Biodiversity Literature Repository
Published July 28, 2023 | Version v1
Taxonomic treatment Open

Jania rosea Decaisne

Creators

  • 1. Universidade Federal de Santa Catarina, Centro de Cie ̂ ncias Biolo ́ gicas, Departamento de Bota ̂ nica, Floriano ́ polis, SC 88040 - 900, Brazil
  • 2. La Trobe University, Department of Environment and Genetics, Plenty Road, Bundoora, Vic. 3083, Australia
  • 3. Universidade Federal do Rio de Janeiro, Instituto de Biodiversidade e Sustentabilidade - NUPEM, Macaé, RJ 27965 - 045, Brazil & Former address: The University of Adelaide, School of Biological Sciences, Adelaide SA 5000, Australia; State Herbarium of South Australia, Department for Environment and Water, SA Government, PO Box 2732, Kent Town, SA 5071, Australia; & SARDI Aquatic Sciences, Department of Primary Industries & Regions, SA Government, PO Box 120, Henley Beach SA 5022, Australia. Corresponding author: fredgurgel @ nupem. ufrj. br

Description

Jania rosea (Lamarck) Decaisne

Jania rosea is extensively recorded across temperate Australia (Australian Virtual Herbarium 2022) and other parts of the world (see AlgaeBase; Guiry and Guiry 2022) such as California (Miller 2012), Brazil (Buys and Gurgel 1998), Indonesia (Atmadja and Prud’homme van Reine 2010), and Sub-Antarctic Islands (Papenfuss 1964). Johansen and Womersley (1986) reported a wide range of variation in thallus morphology in J. rosea. Specimens can grow as purely dichotomously divided thalli, resembling several other Jania species and varieties such as J. pedunculata var. pedunculata (Harvey et al. 2020, fig. 8), J. pedunculata var. adhaerens (Harvey et al. 2020, fig. 17), J. micrarthrodia (Harvey et al. 2020, fig. 6), and J. capillacea Harvey (Mendoza-González et al. 2014, figs. 30-32). Jania rosea can also display a defined slightly compressed main axis and pinnate branches, usually when growing attached to rocks in more exposed sites (Farr et al. 2009, Harvey et al. 2020), or forming well-defined main axis with opposite (or even radially and whorled) branching, resembling some delicate Corallina species (e.g., Calderon et al. 2021).

Australian J. rosea morphotypes have not been recognized as distinct species due to excessive phenotypic plasticity and the high level of observed overlap between morphotypes (Johansen and Womersley 1986, Harvey et al. 2020). Farr et al. (2009) working with New Zealand specimens, found evidence to differentiate two closely related J. rosea clades also on the basis of morphological evidence (i.e., feather versus bottlebrush morphotypes). However, Farr et al. (2009) treated these two distinct genetic entities as a single species, and emphasized ‘that further work is required, and additional species are likely to be recognized in the future’.

Cox 1 phylogenies and SDM results recognized that J.rosea from Australia is a different species and phylogenetically distantly related to the two species passing under the name J. rosea in South Africa (Kogame et al. 2017). Cox 1 molecular data showed that the lineage named J. rosea from South Africa was resolved as a paraphyletic group closely related to J. subulata (Ellis and Solander) Sonder from Hawaii (Fig. 3). In this study the psb A phylogenetic results showed that one J. rosea specimen (LTB18113) formed a clade with C. caespitosa from New Zealand and another five specimens formed a distinct clade with C. berteroi from Australia (LTB18115, LTB18117, LTB18118, LTB18182, and LTB18193), Chile (MZ262616, MZ262579) and California, USA (MZ262623). These data evidence how challenging the morphology-based taxonomy can be and that some Corallina and Jania morpho-anatomical characters overlap.

Notes

Published as part of Macagnan, Leonardo B., Venturin, Claudia S., Azevedo, Marina L., Harvey, Adela & Gurgel, C. Frederico D., 2023, Molecular systematics of Jania species (Corallinales, Rhodophyta) from south-eastern Australia based on cox 1 and psbA DNA sequence analyses, pp. 87-103 in Phytotaxa 606 (2) on pages 98-99, DOI: 10.11646/phytotaxa.606.2.1, http://zenodo.org/record/8202610

Files

Files (3.4 kB)

Name Size Download all
md5:aab2abcccb3bdaa7c67655b544ed926a
3.4 kB Download

System files (23.0 kB)

