Summary
Species with the C4 photosynthetic pathway have evolved biochemical CO2 concentrating mechanisms that allow Rubisco to function in a high CO2 environment. This increases both their nitrogen and water use efficiency compared to C3 species. A comparison between Australian C4 grasses and global data (Glopnet) reveals that C4 species have greater rates of CO2 assimilation than C3 species for a given leaf nitrogen when both parameters are expressed either on a mass or an area basis. The comparison also revealed that although the range in leaf N content per unit area is less in C4 compared to C3 species, the range in leaf nitrogen concentration per unit dry mass is similar for both C4 and C3 species. While C3 and C4 species invest a similar fraction of leaf N into photosynthetic components, C4 species allocate less to Rubisco protein and more to other soluble proteins and thylakoid components. Hence, the driving force that increases CO2 assimilation rate per unit leaf nitrogen in C4 species is greater catalytic turnover rate of Rubisco in vivo. This is exemplified by the fact that differences in photosynthetic nitrogen use efficiency amongst C4 species of the NAD-ME and NADP-ME decarboxylation types is linked to variation in Rubisco kinetic properties amongst these species. Improved leaf and plant water use efficiency in C4 species is due to both higher photosynthetic rates per unit leaf area and lower stomatal conductance. By contrast, leaf and plant water use efficiency is increased in C4 plants under elevated CO2 because of reduced stomatal conductance. The geographic distribution of the different C4 subtypes is strongly correlated with rainfall. One might expect that these distribution differences are linked to differences in water use efficiency. The convergence found in water use efficiency and leaf gas exchange characteristics under most growth conditions, between NAD-ME and NADP-ME grasses, is therefore a curious reminder that geographic distribution may not be related fully to the physiology of photosynthesis.
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Abbreviations
- A:
-
CO2 assimilation rate
- gs :
-
Stomatal conductance
- Kc :
-
Michaelis–Menten constant for CO2
- kcat :
-
Catalytic turnover rate
- LMA:
-
Leaf dry mass per area
- NADP-ME:
-
NADP malic enzyme
- NUE:
-
Nitrogen use efficiency
- PCK:
-
Phosphoenolpyruvate carboxykinase
- pCO2 :
-
CO2 partial pressure
- PEPC:
-
Phosphoenolpyruvate carboxylase
- PNUE:
-
Photosynthetic nitrogen use efficiency
- W:
-
Photosynthetic leaf water use efficiency
- WUE:
-
Water use efficiency (whole plant)
- φ:
-
Bundle sheath leakiness
- Δ:
-
Carbon isotope discrimination
References
Andrews TJ and Lorimer GH (1987) Rubisco: Structure, mechanisms, and prospects for improvement. In ‘The Biochemistry of Plants: A Comprehensive Treatise. Vol 10, Photosynthesis’. (Eds). MD Hatch and NK Boardman. Academic: New York. pp. 131–218
Badger MR and Andrews TJ (1987) Co-evolution of Rubisco and CO2 concentrating mechanisms. In ‘Progress in Photosynthesis Research, Volume III’. (Ed.) J Biggins. Martinus Nijhoff Publishers: Dordrecht. pp. 601–609
Badger MR and Price GD (1992) The CO2 concentrating mechanism in cyanobacteria and microalgae. Physiol Plant 84: 606–615
Berry J and Bjorkman O (1980) Photosynthetic response and adaptation to temperature in higher-plants. Annu Rev Plant Physiol Plant Mol Biol 31: 491–543
Bjorkman O, Badger MR and Armond PA (1980) Response and adaptation of photosynthesis to high temperatures. In ‘Adaptation of Plants to Water and High Temperature Stress’. (Eds). NC Turner and PJ Kramer. Wiley: New York. pp. 233–249
