Register      Login
Australian Journal of Botany Australian Journal of Botany Society
Southern hemisphere botanical ecosystems
Shopping Cart: ( empty )
You are here: Home > Journals > BT > BT19073
RESEARCH ARTICLE
Contents Vol 68(3)

Anatomical aspects of xeromorphy in arid-adapted plants of Australia

V. M. Dörken https://orcid.org/0000-0002-8451-6893 A D , P. G. Ladd https://orcid.org/0000-0002-7730-9685 B and R. F. Parsons C
+ Author Affiliations
- Author Affiliations

A Department of Biology, University of Konstanz, M 613, Universitätsstr. 10, 78457 Konstanz, Germany.

B Environment and Conservation Science, Murdoch University, Murdoch, WA 6150, Australia.

C Department of Ecology, Environment and Evolution, La Trobe University, Melbourne, Vic. 3086, Australia.

D Corresponding author. Email: veit.doerken@uni-konstanz.de

Australian Journal of Botany 68(3) 245-266 https://doi.org/10.1071/BT19073
Submitted: 9 April 2019  Accepted: 23 February 2020   Published: 28 April 2020

Abstract

Plants from arid environments have some of the most diverse morphological and anatomical modifications of any terrestrial plants. Most perennials are classified as xerophytes, and have structures that limit water loss during dry weather, provide structural support to help prevent cell collapse during dry periods or store water in photosynthetic tissues. Some of these traits are also found in sclerophyllous plants and traits that may have developed due to evolution of taxa on nutrient poor soils may also benefit the plants under arid conditions. We examined the morpho-anatomical features of photosynthetic organs of three tree and four shrub species with reduced leaves or photosynthetic stems that occur in arid or semiarid sites in Australia to see if there were patterns of tissue formation particularly associated with xeromorphy. In addition, we reviewed information on succulent and resurrection species. In the tree species (Callitris spp.) with decurrent leaves clothing the stems, the close association between the water transport system and stomata, along with anisotropic physiology would allow the species to fix carbon under increasingly dry conditions in contrast to more broad-leaved species. The shrub species (Tetratheca species and Glischrocaryon flavescens) with photosynthetic stems had extensive sclerenchyma and very dense chlorenchyma. The lack of major anatomical differences between leafless species of Tetratheca from arid areas compared with more mesic sites indicates that quite extreme morphological modifications may not exclude species from growing successfully in competition with species from less arid areas. The sclerophyll flora now characteristic of Australian vegetation from seasonally arid climates may have evolved during mesic times in the past but with relatively minor modifications was able to adjust to the gradually drying climate of much of Australia up to the present time.

Additional keywords: Australian plants, drought, ecology, plant adaptation, plant evolution, plant structure, xeromorphic.


References

Abd Elhalim ME, Abo-Alatta OK, Habib SA, Abd Elbar OH (2016) The anatomical features of the desert halophytes Zygophyllum album L.f. and Nitraria retusa (Forssk.) Asch. Annals of Agricultural Science 61, 97–104.
The anatomical features of the desert halophytes Zygophyllum album L.f. and Nitraria retusa (Forssk.) Asch.Crossref | GoogleScholarGoogle Scholar |

ALA (2018) Atlas of living Australia. Available at http://www.ala.org.au [Verified 28 February 2020]

Baillie AL, Fleming AJ (2020) The developmental relationship between stomata and mesophyll airspace. New Phytologist 225, 1120–1126.
The developmental relationship between stomata and mesophyll airspace.Crossref | GoogleScholarGoogle Scholar | 31774175PubMed |

Baker RT, Smith HG (1910) ‘A research on the pines of Australia. Technical Education Series 16.’ (Technological Museum of New South Wales: Sydney, NSW, Australia)

Barker RM (2013) Zygophyllaceae. In ‘Flora of Australia. Vol. 26’. (Ed. A Wilson) pp. 551–579. (CSIRO Publishing: Melbourne, Vic., Australia)

Beadle NCW (1966) Soil phosphate and its role in molding segments of the Australian flora and vegetation with special reference to xeromorphy and sclerophylly. Ecology 47, 992–1007.
Soil phosphate and its role in molding segments of the Australian flora and vegetation with special reference to xeromorphy and sclerophylly.Crossref | GoogleScholarGoogle Scholar |

Beadle NCW (1968) Some aspects of the ecology and physiology of Australian xeromorphic plants. Australian Journal of Science 30, 348–356.

