The Root Nodule Microbiome of Cultivated and Wild Halophytic Legumes Showed Similar Diversity but Distinct Community Structure in Yellow River Delta Saline Soils.

Symbiotic associations between leguminous plants and their nodule microbiome play a key role in sustainable agriculture by facilitating the fixation of atmospheric nitrogen and enhancing plant stress resistance. This study aimed to decipher the root nodule microbiome of two halophytic legumes, Sesbania cannabina and Glycine soja, which grow in saline soils of the Yellow River Delta, China, using PacBio's circular consensus sequencing for full-length bacterial 16S rRNA gene to obtain finer taxonomic information. The cultivated legume Glycine max was used for comparison. We identified 18 bacterial genera and 55 species in nodule samples, which mainly classified to Proteobacteria, and rhizobial genus Ensifer was the predominant group. The three legumes showed similarity in operational taxonomic unit (OTU) diversity but distinction in OTU richness, indicating that they harbor similar bacterial species with different relative contents. The results of principal coordinates analysis and ANOSIM tests indicated that G. soja and G. max have similar nodule bacterial communities, and these communities differ from that of S. cannabina. Wild legumes S. cannabina and G. soja both harbored a higher number of rhizobia, while G. max possessed more non-rhizobial bacteria. These differences could be associated with their adaptability to saline-alkali stress and revealed clues on the nodule endophytes with relative importance of culturable rhizobial symbionts.

Genome-wide identification, subcellular localization and gene expression analysis of the members of CESA gene family in common tobacco (Nicotiana tabacum L.).

Cellulose-synthase proteins (CESAs) are membrane localized proteins and they form protein complexes to produce cellulose in the plasma membrane. CESA proteins play very important roles in cell wall construction during plant growth and development. In this study, a total of 21 NtCESA gene sequences were identified by using PF03552 conserved protein sequence and 10 AtCESA protein sequences of Arabidopsis thaliana to blast against the common tobacco (Nicotiana tabacum L.) genome database with TBLASTN protocol. We analyzed the physical and chemical properties of protein sequences based on some software or on-line analysis tools. The results showed that there were no significant variances in terms of the physical and chemical properties of the 21 NtCESA proteins. First, phylogenetic tree analysis showed that 21 NtCESA genes and 10 AtCESA genes were clustered into five groups, and the gene structures were similar among the genes that are clustered into the same group. Second, in all of the 21 NtCESA proteins the conserved zinc finger domain was identified in the N-terminus, transmembrane domains were identified in the C-terminus and the DDD-QXXRW conserved domains were also identified. Third, gene expression analysis results indicated that most NtCESA genes were expressed in roots and leaves of seedling or mature tissues of tobacco, seeds and callus tissues. The genes that clustered into the same group share similar expression patterns. Importantly, NtCESA proteins that are involved in secondary cell wall cellulose synthesis have two extra transmembrane domains compared with that involved in primary cell wall cellulose biosynthesis. In addition, subcellular localization results showed that NtCESA9 and NtCESA14 were two plasma membrane anchored proteins. This study will lay a foundation for further functional characterization of these NtCESA genes.