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Complex oil bodies

February 13, 2024

The oil bodies of liverworts, occasionally dubbed “complex” for distinction, are unique organelles exclusive to the Marchantiophyta. They are markedly different from the oil bodies found in algae and other plants in that they are membrane-bound, and are not associated with food storage. The organelles are variable and present in an estimated 90% of liverwort species,[1][2] often proving taxonomically relevant. As a whole, the formation and function of the organelles are poorly understood. Complex oil bodies are recognized as sites of isoprenoid biosynthesis[3] and essential oil accumulation, and have been implicated with anti-herbivory, desiccation tolerance, and photo-protection.[4]

Complex oil bodies of Plagiochila asplenioides

Structure and content edit

The oil bodies of liverworts are recognizable using light microscopy, and they were first officially described in 1834 by Huebener from the plant Mylia taylorii.[4] They were noted as transparent drops, with a shining, membranous texture.[5] They are secretory organelles bound by a single membrane, containing lipophilic globules in a proteinaceous matrix of high refractive index.[4] They are quite variable in size, number, shape, colour, and content between liverwort species. They may appear rounded, globular, homogenous, segmented, clear or tinted.

 
Distinct blue complex oil bodies of Calypogeia azurea.

The lipophilic globules within have been identified as the main site of lipids in liverwort cells,[6] and have long been associated with liverwort's often prominent essential oils.[7][4][8] A visually striking example of this association can be seen in the distinctly blue oil bodies of Calypogeia azurea, found to be due to the localized accumulation of Azulene derivatives.[9] Another early empirical argument for the association of essential oils and complex oil bodies was based upon the dark indophenol blue staining of Radula complanata oil bodies; Indophenol blue dissolves in essential oils and appears dark blue, but appear light pink in unsaturated lipids like those found in the cytoplasmic oil droplets of R. complanata[10]. This was later corroborated by chemical analyses which found the primary constituent of R. complanata oil bodies to be the aromatic 3-methoxy-biphenyl.[11] The association between oil bodies and essential oils is not consistent; While Blasia pusilla lacks both oil bodies and terpenoids, Anthelia julacea lacks oil bodies but retains terpenoids and aromatic compounds.[4][12][8] Although present in some species lacking complex oil bodies, the association with terpenoids is furthered by evidence based upon enzyme localization in Marchantia polymorpha indicating that oil bodies are sites of isoprenoid synthesis in liverworts.[3] The localization of sesquiterpenes and Marchantin A to the oil body has since been confirmed in Marchantia polymorpha based upon the micromanipulation of oil cell contents using glass capillaries and piston syringes.[13] Chemical analyses on hundreds of liverwort species have revealed highly diverse mixtures of aromatic and terpenoid compounds, likely associated with oil bodies.[14]

The essential oils of liverworts are largely composed of sesquiterpenes as well as diterpenes,[4] and more than 3000 terpenoid and aromatic compounds have been reported from the group.[15] Monoterpenes are also present, and have been associated with the sometimes distinctive odours of some species.[14] For example: Chiloscyphus species have been noted to have a strong mossy smell, Jungermannia, Frullania, and Geocalyx species smell of turpentine, and Lophozia vicernata is likened to cedar oil, Moerkia species are intensely unpleasant, Conocephalum species are pungent and mushroomy, Pellia endiviifolia shares qualities with dried seaweed, and Riella species with anise.[14] Interestingly, it has been observed that most sesqui- and diterpenoids in liverworts are enantiomers of those found in vascular plants, although there are numerous only found in liverworts.[citation needed] Pinguisane- and sacculatane-type diterpenes are exclusively found in liverworts,[4] detected in the genera Porella, Pellia, Pallavicini, Fossombronia and Trichocoleopsis.[16]

The secondary metabolites of liverworts offer an under-characterised diversity of potentially pharmaceutically relevant compounds.[citation needed] Liverwort terpenoids and lipophilic compounds have been observed to have significant biological activity, including cyto-toxicity, anti-obesity, anti-influenza, allergenic contact dermatitis, anti-HIV inhibitory, antimicrobial, and vasorelaxant effects.[citation needed] Compounds such as Marchantin[17][18] and Riccardin[19] as well as extracts from Bazzania[20] and Scapania[21] species have been shown to have pronounced antitumour effects.

