Your search keyword '"Schneider, Julio V."' showing total 150 results

1. A study on the genetic population structure and the tetrodotoxin content of rough-skinned newts, Taricha granulosa (Salamandridae), from their northern range of distribution

Author

Mebs, Dietrich, Schneider, Julio V., Schröder, Oskar, Yotsu-Yamashita, Mari, Harley, John R., Mogk, Linda, and Köhler, Gunther

Published

2022

2. Phylogenomics of the tropical plant family Ochnaceae using targeted enrichment of nuclear genes and 250+ taxa

Author

Schneider, Julio V., Jungcurt, Tanja, Cardoso, Domingos, Amorim, André Márcio, Töpel, Mats, Andermann, Tobias, Poncy, Odile, Berberich, Thomas, and Zizka, Georg

Published

2021

3. Origin and diversification of Cristaria (Malvaceae) parallel Andean orogeny and onset of hyperaridity in the Atacama Desert

Author

Böhnert, Tim, Luebert, Federico, Ritter, Benedikt, Merklinger, Felix F., Stoll, Alexandra, Schneider, Julio V., Quandt, Dietmar, and Weigend, Maximilian

Published

2019

4. A new species of Rhyacophila Pictet, 1834 (Trichoptera, Rhyacophilidae) from Corsica with the genomic characterization of the holotype.

Author

Rázuri-Gonzales, Ernesto, Graf, Wolfram, Heckenhauer, Jacqueline, Schneider, Julio V., and Pauls, Steffen U.

Subjects

NUCLEOTIDE sequencing, CYTOCHROME oxidase, CADDISFLIES, GENOMICS, GENOMES, SPECIES

Abstract

We describe a new species in the Rhyacophila tristis group, Rhyacophila lignumvallis Graf & Rázuri-Gonzales, sp. nov., from the island of Corsica (France) based on a single male specimen. In addition to the morphological differences between the new species and the most similar species in the group, we also provide a phylogenetic tree based on the mitochondrial cytochrome c oxidase subunit I (mtCOI), including sequences from 16 out of the 28 currently recognized species in the group. These data, together with conspecific larval sequences, support the status of the new species and shed light on an additional potential new species near Rhyacophila pubescens. Using a low-cost next-generation sequencing approach, we generated the mito- and draft nuclear genome assembly of the holotype of R. lignumvallis sp. nov. as well as that of R. tsurakiana. This genetic data represents an important additional characterization to the description of morphological features and is valuable for future investigations, such as population or phylogenomic studies. [ABSTRACT FROM AUTHOR]

Published

2024

5. Phylogenetic Reconstruction of the Neotropical Family Quiinaceae (Malpighiales) Based on Morphology with Remarks on the Evolution of an Androdioecious Sex Distribution

Author

Schneider, Julio V, Swenson, Ulf, Zizka, Georg, and BioStor

Published

2002

6. Phylogeny, taxonomy and biogeography of Neotropical Quiinoideae (Ochnaceae s.l.)

Author

Schneider, Julio V. and Zizka, Georg

Published

2017

7. Successional and Mature Stands in an Upper Andean Rain Forest Transect of Venezuela: Do Leaf Characteristics of Woody Species Differ?

Author

Schneider, Julio V. and Zizka, Georg

Published

2003

8. Phylogenetic Reconstruction of the Neotropical Family Quiinaceae (Malpighiales) Based on Morphology with Remarks on the Evolution of an Androdioecious Sex Distribution

Author

Schneider, Julio V., Swenson, Ulf, and Zizka, Georg

Published

2002

9. The Genus Touroulia Aubl. (Quiinaceae)

Author

Zizka, Georg and Schneider, Julio V.

Published

1999

10. QUIINACEAE

Author

Schneider, Julio V. and Zizka, Georg

Published

2016

11. The impact of sequencing depth and relatedness of the reference genome in population genomic studies: A case study with two caddisfly species (Trichoptera, Rhyacophilidae, Himalopsyche)

Author

Deng, Xi‐Ling, primary, Frandsen, Paul B., additional, Dikow, Rebecca B., additional, Favre, Adrien, additional, Shah, Deep Narayan, additional, Shah, Ram Devi Tachamo, additional, Schneider, Julio V., additional, Heckenhauer, Jacqueline, additional, and Pauls, Steffen U., additional

Published

2022

12. Phylogenetics, ancestral state reconstruction, and a new infrafamilial classification of the pantropical Ochnaceae (Medusagynaceae, Ochnaceae s.str., Quiinaceae) based on five DNA regions

Author

Schneider, Julio V., Bissiengou, Pulcherie, Amaral, Maria do Carmo E., Tahir, Ali, Fay, Michael F., Thines, Marco, Sosef, Marc S.M., Zizka, Georg, and Chatrou, Lars W.

Published

2014

13. Using high-resolution remote sensing data for habitat suitability models of Bromeliaceae in the city of Mérida, Venezuela

Author

Judith, Caroline, Schneider, Julio V., Schmidt, Marco, Ortega, Rengifo, Gaviria, Juan, and Zizka, Georg

Published

2013

14. Taxonomic revision of the Chilean Puya species (Puyoideae, Bromeliaceae), with special notes on the Puya alpestris-Puya berteroniana species complex

Author

Zizka, Georg, Schneider, Julio V., Schulte, Katharina, and Novoa, Patricio

Published

2013

15. Taxonomic Revision of the Neotropical Genus Lacunaria (Quiinaceae/Ochnaceae s.1.)

Author

Schneider, Julio V. and Zizka, Georg

Published

2012

16. Phylogeny of the eudicot order Malpighiales: analysis of a recalcitrant clade with sequences of the petD group II intron

Author

Korotkova, Nadja, Schneider, Julio V., Quandt, Dietmar, Worberg, Andreas, Zizka, Georg, and Borsch, Thomas

Published

2009

17. Predominantly eastward long-distance dispersal in pantropical ochnaceae inferred from ancestral range estimation and phylogenomics

Author

Schneider, Julio V., Jungcurt, Tanja, Cardoso, Domingos, Amorim, André Márcio, Paule, Juraj, Zizka, Georg, Schneider, Julio V., Jungcurt, Tanja, Cardoso, Domingos, Amorim, André Márcio, Paule, Juraj, and Zizka, Georg

Abstract

Ochnaceae is a pantropical family with multiple transoceanic disjunctions at deep and shallow levels. Earlier attempts to unravel the processes that led to such biogeographic patterns suffered from insufficient phylogenetic resolution and unclear delimitation of some of the genera. In the present study, we estimated divergence time and ancestral ranges based on a phylogenomic framework with a well-resolved phylogenetic backbone to tackle issues of the timing and direction of dispersal that may explain the modern global distribution of Ochnaceae. The nuclear data provided the more robust framework for divergence time estimation compared to the plastome-scale data, although differences in the inferred clade ages were mostly small. While Ochnaceae most likely originated in West Gondwana during the Late Cretaceous, all crown-group disjunctions are inferred as dispersal-based, most of them as transoceanic long-distance dispersal (LDD) during the Cenozoic. All LDDs occurred in an eastward direction except for the SE Asian clade of Sauvagesieae, which was founded by trans-Pacific dispersal from South America. The most species-rich clade by far, Ochninae, originated from either a widespread neotropical-African ancestor or a solely neotropical ancestor which then dispersed to Africa. The ancestors of this clade then diversified in Africa, followed by subsequent dispersal to the Malagasy region and tropical Asia on multiple instances in three genera during the Miocene-Pliocene. In particular, Ochna might have used the South Arabian land corridor to reach South Asia. Thus, the pantropical distribution of Ochnaceae is the result of LDD either transoceanic or via land bridges/corridors, whereas vicariance might have played a role only along the stem of the family.

Published

2022

18. Small and slow is safe: On the drought tolerance of tropical tree species

Author

Guillemot, Joannès, Martin‐Stpaul, Nicolas K., Bulascoschi, Leticia, Poorter, Lourens, Morin, Xavier, Pinho, Bruno X., Maire, Guerric, Bittencourt, Paulo, Oliveira, Rafael S., Bongers, Frans, Brouwer, Rens, Pereira, Luciano, Gonzalez Melo, German Andrés, Boonman, Coline C.F., Brown, Kerry A., Cerabolini, Bruno E.L., Niinemets, Ülo, Onoda, Yusuke, Schneider, Julio V., Sheremetiev, Serge, Brancalion, Pedro H.S., Guillemot, Joannès, Martin‐Stpaul, Nicolas K., Bulascoschi, Leticia, Poorter, Lourens, Morin, Xavier, Pinho, Bruno X., Maire, Guerric, Bittencourt, Paulo, Oliveira, Rafael S., Bongers, Frans, Brouwer, Rens, Pereira, Luciano, Gonzalez Melo, German Andrés, Boonman, Coline C.F., Brown, Kerry A., Cerabolini, Bruno E.L., Niinemets, Ülo, Onoda, Yusuke, Schneider, Julio V., Sheremetiev, Serge, and Brancalion, Pedro H.S.

Abstract

Understanding how evolutionary history and the coordination between trait trade-off axes shape the drought tolerance of trees is crucial to predict forest dynamics under climate change. Here, we compiled traits related to drought tolerance and the fast-slow and stature-recruitment trade-off axes in 601 tropical woody species to explore their covariations and phylogenetic signals. We found that xylem resistance to embolism (P50) determines the risk of hydraulic failure, while the functional significance of leaf turgor loss point (TLP) relies on its coordination with water use strategies. P50 and TLP exhibit weak phylogenetic signals and substantial variation within genera. TLP is closely associated with the fast-slow trait axis: slow species maintain leaf functioning under higher water stress. P50 is associated with both the fast-slow and stature-recruitment trait axes: slow and small species exhibit more resistant xylem. Lower leaf phosphorus concentration is associated with more resistant xylem, which suggests a (nutrient and drought) stress-tolerance syndrome in the tropics. Overall, our results imply that (1) drought tolerance is under strong selective pressure in tropical forests, and TLP and P50 result from the repeated evolutionary adaptation of closely related taxa, and (2) drought tolerance is coordinated with the ecological strategies governing tropical forest demography. These findings provide a physiological basis to interpret the drought-induced shift toward slow-growing, smaller, denser-wooded trees observed in the tropics, with implications for forest restoration programmes.