Bolton JK and Brown RH (1980) Photosynthesis of grass species differing in carbon dioxide fixation pathways. V. Response of Panicum maximum, Panicum milioides, and tall fescue (Festuca arundinacea) to nitrogen nutrition. Plant Physiol 66: 97–100
Bowman WD (1991) Effect of nitrogen nutrition on photosynthesis and growth in C4 Panicum Species. Plant Cell Environ 14: 295–301
Brugnoli E and Farquhar GD (2000) Photosynthetic fractionations of carbon isotopes. In ‘Photosynthesis: Physiology and Metabolism’. (Eds). RC Leegood, TD Sharkey and S von Caemmerer. Kluwer: Dordrecht, The Netherlands. pp. 399–434
Buchmann N, Brooks JR, Rapp KD and Ehleringer JR (1996) Carbon isotope composition of C4 grasses is influenced by light and water supply. Plant Cell Environ 19: 392–402
Cabido M, Pons E, Cantero JJ, Lewis JP and Anton A (2008) Photosynthetic pathway variation among C4 grasses along a precipitation gradient in Argentina. J Biogeogr 35: 131–140
Cousins AB, Badger MR and Von Caemmerer S (2006) Carbonic anhydrase and its influence on carbon isotope discrimination during C4 photosynthesis: insights from antisense RNA in Flaveria bidentis. Plant Physiol 141: 232–242
Cousins AB, Badger MR and von Caemmerer S (2008) C4 photosynthetic isotope exchange in NAD-ME- and NADP-ME-type grasses. J Exp Bot 59: 1695–1703
Dengler NG, Dengler RE, Donnelly PM and Hattersley PW (1994) Quantitative leaf anatomy of C3 and C4 grasses (Poaceae) – bundle sheath and mesophyll surface area relationships. Ann Bot 73: 241–255
Drozak A and Romanowska E (2006) Acclimation of mesophyll and bundle sheath chloroplasts of maize to Âdifferent irradiances during growth. Biochim Biophys Acta – Bioenerg 1757: 1539–1546
Dwyer SA, Ghannoum O, Nicotra A and Von Caemmerer S (2007) High temperature acclimation of C4 photosynthesis is linked to changes in photosynthetic biochemistry. Plant Cell Environ 30: 53–66
Edwards GE, Franceschi VR and Voznesenskaya EV (2004) Single-cell C4 photosynthesis versus the dual-cell (Kranz) paradigm. Annu Rev Plant Biol 55: 173–196
Edwards GE, Huber SC, Ku SB, Rathnam CKM, Gutierrez M and Mayne BC (1976) Variation in photochemical activities of C4 plants in relation to CO2 fixation. In ‘CO2 Metabolism and Plant Productivity’. (Eds) RH Burris and CC Black. University Park Press: Baltimore, MD. pp. 83–112
Ehleringer J and Pearcy RW (1983) Variation in quantum yield for CO2 uptake among C3 and C4 Plants. Plant Physiol 73: 555–559
Ehleringer JR, Cerling TE and Helliker BR (1997) C4 photosynthesis, atmospheric CO2 and climate. Oecologia 112: 285–299
Ehleringer JR and Monson RK (1993) Evolutionary and ecological aspects of photosynthetic pathway variation. Annu Rev Ecol Syst 24: 411–439
Ellis RP, Vogel JC and Fuls A (1980) Photosynthetic pathways and the geographical distribution of grasses in South West Africa/Namibia. S Afr J Sci 76: 307–314
Evans JR (1983) Nitrogen and photosynthesis in the flag leaf of wheat (Triticum aestivum L.). Plant Physiol 72: 297–302
Evans JR (1989) Photosynthesis and nitrogen relationships in leaves of C3 plants. Oecologia 78: 9–19
Evans JR and Poorter H (2001) Photosynthetic acclimation of plants to growth irradiance: the relative importance of specific leaf area and nitrogen partitioning in maximizing carbon gain. Plant Cell Environ 24: 755–767
Evans JR and Seemann JR (1984) Differences between wheat genotypes in specific activity of ribulose-1,5-bisphosphate carboxylase and the relationship to photosynthesis. Plant Physiol 74: 759–765
Evans JR, Vogelmann TC and von Caemmerer S (2007) Balancing light capture with distributed metabolic demand during C4 photosynthesis. In ‘Reconfiguring the Rice Plant’s Photosynthetic Pathway’. (Eds). JE Sheehy, PL Mitchell and B Hardy. International Rice Research Institute: Los Banos, Philippines. pp. 127–143
