<- Bromeliaceae Literature (most recent first) — Michael Barfuss

  1. Leme et al. 2025b (2025) Arachnandra, a new monotypic genus in Tillandsioideae (Bromeliaceae) from the Atlantic Forest in Brazil. Phytotaxa 693(1): 1-32.
  2. Leme et al. 2025 (2025) Twenty Miscellaneous New Species and One New Nothogenus and Nothospecies in Brazilian Bromeliaceae. Phytotaxa 692(1): 1-60.
  3. Groot et al. 2024 (2024/05/10) Closely related facultative and constitutive CAM phenotypes show little transcriptomic overlap in the subgenus Tillandsia. BioRxiv online.
  4. Groot et al. 2024 (2024) CAM evolution is associated with gene family expansion in an explosive bromeliad radiation. The Plant Cell 2024(00): 1–23 [online].
  5. Crego et al. 2023 (2023) Short structural variation fuelled CAM evolution within an explosive bromeliad radiation. bioRxiv preprint 1-51.
  6. Vera-Paz et al. 2023 (2023) Plastome phylogenomics reveals an early Pliocene North- and Central America colonization by long-distance dispersal from South America of a highly diverse bromeliad lineage. Frontiers in Plant Science 14: 1205511 (online).
  7. Seringer, Barfuss & Till, 2023 (2023) Tillandsia mecapacana – A New Name for Tillandsia carnosa var. boliviensis and an Emended Description. Die Bromelie 2023(1,2,3) : 76-91.
  8. Yardeni et al. 2023 (2023) The explosive radiation of the Neotropical Tillandsia subgenus Tillandsia (Bromeliaceae) has been facilitated by pervasive hybridization. , pp.
  9. Couto et al. 2022b (2022) Molecular Phylogenetics and Trait Evolution in Stigmatodon (Bromeliaceae, Tillandsioideae), an Endemic Genus to Brazilian Rocky Outcrops. Systematic Botany 47(2): 347-362.
  10. Donadio et al. 2022 (2022) Phylogenetic relationships and evolutionary trends in Tillandsia subgenus Diaphoranthema and xerophytic species of subgenus Phytarrhiza (Bromeliaceae: Tillandsioideae). Botanical Journal of the Linnean Society 20: 1–22.
  11. Mobus et al. 2021 (2021) Setting the evolutionary timeline: Tillandsia landbeckii in the Chilean Atacama Desert. Plant Systematics and Evolution 307(39): 1-12 (online).
  12. Yardeni et al. (2021) Taxon-specific or universal? Using target capture to study the evolutionary history of a rapid radiation. bioRxiv 2021.05.20.444989 Web.
  13. Bratzel et al. 2020 (2020) The low-copy nuclear gene Agt1 as a novel DNA barcoding marker for Bromeliaceae. BMC Plant Biology 20: 111.
  14. Kessous et al. 2019 (2019) Historical biogeography of a Brazilian lineage of Tillandsioideae (subtribe Vrieseinae, Bromeliaceae): the Paranaean Sea hypothesized as the main vicariant event. Botanical Journal of the Linnean Society boz038.
  15. Harpe et al. 2018 (2018) Genomic footprints of repeated evolution of CAM photosynthesis in tillandsioid bromeliads. bioRxiv .
  16. Pinzon et al. 2016 (2016) Phylogenetics and evolution of the Tillandsia utriculata complex (Bromeliaceae, Tillandsioideae) inferred from three plastid DNA markers and the ETS of the nuclear ribosomal DNA. Botanical Journal of the Linnean Society 181(3): 362-390.
  17. Barfuss et al. 2016 (2016) Taxonomic revision of Bromeliaceae subfam. Tillandsioideae based on a multi-locus DNA sequence phylogeny and morphology. Phytotaxa 279 (1): 001–097.
  18. Barfuss et al. 2015 (2015) Phylogeny and morphology demand a revised classification of Bromeliaceae subfamily Tillandsioideae. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
  19. Castello et al. 2015 (2015) Unraveling the Tillandsia capillaris complex: two species coexisting in sympatry?. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
  20. Givnish et al. 2014 (2014) Adaptive radiation, correlated and contingent evolution, and net species diversification in Bromeliaceae. Molecular Phylogenetics and Evolution 71: 55-78.
  21. Pinzon 2013 (2013) Phylogeny and evolution of Tillandsia subg. Tillandsia: a preliminary project report. Journal of the Bromeliad Society 63(1): 75-82.
  22. Barfuss 2012 (2012) Molecular studies in Bromeliaceae: Implications of plastid and nuclear DNA markers for phylogeny, biogeography, and character evolution with emphasis on a new classification of Tillandsioideae. , 234 pp.
  23. Givnish et al. 2011 (2011) Phylogeny, Adaptive Radiation, And Historical Biogeography In Bromeliaceae: Insights From An Eight-locus Plastid Phylogeny. American Journal of Botany 98(5): 872–895.
  24. Schulte et al. 2009 (2009) Phylogeny of Bromelioideae (Bromeliaceae) inferred from nuclear and plastid DNA loci reveals the evolution of the tank habit within the subfamily. Molecular Phylogenetics and Evolution 51(2): 327-339.
  25. Barfuss et al. 2005 (2005) Phylogenetic relationships in subfamily Tillandsioideae (Bromeliaceae) based on DNA sequence data from seven plastid regions. American journal of botany 92(2): 337-351.
  26. Barfuss et al. 2004 (2004) Molecular Phylogeny in Subfamily Tillandsioideae (Bromeliaceae) Based on Six cpDNA Markers: An Update. Journal of the Bromeliad Society 54(1): 9-17.