Book contents
- Frontmatter
- Epigraph
- Contents
- Preface
- Chapter 1 An overview
- Chapter 2 Leaves: the food producers
- Chapter 3 The trunk and branches: more than a connecting drainpipe
- Chapter 4 Roots: the hidden tree
- Chapter 5 Towards the next generation: flowers, fruits and seeds
- Chapter 6 The growing tree
- Chapter 7 The shape of trees
- Chapter 8 The next generation: new trees from old
- Chapter 9 Age, health, damage and death: living in a hostile world
- Chapter 10 Trees and us
- Further Reading
- Index
- References
Chapter 2 - Leaves: the food producers
Published online by Cambridge University Press: 05 July 2014
Book contents
- Frontmatter
- Epigraph
- Contents
- Preface
- Chapter 1 An overview
- Chapter 2 Leaves: the food producers
- Chapter 3 The trunk and branches: more than a connecting drainpipe
- Chapter 4 Roots: the hidden tree
- Chapter 5 Towards the next generation: flowers, fruits and seeds
- Chapter 6 The growing tree
- Chapter 7 The shape of trees
- Chapter 8 The next generation: new trees from old
- Chapter 9 Age, health, damage and death: living in a hostile world
- Chapter 10 Trees and us
- Further Reading
- Index
- References
Summary
Perhaps the most striking thing about tree leaves is their tremendous diversity in size. The Arctic/alpine willow (Salix nivalis), which grows around the northern hemisphere, can have leaves just 4 mm long on a sprawling ‘tree’ less than a centimetre high (Figure 2.1a). Smaller still, the scale needles of some cypresses are nearer a millimetre long. Amongst the largest of leaves are those of the foxglove tree (Paulownia tomentosa), which on coppiced trees can be over half a metre in length and width on a stalk another half metre long. Such large sail-like leaves are at risk of being torn by the wind (as in the traveller’s palm – Ravenala madagascariensis; Figure 2.1b) so it is perhaps no surprise that big leaves are usually progressively lobed and divided up into leaflets to form a compound leaf. This can lead to even larger leaves: the Japanese angelica tree (Aralia elata) can have leaves well over a metre in length (Figure 2.1c). Many palms have feathery leaves over 3 m long and in the raffia palm (Raphia farinifera) up to 20 m (65 ft) long on a stalk another 4 m long.
The leaves are the main powerhouse of the tree. Combining carbon dioxide from the air with water taken from the soil they photosynthesise using the sun’s energy to produce sugars and oxygen. These sugars (usually exported from the leaf as sucrose, the sugar we buy in packets) are the real food of a tree. They are used as the energy source to run the tree, and they form the raw material of starch and cellulose and, combined with minerals taken from the soil, allow the creation of all other necessary materials from proteins to fats and oils.
- Type
- Chapter
- Information
- TreesTheir Natural History, pp. 13 - 50Publisher: Cambridge University PressPrint publication year: 2014
References
(2009a) Phylogenetic analysis reveals a scattered distribution of autumn colours. Annals of Botany, 103, 703–713.CrossRefGoogle ScholarPubMed
(2009b) Classification of hypotheses on the evolution of autumn colours. Oikos, 118, 328–333.CrossRefGoogle Scholar
& (1993) Stomatal density responses of Egyptian Olea europaea L. leaves to CO2 change since 1327 BC. Annals of Botany, 71, 431–435.CrossRefGoogle Scholar
& (1993) A physiological comparison of leaves and phyllodes in Acacia melanoxylon. Australian Journal of Botany, 41, 293–305.CrossRefGoogle Scholar
& (1969) Interference of moonlight with the photoperiodic measurement of time by plants, and their adaptive reaction. Proceedings of the National Academy of Sciences, USA, 62, 1018–1022.CrossRefGoogle ScholarPubMed
& (1982) The ecology of leaf life spans. Annual Review of Ecology and Systematics, 13, 229–259.CrossRefGoogle Scholar
, , , et al. (2012) Red leaf margins indicate increased polygodial content and function as visual signals to reduce herbivory in Pseudowintera colorata. New Phytologist, 194, 488–497.CrossRefGoogle ScholarPubMed
, , , et al. (2007) Nighttime transpiration in woody plants from contrasting ecosystems. Tree Physiology, 27, 561–575.CrossRefGoogle ScholarPubMed
& (2011) Morphology and anatomy of anomalous cladodes in Sciadopitys verticillata Siebold & Zucc. (Sciadopityaceae). Trees, 25, 199–213.CrossRefGoogle Scholar
, , , & (1992) Foliole movement and canopy architecture of Larrea tridentata (DC.) Cov. in Mexican deserts. Oecologia, 92, 83–89.CrossRefGoogle ScholarPubMed
, & (2001) Why leaves turn red in autumn. The role of anthocyanins in senescing leaves of red-osier dogwood. Plant Physiology, 127, 566–574.CrossRefGoogle ScholarPubMed
(1978).