Evans JR and von Caemmerer S (1996) Carbon dioxide diffusion inside leaves. Plant Physiol 110: 339–346
Evans JR and von Caemmerer S (2000) Would C4 rice produce more biomass than C3 rice? In ‘Redesigning Rice Photosynthesis to Increase Yield’. (Eds). JE Sheehy, PL Mitchell and B Hardy. International Rice Research Institute: Los Banos, Philippines. pp. 53–72
Evans JR, von Caemmerer S, Setchell BA and Hudson GS (1994) The relationship between CO2 transfer conductance and leaf anatomy in transgenic tobacco with a reduced content of Rubisco. Aust J Plant Physiol 21: 475–495
Farquhar GD (1983) On the nature of carbon isotope discrimination in C4 species. Aust J Plant Physiol 10: 205–226
Farquhar GD, Ehleringer JR and Hubick KT (1989) Carbon isotope discrimination and photosynthesis. Annu Rev Plant Physiol Plant Mol Biol 40: 503–537
Farquhar GD, O’Leary MH and Berry JA (1982) On the relationship between carbon isotope discrimination and the inter-cellular carbon-dioxide concentration in leaves. Aust J Plant Physiol 9: 121–137
Farquhar GD and Richards RA (1984) Isotopic composition of plant carbon correlates with water use efficiency of wheat genotypes. Aust J Plant Physiol 11: 539–552
Freitag H and Stichler W (2000) A remarkable new leaf type with unusual photosynthetic tissue in a central Asiatic genus of Chenopodiaceae. Plant Biol 2: 154–160
Furbank RT, Jenkins CLD and Hatch MD (1990) C4 photosynthesis – quantum requirement, C4 acid overcycling and Q-cycle involvement. Aust J Plant Physiol 17: 1–7
Ghannoum O and Conroy JP (1998) Nitrogen deficiency precludes a growth response to CO2 enrichment in C3 and C4 Panicum grasses. Aust J Plant Physiol 25: 627–636
Ghannoum O, Evans JR, Chow WS, Andrews TJ, Conroy JP and von Caemmerer S (2005) Faster Rubisco is the key to superior nitrogen-use efficiency in NADP-malic enzyme relative to NAD-malic enzyme C4 grasses. Plant Physiol 137: 638–650
Ghannoum O, von Caemmerer S and Conroy JP (2001a) Carbon and water economy of Australian NAD-ME and NADP-ME C4 grasses. Aust J Plant Physiol 28: 213–223
Ghannoum O, von Caemmerer S and Conroy JP (2001b) Plant water use efficiency of 17 NAD-ME and NADP-ME C4 grasses at ambient and elevated CO2 partial pressure. Aust J Plant Physiol 28: 1207–1217
Ghannoum O, von Caemmerer S and Conroy JP (2002) The effect of drought on plant water use efficiency of nine NAD-ME and nine NADP-ME Australian C4 grasses. Funct Plant Biol 29: 1337–1348
Hatch MD (1987) C4 photosynthesis: a unique blend of modified biochemistry, anatomy and ultrastructure. Biochim Biophys Acta 895: 81–106
Hatch MD, Kagawa T and Craig S (1975) Subdivision of C4-pathway species based on differing C4 acid decarboxylating systems and ultrastructural features. Aust J Plant Physiol 2: 111–128
Hattersley P (1982) d13C values of C4 types in grasses. Aust J Plant Physiol 9: 139–154
Hattersley PW (1983) The distribution of C3 and C4 grasses in Australia in relation to climate. Oecologia 57: 113–128
Hattersley PW (1992) C4 photosynthetic pathway variation in grasses (Poaceae) its significance for arid and semi-arid lands. In ‘Grass Evolution and Diversification’. (Ed). GP Chapman. Academic: London. pp. 181–212
Hattersley PW and Watson L (1975) Anatomical parameters for predicting photosynthetic pathways of grass leaves: The ‘maximum lateral cell count’ and the ‘maximum cells distant count’. Phytomorphology 25: 325–333
Henderson S, von Caemmerer S and Farquhar GD (1992) Short-term measurements of carbon isotope discrimination in several C4 species. Aust J Plant Physiol 19: 263–285