Beard JS (1981) Vegetation. In ‘Flora of central Australia’. (Ed. J Jessop) pp. xxi–xxvi. (Australian Systematic Botany Society, Reed Books, Sydney, NSW, Australia)

Black RF (1954) The leaf anatomy of Australian members of the genus Atriplex. 1. Atriplex vesicaria Heward and A. nummularia Lindl. Australian Journal of Botany 2, 269–286.
The leaf anatomy of Australian members of the genus Atriplex. 1. Atriplex vesicaria Heward and A. nummularia Lindl.Crossref | GoogleScholarGoogle Scholar |

Böcher TW (1979) Xeromorphic leaf types: evolutionary strategies and tentative semophyletic sequences. Det Kongelige Danske Videnskabernes Selskab Biologiske Skrifter 22, 1–71.

Bouchenak-Khelladi Y, Maurin O, Hurter J, van der Bank M (2010) The evolutionary history and biogeography of Mimosoideae (Leguminosae): an emphasis on African acacias. Molecular Phylogenetics and Evolution 57, 495–508.
The evolutionary history and biogeography of Mimosoideae (Leguminosae): an emphasis on African acacias.Crossref | GoogleScholarGoogle Scholar | 20696261PubMed |

Britton NL, Rose JN (1963) ‘The Cactaceae. Descriptions and illustrations of plants of the cactus family.’ (Dover Press: Mineola, NY, USA)

Brodribb TJ (2015) Bringing anatomy back into the equation. Plant Physiology 168, 1461
Bringing anatomy back into the equation.Crossref | GoogleScholarGoogle Scholar | 26246618PubMed |

Brodribb TJ, Field TS, Jordan GJ (2007) Leaf maximum photosynthetic rate and venation are linked by hydraulics. Plant Physiology 144, 1890–1898.
Leaf maximum photosynthetic rate and venation are linked by hydraulics.Crossref | GoogleScholarGoogle Scholar | 17556506PubMed |

Brodribb TJ, Field TS, Sack L (2010) Viewing leaf structure and evolution from a hydraulic perspective. Functional Plant Biology 37, 488–498.
Viewing leaf structure and evolution from a hydraulic perspective.Crossref | GoogleScholarGoogle Scholar |

Brodribb TJ, Bowman DMJS, Grierson PF, Murphy BP, Nichols S, Prior LD (2013) Conservative water management in the widespread conifer genus Callitris. AoB Plants 5, plt052
Conservative water management in the widespread conifer genus Callitris.Crossref | GoogleScholarGoogle Scholar |

Brodribb TJ, McAdam SAM, Jordan GJ, Martins SCV (2014) Conifer species adapt to low-rainfall climates by following one of two divergent pathways. Proceedings of the National Academy of Sciences of the United States of America 111, 14489–14493.
Conifer species adapt to low-rainfall climates by following one of two divergent pathways.Crossref | GoogleScholarGoogle Scholar | 25246559PubMed |

Byrne M, Yeates DK, Joseph L, Kearney M, Bowler J, Williams MAJ, Cooper S, Donnellan SC, Keogh JS, Leys R, Melville J, Murphy DJ, Porch N, Wyrwoll KH (2008) Birth of a biome: insights into the assembly and maintenance of the Australian arid zone biota. Molecular Ecology 17, 4398–4417.
Birth of a biome: insights into the assembly and maintenance of the Australian arid zone biota.Crossref | GoogleScholarGoogle Scholar | 18761619PubMed |

