Elegance versus Speed: Examining the Competition between Conifer and Angiosperm Trees Author(s): Timothy J. Brodribb, Jarmila Pittermann, and David A. Coomes Reviewed work(s): Source: International Journal of Plant Sciences, Vol. 173, No. 6 (July/August 2012), pp. 673- 694 Published by: The University of Chicago Press Stable URL: http://www.jstor.org/stable/10.1086/666005 . Accessed: 24/07/2012 13:46 Your use of the JSTOR archive indicates your acceptance of the Terms & Conditions of Use, available at . http://www.jstor.org/page/info/about/policies/terms.jsp . JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact [email protected]. . The University of Chicago Press is collaborating with JSTOR to digitize, preserve and extend access to International Journal of Plant Sciences. http://www.jstor.org
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Elegance versus Speed: Examining the Competition between Conifer and Angiosperm TreesAuthor(s): Timothy J. Brodribb, Jarmila Pittermann, and David A. CoomesReviewed work(s):Source: International Journal of Plant Sciences, Vol. 173, No. 6 (July/August 2012), pp. 673-694Published by: The University of Chicago PressStable URL: http://www.jstor.org/stable/10.1086/666005 .Accessed: 24/07/2012 13:46
Your use of the JSTOR archive indicates your acceptance of the Terms & Conditions of Use, available at .http://www.jstor.org/page/info/about/policies/terms.jsp
.JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range ofcontent in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new formsof scholarship. For more information about JSTOR, please contact [email protected].
.
The University of Chicago Press is collaborating with JSTOR to digitize, preserve and extend access toInternational Journal of Plant Sciences.
ELEGANCE VERSUS SPEED: EXAMINING THE COMPETITIONBETWEEN CONIFER AND ANGIOSPERM TREES
Timothy J. Brodribb,1,* Jarmila Pittermann,y and David A. Coomesz
*School of Plant Science, University of Tasmania, Hobart, Tasmania 7001, Australia; yDepartment of Ecology and Evolutionary Biology,University of California, Santa Cruz, California 95064, U.S.A.; and zForest Ecology and Conservation Group, Department
of Plant Sciences, University of Cambridge, Downing Street, Cambridge CB2 3EA, United Kingdom
Angiosperm radiation in the Cretaceous is thought to have profoundly diminished the success of the conifers,the other major woody plant group present at the time. However, today the conifers persist and often thrivedespite their supposed inferiority in vegetative and reproductive function. By exploring this apparent conflictfor global tree dominance, we seek here to reveal patterns that explain not only how the allegedly inferiorconifers persist among angiosperms but also why some conifer groups became extinct in the Cretaceous. Wefind that despite the profound contrast between the dominant conifer families in the Southern and NorthernHemispheres, all conifers can be characterized by a common set of functional attributes that allow them toexist in an important group of niches, from high latitudes to the equator. In these environments, conifers areoften highly efficient at outcompeting, outliving, or outsurviving angiosperms. Hence, we conclude that conifersuccess cannot be dismissed as being uniquely associated with habitats that are unfavorable for angiosperms.
Keywords: conifer, angiosperm, evolution.
Introduction
Gymnosperms and angiosperms are often depicted as arch-rivals in the competition for space in forest canopies. Thisadversarial image derives from paleoecological reconstruc-tions that suggest angiosperm radiation during the Creta-ceous occurred at the expense of gymnosperm diversity andabundance (Lidgard and Crane 1988). Such evidence of a ma-jor transition in plant diversity toward the end of the Creta-ceous has led evolutionary ecologists to propose an array oftheories to account for angiosperm dominance over conifersin both historical and contemporary contexts. In terms of di-versity, gymnosperms are manifestly outgunned by angio-sperms, which have a superior capacity to diversify due torelatively high reproductive efficiency, self-incompatibility,and reduced generation time (Crepet and Niklas 2009). Thisangiospermous reproductive advantage probably stems fromfloral evolution; however, diversity and ecological dominanceare not synonymous, and explanations for the apparent dis-placement of gymnosperms from their ecologically dominantrole in the canopy of Early Cretaceous forests have largelyfocused on vegetative characteristics (Carlquist 1975; Bond1989; Berendse and Scheffer 2009; Brodribb and Feild2010). This latter category of ecological dominance is the fo-cus of our discussion.
One gymnosperm group, the conifers, remain as a majorcontender for canopy dominance across the globe. In this re-view, we determine whether generalizations about the ecol-ogy, physiology, and biogeography of this key gymnosperm
clade can explain their continued success in the face of over100 million years of angiosperm competition. Of particularinterest is the stimulating hypothesis of Bond (1989) that co-nifer persistence can be explained by vegetative competitionin the seedling phase. By portraying conifer seedlings as slow‘‘tortoise’’ regenerators compared with the fast-growing an-giosperm ‘‘hare’’ seedlings, Bond suggested that conifers com-pete where angiosperms are unable to realize their maximumgrowth potential because of environmental limitations onphotosynthesis and growth. Abiotic stress thus reduces thegrowth of angiosperm seedlings to similar rates as those ofconifers, which are intrinsically constrained by inferior watertransport in wood and leaves. Here we explore the evolution-ary history of conifers, highlighting the distinct nature ofPodocarpaceae and Pinaceae in the Southern and NorthernHemispheres, respectively. The contrasting history and ecol-ogy of these key conifer families raises questions about theconcept of a predictable rule for conifer–angiosperm compe-tition. In an attempt to reconcile the observed diversity in co-nifer biogeography with the functional characterization ofconifers, we reexamine key aspects of conifer physiologicaland trait evolution, seeking general principles that may be usedto define global conifer ecology. We conclude that, althoughmany conifer species have conservative traits that enable persis-tence in stressed environments, others are successful pioneersof disturbed habitats. This allows modern conifers to escapehead-on competition for light with broad-leafed angiospermsand to occupy a much broader range of habitats than is in-cluded in Bond’s hypothesis. We emphasize that different line-ages of conifers (specifically the Cupressaceae, Podocarpaceae,and Pinaceae) are distinct in the environmental stressors theytolerate, giving rise to distinct biogeographic distributions ofthese clades.
History and Biogeography of Conifer–AngiospermCompetition
Traditionally, the evolution of angiosperms has been por-trayed as a dire competitive challenge for many Mesozoicplant groups, including conifers (Krassiliov 1978; Knoll 1984).However, the degree to which angiosperm radiation resultedin conifer extinction and displacement is a matter of debate.Here we examine the three largest living conifer families todetermine whether the ecology of extant conifers supports ageneral functional limitation argument whereby conifers aredisadvantaged relative to angiosperms (Bond 1989). As a pre-text to this discussion, it is important to note that the generalconcept of angiosperm superiority over conifers is not borneout by an examination of contemporary forest cover world-wide. The living conifers are a very successful group, and fewangiosperm families could compete with the largest coniferfamilies for biomass or productivity. The only woody plant bi-ome that appears to be generally hostile to conifers is lowlandequatorial rain forest, where very high productivity and com-petition for light creates a bias for large and highly photosyn-thetic leaves with low leaf mass per unit area (Brodribb andHill 1997), characteristics that are absent from any conifertaxon (Wright et al. 2004). Forests at higher latitudes and alti-tudes typically contain mixtures of conifers and angiosperms,and the division of conifer taxa among these regions is wellstructured, providing useful information about the history ofevolutionary competition between these two groups.
Perhaps the most challenging aspect in characterizing conifer–angiosperm competition is the highly distinct nature of the twomost successful conifer families, Podocarpaceae and Pinaceae.The result of this familial differentiation on the global biogeog-raphy of conifers is profound because it produces a taxonomicand ecological split between the Northern and Southern Hemi-spheres. Conifers in the Northern Hemisphere are highly suc-cessful in regions subject to seasonal freezing, while in themilder oceanic Southern Hemisphere, freezing conditions areless prevalent and conifers are much patchier in distribution butreach their highest diversity in wet tropical forests. This patternderives largely from the contrasting distributions and ecologiesof the two largest conifer families, Pinaceae and Podocarpaceae,but similar biases are evident in Araucariaceae and Taxaceae. Infact, Cupressaceae is the only family that is evenly distributedbetween the hemispheres (fig. 1). Biogeographical zonationseems to have characterized the distribution of several coniferfamilies as far back as the Mesozoic, with Pinaceae (Millar1998) and Podocarpaceae (Hill and Brodribb 1999) fossils al-most always being restricted to within the extant range ofthe families and the extinct Cheirolepidiaceae inhabiting lowlatitudes (Alvin 1982). Other conifer families appear to havebeen more cosmopolitan in the past, with Araucariaceae dis-tributed globally (Stockey 1994) and Northern HemisphereCupressaceae such as Sequoia found in the early Cenozoic inAustralia (Peters and Christophel 1978).
Pinaceae Domination of the Northern Hemisphere
Pinaceae are the most successful of all conifers; curiously,however, this success is restricted (with the exception of onespecies) to the Northern Hemisphere. The northern bias of
the family is repeated in the fossil record, with no fossil Pina-ceae having ever been identified south of the equator. Analy-sis of fossil deposits throughout the Northern Hemisphere(Mirov 1967; Rothwell et al. 2012) and molecular evidence(He et al. 2012) suggest an Early to Middle Mesozoic originof Pinaceae at high northern latitudes and of Pinus at middlenorthern latitudes (Millar 1998). Although extant Pinaceaeforests extend from the Arctic Circle to the tropics, the diver-sity of Pinaceae today remains highest at the middle latitudes.The strongest climatic correlate is the distribution of mostmodern Pinaceae species in habitats subject to freezing (Farjon2010). Not only is the association between the distribution ofPinaceae and cool temperatures strong in extant species, thereis evidence that this may have been a feature of the familythroughout its evolution. Indeed, the fluctuating fortunes ofPinaceae appear to have been much better correlated withtemperature than other phenomena throughout the past 100million years, including the radiation of angiosperms. Fossilsof Pinus are rare or globally absent during warm periods inthe Paleocene and Eocene, while cooler periods are character-ized by an abundance of Pinus fossils at middle latitudes(Millar 1993). Migration of pines between high and middlelatitudes is a recurrent theme during the climate oscillations ofthe Neogene, with Pinaceae apparently contracting toward theArctic during warm periods and moving southward undercooler conditions (Mirov 1967; Millar 1998).
