References
Améglio, T., Bodet, C., Lacointe, A., & Cochard, H. (2002). Winter
embolism, mechanisms of xylem hydraulic conductivity recovery and
springtime growth patterns in walnut and peach trees. Tree Physiology,
22(17), 1211-1220.
Bhattarai, K. R., & Vetaas, O. R. (2003). Variation in plant species
richness of different life forms along a subtropical elevation gradient
in the Himalayas, east Nepal. Global Ecology and Biogeography, 12(4),
327-340.
Brodribb, T. J., & Feild, T. S. (2000). Stem hydraulic supply is linked
to leaf photosynthetic capacity: evidence from New Caledonian and
Tasmanian rainforests. Plant, Cell & Environment, 23(12), 1381-1388.
Brodribb, T. J., & Holbrook, N. M. (2004). Diurnal depression of leaf
hydraulic conductance in a tropical tree species. Plant, Cell &
Environment, 27(7), 820-827.
Brodersen, C. R., & McElrone, A. J. (2013). Maintenance of xylem
network transport capacity: a review of embolism repair in vascular
plants. Frontiers in plant science, 4.
Cadotte, M. W., Arnillas, C. A., Livingstone, S. W., & Yasui, S. L. E.
(2015). Predicting communities from functional traits. Trends in ecology
& evolution, 30(9), 510-511.
Carlquist, S. (1988). Comparative Wood Anatomy: Sistematic Ecological,
and Evolutionary Aspects of Dicotyledon Wood. Springer-Verlag.
Chave, J., Coomes, D., Jansen, S., Lewis, S. L., Swenson, N. G., &
Zanne, A. E. (2009). Towards a worldwide wood economics
spectrum. Ecology letters, 12(4), 351-366.
Choat, B., Drayton, W. M., Brodersen, C., Matthews, M. A., Shackel, K.
A., Wada, H., & Mcelrone, A. J. (2010). Measurement of vulnerability to
water stress‐induced cavitation in grapevine: a comparison of four
techniques applied to a long‐vesseled species. Plant, Cell &
Environment, 33(9), 1502-1512.
Chiu, S. T., & Ewers, F. W. (1992). Xylem structure and water transport
in a twiner, a scrambler, and a shrub of Lonicera
(Caprifoliaceae). Trees, 6(4), 216-224.
Christensen‐Dalsgaard, K. K., & Tyree, M. T. (2014). Frost fatigue and
spring recovery of xylem vessels in three diffuse‐porous trees in situ.
Plant, Cell & Environment, 37(5), 1074-1085.
Cochard H. & Tyree M. T. (1990) Xylem dysfunction in Quercus: vessel
sizes, tyloses, cavitation and seasonal changes in embolism. Tree
Physiology, 6:393-407.
Davis, S., Sperry, J. & Hacke, U. (1999) The relationship between xylem
and cavitation caused by freezing. American Journal of Botany, 86,
1367–1372.
De Guzman, M. E., Santiago, L. S., Schnitzer, S. A., & Álvarez-Cansino,
L. (2016). Trade-offs between water transport capacity and drought
resistance in neotropical canopy liana and tree species. Tree
Physiology.
Dewalt, S. J., Schnitzer, S. A., & Denslow, J. S. (2000). Density and
diversity of lianas along a chronosequence in a central Panamanian
lowland forest. Journal of Tropical Ecology, 16(1), 1-19.
DeWalt, S.J., Ickes, K., Nilus, R. et al. (2006) Liana habitat
associations and community structure in a Bornean lowland tropical
forest. Plant Ecology, 186, 203–216.
DeWalt, S. J., Schnitzer, S. A., Chave, J., Bongers, F., Burnham, R. J.,
Cai, Z., … & Thomas, D. (2010). Annual Rainfall and Seasonality
Predict Pan‐tropical Patterns of Liana Density and Basal Area.
Biotropica, 42(3), 309-317.
DeWalt, S. J., Schnitzer, S. A., Alves, L. F., Bongers, F., Burnham, R.
J., Cai, Z., … & Melis, J. V. (2015). Biogeographical patterns of
liana abundance and diversity. Ecology of lianas, 131-146.
Di Castri, F., & Hajek, E. R. (1976). Bioclimatología de chile.
Ewers F. W. (1985) Xylem structure and water conductions in conifer
trees, dicot trees, and lianas. International Association of Wood
Anatomists Bulletin, 6:309-3017.
Ewers, F.W. & Fisher, J.B. (1991) a, Why vines have narrow stems:
histological trends in Bahuinia (Fabaceae). Oecologia, 8, 233–237.
Ewers, F. W., Fisher, J. B., & Fichtner, K. (1991) b, Water flux and
xylem structure in vines. Putz, F, E., Mooney, H, A ed (s). The biology
of vines. Cambridge Univ. Press: Cambridge, 127-60.