Byrne M, Joseph L, Yeates DK, Roberts JD, Edwards D (2018) Evolutionary history. In ‘On the ecology of Australia’s arid zone’. (Ed. H. Lambers) pp. 45–75. (Springer International Publishing AG: Cham, Switzerland)

Carpenter RJ, Macphail MK, Jordan GJ, Hill RS (2015) Fossil evidence for open, Proteaceae-dominated heathlands and fire in the late Cretaceous of Australia. American Journal of Botany 102, 2092–2107.
Fossil evidence for open, Proteaceae-dominated heathlands and fire in the late Cretaceous of Australia.Crossref | GoogleScholarGoogle Scholar | 26643888PubMed |

Cary KL, Ranieri GM, Pittermann J (2020) Xylem form and function under extreme nutrient limitation: an example from California’s pygmy forest. New Phytologist 226, 760–769.
Xylem form and function under extreme nutrient limitation: an example from California’s pygmy forest.Crossref | GoogleScholarGoogle Scholar | 31900931PubMed |

Cowan IR (1981) Coping with water stress. In ‘The biology of Australian plants’. (Eds JS Pate, AJ McComb) pp. 1–32. (University Western Australia Press: Nedlands, WA, Australia)

Craig S, Goodchild DJ (1977) Leaf ultrastructure of Triodia irritans: a C4 grass possessing an unusual arrangement of photosynthetic tissues. Australian Journal of Botany 25, 277–290.
Leaf ultrastructure of Triodia irritans: a C4 grass possessing an unusual arrangement of photosynthetic tissues.Crossref | GoogleScholarGoogle Scholar |

Crayn DM, Rossetto M, Maynard DJ (2006) Molecular phylogeny and dating reveals an Oligo-Miocene radiation of dry-adapted shrubs (former Tremandraceae) from rainforest tree progenitors (Elaeocarpaceae) in Australia. American Journal of Botany 93, 1328–1342.
Molecular phylogeny and dating reveals an Oligo-Miocene radiation of dry-adapted shrubs (former Tremandraceae) from rainforest tree progenitors (Elaeocarpaceae) in Australia.Crossref | GoogleScholarGoogle Scholar | 21642198PubMed |

Crisp MD, West JG, Linder HP (1999) Biogeography of the terrestrial flora. In ‘Flora of Australia. Vol. 1’, 2nd edn. (Ed. AE Orchard) pp. 321–368. (CSIRO Publishing: Melbourne, Vic., Australia)

Crisp MD, Cook LG, Bowman DMJS, Cosgrove M, Isagi Y, Sakaguchi S (2019) Turnover of southern cypresses in the post-Gondwanan world: extinction, transoceanic dispersal, adaptation and rediversification. New Phytologist 221, 2308–2319.
Turnover of southern cypresses in the post-Gondwanan world: extinction, transoceanic dispersal, adaptation and rediversification.Crossref | GoogleScholarGoogle Scholar | 30367483PubMed |

Cunningham SA, Summerhayes B, Westoby M (1999) Evolutionary divergences in leaf structure and chemistry, comparing rainfall and soil nutrient gradients. Ecology 69, 569–588.

De Micco V, Aronne G (2012) Morpho-anatomical traits for plant adaptation to drought. In ‘Plant responses to drought stress’. (Ed. R Aroca) pp. 37–61. (Springer-Verlag: Berlin, Germany)

Dörken VM (2013) Leaf dimorphism in Thuja plicata and Platycladus orientalis (thujoid Cupressaceae s. str., Coniferales): The changes in morphology and anatomy from juvenile needle leaves to mature scale leaves. Plant Systematics and Evolution 299, 1991–2001.
Leaf dimorphism in Thuja plicata and Platycladus orientalis (thujoid Cupressaceae s. str., Coniferales): The changes in morphology and anatomy from juvenile needle leaves to mature scale leaves.Crossref | GoogleScholarGoogle Scholar |