Indeed, liverworts have been used medicinally by humans for centuries. In China, liverworts have been used for a variety of ailments including cuts, burns and bruises, pulmonary tuberculosis, convulsions and neurasthenia.[citation needed] Pellia neesiana has been used in a traditional medicine by Hesquiat people for children's sore mouths, and Conocephalum salebrosum has been used as an eye medicine by the Ditidaht.[22] Various liverworts have been incorporated by Maori in traditional medicine.[23]

Ontogeny edit

Although a synapomorphy for the phylum, the ontogeny of complex oil bodies across liverworts remains uncertain. Uncertainty arises as to the conservation of development between the Marchantiopsida and Jungermanniopsida. Working with light and electron microscopy, the oil bodies of various Jungermanniopsida species were observed to be derived from dilations of endoplasmic reticulum cisternae.[10][24] In certain Marchantiopsida species, again based upon light and electron microscopy, oil bodies were hypothesized to result from the fusion of golgi-associated vesicles.[25] When re-examined independently in Marchantia polymorpha and Lunularia cruciata, this hypothesis was refuted in favour of that which unifies the development of all liverwort oil bodies from ER cisternae.[26] Recent molecular work in Marchantia polymorpha has however once again supported the fusion of vesicles, and oscillating phases of secretory pathway redirection to the plasma membrane and oil body were hypothesized.[27]

Function edit

 
Radula complanata laminal cells, bearing 1-2 large tinted oil-bodies.

Numerous functions for the organelles have been hypothesized, including that the organelles may be largely vestigial.[4][28] Although lost in numerous taxa,[4] the predominant retention and diversity of the organelles suggests an adaptive role, and their importance is quite evident. Theory over the years has implicated complex oil bodies with virtually all evident stressors, such as herbivore and pathogen damage, thermal stress, excessive light/UV irradiation, and desiccation.[4] Empirical evidence is often lacking, however many of these theories have been supported in one way or another. Worth noting is that the modern adaptive function of complex oil bodies may be diverse across the phylum and inconsistent between species. For example, it was found that oil bodies in Southbya nigrella likely served a role is desiccation-tolerance,[29] however xeric Riccia species and highly exposed Anthelia have no oil bodies at all.[4] In Southbya nigrella, the mechanism was attributed to carbohydrates and other molecules whose osmoticum resists water loss, inferred to be contained in the oil bodies and noted due to the oil body collapse upon rehydration.[29] A hypothesized ancestral function has been that of UV tolerance.[4] It has been noted that liverworts produce a high amount of constitutive and inducible UV-absorbing compounds, much greater than mosses,[30] however the localization of these compounds to complex oil bodies has not been confirmed. As liverworts are often considered the closest extant relative of one of the earliest groups of land plants,[31] they would likely have been required to be adapted to the harsh conditions of a thinner ozone layer,[32] thus the development of these UV-shielding compounds may reflect a key development in the evolution of land plants.[4][33][34]

Studies on herbivore grazing are few but supportive of the hypothesis that oil-bodies can function as herbivore-deterrents. Fossil evidence of herbivore damage on the middle Devonian liverwort Metzgeriothallus sharonae suggests an already deterrent role of the oil-bodies, whereby cells presumed to be oil-cells were preferentially avoided.[35] In an early feeding experiment using various liverworts and several species of snail, it was noted that liverworts leached by alcohol were far more palatable, with fresh liverworts often being seldom touched.[36] Recently, a mutant of Marchantia polymorpha lacking oil-bodies was studied for palatability to herbivores, and it was found that a loss of the organelles was associated with far greater grazing by pill-bugs.[37] In general, herbivore grazing on extant liverworts seems to be quite low,[38] and this is likely not due to an un-worthwhile caloric content[39] but the secondary metabolites likely stored in the oil bodies of the plants.[40][41] In vitro studies on the effects of various liverwort extracts have further demonstrated broad feeding-deterrence as well as insecticidal and nematicidal properties.[40]

