GENERAL LITERATURE

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Articles or books by two or more authors are cited as follows. When there are two authors, citation is alphabetical after the second author's name. When there are three or more authors, references are cited in the body of the text as (e.g.) Chase et al. 2000a, 2000b, 2000c, and are listed following these sometimes alphabetically qualified dates of publication immediately after all the single- or two-authored articles by the first author.

Ma, G. [et al. 2012], Zhang, X., Bunn, E., & Dixon, K. 2012. Megasporogenesis and embryogenesis in three sympatric Posidonia seagrass species. Aquat. Bot. 100: 1-7.

Ma, H. [et al. 2015], Lu, J., Liu, B.-B., He, X.-D., & Liu, J.-Q. 2015. Phylotranscriptomic analyses in plants using Betulaceae as an example. J. Syst. Evol. 53: 403-410.

Ma, J. [Ji] [et al. 2013], Yang, B., Zhu, W., Sun, L., Tian, J., & Wang, X. 2013. The complete chloroplast genome sequence of Mahonia bealei reveals a significant expansion of the inverted repeat and phylogenetic relationship with other angiosperms. Gene 528: 120-131.

Ma, J. [Jianchow] [et al. 2022], Wang, S., Zhu, X., Sun, G., Chang, G., Li, L., Huy, X., Zhang, S., Zhou, Y., Song, C.-P., & Huang J. 2022. Major episodes of horizontal gene transfer drove the evolution of land plants. Molec. Plant 15: 857–871.

Ma, J. F., & Takahashi, E. 2002. Soil, Fertilizer, and Plant Silicon Research in Japan. Elsevier, Amsterdam.

Ma, J. [et al. 2021], Sun, P., Wang, D., Wang, Z., Yang, J., Li, Y., Mu, W., Xu, R., Wu, Y., Dong, C., Shrestha, N., Liu, J., & Yang, Y. 2021. The Chloranthus sessilifolius genome provides insight into early diversification of angiosperms. Nature Communic. 12:6929.

Ma, L. [et al. 2015], Hatlen, A., Kelly, L. J., Wang, W., Kovarik, A., Leitch, I. J., & Leitch, A. R. 2015. Angiosperms are unique among land plant lineages in the occurrence of key genes in the RNA-directed DNA methylation (RdDM) pathway. Genome Biol. Evol. 7: 2648-2662.

Ma, O. S. W., & Saunders, R. M. K. 2003. Comparative floral ontogeny of Maesa (Maesaceae), Aegiceras (Myrsinaceae) and Embelia (Myrsinaceae): Taxonomic and phylogenetic implications. Plant Syst. Evol. 243: 39-58.

Ma, P.-F. [et al. 2014], Zhang, Y.-X., Zeng, C.-X., Guo, Z.-H., & Li, D.-Z. 2014. Chloroplast phylogenomic analyses resolve deep-level relationships of an intractable bamboo tribe Arundinarieae (Poaceae). Syst. Biol. 63: 933-950.

Ma, P.-F. [et al. 2021], Liu, Y.-L., Jin, G.-H., Liu, J.-X., Wu, H., He, J., Guo, Z.-H., & Li, D.-Z. 2021. The Pharus latifolius genome bridges the gap of early grass evolution. Plant Cell 33: 846-864.

Ma, Q. [et al. 2017], Liu, X., Franks, R. G., & Xiang, Q.-Y. (J.) 2017. Alterations of CorTFL1 and CorAP1 expression correlate with major evolutionary shifts of inflorescence architecture in Cornus (Cornaceae) — a proposed model for variation of closed inflorescence forms. New Phytol. 216: 519-535. doi: 10.1111/nph.14197

Ma, Q. [et al. 2017], Zhang, W., & Xiang, Q.-Y. (J.) 2017. Evolution and genetics of floral display — a review of progress. J. Syst. Evol. 55: 487-515.

Ma, Q.-W. [et al. 2009], Ferguson, D. K., Li, F.-L., & Li, C.-S. 2009. Leaf epidermal structures of extant plants of Cunninghamia and Taiwania (Cupressaceae sensu lato) and their taxonomic application. Rev. Palaeobot. Palynol. 155: 15-24.