Henderson S, von Caemmerer S, Farquhar GD, Wade L and Hammer G (1998) Correlation between carbon isotope discrimination and transpiration efficiency in lines of the C4 species Sorghum bicolor in the glasshouse and the field. Aust J Plant Physiol 25: 111–123
Hunt EW, Weber JA and Gates DM (1985) Effects of nitrate application on Amaranthus powellii wats. III. Optimal allocation of leaf nitrogen for photosynthesis and stomatal conductance. Plant Physiol 79: 619–624
Jordan DB and Ogren WL (1981) Species variation in the specificity of ribulose bisphosphate carboxylase/oxygenase. Nature 291: 513–515
Kalapos T, van den Boogaard R and Lambers H (1996) Effect of soil drying on growth, biomass allocation and leaf gas exchange of two annual grass species. Plant Soil 185: 137–149
Kawamitsu Y, Agata W and Miura S (1987) Effects of vapour pressure difference on CO2 assimilation rate, leaf conductance and water use efficiency in grass species. J Fac Agric Kyushu Univ 31: 1–10
Kephart KD, Buxton DR and Taylor SE (1992) Growth of C3 and C4 perennial grasses under reduced irradiance. Crop Sci 32: 1033–1038
Knapp AK (1993) Gas-exchange dynamics in C3 and C4 grasses – consequences of differences in stomatal conductance. Ecology 74: 113–123
Knapp AK and Medina E (1999) Success of C4 photosynthesis in the field: lessons from communities dominated by C4 plants. In ‘C4 plant biology’. (Eds). RF Sage and R Monson. Academic: San Diego, CA. pp. 251–283
Körner C, Scheel JA and Bauer H (1979) Maximum leaf diffusive conductance in vascular plants. Photosynthetica 13: 45–82
Ku MSB, Schmid MR and Edwards GE (1979) Quantitative determination of RuBP carboxylase-oxygenase protein in leaves of several C3 and C4 plants. J Exp Bot 30: 89–98
Leakey ADB, Uribelarrea M, Ainsworth EA, Naidu SL, Rogers A, Ort DR and Long SP (2006) Photosynthesis, productivity, and yield of maize are not affected by open-air elevation of CO2 concentration in the absence of drought. Plant Physiol 140: 779–790
Leegood RC, von Caemmerer S and Osmond CB (1997) Metabolite transport and photosynthetic regulation in C4 and CAM plants. In ‘Plant Metabolism’. (Eds). DT Dennis, DH Turpin, DD Leferbvre and DB Layzell. Longman: Burnt Mill. pp. 341–369
Lloyd J and Farquhar GD (1994) 13C discrimination during CO2 assimilation by the terrestrial biosphere. Oecologia 99: 201–215
Long SP (1999) Environmental responses. In ‘C4 Plant Biology’. (Eds). RF Sage and R Monson. Academic: San Diego, CA. pp. 215–250
Makino A, Mae T and Ohira K (1988) Differences between wheat and rice in the enzymic properties of ribulose-1,5-bisphosphate carboxylase/oxygenase and the relationship to photosynthetic gas exchange. Planta 174: 30–38
Makino A and Osmond B (1991) Effects of nitrogen nutrition on nitrogen partitioning between chloroplasts and mitochondria in pea and wheat. Plant Physiol 96: 355–362
Makino A, Sakuma H, Sudo E and Mae T (2003) Differences between maize and rice in N-use efficiency for photosynthesis and protein allocation. Plant Cell Physiol 44: 952–956
Makino A, Sato T, Nakano H and Mae T (1997) Leaf photosynthesis, plant growth and nitrogen allocation in rice under different irradiances. Planta 203: 390–398
Mayne BC, Dee AM and Edwards GE (1974) Photosynthesis in mesophyll protoplasts and bundle sheath cells of various type of C4 plants. III. Fluorescence emission spectra, delayed light emission, and P700 content. Z Pflanzenphysiol 74: 275–291
Monson RK (1989) The relative contributions of reduced photorespiration, and improved water- and nitrogen-use efficiencies, to the advantages of C3-C4 intermediate photosynthesis in Flaveria. Oecologia 80: 215–221
Morgan JA and Brown RH (1979) Photosynthesis in grass species differing in CO2 fixation pathways. II. Search for species with intermediate gas exchange and anatomical characteristics. Plant Physiol 64: 257–262