Although noted that liverwort colonies are seldom damaged by fungal or bacterial pathogens,[40] empirical evidence of oil-bodies protecting against invasion is lacking. Extracts from a range of liverwort taxa demonstrate pronounced and diverse antifungal and antibacterial properties.[14] Fungal endophytes however are not uncommon among liverwort taxa, and the fungal invasion of liverworts in the family Arnelliaceae has been associated with a rapid breakdown of oil bodies.[42]

Taxonomic importance edit

 
Marchantia polymorpha antheridiophore with dark ocelli.

Complex oil bodies are often the most conspicuous features of liverwort cells in light microscopy, and as variable as they are in number, shape, colour, and homogeneity, they have long been recognized as taxonomically relevant.[4] Unfortunately, this is a character that requires observation in fresh material, as under unnaturally high rates of drying the complex oil bodies disintegrate.[4] Worth noting is that under natural rates of desiccation the oil bodies seem to retain their original structure.[29] Various classifications for oil body types have been proposed based upon their high variability, and they have been used extensively to distinguish between families, genera and species.[4] Chemotaxonomics based on the putative oil-body contents has also proved valuable.[15]

Although some families such as Blasiaceae, Metzgeriaceae, Cephaloziaceae, Lepidoziaceae, and Antheliaceae lack complex oil bodies, they are broadly present in all mature gametophytic and sporophytic cells in the Jungermanniopsida and Haplomitriales, and restricted to specialized oil-cells sometimes denoted as ocelli in the Marchantiopsida and Treubiales.[4] Phylogenetic evidence does not indicate an evident ancestral form of the complex oil bodies as the basal Haplomitriopsida lineages Treubia and Haplomitrium display two different types of oil bodies.[4] Limited fossil evidence has suggested that Paleozoic liverwort oil bodies are homologous to the specialized oil-cells found in extant taxa, perhaps indicating the more ancestral type.[4]