Ma, Y.-P. [et al. 2008], Fang, X.-H., Chen, F., & Dai, S.-L. 2008. DFL a FLORICAULA/LEAFY homologue gene from Dendranthema lavandulifolium is expressed both in the vegetative and reproductive tissues. Plant Cell Reports 27: 647-654.

Ma, Z. [et al. 2001], Bielenberg, D. G., Brown, K. M., & Lynch, J. P. 2001. Regulation of root hair density by phosphorus availability in Arabidopsis thaliana. Plant Cell Environ. 24: 459-467.

Ma, Z. [et al. 2018], Guo, D., Xu, X., Lu, M., Bardgett, R. D., Eissenstat, D. M., McCormack, M. L., & Hedin, L. O. 2018. Evolutionary history resolves global organization of root functional traits. Nature 555: 94-97.

Ma, Z.-Y. [ert al. 2020], Nie, Z.-L., Ren, C., Liu, X.-Q., Zimmer, E. A., & Wen, J. 2021 [= 2020]. Phylogenomic relationships and character evolution in the grape family (Vitaceae). Molec. Phyl. Evol. 154:106948. https://doi.org/1016/j.ympev.2020.106948

Maad, J., & Nilsson, L. A. 2004. On the mechanism of floral shifts in speciation: Gained pollination efficiency from tongue- to eye-attachment of pollinia in Platanthera (Orchidaceae). Biol. J. Linnean Soc. 83: 481-495.

Maas, P. J. M. 1972. Flora Neotropica Monograph No. 8. Costoideae (Zingiberaceae). Hafner, New York.

Maas, P. J. M. 1977. Flora Neotropica Monograph No. 18 Renealmia (Zingiberaceae - Zingiberoideae), Costoideae (Additions) (Zingiberaceae). New York Botanical Garden, New York.

Maas, P. J. M., & Maas-van der Kamer, H. 1993. Flora Neotropica Monograph 61. Haemodoraceae. New York Botanical Garden, New York.

Maas, P. J. M., & Rübsamen, T. 1986. Flora Neotropica Monograph Number 40. Triuridaceae. New York Botanical Garden, New York.

Maas, P. J. M., & Ruyters, P. 1986. Flora Neotropica Monograph Number 41. Voyria and Voyriella (Saprophytic Gentianaceae). New York Botanical Garden, New York.

Maas, P. J. M., & Westra, L. Y. T. 1984. Studies in Annonaceae. II A monograph of the genus Anaxagorea A. St. Hil. Part 1. Bot. Jahrb. Syst. Pflanzenges. Pflanzengeog. 105: 73-134.

Maas, P. J. M., & Westra, L. Y. T. 1984. Studies in Annonaceae. II A monograph of the genus Anaxagorea A. St. Hil. Part 2. Bot. Jahrb. Syst. Pflanzenges. Pflanzengeog. 105: 145-204.

Maas, P. J. M., & Westra, L. Y. T. 1993. Neotropical Plant Families. Koeltz, Koenigstein.

Maas, P. J. M. [et al. 1986], Maas-van der Kamer, H., van Benthem, J., Snelders, H. C. M., & Rübsamen, T. 1986. Flora Neotropica Monograph Number 42. Burmanniaceae. New York Botanical Garden, New York.

Maas, P. J. M. [et al. 1992], Baas, P., Boesewinkel, F. D., Hiepko, P., Lobreau-Callen, D., van den Oever, L., & ter Welle, B. J. H. 1992. The identity of "Unknown Z": Maburea Maas, a new genus of Olacaceae in Guyana. Bot. Jahrb. Syst. Pflanzenges. Pflanzengeog. 114: 275-291.

Maas, P. J. M. [et al. 2003], Westra, L. Y. T., Chatrou, L. W., & collaborators. 2003. Flora Neotropica Monograph 18 Duguetia (Annonaceae). New York Botanical Garden, New York.

Maas, P. J. M. [et al. 2011], Westra, L. Y. T., Reiner, H., Lobão, A. Q., & Erkens, R. H. J. 2011. An updated index to genera, species, and infraspecific taxa of Neotropical Annonaceae. Nordic J. Bot. 29: 257-356.