Dörken VM, Lepetit B (2018) Morpho-anatomical and physiological differences between sun and shade leaves in Abies alba Mill. (Pinaceae, Coniferales): a combined approach. Plant, Cell & Environment 41, 1683–1697.
Morpho-anatomical and physiological differences between sun and shade leaves in Abies alba Mill. (Pinaceae, Coniferales): a combined approach.Crossref | GoogleScholarGoogle Scholar |

Dörken VM, Parsons RF, Ladd PG (2018) The foliar change from seedlings to adults in Allocasuarina (Casuarinaceae): the evolutionary and ecological aspects of leaf reduction, xeromorphy and scleromorphy. Feddes Repertorium 129, 193–222.
The foliar change from seedlings to adults in Allocasuarina (Casuarinaceae): the evolutionary and ecological aspects of leaf reduction, xeromorphy and scleromorphy.Crossref | GoogleScholarGoogle Scholar |

Dörken VM, Ladd PG, Parsons RF (2019) The foliar characters in Callitris (Callitroideae, Cupressaceae s. str.) and their evolutionary and ecological significance. Feddes Repertorium 130, 247–271.
The foliar characters in Callitris (Callitroideae, Cupressaceae s. str.) and their evolutionary and ecological significance.Crossref | GoogleScholarGoogle Scholar |

Drake PL, Boer HJ, Schymanski SJ, Veneklaas EJ (2018) Two sides to every leaf: water and CO2 transport in hypostomatous and amphistomatous leaves. New Phytologist 222, 1179–1187.
Two sides to every leaf: water and CO2 transport in hypostomatous and amphistomatous leaves.Crossref | GoogleScholarGoogle Scholar |

Eller CB, Rowland L, Mencuccini M, Rosas T, Williams K, Harper A, Medlyn BE, Wagner Y, Klein T, Teodoro GS, Oliveira RS, Matos IS, Rosado BHP, Fuchs K, Wohlfahrt G, Montagnani L, Meir P, Sitch S, Cox PM (2020) Stomatal optimization based on xylem hydraulics (SOX) improves land surface model simulation of vegetation response to climate. New Phytologist
Stomatal optimization based on xylem hydraulics (SOX) improves land surface model simulation of vegetation response to climate.Crossref | GoogleScholarGoogle Scholar | 31916258PubMed |

Evans JR, Loreto F (2000) Acquisition and diffusion of CO2 in higher plants. In ‘Photosynthesis: physiology and metabolism’. (Eds RC Leegood, TD Sharkey, S von Cammerer) pp. 321–351. (Springer: Dordrecht, Netherlands)

Gaff DF (1981) The biology of resurrection plants. In ‘The biology of Australian plants’. (Eds JS Pate, AJ McComb) pp. 115–146. (University of Western Australia Press: Nedlands, WA, Australia)

Gaff DF, Oliver M (2013) The evolution of desiccation tolerance in angiosperm plants: a rare yet common phenomenon. Functional Plant Biology 40, 315–328.
The evolution of desiccation tolerance in angiosperm plants: a rare yet common phenomenon.Crossref | GoogleScholarGoogle Scholar |

George A (2002) ‘The long dry bush colours of summer and autumn in south-western Australia.’ (Four Gables Press: Kardinya, WA, Australia)

Gerlach D (1984) ‘Botanische Mikrotomtechnik, eine Einführung’, 2nd edn. (Thieme: Stuttgart, Germany)

Gerstberger P, Leins P (1978) Rasterelektronenmikroskopische Untersuchungen an Blütenknospen von Physalis philadelphia (Solanaceae). Berichte der Deutschen Botanischen Gesellschaft 91, 381–387.

