<p>Duckweeds (Lemnaceae Martinov) are aquatic monocotyledonous plants known to be the smallest and fastest-growing flowering plants on Earth. Many species are morphologically indistinguishable due to their reduced structures, yet molecular evidence suggests that visually similar clones could be distinct species or hybrids. Using a comprehensive suite of genomic, molecular and cytogenetic methods, we analyzed 58 presumed <i>Lemna minor</i> clones to resolve their relationships. Our study revealed extensive genome plasticity within the “<i>Lemna minor</i> complex,” identifying diploid and triploid <i>L. minor</i> clones, as well as allodiploid and allotriploid interspecific hybrids, in addition to a novel African-clade <i>L. minor</i> lineage. Triploidy in the <i>L. minor</i> complex is prevalent in nature, occurring in 33% of the clones previously identified as <i>L. minor</i> in our collection, and is associated with enhanced growth metrics under optimal conditions. For asexually propagative species such as duckweeds, where the triploid block is not a deterrent, triploid progenies may become the majority as has been observed in numerous wild <i>Lemna</i> populations. Our study shows that polyploidy and hybridization in these primarily asexually propagating plants could play important roles in their population dynamics and evolution under changing environments.</p>

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Triploidy is prominent in the duckweed Lemna minor complex

  • Todd P. Michael,
  • Phuong T. N. Hoang,
  • Bradley W. Abramson,
  • Allen Mamerto,
  • Buntora Pasaribu,
  • Jörg Fuchs,
  • Evan Ernst,
  • Nicholas Allsing,
  • Luca Braglia,
  • Semar Petrus,
  • Veit Schubert,
  • Nolan Hartwick,
  • Megan Wang,
  • Yi-Feng Chen,
  • Mariele Lensink,
  • Tiffany Duong,
  • Kelly Colt,
  • Manuela Bog,
  • K. Sowjanya Sree,
  • Laura Morello,
  • Klaus-J. Appenroth,
  • Ingo Schubert,
  • Robert A. Martienssen,
  • Eric Lam

摘要

Duckweeds (Lemnaceae Martinov) are aquatic monocotyledonous plants known to be the smallest and fastest-growing flowering plants on Earth. Many species are morphologically indistinguishable due to their reduced structures, yet molecular evidence suggests that visually similar clones could be distinct species or hybrids. Using a comprehensive suite of genomic, molecular and cytogenetic methods, we analyzed 58 presumed Lemna minor clones to resolve their relationships. Our study revealed extensive genome plasticity within the “Lemna minor complex,” identifying diploid and triploid L. minor clones, as well as allodiploid and allotriploid interspecific hybrids, in addition to a novel African-clade L. minor lineage. Triploidy in the L. minor complex is prevalent in nature, occurring in 33% of the clones previously identified as L. minor in our collection, and is associated with enhanced growth metrics under optimal conditions. For asexually propagative species such as duckweeds, where the triploid block is not a deterrent, triploid progenies may become the majority as has been observed in numerous wild Lemna populations. Our study shows that polyploidy and hybridization in these primarily asexually propagating plants could play important roles in their population dynamics and evolution under changing environments.