Maas, P. J. M. [et al. 2015], Westra, L. Y. T., Guerrero, S. A., Lobão, A. Q., Scharf, U., Zamora, N. A., & Erkens, R. H. J. 2015. Confronting a morphological nightmare: Revision of the Neotropical genus Guatteria (Annonaceae). Blumea 60: 1-219.

Maas, P. J. M. [et al. 2019], Baas, P., Christenhusz, M. J. M., Clarkson, J. J., Koek-Noorman, J., Mennega, A. M. W., Tokuoka, T., van der Bank, M., van der Ham, R. W. J. M., van Marle, E.-J., Westra, L. Y. T., & Chase, M. W. 2019. 'Unknown yellow': Pibiria, a new genus of Passifloraceae with a mixture of features found in Passifloroideae and Turneroideae. Bot. J. Linnean Soc. 189: 397-407.

Maassoumi, A. [et al. 2016], Kazempour Osaloo, S., & Sotoodeh, A. 2016. A new infrageneric grouping of Astragalus (Fabaceae). Iranian J. Bot. 22: 88-100.

Maas-van de Kamer, H. 1995. Triuridiflorae - Gardner's delight? Pp. 287-301, in Rudall, P. J., Cribb, P. J., Cutler, D. F., & Humphries, C. J. (eds), Monocotyledons: Systematics and Evolution. Royal Botanic Gardens, Kew.

Maas-van de Kamer, H. 1998. Burmanniaceae. Pp. 154-163, in Kubitzki, K. (ed.), The Families and Genera of Vascular Plants. III. Flowering Plants: Monocotyledons. Lilianae (except Orchidaceae). Springer, Berlin.

Maas-van de Kamer, H. 2003. Afrothismia gesnerioides, another new species of Afrothismia (Burmanniaceae) from tropical Africa. Blumea 48: 475-478.

Maas-van de Kamer, H., & Maas, P. J. M. 2008. The Cannaceae of the world. Blumea 53: 247-318.

Maas-van de Kamer, H., & Weustenfeld, T. 1998. Triuridaceae. Pp. 452-458, in Kubitzki, K. (ed.), The Families and Genera of Vascular Plants. III. Flowering Plants: Monocotyledons. Lilianae (except Orchidaceae). Springer, Berlin.

Maas-van de Kamer, H. [et al. 2016], Maas, P. J. M., Wieringa, J. J., & Specht, C. D. 2016. Monograph of African Costaceae. Blumea 61: 280-318.

Mabberley, D. J. 1997. The Plant Book. Ed. 2. Cambridge University Press, Cambridge.

Mabberley, D. J. 2008. Mabberley's Plant Book: A Portable Dictionary of Plants, their Classifications, and Uses. Ed. 3. Cambridge University Press, Cambridge.

Mabberley, D. J. 2011. Meliaceae. Pp. 185-211, in Kubitzki, K. (ed.), The Families and Genera of Flowering Plants. X. Flowering Plants: Eudicots. Sapindales, Cucurbitales, Myrtaceae. Springer, Berlin.

Mabberley, D. J. 2017. Mabberley's Plant Book: A Portable Dictionary of Plants, their Classifications, and Uses. Ed. 4. Cambridge University Press, Cambridge.

Mabberley, D. J. [et al. 1995], Pannell, C. M., & Sing, A. M. 1995. Meliaceae. Pp. 1-407, in Kalkman, C. et al. (eds), Flora malesiana. Vol. 12. Rijksherbarium, Leiden.

Mabry, M. E., & Simpson, M. G. 2018. Evaluating the monophyly and biogeography of Cryptantha (Boraginaceae). Syst. Bot. 43: 53-76.

Mabry, M. E. [et al. 2020], Brose, J. M., Blischak, P. D., Sutherland, B., Dismukes, W. T., Bottoms, C. A., Edger, P. P., Washburn, J. D., An, H., Hall, J. C., McKain, M. R., Al-Shehbaz, I., Barker, M. S., Schranz, M. E., Conant, G. C., & Pires, J. C. 2020. Phylogeny and multiple independent whole-genome duplication events in Brassicales. American J. Bot. 107: 1148-1164.

