Anastasiia I. Evkaikina scite author profile

Anastasiia I. Evkaikina

4Publications

70Citation Statements Received

265Citation Statements Given

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Affiliations

Russian Academy of Sciences, Botanical Institute VL Komarova

Publications

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The Huperzia selago Shoot Tip Transcriptome Sheds New Light on the Evolution of Leaves

Evkaikina

Berke

Romanova

et al. 2017

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Lycopodiophyta—consisting of three orders, Lycopodiales, Isoetales and Selaginellales, with different types of shoot apical meristems (SAMs)—form the earliest branch among the extant vascular plants. They represent a sister group to all other vascular plants, from which they differ in that their leaves are microphylls—that is, leaves with a single, unbranched vein, emerging from the protostele without a leaf gap—not megaphylls. All leaves represent determinate organs originating on the flanks of indeterminate SAMs. Thus, leaf formation requires the suppression of indeterminacy, that is, of KNOX transcription factors. In seed plants, this is mediated by different groups of transcription factors including ARP and YABBY.We generated a shoot tip transcriptome of Huperzia selago (Lycopodiales) to examine the genes involved in leaf formation. Our H. selago transcriptome does not contain any ARP homolog, although transcriptomes of Selaginella spp. do. Surprisingly, we discovered a YABBY homolog, although these transcription factors were assumed to have evolved only in seed plants.The existence of a YABBY homolog in H. selago suggests that YABBY evolved already in the common ancestor of the vascular plants, and subsequently was lost in some lineages like Selaginellales, whereas ARP may have been lost in Lycopodiales. The presence of YABBY in the common ancestor of vascular plants would also support the hypothesis that this common ancestor had a simplex SAM. Furthermore, a comparison of the expression patterns of ARP in shoot tips of Selaginella kraussiana (Harrison CJ, etal. 2005. Independent recruitment of a conserved developmental mechanism during leaf evolution. Nature 434(7032):509–514.) and YABBY in shoot tips of H. selago implies that the development of microphylls, unlike megaphylls, does not seem to depend on the combined activities of ARP and YABBY. Altogether, our data show that Lycopodiophyta are a diverse group; so, in order to understand the role of Lycopodiophyta in evolution, representatives of Lycopodiales, Selaginellales, as well as of Isoetales, have to be examined.

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Evolutionary aspects of non-cell-autonomous regulation in vascular plants: structural background and models to study

Evkaikina¹,

Romanova²,

Voitsekhovskaja³

2014

Front. Plant Sci.

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Plasmodesmata (PD) serve for the exchange of information in form of miRNA, proteins, and mRNA between adjacent cells in the course of plant development. This fundamental role of PD is well established in angiosperms but has not yet been traced back to the evolutionary ancient plant taxa where functional studies lag behind studies of PD structure and ontogenetic origin. There is convincing evidence that the ability to form secondary (post-cytokinesis) PD, which can connect any adjacent cells, contrary to primary PD which form during cytokinesis and link only cells of the same lineage, appeared in the evolution of higher plants at least twice: in seed plants and in some representatives of the Lycopodiophyta. The (in)ability to form secondary PD is manifested in the symplasmic organization of the shoot apical meristem (SAM) which in most taxa of seedless vascular plants differs dramatically from that in seed plants. Lycopodiophyta appear to be suitable models to analyze the transport of developmental regulators via PD in SAMs with symplasmic organization both different from, as well as analogous to, that in angiosperms, and to understand the evolutionary aspects of the role of this transport in the morphogenesis of vascular plant taxa.