Published

2022

19. Molecular evidence for hybridization and introgression in the neotropical coastal desert-endemic Palaua (Malveae, Malvaceae)

Author

Schneider, Julio V., Schulte, Katharina, Aguilar, Javier Fuertes, and Huertas, Marilú L.

Published

2011

20. Phylogenetic Analysis of Palaua (Malveae, Malvaceae) Based on Plastid and Nuclear Sequences

Author

Huertas, Marilú L., Schneider, Julio V., and Zizka, Georg

Published

2007

21. Plant migration under long‐lasting hyperaridity – phylogenomics unravels recent biogeographic history in one of the oldest deserts on Earth

Author

Böhnert, Tim, primary, Luebert, Federico, additional, Merklinger, Felix F., additional, Harpke, Dörte, additional, Stoll, Alexandra, additional, Schneider, Julio V., additional, Blattner, Frank R., additional, Quandt, Dietmar, additional, and Weigend, Maximilian, additional

Published

2022

22. Predominantly Eastward Long-Distance Dispersal in Pantropical Ochnaceae Inferred From Ancestral Range Estimation and Phylogenomics

Author

Schneider, Julio V., primary, Jungcurt, Tanja, additional, Cardoso, Domingos, additional, Amorim, André M., additional, Paule, Juraj, additional, and Zizka, Georg, additional

Published

2022

23. Small and slow is safe: On the drought tolerance of tropical tree species

Author

Guillemot, Joannès, primary, Martin‐StPaul, Nicolas K., additional, Bulascoschi, Leticia, additional, Poorter, Lourens, additional, Morin, Xavier, additional, Pinho, Bruno X., additional, le Maire, Guerric, additional, R. L. Bittencourt, Paulo, additional, Oliveira, Rafael S., additional, Bongers, Frans, additional, Brouwer, Rens, additional, Pereira, Luciano, additional, Gonzalez Melo, German Andrés, additional, Boonman, Coline C. F., additional, Brown, Kerry A., additional, Cerabolini, Bruno E. L., additional, Niinemets, Ülo, additional, Onoda, Yusuke, additional, Schneider, Julio V., additional, Sheremetiev, Serge, additional, and Brancalion, Pedro H. S., additional

Published

2022

24. Genome size evolution in the diverse insect order Trichoptera

Author

Heckenhauer, Jacqueline, primary, Frandsen, Paul B, additional, Sproul, John S, additional, Li, Zheng, additional, Paule, Juraj, additional, Larracuente, Amanda M, additional, Maughan, Peter J, additional, Barker, Michael S, additional, Schneider, Julio V, additional, Stewart, Russell J, additional, and Pauls, Steffen U, additional

Published

2022

25. Phylogenetics of Ochna (Ochnaceae) and a new infrageneric classification

Author

Shah, Toral, primary, Mashimba, Fandey H, additional, Suleiman, Haji O, additional, Mbailwa, Yahya S, additional, Schneider, Julio V, additional, Zizka, Georg, additional, Savolainen, Vincent, additional, Larridon, Isabel, additional, and Darbyshire, Iain, additional

Published

2021

26. Population genetic structure and connectivity in three montane freshwater invertebrate species (Ephemeroptera, Plecoptera, Amphipoda) with differing life cycles and dispersal capabilities

Author

Schröder, Oskar, primary, Schneider, Julio V., additional, Schell, Tilman, additional, Seifert, Linda, additional, and Pauls, Steffen U., additional

Published

2021

27. Joining forces in Ochnaceae phylogenomics: a tale of two targeted sequencing probe kits

Author

Shah, Toral, primary, Schneider, Julio V., additional, Zizka, Georg, additional, Maurin, Olivier, additional, Baker, William, additional, Forest, Félix, additional, Brewer, Grace E., additional, Savolainen, Vincent, additional, Darbyshire, Iain, additional, and Larridon, Isabel, additional

Published

2021

28. Joining forces in Ochnaceae phylogenomics: a tale of two targeted sequencing probe kits

Author

Shah, Toral, Schneider, Julio V., Zizka, Georg, Maurin, Olivier, Baker, William, Forest, Félix, Brewer, Grace E., Savolainen, Vincent, Darbyshire, Iain, Larridon, Isabel, Shah, Toral, Schneider, Julio V., Zizka, Georg, Maurin, Olivier, Baker, William, Forest, Félix, Brewer, Grace E., Savolainen, Vincent, Darbyshire, Iain, and Larridon, Isabel

Abstract

Premise: Both universal and family-specific targeted sequencing probe kits are becoming widely used for reconstruction of phylogenetic relationships in angiosperms. Within the pantropical Ochnaceae, we show that with careful data filtering, universal kits are equally as capable in resolving intergeneric relationships as custom probe kits. Furthermore, we show the strength in combining data from both kits to mitigate bias and provide a more robust result to resolve evolutionary relationships. Methods: We sampled 23 Ochnaceae genera and used targeted sequencing with two probe kits, the universal Angiosperms353 kit and a family-specific kit. We used maximum likelihood inference with a concatenated matrix of loci and multispecies-coalescence approaches to infer relationships in the family. We explored phylogenetic informativeness and the impact of missing data on resolution and tree support. Results: For the Angiosperms353 data set, the concatenation approach provided results more congruent with those of the Ochnaceae-specific data set. Filtering missing data was most impactful on the Angiosperms353 data set, with a relaxed threshold being the optimum scenario. The Ochnaceae-specific data set resolved consistent topologies using both inference methods, and no major improvements were obtained after data filtering. Merging of data obtained with the two kits resulted in a well-supported phylogenetic tree. Conclusions: The Angiosperms353 data set improved upon data filtering, and missing data played an important role in phylogenetic reconstruction. The Angiosperms353 data set resolved the phylogenetic backbone of Ochnaceae as equally well as the family specific data set. All analyses indicated that both Sauvagesia L. and Campylospermum Tiegh. as currently circumscribed are polyphyletic and require revised delimitation.

Published

2021

29. Genome size evolution in the diverse insect order Trichoptera

Author

Heckenhauer, Jacqueline, primary, Frandsen, Paul B., additional, Sproul, John S., additional, Li, Zheng, additional, Paule, Juraj, additional, Larracuente, Amanda M., additional, Maughan, Peter J., additional, Barker, Michael S., additional, Schneider, Julio V., additional, Stewart, Russell J., additional, and Pauls, Steffen U., additional

Published

2021

30. Inventario florístico de un bosque altimontano húmedo en el Valle de San Javier, Edo. Mérida, Venezuela

Author

Schneider, Julio V., Gaviria, Juan, and Zizka, Georg

Published

2003

31. Variación morfológica de una población de Tillandsia biflora Ruiz & Pav. (Bromeliaceae) en un bosque altoandino de Venezuela (La Caña, Valle de San Javier, Edo. Mérida)

Author

Zipp, Daniela, Schneider, Julio V., Gaviria, Juan, and Zizka, Georg

Published

2003

32. Resolving Recalcitrant Clades in the Pantropical Ochnaceae: Insights From Comparative Phylogenomics of Plastome and Nuclear Genomic Data Derived From Targeted Sequencing

Author

Schneider, Julio V., primary, Paule, Juraj, additional, Jungcurt, Tanja, additional, Cardoso, Domingos, additional, Amorim, André Márcio, additional, Berberich, Thomas, additional, and Zizka, Georg, additional

Published

2021

33. Genetic data support local persistence in multiple glacial refugia in the montane net‐winged midge Liponeura cinerascens cinerascens (diptera, blephariceridae)

Author

Schröder, Oskar, primary, Cavanaugh, Kirstin K., additional, Schneider, Julio V., additional, Schell, Tilman, additional, Bonada, Núria, additional, Seifert, Linda, additional, and Pauls, Steffen U., additional

Published

2021

34. Phylogenomics of the tropical plant family Ochnaceae using targeted enrichment of nuclear genes and 250+ taxa

Author

Schneider, Julio V., primary, Jungcurt, Tanja, additional, Cardoso, Domingos, additional, Amorim, André Márcio, additional, Töpel, Mats, additional, Andermann, Tobias, additional, Poncy, Odile, additional, Berberich, Thomas, additional, and Zizka, Georg, additional

Published

2020

35. Karyotype analysis and polyploidy in Palaua and a comparison with its sister group Fuertesimalva (Malvaceae)

Author

SCHNEIDER, Julio V and HUERTAS, Marilú L

Published

2010

36. Phylogenetics of Ochna (Ochnaceae) and a new infrageneric classification.

Author

Shah, Toral, Mashimba, Fandey H, Suleiman, Haji O, Mbailwa, Yahya S, Schneider, Julio V, Zizka, Georg, Savolainen, Vincent, Larridon, Isabel, and Darbyshire, Iain

Subjects

PHYLOGENY, CLASSIFICATION, DNA sequencing, TAXONOMY

Abstract

Advances in high-throughput DNA sequencing are allowing faster and more affordable generation of molecular phylogenetic trees for many organisms. However, resolving relationships at species level is still challenging, particularly for taxonomically difficult groups. Until recently, the classification of Ochna had been based only on morphological data. Here, we present the first comprehensive phylogenomic study for the genus using targeted sequencing with a custom probe kit. We sampled c. 85% of species to evaluate the current infrageneric classification. Our results show that the data generated using the custom probe kit are effective in resolving relationships in the genus, revealing three sections consistent with the current classification and a new section consisting of species from Madagascar and the Mascarene Islands. Our results provide the first insights into the evolutionary relationships of several widespread and morphologically diverse species numerous poorly known and potentially new species to science. We demonstrate that for morphologically challenging groups such as Ochna , an integrated approach to classification is essential. Phylogenomic results are only informative when derived from accurately named samples. There is a symbiotic relationship between molecular phylogenomics and morphology-based taxonomy, with taxonomic expertise a requirement to accurately interpret the phylogenomic results. [ABSTRACT FROM AUTHOR]

Published

2022

37. Population genetic structure and connectivity in three montane freshwater invertebrate species (Ephemeroptera, Plecoptera, Amphipoda) with differing life cycles and dispersal capabilities.

Author

Schröder, Oskar, Schneider, Julio V., Schell, Tilman, Seifert, Linda, and Pauls, Steffen U.