References edit

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February 13, 2024
complex, bodies, bodies, liverworts, occasionally, dubbed, complex, distinction, unique, organelles, exclusive, marchantiophyta, they, markedly, different, from, bodies, found, algae, other, plants, that, they, membrane, bound, associated, with, food, storage,. The oil bodies of liverworts occasionally dubbed complex for distinction are unique organelles exclusive to the Marchantiophyta They are markedly different from the oil bodies found in algae and other plants in that they are membrane bound and are not associated with food storage The organelles are variable and present in an estimated 90 of liverwort species 1 2 often proving taxonomically relevant As a whole the formation and function of the organelles are poorly understood Complex oil bodies are recognized as sites of isoprenoid biosynthesis 3 and essential oil accumulation and have been implicated with anti herbivory desiccation tolerance and photo protection 4 Complex oil bodies of Plagiochila asplenioides Contents 1 Structure and content 2 Ontogeny 3 Function 4 Taxonomic importance 5 ReferencesStructure and content editThe oil bodies of liverworts are recognizable using light microscopy and they were first officially described in 1834 by Huebener from the plant Mylia taylorii 4 They were noted as transparent drops with a shining membranous texture 5 They are secretory organelles bound by a single membrane containing lipophilic globules in a proteinaceous matrix of high refractive index 4 They are quite variable in size number shape colour and content between liverwort species They may appear rounded globular homogenous segmented clear or tinted nbsp Distinct blue complex oil bodies of Calypogeia azurea The lipophilic globules within have been identified as the main site of lipids in liverwort cells 6 and have long been associated with liverwort s often prominent essential oils 7 4 8 A visually striking example of this association can be seen in the distinctly blue oil bodies of Calypogeia azurea found to be due to the localized accumulation of Azulene derivatives 9 Another early empirical argument for the association of essential oils and complex oil bodies was based upon the dark indophenol blue staining of Radula complanata oil bodies Indophenol blue dissolves in essential oils and appears dark blue but appear light pink in unsaturated lipids like those found in the cytoplasmic oil droplets of R complanata 10 This was later corroborated by chemical analyses which found the primary constituent of R complanata oil bodies to be the aromatic 3 methoxy biphenyl 11 The association between oil bodies and essential oils is not consistent While Blasia pusilla lacks both oil bodies and terpenoids Anthelia julacea lacks oil bodies but retains terpenoids and aromatic compounds 4 12 8 Although present in some species lacking complex oil bodies the association with terpenoids is furthered by evidence based upon enzyme localization in Marchantia polymorpha indicating that oil bodies are sites of isoprenoid synthesis in liverworts 3 The localization of sesquiterpenes and Marchantin A to the oil body has since been confirmed in Marchantia polymorpha based upon the micromanipulation of oil cell contents using glass capillaries and piston syringes 13 Chemical analyses on hundreds of liverwort species have revealed highly diverse mixtures of aromatic and terpenoid compounds likely associated with oil bodies 14 The essential oils of liverworts are largely composed of sesquiterpenes as well as diterpenes 4 and more than 3000 terpenoid and aromatic compounds have been reported from the group 15 Monoterpenes are also present and have been associated with the sometimes distinctive odours of some species 14 For example Chiloscyphus species have been noted to have a strong mossy smell Jungermannia Frullania and Geocalyx species smell of turpentine and Lophozia vicernata is likened to cedar oil Moerkia species are intensely unpleasant Conocephalum species are pungent and mushroomy Pellia endiviifolia shares qualities with dried seaweed and Riella species with anise 14 Interestingly it has been observed that most sesqui and diterpenoids in liverworts are enantiomers of those found in vascular plants although there are numerous only found in liverworts