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The absence of chlorophyll b affects lateral mobility of photosynthetic complexes and lipids in grana membranes of Arabidopsis and barley chlorina mutants

et al. 2017

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The lateral mobility of integral components of thylakoid membranes, such as plastoquinone, xanthophylls, and pigment-protein complexes, is critical for the maintenance of efficient light harvesting, high rates of linear electron transport, and successful repair of damaged photosystem II (PSII). The packaging of the photosynthetic pigment-protein complexes in the membrane depends on their size and stereometric parameters which in turn depend on the composition of the complexes. Chlorophyll b (Chlb) is an important regulator of antenna size and composition. In this study, the lateral mobility (the mobile fraction size) of pigment-protein complexes and lipids in grana membranes was analyzed in chlorina mutants of Arabidopsis and barley lacking Chlb. In the Arabidopsis ch1-3 mutant, diffusion of membrane lipids decreased as compared to wild-type plants, but the diffusion of photosynthetic complexes was not affected. In the barley chlorina f2 3613 mutant, the diffusion of pigment-protein complexes significantly decreased, while the diffusion of lipids increased, as compared to wild-type plants. We propose that the size of the mobile fractions of pigment-protein complexes in grana membranes in vivo is higher than reported previously. The data are discussed in the context of the protein composition of antennae, characteristics of the plastoquinone pool, and production of reactive oxygen species in leaves of chlorina mutants.

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Chlorophyllide-a-Oxygenase (CAO) deficiency affects the levels of singlet oxygen and formation of plasmodesmata in leaves and shoot apical meristems of barley

Dmitrieva

Ivanova

Tyutereva

et al. 2017

Plant Signaling & Behavior

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In plants, organogenesis and specification of cell layers and tissues rely on precise symplastic delivery of regulatory molecules via plasmodesmata. Accordingly, abundance and aperture of plasmodesmata at individual cell boundaries should be controlled by the plant. Recently, studies in Arabidopsis established reactive oxygen species as major regulators of plasmodesmata formation and gating. We show that in a barley mutant deficient in the synthesis of chlorophyll b, the numbers of plasmodesmata in leaves and in the shoot apical meristem are significantly higher than in the corresponding wild type, probably due to redox imbalance in the mutant. The resulting disturbance of symplasmic transport is likely to be the reason for the observed delayed floral transition in these mutants. In plants, plasmodesmata (PD) are indispensable regulators of cell-to-cell communications. 1 The function of meristems as well as the specification of cell layers and tissues during organogenesis rely on the symplasmic transport of regulatory molecules such as miRNAs, transcription factors or their transcripts.2 For instance, PD serve for cell-to-cell transport of the homeodomain-containing meristem regulators WUS and KNOX in shoot apical meristems (SAMs), and of floral homeotic MADS-box proteins in inflorescence meristems.3 Leaves are determinate organs the main function of which lies in the production and release of photosynthates to other plant organs. However, leaves are also the source of many signals which spread over the symplasmic route. For instance, Flowering locus T (FT) is synthesized in phloem companion cells in leaves and moves systemically to SAMs where it initiates floral transition upon unloading via PD. 4 Most likely, movement and activity of non-cell-autonomous transcription factors are controlled by developmental changes of the numbers and functional state of PD. 5,3 At the same time, we know relatively little not only about the fine structure of PD and mechanisms of protein translocation via PD, 6,7 but also about how plants control numbers and states of PD at individual cell boundaries. One of the factors involved in these processes could be the plant hormone cytokinine.8 Recent studies provided a major breakthrough in the elucidation of mechanisms regulating PD formation in plant cells. They revealed that the production of reactive oxygen species (ROS) by cellular organelles can differentially influence the formation of PD as well as their aperture. 9,10,11,12 Mutations in a gene encoding the plastid-localized thioredoxin m led to an increase in ROS and a decrease in PD conductivity in Arabidopsis roots; the mutation could be mimicked by application of methyl viologen.9 An opposite effect, namely an increase in PD conductivity, was observed in the ise1 mutant which carries a defect in a mitochondrial RNA helicase; plants defective for ISE1 also exhibited increased ROS production. 13The formation of secondary plasmodesmata was enhanced in the ise1 mutant and also in a mutant lacking the plastid RNA helicase...

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