Abstract
The genus Cuphea (Lyhtracea) is a New World genus, with about 600 species of herbaceous, perennial, and small shrubs native to North, Central, and South America. Many of Cuphea species have the ability to synthesize and store medium chain fatty acids (MCFAs) in their seeds. These MCFAs, such as capric, lauric, and myristic acids have several medicinal and nutritional uses. Modern studies in Cuphea systematics rely upon many kinds of comparative data such as cytology, cytogenetics, metabolites and molecular studies, which are important sources of information to depict evolution. Recently, attention has been focused on domestication of the species within the genus Cuphea, but Cuphea generally exhibits wild traits, such as undeterminate pattern of growth, flowering, seed shattering, seed dormancy, and viscid and glandular hairs on plants. These traits are major constraints to agricultural use. Several breeding and modern biotechnology methods have been attempting to remove these limitations to domestication of Cuphea. Gene flow from wild to domesticated plant species has an important role in relation to the evolution of crop plants. This risk of gene transfer from Cuphea to related weedy species, as well as Lythrum, may be production of new aggressive weeds (superweeds). Most of the wild plants, for example Cuphea, have already been adapted to European and USA climate with higher yield and storage, using the different new technologies.
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References
Arkcoll DB, Aguiar J (1984) Peach palm (Bactris gasipaes H.B.K.), a new source of vegetable oil from the wet tropics. J Sci Food Agric 35:520–526
Aubert D, Chen L, Moon YH, Martin D, Castle LA, Yang CH, Sung ZR (2001) EMF1, a novel protein involved in the control of shoot architecture and flowering in Arabidopsis. Plant Cell 13:1865–1875
Badr A, Muller K, Schafer-Pregl R, El Rabey H, Effgen S, Ibrahim HH, Pozzi C, Rohde W, Berti MT, Johnson BL (2008) Growth and development of Cuphea. Ind Crops Prod 27:265–271
Berti MT, Johnson BI (2008) Changes during physiological maturing of cuphea. Field Crops Res 106:163–170
Blasquez M (2000) Flower development pathways. J Cell Sci 113:3547–3548
Blatt CCT, Salatino A, Salatino MLF, del Pero Martinez MA, Cavalcanti TB (1994) Flavonoids of Diplusodon (Lythraceae). Biochem Syst Ecol 22:101–107
Bradley D, Ratcliffe O, Vincent C, Carpenter R, Coen E (1997) Inflorescence commitment and architecture in Arabidopsis. Science 275:80–83
Brenton SS, Gesch RW (2004) Water use and roots length density of Cuphea ssp. Influence by row spacing ans sowing date. Agron J 96:1475–1480
Cavalcanti TB, Graham SA (2005) New taxa in Lythraceae from Latin America. Novon 15:59–68
Chen L, Cheng JC, Castle L, Sung ZR (1997) EMF genes regulate Arabidopsis inflorescence development. Plant Cell 9:2011–2024
Darwin C (1859) On the origin of species by means of natural selection. John Murray, London, UK
Dehes K, Edwards P, Hayes T, Cranmer AN, Fillatti J (1996) Two novel thioesterase are key determinants of the bimodal distribution of acyl chain length of Cuphea palustris seed oil. Plant Physiol 100:203–210
Finlay MR (2004) Old efforts at new uses: a brief history of chemurgy and the American search for biobased materials. J Ind Ecol 7:33–46
Forcella F, Gesch RW, Isbell TA (2005) Seed yield, oil and fatty acids of Cuphea in Northwestern Corn Belt. Crop Sci 45:2195–2202
Ford CS, Allainguillaume J, Chantler PG, Cuccato G, Allender CJ, Wilkinson MJ (2006) Spontaneous gene flow from rapeseed (Brassica napus) to wild Brassica oleracea. Proc R Soc B 273:3111–3115
