Bo Lan’s research while affiliated with Beijing Forestry University and other places

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Publications (3)


Genome sequencing status of threatened plants. A Map of threatened plants with sequenced genomes (red, orange, and yellow dots represent “critically endangered,” “endangered,” and “vulnerable” plants, respectively), and global regulatory status of genome-edited (GE) plants in indicated areas (adapted from [53]). SDN, site-directed nuclease; GMO, genetically modified organism. B Genome sequencing status of threatened plants. Total numbers of species (in blue) and numbers with sequenced genomes (in red) in three groups of threatened plants. C Increase in numbers of sequenced genomes of threatened plants with time between 2014 and 2022
Potential applications of genome editing (GE) in plant conservation. A Deleterious mutations can be identified by several software packages at the population level, then modified by GE tools, B GE can be used to modify flower pigmentation to increase pollinator visitation, which may lead to increases in gene flow and thus genetic diversity, C genomes of susceptible plants can be engineered to enhance their disease resistance either by host induced gene silencing (HIGS) or modifying susceptibility (S) genes, and D GE can be used to engineer plant-associated microbes or microbiomes. The engineered microbes or microbiomes can then colonize either above- or below-ground parts of plants, which may promote resistance, tolerance, and/or growth
A road map from the feasibility of introducing genome editing (GE) technology to threatened plant species to the creation of successful GE variants
Plant conservation in the age of genome editing: opportunities and challenges
  • Literature Review
  • Full-text available

October 2024

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68 Reads

Genome Biology

Kangquan Yin

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Mi Yoon Chung

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Bo Lan

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[...]

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Myong Gi Chung

Numerous plant taxa are threatened by habitat destruction or overexploitation. To overcome these threats, new methods are urgently needed for rescuing threatened and endangered plant species. Here, we review the genetic consequences of threats to species populations. We highlight potential advantages of genome editing for mitigating negative effects caused by new pathogens and pests or climate change where other approaches have failed. We propose solutions to protect threatened plants using genome editing technology unless absolutely necessary. We further discuss the challenges associated with genome editing in plant conservation to mitigate the decline of plant diversity.

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Virulent Fusarium isolates with diverse morphologies show similar invasion and colonization strategies in alfalfa

May 2024

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56 Reads

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3 Citations

Root rot is a major disease that causes decline of alfalfa production, and Fusarium is a major pathogen associated with root rot. In this study, 13 Fusarium isolates were obtained from alfalfa with root rot in Gansu Province, the major alfalfa production region in China. The isolates were characterized by molecular genotyping (ITS, TEF 1-α and RPB2 fragments) and identified as six species, which included the F. acuminatum, F. incarnatum, F. oxysporum, F. proliferatum, F. redolens, and F. solani. We found that their morphology varied significantly at both the macro- and micro-levels, even for those from the same species. We developed a low cost and fast pathogenicity test and revealed that all isolates were pathogenic to alfalfa with typical root rot symptoms such as leaf yellowing and brown lesions on the root and stem. However, the virulence of the isolates differed. We also found that the conidia of all isolates germinated as early as 24 hours post inoculation (hpi), while hyphae colonized the root extensively and invaded the xylem vessel by 48 hpi. Together our results reveal that different virulent Fusarium isolates use a similar invasion strategy in alfalfa. This natural plant-fungus pathosystem is intriguing and warrants further examination, particularly with regard to efforts aimed at mitigating the impact of multiple similar vascular pathogens on infected alfalfa plants.


Complete genome sequence of Agrobacterium fabrum ARqua1

October 2023

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10 Reads

Microbiology Resource Announcements

We report the complete genome of Agrobacterium fabrum ARqua1 generated from Oxford Nanopore and Illumina sequencing. The genome of ARqua1 has a total length of 5,714,310 bp, comprising a circular chromosome, a linear chromosome, and two plasmids. In total, 5,446 genes were predicted, of which 5,288 were annotated.

Citations (1)


... [63] and (iv) Corynascus verrucosus which has the capacity of decomposing crop residue such as cellulose, lipid and lignin in the composting process [64]. Alfalfa showed the following crop-specific fungal species: Aspergillus niveus, a xylanase producer [65]; Bipolaris sorokiniana, identified as a plant pathogen causing spot blotch [66]; and Fusarium oxysporum, a plant pathogen causing vascular wilt [67]. Maize also shared with alfalfa a few fusarium species: Fusarium proliferatum, the main source of fumonisins, a health risk mycotoxin, contaminating agro-products [68], and Fusarium equiseti which causes stalk rot in maize [69,70]. ...

Reference:

Cultivable Rhizosphere Microbial Community Structure in the Yaqui Valley's Agroecosystems
Virulent Fusarium isolates with diverse morphologies show similar invasion and colonization strategies in alfalfa