citation needed Pinguisane and sacculatane type diterpenes are exclusively found in liverworts 4 detected in the genera Porella Pellia Pallavicini Fossombronia and Trichocoleopsis 16 The secondary metabolites of liverworts offer an under characterised diversity of potentially pharmaceutically relevant compounds citation needed Liverwort terpenoids and lipophilic compounds have been observed to have significant biological activity including cyto toxicity anti obesity anti influenza allergenic contact dermatitis anti HIV inhibitory antimicrobial and vasorelaxant effects citation needed Compounds such as Marchantin 17 18 and Riccardin 19 as well as extracts from Bazzania 20 and Scapania 21 species have been shown to have pronounced antitumour effects Indeed liverworts have been used medicinally by humans for centuries In China liverworts have been used for a variety of ailments including cuts burns and bruises pulmonary tuberculosis convulsions and neurasthenia citation needed Pellia neesiana has been used in a traditional medicine by Hesquiat people for children s sore mouths and Conocephalum salebrosum has been used as an eye medicine by the Ditidaht 22 Various liverworts have been incorporated by Maori in traditional medicine 23 Ontogeny editAlthough a synapomorphy for the phylum the ontogeny of complex oil bodies across liverworts remains uncertain Uncertainty arises as to the conservation of development between the Marchantiopsida and Jungermanniopsida Working with light and electron microscopy the oil bodies of various Jungermanniopsida species were observed to be derived from dilations of endoplasmic reticulum cisternae 10 24 In certain Marchantiopsida species again based upon light and electron microscopy oil bodies were hypothesized to result from the fusion of golgi associated vesicles 25 When re examined independently in Marchantia polymorpha and Lunularia cruciata this hypothesis was refuted in favour of that which unifies the development of all liverwort oil bodies from ER cisternae 26 Recent molecular work in Marchantia polymorpha has however once again supported the fusion of vesicles and oscillating phases of secretory pathway redirection to the plasma membrane and oil body were hypothesized 27 Function edit nbsp Radula complanata laminal cells bearing 1 2 large tinted oil bodies Numerous functions for the organelles have been hypothesized including that the organelles may be largely vestigial 4 28 Although lost in numerous taxa 4 the predominant retention and diversity of the organelles suggests an adaptive role and their importance is quite evident Theory over the years has implicated complex oil bodies with virtually all evident stressors such as herbivore and pathogen damage thermal stress excessive light UV irradiation and desiccation 4 Empirical evidence is often lacking however many of these theories have been supported in one way or another Worth noting is that the modern adaptive function of complex oil bodies may be diverse across the phylum and inconsistent between species For example it was found that oil bodies in Southbya nigrella likely served a role is desiccation tolerance 29 however xeric Riccia species and highly exposed Anthelia have no oil bodies at all 4 In Southbya nigrella the mechanism was attributed to carbohydrates and other molecules whose osmoticum resists water loss inferred to be contained in the oil bodies and noted due to the oil body collapse upon rehydration 29 A hypothesized ancestral function has been that of UV tolerance 4 It has been noted that liverworts produce a high amount of constitutive and inducible UV absorbing compounds much greater than mosses 30 however the localization of these compounds to complex oil bodies has not been confirmed As liverworts are often considered the closest extant relative of one of the earliest groups of land plants 31 they would likely have been required to be adapted to the harsh conditions of a thinner ozone layer 32 thus the development of these UV shielding compounds may reflect a key development in the evolution of land plants 4 33 34 Studies on herbivore grazing are few but supportive of the hypothesis that oil bodies can function as herbivore deterrents Fossil evidence of herbivore damage on the middle Devonian liverwort Metzgeriothallus sharonae suggests an already deterrent role of the