Gathman AC, Ray DT (1987) Meiotic analysis of 14 Cuphea species and two interspecific hybrids. J Hered 78:315–318
Geller DP, Goodrum JW, Knapp SJ (1999) Fuel properties of oil from genetically altered Cuphea viscosissima. Ind Crop Prod 9:85–91
Gepts P, Papa R (2003) Possible effects of (trans) gene flow from crops on the genetic diversity from landraces and wild relatives. Environ Biosaf Res 2:89–103
Gesch RW, Cermak SC, Isbell TA, Forcella F (2005) Seed yield and oil content of Cuphea as affected by harvest date. Agron J 7:817–822
Graham SA (1995) Innovative seed morphology in Lythraceae. Am J Bot 82:132 (Abstr)
Graham SA, Cavalcanti TB (2001) New chromosome counts in the Lythraceae and a review of chromosome numbers in the family. Syst Bot 26:445–458
Graham SA, Crisci JV, Hoch PC (1993) Cladiscic analysis of the Lythraceae sensu lato based on morphological characters. Bot J Linn Soc 113:1–33
Graham SA, Freudenstein J, Luker M (2006) A phylogenetic study of Cuphea (Lythraceae) based on morphology and nuclear rDNA, ITS sequences. Syst Bot 31:764–778
Graham SA, Hirsinger F, Röbbelen G (1981) Fatty acid of Cuphea seed lipids and their systematic significance. Am J Bot 8:908–917
Graham SA, Kleimann R (1987) Seed lipids of the Lythraceae. Biochem Syst Ecol 15:433–439
Graham SA (1989) Revision of Cuphea sect. Leptocalyx (Lythracaea) Syst Bot 14:43–76
Graham SA, Timmermann BN, Mabry TJ (1980) Flavonoids glycosides in Ammania (Lythraceae). J Nat Prod 34:644–645
Hammond EG, Pan WP, Mora Urpi J (1982) Fatty acid composition and glyceride structure of the mesocarp and kernel oils of the palm (Bactris gasipaes H.B.K.). Rev Biol Trop 30:91–93
Hillis DM, Moritz G, Mable BK (1996) Molecular systematics. Sinauer Associates, Sunderland
Hirsinger F, Knowles PF (1984) Morphological and agronomic description of selected Cuphea germplasm. Econ Bot 38:439–451
Jarvis DI, Hodgkin T (1999) Wild relatives and crop cultivars: detecting natural introgression and farmer selection of new genetic combinations in agroecosystems. Mol Ecol 8:159–173
Kimpel JA (1999) Freedom to operate: intellectual property protection in plant biology and its implications for the conduct of research. Annu Rev Phytopathol 37:29–51
Knapp SJ (1993) Breakthroughs towards the domestication of Cuphea. In: Janick J, Simon JE (eds) New crops. Wiley, New York, USA, pp 372–379
Koehne E (1881) Lyhtraceae monographice describuntur, VI Cuphea. Botanische Jahrebucher fur Systematic Pflanzengeschichte und Pflancengeographie 1:437–458
Koehne E (1903) Lythraceae. In: Engler A (ed) Das Pflanzenreich. IV 216, Heft 17. Wilhelm Engelmann, Leipzig, Germany, pp 1–326
Koinange EMK, Singh SP, Gepts P (1996) Genetic control of the domestication syndrome in common bean. Crop Sci 36:1037–1045
Konishi S, Izawa T, Yang S, Ebana K, Fukuta Y, Sasaki T, Yano M (2006) An SNP caused loss of seed shattering during rice domestication. Science 312:1392–1396
Ladizinsky G (1985) Founder effect in crop–plant evolution. Econ Bot 39:191–199
Lorey W, Röbbelen G (1984) Interspecific hybridization within the genus Cuphea (Lythraceae). Agnew Bot 58:423–432
Myers JH, Denoth M, Shaben J (2004) Invasive plants: their impact and control in changing environments. In: Proceedings of the species at risk, Victoria, USA, 2–6 Mar 2004, pp 1–5
Olejniczak J, Adamska E (2000) The effect of different level of irrigation quantitative traits in two Cuphea species. Biul Inst Hod Akl Rosl 216:491–495
Olejniczak J, Adamczak G, Wojciechowski A (2006) Rapeseed as on the main source renewable energy in sustainable agriculture. In: Jezowski et al. (ed) Alternative plants for sustainable agriculture, vol 5. PAGEN IGR, PAN, Poznan, Poland, pp 141–145