Mabry, M. E. [et al. 2021], Turner-Hissong, S. D., Gallagher, E. Y., McAlvay, A. C., An, H., Edger, P. P., Moore, J. D., Pink, D. A. C., Teakle, G. R., Stevens, C. J., Barker, G., Labate, J., Fuller, D. Q., Allaby, R. G., Beissinger, T., Decker, J. E., Gore, M. A., & Pires, J. C. 2021. The evolutionary history of wild, domesticated, and feral Brassica oleracea (Brassicaceae). Molec. Biol. Evol. 38: 4419-4434. https://doi.org/10.1093/molbev/msab183

Mc... and Mac... go together.

McAbee, J. M. [et al. 2005], Kuzoff, R. K., & Gasser, C. S. 2005. Mechanisms of derived unitegmy among Impatiens species. Plant Cell 17: 1674-1684.

McAbee, J. M. [et al. 2006], Hill, T. A., Skinner, D. J., Izhaki, A., Hauser, B. A., Meister, R. J., Reddy, G. V., Meyerowitz, E. M., Bowman, J. L., & Gasser, C. S. 2006. ABERRANT TESTA SHAPE encodes a KANADI family member, linking polarity determination to separation and growth of Arabidopsis ovule integuments. Plant J. 46: 522-531. https://doi.org/10.1111/j.1365-313X.2006.02717.x

McAdam, S. A. M., & Brodribb, T. J. 2012a. Fern and lycophyte guard cells do not respond to endogenous abscisic acid. Plant Cell 24: 1510-1521.

McAdam, S. A. M., & Brodribb, T. J. 2012b. Stomatal innovation and the rise of seed plants. Ecology Lett. 15: 1-8.

McAdam, S. A. M., & Brodribb, T. J. 2013. Ancestral stomatal control results in a canalization of fern and lycophyte adaptation to drought. New Phytol. 198: 429-441.

McAdam, S. A. M., & Brodribb, T. J. 2014. Separating active and passive influences on stomatal control of transpiration. Plant Physiol. 164: 1578-1586.

McAdam, S. A. M., & Brodribb, T. J. 2016. Linking turgor with ABA biosynthesis: Implications for stomatal responses to vapor pressure deficit across land plants. Plant Physiol. 171: 2008-2016.

McAdam, S. A. [et al. 2016], Brodribb, T. J., Banks, J. A., Hedrich, R., Atallah, N. M., Cai, C., Geringer, M. A., Lind, C., Nichols, D. S., Stachowski, K., Geiger, D., & Sussmilch, F. C. 2016. Abscisic acid controlled sex before transpiration in vascular plants. Proc. National Acad. Sci. 113: 12862-12867,

McAdam, S. A. M. [et al. 2021], Duckett, J. G., Sussmilch, F. C., Pressel, S., Renzaglia, K. S., Hedrich, R., Brodribb, T. J., & Merced, A. 2021. Stomata: The holey grail of plant evolution. American J. Bot. 108: 366-371.

McAllister, C. A. [et al. 2018], McKain, M. R., Li, M., Bookout, B., & Kellogg, E. A. 2018. Specimen-based analysis of morphology and the environment in ecologically dominant grasses: The power of the herbarium. Phil. Trans. Royal Soc. B, 2017:0403. http://dx.doi.org/10.1098/rstb.2017.0403

McBride, C. S. [et al. 2009], van Velzen, R., & Larsen, T. B. 2009. Allopatric origin of cryptic butterfly species that were discovered feeding on distinct host plants in sympatry. Molec. Ecol. 18: 3639-3651.

McCall, A. C., & Fordyce, J. A. 2010. Can optimal defence theory be used to predict the distribution of plant chemical defences? J. Ecol. 98: 985-992.

McCarren, S. [et al. 2021], Coetzee, A., & Midgley, J. 2021. Corolla stickiness prevents nectar robbing in Erica. J. Plant Res. 134: 963-970.

McCartha, G. L. [et al. 2019], Taylor, C. M., van der Ent, A., Echevarria, G., Navarrete Gutiérrez, D. M., & Pollard, A. J. 2019. Phylogenetic and geographic distribution of nickel hyperaccumulation in Neotropical Psychotria. American J. Bot. 106: 1377-1385.