As discussed in detail below, the wood of conifers is wellsuited to freezing because the small size of its conduits pre-vents freeze-thaw embolism. This, combined with a photosyn-thetic physiology that is well adapted to downregulationduring freezing (Ottander and Oquist 1991), raises the possi-bility that Pinaceae have always occupied forests prone tofreezing. It is therefore conceivable that angiosperm evo-lution may have had little effect on the Pinaceae niche andthis conifer family has maintained or increased its impor-tance as freezing climates extended to lower latitudes duringthe latter half of the Cenozoic. It is difficult to directly assessthe impact of angiosperm evolution on Pinaceae, because an-giosperms radiated at a time when temperature and humidityat middle latitudes were high and hence the distribution ofPinaceae was minimal (Millar 1998). However, the paradigmof angiosperm domination does not really apply to contem-porary forest cover in most of the land masses of the North-ern Hemisphere. Indeed, it seems that since the inception ofPleistocene glacial cycles, the Pinaceae have been aggressivecompetitors capable of dominating entire regions such as theboreal zone, often to the exclusion of angiosperm trees. Twofactors appear to be closely linked to the success of Pinaceae.First, their tracheid-bearing vascular system is highly resistantto freeze-thaw embolism (see below). Second, in Pinus in par-ticular, photosyntheticically efficient needle leaves can pro-duce maximum photosynthetic rates that are equivalent to orgreater than those of associated angiosperm trees (Turnbullet al. 1998; Brodribb and Feild 2008), and low wood densityenables fast-volume growth rates under high-light conditions(Becker 2000). In this way, the classic Pinus pioneer ecologylargely seems to defy the analogy of Bond (1989) that coniferseedling growth was tortoise-like compared with that of thehare-like angiosperms. Indeed, considering the rapid dispersalof Pinaceae into postglacial landscapes across the Northern
674 INTERNATIONAL JOURNAL OF PLANT SCIENCES
Hemisphere, conifers do seem to be more deserving of the‘‘hare’’ title (Gear and Huntley 1991).
Within the broad environmental envelope established bywinter cold, local abundance of Pinaceae is strongly influ-enced by nutrient cycling. Pinaceae dominate boreal andmontane regions of the Northern Hemisphere, where lowtemperatures and slow decomposition hamper recycling oforganic nitrogen by the soil microbial community. Pines incool and warm temperate regions often attain the greatestabundance on sandy or shallow soils (Richardson and Run-
del 1998), although the link between soil type and coniferabundance may be blurred by disturbance history, which alsohas strong influences on local abundance patterns (Becker2000). Pinaceae are associated with poor soils because theirneedles live longer than the leaves of co-occurring angio-sperm trees, reducing the flux of nutrients to the decomposercommunity via litterfall and increasing the trees’ nutrient useefficiency. Deciduousness is effective in preventing damage totemperate angiosperm trees over the cold winter months, butat higher latitudes where winter conditions are much harsher
Fig. 1 Frequency distribution plots of the three major conifer families from Arctic to Antarctic latitudes. Podocarps and Pinaceae show strong
latitudinal differentiation, while Cupressaceae are successful in both hemispheres. The peak diversity of Podocarpaceae at equatorial latitudes
contrasts strongly with the pattern in both Cupressaceae and Pinaceae.
675BRODRIBB ET AL.—COMPETITION BETWEEN CONIFERS AND ANGIOSPERMS
it is evergreen conifers that dominate; this indicates the criti-cal role of mineral nutrition alongside winter cold in givingconifers a competitive advantage in boreal regions.
Pinaceae diversity reaches a maximum at temperate lati-tudes, although it is also significant in the northern tropics,including in China and Mexico, where this family is commonat altitudes subject to freezing or fire (Agee 1998; Farjon1996). With a few exceptions (Pinus canariensis and Pinuscaribaea), Pinaceae are not capable of growing at low alti-tudes in the tropics; their diversity drops very quickly whenmoving from the Tropic of Cancer to the equator, with onlyone species (Pinus merkusii in Sumatra) recorded in naturalforest in the Southern Hemisphere. The rapid decline in thesuccess of Pinaceae at low latitudes has been attributed tothe absence of freezing habitats and high rainfall close to theequator. Without fire disturbances to open the canopy, Pina-ceae needles are ineffective at tolerating the deep shade castby angiosperms (Brodribb and Feild 2008). Leaves of Pina-ceae are characteristically needle shaped and hence rather in-efficient at harvesting light of low intensity because of boththeir relatively high leaf mass per unit area (Reich et al. 2007)and self-shading (Leverenz and Hinckley 1990). Hence, thePinaceae needle leaf morphology is not likely to be competitivewith the fast-growing angiosperms producing large, thinleaves in the tropics. In this respect, it is interesting to notethat of the few Pinaceae species living close to the equatorin Vietnam, several (e.g., Keteleeria and Pinus krempfii) haveflattened leaves that enable them to grow in the understoryof angiosperm-dominated forests (Brodribb and Feild 2008).However, the anatomical adaptations linked to leaf flatteningin these species render these leaves less sophisticated and lessefficient than the multivein leaves of angiosperms or the flat-tened leaves in many of the Podocarpaceae genera that in-habit the tropics (see below).
One common ecological attribute of modern Pinaceae, andof Pinus in particular, is the capacity to regenerate as pio-neers after fires, which is related to their light-demandingneedle leaf morphology. In sharp contrast, the Podocarpaceaeare typically very fire sensitive, with the notable exception ofPodocarpus drouynianus in Australia (Chalwell and Ladd2005). Many species of Pinaceae develop thick bark that pro-tects trees from low-intensity ground fires; Pinus species inparticular appear to use fire as a means of escaping competi-tion with angiosperms for long enough to complete their lifecycles (see below). Given the apparent abundance of fire-prone vegetation in the Southern Hemisphere, the absence ofPinaceae here is rather enigmatic, particularly considering thesuccessful northward movement of Podocarpaceae from theSouthern Hemisphere into Asia and Central America (Morley2011). It is possible that the absence of Pinaceae in theSouthern Hemisphere is linked to the much more limitedexistence of conditions below the tree line where freezingis common. Climatic differences between hemispheres areborne out by much lower minimum temperatures at the treeline in the Northern Hemisphere compared with the south.These differences are highly significant, because evergreen an-giosperms often dominate the tree line in mountains in theSouthern Hemisphere, where they possess small-diameter xy-lem vessels that are resistant to moderate, low-frequency freez-ing events (Feild and Brodribb 2001). By contrast, even at sea
level in the middle to high latitudes of the Northern Hemi-sphere, plants are exposed to a high frequency of cold eventsthat are sufficiently harsh to freeze xylem sap in tree trunks.This provides a significant advantage to Pinaceae with theirsmall, freeze-thaw-resistant tracheids (Sperry et al. 1994). Itis noteworthy that Pinaceae species have become invasiveabove the tree line in some parts of South America and NewZealand (Wardle 1985). This suggests that there exists poten-tial for Pinaceae to colonize some alpine zones in the South-ern Hemisphere, although climate analysis suggests that thereis only a narrow ‘‘vacant altitudinal belt’’ for introduced Pina-ceae (Jobbagy and Jackson 2000).
It is unclear why Pinaceae species have not been able todisperse through Central America and Southeast Asia intothe Southern Hemisphere alpine zone over the past 5 millionyears, when Northern and Southern Hemisphere landmassescame into contact. However, there is evidence that the Ceno-zoic proliferation of angiosperms in the equatorial zone ledto the creation of a highly productive and deeply shaded rainforest belt (Boyce et al. 2010) that is hostile to typical needle-leaved, shade-intolerant Pinaceae. Given the relatively recentconnections between northern and southern landmasses inthe Americas and Southeast Asia, it is possible that Cenozoicdevelopment of an angiosperm equatorial forest created a bar-rier to Pinaceae penetration into the Southern Hemisphere(Brodribb and Feild 2008). Another possible limitation forsouthward-bound Pinaceae is the absence of suitable fungalsymbionts in the Southern Hemisphere. Many species ofPinaceae have become invasive in temperate regions of theSouthern Hemisphere (Richardson and Rejmanek 2004),having spread from forestry block, but plantations were un-successful until suitable ectomycorrhizal fungi were intro-duced from these species’ home ranges (Pringle et al. 2009).Indeed, the mycorrhizal fungi associated with invasive Pinuscontorta in New Zealand are all nonnative or cosmopolitanspecies, with no evidence of novel associations with nativemutualists (Dickie et al. 2010), emphasizing the reliance ofpines on coinvasion by mutualists.
Podocarpaceae Evolution in the Tropics
Podocarps are diverse and widespread in the Southern Hemi-sphere but, despite being the most successful conifer familythere, they are rarely dominant at a regional level in the wayPinaceae forests are in the Northern Hemisphere. Podocarpsexhibit an enormous morphological diversity, but ecologi-cally they are almost always restricted to rain forest commu-nities, where they coexist with angiosperms. Despite a wooddensity that is relatively high for conifers (Pittermann et al.2006a), the water transport system of podocarps is vulnera-ble to water stress–induced embolism, causing a family-widedrought sensitivity (see above). As a result, podocarps are absentfrom the type of dry forest communities in which Pinaceae andCupressaceae often thrive. However, a combination of significantshade tolerance and longevity appears to allow podocarps tocompete successfully with angiosperms, particularly where lowtemperatures or nutrients restrict angiosperm productivity. In to-tal, about three-quarters of all podocarp species predominateon soils that are either shallow, waterlogged, sandy, high alti-tude, or derived from ultramafic rocks rich in plant-toxic ele-
676 INTERNATIONAL JOURNAL OF PLANT SCIENCES
ments (Coomes and Bellingham 2011). Efficient nutrient usein podocarps is evidenced by typically long leaf life spanscompared with those of angiosperm associates in temperaterain forests (Lusk 2001; Coomes and Bellingham 2011).
