2002
DOI: 10.1104/pp.010630
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Characterization of Calcium Oxalates Generated as Biominerals in Cacti

Abstract: The chemical composition and morphology of solid material isolated from various Cactaceae species have been analyzed. All of the tested specimens deposited high-purity calcium oxalate crystals in their succulent modified stems. These deposits occurred most frequently as round-shaped druses that sometimes coexist with abundant crystal sand in the tissue. The biominerals were identified either as CaC 2 O 4 .2H 2 O (weddellite) or as CaC 2 O 4 .H 2 O (whewellite). Seven different species from the Opuntioideae sub… Show more

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Cited by 137 publications
(80 citation statements)
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“…Members of the Cactaceae family are not an exception, as crystals have been observed in the stems, roots, and fl owers, mainly in the cells of the fundamental tissue (Terrazas and Mauseth, 2002;Hartl et al, 2007). Crystals have been documented in the hypodermis of Opuntia species (Conde, 1975;Monje and Baran, 2002;Tovar-Puente et al, 2007) and in wood the crystals are rare (Gibson, 1973). There are also reports of crystals in stem epidermal cells of various genera of the subfamily Cactoideae, where they vary in shape and number.…”
mentioning
confidence: 99%
“…Members of the Cactaceae family are not an exception, as crystals have been observed in the stems, roots, and fl owers, mainly in the cells of the fundamental tissue (Terrazas and Mauseth, 2002;Hartl et al, 2007). Crystals have been documented in the hypodermis of Opuntia species (Conde, 1975;Monje and Baran, 2002;Tovar-Puente et al, 2007) and in wood the crystals are rare (Gibson, 1973). There are also reports of crystals in stem epidermal cells of various genera of the subfamily Cactoideae, where they vary in shape and number.…”
mentioning
confidence: 99%
“…unfortunately, it was not possible to arrive to an unambiguous identification of the chemical nature of the calcium oxalate found in these plants on the basis of the only relatively well defined oxalate IR band (located at 1641 cm -1 in the A. pruinosa sample and between 1641 and 1658 cm -1 in the spectra of the other species) one could tentatively suggest the presence of weddellite (pure weddelite band is found at 1645 cm -1 whereas in whewellite it is found at 1622 cm -1 (Monje & Baran, 1996, 1997). Furthermore, the low frequency spectral range which usually allows a clear differentiation between the two calcium oxalate forms (Monje & Baran 2002), appears partially overlapped by one of the typical sio 2 bands and is highly undefined. a clearly different iR spectrum was obtained when one of the milled samples, or a dry sample of the plant material, was slowly heated in a muffle furnace up to 400 °C and then maintained for 2 hours at this temperature ( figure 1B).…”
Section: Resultsmentioning
confidence: 99%
“…Where Ca 2+ can then react with oxalic acid to form calcium oxalate as either mono-or di-hydrate crystals (Verrecchia 1990;Verrecchia et al 2006) acidic soil environments. At current, investigations have confirmed 24 species are associated with active OCPs Cailleau et al 2004;Cailleau et al 2014;Ferro 2012;Garvie 2003Garvie , 2006Monje and Baran 2002), typically utilising the emblematic localised alkalinisation of acidic soils as a geochemical proxy for oxalogenesis. The most heavily investigated OCP is associated with Milicia excelsa Welw.…”
mentioning
confidence: 99%
“…Oxalic acid can then be converted into insoluble CaOx crystals (K sp ≈ 10 −8.5 ; Certini et al 2000;Monje and Baran 2002;Palak et al 2012) by plants within specialised cells called crystal idioblasts (Faheed et al 2013;Franceschi and Nakata 2005;Nakata 2002Nakata , 2003. These CaOx crystals are subsequently released during herbivory and decomposition, creating a CaOx pool adjacent to the producing species, in its rhizosphere (Cailleau et al 2011;Jayasuriya 1955), stomachs of endopedonic species (Bassalik 1913), or within phytoabrasions Verrecchia et al 2006).…”
mentioning
confidence: 99%