Ewers, F.W., Cochard, H. & Tyree, M.T. (1997) A survey of root
pressures in vines of a tropical lowland forest. Oecologia, 110,
191–196.
Fisher, J.B., Angeles, G., Ewers, F.W. & LopezPortillo, J. (1997)
Survey of root pressure in tropical vines and woody species.
International Journal of Plant Sciences, 110, 191–196.
Gartner, B., Bullock, S., Mooney, H., Brown, B. & Whitbeck, J. (1990)
Water transport of vine and tree stems in tropical deciduous forest.
American Journal of Botany, 77, 742–749.
Gentry, A. H. (1991). The distribution and evolution of climbing
plants. The biology of vines, 3, 49.
Gorsuch, D. M., Oberbauer S. F. & Fisher J. B. (2001) Comparative
vessel anatomy of artic deciduous and evergreen dicots. American journal
of Botany, 88: 1643-1649.
Hacke, U. G., & Sperry, J. S. (2001). Functional and ecological xylem
anatomy. Perspectives in plant ecology, evolution, and
systematics, 4(2), 97-115.
Hadfield, J. D., & Nakagawa, S. (2010). General quantitative genetic
methods for comparative biology: phylogenies, taxonomies, and
multi‐trait models for continuous and categorical characters. Journal of
evolutionary biology, 23(3), 494-508.
Hadfield, J. (2014). MCMCglmm course notes. Cran-R web site
Hegarty, E. E. & Caballe, G. (1991). Distribution and abundance of
vines in forest communities. Pp. 313-335 in Putz, F.E. & Mooney, H.A.
(eds). The biology of vines. Cambridge University Press, Cambridge.
Holbrook, N. M., & Putz, F. E. (1996). From epiphyte to tree:
differences in leaf structure and leaf water relations associated with
the transition in growth form in eight species of hemiepiphytes. Plant,
Cell & Environment, 19(6), 631-642.
Hu, L., Li, M., & Li, Z. (2010). Geographical and environmental
gradients of lianas and vines in China. Global Ecology and
Biogeography, 19(4), 554-561.
Isnard, S. & Silk, W.K. (2009) Moving with climbing plants from Charles
Darwin ‘s time into the 21st century. American Journal of Botany, 96,
1205–1221.
Jiménez-Castillo, M., Wiser, S.K. & Lusk, C.H. (2007) Elevational
parallels of latitudinal variation in the proportion of lianas in woody
floras. Journal of Biogeography, 34, 163–168.
Jiménez‐Castillo, M., & Lusk, C. H. (2013). Vascular performance of
woody plants in a temperate rain forest: lianas suffer higher levels of
freeze–thaw embolism than associated trees. Functional Ecology, 27(2),
403-412.
Lavorel, S., & Garnier, E. (2002). Predicting changes in community
composition and ecosystem functioning from plant traits: revisiting the
Holy Grail. Functional ecology, 16(5), 545-556.
Lobos-Catalán, P., & Jiménez-Castillo, M. (2019). Temperature shapes
liana diversity pattern along a latitudinal gradient in southern
temperate rainforest. Plant Ecology, 220(12), 1109-1117.
Londré, R. A., & Schnitzer, S. A. (2006). The distribution of lianas
and their change in abundance in temperate forests over the past 45
years. Ecology, 87(12), 2973-2978.
Martínez-Cabrera HI, Schenk HJ, Cevallos-Ferriz SRS, Jones CS (2011)
Integration of vessel traits, wood density, and height in angiosperm
shrubs and trees. American Journal of Botany 98:915–22.
McDowell, N. G., Brodribb, T. J., & Nardini, A. (2019). Hydraulics in
the 21st century.
Nardini, A., Gullo, M. A. L., & Salleo, S. (2011). Refilling embolized
xylem conduits: is it a matter of phloem unloading?. Plant Science,
180(4), 604-611.
Osazuwa-Peters & Zanne A.E, (2010) PrometheusWiki contributors, ”Wood
density protocol,”
PrometheusWiki,http://www.publish.csiro.au/prometheuswiki/tikipagehistory.php?page=Wood
density protocol&preview=11 (accessed June 18, 2015).
Phillips, O.L. & Miller, J.S. (2002) Global Patterns of Plant
Diversity: Alwyn H. Gentry’s Forest Transect Data Set. Missouri
Botanical Garden, St. Louis, MO.
Poorter, L., McDonald, I., Alarcón, A., Fichtler, E., Licona, J. C.,
Peña‐Claros, M., … & Sass‐Klaassen, U. (2010). The importance of wood
traits and hydraulic conductance for the performance and life history
strategies of 42 rainforest tree species. New phytologist, 185(2),
481-492.
Putz, F. E., & Mooney, H. A. (1991). The biology of vines. Cambridge
University Press.
