Abstract
Rhizomorphic lycopsids are the land plant group that includes the first giant trees to grow on Earth and extant species in the genus Isoetes. Two mutually exclusive hypotheses account for the evolution of terminal rooting axes called rootlets among the rhizomorphic lycopsids. One hypothesis states that rootlets are true roots, like roots in other lycopsids. The other states that rootlets are modified leaves. Here we test predictions of each hypothesis by investigating gene expression in the leaves and rootlets of Isoetes echinospora. We assembled the de novo transcriptome of axenically cultured I. echinospora. Gene expression signatures of I. echinospora rootlets and leaves were different. Furthermore, gene expression signatures of I. echinospora rootlets were similar to gene expression signatures of true roots of Selaginella moellendorffii and Arabidopsis thaliana. RSL genes which positively regulate cell differentiation in roots were either exclusively or preferentially expressed in the I. echinospora rootlets, S. moellendorffii roots and A. thaliana roots compared to the leaves of each respective species. Taken together, gene expression data from the de-novo transcriptome of I. echinospora are consistent with the hypothesis that Isoetes rootlets are true roots and not modified leaves.
Highlights
IntroductionGene expression data from the de-novo transcriptome of I. echinospora are consistent with the hypothesis that Isoetes rootlets are true roots and not modified leaves
Rhizomorphic lycopsids are the land plant group that includes the first giant trees to grow on Earth and extant species in the genus Isoetes
To define gene expression signatures in the organs of I. echinospora, a population of plants was collected from the wild (Fig. 1a) and protocols to grow the plants in axenic culture were developed (Fig. 1b,c)
Summary
Gene expression data from the de-novo transcriptome of I. echinospora are consistent with the hypothesis that Isoetes rootlets are true roots and not modified leaves. The modified shoot hypothesis posits that the ancestral embryo condition in the rhizomorphic lycopsids lacked an embryonic root, but instead developed a single shoot axis that divided to give a typical shoot and modified rooting shoot axis that developed modified leaves (rootlets). The embryo of Oxroadia does not support the hypothesis that a branching event in the embryo produced a rooting shoot axis (rhizomorph) that developed root-like leaves (rootlets). The discovery of the development of root hairs on rootlets of extinct rhizomorphic lycopsids that are identical to the root hairs that develop on extant lycopsids suggest that rootlets are root-like[2] Together these three studies present an emerging body of evidence that is incompatible with the modified shoot hypothesis
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