Olejniczak J, Adamska E (1999) Adaptation of Cuphea oil plant to Polish climatic conditions. In: Schriftenreihe “Nachwachsende Rohstoffe”. Band 14, Landwirtschaftsverlag GmbH Münster, Germany, pp 375–380
Olejniczak J (1996) Induced and recombination variability of Cuphea oil plant. Monograph No. 5. IPG, PAS, Poznań, Poland, pp 1–50
Ostergaard L, Kempin SA, Bies D, Klee HJ, Yanofsky F (2006) Pod shattering-resistance Brassica fruit production by ectopic expression of the FRUITFULL gene. Plant Biot J 4:45–51
Patel VC, Skvarla JJ, Raven PH (1984) Pollen characters in relation to the delimination of the Myrtales. Ann MO Bot Gard 71:859–969
Princen LH (1984) Development of new crops for industrial raw materials. J Am Oil Chem Soc 61:235A
Przybecki Z, Olejniczak J, Adamska E (2001a) Regeneration of Cuphea tolucana in vitro culture. Cell Mol Biol Lett 6:587–591
Przybecki Z, Olejniczak J, Adamska E (2001b) Regeneration of Cuphea wrightii (Peyr 651) and fertile C. wrightii x C. tolucana hybrids from leaf explants. Cell Mol Biol Lett 6:859–870
Roath WW (1998) Managing seedling emergence of Cuphea in Iowa. J Iowa Acad Sci 105:23–26
Röbbelen G, Hirsinger F (1982) Cuphea, the first annual oil crop for the production of medium-chain triglycerides (MCT). In: Improvement of oil seed and industrial crops by induced mutations. Panel Proceedings Series – International Atomic Energy Agency, Vienna, Austria, pp 161–170
Salamini F, Ozkan H, Brandolini A, Schafer-Pregl R, Martin W (2002) Genetics and geography of wild cereal domestication in the Near East. Nat Rev Genet 3:429–331
Santos DYAC, Salatino MFL, Salatino A (1995) Flavonoids of species of Cuphea (Lythraceae) from Brasil. Biochem Syst Ecol 23:99–103
Santos DYAC, Salatino MFL, Salatino A (2000) Flavonoids of Lafoensia (Lythraceae). Biochem Syst Ecol 28:487–488
Schwab M (2008) Identificetion of novel seed dormancy mutants in Arabidopsis thaliana and molecular and biochemical characterization of the seed dormancy gene DOG1. PhD der Universität zu Kölln, Germany
Sharratt BS, Gesch RW (2004) Water use and root length density of Cuphea spp. influenced by row spacing and sowing date. Agron J 96:1475–1480
Sobisz Z (2007) Phytocenoses with Heracleum Sosnowskyi Manden. In: Central Pomerania. Rocz AR Poznan 386 Bot Sect 11:53–56
Tobe H, Graham S, Raven P (1998) Floral morphology and evolution in Lythracea sensu lato. In: Owens SJ, Rudall PJ (eds) Reproductive biology. Royal Botanical Garden, Richamond, UK
Torada A, Amano Y (2002) Effect of seed coat color on dormancy in different environments. Euphytica 126:99–105
UN (1935) Genome analysis in Brassica with special reference to the experimental formation of B. napus and peculiar mode of fertilization. Jpn J Bot 7:389–452
Voelker TA, Hayes TR, Cranmer AC, Davies HM (1996) Genetic engineering of a quantitative trait: metabolic and genetic parameters influencing the accumulation of laurate in rapeseed. Plant J 9:229–241
Voelker TA, Worrel AM, Anderson L, Bleibaum J, Fan C, Hawkins DH, Radke SE, Davies HM (1992) Fatty acid biosynthesis redirected to medium chains in transgenic oilseed plants. Science 257:72–74
Wrigth SIVBI, Schroeder SG, Yamasaki M, Daeblej JF (2005) The effect of artifical selection on the maize genome. Science 308:1310–1314
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Olejniczak, J. (2011). Cuphea. In: Kole, C. (eds) Wild Crop Relatives: Genomic and Breeding Resources. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-14871-2_6
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