Subjects

*FRESHWATER invertebrates, *AMPHIPODA, *AQUATIC invertebrates, *MAYFLIES, *STONEFLIES, *LIFE history theory, *SPECIES

Abstract

Dispersal abilities and the resulting levels of connectivity between streams influence population structure in aquatic organisms. We investigated how different dispersal and life‐history traits affect gene flow and population structure in three aquatic invertebrate species in a central European mountain range.We used microsatellite markers and mitochondrial cytochrome oxidase I barcode data to assess small‐scale population structure and connectivity of the mayfly Baetis alpinus, the stonefly Brachyptera seticornis, and the amphipod Gammarus fossarum in seven streams within Bavarian Forest National Park, Germany.Significant population structure within the study area was detected in B. alpinus and G. fossarum, whereas B. seticornis had signatures of panmixia. In G. fossarum, that structure corresponded to stream topography, while in B. alpinus it did not. The Bavarian Forest range appears to be a contact zone for different mitochondrial lineages of B. alpinus and G. fossarum.Limited geneflow between sample sites in B. alpinus can be explained by the species' short adult lifespans, which restricts dispersal between sites. Since imagines are able to disperse via adult flight population structure is, however, decoupled from stream topology. Longer‐lived B. seticornis is better able to maintain geneflow between sample sites. In flightless G. fossarum, population structure corresponding to stream topology can be explained by limited dispersal capabilities between streams.Dispersal ability alone is insufficient to predict or explain patterns of gene flow and connectivity for individual species, and should be examined together with life‐history traits when assessing population and community structure. [ABSTRACT FROM AUTHOR]

