Journal of Applied Phycology

, Volume 31, Issue 2, pp 1475–1481 | Cite as

Reproductive strategies of Lessonia berteroana (Laminariales, Phaeophyceae) gametophytes from Chile: Apogamy, parthenogenesis and cross-fertility with L. spicata

  • Dieter G. Müller
  • Pedro Murúa
  • Renato WestermeierEmail author


Lessonia berteroana is one of the most exploited seaweeds in the Southeastern Pacific and its populations are recurrently facing overexploitation in northern Chile. Since germplasms are not available, we decided to start gametophyte biobanking to support conservation measures for this important resource in the future. Spores of L. berteroana from nine localities at the Atacama coast were used to establish clonal male and female gametophyte cultures. Unexpectedly, after isolation and under low light conditions, juvenile sporophytes originated from somatic cells via apogamy in most female gametophyte strains. In addition, eggs from solitary female gametophytes from Caleta Cisnes and Torres del Inca had a strong tendency to generate sporophytes by parthenogenesis, some of them even under low light regimes. Contrarily, female gametophytes of the sister species Lessonia spicata from southern Chile showed no evidence for apomixis. When one of these L. berteroana strains is cross-fertilized with L. spicata, true hybrids emerged based on the presence of eggs and subsequent sperm attraction. These observations contrast with (i) kelp recruitment assumed to be majorly by sexual reproduction and (ii) the strict reproductive separation of the two taxa reported for natural populations within their contact zone at 30°S and highlight their consideration for future repopulation and breeding programs of Lessonia.


Phaeophyta Lessonia berteroana L. spicata Apogamy Apomixis Interspecific hybridization Kelp Life history Parthenogenesis 



Sincere thanks are due to C. Atero for collection of field samples, U. Hueppeler and I. Maier for support with art-work and to the three anonymous reviewers for their contributions that helped to improve the earlier version of this MS. This work was done in the framework of the projects FIC 2013 33-91-243, FIC 2015 33-01-244 and FIC 2016 40486116 (GORE Atacama), FONDEF D04I1288 and VW Foundation, granted to the Universidad Austral de Chile (RW).

Supplementary material

10811_2018_1625_MOESM1_ESM.docx (20 kb)
Table S1 (DOCX 19 kb)


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Copyright information

© Springer Nature B.V. 2018

Authors and Affiliations

  1. 1.Fachbereich Biologie der Universität KonstanzKonstanzGermany
  2. 2.The Scottish Association for Marine Science, Scottish Marine Institute, Culture Collection for Algae and ProtozoaObanUnited Kingdom
  3. 3.Instituto de AcuiculturaUniversidad Austral de ChilePuerto MonttChile

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