Ohsugi R, Samejima M, Chonan N and Murata T (1988) δC13 values and the occurrence of suberized lamellae in some panicum species. Ann Bot 62: 53–59
Osmond B (1982) Functional significance of different pathways of CO2 fixation in photosynthesis. In ‘Physiological Plant Ecology II, Encylopedia of Plant Physiology New Series’. (Eds). OL Lange, PS Nobel, B Osmond and H Ziegler. Springer-Verlag: Heidelberg. pp. 479–549
Pearcy RW, Harrison AT, Mooney HA and Bjorkman O (1974) Seasonal changes in net photosynthesis of Atriplex hymenelytra shrubs growing in Death Valley, California. Oecologia 17: 111–121
Poorter H and Evans JR (1998) Photosynthetic nitrogen-use efficiency of species that differ inherently in specific leaf area. Oecologia 116: 26–37
Reich PB, Walters MB and Ellsworth DS (1997) From Tropics to Tundra – global convergence in plant functioning. Proc Natl Acad Sci USA 94: 13730–13734
Ripley BS, Gilbert ME, Ibrahim DG and Osborne CP (2007) Drought constraints on C4 photosynthesis: stomatal and metabolic limitations in C3 and C4 subspecies of Alloteropsis semialata. J Exp Bot 58: 1351–1363
Sage R, Pearcy RW and Seemann JR (1987) The nitrogen use efficiency of C3 and C4 plants. III. Leaf nitrogen effects on the activity of carboxylating enzymes in Chenopodium album (L.) and Amaranthus retroflexus (L.). Plant Physiol 85: 355–359
Sage RF (2002) Variation in the k(cat) of Rubisco in C3 and C4 plants and some implications for photosynthetic performance at high and low temperature. J Exp Bot 53: 609–620
Sage RF (2004) The evolution of C4 photosynthesis. New Phytol 161: 341–370
Sage RF and Kubien DS (2007) The temperature response of C3 and C4 photosynthesis. Plant Cell Environ 30: 1086–1106
Sage RF and Pearcy RW (1987) The nitrogen use efficiency of C3 and C4 plants. II Leaf nitrogen effects on the gas exchange characterisitcs of Chenopodium album L. and Amaranthus retroflexus L. Plant Physiol 84: 959–963
Sage RF and Pearcy RW (2000) The Physiological Ecology of C4 Photosynthesis. Kluwer: Dordrecht, The Netherlands
Seemann JR, Badger MR and Berry JA (1984) Variations in the specific activity of ribulose-1,5-bisphosphate carboxylase between species utilizing differing photosynthetic pathways. Plant Physiol 74: 791–794
Siebke K, Ghannoum O, Conroy JP and von Caemmerer S (2002) Elevated CO2 increases the leaf temperature of two glasshouse-grown C4 grasses. Funct Plant Biol 29: 1377–1385
Taub DR (2000) Climate and the US distribution of C4 grass subfamilies and decarboxylation variants of C4 photosynthesis. Am J Bot 87: 1211–1215
Taub DR and Lerdau MT (2000) Relationship between leaf nitrogen and photosynthetic rate for three NAD-ME and three NADP-ME C4 grasses. Am J Bot 87: 412–417
Taylor SH, Hulme SP, Rees M, Ripley BS, Woodward FI and Osborne CP (2010) Ecophysiological traits in C-3 and C-4 grasses: a phylogenetically controlled screening experiment. New Phytol 185: 780 –791
Tazoe Y, Noguchi K and Terashima I (2006) Effects of growth light and nitrogen nutrition on the organization of the photosynthetic apparatus in leaves of a C4 plant, Amaranthus cruentus. Plant Cell Environ 29: 691–700
Tcherkez GGB, Farquhar GD and Andrews TJ (2006) Despite slow catalysis and confused substrate specificity, all ribulose bisphosphate carboxylases may be nearly perfectly optimized. Proc Natl Acad Sci USA 103: 7246–7251
Teeri JA and Stowe LG (1976) Climatic patterns and the distribution of C4 grasses in North America. Oecologia 23: 1–12
Terashima I and Evans JR (1988) Effects of light and nitrogen nutrition on the organization of the photosynthetic apparatus in spinach. Plant Cell Physiol 29: 143–155