Published

2022

38. TRY plant trait database – enhanced coverage and open access

Author

Kattge, Jens, Bönisch, Gerhard, Díaz, Sandra, Lavorel, Sandra, Prentice, Iain Colin, Leadley, Paul, Tautenhahn, Susanne, Werner, Gijsbert D. A., Aakala, Tuomas, Abedi, Mehdi, Acosta, Alicia T. R., Adamidis, George C., Adamson, Kairi, Aiba, Masahiro, Albert, Cécile H., Alcántara, Julio M., Alcázar C, Carolina, Aleixo, Izabela, Ali, Hamada, Amiaud, Bernard, Ammer, Christian, Amoroso, Mariano M., Anand, Madhur, Anderson, Carolyn, Anten, Niels, Antos, Joseph, Apgaua, Deborah Mattos Guimarães, Ashman, Tia-Lynn, Asmara, Degi Harja, Asner, Gregory P., Aspinwall, Michael, Atkin, Owen, Aubin, Isabelle, Baastrup-Spohr, Lars, Bahalkeh, Khadijeh, Bahn, Michael, Baker, Timothy, Baker, William J., Bakker, Jan P., Baldocchi, Dennis, Baltzer, Jennifer, Banerjee, Arindam, Baranger, Anne, Barlow, Jos, Barneche, Diego R., Baruch, Zdravko, Bastianelli, Denis, Battles, John, Bauerle, William, Bauters, Marijn, Bazzato, Erika, Beckmann, Michael, Beeckman, Hans, Beierkuhnlein, Carl, Bekker, Renee, Belfry, Gavin, Belluau, Michael, Beloiu, Mirela, Benavides, Raquel, Benomar, Lahcen, Berdugo-Lattke, Mary Lee, Berenguer, Erika, Bergamin, Rodrigo, Bergmann, Joana, Bergmann Carlucci, Marcos, Berner, Logan, Bernhardt-Römermann, Markus, Bigler, Christof, Bjorkman, Anne D., Blackman, Chris, Blanco, Carolina, Blonder, Benjamin, Blumenthal, Dana, Bocanegra-González, Kelly T., Boeckx, Pascal, Bohlman, Stephanie, Böhning-Gaese, Katrin, Boisvert-Marsh, Laura, Bond, William, Bond-Lamberty, Ben, Boom, Arnoud, Boonman, Coline C. F., Bordin, Kauane, Boughton, Elizabeth H., Boukili, Vanessa, Bowman, David M. J. S., Bravo, Sandra, Brendel, Marco Richard, Broadley, Martin R., Brown, Kerry A., Bruelheide, Helge, Brumnich, Federico, Bruun, Hans Henrik, Bruy, David, Buchanan, Serra W., Bucher, Solveig Franziska, Buchmann, Nina, Buitenwerf, Robert, Bunker, Daniel E., Bürger, Jana, Burrascano, Sabina, Burslem, David F. R. P., Butterfield, Bradley J., Byun, Chaeho, Marques, Marcia, Scalon, Marina C., Caccianiga, Marco, Cadotte, Marc, Cailleret, Maxime, Camac, James, Camarero, Jesús Julio, Campany, Courtney, Campetella, Giandiego, Campos, Juan Antonio, Cano-Arboleda, Laura, Canullo, Roberto, Carbognani, Michele, Carvalho, Fabio, Casanoves, Fernando, Castagneyrol, Bastien, Catford, Jane A., Cavender-Bares, Jeannine, Cerabolini, Bruno E. L., Cervellini, Marco, Chacón-Madrigal, Eduardo, Chapin, Kenneth, Chapin, F. Stuart, Chelli, Stefano, Chen, Si-Chong, Chen, Anping, Cherubini, Paolo, Chianucci, Francesco, Choat, Brendan, Chung, Kyong-Sook, Chytrý, Milan, Ciccarelli, Daniela, Coll, Lluís, Collins, Courtney G., Conti, Luisa, Coomes, David, Cornelissen, Johannes H. C., Cornwell, William K., Corona, Piermaria, Coyea, Marie, Craine, Joseph, Craven, Dylan, Cromsigt, Joris P. G. M., Csecserits, Anikó, Cufar, Katarina, Cuntz, Matthias, da Silva, Ana Carolina, Dahlin, Kyla M., Dainese, Matteo, Dalke, Igor, Dalle Fratte, Michele, Dang-Le, Anh Tuan, Danihelka, Jirí, Dannoura, Masako, Dawson, Samantha, de Beer, Arend Jacobus, De Frutos, Angel, De Long, Jonathan R., Dechant, Benjamin, Delagrange, Sylvain, Delpierre, Nicolas, Derroire, Géraldine, Dias, Arildo S., Diaz-Toribio, Milton Hugo, Dimitrakopoulos, Panayiotis G., Dobrowolski, Mark, Doktor, Daniel, Dřevojan, Pavel, Dong, Ning, Dransfield, John, Dressler, Stefan, Duarte, Leandro, Ducouret, Emilie, Dullinger, Stefan, Durka, Walter, Duursma, Remko, Dymova, Olga, E-Vojtkó, Anna, Eckstein, Rolf Lutz, Ejtehadi, Hamid, Elser, James, Emilio, Thaise, Engemann, Kristine, Erfanian, Mohammad Bagher, Erfmeier, Alexandra, Esquivel-Muelbert, Adriane, Esser, Gerd, Estiarte, Marc, Domingues, Tomas F., Fagan, William F., Fagúndez, Jaime, Falster, Daniel S., Fang, Jingyun, Farris, Emmanuele, Fazlioglu, Fatih, Feng, Yanhao, Fernandez-Mendez, Fernando, Ferrara, Carlotta, Ferreira, Joice, Fidelis, Alessandra, Finegan, Bryan, Firn, Jennifer, Flowers, Timothy J., Flynn, Dan F. B., Fontana, Veronika, Forey, Estelle, Forgiarini, Cristiane, François, Louis, Frangipani, Marcelo, Frank, Dorothea, Frenette-Dussault, Cedric, Freschet, Grégoire T., Fry, Ellen L., Fyllas, Nikolaos M., Mazzochini, Guilherme G., Gachet, Sophie, Gallagher, Rachael, Ganade, Gislene, Ganga, Francesca, García-Palacios, Pablo, Gargaglione, Verónica, Garnier, Eric, Garrido, Jose Luis, de Gasper, André Luís, Gea-Izquierdo, Guillermo, Gibson, David, Gillison, Andrew N., Giroldo, Aelton, Glasenhardt, Mary-Claire, Gleason, Sean, Gliesch, Mariana, Goldberg, Emma, Göldel, Bastian, Gonzalez-Akre, Erika, Gonzalez-Andujar, Jose L., González-Melo, Andrés, González-Robles, Ana, Graae, Bente Jessen, Granda, Elena, Graves, Sarah, Green, Walton A., Gregor, Thomas, Gross, Nicolas, Guerin, Greg R., Günther, Angela, Gutiérrez, Alvaro G., Haddock, Lillie, Haines, Anna, Hall, Jefferson, Hambuckers, Alain, Han, Wenxuan, Harrison, Sandy P., Hattingh, Wesley, Hawes, Joseph E., He, Tianhua, He, Pengcheng, Heberling, Jacob Mason, Helm, Aveliina, Hempel, Stefan, Hentschel, Jörn, Hérault, Bruno, Hereş, Ana-Maria, Herz, Katharina, Heuertz, Myriam, Hickler, Thomas, Hietz, Peter, Higuchi, Pedro, Hipp, Andrew L., Hirons, Andrew, Hock, Maria, Hogan, James Aaron, Holl, Karen, Honnay, Olivier, Hornstein, Daniel, Hou, Enqing, Hough-Snee, Nate, Hovstad, Knut Anders, Ichie, Tomoaki, Igić, Boris, Illa, Estela, Isaac, Marney, Ishihara, Masae, Ivanov, Leonid, Ivanova, Larissa, Iversen, Colleen M., Izquierdo, Jordi, Jackson, Robert B., Jackson, Benjamin, Jactel, Hervé, Jagodzinski, Andrzej M., Jandt, Ute, Jansen, Steven, Jenkins, Thomas, Jentsch, Anke, Jespersen, Jens Rasmus Plantener, Jiang, Guo-Feng, Johansen, Jesper Liengaard, Johnson, David, Jokela, Eric J., Joly, Carlos Alfredo, Jordan, Gregory J., Joseph, Grant Stuart, Junaedi, Decky, Junker, Robert R., Justes, Eric, Kabzems, Richard, Kane, Jeffrey, Kaplan, Zdenek, Kattenborn, Teja, Kavelenova, Lyudmila, Kearsley, Elizabeth, Kempel, Anne, Kenzo, Tanaka, Kerkhoff, Andrew, Khalil, Mohammed I., Kinlock, Nicole L., Kissling, Wilm Daniel, Kitajima, Kaoru, Kitzberger, Thomas, Kjøller, Rasmus, Klein, Tamir, Kleyer, Michael, Klimešová, Jitka, Klipel, Joice, Kloeppel, Brian, Klotz, Stefan, Knops, Johannes M. H., Kohyama, Takashi, Koike, Fumito, Kollmann, Johannes, Komac, Benjamin, Komatsu, Kimberly, König, Christian, Kraft, Nathan J. B., Kramer, Koen, Kreft, Holger, Kühn, Ingolf, Kumarathunge, Dushan, Kuppler, Jonas, Kurokawa, Hiroko, Kurosawa, Yoko, Kuyah, Shem, Laclau, Jean-Paul, Lafleur, Benoit, Lallai, Erik, Lamb, Eric, Lamprecht, Andrea, Larkin, Daniel J., Laughlin, Daniel, Le Bagousse-Pinguet, Yoann, le Maire, Guerric, le Roux, Peter C., le Roux, Elizabeth, Lee, Tali, Lens, Frederic, Lewis, Simon L., Lhotsky, Barbara, Li, Yuanzhi, Li, Xine, Lichstein, Jeremy W., Liebergesell, Mario, Lim, Jun Ying, Lin, Yan-Shih, Linares, Juan Carlos, Liu, Chunjiang, Liu, Daijun, Liu, Udayangani, Livingstone, Stuart, Llusià, Joan, Lohbeck, Madelon, López-García, Álvaro, Lopez-Gonzalez, Gabriela, Lososová, Zdeňka, Louault, Frédérique, Lukács, Balázs A., Lukeš, Petr, Luo, Yunjian, Lussu, Michele, Ma, Siyan, Maciel Rabelo Pereira, Camilla, Mack, Michelle, Maire, Vincent, Mäkelä, Annikki, Mäkinen, Harri, Malhado, Ana Claudia Mendes, Mallik, Azim, Manning, Peter, Manzoni, Stefano, Marchetti, Zuleica, Marchino, Luca, Marcilio-Silva, Vinicius, Marcon, Eric, Marignani, Michela, Markesteijn, Lars, Martin, Adam, Martínez-Garza, Cristina, Martínez-Vilalta, Jordi, Mašková, Tereza, Mason, Kelly, Mason, Norman, Massad, Tara Joy, Masse, Jacynthe, Mayrose, Itay, McCarthy, James, McCormack, M. Luke, McCulloh, Katherine, McFadden, Ian R., McGill, Brian J., McPartland, Mara Y., Medeiros, Juliana S., Medlyn, Belinda, Meerts, Pierre, Mehrabi, Zia, Meir, Patrick, Melo, Felipe P. L., Mencuccini, Maurizio, Meredieu, Céline, Messier, Julie, Mészáros, Ilona, Metsaranta, Juha, Michaletz, Sean T., Michelaki, Chrysanthi, Migalina, Svetlana, Milla, Ruben, Miller, Jesse E. D., Minden, Vanessa, Ming, Ray, Mokany, Karel, Moles, Angela T., Molnár V, Attila, Molofsky, Jane, Molz, Martin, Montgomery, Rebecca A., Monty, Arnaud, Moravcová, Lenka, Moreno-Martínez, Alvaro, Moretti, Marco, Mori, Akira S., Mori, Shigeta, Morris, Dave, Morrison, Jane, Mucina, Ladislav, Mueller, Sandra, Muir, Christopher D., Müller, Sandra Cristina, Munoz, François, Myers-Smith, Isla H., Myster, Randall W., Nagano, Masahiro, Naidu, Shawna, Narayanan, Ayyappan, Natesan, Balachandran, Negoita, Luka, Nelson, Andrew S., Neuschulz, Eike Lena, Ni, Jian, Niedrist, Georg, Nieto, Jhon, Niinemets, Ülo, Nolan, Rachael, Nottebrock, Henning, Nouvellon, Yann, Novakovskiy, Alexander, Network, The Nutrient, Nystuen, Kristin Odden, O'Grady, Anthony, O'Hara, Kevin, O'Reilly-Nugent, Andrew, Oakley, Simon, Oberhuber, Walter, Ohtsuka, Toshiyuki, Oliveira, Ricardo, Öllerer, Kinga, Olson, Mark E., Onipchenko, Vladimir, Onoda, Yusuke, Onstein, Renske E., Ordonez, Jenny C., Osada, Noriyuki, Ostonen, Ivika, Ottaviani, Gianluigi, Otto, Sarah, Overbeck, Gerhard E., Ozinga, Wim A., Pahl, Anna T., Paine, C. E. Timothy, Pakeman, Robin J., Papageorgiou, Aristotelis C., Parfionova, Evgeniya, Pärtel, Meelis, Patacca, Marco, Paula, Susana, Paule, Juraj, Pauli, Harald, Pausas, Juli G., Peco, Begoña, Penuelas, Josep, Perea, Antonio, Peri, Pablo Luis, Petisco-Souza, Ana Carolina, Petraglia, Alessandro, Petritan, Any Mary, Phillips, Oliver L., Pierce, Simon, Pillar, Valério D., Pisek, Jan, Pomogaybin, Alexandr, Poorter, Hendrik, Portsmuth, Angelika, Poschlod, Peter, Potvin, Catherine, Pounds, Devon, Powell, A. Shafer, Power, Sally A., Prinzing, Andreas, Puglielli, Giacomo, Pyšek, Petr, Raevel, Valerie, Rammig, Anja, Ransijn, Johannes, Ray, Courtenay A., Reich, Peter B., Reichstein, Markus, Reid, Douglas E. B., Réjou-Méchain, Maxime, de Dios, Victor Resco, Ribeiro, Sabina, Richardson, Sarah, Riibak, Kersti, Rillig, Matthias C., Riviera, Fiamma, Robert, Elisabeth M. R., Roberts, Scott, Robroek, Bjorn, Roddy, Adam, Rodrigues, Arthur Vinicius, Rogers, Alistair, Rollinson, Emily, Rolo, Victor, Römermann, Christine, Ronzhina, Dina, Roscher, Christiane, Rosell, Julieta A., Rosenfield, Milena Fermina, Rossi, Christian, Roy, David B., Royer-Tardif, Samuel, Rüger, Nadja, Ruiz-Peinado, Ricardo, Rumpf, Sabine B., Rusch, Graciela M., Ryo, Masahiro, Sack, Lawren, Saldaña, Angela, Salgado-Negret, Beatriz, Salguero-Gomez, Roberto, Santa-Regina, Ignacio, Santacruz-García, Ana Carolina, Santos, Joaquim, Sardans, Jordi, Schamp, Brandon, Scherer-Lorenzen, Michael, Schleuning, Matthias, Schmid, Bernhard, Schmidt, Marco, Schmitt, Sylvain, Schneider, Julio V., Schowanek, Simon D., Schrader, Julian, Schrodt, Franziska, Schuldt, Bernhard, Schurr, Frank, Selaya Garvizu, Galia, Semchenko, Marina, Seymour, Colleen, Sfair, Julia C., Sharpe, Joanne M., Sheppard, Christine S., Sheremetiev, Serge, Shiodera, Satomi, Shipley, Bill, Shovon, Tanvir Ahmed, Siebenkäs, Alrun, Sierra, Carlos, Silva, Vasco, Silva, Mateus, Sitzia, Tommaso, Sjöman, Henrik, Slot, Martijn, Smith, Nicholas G., Sodhi, Darwin, Soltis, Pamela, Soltis, Douglas, Somers, Ben, Sonnier, Grégory, Sørensen, Mia Vedel, Sosinski Jr, Enio Egon, Soudzilovskaia, Nadejda A., Souza, Alexandre F., Spasojevic, Marko, Sperandii, Marta Gaia, Stan, Amanda B., Stegen, James, Steinbauer, Klaus, Stephan, Jörg G., Sterck, Frank, Stojanovic, Dejan B., Strydom, Tanya, Suarez, Maria Laura, Svenning, Jens-Christian, Svitková, Ivana, Svitok, Marek, Svoboda, Miroslav, Swaine, Emily, Swenson, Nathan, Tabarelli, Marcelo, Takagi, Kentaro, Tappeiner, Ulrike, Tarifa, Rubén, Tauugourdeau, Simon, Tavsanoglu, Cagatay, te Beest, Mariska, Tedersoo, Leho, Thiffault, Nelson, Thom, Dominik, Thomas, Evert, Thompson, Ken, Thornton, Peter E., Thuiller, Wilfried, Tichý, Lubomír, Tissue, David, Tjoelker, Mark G., Tng, David Yue Phin, Tobias, Joseph, Török, Péter, Tarin, Tonantzin, Torres-Ruiz, José M., Tóthmérész, Béla, Treurnicht, Martina, Trivellone, Valeria, Trolliet, Franck, Trotsiuk, Volodymyr, Tsakalos, James L., Tsiripidis, Ioannis, Tysklind, Niklas, Umehara, Toru, Usoltsev, Vladimir, Vadeboncoeur, Matthew, Vaezi, Jamil, Valladares, Fernando, Vamosi, Jana, van Bodegom, Peter M., van Breugel, Michiel, Van Cleemput, Elisa, van de Weg, Martine, van der Merwe, Stephni, van der Plas, Fons, van der Sande, Masha T., van Kleunen, Mark, Van Meerbeek, Koenraad, Vanderwel, Mark, Vanselow, Kim André, Vårhammar, Angelica, Varone, Laura, Vasquez Valderrama, Maribel Yesenia, Vassilev, Kiril, Vellend, Mark, Veneklaas, Erik J., Verbeeck, Hans, Verheyen, Kris, Vibrans, Alexander, Vieira, Ima, Villacís, Jaime, Violle, Cyrille, Vivek, Pandi, Wagner, Katrin, Waldram, Matthew, Waldron, Anthony, Walker, Anthony P., Waller, Martyn, Walther, Gabriel, Wang, Han, Wang, Feng, Wang, Weiqi, Watkins, Harry, Watkins, James, Weber, Ulrich, Weedon, James T., Wei, Liping, Weigelt, Patrick, Weiher, Evan, Wells, Aidan W., Wellstein, Camilla, Wenk, Elizabeth, Westoby, Mark, Westwood, Alana, White, Philip John, Whitten, Mark, Williams, Mathew, Winkler, Daniel E., Winter, Klaus, Womack, Chevonne, Wright, Ian J., Wright, S. Joseph, Wright, Justin, Pinho, Bruno X., Ximenes, Fabiano, Yamada, Toshihiro, Yamaji, Keiko, Yanai, Ruth, Yankov, Nikolay, Yguel, Benjamin, Zanini, Kátia Janaina, Zanne, Amy E., Zelený, David, Zhao, Yun-Peng, Zheng, Jingming, Zheng, Ji, Ziemińska, Kasia, Zirbel, Chad R., Zizka, Georg, Zo-Bi, Irié