Givnish TJ (1979) On the adaptive significance of leaf form. In ‘Topics in plant population biology’. (Eds OT Solbrig, S Jain, GB Johnson, PH Raven) pp. 375–407. (Columbia University Press, New York, NY, USA)

Grigg AM, Veneklaas EJ, Lambers H (2008) Water relations and mineral nutrition of Triodia grasses on desert dunes and interdunes. Australian Journal of Botany 56, 408–421.
Water relations and mineral nutrition of Triodia grasses on desert dunes and interdunes.Crossref | GoogleScholarGoogle Scholar |

Groom PK, Lamont BB (2015) ‘Plant life of southwestern Australia Adaptations for survival.’ (De Gruyter Open: Warsaw, Germany)

Hammer T, Davis R, Thiele K (2015) A molecular framework phylogeny for Ptilotus (Amaranthaceae): evidence for the rapid diversification of an arid Australian genus. Taxon 64, 272–285.
A molecular framework phylogeny for Ptilotus (Amaranthaceae): evidence for the rapid diversification of an arid Australian genus.Crossref | GoogleScholarGoogle Scholar |

Hattersley PW (1983) The distribution of C3 and C4 grasses in Australia in relation to climate. Oecologia 57, 113–128.
The distribution of C3 and C4 grasses in Australia in relation to climate.Crossref | GoogleScholarGoogle Scholar | 28310164PubMed |

Hauenschild F, Favre A, Schulz M, Muellner-Riehl AN (2018) Biogeographic analyses support an Australian origin for the Indomalesian-Australasian wet forest-adapted tropical tree and shrub genus Alphitonia and its close allies (Rhamnaceae). Botanical Journal of the Linnean Society 188, 1–20.
Biogeographic analyses support an Australian origin for the Indomalesian-Australasian wet forest-adapted tropical tree and shrub genus Alphitonia and its close allies (Rhamnaceae).Crossref | GoogleScholarGoogle Scholar |

Hill RS (1998) Fossil evidence for the onset of xeromorphy and scleromorphy in Australian Proteaceae. Australian Systematic Botany 11, 391–400.
Fossil evidence for the onset of xeromorphy and scleromorphy in Australian Proteaceae.Crossref | GoogleScholarGoogle Scholar |

Holtum JAM, Hancock LP, Edwards EJ, Crisp MD, Crayn DM, Sage R, Winter K (2016) Australia lacks stem succulents but is it depauperate in plants with crassulacean acid metabolism (CAM)? Current Opinion in Plant Biology 31, 109–117.
Australia lacks stem succulents but is it depauperate in plants with crassulacean acid metabolism (CAM)?Crossref | GoogleScholarGoogle Scholar |

Jordan GJ, Dillon RA, Weston PH (2005) Solar radiation as a factor in the evolution of scleromorphic leaf anatomy in Proteaceae. American Journal of Botany 92, 789–796.
Solar radiation as a factor in the evolution of scleromorphic leaf anatomy in Proteaceae.Crossref | GoogleScholarGoogle Scholar | 21652458PubMed |

Jordan GJ, Weston PH, Carpenter RJ, Dillon RA, Brodribb TJ (2008) The evolutionary relations of sunken, covered, and encrypted stomata to dry habitats in Proteaceae. American Journal of Botany 95, 521–530.
The evolutionary relations of sunken, covered, and encrypted stomata to dry habitats in Proteaceae.Crossref | GoogleScholarGoogle Scholar | 21632378PubMed |

Jordan GJ, Brodribb TJ, Blackman CJ, Weston PH (2013) Climate drives vein anatomy in Proteaceae. American Journal of Botany 100, 1483–1493.
Climate drives vein anatomy in Proteaceae.Crossref | GoogleScholarGoogle Scholar | 23935111PubMed |

Kulmatiski A, Yu K, Mackay DS, Holdrege MC, Staver AC, Parolari AJ, Liu Y, Majumder S, Trugman AT (2020) Forecasting semi-arid biome shifts in the Anthropocene. New Phytologist
Forecasting semi-arid biome shifts in the Anthropocene.Crossref | GoogleScholarGoogle Scholar | 31853979PubMed |