Usuda H, Ku MSB and Edwards GE (1984) Rates of photosynthesis relative to activity of photosynthetic enzymes, chlorophyll and soluble protein content among ten C4 species. Aust J Plant Physiol 11: 509–517
Vogan PJ, Frohlich MW and Sage RF (2007) The functional significance of C3-C4 intermediate traits in Heliotropium L. (Boraginaceae): gas exchange perspectives. Plant Cell Environ 30: 1337–1345
Vogel JC, Fuls A and Ellis RP (1978) The geographic distribution of Kranz grasses in South Afrika. S Afr J Sci 74: 209–215
von Caemmerer S, Evans JR, Cousins AB, Badger MR and Furbank RT (2007) C4 photosynthesis and CO2 diffusion. In ‘Reconfiguring the Rice Plant’s Photosynthetic Pathway’. (Eds). JE Sheehy, PL Mitchell and B Hardy. International Rice Research Institute: Los Banos, Phillipines. pp. 95–115
von Caemmerer S, Ludwig M, Millgate A, Farquhar GD, Price D, Badger M and Furbank RT (1997) Carbon isotope discrimination during C4 photosynthesis: Insights from transgenic plants. Aust J Plant Physiol 24: 487–494
Voznesenskaya EV, Franceschi VR, Kiirats O, Freitag H and Edwards GE (2001) Kranz anatomy is not essential for terrestrial C4 plant photosynthesis. Nature 414: 543–546
Ward DA and Woolhouse HW (1986) Comparative effects of light during growth on the photosynthetic properties of NADP-ME type C4 grasses from open and shaded habitats. 11. Photosynthetic enzyme activities and metabolism. Plant Cell Environ 9: 271–277
Wessinger ME, Edwards GE and Ku MSB (1989) Quantity and kinetic properties of ribulose 1,5-bisphosphate carboxylase in C3, C4, and C3-C4 intermediate species of Flaveria (Asteraceae). Plant Cell Physiol 30: 665–671
Westbeek MHM, Pons TL, Cambridge ML and Atkin OK (1999) Analysis of differences in photosynthetic nitrogen use efficiency of alpine and lowland Poa species. Oecologia 120: 19–26
Wong SC, Cowan IR and Farquhar GD (1979) Stomatal conductance correlates with photosynthetic capacity. Nature 282: 424–426
Wong SC, Cowan IR and Farquhar GD (1985) Leaf conductance in relation to rate of CO2 assimilation. I. Influence of nitrogen nutrition, phosphorus nutrition, photon flux densitiy, and ambient partial pressure of CO2 during ontogeny. Plant Physiol 78: 821–825
Woo KC, Anderson JM, Boardman NK, Downton WJS, Osmond CB and Thorne SW (1970) Deficient photosystem II in agranal bundle sheath chloroplasts of C4 plants. Proc Natl Acad Sci USA 67: 18–25
Wright IJ, Reich PB, Westoby M, Ackerly DD, Baruch Z, Bongers F, Cavender-Bares J, Chapin T, Cornelissen JHC, Diemer M, Flexas J, Garnier E, Groom PK, Gulias J, Hikosaka K, Lamont BB, Lee T, Lee W, Lusk C, Midgley JJ, Navas M-L, Niinemets U, Oleksyn J, Osada N, Poorter H, Poot P, Prior L, Pyankov VI, Roumet C, Thomas SC, Tjoelker MG, Veneklaas EJ and Villar R (2004) The worldwide leaf economics spectrum. Nature 428: 821–827
Yano S and Terashima I (2004) Developmental process of sun and shade leaves in Chenopodium album L. Plant Cell Environ 27: 781–793
Yeoh HH, Badger MR and Watson L (1981) Variations in kinetic-properties of ribulose-1,5-bisphosphate carboxylases among plants. Plant Physiol 67: 1151–1155
Yeoh H-H, Badger MR and Watson L (1980) Variations in Km(CO2) of ribulose-1,5-bisphosphate carboxylase among grasses. Plant Physiol 66: 1110–1112
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Ghannoum, O., Evans, J.R., von Caemmerer, S. (2010). Chapter 8 Nitrogen and Water Use Efficiency of C4 Plants. In: Raghavendra, A., Sage, R. (eds) C4 Photosynthesis and Related CO2 Concentrating Mechanisms. Advances in Photosynthesis and Respiration, vol 32. Springer, Dordrecht. https://doi.org/10.1007/978-90-481-9407-0_8
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