McCarthy, J. K. [et al. 2020], McGlone, M. S., & Heenan, P. B. 2021 [= 2020]. Lineage through time analyses have their limitations: The case of the New Zealand flora. New Zealand J. Bot. 59: 157-174.

McCarthy, P. M. (ed.). 1995. Flora of Australia. Volume 16. Elaeagnaceae, Proteaceae 1. A.B.R.S/C.S.I.R.O., Melbourne.

Machado, M. C. 2008. What is the role of hybridization in the evolution of Cactaceae? Bradleya 26: 1-18.

Machado, S. R. [et al. 2014], Teixeira, S. D. P., & Rodrigues, T. M. 2014. Bacterial leaf glands in Styrax camporum (Styracaceae): First report for the family. Botany 92: 403-411.

Machado-Allison, C. E. [et al. 1983], Rodriguez, D. J., Barrera R., R., & Cova, C. G. 1983. The insect community associated with inflorescences of Heliconia caribaea in Venezuela. Pp. 247-270, in Frank, J. H., & Lounibos, L. P. (eds), Phytotelmata: Terrestrial Plants as Hosts for Aquatic Insect Communities. Plexus, New Jersey.

Machado da Costa, F. G. C. [et al. 2018], Klein, D. E., Philbrick, C. T., & Bove, C. P. 2018. Silica bodies in leaves of Neotropical Podostemaceae: Taxonomic and phylogenteic perspectives. Ann. Bot. 122: 1187-1201.

McClain, A. M., & Manchester, S. R. 2001. Dipteronia (Sapindaceae) from the Tertiary of North America and implications for the phytogeographic history of the Aceroideae. American J. Bot. 88: 1316-1325.

McClellan, Y., & Boecklen, W. J. 1993. Plant mediation of ant-herbivore associations: The role of sticky rings formed by Boerhavia spicata. Coenoses 8: 15-20.

McClintock, E. 1957. A monograph of the genus Hydrangea. Proc. California Acad. Sci. 29(5): 147-256.

McCloud, E. S. [et al. 1995], Tallamy, D. W., & Halaweish, E. T. 1995. Squash beetle trenching behavior: Avoidance of cucurbitacin induction or mucilaginous plant sap? Ecol. Entomol. 20: 51-59.

McClure, B. 2008. Comparing models for S-RNase-based self-incompatability. Pp. 217-236, in Franklin-Tong, V. E. (ed.), Self Incompatability in Flowering Plants: Evolution, Diversity, and Mechanisms. Springer, Berlin.

McClure, F. A. 1968. The Bamboos: A Fresh Perspective. Cambridge, Mass., Harvard University Press.

McClure, F. A. 1973. Genera of bamboos native to the New World (Gramineae: Bambusoideae). Smithsonian Contrib. Bot. 9: 1-148.

McCollum, R. L. 1939. The development of the embryo sac and seed of Commelina angustifolia Michx. Bull. Torrey Bot. Club 66: 539-548.

McCombe, D., & Ackerman, J. D. 2018. Collector motion affects particle capture in physical models and in wind pollination. American Naturalist 192: 81-93.

McConchie, C. A. 1983. Floral development of Maidenia rubra Rendle (Hydrocharitaceae). Australian J. Bot. 31: 585-603.

McConchie, C. A., & Knox, R. B. 1989. Pollination and reproductive biology of seagrasses. Pp.74-111, in Larkum, A. W. D., McComb, A. J., & Shepherd, S. A. (eds), Biology of Seagrasses. A Treatise on the Biology of Seagrasses with Special Reference to the Australian Region. Elsevier, Amsterdam.

McConchie, C. A. [et al. 1982], Ducker, S. C., & Knox, R. B. 1982. Biology of Australian seagrasses: Floral development and morphology in Amphibolis (Cymodoceaceae). Australian J. Bot. 30: 251-264.

McConchie, C. A. [et al. 1986], Hough, T., Singh, M. B., & Knox, R. B. 1986. Pollen presentation on petal combs in the geoflorous heath Acrotriche serrulata (Epacridaceae). Ann. Bot. 57: 155-164.

McConkey, K. R., & Drake, D. R. 2015. Low redundancy in seed dispersal within an island frugivore community. AoB Plants 7: plv088. doi: 10.1093/aobpla/plv088

McConnell, J. R., & Barton, M. K. Leaf polarity and meistem formation in Arabidopsis. Development 125: 2935-2942.