Kumar D, Kellogg EA (2018) Getting closer; vein density in C4 leaves. New Phytologist 221, 1260–1267.
Getting closer; vein density in C4 leaves.Crossref | GoogleScholarGoogle Scholar | 30368826PubMed |

Ladiges PY, Evans BK, Saint RB (2010) ‘Biology: an Australian focus’, 4th edn. (McGraw-Hill: North Ryde, NSW, Australia)

Lambers H, Colmer TD, Hassiotou F, Mitchell PM, Poot P, Shane MW, Veneklaas EJ (2014) Carbon and water relations. In ‘Plant life of the sandplains in southwestern Australia’. (Ed. H Lambers) pp. 129–146. (Univ. Western Australia Press: Nedlands, WA, Australia)

Lamont BB, He T (2017) When did a Mediterranean-type climate originate in southwestern Australia? Global and Planetary Change 156, 46–58.
When did a Mediterranean-type climate originate in southwestern Australia?Crossref | GoogleScholarGoogle Scholar |

Lamont BB, Groom PK, Williams M, He T (2015) LMA, density and thickness: recognizing different leaf shapes and correcting for their nonlaminarity. New Phytologist 207, 942–947.
LMA, density and thickness: recognizing different leaf shapes and correcting for their nonlaminarity.Crossref | GoogleScholarGoogle Scholar | 25967596PubMed |

Lamont BB, He T, Yan Z (2019) Fire as a pre-emptive evolutionary trigger among seed plants. Perspectives in Plant Ecology, Evolution and Systematics 36, 13–23.
Fire as a pre-emptive evolutionary trigger among seed plants.Crossref | GoogleScholarGoogle Scholar |

Laughlin DC, Delzon S, Clearwater MJ, Bellingham PJ, McGlone MS, Richardson SJ (2020) Climatic limits of temperate rainforest tree species are explained by xylem embolism resistance among angiosperms but not among conifers. New Phytologist
Climatic limits of temperate rainforest tree species are explained by xylem embolism resistance among angiosperms but not among conifers.Crossref | GoogleScholarGoogle Scholar | 31981422PubMed |

Loveless AR (1962) Further evidence to support a nutritional interpretation of sclerophylly Annals of Botany 26, 551–561.
Further evidence to support a nutritional interpretation of sclerophyllyCrossref | GoogleScholarGoogle Scholar |

Macklin ED (1927) A revision of the ‘distyla complex’ of the genus Casuarina. Transactions of the Royal Society of South Australia 51, 257–286.

Macphail MK, Hill RS (2018) What was the vegetation in northwest Australia during the Paleogene, 66–23 million years ago? Australian Journal of Botany 66, 556–574.
What was the vegetation in northwest Australia during the Paleogene, 66–23 million years ago?Crossref | GoogleScholarGoogle Scholar |

Martin HA (2006) Cenozoic climatic change and the development of arid vegetation in Australia. Journal of Arid Environments 66, 533–563.
Cenozoic climatic change and the development of arid vegetation in Australia.Crossref | GoogleScholarGoogle Scholar |

Maximov NA (1931) The physiological significance of the xeromorphic structure of plants. Journal of Ecology 19, 273–282.
The physiological significance of the xeromorphic structure of plants.Crossref | GoogleScholarGoogle Scholar |

McGowran B, Holdgate GR, Li Q, Gallagher SJ (2004) Cenozoic stratigraphic succession in southeastern Australia. Australian Journal of Earth Sciences 51, 459–496.
Cenozoic stratigraphic succession in southeastern Australia.Crossref | GoogleScholarGoogle Scholar |

McWilliam JR, Mison K (1974) Significance of the C4 pathway in Triodia irritans (spinifex), a grass adapted to arid environments. Australian Journal of Plant Physiology 1, 171–175.

