Morphological Diversity between Culture Strains of a Chlorarachniophyte, Lotharella globosa

Yoshihisa Hirakawa,Erick R James,Alexis Howe,Patrick J Keeling,Rosemary J Redfield

doi:10.1371/journal.pone.0023193

Yoshihisa Hirakawa, Erick R James + Show 3 more

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https://doi.org/10.1371/journal.pone.0023193

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Abstract

Chlorarachniophytes are marine unicellular algae that possess secondary plastids of green algal origin. Although chlorarachniophytes are a small group (the phylum of Chlorarachniophyta contains 14 species in 8 genera), they have variable and complex life cycles that include amoeboid, coccoid, and/or flagellate cells. The majority of chlorarachniophytes possess two or more cell types in their life cycles, and which cell types are found is one of the principle morphological criteria used for species descriptions. Here we describe an unidentified chlorarachniophyte that was isolated from an artificial coral reef that calls this criterion into question. The life cycle of the new strain includes all three major cell types, but DNA barcoding based on the established nucleomorph ITS sequences showed it to share 100% sequence identity with Lotharella globosa. The type strain of L. globosa was also isolated from a coral reef, but is defined as completely lacking an amoeboid stage throughout its life cycle. We conclude that L. globosa possesses morphological diversity between culture strains, and that the new strain is a variety of L. globosa, which we describe as Lotharella globosa var. fortis var. nov. to include the amoeboid stage in the formal description of L. globosa. This intraspecies variation suggest that gross morphological stages maybe lost rather rapidly, and specifically that the type strain of L. globosa has lost the ability to form the amoeboid stage, perhaps recently. This in turn suggests that even major morphological characters used for taxonomy of this group may be variable in natural populations, and therefore misleading.

Highlights

Chlorarachniophytes are marine unicellular photosynthetic organisms that have acquired their plastid via a secondary endosymbiosis between a green alga and a cercozoan protist [1,2]
DNA was extracted from LEX01, and the small subunit (SSU) rRNA and internal transcribed spacer (ITS) sequences (JF806440 to JF806448) from both the nuclear and nucleomorph genome were amplified by PCR using specific primer sets
DNA barcoding indicated that LEX01 is a strain of Lotharella globosa, closely related to the type strain: the conservation of nucleomorph ITS sequences is only 75.2 to 83.4% between Lotharella species, the nucleomorph ITS sequence of the LEX01 was found to be 100% identical to that of all three sampled strains of L. globosa

Summary

Introduction

Chlorarachniophytes are marine unicellular photosynthetic organisms that have acquired their plastid via a secondary endosymbiosis between a green alga and a cercozoan protist [1,2]. Chlorarachniophytes are widely distributed in marine environments from tropical coast to open ocean, and they possess various cell types such as amoeboid, coccoid, and flagellate cells. Lotharella vacuolata and Chlorarachnion reptans possess all three cell types [5,6], whereas Bigelowiella natans is only found in the flagellate form [7]. This variation is one of the cornerstones of chlorarachniophyte classification, the others being plastid ultrastructure (pyrenoid structure and the position of the nucleomorph in the periplastidal compartment) and morphological characters of the main vegetative cells [1]. A DNA barcoding system has been developed for rapid and accurate identification of chlorarachniophyte species based on the internal transcribed spacer (ITS) sequences of nuclear and nucleomorph rRNA cistrons [8]

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