Casimir, Zotz, Gerhard, Wirth, Christian, Kattge, Jens, Bönisch, Gerhard, Díaz, Sandra, Lavorel, Sandra, Prentice, Iain Colin, Leadley, Paul, Tautenhahn, Susanne, Werner, Gijsbert D. A., Aakala, Tuomas, Abedi, Mehdi, Acosta, Alicia T. R., Adamidis, George C., Adamson, Kairi, Aiba, Masahiro, Albert, Cécile H., Alcántara, Julio M., Alcázar C, Carolina, Aleixo, Izabela, Ali, Hamada, Amiaud, Bernard, Ammer, Christian, Amoroso, Mariano M., Anand, Madhur, Anderson, Carolyn, Anten, Niels, Antos, Joseph, Apgaua, Deborah Mattos Guimarães, Ashman, Tia-Lynn, Asmara, Degi Harja, Asner, Gregory P., Aspinwall, Michael, Atkin, Owen, Aubin, Isabelle, Baastrup-Spohr, Lars, Bahalkeh, Khadijeh, Bahn, Michael, Baker, Timothy, Baker, William J., Bakker, Jan P., Baldocchi, Dennis, Baltzer, Jennifer, Banerjee, Arindam, Baranger, Anne, Barlow, Jos, Barneche, Diego R., Baruch, Zdravko, Bastianelli, Denis, Battles, John, Bauerle, William, Bauters, Marijn, Bazzato, Erika, Beckmann, Michael, Beeckman, Hans, Beierkuhnlein, Carl, Bekker, Renee, Belfry, Gavin, Belluau, Michael, Beloiu, Mirela, Benavides, Raquel, Benomar, Lahcen, Berdugo-Lattke, Mary Lee, Berenguer, Erika, Bergamin, Rodrigo, Bergmann, Joana, Bergmann Carlucci, Marcos, Berner, Logan, Bernhardt-Römermann, Markus, Bigler, Christof, Bjorkman, Anne D., Blackman, Chris, Blanco, Carolina, Blonder, Benjamin, Blumenthal, Dana, Bocanegra-González, Kelly T., Boeckx, Pascal, Bohlman, Stephanie, Böhning-Gaese, Katrin, Boisvert-Marsh, Laura, Bond, William, Bond-Lamberty, Ben, Boom, Arnoud, Boonman, Coline C. F., Bordin, Kauane, Boughton, Elizabeth H., Boukili, Vanessa, Bowman, David M. J. S., Bravo, Sandra, Brendel, Marco Richard, Broadley, Martin R., Brown, Kerry A., Bruelheide, Helge, Brumnich, Federico, Bruun, Hans Henrik, Bruy, David, Buchanan, Serra W., Bucher, Solveig Franziska, Buchmann, Nina, Buitenwerf, Robert, Bunker, Daniel E., Bürger, Jana, Burrascano, Sabina, Burslem, David F. R. P., Butterfield, Bradley J., Byun, Chaeho, Marques, Marcia, Scalon, Marina C., Caccianiga, Marco, Cadotte, Marc, Cailleret, Maxime, Camac, James, Camarero, Jesús Julio, Campany, Courtney, Campetella, Giandiego, Campos, Juan Antonio, Cano-Arboleda, Laura, Canullo, Roberto, Carbognani, Michele, Carvalho, Fabio, Casanoves, Fernando, Castagneyrol, Bastien, Catford, Jane A., Cavender-Bares, Jeannine, Cerabolini, Bruno E. L., Cervellini, Marco, Chacón-Madrigal, Eduardo, Chapin, Kenneth, Chapin, F. Stuart, Chelli, Stefano, Chen, Si-Chong, Chen, Anping, Cherubini, Paolo, Chianucci, Francesco, Choat, Brendan, Chung, Kyong-Sook, Chytrý, Milan, Ciccarelli, Daniela, Coll, Lluís, Collins, Courtney G., Conti, Luisa, Coomes, David, Cornelissen, Johannes H. C., Cornwell, William K., Corona, Piermaria, Coyea, Marie, Craine, Joseph, Craven, Dylan, Cromsigt, Joris P. G. M., Csecserits, Anikó, Cufar, Katarina, Cuntz, Matthias, da Silva, Ana Carolina, Dahlin, Kyla M., Dainese, Matteo, Dalke, Igor, Dalle Fratte, Michele, Dang-Le, Anh Tuan, Danihelka, Jirí, Dannoura, Masako, Dawson, Samantha, de Beer, Arend Jacobus, De Frutos, Angel, De Long, Jonathan R., Dechant, Benjamin, Delagrange, Sylvain, Delpierre, Nicolas, Derroire, Géraldine, Dias, Arildo S., Diaz-Toribio, Milton Hugo, Dimitrakopoulos, Panayiotis G., Dobrowolski, Mark, Doktor, Daniel, Dřevojan, Pavel, Dong, Ning, Dransfield, John, Dressler, Stefan, Duarte, Leandro, Ducouret, Emilie, Dullinger, Stefan, Durka, Walter, Duursma, Remko, Dymova, Olga, E-Vojtkó, Anna, Eckstein, Rolf Lutz, Ejtehadi, Hamid, Elser, James, Emilio, Thaise, Engemann, Kristine, Erfanian, Mohammad Bagher, Erfmeier, Alexandra, Esquivel-Muelbert, Adriane, Esser, Gerd, Estiarte, Marc, Domingues, Tomas F., Fagan, William F., Fagúndez, Jaime, Falster, Daniel S., Fang, Jingyun, Farris, Emmanuele, Fazlioglu, Fatih, Feng, Yanhao, Fernandez-Mendez, Fernando, Ferrara, Carlotta, Ferreira, Joice, Fidelis, Alessandra, Finegan, Bryan, Firn, Jennifer, Flowers, Timothy J., Flynn, Dan F. B., Fontana, Veronika, Forey, Estelle, Forgiarini, Cristiane, François, Louis, Frangipani, Marcelo, Frank, Dorothea, Frenette-Dussault, Cedric, Freschet, Grégoire T., Fry, Ellen L., Fyllas, Nikolaos M., Mazzochini, Guilherme G., Gachet, Sophie, Gallagher, Rachael, Ganade, Gislene, Ganga, Francesca, García-Palacios, Pablo, Gargaglione, Verónica, Garnier, Eric, Garrido, Jose Luis, de Gasper, André Luís, Gea-Izquierdo, Guillermo, Gibson, David, Gillison, Andrew N., Giroldo, Aelton, Glasenhardt, Mary-Claire, Gleason, Sean, Gliesch, Mariana, Goldberg, Emma, Göldel, Bastian, Gonzalez-Akre, Erika, Gonzalez-Andujar, Jose L., González-Melo, Andrés, González-Robles, Ana, Graae, Bente Jessen, Granda, Elena, Graves, Sarah, Green, Walton A., Gregor, Thomas, Gross, Nicolas, Guerin, Greg R., Günther, Angela, Gutiérrez, Alvaro G., Haddock, Lillie, Haines, Anna, Hall, Jefferson, Hambuckers, Alain, Han, Wenxuan, Harrison, Sandy P., Hattingh, Wesley, Hawes, Joseph E., He, Tianhua, He, Pengcheng, Heberling, Jacob Mason, Helm, Aveliina, Hempel, Stefan, Hentschel, Jörn, Hérault, Bruno, Hereş, Ana-Maria, Herz, Katharina, Heuertz, Myriam, Hickler, Thomas, Hietz, Peter, Higuchi, Pedro, Hipp, Andrew L., Hirons, Andrew, Hock, Maria, Hogan, James Aaron, Holl, Karen, Honnay, Olivier, Hornstein, Daniel, Hou, Enqing, Hough-Snee, Nate, Hovstad, Knut Anders, Ichie, Tomoaki, Igić, Boris, Illa, Estela, Isaac, Marney, Ishihara, Masae, Ivanov, Leonid, Ivanova, Larissa, Iversen, Colleen M., Izquierdo, Jordi, Jackson, Robert B., Jackson, Benjamin, Jactel, Hervé, Jagodzinski, Andrzej M., Jandt, Ute, Jansen, Steven, Jenkins, Thomas, Jentsch, Anke, Jespersen, Jens Rasmus Plantener, Jiang, Guo-Feng, Johansen, Jesper Liengaard, Johnson, David, Jokela, Eric J., Joly, Carlos Alfredo, Jordan, Gregory J., Joseph, Grant Stuart, Junaedi, Decky, Junker, Robert R., Justes, Eric, Kabzems, Richard, Kane, Jeffrey, Kaplan, Zdenek, Kattenborn, Teja, Kavelenova, Lyudmila, Kearsley, Elizabeth, Kempel, Anne, Kenzo, Tanaka, Kerkhoff, Andrew, Khalil, Mohammed I., Kinlock, Nicole L., Kissling, Wilm Daniel, Kitajima, Kaoru, Kitzberger, Thomas, Kjøller, Rasmus, Klein, Tamir, Kleyer, Michael, Klimešová, Jitka, Klipel, Joice, Kloeppel, Brian, Klotz, Stefan, Knops, Johannes M. H., Kohyama, Takashi, Koike, Fumito, Kollmann, Johannes, Komac, Benjamin, Komatsu, Kimberly, König, Christian, Kraft, Nathan J. B., Kramer, Koen, Kreft, Holger, Kühn, Ingolf, Kumarathunge, Dushan, Kuppler, Jonas, Kurokawa, Hiroko, Kurosawa, Yoko, Kuyah, Shem, Laclau, Jean-Paul, Lafleur, Benoit, Lallai, Erik, Lamb, Eric, Lamprecht, Andrea, Larkin, Daniel J., Laughlin, Daniel, Le Bagousse-Pinguet, Yoann, le Maire, Guerric, le Roux, Peter C., le Roux, Elizabeth, Lee, Tali, Lens, Frederic, Lewis, Simon L., Lhotsky, Barbara, Li, Yuanzhi, Li, Xine, Lichstein, Jeremy W., Liebergesell, Mario, Lim, Jun Ying, Lin, Yan-Shih, Linares, Juan Carlos, Liu, Chunjiang, Liu, Daijun, Liu, Udayangani, Livingstone, Stuart, Llusià, Joan, Lohbeck, Madelon, López-García, Álvaro, Lopez-Gonzalez, Gabriela, Lososová, Zdeňka, Louault, Frédérique, Lukács, Balázs A., Lukeš, Petr, Luo, Yunjian, Lussu, Michele, Ma, Siyan, Maciel Rabelo Pereira, Camilla, Mack, Michelle, Maire, Vincent, Mäkelä, Annikki, Mäkinen, Harri, Malhado, Ana Claudia Mendes, Mallik, Azim, Manning, Peter, Manzoni, Stefano, Marchetti, Zuleica, Marchino, Luca, Marcilio-Silva, Vinicius, Marcon, Eric, Marignani, Michela, Markesteijn, Lars, Martin, Adam, Martínez-Garza, Cristina, Martínez-Vilalta, Jordi, Mašková, Tereza, Mason, Kelly, Mason, Norman, Massad, Tara Joy, Masse, Jacynthe, Mayrose, Itay, McCarthy, James, McCormack, M. Luke, McCulloh, Katherine, McFadden, Ian R., McGill, Brian J., McPartland, Mara Y., Medeiros, Juliana S., Medlyn, Belinda, Meerts, Pierre, Mehrabi, Zia, Meir, Patrick, Melo, Felipe P. L., Mencuccini, Maurizio, Meredieu, Céline, Messier, Julie, Mészáros, Ilona, Metsaranta, Juha, Michaletz, Sean T., Michelaki, Chrysanthi, Migalina, Svetlana, Milla, Ruben, Miller, Jesse E. D., Minden, Vanessa, Ming, Ray, Mokany, Karel, Moles, Angela T., Molnár V, Attila, Molofsky, Jane, Molz, Martin, Montgomery, Rebecca A., Monty, Arnaud, Moravcová, Lenka, Moreno-Martínez, Alvaro, Moretti, Marco, Mori, Akira S., Mori, Shigeta, Morris, Dave, Morrison, Jane, Mucina, Ladislav, Mueller, Sandra, Muir, Christopher D., Müller, Sandra Cristina, Munoz, François, Myers-Smith, Isla H., Myster, Randall W., Nagano, Masahiro, Naidu, Shawna, Narayanan, Ayyappan, Natesan, Balachandran, Negoita, Luka, Nelson, Andrew S., Neuschulz, Eike Lena, Ni, Jian, Niedrist, Georg, Nieto, Jhon, Niinemets, Ülo, Nolan, Rachael, Nottebrock, Henning, Nouvellon, Yann, Novakovskiy, Alexander, Network, The Nutrient, Nystuen, Kristin Odden, O'Grady, Anthony, O'Hara, Kevin, O'Reilly-Nugent, Andrew, Oakley, Simon, Oberhuber, Walter, Ohtsuka, Toshiyuki, Oliveira, Ricardo, Öllerer, Kinga, Olson, Mark E., Onipchenko, Vladimir, Onoda, Yusuke, Onstein, Renske E., Ordonez, Jenny C., Osada, Noriyuki, Ostonen, Ivika, Ottaviani, Gianluigi, Otto, Sarah, Overbeck, Gerhard E., Ozinga, Wim A., Pahl, Anna T., Paine, C. E. Timothy, Pakeman, Robin J., Papageorgiou, Aristotelis C., Parfionova, Evgeniya, Pärtel, Meelis, Patacca, Marco, Paula, Susana, Paule, Juraj, Pauli, Harald, Pausas, Juli G., Peco, Begoña, Penuelas, Josep, Perea, Antonio, Peri, Pablo Luis, Petisco-Souza, Ana Carolina, Petraglia, Alessandro, Petritan, Any Mary, Phillips, Oliver L., Pierce, Simon, Pillar, Valério D., Pisek, Jan, Pomogaybin, Alexandr, Poorter, Hendrik, Portsmuth, Angelika, Poschlod, Peter, Potvin, Catherine, Pounds, Devon, Powell, A. Shafer, Power, Sally A., Prinzing, Andreas, Puglielli, Giacomo, Pyšek, Petr, Raevel, Valerie, Rammig, Anja, Ransijn, Johannes, Ray, Courtenay A., Reich, Peter B., Reichstein, Markus, Reid, Douglas E. B., Réjou-Méchain, Maxime, de Dios, Victor Resco, Ribeiro, Sabina, Richardson, Sarah, Riibak, Kersti, Rillig, Matthias C., Riviera, Fiamma, Robert, Elisabeth M. R., Roberts, Scott, Robroek, Bjorn, Roddy, Adam, Rodrigues, Arthur Vinicius, Rogers, Alistair, Rollinson, Emily, Rolo, Victor, Römermann, Christine, Ronzhina, Dina, Roscher, Christiane, Rosell, Julieta A., Rosenfield, Milena Fermina, Rossi, Christian, Roy, David B., Royer-Tardif, Samuel, Rüger, Nadja, Ruiz-Peinado, Ricardo, Rumpf, Sabine B., Rusch, Graciela M., Ryo, Masahiro, Sack, Lawren, Saldaña, Angela, Salgado-Negret, Beatriz, Salguero-Gomez, Roberto, Santa-Regina, Ignacio, Santacruz-García, Ana Carolina, Santos, Joaquim, Sardans, Jordi, Schamp, Brandon, Scherer-Lorenzen, Michael, Schleuning, Matthias, Schmid, Bernhard, Schmidt, Marco, Schmitt, Sylvain, Schneider, Julio V., Schowanek, Simon D., Schrader, Julian, Schrodt, Franziska, Schuldt, Bernhard, Schurr, Frank, Selaya Garvizu, Galia, Semchenko, Marina, Seymour, Colleen, Sfair, Julia C., Sharpe, Joanne M., Sheppard, Christine S., Sheremetiev, Serge, Shiodera, Satomi, Shipley, Bill, Shovon, Tanvir Ahmed, Siebenkäs, Alrun, Sierra, Carlos, Silva, Vasco, Silva, Mateus, Sitzia, Tommaso, Sjöman, Henrik, Slot, Martijn, Smith, Nicholas G., Sodhi, Darwin, Soltis, Pamela, Soltis, Douglas, Somers, Ben, Sonnier, Grégory, Sørensen, Mia Vedel, Sosinski Jr, Enio Egon, Soudzilovskaia, Nadejda A., Souza, Alexandre F., Spasojevic, Marko, Sperandii, Marta Gaia, Stan, Amanda B., Stegen, James, Steinbauer, Klaus, Stephan, Jörg G., Sterck, Frank, Stojanovic, Dejan B., Strydom, Tanya, Suarez, Maria Laura, Svenning, Jens-Christian, Svitková, Ivana, Svitok, Marek, Svoboda, Miroslav, Swaine, Emily, Swenson, Nathan, Tabarelli, Marcelo, Takagi, Kentaro, Tappeiner, Ulrike, Tarifa, Rubén, Tauugourdeau, Simon, Tavsanoglu, Cagatay, te Beest, Mariska, Tedersoo, Leho, Thiffault, Nelson, Thom, Dominik, Thomas, Evert, Thompson, Ken, Thornton, Peter E., Thuiller, Wilfried, Tichý, Lubomír, Tissue, David, Tjoelker, Mark G., Tng, David Yue Phin, Tobias, Joseph, Török, Péter, Tarin, Tonantzin, Torres-Ruiz, José M., Tóthmérész, Béla, Treurnicht, Martina, Trivellone, Valeria, Trolliet, Franck, Trotsiuk, Volodymyr, Tsakalos, James L., Tsiripidis, Ioannis, Tysklind, Niklas, Umehara, Toru, Usoltsev, Vladimir, Vadeboncoeur, Matthew, Vaezi, Jamil, Valladares, Fernando, Vamosi, Jana, van Bodegom, Peter M., van Breugel, Michiel, Van Cleemput, Elisa, van de Weg, Martine, van der Merwe, Stephni, van der Plas, Fons, van der Sande, Masha T., van Kleunen, Mark, Van Meerbeek, Koenraad, Vanderwel, Mark, Vanselow, Kim André, Vårhammar, Angelica, Varone, Laura, Vasquez Valderrama, Maribel Yesenia, Vassilev, Kiril, Vellend, Mark, Veneklaas, Erik J., Verbeeck, Hans, Verheyen, Kris, Vibrans, Alexander, Vieira, Ima, Villacís, Jaime, Violle, Cyrille, Vivek, Pandi, Wagner, Katrin, Waldram, Matthew, Waldron, Anthony, Walker, Anthony P., Waller, Martyn, Walther, Gabriel, Wang, Han, Wang, Feng, Wang, Weiqi, Watkins, Harry, Watkins, James, Weber, Ulrich, Weedon, James T., Wei, Liping, Weigelt, Patrick, Weiher, Evan, Wells, Aidan W., Wellstein, Camilla, Wenk, Elizabeth, Westoby, Mark, Westwood, Alana, White, Philip John, Whitten, Mark, Williams, Mathew, Winkler, Daniel E., Winter, Klaus, Womack, Chevonne, Wright, Ian J., Wright, S. Joseph, Wright, Justin, Pinho, Bruno X., Ximenes, Fabiano, Yamada, Toshihiro, Yamaji, Keiko, Yanai, Ruth, Yankov, Nikolay, Yguel, Benjamin, Zanini, Kátia Janaina, Zanne, Amy E., Zelený, David, Zhao, Yun-Peng, Zheng, Jingming, Zheng, Ji, Ziemińska, Kasia, Zirbel, Chad R., Zizka, Georg, Zo-Bi, Irié Casimir, Zotz, Gerhard, and Wirth, Christian