Podocarps and Pinaceae express different nutrient associa-tions, with the former often associated with old lowland soilswith a phosphorus deficit while Pinaceae are very successfulin the nitrogen-limited soils of high altitudes and latitudes.This distinction may be linked to differing mycorrhizal as-sociations. Pinaceae tend to be ectomycorrhizal, with fungalsymbionts capable of extracting nitrogen directly from organicmatter, whereas Podocarpaceae are arbuscular mycorrhizal,with fungi associates from a basal group, Glomales, that lackthe capacity to break down organic matter but that are ef-fective at capturing phosphate from soils (Brundrett 2002;Smith and Read 2008). Thus, it may well be that SouthernHemisphere conifer species are better suited to growing onphosphorus-depleted soils. In New Zealand, for instance, tallpodocarps are prevalent in lowland rain forests, while ectomy-corrhizal angiosperms (in Nothofagaceae) dominate overmuch of the Southern Alps (Wardle 1984). Interestingly, theectomycorrhizal Douglas fir is starting to invade Nothofagusforests in the mountains of New Zealand and is showing signsof becoming a formidable competitor against the dominant na-tive tree (Dickie et al. 2010). The types of mycorrhizal fungithat are prevalent in a region depend on whether the nitrogenor the phosphorus supply is most threatening plant fitness(Read and Perez-Moreno 2003). There is virtually no nitro-gen in mineral soil, so the supply of this element to roots isdictated by rates of litter decomposition and nitrogen fixa-tion by microbes. Decomposition of organic matter is slow inregions with low mean annual temperatures, resulting in lim-ited nitrogen supply for plants growing in tundra, taiga, andboreal ecosystems and in tropical and temperate mountains(Aerts and Chapin 2000). Under these conditions, ectomycor-rhizal (alongside ericoid) associations often dominate, be-cause the fungi are physiologically capable of extractingnitrogen directly from organic matter in the litter and uppersoil layers. Many ectomycorrhizal fungi produce extracellularenzymes capable of degrading structural materials within de-tritus, enabling them to attack nutrient-containing polymerswith diffusible proteinase enzymes (Read et al. 1989). Thehyphae take up short-chain organic nitrogen produced byproteinases as well as NHþ
4 mineralized by generalist sapro-trophs. The situation in lowland temperate and tropical rainforests is quite different: detritus is decomposed rapidly, releas-ing nitrogen to plants in the process, while phosphorus isbound in aluminium sesquioxide complexes and leached fromsoils by heavy rainfall. Arbuscular mycorrhizal fungi dominatein most tropical rain forests.
The most striking contrast between Pinaceae and Podo-carpaceae emerges in the tropics, where podocarp diversityreaches a maximum and can occur anywhere from sea levelup to the tree line. Their abundance in tropical regions meansthat podocarps compete directly with angiosperms in tropicalrain forests (fig. 2), and there is strong evidence that a historyof competition with broad-leaf angiosperms has had a majorimpact on the adaptive morphology and function of podo-carps. Reconstructions of the morphological evolution ofpodocarp shoots show that, coincident with the angiosperm
radiation of the Late Cretaceous–Early Cenozoic period,there was a rise in the diversification rate of Podocarpaceaewith broadly flattened leaves and shoots (Biffin et al. 2012).These multiple independent origins of shoot flattening aregenerally associated with the development of water-conductingtracheids lying outside the midrib xylem that provide radialwater transport from the midrib to the leaf margin (Griffith1957; Brodribb and Holbrook 2005). This efficient alterna-tive to the angiosperm reticulate-vein leaf enables single-veined podocarp ‘‘needles’’ to achieve widths of >30 mm(fig. 2), which greatly enhances the efficiency of light harvest-ing and shade tolerance in these topical podocarps (Brodribband Hill 1999). During angiosperm diversification, the rateof speciation of imbricate podocarp species with lower light-use efficiency declined (Biffin et al. 2012), and this supportsthe idea that shoot flattening in podocarps was a response toangiosperm competition for light. One interpretation of theseobservations is that the invasion of broad-leaf angiospermsinto the tropics caused a change in the ecology and climateof the equatorial belt (Boyce et al. 2010), increasing rainfalland hence the competition for light in the understory. Asa result, narrow- and imbricate-leaved conifers seem to havebeen subsequently replaced by podocarps with large, flatphotosynthetic structures capable of efficient light harvesting.Other conifers such as Taxaceae (Amentotaxus, Austrotaxus,and Cephalotaxus) and Araucariaceae have also enjoyedsome success competing with broad-leaf angiosperms by pro-ducing large, flattened leaves. However, no tropical conifergroup comes close to the diversity of flattened morphologiesor the competitive success of tropical Podocarpaceae.
An ability to coexist with angiosperms in evergreen broad-leaf forest enables Podocarpaceae to extend into the northerntropics, but similar to Pinaceae at the equator, Podocarpaceaesuccess drops off rapidly north of the Tropic of Cancer. Rea-sons for this northward limit may include a combination ofdeclining rain forest environments due to reduced rainfallnorth of 20�N latitude and a rapid increase in freezing expo-sure, to which Pinaceae appear to be better adapted (Sakaiand Wardle 1978). Possibly because of the specialized leafanatomy in podocarps (an abundance of sclereids; Brodribb2011) or a sensitivity to drought (also significant under freez-ing conditions), Pinaceae are likely to outcompete podocarpsin environments where freezing creates opportunities forPinaceae to succeed. Dispersal rates could also limit the suc-cess of transhemispheric colonization of both Pinaceae andPodocarpaceae. However, in the light of evidence demon-strating very rapid dispersal in Pinaceae (Huntley and Webb1989) and long-distance dispersal of podocarps between Pa-cific islands, it seems that an ecological rather than vicarianceexplanation is more likely to account for latitudinal distribu-tional limits of both conifer families.
Global Cupressaceae
The third-largest conifer family, Cupressaceae, provides aninteresting comparison with Pinaceae and Podocarpaceae be-cause it exhibits a panglobal distribution. In the NorthernHemisphere, Cupressaceae show a similar latitudinal distri-bution to Pinaceae, with maximum diversity between 30�and 40�N and a rapid decline to only a few species in equa-
677BRODRIBB ET AL.—COMPETITION BETWEEN CONIFERS AND ANGIOSPERMS
torial regions. South of the equator, diversity rises again toa peak at a latitude of ;35�S, equivalent to that in the drylatitudes, where podocarp diversity falls to its lowest level inthis hemisphere. In both hemispheres, Cupressaceae adopta similar strategy whereby they coexist with Pinaceae or
Podocarpaceae in cool, wet environments but also have thecapacity to survive in very dry areas, where the efficient wa-ter transport capacity of angiosperms is limited by regularexposure to extreme water stress (Willson et al. 2008;Brodribb et al. 2010; Pittermann et al. 2010). Cupressaceae
Fig. 2 Podocarps Phyllocladus hypophyllus in Papua New Guinea (top) and Podocarpus dispermis in tropical northern Australia (bottom).
Both compete successfully with broad-leaf angiosperms in the understories of tropical rain forests, and both have divergent mechanisms for leaf
and shoot flattening that lead to the production of broad photosynthetic structures reminiscent of angiosperm leaves.
678 INTERNATIONAL JOURNAL OF PLANT SCIENCES
exhibit an extremely large range of xylem tolerance to watertension, from swamp-dwelling species that are highly vulnera-ble (e.g., Taxodium) to arid-zone species with the most water-stress-resistant xylem yet measured, Juniperus in the NorthernHemisphere (Willson et al. 2008) and Callitris in the South-ern Hemisphere (Brodribb et al. 2010). Diversity in xylemcavitation resistance appears to be an important adaptivetool for Cupressaceae, and one that is likely to have contrib-uted to the success of the family in both hemispheres. Itshould be noted that there are distinct north–south divisionsin the phylogeny of Cupressaceae after the divergence of theold Taxodiaceae groups (Gadek et al. 2000). Interestingly,within both of these subdivisions (Callitroideae in the SouthernHemisphere and Cupressoideae in the Northern Hemisphere)there are multiple origins of extreme drought tolerance, indi-cating that this capacity has favored diversification of theseclades but that extreme drought tolerance is not the ancestralcondition (Pittermann et al. 2012). Presumably, the higher costassociated with producing cavitation-resistant wood in angio-sperms (see above) prevents this group from competing effec-tively with conifers in dry habitats, particularly where drynessand cold are combined. The resultant domination of dry habi-tats by Juniperus and Cupressus in the Northern Hemisphereand Callitris and Widdringtonia in the Southern Hemisphere istempered only by intense fire, which greatly impedes the suc-cess of these species in most cases.
The preceding discussion paints a rather diverse picture ofconifer evolution, with major families following relativelydistinct evolutionary pathways. This apparent functional di-versity seems to defy a reductionist principle for predictingthe outcome of conifer–angiosperm competition, such as thatproposed by Bond (1989). However, an examination of thegeneral physiology of conifers suggests that the functionalamplitude of conifers is small compared with that of angio-sperms and that there is potential to explain the familial di-versity of interactions between conifers and angiosperms interms of generalities. In the following section, we review keyaspects of conifer function, including water transport.
General Functional Attributes of Conifers
William Bond was the first to link conifer and angiospermbiogeography and evolutionary strategy with xylem function,and his ideas have had a profound influence on comparativeplant ecophysiology. When commenting on the dominance ofangiosperms in the tropics and conifers in the NorthernHemisphere, many have argued that enhanced transport effi-ciency, courtesy of large vessels and complex venation patterns,equipped the angiosperms with a physiological supremacy thatis reflected in their rapid growth rates, particularly at the es-tablishment stage, during which the less vascularized coniferseedlings simply cannot compete (Carlquist 1975; Bond 1989;Brodribb et al. 2005a). The following section reviews recentprogress in our understanding of water transport, nutrient ac-quisition, and photosynthesis in conifers and angiosperms, firstby discussing key anatomical differences between these planttypes and the climatic drivers that have acted to favor one vas-cular strategy over another across the world’s biomes.
