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dc.contributor.authorEnright, Neal
dc.contributor.authorMosner, E.
dc.contributor.authorMiller, Ben
dc.contributor.authorJohnson, Nicole
dc.contributor.authorLamont, Byron
dc.date.accessioned2017-01-30T13:55:22Z
dc.date.available2017-01-30T13:55:22Z
dc.date.created2008-11-12T23:36:12Z
dc.date.issued2007
dc.identifier.citationEnright, N. J. and Mosner, E and Miller, B. P. and Johnson, N. and Lamont, Byron B.. 2007. Soil vs. canopy seed storage and plant species coexistence in species-rich Australian shrublands. Ecology. 88 (9): 2292-2304.
dc.identifier.urihttp://hdl.handle.net/20.500.11937/36364
dc.identifier.doi10.1890/06-1343.1
dc.description.abstract

The fire-prone shrublands of southwestern Australia are renowned for their high plant species diversity and prominence of canopy seed storage (serotiny). We compared species richness, abundance, and life history attributes for soil and canopy seed banks in relation to extant vegetation among four sites with different substrate conditions and high species turnover (50 80%) to identify whether this unusual community-level organization of seed storage might contribute to maintenance of high species richness.Soil seed bank (SSB) densities were low to moderate (233 1435 seeds/m2) compared with densities for other Mediterranean-type vegetation and were lowest for sites with highest canopy seed bank (CSB) species richness and lowest nutrient availability, but not richness or abundance of resprouters. Annuals were infrequent in the lowest nutrient sites, but there was no evidence that small SSB size was due to low seed inputs or a trade-off between seed production/storage and seed size in response to low nutrient availability. Sorensen's similarity between SSB and extant vegetation was 26 43% but increased to 54 57% when the CSB was included, representing levels higher than reported for most other ecosystems. Resprouting species were well represented in both the SSB and CSB, and there was no evidence for lower seed production in resprouters than in non-sprouters overall. The SSB and CSB held no species in common and were characterized by markedly different seed dispersal attributes, with winged or small seeds in the CSB and seeds dispersed by ants, birds, and wind (though none with wings) in the SSB. There was no evidence of spatial differentiation in the distribution of seeds of SSB species between vegetated and open microsites that might facilitate species coexistence, but most woody non-sprouters showed aggregation at scales of 1 2 m, implying limited seed dispersal. High similarity between overall seed bank (SSB + CSB) and extant species composition, high number of resprouting species, and seed dispersal processes before (SSB) and after fire (CSB) leading to differential spatial aggregation of post-fire recruits from the two seed bank types may buffer species composition against rapid change and provide a mechanism for maintaining species coexistence at the local scale.

dc.publisherEcological Society of America
dc.subjectserotiny
dc.subjectspecies richness
dc.subjectsoil seed bank
dc.subjectcanopy seed bank
dc.subjectcoexistence
dc.subjectsouthwestern Australia
dc.subjectfire
dc.subjectshrublands
dc.titleSoil vs. canopy seed storage and plant species coexistence in species-rich Australian shrublands
dc.typeJournal Article
dcterms.source.volume88
dcterms.source.number9
dcterms.source.monthsep
dcterms.source.startPage2292
dcterms.source.endPage2304
dcterms.source.titleEcology.
curtin.identifierEPR-2778
curtin.accessStatusOpen access
curtin.facultyDivision of Resources and Environment
curtin.facultyMuresk Institute
curtin.facultyDepartment of Environmental Biology


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