Abstract

Plant traits-the morphological, anatomical, physiological, biochemical and phenological characteristics of plants-determine how plants respond to environmental factors, affect other trophic levels, and influence ecosystem properties and their benefits and detriments to people. Plant trait data thus represent the basis for a vast area of research spanning from evolutionary biology, community and functional ecology, to biodiversity conservation, ecosystem and landscape management, restoration, biogeography and earth system modelling. Since its foundation in 2007, the TRY database of plant traits has grown continuously. It now provides unprecedented data coverage under an open access data policy and is the main plant trait database used by the research community worldwide. Increasingly, the TRY database also supports new frontiers of trait-based plant research, including the identification of data gaps and the subsequent mobilization or measurement of new data. To support this development, in this article we evaluate the extent of the trait data compiled in TRY and analyse emerging patterns of data coverage and representativeness. Best species coverage is achieved for categorical traits-almost complete coverage for 'plant growth form'. However, most traits relevant for ecology and vegetation modelling are characterized by continuous intraspecific variation and trait-environmental relationships. These traits have to be measured on individual plants in their respective environment. Despite unprecedented data coverage, we observe a humbling lack of completeness and representativeness of these continuous traits in many aspects. We, therefore, conclude that reducing data gaps and biases in the TRY database remains a key challenge and requires a coordinated approach to data mobilization and trait measurements. This can only be achieved in collaboration with other initiatives.