McCormack, M. L. [et al. 2015], Dickie, I. A., Eissenstat, D. M., Fahey, T. J., Fernandez, C. W., Guo, D., Helmisaari, H.-S., Hobbie, E. A., Iversen, C. M., Jackson, R. B., Leppälammi-Kujansuu, J., Norby, R. J., Phillips, R. P., Pregitzer, K. S., Pritchard, S. G., Rewald, B., & Zadworny, M. 2015. Redefining fine roots improves understanding of below-ground contibutions to terrestrial biosphere processes. New Phytol. 207: 505-518. doi: 10.1111/nph.13363

McCormack, M. L [et al. 2017], Guo, D., Iversen, C. M., Chen, W., Eissenstat, D. M., Fernandez, C. W., Li, L., Ma, C., Ma, Z., Poorter, H., Reich, P. B., Zadworny, M., & Zanne, A. 2017. Building a better foundation: Improving root-trait measurements to understand and model plant and ecosystem processes. New Phytol. 215: 27-37. doi:10.1111/nph.14459

McCormick, M. K., & Jacquemyn, H. 2014 [= 2013]. What constrains the distribution of orchid populations? New Phytol. 202: 392-400.

McCoy, S. K. R. [et al. 2006], Kuehl, J. V., Boore, J. L., & Raubeson, L. A. 2006. The complete plastid genome sequence of Welwitschia mirabilis. P. 289, in Botany 2006 - Looking to the Future - Conserving the Past. [Abstracts: Botanical Society of America, etc.].

McCoy, S. K. R. [et al. 2008], Kuehl, J. V., Boore, J. L., & Raubeson, L. A. 2008. The complete plastid genome sequence of Welwitschia mirabilis: An unusually compact plastome with accelerated divergence rates. BMC Evol. Biol. 8:130. doi: 10:1168/14721-2148-8-130

McCoy, T. 2019. The Aloes of Arabia. McCoy Publishing.

McCoy, V. E. [et al. 2022], Gee, C. T., Michalski, J. M., & Wings, O. 2022. Oldest fossil evidence of latex sabotaging behavior by herbivorous insects. Review Palaeobot. Palynol. 300:104631. https://doi.org/10.1016/j.revpalbo.2022.104631

Maccracken, S. A. [et al. 2019], Miller, I. M., & Labandeira, C. C. 2019. Late Cretaceous domatia reveal the antiquity of plant-mite mutualisms in flowering plants. Biol. Lett. 15:20190657. http://dx.doi.org/10/1098/rsbl.2019.0657

McCubbin, A. 2008. Heteromorphic self-incompatability in Primula: Twenty-first century tools promise to unravel a classic nineteenth century model system. Pp. 289-308, in Franklin-Tong, V. E. (ed.), Self Incompatability in Flowering Plants: Evolution, Diversity, and Mechanisms. Springer, Berlin.

McCulloch, G. A., & Waters, J. M. 2019. Phylogenetic divergence of island biotas: Molecular dates, extinction, and "relict" lineages. Molec. Ecol. 28: 4354-4362. doi: 10.1111/mec.15229

McCulloch, L. A., & Porder, S. 2021. Light fuels while nitrogen suppresses symbiotic nitrogen fixation hotspots in Neotropical canopy gap seedlings. New Phytol. 231: 1734-1745.

McCully, M. 1995. How do real roots work? Some new views of root structure. Plant Physiol. 109: 1-6.

McDade, L. A. 1992. Pollinator relationships, biogeography, and phylogenetics. Bioscience 42: 21-26.

McDade, L. A., & Moody, M. L. 1999. Phylogenetic relationships among Acanthaceae: Evidence from noncoding trnL-trnF chloroplast DNA sequences. American J. Bot. 86: 70-80.

McDade, L. A., & Turner, M. D. 1997. Structure and development of bracteal nectary glands in Aphelandra (Acanthaceae). American J. Bot. 84: 1-15.

McDade, L. A. [et al. 2000a], Masta, S. E., Moody, M. L., & Waters, E. 2000a. Phylogenetic relationships among Acanthaceae: Evidence from two genomes. Syst. Bot. 25: 106-121.