On the adaptive significance of compound leaves with particular reference to tropical trees. In: Tropical Trees as Living Systems (edited by & ). Cambridge University Press, New York, pp 351–379.Google Scholar
& (2007) The adaptive value of young leaves being tightly folded or rolled on monocotyledons in tropical lowland rain forest: an hypothesis in two parts. Plant Ecology, 192, 317–327.CrossRefGoogle Scholar
& (2001) Autumn tree colours as a handicap signal. Proceedings of the Royal Society of London, Series B, Biological Sciences, 268, 1489–1493.CrossRefGoogle ScholarPubMed
, & (2003) Resorption protection. Anthocyanins facilitate nutrient recovery in autumn by shielding leaves from potentially damaging light levels. Plant Physiology, 133, 1296–1305.CrossRefGoogle ScholarPubMed
, , & (1994) Foliar sclereids of Olea europaea may function as optical fibres. Canadian Journal of Botany, 72, 330–336.CrossRefGoogle Scholar
(1992) Leaf longevity in evergreen shrubs: variation within and among European species. Oecologia, 91, 346–349.CrossRefGoogle ScholarPubMed
, , & (2005) A cellular timetable of autumn senescence. Plant Physiology, 139, 1635–1648.CrossRefGoogle ScholarPubMed
(1995) The basis for variation in leaf longevity of plants. Vegetatio, 121, 89–100.CrossRefGoogle Scholar
& (2007) The leaf size/number trade-off in trees. Journal of Ecology, 95, 376–382.CrossRefGoogle Scholar
(1990) Autumn coloring, photosynthetic performance and leaf development of deciduous broad-leaved trees in relation to forest succession. Tree Physiology, 7, 21–32.CrossRefGoogle ScholarPubMed
& (1992) Delayed greening in tropical leaves: an antiherbivore defense?Biotropica, 24, 256–262.CrossRefGoogle Scholar
, , & (2003) Pigment dynamics and autumn leaf senescence in a New England deciduous forest, eastern USA. Ecological Research, 18, 677–694.CrossRefGoogle Scholar
, & (1994) Photoinhibition and recovery in tropical plant species: response to disturbance. Oecologia, 97, 297–307.CrossRefGoogle ScholarPubMed
(2008) Clusia: Holy Grail and enigma. Journal of Experimental Botany, 59 (7), 1503–1514.CrossRefGoogle ScholarPubMed
, , , et al. (2010) Ethylene triggers needle abscission in root-detached balsam fir. Trees, 24, 879–886.CrossRefGoogle Scholar
& (2007) The ecological and functional correlates of nocturnal transpiration. Tree Physiology, 27, 577–584.CrossRefGoogle ScholarPubMed
& (1981) Why do beech and oak trees retain leaves until spring?Oikos, 37, 387–390.CrossRefGoogle Scholar
& (1975) C4 photosynthesis in tree form Euphorbia species from Hawaiian rainforest sites. Plant Physiology, 55, 1054–1056.CrossRefGoogle Scholar
& (2007) Do aphids paint the tree red (or yellow) – can herbivore resistance or photoprotection explain colourful leaves in autumn?Plant Ecology, 191, 77–84.CrossRefGoogle Scholar
, & (2009) Freezing induced leaf movements and their potential implications to early spring carbon gain: Rhododendron maximum as exemplar. Functional Ecology, 23, 463–471.CrossRefGoogle Scholar
, , , & (2008) Association of red coloration with senescence of sugar maple leaves in autumn. Trees, 22, 573–578.CrossRefGoogle Scholar
, & (2009) Fog interception by Sequoia sempervirens (D. Don) crowns decouples physiology from soil water deficit. Plant, Cell & Environment, 32, 882–892.CrossRefGoogle ScholarPubMed
, & (2011) Impact of artificial pruning on growth and secondary shoot development of wild cherry (Prunus avium L.). Forest Ecology and Management, 261, 764–769.CrossRefGoogle Scholar
, , & (2011) Reddish spring colouring of deciduous leaves: a sign of ecotype?Trees, 25, 231–236.CrossRefGoogle Scholar
, & (2011) Flora of the British Isles Euonymus europaeus L. Journal of Ecology, 99, 345–365.CrossRefGoogle Scholar
, & (2009) Anthocyanin influence on light absorption within juvenile and senescing sugar maples leaves – do anthocyanins function as photoprotective visible light screens?Functional Plant Biology, 36, 793–800.CrossRefGoogle Scholar
(2009) Leaves in the lowest and highest winds: temperature, force and shape. New Phytologist, 183, 13–26.CrossRefGoogle ScholarPubMed
(2009) Catching a red herring: autumn colours and aphids. Oikos, 118, 1610–1612.CrossRefGoogle Scholar
, , & (2008) The influence of summertime fog and overcast clouds on the growth of a coastal Californian pine: a tree-ring study. Oecologia, 15, 601–611.CrossRefGoogle Scholar
(1981) C4 plants of high biomass in arid regions of Asia – occurrence of C4 photosynthesis in Chenopodiaceae and Polygonaceae for the Middle East and USSR. Oecologia, 48, 100–106.CrossRefGoogle ScholarPubMed
, & (1998) A review of whole-plant water use studies in trees. Tree Physiology, 18, 499–512.CrossRefGoogle Scholar
, , & (2008) The response of sap flow to pulses of rain in a temperate Australian woodland. Plant and Soil, 305,121–130.CrossRefGoogle Scholar