Hydraulic Efficiency in Conifers and Angiosperms
The main goal of xylem function is to move water fromroot to shoot with low resistance, thus minimizing the pres-sure drop associated with gravity and friction (Sperry 2003;McCulloh et al. 2010). A secondary requirement is canopysupport. Hence, the combined needs of transport efficiencyand support selected for a variety of secondary growth pat-terns, of which only the tracheid-based conifer and vessel-fiber-based angiosperm models remain common (Spicer and Groover2010). Conifers move water by means of xylem composed en-tirely of tracheids: dead, hollow, overlapping single cells rarelyexceeding 2 mm in length. By contrast, the more derived angio-sperm xylem relies on vessels: multicellular tubes composedof dead and hollow vessel elements stacked to create pipesthat can reach several meters in length and up to 500 mm inwidth. Vessels can be distributed in a ring or a diffuse-porouspattern and are embedded in a matrix of fibers, making themless abundant per unit area than tracheids (Ewers et al. 1989;Isnard and Silk 2009; McCulloh et al. 2010).
Vessels that are wide and long are considered to be the pin-nacle of hydraulic efficiency; in comparison, conifer xylem,with its narrow tracheids, should be doomed to extinction.Indeed, as early as in the Devonian, the need for low-resistancexylem selected for a 17-fold increase in tracheid diameter, fromthe narrow 8-mm-wide conduits of Cooksonia to the 140-mm-wide tracheids of the fern relative Stenomylon (Niklas 1985).Today, the largest conifer tracheids rarely exceed 40 mm in di-ameter, even in riparian species such as Taxodium (Pittermannet al. 2006b), and yet conduit size is critical to transport. Thisis because the hydraulic conductance (K; volume flow rate stan-dardized for the pressure gradient driving flow) of a conduitscales to the fourth power of the lumen radius, so even mar-ginal gains in size translate to major gains in flow (Zimmer-mann and Tyree 2002).
Despite the size limitations imposed on tracheids, some ofthe tallest and oldest plants in the world, such as the coastredwood (Sequoia sempervirens) and the bristlecone pine(Pinus longaeva), are conifers. Vast regions in the NorthernHemisphere are dominated by Pinaceae, while conifers suchas Agathis, Fitzroya, and Dacrycarpus are the largest andlongest-lived species south of the equator (Enright and Hill1995). Clearly, selection has acted on conifer xylem in a man-ner that compensated for its unicellular composition. In re-cent years, the ultrastructure of tracheids and vessels hascome under close scrutiny, revealing that the movement ofwater from one conduit to another through interconduit pitmembranes is just as important as its travel within tracheidand vessel lumens.
Pit membranes are permeable, partially digested regions ofthe primary conduit cell wall that are composed of celluloseand pectin polysaccharides (for details, see review by Choatet al. [2008]). In angiosperm vessels, pit membranes resemblea tightly woven fabric of microfibers with variable porosityand thickness but otherwise exhibit little structural variation(fig. 3; Jansen et al. 2009; Lens et al. 2011). By contrast, thepresence of the torus and margo regions readily distinguishthe conifer pit membrane from the angiosperm type. Themargo is the porous, netlike region of the membrane thatallows water flow between tracheids, and it supports the
679BRODRIBB ET AL.—COMPETITION BETWEEN CONIFERS AND ANGIOSPERMS
Fig. 3 Comparative anatomy of conifer and angiosperm xylem. A, Cross section of Quercus agrifolia wood stained with toluidine blue,
showing large, clear vessels surrounded by thick-walled fibers. B, SEM micrograph of a cross section of Betula nigra vessel wall showing pit
membranes connecting the two vessels. C, SEM micrograph of an exposed Acer negundo pit membrane with visible membrane pores (image
courtesy of B. Choat). D, Air seeding in angiosperms (see text). E, Cross section of Sequoia sempervirens xylem stained with toluidine blue. F,
centrally located torus: a dense, impermeable structure thatseals an air-filled tracheid from a functional, water-filledone (see below; Hacke and Jansen 2009; Delzon et al.2010; Pittermann et al. 2010).
What explains the dimorphism of angiosperm and torus-margo pit membranes? The answer lies in the hydraulic resis-tance conferred by these structures and its effect on xylem sapflow in unicellular versus vessel-based xylem. On a pit areabasis, the resistance (inverse of conductance) of the torus-margo pit membrane is on average 5:7 6 1:3 MPa s m�1,nearly one-sixtieth that of the angiosperm pit membrane(336 6 81 MPa s m�1; Pittermann et al. 2005). On a sapwoodarea basis, this means that conifers and angiosperms withequivalent mean conduit diameters can exhibit comparable hy-draulic conductivity because the low hydraulic resistance of-fered by the porous margo region of the conifer pit membranecompensates for the shorter length of the conifer tracheids andthe more frequent tracheid-to-tracheid crossings (Pittermannet al. 2005; Sperry et al. 2006). Indeed, in the absence of torus-margo pitting, tracheid-based xylem resistivity is predicted toincrease 38-fold, on account of passage through the much lessporous, homogenous pit membranes.
The torus-margo pit membrane thus confers a tremendous hy-draulic advantage to long-distance transport in an otherwise an-cestral, tracheid-based vascular system that may have constrainedthe physiological development of ferns, basal angiosperms, andcycads as well as extinct tracheid-based flora with secondaryxylem (Sperry 2003; Pittermann 2010; Wilson and Knoll 2010;Pittermann et al. 2011). Given the high frictional resistance asso-ciated with both short conduits and homogenous pit membranes,it is unlikely that conifers could compete with angiosperms innorthern temperate habitats or reach their spectacular heightswithout torus and margo pitting (Koch et al. 2004; Pittermannet al. 2005; Burgess et al. 2006; Domec et al. 2008).
Research over the past decade has shown that the gap in hy-draulic aptitude between conifers and angiosperms has nar-rowed, but it is important to emphasize that not even high pitmembrane conductance can compensate for the developmentaland hydraulic limits imposed on conifer tracheid dimensions.Indeed, the evolution of long and wide vessels allowed the an-giosperms to explore peaks in hydraulic conductivities that areunmatched by conifers. For example, lianas and vines areregarded as paragons of hydraulic efficiency by virtue of theirexceptionally large vessels, which allow these climbers totransport water over 100 times more efficiently than gymno-sperms (Zimmermann and Tyree 2002). By relying on plantsand other external structures for support, climbing angio-sperms minimize investment in nonconductive xylem tissuesuch as fibers and thus maximize transport with large con-duits that are structurally irrelevant though hydraulically
efficient (see below). Presumably, it is the canalized develop-mental pattern of homoxylous wood that precluded the evo-lution of viny conifers (with broad, innervated leaves) andthus set a low upper limit on the hydraulic capacity of coni-fer xylem. Gnetales, a vessel-bearing gymnosperm lineage, isthe exception that proves the rule, because several species inthe genus Gnetum have evolved lianescence (Feild and Balun2008). However, the hydraulic capacity of these plants is, onaverage, one-fifth that of angiosperm vines.
Trade-Offs Associated with Drought Stress Resistancein Conifer and Angiosperm Xylem
Depending on their habitat, terrestrial plants may experi-ence water deficit on a daily basis. Drought stress can causeair to enter the xylem; if a large proportion of xylem con-duits contain air rather than water, hydraulic transport issignificantly impeded. Not surprisingly, plants have evolvedways to increase the drought-stress tolerance of their xylemtissue, but such resilience typically requires a sacrifice in theeconomy or efficiency of other vascular traits. The followingsection examines the hydraulic and construction costs associ-ated with cavitation resistance, focusing on these trade-offsfirst at the pit membrane level and then the xylem tissue levelin both conifers and angiosperms.
Aside from facilitating water transport throughout the xy-lem, pit membranes function to isolate functional, water-filledconduits from those that are filled with air (fig. 3). Becausewater moves through a plant in a state of negative potential ortension, the water column is vulnerable to the entry of air(cavitation). Air-filled or embolized conduits cannot conductwater and so, unless the conduits are repaired, extensive em-bolism causes stomatal closure or plant death (Hubbard et al.2001; McDowell et al. 2008). Plants may contend with drought-induced embolism on a seasonal or even a daily basis (Arandaet al. 2005; Li et al. 2007), and there is consensus that duringdrought stress it is the pit membranes that are the primary sitesof air entry (Choat et al. 2008; Christman et al. 2009; but seeJacobsen et al. 2005 for alternative hypotheses).
In angiosperms, cavitation occurs when the pressure differ-ence between an air-filled vessel and an adjacent water-filledvessel (DPx) exceeds the meniscal strength of the largest porein the pit membrane (DP�x) as described by the Young-Laplaceequation:
DP�x ¼2t
r;
where t is the surface tension of water and r is the radius ofthe largest membrane pore (Cochard et al. 1992; Choat et al.2008; Christman et al. 2009). A simple prediction would
TEM micrograph of a cross section of an S. sempervirens torus-margo pit membrane, where T indicates the torus. The thin strands of the margo
are not visible. (Image courtesy of S. Jansen.) G, Face view of a Sequoiadendron giganteum torus-margo pit membrane. Water moves from onetracheid to another through the margo strands that support the torus. (Image courtesy of B. Choat.) H, The function of the torus-margo pit
membrane. When tracheids on both sides of the membrane are water filled, the pit membrane remains in a neutral position (left). Should one
tracheid become air filled, the pit membrane is pulled against the pit aperture in the direction of the functional conduit (center). Air seeding occurs
when the xylem pressure in the water-filled conduit exceeds the mechanical strength of the pit membrane and the torus slips from its sealingposition, allowing air to enter the functional conduit and creating an embolism.
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be that angiosperms with larger membrane pore diametersshould be more vulnerable to cavitation by air seeding; yet,this idea has received mixed empirical support depending onthe species examined and the experimental approach used.The ‘‘rare pore’’ or ‘‘pit area’’ hypothesis first proposed byWheeler et al. (2005) argued that the probability of air seed-ing increases with pit area, because a greater pit area is morelikely to give rise to a large pore: the weak link that rendersthe xylem vulnerable to air seeding. Support for this has beenfound across a broad sampling of angiosperms (Hacke et al.2006, 2007; Hacke and Jansen 2009). However, more tar-geted work on Acer species with variable cavitation resis-tance has revealed that vulnerability to air seeding is closelyrelated to pit membrane thickness and porosity rather thanpit membrane quantity (Christman et al. 2009; Lens et al.2011; see also Hacke and Jansen 2009; Jansen et al. 2009).In general, it appears that both pit membrane anatomy andabundance contribute to cavitation resistance in angiosperms,although the relative importance of these traits across differ-ent angiosperm lineages remains unclear.