McDade, L. A. [et al. 2000b], Daniel, T. F., & Riley, K. M. 2000b. Phylogenetic relationships within the enigmatic tribe Justiceae. American J. Bot. 87(6, suppl.): 143.

McDade, L. A. [et al. 2000c], Daniel, T. F., Masta, S. E., & Riley, K. M. 2000c. Phylogenetic relationships within the tribe Justicieae (Acanthaceae): Evidence from molecular sequences, morphology, and cytology. Ann. Missouri Bot. Gard. 87: 435-458.

McDade, L. A. [ et al. 2002], Daniel, T. F., & Foose, S. E. 2002. Phylogenetic relationships among Acantheae (Acanthaceae): Taxonomic, biogeographic and morphological implications. P. 138, in Botany 2002: Botany in the Curriculum, Abstracts. [Madison, Wisconsin.]

McDade, L. A. [et al. 2005], Daniel, T. F., Kiel, C. A., & Vollesen, K. 2005. Phylogenetic relationships among Acantheae (Acanthaceae): Major lineages present contrasting patterns of molecular evolution and morphological differentiation. Syst. Bot. 30: 834-862.

McDade, L. A. [et al. 2006], Daniel, T. F., & Kiel, C. A. 2006. Relationships among the major lineages of Acanthaceae s.l.: The big picture. Pp. 238-239, in Botany 2006 - Looking to the Future - Conserving the Past. [Abstracts: Botanical Society of America, etc.]

McDade, L. A. [et al. 2008], Daniel, T. F., & Kiel, C. A. 2008. Toward a comprehensive understanding of phylogenetic relationships among lineages of Acanthaceae s.l. (Lamiales). American J. Bot. 95: 1136-1152.

McDade, L. A. [et al. 2009], Daniel, T. F., Ocampo, G., & Kiel, C. A. 2009. Relationships, character evolution, and biogeographic patterns in the phylogenetically pivotal lineage Nelsonioideae (Acanthaceae s.l.). P. 186, in Botany and Mycology 2009. Snowbird, Utah July 25-29. Abstract Book.

McDade, L. A. [et al. 2012], Daniel, T. F., Kiel, C. A., & Borg, A. J. 2012. Phylogenetic placement, delimitation, and relationships among genera of the enigmatic Nelsonioideae (Lamiales: Acanthaceae). Taxon 61: 637-651.

McDade, L. A. [et al. 2018], Daniel, T. F., & Kiel, C. A. 2018. The Tetramerium lineage (Acanthaceae, Justicieae) revisited: Phylogenetic relationships reveal polyphyly of many New World genera accompanied by rampant evolution in floral morphology. Syst. Bot. 43: 97-116.

McDade, L. A. [et al. 2020], Kiel, C. A., Daniel, T. F., & Darbyshire, I. 2021 [= 2020]. Justicieae II: Resolved placement of many genera and recognition of a new lineage sister to Isoglossinae. Aliso 38: 1-31.

McDaniel, J., & Cameron, K. 2016. The power of movement in orchids: A kinematic study of Poroglossum (Pleurothallidinae). P. 164, in Botany 2016. Celebrating our History, Conserving our Future. Savannah, Georgia. [Abstracts.]

McDaniel, S. F. 2021. Bryophytes are not early diverging land plants. New Phytol. 230: 1300-1304.

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Martínez-Azorín, M. [et al. 2011], Crespo, M. B., Juan, A., & Fay, M. F. 2011. Molecular phylogenetics of subfamily Ornithogaloideae (Hyacinthaceae) based on nuclear and plastid DNA regions, including a new taxonomic arrangement. Ann. Bot. 107: 1-37.

Martínez-Azorín, M. [et al. 2015], Pinter, M., & Wetschnig, W. 2015. Desertia, a new genus in Massonieae (Asparagaceae, Scilloideae), including the description of Desertia luteovirens and the taxonomic revisions of Whiteheadia and Namophila. Phytotaxa 221: 201-225.