oil bodies whereby cells presumed to be oil cells were preferentially avoided 35 In an early feeding experiment using various liverworts and several species of snail it was noted that liverworts leached by alcohol were far more palatable with fresh liverworts often being seldom touched 36 Recently a mutant of Marchantia polymorpha lacking oil bodies was studied for palatability to herbivores and it was found that a loss of the organelles was associated with far greater grazing by pill bugs 37 In general herbivore grazing on extant liverworts seems to be quite low 38 and this is likely not due to an un worthwhile caloric content 39 but the secondary metabolites likely stored in the oil bodies of the plants 40 41 In vitro studies on the effects of various liverwort extracts have further demonstrated broad feeding deterrence as well as insecticidal and nematicidal properties 40 Although noted that liverwort colonies are seldom damaged by fungal or bacterial pathogens 40 empirical evidence of oil bodies protecting against invasion is lacking Extracts from a range of liverwort taxa demonstrate pronounced and diverse antifungal and antibacterial properties 14 Fungal endophytes however are not uncommon among liverwort taxa and the fungal invasion of liverworts in the family Arnelliaceae has been associated with a rapid breakdown of oil bodies 42 Taxonomic importance edit nbsp Marchantia polymorpha antheridiophore with dark ocelli Complex oil bodies are often the most conspicuous features of liverwort cells in light microscopy and as variable as they are in number shape colour and homogeneity they have long been recognized as taxonomically relevant 4 Unfortunately this is a character that requires observation in fresh material as under unnaturally high rates of drying the complex oil bodies disintegrate 4 Worth noting is that under natural rates of desiccation the oil bodies seem to retain their original structure 29 Various classifications for oil body types have been proposed based upon their high variability and they have been used extensively to distinguish between families genera and species 4 Chemotaxonomics based on the putative oil body contents has also proved valuable 15 Although some families such as Blasiaceae Metzgeriaceae Cephaloziaceae Lepidoziaceae and Antheliaceae lack complex oil bodies they are broadly present in all mature gametophytic and sporophytic cells in the Jungermanniopsida and Haplomitriales and restricted to specialized oil cells sometimes denoted as ocelli in the Marchantiopsida and Treubiales 4 Phylogenetic evidence does not indicate an evident ancestral form of the complex oil bodies as the basal Haplomitriopsida lineages Treubia and Haplomitrium display two different types of oil bodies 4 Limited fossil evidence has suggested that Paleozoic liverwort oil bodies are homologous to the specialized oil cells found in extant taxa perhaps indicating the more ancestral type 4 References edit he Xiaolan Ahonen Inkeri Juslen Aino Glenny David Piippo Sinikka 2004 01 01 Phylogeny of liverworts beyond a leaf and a thallus Monogr Syst Bot Missouri Bot Gard 98 87 118 Crandall Stotler Barbara Stotler Raymond E 2000 08 31 Morphology and classification of the Marchantiophyta Bryophyte Biology Cambridge University Press pp 21 70 doi 10 1017 cbo9781139171304 003 ISBN 9780521667944 retrieved 2022 04 16 a b Suire Claude Bouvier Florence Backhaus Ralph A Begu Dominique Bonneu Marc Camara Bilal 2000 11 01 Cellular Localization of Isoprenoid Biosynthetic Enzymes inMarchantia polymorpha Uncovering a New Role of Oil Bodies Plant Physiology 124 3 971 978 doi 10 1104 pp 124 3 971 ISSN 1532 2548 PMC 59197 PMID 11080275 a b c d e f g h i j k l m n o p q r s He Xiaolan Sun Yu Zhu Rui Liang 2013 09 03 The Oil Bodies of Liverworts Unique and Important Organelles in Land Plants Critical Reviews in Plant Sciences 32 5 293 302 doi 10 1080 07352689 2013 765765 ISSN 0735 2689 S2CID 55444410 Hubener Johann Wilhelm Peter 1834 Hepaticologia Germanica oder Beschreibung der deutschen Lebermoose im erweiterten Umfange nach dem jetzigen Stande der Wissenschaft nebst Erorterung der Standorter und ihrer Entdecker kritisch und mit erlauternden Anmerkungen Schwan amp Gotz OCLC 1194197676 Pihakaski Kaarina 1972 Histochemical studies on the oil bodies of the liverworts Pellia epiphylla and Bazzania