The conifer pit membrane also protects against the spreadof air, but it functions differently. A water-filled tracheid isisolated from an embolized one by an aspirated pit mem-brane, whereby the torus seals over the pit aperture, therebypreventing the spread of air (Sperry and Tyree 1990; Choatet al. 2008; Cochard et al. 2009). The bulk of the evidencesuggests that cavitation occurs when the torus is displacedfrom its sealing position because of negative xylem pressure(Sperry and Tyree 1990; Delzon et al. 2010). Consistent withthis hypothesis, pit membranes in cavitation-resistant coniferxylem exhibit a high degree of torus–aperture overlap, a trenddriven primarily by a reduction in pit aperture diameter inCupressaceae and Pinaceae (Domec et al. 2008; Hacke andJansen 2009; Pittermann et al. 2010). Interestingly, torusthickness increases with greater cavitation resistance in Cup-ressaceae but not in Pinaceae, which suggests that torus flex-ibility may also contribute to effective sealing (Hacke andJansen 2009; Pittermann et al. 2010). Pit membranes in otherimportant families such as Podocarpaceae and Araucariaceaehave not been scrutinized to the same level of anatomical de-tail, but a broad survey by Delzon et al. (2010) suggests thatthe presence of greater torus–aperture overlap in cavitation-resistant conifers is a conserved trait.
Broadly speaking, can we say that the torus-margo mem-brane is superior to the angiosperm type? Cavitation resis-tance is under strong selection in woody plants, and on thewhole, conifers and angiosperms show an equivalent range ofcavitation resistance, indicating that homogenous and torus-margo pit membranes are equally functional in preventing airseeding (Pittermann et al. 2005). Angiosperm pit membranespersist despite their high hydraulic resistance, which suggeststhat they may confer important although less obvious func-tional advantages. For example, homogenous pit membranesmay be an asset in angiosperms that routinely refill theirembolized vessels, such as grapevine (Sperry et al. 1987; Bro-dersen et al. 2010), bay laurel, and rice (Hacke and Sperry2003; Salleo et al. 2004; Stiller et al. 2005). These membranespotentially resist mechanical damage caused by air seeding(cavitation fatigue) and simultaneously serve to isolate con-duits undergoing active refilling from those that are functional
and under tension (Hacke et al. 2001; Zwieniecki and Hol-brook 2009). By contrast, it appears that once the conifertorus-margo pit membrane is aspirated and displaced fromthe aperture, stretching and mechanical damage of themargo strands cannot be repaired and the associated tra-cheids remain dysfunctional (Sperry and Tyree 1990). Re-cent evidence indicates that when they are exposed tomildly negative pressures, conifer tracheids may exhibit amechanism for embolism repair (McCulloh et al. 2010), sug-gesting that membranes stretched within their elastic limitsmay spring back to their original functional position, notunlike the ‘‘strong and flexible’’ membranes first describedby Hacke et al. (2004).
Characterizing the carbon investment and hydraulic costsassociated with cavitation resistance at the xylem tissue levelis straightforward in conifers but less so in angiosperms.Hence, a basic comparison of xylem-level structural differ-ences between these wood types is a useful starting point.Angiosperms exploit a larger range of life-history strategiesand have evolved more complex xylem structures associated,for example, with the climbing habit and ring- and diffuse-porous wood. At a minimum, it is the fiber- and vessel-basedstructure of angiosperm xylem that represents a derived andhighly adaptive departure from the ancestral unicellular, tracheid-based xylem of conifers. This is because the two different celltypes allow for a division of labor whereby fibers serve ina biomechanical capacity, supporting the shoot, whereas ves-sels evolved to function solely for the purpose of water trans-port. By contrast, conifer tracheids perform tasks of watertransport as well as canopy support. Because angiosperm fi-bers are single celled and narrow and occupy a higher frac-tion of the xylem than vessels, they represent a substantiallygreater carbon investment relative to the conifers’ tracheid-based xylem. Indeed, average wood densities in northern tem-perate angiosperms can be over 40% greater in angiosperms(hardwoods) than in conifers (Hacke et al. 2001). It is not un-likely that the ‘‘cheaper’’ xylem of conifers, in combinationwith their evergreen habit, may explain why conifers succeedin habitats with low resource availability, where selection fa-vors more economically conservative life-history strategies(Bond 1989; Hacke et al. 2001; Wright et al. 2004; Coomeset al. 2005). The degree to which cavitation resistance rein-forces these structural costs is a function of a species’s habitat.
In conifers and angiosperms, drought-induced cavitationresistance is correlated with minimum seasonal water poten-tial or rainfall (Brodribb and Hill 1998; Pockman andSperry 2000; Blackman et al. 2010), meaning that woodyplants are only as resistant as they need to be. This is be-cause drought resistance is associated with xylem-level costs,which arise from the need for conduits to be sufficiently for-tified to transport water under varying degrees of negativepressure; without this fortification, conduits collapse undertension (Cochard et al. 2004; Brodribb and Holbrook2005). Specifically, xylem conduits must withstand implo-sion from the tension-induced bending stresses imposed oncell walls. This implosion resistance is characterized by theratio of conduit double-wall thickness to lumen diametert=Dð Þ2h, with cavitation-resistant species exhibiting conduits
with higher thickness-to-diameter ratios (Hacke et al. 2001;Jacobsen et al. 2007; Hacke and Jansen 2009).
682 INTERNATIONAL JOURNAL OF PLANT SCIENCES
In cavitation-resistant conifers, increased t=Dð Þ2h ratiosare a function of reduced tracheid diameter (D) rather thana dramatic thickening of tracheid secondary walls (Pitter-mann et al. 2006a; Sperry et al. 2006). Functionally, thisreduction in conduit size increases redundancy and pathwaypotential during drought stress (McCulloh et al. 2010),but it also translates to lower transport rates in drought-resistant conifers, an important cost of cavitation resistance(Pittermann et al. 2006a). Finally, these tracheid-level adjust-ments also mean that drought-resistant conifers exhibit a higherfraction of wall material relative to mesic species, and socavitation resistance in northern temperate conifers is neces-sarily associated with higher wood densities (Hacke et al.2001; Pittermann et al. 2006a; McCulloh et al. 2010).
Cavitation-resistant angiosperm xylem also exhibits greaterwood density and thickness-to-span ratios, as well as reducedhydraulic efficiency, but the functional links between conduit-scale adjustments are more complex here than in conifers(Hacke et al. 2001, 2006; Jacobsen et al. 2007). For example,drought-resistant angiosperms typically exhibit reduced vessellengths and diameters (Hargrave et al. 1994; Hacke et al.2006; Jacobsen et al. 2007), probably because smaller conduitsize is coupled with a reduced total pit area and thus an in-creased cavitation safety (Wheeler et al. 2005; Hacke et al.2006; Hacke and Jansen 2009). Second, embolism is bettercontained in xylem composed of smaller, redundant vessels,such that transport is less impeded by the loss of several smallconduits than a few large ones (Comstock and Sperry 2000;Zimmermann and Tyree 2002; Loepfe et al. 2007). Finally,the degree to which vessels cluster and contact one another re-lates to cavitation resistance, because conduit arrangement candirectly affect air propagation through the xylem network(Zanne et al. 2006; Loepfe et al. 2007; Schenk et al. 2008;Lens et al. 2011). These structural variables are responsiblefor the tremendous adaptability of angiosperms with respectto water availability, but they introduce challenges to generat-ing a simple trade-off model, as in the conifers. Additionally,it is worth noting that the fibers of drought-resistant angio-sperms also exhibit adjustments in t=Dð Þ2h ratios, and variationin tissue composition may further affect trade-offs with respectto xylem safety and efficiency (Jacobsen et al. 2005; Poorteret al. 2010; Zanne et al. 2010).
The anatomical diversity of their xylem has allowed angio-sperms to exploit a suite of life-history strategies and habitats thatare significantly more diverse than those of the conifers. Indeed,hydraulic flexibility may trump hydraulic capacity if we wish tounderstand the evolutionary and biogeographical implications ofdifferences in the physiology, morphology, and ecology of coni-fers and angiosperms. For example, highly diverse angiospermleaf venation patterns that improve leaf conductance as well assafety in the form of redundancy further reinforce the ideathat hydraulic flexibility, combined with a surge in photosyn-thetic capacity, growth rates, and diversification, gave the an-giosperms a tremendous competitive advantage (Sack et al.2008; Brodribb and Feild 2010). By contrast, leaf and needlearchitecture in conifers is canalized, even in large-leaved mem-bers of Agathis and Podocarpus (Brodribb et al. 2007, 2008).In the absence of developmental potential to evolve complexxylem traits and variable structural arrangements, conifers can-not exploit the physiological capacity of angiosperms and are
thus relegated to stressful habitats where angiosperms paya competitive penalty for their more expensive xylem strategy.
The discussion above centers on safety versus efficiencytrade-offs characterized in northern temperate woody plants,but Podocarpaceae and Araucariaceae conifers are an inter-esting exception to these so-called rules. In contrast to north-ern temperate Pinaceae and Cupressaceae, the stem xylem ofSouthern Hemisphere conifers exhibit on average 30% higherwood densities, and these bear no relationship to species’cavitation resistance, suggesting that selection has acted dif-ferently on this xylem relative to that of the northern temper-ate species (Pittermann et al. 2006a). Surprisingly, the xylemof these trees appears to be excessively fortified, possessingnarrow tracheids and low hydraulic efficiencies despite grow-ing in mesic habitats where prolonged drought and frostare uncommon. Even at the pit level, no relationship was ob-served between pit conductivity cavitation resistance, in in-teresting contrast to the northern temperate conifer data(Pittermann et al. 2006a, 2010; Domec et al. 2008).