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Martínez-Habibe, M. C. 2022. Fruit anatomy of the Canarieae (Burseraceae). Plants (Basel) 11(3):253. doi: 10.3390/plants11030253

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Peterson, P. M. [et al. 2010a], Romaschenko, K., & Johnson, G. 2010a. A classification of the Chloridoideae (Poaceae) based on multi-gene phylogenetic trees. Molec. Phyl. Evol. 55: 580-598.

Peterson, P. M. [et al. 2010b], Romaschenko, K., & Johnson, G. 2010b. A phylogeny and classification of the Muhlenbergiinae (Poaceae: Chloridoideae: Cynodonteae) based on plastid and nuclear DNA sequences. American J. Bot. 97: 1532-1554.

Peterson, P. M. [et al. 2011a], Romaschenko, K., & Johnson, G. 2011a. Phylogeny of the Chloridoideae (Poaceae) based on analysis of 11 DNA loci. Pp. 270-271, in XVIII International Botanical Congress 2011, Melbourne. [Abstracts.]

Peterson, P. M. [et al. 2011b], Romaschenko, K., Barker, N. P., & Linder, H. P. 2011b. Centropodieae and Ellisochloa, a new tribe and genus in Chloridoideae (Poaceae). Taxon 60: 1113-1122.

Peterson, P. M. [et al. 2012], Romaschenko, K., Snow, N., & Johnson, G. 2012. A molecular phylogeny and classification of Leptochloa (Poaceae: Chloridoideae: Chlorideae) sensu lato and related genera. Ann. Bot. 109: 1317-1329.

Peterson, P. M. [et al. 2014a], Romaschenko, K., & Herrera Arrieta, Y. 2014a. A molecular phylogeny and classification of the Cteniinae, Farragininae, Gouiniinae, Gymnopogoninae, Perotidinae, and Trichoneurinae (Poaceae: Chloridoideae: Cynodonteae). Taxon 63: 275-286. doi:10.12705/632.35

Peterson, P. M. [et al. 2014b], Romaschenko, K., Arrieta, Y. H., & Saarela, J. M. 2014b. A molecular phylogeny and a new subgeneric classification of Sporobolus (Poaceae: Chloridoideae: Sporobolinae). Taxon 63: 1212-1243.

Peterson, P. M. [et al. 2015a], Romaschenko, K., & Herrera Arrieta, Y. 2015a. A molecular phylogeny and classification of the Eleusininae with a new genus, Micrachne (Poaceae: Chloridoideae: Cynodonteae). Taxon 64: 445-467.

Peterson, P. M. [et al. 2015b], Romaschenko, K., & Herrera Arrieta, Y. 2015b. Phylogeny and subgeneric classification of Bouteloua with a new species, B. herrera-arrietae (Poaceae: Chloridoideae: Cynodonteae: Boutelouinae). J. Syst. Evol. 53: 351-366.

Peterson, P. M. [et al. 2016a], Romaschenko, K., & Herrera Arrieta, Y. 2016a. A molecular phylogeny of the Cynodonteae (Poaceae: Chloridoideae). P. 185, in Botany 2016. Celebrating our History, Conserving our Future. Savannah, Georgia. [Abstracts.]

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Peterson, P. M. [et al. 2021b], Roquet, C., Romaschenko, K., Arrieta, Y. H., & Susanna, A. 2022 [= 2021b]. A biogeographical analysis of Muhlenbergia (Poaceae: Chloridoideae: Cynodonteae: Muhlenbergiinae). J. Syst. Evol. 60: 621-629. https://doi.org/10.1111/jse.12805

Peterson, P. M. [et al. 2021c], Soreng, R. J., Romaschenko, K., Barberá, P., Quintanar, A., Aedo, C., & Saarela, J. H. 2022 [ = 2021c]. Phylogeny and biogeography of Calamagrostis (Poaceae: Pooideae: Poeae: Agrostidinae), description of a new genus, Condilorachia (Calothecinae), and expansion of Greeneochloa and Pentapogon (Echinopogoninae). J. Syst. Evol. 60: 570-590. https://doi.org/10.1111/jse.12819

Peterson, P. M. [et al. 2022a], Romaschenko, K., & Arrieta, Y. H. 2022a. A phylogeny of the Triraphideae including Habrochloa and Nematopoa (Poaceae, Chloridoideae). PhytoKeys 194: 123-133.

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