Name Size Download all
md5:0463b738165b3847d7ae7c6904055f67
23.0 kB Download

Linked records

Additional details

Identifiers

URL
http://treatment.plazi.org/id/03F187C8FF9DFFD5FF4CFA388B90FE15

Cites
Figure: 10.5281/zenodo.8202616 (DOI)
Is part of
Journal article: 10.11646/phytotaxa.606.2.1 (DOI)
Journal article: http://zenodo.org/record/8202610 (URL)
Journal article: http://publication.plazi.org/id/FFC8FFB0FF96FFD9FFF1FFEA8E02FFA1 (URL)
Is source of
https://sibils.text-analytics.ch/search/collections/plazi/03F187C8FF9DFFD5FF4CFA388B90FE15 (URL)
https://www.gbif.org/species/212426674 (URL)
https://www.checklistbank.org/dataset/263452/taxon/03F187C8FF9DFFD5FF4CFA388B90FE15.taxon (URL)

Biodiversity

Family
Corallinaceae
Genus
Jania
Kingdom
Plantae
Order
Cryptonemiales
Phylum
Rhodophyta
Scientific name authorship
Decaisne
Species
rosea
Taxon rank
species

References

  • Guiry, M. D. & Guiry, G. M. (2022) [continuously updated] AlgaeBase. World-wide electronic publication, National University of Ireland, Galway. Available from: https: // www. algaebase. org (accessed 27 July 2023)
  • Miller, K. A. (2012) Seaweeds of California. Updates of California Seaweed Species List. Berkeley: University of California Jepson Herbarium. pp. 1 - 59.
  • Buys, S. S. & Gurgel, C. F. D. (1998) Ocorrencia de Haliptilon roseum (Rhodophyta, Corallinales) no litoral brasileiro. Journal of the Department of Botany of the Federal University of Rio de Janeiro, Leandra 13: 1 - 6.
  • Atmadja, W. S. & Prud'homme van Reine, W. F. (2010) Checklist of the seaweed species biodiversity of Indonesia with their distribution and classification: Rhodophyceae. Ceklis keanekaragaman jenis rumput laut di Indonesia dengan sebaran dan klasifikasinya merah (Rhodophyceae). Jakarta: Coral Reef Information and Training Centre. Coral Reef Rehabilitation and Management Programme. Indonesian Institute of Sciences (LIPI). Jakarta, Indonesia. pp. 72.
  • Papenfuss, G. F. (1964) Catalogue and bibliography of Antarctic and Sub-Antarctic benthic marine algae. In: Antarctic Research Series. Volume 1. Bibliography of the Antarctic Seas. (Lee, M. O. Eds). Washington D. C.: American Geophysical Union. pp. 1 - 76.
  • Johansen, H. W. & Womersley, H. B. S. (1986) Haliptilon roseum (Corallinaceae, Rhodophyta) in southern Australia. Australian Journal of Botany 34 (5): 551 - 567. https: // doi. org / 10.1071 / BT 9860551
  • Harvey, A. S., Woelkerling, W. J. & De Reviers, B. (2020) A taxonomic analysis of Jania (Corallinaceae, Rhodophyta) in south-eastern Australia. Australian Systematic Botany 33 (3): 221 - 277. https: // doi. org / 10.1071 / SB 18064
  • Mendoza-Gonzalez, A. C., Mateo-Cid, L. E., Garcia-Lopez, D. Y. & Acosta-Calderon, J. A. (2014) Diversity and Distribution of articulated Coralline algae (Rhodophyta, Corallinales) of the Atlantic coast of Mexico. Phytotaxa 190 (1): 45 - 63. http: // dx. doi. org / 10.11646 / phytotaxa. 190.1.6
  • Farr, T., Broom, J., Hart, D., Neill, K. & Nelson, W. (2009) Common coralline algae of northern New Zealand: An identification guide. NIWA Information Series 125.
  • Calderon, M. S., Bustamante, D. E., Gabrielson, P. W., Martone, P. T., Hind, K. R., Schipper, S. R. & Mansilla, A. (2021) Type specimen sequencing, multilocus analyses, and species delimitation methods recognize the cosmopolitan Corallina berteroi and establish the northern Japanese C. yendoi sp. nov. (Corallinaceae, Rhodophyta). Journal of Phycology 57 (5): 1659 - 1672. https: // doi. org / 10.1111 / jpy. 13202
  • Kogame, K., Uwai, S., Anderson, R. J., Choi, H. G. & Bolton, J. J. (2017) DNA barcoding of South African geniculate coralline red algae (Corallinales, Rhodophyta). South African Journal of Botany 108: 337 - 341. https: // doi. org / 10.1016 / j. sajb. 2016.08.013