Intersections between immune responses and morphological regulation in plants

A Genomic and Transcriptomic Overview of MATE, ABC, and MFS Transporters in Citrus sinensis Interaction with Xanthomonas citri subsp. citri

The multi-antimicrobial extrusion (MATE), ATP-binding cassette (ABC), and major facilitator superfamily (MFS) are the main plant transporters families, playing an essential role in the membrane-trafficking network and plant-defense mechanism. The citrus canker type A (CC), is a devastating disease caused by Xanthomonas citri subsp. citri (Xac), affecting all citrus species. In this work, we performed an in silico analysis of genes and transcripts from MATE, ABC, and MFS families to infer the role of membrane transporters in Citrus-Xac interaction. Using as reference, the available Citrus sinensis genome and the citrus reference transcriptome from CitrusKB database, 67 MATE, 91 MFS, and 143 ABC genes and 82 MATE, 139 MFS, and 226 ABC transcripts were identified and classified into subfamilies. Duplications, alternative-splicing, and potentially non-transcribed transporters' genes were revealed. Interestingly, MATE I and ABC G subfamilies appear differently regulated during Xac infection. Furthermore, Citrus spp. showing distinct levels of CC susceptibility exhibited different sets of transporters transcripts, supporting dissimilar molecular patterns of membrane transporters in Citrus-Xac interaction. According to our findings, 4 MATE, 10 ABC, and 3 MFS are potentially related to plant-defense mechanisms. Overall, this work provides an extensive analysis of MATE, ABC, and MFS transporters' in Citrus-Xac interaction, bringing new insights on membrane transporters in plant-pathogen interactions.

Insights into the regenerative property of plant cells and their receptivity to transgenesis: wheat as a research case study

From a holistic perspective, the discovery of cellular plasticity, a very interesting property of totipotency, underlies many topical issues in biology with important medical applications, while transgenesis is a core research tool in biology. Partially known, some basic mechanisms involved in the regenerative property of cells and in their receptivity to transgenesis are common to plant and animal cells and highlight the principle of the unity of life. Transgenesis provides an important investigative instrument in plant physiology and is regarded as a valuable tool for crop improvement. The economic, social, cultural and scientific importance of cereals has led to a rich stream of research into their genetics, biology and evolution. Sustained efforts to achieve the results obtained in the fields of genetic engineering and applied biotechnology reflect this deep interest. Difficulties encountered in creating genetically modified cereals, especially wheat, highlighted the central notions of tissue culture regeneration and transformation competencies. From the perspective of combining or encountering these competencies in the same cell lineage, this reputedly recalcitrant species provides a stimulating biological system in which to explore the physiological and genetic complexity of both competencies. The former involves two phases, dedifferentiation and redifferentiation. Cells undergo development switches regulated by extrinsic and intrinsic factors. The re-entry into the cell division cycle progressively culminates in the development of organized structures. This is achieved by global chromatin reorganization associated with the reprogramming of the gene expression pattern. The latter is linked with surveillance mechanisms and DNA repair, aimed at maintaining genome integrity before cells move into mitosis, and with those mechanisms aimed at genome expression control and regulation. In order to clarify the biological basis of these two physiological properties and their interconnectedness, we look at both competencies at the core of defense/adaptive mechanisms and survival, between undifferentiated cell proliferation and organization, constituting a transition phase between two different dynamic regimes, a typical feature of critical dynamic systems. Opting for a candidate-gene strategy, several gene families could be proposed as relevant targets for investigating this hypothesis at the molecular level.

EMSY-like genes are required for full RPP7-mediated race-specific immunity and basal defense in Arabidopsis

The Arabidopsis thaliana gene enhanced downy mildew 2 (EDM2) encodes a nuclear protein required for RPP7-mediated race-specific disease resistance against Hyaloperonospora arabidopsidis, proper floral transition and additional developmental processes. Transcript levels of the disease-resistance gene RPP7 are enhanced by EDM2 while those of the floral suppressor FLC are repressed by EDM2. By yeast two-hybrid screening for EDM2-interacting proteins, we identified AtEML1, a member of a small group of four Arabidopsis proteins containing an EMSY N-terminal domain, a central Agenet domain, and a C-terminal coiled-coil motif. Using T-DNA mutants combined with silencing by artificial microRNAs, we found AtEML1, AtEML2, and, likely, AtEML4 to contribute to RPP7-mediated immunity. Besides this, AtEML1 and AtEML2 participate in a second EDM2-dependent function and affect floral transition. Unlike EDM2, whose role in immunity appears to be limited to RPP7-mediated disease resistance, some AtEML members contribute to basal defense, an unspecific general defense mechanism. Domain architectures of EDM2 as well as AtEML proteins suggest roles of these proteins in the regulation of chromatin states. Thus, possible cooperation of AtEML members with EDM2 at the level of chromatin dynamics may link race-specific pathogen recognition to general defense mechanisms.

Regulation of NB-LRR-type UNI and its related signaling pathway: signaling crosstalk and methodology for quick identification of related factors

Activation of NB-LRR-related UNI proteins by uni-1D mutation, a gain-of-function mutation of the UNI gene, induces some pathogenesis-related responses and also affects morphology through modulation of meristem activities. In a recent study we reported that the uni-1D phenotypes require cooperative action of ERECTA (ER) receptor kinase family members in UNI-expressing cells, suggesting that an intracellular signaling crosstalk between ER-family-dependent and UNI-triggered signaling pathways plays a significant role in the phenotypes. Further we recently succeeded in the establishment of a methodology for rapid identification of factors involved in the UNI function. EMS-induced causal mutations that suppress the uni-1D phenotypes could be identified using whole-genome-sequencing technologies with much less labor compared with the conventional map-based cloning method that is generally time-consuming and labor-intensive. Thus it would be now possible to intensively identify factors that play significant roles in regulation of UNI proteins and/or UNI-related signaling pathways.