Several ideas have been proposed to explain the divergentxylem strategies of the Southern Hemisphere taxa, but perhapsthe most plausible hypothesis is that these plants evolved tocompete for light in emergent Cretaceous angiosperm cano-pies. Indeed, the leaves of several Podocarpaceae and Araucar-iaceae resemble those of angiosperms in both size and shape,reinforcing the idea that selection acted on leaf rather than xy-lem traits (Hill and Brodribb 1999). That said, the relevanceof wood density to xylem traits is not only related to transportand support functions; denser wood may also serve to reducerespiration costs in long-lived species and prevent decay by mi-crobial and fungal agents, which may be abundant in the mesicto subtropical forests where these conifers grow (Augspurgerand Kelly 1984) Alternatively, there may be a relatively smallcost associated with dense wood in regions with limited season-ality and thus year-round growth.
In summary, the structural and functional trade-offs associ-ated with drought-induced cavitation resistance are similarfor both conifers and angiosperms, but the presence of fibersincreases those costs in angiosperm xylem relative to that ofconifers. This can explain the success of shrubby rather thanarborescent angiosperms in habitats with seasonal and in-tense water deficits, such as the Great Basin high deserts andthe coastal and Mojave scrublands of Southern California(Hacke et al. 2000; Jacobsen et al. 2008). Interestingly, manysuch habitats also experience freezing temperatures, and theconduit features that explain resistance to drought-inducedcavitation can confer traits that resist cavitation broughtabout by freeze-thaw cycles.
Trade-Offs Associated with Freeze-Thaw Stressin Conifers and Angiosperms
For conifers and angiosperms growing in temperate climates,freeze-thaw cycles can cause severe impediment of hydraulicfunction. Bond (1989) commented that freeze-thaw cavitationresistance may be related to the conifers’ success at high-latitude/high-altitude habitats, but the mechanism, as well asthe conifer and angiosperm strategies to cope with it, has re-ceived only modest attention when compared with the effortsaimed at understanding the drought response. It is clear that
683BRODRIBB ET AL.—COMPETITION BETWEEN CONIFERS AND ANGIOSPERMS
conifers have a distinct advantage over angiosperms in theirtolerance of freezing temperatures, as evidenced by their pre-dominance in alpine and boreal ecosystems. Why evergreenangiosperms occupy cold habitats less successfully than coni-fers do has not been explored, but there is no a priori reasonfor their diminished distributions at higher elevations andhigher latitudes. It may be that short growing seasons in theseregions constrain total carbon uptake and wood production toa degree that selects against more costly angiosperm wood.The following discussion explores the mechanism of freeze-thaw cavitation and how resistance to freeze-thaw stress con-strains transport efficiency in woody plants.
In both conifers and angiosperms, vulnerability to freeze-thawcavitation is directly related to conduit diameter, rendering specieswith large conduits, such as ring-porous angiosperms and riparianconifers, vulnerable to freeze-thaw cavitation (Sperry and Sullivan1992; Sperry et al. 1994; Davis et al. 1999; Cochard et al. 2001;Stuart et al. 2007). The classical ‘‘thaw-expansion’’ mechanism offreeze-thaw cavitation explains this phenomenon as follows: whenxylem sap freezes, the movement of the ice crystal lattice in a cen-tripetal direction forces gases out of solution and into a bubblethat is typically located in the center of the conduit. As the con-duit diameter increases, so too does the volume of air that coa-lesces into a bubble (Sperry and Sullivan 1992; Davis et al. 1999;Pittermann and Sperry 2006). Whether the bubble redissolvesback into the sap during the thaw or expands to create an embo-lism depends on both the size of the bubble and the negative xy-lem pressure, whereby:
P�x ¼2t
rþ Pb:
This modification of the Young-Laplace equation for spheri-cal surfaces states that a bubble of radius r and surface ten-sion t will expand and nucleate cavitation if the value of Px
is more negative than the value of P�x, the critical xylem pres-sure (Davis et al. 1999; Mayr and Sperry 2010). For simplic-ity, it is assumed that the internal pressure of the bubble (Pb)is atmospheric (or 0 MPa in relative terms). Functionally, thismeans that large-diameter conduits will produce larger bub-bles during freezing, and these larger bubbles will nucleatecavitation at less negative Px values as the xylem thaws.
Empirical data collected on both conifer and angiosperm xy-lem are consistent with this theory. They indicate that it is con-duit diameter rather than volume that dictates vulnerability tofreeze-thaw cavitation, and that this is in spite of any variationin conduit and pit membrane anatomy, which was previouslyproposed to explain conifer resistance to this stress (Davis et al.1999; Sperry and Robson 2001; Pittermann and Sperry 2003,2006). Specifically, species with mean conduit diameters greaterthan 30 mm are vulnerable even at a moderate Px value of �0.5MPa during thawing (Davis et al. 1999). As xylem tensions in-crease in magnitude during the thaw, these critical conduit di-ameters have been shown to decrease (Pittermann and Sperry2006). Hence, the biophysics of freeze-thaw embolism are con-sistent with the dominance of conifers in high-latitude and al-pine environments, where the narrow tracheids found in stemsand shallow roots are resistant to freeze-thaw stress (Sperry andSullivan 1992; Sperry et al. 1994; Feild and Brodribb 2001; Pit-termann and Sperry 2003).
Hydraulic dysfunction over the winter season may also beattributed to the co-occurring effects of drought and freeze-thaw cavitation, although it is difficult to resolve how thesestress events interact in situ. Indeed, almost complete lossesof transport capacity have been observed in several Pinusspecies by the end of a winter season, and this cannot easilybe explained on the basis of freeze-thaw cavitation alone(Mayr et al. 2003; Mayr and Charra-Vaskou 2007). Frozensoils combined with cuticular water loss can reduce Px valuessuch that conduits narrower than 30 mm can suffer hydrauliclosses from freeze-thaw cavitation, but drought stress mayalso occur when some parts of the plant remain frozen whileothers transpire (Hadley and Smith 1983; Grace 1990; Mayret al. 2003). Despite extensive embolism over the winter sea-son, conifers do recover full hydraulic conductivity in spring,but the mechanism by which they refill their xylem remainsunknown (Sperry and Robson 2001). Because pit-mediatedair seeding does not occur during freeze-thaw cavitation, it ispossible that the membranes avoid so-called cavitation fa-tigue, making refilling possible.
Reduced hydraulic efficiency is the key trade-off associatedwith resistance to freeze-thaw cavitation in both conifers andangiosperms, because conduit diameter is intimately linkedto both vulnerability to freeze-thaw stress and hydraulic effi-ciency. Invariably, freeze-thaw-resistant species exhibit nar-row conduit diameters and lower conductivities (Davis et al.1999; Feild and Brodribb 2001; Feild et al. 2002; Pittermannand Sperry 2003). Recent work on high-elevation angio-sperms has demonstrated that the hydraulic limitations im-posed by narrow vessel diameters constrain leaf-level processessuch that freeze-thaw-resistant species exhibit reduced rates ofgas exchange during the growing season (Choat et al. 2011).The degree to which freezing stress affects productivity andcompetition has not been studied explicitly, but several studiesshow that the hydraulic limitations imposed by selection forfreeze-thaw resistance constrain species distributions andmay be a barrier to competition with seasonally deciduous taxa(Cavender-Bares and Holbrook 2001; Stuart et al. 2007). Wanget al. (1992) effectively argue that it is resistance to freeze-thawcavitation that governs the phenology of coniferous, diffuse-porous, and ring-porous species, such that ring-porousplants (e.g., oak and walnut) exhibit the most delayed seasonalleaf flush to avoid the possibility of a late-season freezing event.In high-elevation/high-latitude regions, the frost-free growingseason may be too short to support the carbon investment re-quired by the arborescent angiosperm xylem strategy, thus giv-ing conifers a distinct advantage.
Longevity
One of the key unifying traits of conifers is the longevity ofthe whole plant (table 1), including leaves and possibly roots(Coomes and Bellingham 2011). Many species of conifers arecapable of exceeding an age of 1000 years, and although verylong-lived species are more common in Pinaceae and Cupres-saceae, other major families (Podocarpaceae, Araucariaceae,and Taxaceae) have species capable of attaining >1000 yearsof growth (Ogden and Stewart 1995). The capacity for greatlongevity in conifers has been attributed to decay resistance inconifer wood (Savory 1954; Takahashi and Nishimoto 1973),
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and all conifers possess a system of resin canals that bathe thewood and leaves in a terpene-rich sap, which guards themagainst insect and fungal attacks. It has been suggested thatother adaptations at the chromosomal level contribute to coni-fer longevity (Flanary and Kletetschka 2005), although theseadaptations are unlikely to be specific to the conifer clade.Long-lived trees can be relatively fast-growing pioneer speciessuch as Sequoiadendron (maximum verified age, 3266 years)or slow-growing rain forest trees such as Lagarostrobos inTasmania (maximum age, 2500 years). Furthermore, climateseems to exert little influence on the existence of long-lived co-nifers, with dry forest (Juniperus and Pinus), temperate rainforest (Sequoidendron, Fitzroya, and Lagarostrobos), andtropical species (Agathis vitiensis) all being capable of at least600 years of growth. The almost ubiquitous presence of longe-vous species in conifer clades indicates that this trait is a deeplyembedded feature of the group.
Conifer leaves are also often very long lived, with the Chil-ean Araucaria araucana holding the record, with leaf lifespans of ;25 years (Lusk 2001). In temperate rain foreststhe conifers have longer-lived leaves than most of the angio-sperms (Lusk 2001; Coomes and Bellingham 2011), and innorthern temperate forests the conifers retain leaves for twoor more years while the majority of angiosperms are decidu-ous. Whether conifers have longer root life spans than angio-sperms remains almost entirely unexplored because of theimmense challenges involved in measuring this attribute. Ina comparison of 11 North American species, root life spanwas found to be negatively correlated with root nitrogen-to-
carbon ratios, but conifer and angiosperm species were in-distinguishable (Withington et al. 2006). In contrast, speciesfound on soils with low nitrogen availability tend to havelonger root life spans (Eissenstat and Yanai 1997); giventhat conifers are often associated with poor soils, this sug-gests that conifer roots are long lived.