Moody ML, Les DH (2007) Phylogenetic systematics and character evolution in the angiosperm family Haloragaceae. American Journal of Botany 94, 2005–2025.
Phylogenetic systematics and character evolution in the angiosperm family Haloragaceae.Crossref | GoogleScholarGoogle Scholar | 21636395PubMed |

Morton SR, Stafford Smith DM, Dickman CR, Dunkerley DL, Friedel MH, McAllister RRJ, Reid JRW, Roshier DA, Smith MA, Walsh FJ, Wardle GM, Watson IW, Westoby (2011) A fresh framework for the ecology of arid Australia. Journal of Arid Environments 75, 313–329.
A fresh framework for the ecology of arid Australia.Crossref | GoogleScholarGoogle Scholar |

Onstein RE, Linder HP (2016) Beyond climate: convergence in fast evolving sclerophylls in Cape and Australian Rhamnaceae predates the Mediterranean climate. Journal of Ecology 104, 665–677.
Beyond climate: convergence in fast evolving sclerophylls in Cape and Australian Rhamnaceae predates the Mediterranean climate.Crossref | GoogleScholarGoogle Scholar |

Orians GH, Milewski AV (2007) Ecology of Australia: the effects of nutrient-poor soils and intense fires. Biological Reviews of the Cambridge Philosophical Society 82, 393–423.
Ecology of Australia: the effects of nutrient-poor soils and intense fires.Crossref | GoogleScholarGoogle Scholar | 17624961PubMed |

Orians GH, Solbrig OT (1977) A cost income model of leaves and roots with special reference to arid and semiarid areas. American Naturalist 111, 677–690.
A cost income model of leaves and roots with special reference to arid and semiarid areas.Crossref | GoogleScholarGoogle Scholar |

Paull R, Hill RS (2010) Early Oligocene Callitris and Fitzroya (Cupressaceae) from Tasmania. American Journal of Botany 97, 809–820.
Early Oligocene Callitris and Fitzroya (Cupressaceae) from Tasmania.Crossref | GoogleScholarGoogle Scholar | 21622446PubMed |

Prescott A, Venning J (1984) Aizoaceae. In ‘Flora of Australia. Vol. 4’. (Ed. AS George) pp. 19–61. (Australian Government Publishing Service: Canberra, ACT, Australia)

Raghu S, Walton C (2007) Understanding the ghost of Cactoblastis past: historical clarifications on a poster child of classical biological control. Bioscience 57, 699–705.
Understanding the ghost of Cactoblastis past: historical clarifications on a poster child of classical biological control.Crossref | GoogleScholarGoogle Scholar |

Read J, Sanson GD (2003) Characterizing sclerophylly: the mechanical properties of a diverse range of leaf types. New Phytologist 160, 81–99.
Characterizing sclerophylly: the mechanical properties of a diverse range of leaf types.Crossref | GoogleScholarGoogle Scholar |

Read J, Sanson GD, Lamont BB (2005) Leaf mechanical properties in sclerophyll woodland and shrubland on contrasting soils. Plant and Soil 276, 95–113.
Leaf mechanical properties in sclerophyll woodland and shrubland on contrasting soils.Crossref | GoogleScholarGoogle Scholar |

Read J, Sanson GD, de Garine-Wichatitsky M, Jaffre T (2006) Sclerophylly in two contrasting tropical environments: low nutrients vs low rainfall. American Journal of Botany 93, 1601–1614.
Sclerophylly in two contrasting tropical environments: low nutrients vs low rainfall.Crossref | GoogleScholarGoogle Scholar | 21642105PubMed |

Roth-Nebelsick A (2007) Computer-based studies of diffusion through stomata of different architecture. Annals of Botany 100, 23–32.
Computer-based studies of diffusion through stomata of different architecture.Crossref | GoogleScholarGoogle Scholar | 17483152PubMed |

Roth-Nebelsick A, Hassiotou F, Veneklaas EJ (2009) Stomatal crypts have small effects on transpiration: a numerical model analysis. Plant Physiology 151, 2018–2027.
Stomatal crypts have small effects on transpiration: a numerical model analysis.Crossref | GoogleScholarGoogle Scholar | 19864375PubMed |

