Williams JB (2000) ‘The vegetation and plant species of New England National Park.’ (Botany Publications, University of New England: Armidale)
Clarke PJ, Knox KJE, Butler D (2010) Fire intensity, serotiny and seed release in 19 woody species: evidence for risk spreading among wind-dispersed and resprouting syndromes. Australian Journal of Botany 58, 629–636.
Crawley MJ (1993) ‘GLIM for ecologists.’ (Blackwell: Oxford)
Dalling JW, Denslow JS (1998) Soil seed bank composition along a forest chromosequence in a seasonally moist tropical forest in Panama. Journal of Vegetation Science 9, 669–678.
| Soil seed bank composition along a forest chromosequence in a seasonally moist tropical forest in Panama.Crossref | GoogleScholarGoogle Scholar |
Denslow JS (1985) Disturbance mediated coexistence of species. In ‘The ecology of natural disturbance and patch dynamics’. (Eds STA Pickett, PS White) pp. 307–323. (Academic Press: Orlando, FL)
Fox GA (2001) Failure time analysis: studying times-to-events and rates at which events occur. In ‘Design and analysis of ecological experiments’. 2nd edn. (Eds SM Scheiner, J Gurevitch) pp. 235–266. (Oxford University Press: Oxford)
Francis B, Green M, Payne C (1993) ‘The GLIM 4 System: the statistical system for Generalised Linear Modelling.’ (Clarendon Press: Oxford)
Gilbert JM (1959) Forest succession in the Florentine Valley, Tasmania. Proceedings of the Royal Society of Tasmania 93, 129–151.
Gill AM (1981) Adaptive responses of Australian vascular plant species to fire. In ‘Fire and the Australian biota’. (Eds AM Gill, RH Groves, IR Noble) pp. 243–272. (Australian Academy of Science: Canberra)
Henderson MK, Keith DA (2002) Correlation of burning and grazing indicators with composition of woody understorey flora of dells in a temperate eucalypt forest. Austral Ecology 27, 121–131.
| Correlation of burning and grazing indicators with composition of woody understorey flora of dells in a temperate eucalypt forest.Crossref | GoogleScholarGoogle Scholar |
Hill RS, Read J (1984) Post-fire regeneration of rainforest and mixed forest in Western Tasmania. Australian Journal of Botany 32, 481–493.
| Post-fire regeneration of rainforest and mixed forest in Western Tasmania.Crossref | GoogleScholarGoogle Scholar |
Hopkins MS, Graham AW (1984) Viable soil seed banks in disturbed lowland tropical rainforest sites in North Queensland. Australian Journal of Ecology 9, 71–79.
| Viable soil seed banks in disturbed lowland tropical rainforest sites in North Queensland.Crossref | GoogleScholarGoogle Scholar |
Hopkins MS, Graham AW (1987) The viability of seeds of rainforest species after experimental soil burials under tropical wet lowland forest in north-eastern Australia. Australian Journal of Ecology 12, 97–108.
| The viability of seeds of rainforest species after experimental soil burials under tropical wet lowland forest in north-eastern Australia.Crossref | GoogleScholarGoogle Scholar |
Knox KJE, Clarke PJ (2006) Response of resprouting shrubs to repeated fires in the dry sclerophyll forest of Gibraltar Range National Park. Proceedings of the Linnean Society of New South Wales 127, 49–56.
Knox KJE, Clarke PJ (2011) Fire severity and resource availability do not constrain resprouting ability in sclerophyll forests. Plant Ecology 12, 1967–1968.
Lamont BB, Enright NJ, He T (2011) Fitness and evolution of resprouters in relation to fire. Plant Ecology 12, 1950–1960.
Martinez-Ramos M, Soto-Castro A (1993) Seed rain and advanced regeneration in a tropical rainforest. Vegetatio 108, 299–318.
Melick DR, Ashton DA (1991) The effects of natural disturbance on warm temperate rainforests in south-eastern Australia. Australian Journal of Botany 39, 1–30.
| The effects of natural disturbance on warm temperate rainforests in south-eastern Australia.Crossref | GoogleScholarGoogle Scholar |
Merritt DJ, Turner SR, Clarke S, Dixon K (2007) Seed dormancy and germination stimulation syndromes for Australian temperate species. Australian Journal of Botany 55, 336–344.
| Seed dormancy and germination stimulation syndromes for Australian temperate species.Crossref | GoogleScholarGoogle Scholar |
Oke SO, Oladipo OT, Iscichei AO (2006) Seed bank dynamics in a secondary lowland rainforest in Nigeria. International Journal of Botany 2, 363–371.