Published

2020

39. Annotated Draft Genomes of Two Caddisfly Species Plectrocnemia conspersa CURTIS and Hydropsyche tenuis NAVAS (Insecta: Trichoptera)

Author

Heckenhauer, Jacqueline, primary, Frandsen, Paul B, additional, Gupta, Deepak K, additional, Paule, Juraj, additional, Prost, Stefan, additional, Schell, Tilman, additional, Schneider, Julio V, additional, Stewart, Russell J, additional, and Pauls, Steffen U, additional

Published

2019

40. Origin and diversification of Cristaria (Malvaceae) parallel Andean orogeny and onset of hyperaridity in the Atacama Desert

Author

Boehnert, Tim, Luebert, Federico, Ritter, Benedikt, Merklinger, Felix F., Stoll, Alexandra, Schneider, Julio V., Quandt, Dietmar, Weigend, Maximilian, Boehnert, Tim, Luebert, Federico, Ritter, Benedikt, Merklinger, Felix F., Stoll, Alexandra, Schneider, Julio V., Quandt, Dietmar, and Weigend, Maximilian

Abstract

The Atacama Desert in western South America is considered as one of the driest places on earth, but is nevertheless characterized by surprisingly high species richness and levels of endemism. The plant genus Cristaria (Malvaceae), with ca. 21 species, is one of the most diverse genera of the Atacama Desert, while the much less diverse sister genus Lecanophora (7 species) is found east of the Andes. Here, we use DNA sequence data and divergence time estimates in order to investigate the biogeographical history of the Atacama species of Cristaria. We further investigate a possible influence of Andean uplift and the subsequent onset of hyperaridity in the Atacama Desert on diversification times in Cristaria. We sequenced three plastid markers (ndhF, trnK(matK) & rpl16) for 19 species of Cristaria and two species of Lecanophora from the Atacama Desert and Argentina, respectively. Further, we included sequences of the same plastid regions from GenBank in order to get a comprehensive dataset of Malvoideae. Phylogenetic relationships were inferred using maximum likelihood and Bayesian analyses, and divergence times were estimated with BEAST2. Our results place the monophyletic genera Cristaria and Lecanophora as sister groups in a Glade sister to the rest of Malveae. The split between these two lineages (similar to 20 Ma) correlates with Andean uplift during the early Miocene, indicating a vicariant event. During the late Miocene, two Mediterranean members of Cristaria separated from the major Atacama Glade. The subsequent diversification of the latter one correlates with the onset and subsequent temporal expansion of hyperarid conditions in the Atacama Desert since the late Miocene and during the Quaternary climate oscillations.

Published

2019

41. Improved non-destructive 2D and 3D X-ray imaging of leaf venation

Author

Schneider, Julio V., primary, Rabenstein, Renate, additional, Wesenberg, Jens, additional, Wesche, Karsten, additional, Zizka, Georg, additional, and Habersetzer, Jörg, additional

Published

2018

42. Taxonomic diversity masks leaf vein–climate relationships: lessons from herbarium collections across a latitudinal rainfall gradient in West Africa

Author

Schneider, Julio V., primary, Negraschis, Vanessa, additional, Habersetzer, Jörg, additional, Rabenstein, Renate, additional, Wesenberg, Jens, additional, Wesche, Karsten, additional, and Zizka, Georg, additional

Published

2018

43. Water supply and demand remain coordinated during breakdown of the global scaling relationship between leaf size and major vein density

Author

Schneider, Julio V., primary, Habersetzer, Jörg, additional, Rabenstein, Renate, additional, Wesenberg, Jens, additional, Wesche, Karsten, additional, and Zizka, Georg, additional

Published

2016

44. The Peruvian species of Cristaria (Malveae, Malvaceae): taxonomic revision, chromosome counts, and breeding system

Author

Schneider, Julio V.

Subjects

Biodiversity, Taxonomy

Abstract

Schneider, Julio V. (2013): The Peruvian species of Cristaria (Malveae, Malvaceae): taxonomic revision, chromosome counts, and breeding system. Phytotaxa 110 (1): 31-47, DOI: 10.11646/phytotaxa.110.1.3, URL: http://dx.doi.org/10.11646/phytotaxa.110.1.3

Published

2013

45. Quiina zamorensis J. V. Schneid. & Zizka. A. Branchlet 2012, spec. nova

Author

Schneider, Julio V. and Zizka, Georg

Subjects

Tracheophyta, Magnoliopsida, Quiina, Quiina zamorensis, Quiinaceae, Malpighiales, Biodiversity, Plantae, Taxonomy

Abstract

Quiina zamorensis J. V. Schneid. & Zizka, spec. nova (Fig. 2, 3). Typus: ECUADOR. Zamora-Chinchipe: road Loja-Zamora, c. 35 km from Loja, Estaci��n Cient��fica San Francisco, 3��58���S 79��04���W, 1800 m, 16.III.2000, Homeier 333 (holo-: BIEL!; iso-: QCNE, MO, LOJA). Folia rigida. Inflorescentia hermaphrodita solum visa racemiforma, 1-11-flora, rhachidi 0,3-0,7 cm longa. Trees. Terminal internodes terete, longitudinally furrowed, 2-3 mm in diameter, glabrous. Leaves petiolate; stipules caducous, (narrowly) triangular-ovate, 0.3-0.9 �� 0.08-0.15 cm, apex acute, glabrous or adaxially puberulent, the adjacent stipules joint at base or to 0.3 mm distant; petiole canaliculate, 0.3- 0.65 cm long, 1.5-3 mm in diameter; lamina coriaceous, rigid, elliptical, 7-16 �� 3.2-6.9 cm, base shortly attenuate to broadly cuneate, apex shortly (sub-)acuminate, the very apex rounded or obtuse, adaxially glabrous, abaxially sparsely hairy along midvein, the hairs red-brown, 0.3-1.1 mm long; margin not or minutely revolute, entire or very inconspicuously serrulate; secondary veins 8-16 per side, adaxially impressed to prominulous, abaxially prominent, 0.7-1.7 cm distant at middle of lamina, interspersed by 0-1(-4) intersecondary veins. Hermaphroditic inflorescence botryoid, 1-11-flowered, male inflorescence not seen; rachis 1(-3) per axile, subterete to inconspicuously quadrangular, longitudinally furrowed, 0.3-0.7 cm long, c. 1 mm in diameter, �� glabrous or sparsely puberulent with brownish hairs to 0.3 mm long; bracts subopposite, ovate, 0.6-1.3 �� 0.6-1 mm, apex acute, puberulent, bracteoles not seen; pedicel below articulation to 2 mm long, above articulation subterete, apically inconspicuously widened, 5-10 mm long (in male flowers to 12 mm long), 0.7-0.8 mm in diameter, glabrous. Flowers subglobose in bud; sepals 4, coriaceous, elliptical to suborbicular, strongly concave, 2-3 �� 1.3-4 mm, rounded, abaxially glabrous, margin ciliate; petals 5, obovate, reflexed, 4-5 �� 2-4 mm, rounded, margin ciliolate; stamens in hermaphroditic flowers c. 17, in male flowers c. 65 (see remarks), filaments c. 5 mm long, anthers c. 0.4-0.7 �� 0.3-0.6 mm, in male flowers larger; ovary 2-locular, styles 2, 2.5-3 mm long, stigma inconspicuously broadened. Fruit ellipsoid, longitudinally striate, 2-3 �� 1.2- 1.5 cm, apically obtuse to subacute, glabrous; seeds not seen. Distribution. ��� Only known from Ecuador. Occurs in tropical montane rain forest at about 1800 m. Phenology. ��� Flowers in March. Etymology. ��� The species epithet refers to the type locality near Zamora. Additional material examined. ��� ECUADOR. Zamora-Chinchipe: road Loja-Zamora, c. 35 km from Loja, Estaci��n Cient��fica San Francisco, 1830 m, 7 Apr 2004, Homeier 1375 (BIEL, FR). Notes. ��� This species is similar in leaf shape to Q. florida, but contrasts in a rigid-coriaceous leaf texture. The leaf texture is similar to Q. integrifolia Pulle, but this species has longer inflorescences with more flowers. The short inflorescences, in turn, are similar to Q. blackii Pires. However, Q. blackii differs in chartaceous to subcoriaceous leaves and subulate stipules. Male flowers were provided by J. Homeier (no specimen seen)., Published as part of Schneider, Julio V. & Zizka, Georg, 2012, Quiina maracaensis J. V. Schneid. & Zizka and Quiina zamorensis J. V. Schneid. & Zizka (Quiinaceae), two new species of Quiina Aubl. from the Neotropics, pp. 261-267 in Candollea 67 (2) on page 265, DOI: 10.15553/c2012v672a7, http://zenodo.org/record/5773041

Published

2012

46. Quiina maracaensis J. V. Schneid. & Zizka 2012, spec. nova

Author

Schneider, Julio V. and Zizka, Georg

Subjects

Tracheophyta, Magnoliopsida, Quiina, Quiina maracaensis, Quiinaceae, Malpighiales, Biodiversity, Plantae, Taxonomy