Reich, P. B., Wright, I. J., Cavender-Bares, J., Craine, J. M., Oleksyn,
J., Westoby, M., & Walters, M. B. (2003). The evolution of plant
functional variation: traits, spectra, and strategies. International
Journal of Plant Sciences, 164(S3), S143-S164.
R Core Team (2020). R: A language and environment for statistical
computing. R Foundation for Statistical Computing, Vienna, Austria. URL
https://www.R-project.org/.
Santiago, L. S., G. Goldstein, F. C. Meinzer, J. B. Fisher, K. Machado,
D. Woodruff, and T. Jones. (2004). Leaf photosynthetic traits scale with
hydraulic conductivity and wood density in Panamanian forest canopy
trees. Oecologia 140:543–550.
Schnitzler, SA., Amigo, J., Hale, B., & Schnitzler, C. (2016). Patterns
of climber distribution in temperate forests of the Americas. Journal of
Plant Ecology, rtw012.
Schnitzer, S. A., & Bongers, F. (2002). The ecology of lianas and their
role in forests. Trends in Ecology & Evolution, 17(5), 223-230.
Schnitzer, S. A. (2005). A mechanistic explanation for global patterns
of liana abundance and distribution. The American Naturalist, 166(2),
262-276.
Schnitzer, S. A., & Bongers, F. (2011). Increasing liana abundance and
biomass in tropical forests: emerging patterns and putative mechanisms.
Ecology letters, 14(4), 397-406.
Schnitzer, S. A. (2015). Increasing liana abundance in neotropical
forests: causes and consequences. Ecology of lianas, 451-464.
Schnitzer, S. A. (2018). Testing ecological theory with lianas. New
Phytologist, 220(2), 366-380.
Sperry, J., Holbrook, N.M., Zimmermann, M. & Tyree, M. (1987) Spring
filling of vessels in wild grapevine. Plant Physiology, 83, 414–417.
Sperry, J.S. & Sullivan, J. (1992) Xylem embolism in response to
freeze-thaw cycles stress in ring–porous, diffuse-porous, and conifer
species. Plant Physiology, 100, 605–613.
Sperry, J. S., Hacke, U. G., & Pittermann, J. (2006). Size and function
in conifer tracheids and angiosperm vessels. American Journal of
Botany, 93(10), 1490-1500.
Tibbetts, T. & Ewers, F.W. (2000) Root pressure and specific
conductivity in temperate lianas: exotic Celastrus orbiculatus
(Celasteraceae) v/s native Vitis riparia (Vitaceae). American Journal of
Botany, 87, 1272–1278.
Tyree, M.T., Sinclair, B., Lu, P. & Granier, A. (1993) Whole shoot
hydraulic resistance in Quercus species measured with a new
high-pressure flowmeter. Annals of Forest Science, 50, 417–423.
Tyree, M.T., Yang, S., Cruiziat, P. & Sinclair, B. (1994) Novel methods
of measuring hydraulic conductivity of tree root system and
interpretation using AMAIZED. A maize-root dynamic model for water and
solute transport. Plant Physiology, 104, 189–199.
Tyree, M. T., & Ewers, F. W. (1996). Hydraulic architecture of woody
tropical plants. Tropical forest plant ecophysiology, 217-243.
van der Heijden, G. M., & Phillips, O. L. (2008). What controls liana
success in Neotropical forests? Global Ecology and Biogeography, 17(3),
372-383.
van der Sande, M. T., Poorter, L., Schnitzer, S. A., Engelbrecht, B. M.,
& Markesteijn, L. (2019). The hydraulic efficiency–safety trade‐off
differs between lianas and trees. Ecology, e02666.
Vázquez, J.A. & Givnish, T.J. (1998) Altitudinal gradients in tropical
forest composition, structure, and diversity in the Sierra de Manantlán.
Journal of Ecology, 96, 999–1020.
Violle, C., Navas, M. L., Vile, D., Kazakou, E., Fortunel, C., Hummel,
I., & Garnier, E. (2007). Let the concept of trait be functional!
Oikos, 116(5), 882-892.
Westoby, M., & Wright, I. J. (2006). Land-plant ecology on the basis of
functional traits. Trends in ecology & evolution, 21(5), 261-268.
Yin, X. H., Sterck, F., & Hao, G. Y. (2018). Divergent hydraulic
strategies to cope with freezing in co‐occurring temperate tree species
with special reference to root and stem pressure generation. New
Phytologist, 219(2), 530-541.
Zimmermann, M. H. (1983) Xylem structure and the ascent of sap.
Springer, Berlin.
Zwieniecki, ZM. A., & Holbrook, N. M. (2009). Confronting Maxwell’s
demon: biophysics of xylem embolism repair. Trends in plant
science, 14(10), 530-534.