| Seed bank dynamics in a secondary lowland rainforest in Nigeria.Crossref | GoogleScholarGoogle Scholar |
Ooi M (2007) Dormancy classification and potential dormancy breaking cues for shrub species from fire-prone southeastern Australia. In ‘Seeds: biology, development and ecology’. (Eds SW Adkins, SE Ashmore, SC Navie) pp. 205–216. (CABI: Cambridge, MA)
Pickett STA, White PS (1985) ‘The ecology of natural disturbance and patch dynamics.’ (Academic Press: New York)
Rico-Gray V, Franco JG (1992) Vegetation and soil seed bank of successional stages in a tropical lowland deciduous forest. Journal of Vegetation Science 3, 617–624.
| Vegetation and soil seed bank of successional stages in a tropical lowland deciduous forest.Crossref | GoogleScholarGoogle Scholar |
Roberts EH (1972) Dormancy: a factor affecting seed survival in soil. In ‘Viability of seed’. (Ed. EH Roberts) pp. 321–359. (Chapman and Hall: London)
Saatkamp A, Affre L, Dutoit T, Poschold P (2009) The seed bank longevity index revisited: limited reliability evident from a burial experiment and database analyses. Annals of Botany 104, 715–724.
| The seed bank longevity index revisited: limited reliability evident from a burial experiment and database analyses.Crossref | GoogleScholarGoogle Scholar |
Shugart HH (1984) ‘A theory of forest dynamics.’ (Springer-Verlag: New York)
Tang Y, Boulter SL, Kitching RL (2003) Heat and smoke effects on the germination of seeds from soil seed banks across forest edges between subtropical rainforest and eucalypt forest at Lamington National Park, south-eastern Queensland. Australian Journal of Botany 51, 227–237.
| Heat and smoke effects on the germination of seeds from soil seed banks across forest edges between subtropical rainforest and eucalypt forest at Lamington National Park, south-eastern Queensland.Crossref | GoogleScholarGoogle Scholar |
Tasker EM, Bradstock RA (2006) Influence of cattle grazing practices on forest understorey structure in north-eastern New South Wales. Austral Ecology 31, 490–502.
| Influence of cattle grazing practices on forest understorey structure in north-eastern New South Wales.Crossref | GoogleScholarGoogle Scholar |
Thompson K, Bakker JP, Bekker RM, Hodgson JG (1998) Ecological correlates of seed persistence in soil in the north-west European flora. Journal of Ecology 86, 163–169.
| Ecological correlates of seed persistence in soil in the north-west European flora.Crossref | GoogleScholarGoogle Scholar |
Vazquez-Yanes C, Orozco-Segovia A (1993) Patterns of seed longevity and germination in the tropical rainforest. Annual Review of Ecology and Systematics 24, 69–87.
| Patterns of seed longevity and germination in the tropical rainforest.Crossref | GoogleScholarGoogle Scholar |
Venable DL, Brown JS (1988) The selective interaction of dispersal, dormancy and seed size as adaptations for reduced risk in variable environments. American Naturalist 131, 360–384.
| The selective interaction of dispersal, dormancy and seed size as adaptations for reduced risk in variable environments.Crossref | GoogleScholarGoogle Scholar |
Wang L (1997) The soil seed bank and understorey regeneration in Eucalyptus regnans forest, Victoria. Australian Journal of Ecology 22, 404–411.
| The soil seed bank and understorey regeneration in Eucalyptus regnans forest, Victoria.Crossref | GoogleScholarGoogle Scholar |
Weiss PW (1984) Seed characteristics and regeneration of some species in invaded coastal communities. Australian Journal of Ecology 9, 99–106.
| Seed characteristics and regeneration of some species in invaded coastal communities.Crossref | GoogleScholarGoogle Scholar |
Whitmore TC (1983) Secondary succession from seed in tropical rainforests. Forestry Abstracts 44, 767–779.
Williams PR (2000) Fire-stimulated rainforest seedling recruitment and vegetative regeneration in a densely grassed wet sclerophyll forest of north-eastern Australia. Australian Journal of Botany 48, 651–658.
| Fire-stimulated rainforest seedling recruitment and vegetative regeneration in a densely grassed wet sclerophyll forest of north-eastern Australia.Crossref | GoogleScholarGoogle Scholar |
Williams PR, Clarke PJ (1997) Habitat segregation by serotinous shrubs in heaths: post-fire emergence and seedling survival. Australian Journal of Botany 45, 31–39.
| Habitat segregation by serotinous shrubs in heaths: post-fire emergence and seedling survival.Crossref | GoogleScholarGoogle Scholar |