Abstract

Quiina maracaensis J. V. Schneid. & Zizka, spec. nova (Fig. 1, 3). Typus: BRAZIL. Roraima: SEMA Ecological Reserve, Ilha de Maracá, riverine vegetation bordering the Igarapé Pedra Sentada, 3°30’N 61°43’W, 30.III.1987, Milliken & Lima 35 (holo-: NY!; iso-: E, K!). Arbor parva, ramulis terminalis puberulentis vel pilosis. Nonnulli pili longior quam 0,8 mm. Lamina subcoriacea, elliptica, rarius ovato-elliptica, (2,8-)4,8-14,1 Χ (1,1-)2,2- 4,6 cm. Inflorescentia masculina 11-32-flora, hermaphrodita 5-11-flora. Fructus 0,6-0,9 Χ 0,55-0,8 cm. Small trees or shrubs to 12 m tall. Terminal internodes laterally compressed or subterete, longitudinally striate, 0.8- 2 mm in diameter, densely puberulent to pilose, with trichomes 0.1-0.4 mm long, erect, 0.2-1.5 mm long (at least some hairs> 0.8 mm long), curved, multicellular. Leaves petiolate; stipules caducous, elliptical, subulate, or narrowly ovate, (0.45-) 0.9-3.2 Χ (0.06-) 0.1-0.6 cm, apex acute, abaxially pilose, the adjacent stipules 0.1-0.4 mm distant at base, scars transversely elliptical to orbicular, 0.3-0.6 Χ 0.4-1 mm; petiole subterete, inconspicuously canaliculate or even, ± equally thickened, 0.1- 0.5 cm long, 0.8-2 mm in diameter; lamina subcoriaceous, elliptical (or ovate-elliptical), (2.8-)4.8-14.1 Χ (1.1-) 2.2- 4.6 cm, base attenuate, cuneate, or acute, apex (sub-)acuminate, adaxially glabrous or pilose at base, abaxially pilose along midvein (or covering the whole surface when juvenile); margin inconspicuously revolute, minutely serrulate or entire; secondary veins 7-14 per side, adaxially slightly impressed or prominulous, abaxially prominulous, 0.25-1.7 cm distant at middle of lamina, interspersed by 0-2(-4) conspicuous intersecondary veins. Male inflorescence thyrsoid, 11-32-flowered, with flowers in fascicles of (1-)3, hermaphroditic inflorescence botryoid, 5-11-flowered, with flowers solitary, not in fascicles; rachis 1 per axile, laterally compressed (or subterete), longitudinally furrowed, inconspicuously thickened in fruit, 0.8- 1.7(-2.7) cm long, 0.5-1 mm in diameter, densely pilose; bracts (sub-)opposite, ovate to elliptical, (0.9-)1.4-2.5 Χ 0.7-1.3 mm, apex acute, glabrous or sparsely hairy; bracteoles subulate to ovate, 0.4-1.3 0.2-0.4 mm, apex acuminate; pedicel below articulation to (0.3-) 0.7-2.4 mm long, above articulation (sub-) terete, (1.5-) 3-5 mm long, 0.3-0.7 mm in diameter, inconspicuously puberulent or glabrous. Flowers 2.5-3 mm in diameter; sepals 4, coriaceous, elliptical to ovate (to suborbicular), 1.4-1.7(-2.3) Χ 1.1-1.6 mm, apex rounded or obtuse; petals 4, yellow, elliptical to obovate, c. 2 Χ 1.6 mm, apex rounded, glabrous, rarely ciliolate; stamens in male flowers 21-26, in hermaphroditic flowers c. 12, filaments to 1.8 mm long, free or in hermaphroditic flowers sometimes adnate to petals; ovary 2-locular, styles 2, 1.8-1.9 mm long. Fruit subglobose, ellipsoid or obovoid, longitudinally striate, 0.6-0.9 Χ 0.55- 0.8 cm, apex rounded, glabrous; seeds 1 per fruit, ellipsoid to subglobose, 0.55 Χ 0.5 cm, densely villous (trichomes 0.3- 0.7 mm long). Distribution. – Known from southern Venezuela and northern Brazil. Occurs in terra firme and riverine forests, in campina or capoeira, on sandy or bauxitic (lateritic) soils; up to 800 m. Phenology. – Flowering in February and August (few data available), fruiting from February to August. Etymology. – The species epithet refers to the type locality, the Ilha de Maracá. Notes. – This species is characterized by the combination of small ellipsoid to subglobose fruits, small ± lanceolate stipules, pedicels with basal articulation, and especially the long multicellular trichomes (at least in some parts> 0.8 mm long) at terminal internodes, leaves and inflorescences. Quiina florida Tul. is similar in leaf shape, but differs in larger fruits and inflorescences, the usually broader stipules, and shorter trichomes. Quiina wurdackii Pires differs in shorter inflorescences and few, rather obscure secondary veins, while Q. parvifolia Lanj. & Heerdt is distinguished by broader stipules, broader leaf blades, and longer pedicels. Additional material examined. – VENEZUELA. Bolívar: Municipio Cedeño, Cabeceras del río Túriba y Caño La Miel, 45 km E de Los Pijiguaos, VIII.1989, Sanoja & Fernández 2904 (MO); Municipio Cedeño, headwaters of río Túriba and Caño La Miel, 45 km E of Pijiguaos, 6°34’N 66°23’W, VIII.1989, Fernández & Sanoja 5892 (MO, NY, PORT); Municipio Raúl Leoni, headwaters of río Túriba and Caño La Miel, 45 km E of Pijiguaos, 6°34’N 66°23’W, VI.1989, Fernández & Delgado 5813 (MO, NY, PORT). Amazonas: Alto Orinoco, Salto Salas, 18.VIII.1951, Croizat 536 (NY); Dept. Atabapo, Caño Jayuwapuey, tributary of the Ocamo River, 3°4’N 64°40’W, I.1990, Fernández 6789 (PORT). BRAZIL. Amazonas: Vicinity of Pico Rondon, Perimetral Norte, Highway Km 211, 3 km from Km 211, lower slopes of Pico Rondon, 1°32’N 62°48’W, 2.II.1984, Prance & al. 28761 (F, GH, K, NY, UB). Pará: Sete Varas airstrip on Rio Curua, 0°95’S 54°92’W, 4.VIII.1981, Strudwick & al. 4083 (F, K, NY, UEC). Roraima: Município Alto Alegre, Ilha de Maracá, SEMA Estação, forest trails close to Estação, 3°22’N 61°20’W, 6.VI.1986, Hopkins & al.515 (FR, NY); Município Alto Alegre, Ilha de Maracá, SEMA Estação, Furo Pananá de Firmino of Rio Uraricuera on S side of island, forest near Casa Maracá, 3°24’N 61°26’W, 10.VI.1986, Hopkins & al. 634 (FR, NY); Município de Boa Vista, Estação Ecológica de Maracá, 21.V.1987, Lima 804 (K); SEMA Ecological Reserve, Ilha de Maracá, 3°22’N 61°26’W, 21.IV.1987, Milliken 77 (E, K, NY); Serrinha, Rio Mucajaí, 31.I.1967, Prance & al. 4198 (COL, F, GH, IAN, K, NY, R, S, U); Posto Mucajaí, Rio Mucajaí, Vicinity of Mucajaí airstrip, 13.III.1971, Prance & al. 10928 (F, IAN, K, M, NY, P, R, S, U); SEMA Ecological Station, Ilha de Maracá, in forest at Santa Rosa, 3°22’N 61°25’W, 7.III.1987, Ratter & al.5587 (E, K); SEMA Ecological Station, Ilha de Maracá, 3°22’N 61°25’W, 11.III.1987 (st), Ratter & al. 5679 (K); SEMA Ecological Sation, Ilha de Maracá, 3°22’N 61°25’W, 18.III.1987, Ratter & al. 5748 (E, K); Surroundings of Ecological Station of Maracá, 3°22’N 61°25’W, 9.II.1979, Rosa 3121 (F, NY).

Published

2012

47. Quiina maracaensis J. V. Schneid. & Zizka and Quiina zamorensis J. V. Schneid. & Zizka (Quiinaceae), two new species of Quiina Aubl. from the Neotropics

Author

Schneider, Julio V. and Zizka, Georg

Subjects

Tracheophyta, Magnoliopsida, Quiinaceae, Malpighiales, Biodiversity, Plantae, Taxonomy

Abstract

Schneider, Julio V., Zizka, Georg (2012): Quiina maracaensis J. V. Schneid. & Zizka and Quiina zamorensis J. V. Schneid. & Zizka (Quiinaceae), two new species of Quiina Aubl. from the Neotropics. Candollea 67 (2): 261-267, DOI: 10.15553/c2012v672a7

Published

2012

48. Notes on the typification of Ochagavia litoralis (Bromelioideae, Bromeliaceae)

Author

Schneider, Julio V., Zizka, Georg, and Muñoz-Schick, Melica

Subjects

Biodiversity, Taxonomy

Abstract

Schneider, Julio V., Zizka, Georg, Muñoz-Schick, Melica (2012): Notes on the typification of Ochagavia litoralis (Bromelioideae, Bromeliaceae). Phytotaxa 56 (1): 21-22, DOI: 10.11646/phytotaxa.56.1.5, URL: http://biotaxa.org/Phytotaxa/article/view/phytotaxa.56.1.5

Published

2012

49. Water supply and demand remain coordinated during breakdown of the global scaling relationship between leaf size and major vein density.

Author

Schneider, Julio V., Habersetzer, Jörg, Rabenstein, Renate, Wesenberg, Jens, Wesche, Karsten, and Zizka, Georg

Subjects

*LEAF anatomy, *LEAF physiology, *VEINS (Botany), *VASCULAR system of plants, *DICOTYLEDONS

Abstract

Vein networks that disobey the global scaling of major vein density with leaf size shed light on functional constraints of vein network formation in dicotyledons. Understanding their evolution, distribution and impact on vein-stomata-climate associations is an important contribution to our global view of vein network organization., Based on vein traits of 55 species of pantropical Ochnaceae, stomata and climatic niche data, and a dated molecular phylogeny, we unveil major structural shifts in vein networks through deep time, relationships between leaf size, vein and stomata traits, and their interplay with climate., Dense 2° veins, reduction of minor veins and the associated breakdown of vein-leaf size scaling evolved multiple times independently in Ochnaceae. In spite of the drastic changes in vein architecture in this venation type, vein and stomatal densities remain correlated., Our study demonstrates that shortening the major vein-stomata distance is economically not less advantageous than by increasing minor vein density, as illustrated by the same degree of coordination between vein and stomatal densities and the similar construction costs across networks with dense 2° veins and those with 'normally' spaced 2° veins. [ABSTRACT FROM AUTHOR]

Published

2017

50. Divergent genome sizes reflect the infrafamilial subdivision of the neotropical woody Marcgraviaceae

Author

Schneider, Julio V., primary, Paule, Juraj, additional, Gitaí, Jailson, additional, Dressler, Stefan, additional, Gusmão, Cássia Lima Silva, additional, and Benko-Iseppon, Ana Maria, additional

Published

2014