trilobata Annales Botanici Fennici 9 2 65 76 ISSN 0003 3847 JSTOR 23724932 Academia Caesarea Leopoldino Carolina Naturae Curiosorum Gottsche C M 1843 Novorum actorum Academiae Caesareae Leopoldino Carolinae Naturae Curiosorum Vol 20 Jenae Friedrich Frommann p 268 a b ASAKAWA YOSHINORI 1988 06 14 CHEMICAL EVOLUTION OF MONO AND SESQUITERPENOIDS OF LIVERWORTS The Journal of the Hattori Botanical Laboratory Hattori Botanical Laboratory 64 doi 10 18968 jhbl 64 0 97 retrieved 2022 04 17 Siegelaf U Mues R Donig R Eicher Th Blechschmidt M Becker H May 1992 Ten asulenes from Plagiochila longispina and Calypogeia azurea Phytochemistry 31 5 1671 1678 doi 10 1016 0031 9422 92 83126 j ISSN 0031 9422 a b Suire Claude 1970 Recherches cytologiques sur deux hepatiques Pellia epiphylla L Corda Metzgeriale et Radula complanata L Dum Jungermanniale ergastome sporogenese et spermatogenese OCLC 884862360 Flegel M Becker and H March 2000 Characterization of the Contents of Oil Bodies from the Liverwort Radula complanata1 Plant Biology 2 2 208 210 doi 10 1055 s 2000 9156 浅川 義範 豊田 正夫 竹本 常松 服部 新佐 水谷 正美 Suire Claude 1980 12 15 化学成分を一形質とした苔類分類学へのアプローチ 第9回大会講演要旨 日本蘚苔類学会会報 in Japanese 日本蘚苔類学会 2 doi 10 24474 koke 2 12 172 retrieved 2022 04 17 Tanaka M Esaki T Kenmoku H Koeduka T Kiyoyama Y Masujima T Asakawa Y Matsui K Oct 2016 Direct evidence of specific localization of sesquiterpenes and marchantin A in oil body cells of Marchantia polymorpha L Phytochemistry 130 77 84 doi 10 1016 j phytochem 2016 06 008 PMID 27406893 a b c d Asakawa Y 1995 Chemical Constituents of the Bryophytes Progress in the Chemistry of Organic Natural Products Vienna Springer Vienna pp 1 562 doi 10 1007 978 3 7091 6896 7 1 ISBN 978 3 7091 7427 2 retrieved 2022 04 17 a b Ludwiczuk Agnieszka Asakawa Yoshinori May 2015 Chemotaxonomic value of essential oil components in liverwort species A review Chemotaxonomic value of essential oils from liverworts Flavour and Fragrance Journal 30 3 189 196 doi 10 1002 ffj 3236 Asakawa Yoshinori March 2004 Chemosystematics of the Hepaticae Phytochemistry 65 6 623 669 doi 10 1016 j phytochem 2004 01 003 PMID 15016562 Shi Yan qiu Zhu Chang jun Yuan Hui qing Li Bo qin Gao Jie Qu Xian jun Sun Bin Cheng Yan na Li Song Li Xia Lou Hong Xiang April 2009 Marchantin C a novel microtubule inhibitor from liverwort with anti tumor activity both in vivo and in vitro Cancer Letters 276 2 160 170 doi 10 1016 j canlet 2008 11 004 ISSN 0304 3835 PMID 19095349 Huang Wei Jan Wu Chia Li Lin Chia Wei Chi Li Ling Chen Pen Yuan Chiu Chun Jung Huang Chung Yang Chen Chia Nan May 2010 Marchantin A a cyclic bis bibenzyl ether isolated from the liverwort Marchantia emarginata subsp tosana induces apoptosis in human MCF 7 breast cancer cells Cancer Letters 291 1 108 119 doi 10 1016 j canlet 2009 10 006 ISSN 0304 3835 PMID 19913353 Xue Xia Sun De Fu Sun Cui Cui Liu Hui Ping Yue Bin Zhao Cui Rong Lou Hong Xiang Qu Xian Jun June 2012 Inhibitory effect of riccardin D on growth of human non small cell lung cancer In vitro and in vivo studies Lung Cancer 76 3 300 308 doi 10 1016 j lungcan 2011 12 013 PMID 22261315 Burgess Elaine J Larsen Lesley Perry Nigel B 2000 04 01 A Cytotoxic Sesquiterpene Caffeate from the Liverwort Bazzania n ovae zelandiae Journal 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Takehiko Goodger Jason Q D Mentink Remco A Dierschke Tom Zachgo Sabine Ueda Takashi Bowman John L Tsiantis Miltos July 2020 Oil Body Formation in Marchantia polymorpha Is Controlled by MpC1HDZ and Serves as a Defense against Arthropod Herbivores Current Biology 30 14 2815 2828 e8 doi 10 1016 j cub 2020 05 081 hdl 21 11116 0000 0007 B7EC 1 ISSN 0960 9822 PMID 32559445 S2CID 219942719 Gerson Uri 1982 Bryophytes and Invertebrates Bryophyte Ecology Dordrecht Springer Netherlands pp 291 332 doi 10 1007 978 94 009 5891 3 9 ISBN 978 94 009 5893 7 retrieved 2022 04 17 Haines William P Renwick J Alan A December 2009 Bryophytes as food comparative consumption and utilization of mosses by a generalist insect herbivore Entomologia Experimentalis et Applicata 133 3 296 306 doi 10 1111 j 1570 7458 2009 00929 x ISSN 0013 8703 S2CID 86138304 a b c Chen Feng Ludwiczuk Agnieszka Wei Guo Chen Xinlu Crandall Stotler Barbara Bowman John L 2018 05 04 Terpenoid Secondary Metabolites in Bryophytes Chemical 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