Adaptations to Poor Soils
Species associated with nutrient-poor soils often have long-lived leaves (Grime 1977; Chapin 1980), because a long lifespan reduces the annual rate of mineral nutrient loss via ab-scission (Monk 1966; Small 1972; Givnish 2002). Plants sal-vage only ;50% of nitrogen and 60% of phosphorus fromleaves during abscission (Aerts and Chapin 2000); the rest islost to the ground in leaf litter and must be recaptured in theface of strong competition with neighboring plants (Coomesand Grubb 2000). Thus, a long leaf life span is advantageous(Berendse et al. 1987; Aerts 1995) on poor soils, but this ad-aptation comes at the cost of photosynthetic rate. Associatedwith long leaf life span are high leaf construction costs andrelatively low maximum rates of photosynthesis (Wright et al.2004); conifer needles have even lower photosynthetic ratesthan the leaves of angiosperms with comparable leaf life spans(Lusk et al. 2003). Fine root traits have an even greater influ-ence on soil nutrient availability than leaf litter (Parton et al.2007), but not enough is known about root longevity to com-ment on its influences in relation to soil nutrients.
Table 1
Summary of Some Key Functional Differences between Conifers and Angiosperms
Mean 6 SD stem wood density (g cm�3) Northern temperate conifers: .526 6 .134;
Southern Hemisphere conifers: .65 6 .138
.613 6 .184 (min: .23, max: 1.9)
685BRODRIBB ET AL.—COMPETITION BETWEEN CONIFERS AND ANGIOSPERMS
There is also evidence that conifers are ‘‘ecosystem engi-neers’’ that alter habitats to their own favor: the tough, fi-brous leaves of conifers are slow to decompose (Wardleet al. 2008; Hoorens et al. 2010), resulting in the accumula-tion of organic matter within soils, which increases soilC : P and N : P ratios and affects the community structure ofsoil microflora (Wardle et al. 2008). Nutrients are seques-tered within the recalcitrant organic matter. Locking up nu-trients in this way is an effective means of competing fornutrients if competitors are relatively intolerant of extremenutrient shortage or less able to access organic nutrients.The roots of conifers also have slow decomposition ratesrelative to those of angiosperms (Silver and Miya 2001),because they contain relatively low concentrations of Caand N and have high C : N and lignin : N ratios. In effect,conifers may engineer their local belowground environ-ments to their own advantage. Berendse and Scheffer(2009) proposed that an acceleration of nutrient cycling byangiosperms may have contributed to their rise to domi-nance, but Mueller et al. (2010) questioned the evidence forthis.
Conifers form symbiotic relationships with mycorrhizal fungi,providing the decomposers with sugars such that they are nolonger carbon limited. In return, the conifers gain access to oth-erwise inaccessible forms of N and P. The figures are remarkable:a single gram of soil beneath a pine forest may contain 200 m ofhyphae, exceeding root length by a factor of 200,000 (Read1998). Fungal production, as estimated in a boreal pine foreststudy, corresponded to 14%–15% of carbon assimilation (Finlayand Soderstrom 1992). Carbon fixed by autotrophs is trans-ported to roots and fungi within hours, as has been demon-strated vividly by monitoring soil respiration before andafter severing phloem connections between leaves and roots(girdling experiments; Hogberg et al. 2001). Symbioses withpines allow ctomycorrhizal fungi to monopolize decomposercommunities on nutrient-poor soils and suppress nutrient im-mobilization by generalist saprotrophs (Hogberg et al. 2001).Increasingly, such studies challenge the traditional view thatplants depend on the mineralizing activities of microbial gener-alists to supply them with N and P, because ectomycorrhizalfungi are capable of mobilizing and capturing these mineralnutrients directly from organic matter. Whether conifers aremore successful at exploiting mycorrhizal symbioses than an-giosperms is largely unresolved. For instance, angiospermspecies in podocarp-dominated forests are also heavily in-fected with arbuscular mycorrhizae and so can be similarly ef-fective at acquiring nutrients via their fungal partners (Hurstet al. 2002; Dickie and Holdaway 2011). Two studies providetantalizing evidence that conifer mycorrhizae may be particu-larly effective. Soil respiration rates were 10% lower in conif-erous forests than in broad-leaf forests growing on equivalentsoils in temperate North America (six paired comparisons;Raich et al. 2000), suggesting that conifers meet their nutrientrequirements at a relatively low cost. Podocarps growing alonga soil chronosequence in New Zealand had lower foliar N : Pratios than ferns or angiosperms on the phosphorus-impover-ished soils, which suggested that they were better able to extractsoil phosphorus (Richardson et al. 2004). More work is re-quired to understand the implications of fungal symbiosis forcompetition between conifers and angiosperms.
Responses to Disturbance: Early Successional Adaptations
Many conifers escape head-on competition with angio-sperms by responding differentially to disturbance. Distur-bance can be defined as a discrete, punctuated killing of ordamage to one or more individuals, resulting in an alterationof the niche opportunities available to the species in a systemby removing biomass and freeing up resources for other or-ganisms to use (adapted from Sousa 1984 and Shea et al.2004). As Svensson (2010) pointed out, this definition dis-tinguishes disturbance from stress, which is defined as theexternal constraints that limit the rate of dry-matter pro-duction of all or part of the vegetation (Grime 1977) andcause changes in performance, as opposed to mortality, byreducing conversion efficiency or increasing metabolic costs(Wootton 1998).
Fire is the most thoroughly investigated of all disturbanceagents. Intense crown fires consume virtually all abovegroundbiomass as well as the humus layer of soil. Pines and other mem-bers of Pinaceae have evolved alongside fire and have greatlyexpanded within their ranges since humans started lighting fires,at least 400,000 years ago in Europe and 30,000 years ago inthe Americas (Richardson and Bond 1991; Agee 1998). Manypines produce serotinous cones, which are held on the tree forat least 1 yr and open rapidly when fire melts the resin sealingthe cone scales, releasing seeds into the ash. Pinus halepensis,a widespread pine on poor soils in the Mediterranean region,produces serotinous cones from an early age (;7 yr). Giventhat the maximum fire return interval in the region is 30–50 yr,precocious seed production allows the species to accumulatelarge numbers of serotinous cones before fire next strikes and todisperse many seeds into freshly burned sites. However, passagefrom seedling to mature tree is far from assured: pine seedlingsgrow slowly at first, reaching a height of only 1 m after 10 yr,and competition with herbs and resprouting shrubs is intense,particularly because angiosperms respond strongly to 3–10-foldincreases in available N, P, and K in soils following fire (Agee1998). However, enough seedlings usually survive to overtopshrubs and create a new tree layer. Like most pines, P. halepen-sis is light demanding and would be replaced by angiosperms ifprotected from fire for ;100 yr (Naveh and Whittaker 1980),but this never occurs in the Mediterranean.
Pines occupy a remarkable range of habitats across temper-ate North America, from woodlands bordering semidesertsto mesic broad-leaf forests, but in all cases they require cata-strophic disturbance (most usually fire) to gain respite fromangiosperms via a colonization advantage. The life-historytraits of species map out in regional differences in fire inten-sity and frequency (Agee 1998; Keeley and Zedler 1998).One of the most challenging habitats for pines is mesic for-ests that experience infrequent fires: Pinus strobus in easternforests is more shade tolerant than most pines, which allowsit to regenerate in small gap environments within thesedeeply shaded areas, although it still takes advantage of occa-sional fires and hurricanes.
Three species of shade-tolerant podocarps that dominate thealluvial floodplain forests of New Zealand are excellent colo-nizers of catastrophically disturbed sites. The slow-growingpodocarps Dacrycarpus dacrydioides on poorly drained soilsand Podocarpus totara and Prumnopitys taxifolia on better-
686 INTERNATIONAL JOURNAL OF PLANT SCIENCES
drained soils are incapable of regenerating beneath mature forestcanopies and seldom succeed in small gaps, which become clog-ged with fast-growing woody angiosperms, ferns, and herba-ceous plants (Coomes et al. 2005, 2009; Urlich et al. 2005).Their dominance of floodplain forests is due to their ability tosuccessfully regenerate after catastrophic disturbances, such asthose resulting from debris triggered by major movements offaults in the Southern Alps and associated floods (Wells et al.2001; Cullen et al. 2003). The long life spans of these podocarps(up to 3000 yr) allow them to persist from one rare catastrophicdisturbance to the next (Enright and Ogden 1995; Lusk andSmith 1998). Floodplain podocarps grow well in bare mineralsoil (Wardle 1974) and presumably benefit from reduced com-petition with angiosperms on fresh alluvium. Birds feed on thepseudoarils of podocarps and disperse the seeds into seralcommunities (Wardle 1991); podocarp seedlings grow upbeneath the open-crowned bushes and trees and eventuallyovertop them (Beveridge 1973). This unusual regenerationstrategy is also observed in podocarps of Tasmania and main-land Australia (Barker 1991; Gibson and Brown 1991).
Response to Disturbance: Persistent Species
As has already been discussed, many conifers are longlived; by definition, they survive disturbance events that killother trees around them. Many conifers in Pinaceae andCupressaceae develop thick bark that protects them fromlow-intensity ground fires, at least when the trees becometall enough to avoid these ground fires spreading into theircrowns. Because of this protection, fire is less damaging tothick-barked conifers than it is to competitors. Many pinesare favored by frequent fire because seeds retained within se-rotinous cones on tree branches are dispersed immediatelyand in copious amounts into freshly burned areas and rapidlyestablish in the ash (Agee 1998). Pinus palustris is one of themost remarkable pines, growing in nutrient-poor sandy soilsof the coastal plains of the southeastern United States (Keeleyand Zedler 1998) and benefiting from frequent low-intensityfires. In early life stages, internode development is slow, withthe seedling looking much like a bunchgrass; the needles pro-tect the meristem against fire and starch is accumulated inlignotubers. After 5–20 yr of development, the stem elon-gates rapidly at a rate of 50 cm/yr and, although it is initiallysusceptible to fire damage, the bark soon thickens. Lowerbranches self-prune, which leads to fire-resistant trees aftera few more decades. Without the occurrence of fires, oaksand other angiosperms soon crowd out the pines (Keeley andZedler 1998). Where fire intensity increases, P. palustris givesway to equally remarkable pine species such as Pinus echi-nata that can resprout after fire from basal axillary buds orepicormical meristems (Keeley and Zedler 1998). Fires in ma-ture forests of coast and Sierra redwood rarely damage ma-ture trees, but they clear the understory of fire-sensitivespecies and promote seedling regeneration by removing thelitter layer (Ramage et al. 2010).
