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Authors Li

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Li, Xiang


Publications
4

CitationNamesAbstract
Potential habitat suitability of Candidatus Liberibacter asiaticus and genetic diversity of its prophages across China You et al. (2024). Microbiology Spectrum 12 (11) Ca. Liberibacter asiaticus
The functional decline of tomato plants infected by Candidatus Liberbacter solanacearum: an RNA-seq transcriptomic analysis Chuan et al. (2024). Frontiers in Plant Science 15 “Liberibacter solanacearum”
Aliikangiella marina gen. nov., sp. nov., a marine bacterium from the culture broth of Picochlorum sp. 122, and proposal of Kangiellaceae fam. nov. in the order Oceanospirillales Wang et al. (2015). International Journal of Systematic and Evolutionary Microbiology 65 (Pt_12) Pleionea Kangiella Kangiellaceae
Wenzhouxiangella marina gen. nov, sp. nov, a marine bacterium from the culture broth of Picochlorum sp. 122, and proposal of Wenzhouxiangellaceae fam. nov. in the order Chromatiales Wang et al. (2015). Antonie van Leeuwenhoek 107 (6) “Halotectona”

Potential habitat suitability of Candidatus Liberibacter asiaticus and genetic diversity of its prophages across China
ABSTRACT Huanglongbing (HLB) is a severe citrus disease in China caused by Candidatus Liberibacter asiaticus ( C Las). Since its initial identification, the pathogen has spread to 10 mainland provinces in China and caused devastating loss. Three distinct prophage types have been identified in C Las; however, their distribution and diversity in China remain inadequately understood. In this study, we collected 500 C Las samples from 10 provinces in China, employing three specific genomic loci to identify prophage types. Subsequently, Sanger sequencing was employed to analyze the genetic diversity of prophage within populations of C Las in China. In addition, the MaxEnt model optimized by the ENMeval software package, was used to predict the habitat suitability of populations of C Las and assess the potential impact of future climate change on its distribution in China. Our analysis revealed that type 2 prophage is the most prevalent, accounting for 55% in China. Among the 10 provinces tested, C Las populations in Yunnan and Sichuan demonstrated higher genetic diversity. Further analysis reveals that C Las populations harboring type 1 prophage remain relatively stable, whereas those carrying type 2 and type 3 prophages undergo population expansion. Furthermore, our predictive models indicate that the presently suitable habitat for C Las populations is concentrated in the southern and certain central regions of China, with an anticipated expansion under future climate change conditions. Presently, the center of populations of C Las characterized by favorable living conditions is situated in Zunyi City, Guizhou Province. Nevertheless, a projected trend indicates a shift toward the northeast, particularly targeting Tongren City in the foreseeable future. IMPORTANCE This study offers significant insights into the distribution and genetic diversity of three types of prophages associated with Candidatus Liberibacter asiaticus ( C Las) in China. Our predictions underscore the implications of climate change on the future distribution of C Las. These findings contribute to a better understanding of Huanglongbing management strategies and can facilitate the development of effective measures to control the spread of this devastating disease within the citrus industry.
The functional decline of tomato plants infected by Candidatus Liberbacter solanacearum: an RNA-seq transcriptomic analysis
IntroductionCandidatus Liberibacter solanacearum (CLso) is a regulated plant pathogen in European and some Asian countries, associated with severe diseases in economically important Apiaceous and Solanaceous crops, including potato, tomato, and carrot. Eleven haplotypes of CLso have been identified based on the difference in rRNA and conserved genes and host and pathogenicity. Although it is pathogenic to a wide range of plants, the mechanisms of plant response and functional decline of host plants are not well defined. This study aims to describe the underlying mechanism of the functional decline of tomato plants infected by CLso by analyzing the transcriptomic response of tomato plants to CLso haplotypes A and B.MethodsNext-generation sequencing (NGS) data were generated from total RNA of tomato plants infected by CLso haplotypes A and B, and uninfected tomato plants, while qPCR analysis was used to validate the in-silico expression analysis. Gene Ontology and KEGG pathways were enriched using differentially expressed genes.ResultsPlants infected with CLso haplotype B saw 229 genes upregulated when compared to uninfected plants, while 1,135 were downregulated. Healthy tomato plants and plants infected by haplotype A had similar expression levels, which is consistent with the fact that CLso haplotype A does not show apparent symptoms in tomato plants. Photosynthesis and starch biosynthesis were impaired while starch amylolysis was promoted in plants infected by CLso haplotype B compared with uninfected plants. The changes in pathway gene expression suggest that carbohydrate consumption in infected plants was more extensive than accumulation. In addition, cell-wall-related genes, including steroid biosynthesis pathways, were downregulated in plants infected with CLso haplotype B suggesting a reduction in membrane fluidity, cell signaling, and defense against bacteria. In addition, genes in phenylpropanoid metabolism and DNA replication were generally suppressed by CLso infection, affecting plant growth and defense.DiscussionThis study provides insights into plants’ defense and functional decline due to pathogenic CLso using whole transcriptome sequencing and qPCR validation. Our results show how tomato plants react in metabolic pathways during the deterioration caused by pathogenic CLso. Understanding the underlying mechanisms can enhance disease control and create opportunities for breeding resistant or tolerant varieties.
Aliikangiella marina gen. nov., sp. nov., a marine bacterium from the culture broth of Picochlorum sp. 122, and proposal of Kangiellaceae fam. nov. in the order Oceanospirillales
A Gram-stain-negative, non-motile, non-spore-forming, long rod-shaped bacterium, designated strain GYP-15T, was isolated from the culture broth of a marine microalga,Picochlorumasp. 122. Phylogenetic analyses revealed that strain GYP-15Tshared 90.6 % 16S rRNA gene sequence similarity with its closest relative,Kangiella aquimarinaKCTC 12183T, and represents a distinct phylogenetic lineage in a robust clade consisting of GYP-15Tand members of the generaKangiellaandPleioneain the orderOceanospirillales. Chemotaxonomic and physiological characteristics, including major cellular fatty acids, NaCl tolerance and pattern of carbon source utilization, could also readily distinguish strain GYP-15Tfrom all established genera and species. Thus, it is concluded that strain GYP-15Trepresents a novel species of a new genus, for which the nameAliikangiella marinagen. nov., sp. nov. is proposed. The type strain ofAliikangiella marinais GYP-15T( = MCCC 1K01163T = KCTC 42667T). Based on phylogenetic results, 16S rRNA gene signature nucleotide pattern and some physiological characteristics, the three generaKangiella,PleioneaandAliikangiellaare proposed to make up a novel family,Kangiellaceaefam. nov., in the orderOceanospirillales.
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