Salleo S, Nardini A (2000) Sclerophylly: evolutionary advantage or mere epiphenomenon? Plant Biosystems 134, 247–259.
Sclerophylly: evolutionary advantage or mere epiphenomenon?Crossref | GoogleScholarGoogle Scholar |

Shao H-B, Chu L-Y, Jaleel CA, Zhao C-X (2008) Water-deficit stress-induced anatomical changes in higher plants. Comptes Rendus Biologies 331, 215–225.
Water-deficit stress-induced anatomical changes in higher plants.Crossref | GoogleScholarGoogle Scholar | 18280987PubMed |

Shields LM (1950) Leaf xeromorphy as related to physiological and structural influences. Botanical Review 16, 399–447.
Leaf xeromorphy as related to physiological and structural influences.Crossref | GoogleScholarGoogle Scholar |

Skelton RP, Anderegg LDL, Lamarque LJ (2019) Examining variation in hydraulic and resource acquisition traits along climatic gradients tests our understanding of plant form and function. New Phytologist 223, 505–507.
Examining variation in hydraulic and resource acquisition traits along climatic gradients tests our understanding of plant form and function.Crossref | GoogleScholarGoogle Scholar | 31125111PubMed |

Toon A, Crisp MD, Gamage H, Mant J, Morris DC, Schmidt S, Cook LG (2015) Key innovations or adaptive change? A test of leaf traits using Triodiinae in Australia. Scientific Reports 5, 12398
Key innovations or adaptive change? A test of leaf traits using Triodiinae in Australia.Crossref | GoogleScholarGoogle Scholar | 26215163PubMed |

Turner IM (1994) Sclerophylly: primarily protective? Functional Ecology 8, 669–675.
Sclerophylly: primarily protective?Crossref | GoogleScholarGoogle Scholar |

van der Merwe AM, van der Walt JJA, Marais EM (1994) Anatomical adaptations in the leaves of selected fynbos species. South African Journal of Botany 60, 99–107.
Anatomical adaptations in the leaves of selected fynbos species.Crossref | GoogleScholarGoogle Scholar |

Voznesenskaya EV, Akhani H, Koteyeva NK, Chuong SDX, Roalson EH, Kiirats O, Franceschi VR, Edwards GE (2008) Structural, biochemical, and physiological characterization of photosynthesis in two C4 subspecies of Tecticornia indica and the C3 species Tecticornia pergranulata (Chenopodicaceae) Journal of Experimental Botany 59, 1715–1734.
Structural, biochemical, and physiological characterization of photosynthesis in two C4 subspecies of Tecticornia indica and the C3 species Tecticornia pergranulata (Chenopodicaceae)Crossref | GoogleScholarGoogle Scholar | 18390850PubMed |

Wilson PG (1984) Chenopodiaceae. In ‘Flora of Australia. Vol. 4’. (Ed. AS George) pp. 81–317. (Australian Government Publishing Service: Canberra, ACT, Australia)

Wood JG (1934) The physiology of xerophytism in Australian plants: the stomatal frequencies, transpiration and osmotic pressures of sclerophyll and tomentose-succulent leaved plans. Journal of Ecology 22, 69–87.
The physiology of xerophytism in Australian plants: the stomatal frequencies, transpiration and osmotic pressures of sclerophyll and tomentose-succulent leaved plans.Crossref | GoogleScholarGoogle Scholar |

Xu T, Hutchinson M (2011) ‘ANUCLIM version 6.1: user guide.’ (The Australian National University Fenner School of Environment and Society: Canberra, ACT, Australia)

Yates CJ, Gosper CR, Hopper SD, Keith DA, Prober SM, Tozer MG (2017) Mallee woodlands and shrublands: the Mallee, Muruk/Muert and Maalok vegetation of southern Australia. In ‘Australian vegetation’, 3rd edn. (Ed. DA Keith) pp. 570–598. (Cambridge University Press: Cambridge, UK)