Niches Occupied by Conifers
In this final section, we attempt to characterize the ecologyof conifers and their coexistence with angiosperms in general
terms. We compare the general patterns observed amongconifers with the concept of a single ecological theory ofconifer–tangiosperm competition proposed by Bond (1989). Infigure 4, we provide four explanations for conifer occurrenceacross a wide range of habitats outside the lowland wettropics.
Under Extreme Conditions becauseThey Are Stress Tolerators
The proposition at the heart of Bond’s theory, that conifersare archetypal stress tolerators that persist in stressful habitatsby having conservative functional traits (Diaz et al. 2004), isindubitable. Numerous conifers survive in some of the mostextreme environments on earth: Pinus halepensis and Juniperturbinata border the Sahara Desert in North Africa (Barberoet al. 1998), Pinus ponderosa and Juniperus occidentalis in-habit the dry woodlands of the northwestern United States,Pinus sylvestris survives in ombrotrophic bogs, and Podocarpusalpinus and Podocarpus nivalis are found in the high-altitudeshrublands of Tasmania and New Zealand. Such extreme envi-ronments lack fast-growing angiosperms capable of smotheringslow-growing conifers, and facilitation rather than competitionmay predominate (Callaway 2007). In the xylem physiology sec-tion, we summarized recent research on the hydraulic con-ductivity of conifers compared with angiosperms, as well asconifer responses to abiotic stress arising from drought,freeze-thaw events, nutrient shortage, and shade. This sectionemphasizes that some species of conifers are adapted tostressful environments.
Under More Equable Conditions because TheyAre Not Necessarily Inferior Competitors
In some habitats, conifers may become strong competitorsfor resources when they become mature, suppressing the growthof neighboring angiosperms and stifling regeneration (fig. 4b).For instance, in the boreal region, statistical modeling of growthdata provides compelling evidence that conifers are effectivecompetitors for belowground resources, with adult trees sup-pressing angiosperms in their neighborhoods (Coates et al.2009). Tilman (1988) defines this as R* competition, whichoccurs when a population reduces resource availability in itsneighborhood to such an extent that the growth and survivalof other species are inhibited. It has also been recognized formany years that mature conifers can be effective below-ground competitors and that trenching (i.e., cutting aroundthe outside of a plot to sever conifer roots) results in some-times spectacular colonization of patches by angiosperms(Coomes and Grubb 2000). Conifers of xeric habitats areable to extract water from soils at well below the wiltingpoint of angiosperms (Ryan and Yoder 1997), and classicstudies by Fricke (1904) and Korstian and Coile (1938) haveshown that root trenching in dry Pinus sylvestris woodlandsallowed trees that normally occur on moister soils to invadespontaneously. In the water transport physiology section ofthis article, we discussed why conifers can be as effective ormore effective than angiosperms at acquiring resources insome habitats.
687BRODRIBB ET AL.—COMPETITION BETWEEN CONIFERS AND ANGIOSPERMS
As we have already seen, whether a species is capable oftolerating shade and becoming the late-successional domi-nant depends critically on the shade cast by the forest can-opy. Forests in dry regions and on nutrient-poor soils haveopen canopies (Coomes and Grubb 2000), which allow morelight to penetrate to the understory. Under these conditions,conifers do not need broad, flattened needles in order tophotosynthesize effectively. Indeed, many podocarps onpoor soil have tiny, imbricated leaves and yet regenerate un-
der the forest canopy because it is so open (Coomes et al.2009; Kunstler et al. 2009). English yew (Taxus baccata) re-generates most successfully in spiny shrublands of juniper(Juniperus communis) or hawthorn (Crataegus monogyna),which protect seedlings against herbivory by goats, deer, anddomestic livestock (Mysterud and Østbye 2004) and the dry-ing effects of bright sunlight (Garcıa et al. 2000). Althoughthis species is very shade tolerant, regeneration is rare withinmature T. baccata woodlands in Europe (Thomas and Polwart
Fig. 4 Four explanations of why conifers have not been competitively excluded by angiosperms from every habitat on Earth. Each set of
illustrations shows vegetation dynamics over time, with disturbances killing established vegetation and enabling regeneration from seed or
resprouts. Triangles represent conifers, green circles represent angiosperm trees, and orange circles represent seral woody species. The four
explanations are that (a) conifers have conservative traits, which enable them to persist in extreme environments (the Bond hypothesis); (b)conifers are ineffective competitors when small but strongly inhibit neighbors through resource competition when mature; (c) conifers are
excellent colonizers of early successional habitats; and (d) conifers have traits associated with longevity, which enable them to persist after minor
disturbances that kill their competitors. There is a great diversity of responses among the 800 or so species of conifer.
688 INTERNATIONAL JOURNAL OF PLANT SCIENCES
2003), and it seems that the trees are dependent on gapscreated by the death of mature trees, in which shrubby com-munities can establish where yew seedlings can occur (Watt1926).
After Catastrophic Disturbances becauseof Superior Colonization Ability
Many conifers are successful colonizers of disturbed sites,where they can buy themselves enough time to establish andgrow in size before competition with angiosperms intensifies(fig. 4b). Fires, earthquakes, floods, volcanic ash deposition,and hurricanes all have the potential to disrupt the vicelikegrip of angiosperm competition and provide opportunitiesfor conifers to regenerate from seed (Ogden and Stewart1995; Richardson and Rundel 1998; Wells et al. 2001;Richardson and Rejmanek 2004). Given enough time with-out catastrophic disturbance in an area, angiosperms mayreturn to dominance (more details are provided in the sectionon response to disturbance above).
After Disturbance because They Are Able to Persist
Many conifer species are notoriously long lived, becausethey are better able to withstand disturbance events than an-giosperms of the same region. We have provided examples ofhow some conifers develop thick bark, which protects themfrom low-intensity ground fires, at least when the trees be-come tall enough to escape ground fires spreading into theircrowns. Because of this protection, fire is less damaging tothick-barked conifers than it is to competitors. More gener-ally, the longevity of conifers means that they must regener-ate only infrequently (even at intervals of several hundredyears) to persist in forests (Ogden and Stewart 1995).
To summarize, conifer seedlings may often grow moreslowly than those of angiosperms, but conifers are present ina wide range of habitats because many establish early in suc-cession and persist for many hundreds or even thousands ofyears. They are thereby able to escape or tolerate intensecompetition for resources. In some circumstances, conifersare superior resource competitors to angiosperms, suppress-ing growth in their vicinity.
Synopsis
The evolution of angiosperms led to a significant reduc-tion in conifer diversity and ecological success, but much ofthe impact may have been confined to extinct families (e.g.,Cheirolepidiaceae) at low latitudes. When considering ex-tant conifers, some generalizations are useful to account forthe paucity of species in the most productive regions of thetropics; specifically, hydraulic limitations prevent gymno-sperms from competing with large, superproductive an-giosperm leaves (Bond 1989; Brodribb and Feild 2010).However, explaining the continuing success of contempo-rary conifers outside the lowland equatorial zone is compli-cated by the divergent ecology of the major conifer families.It may be that Pinaceae and Cupressaceae have been little
impacted by the evolution of angiosperms and they con-tinue to occupy the same dry and/or cold niches they haveoccupied since the Mesozoic, protected by the fact thatadapting to water stress or freezing is likely to be morecostly for angiosperms than conifers, particularly in termsof wood properties. Economically cheap wood and highlyphotosynthetic needles enable Pinaceae to succeed as pio-neer seedlings after fire, but other traits of adult plants suchas serotiny, longevity, thick bark, and ectomycorrhizae al-low them to avoid angiosperm competition in the NorthernHemisphere. Podocarpaceae, on the other hand, seem tohave responded to angiosperm evolution by adapting tothe angiosperm-modified tropical rain forest niche. Theysuccessfully compete with angiosperm trees, albeit oftenin sites of lower soil nutrition, by converging upon similarleaf and tree morphologies. Similar family-specific ecologyof other conifers groups such as Araucariaceae and Taxa-ceae explain why concepts such as Bond’s slow-seedlinghypothesis (Bond 1989) encounter many exceptions withspecies found outside the equatorial zone (Becker 2000).Bond argues that conservative traits prevent conifers fromgrowing rapidly as seedlings when resources are plentiful,leading to competitive exclusion from productive sites.This aspect of Bond’s thinking resonates with the regen-eration niche theory of Grubb (1977), which emphasizesthe critical role of competition during the seedling stage indetermining a species’s fitness. However, we depart fromBond’s perspective in one key respect. Whereas Bond’s hy-pothesis regards competitive filtering during regenerationas the critical determinant of conifer abundance at the land-scape level, evidence gathered over the past 20 yr lends sup-port for the idea that conifers occupy a much broaderrange of habitats than predicted by the slow-seedling hy-pothesis because of various mechanisms that allow them toescape a more direct confrontation with their angiospermcompetitors.
A more quantitative framework is required for specifictheories to be tested. In the case of the tortoise and the hare(Bond 1989), it should be possible to define conifer seedlingcompetitiveness as a function of maximum potential siteproductivity. Gradients in moisture, temperature, nutrients,and seasonality should therefore produce predictable gra-dients in conifer abundance. Given the discussion above, itseems unlikely that such a predictive test would support seed-ling competition as a unique predictor of conifer success. Co-nifers are more tenacious than they are often credited for.When taking together their efficient wood structure, longevity,diverse leaf morphology, and high physiological tolerances,conifers have access to a suite of traits that make them very ef-fective competitors with angiosperms in all but the most highlyproductive environments.
Acknowledgments
We thank Lawren Sack and Kevin Boyce for their help-ful comments and Taylor Feild and Erika Edwards for theinvitation to submit this article. T. J. Brodribb is fundedby an Australian Future Fellowship (Australian ResearchCouncil).
689BRODRIBB ET AL.—COMPETITION BETWEEN CONIFERS AND ANGIOSPERMS
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