Page 39 - 《华中农业大学学报》2024年第4期

P. 39

第 4 期陈彦昭等：细菌根际黏附的界面作用机制研究 31

https：//doi.org/10.1016/ j.isci.2023.107925. microbiome assembly［J/OL］. Environmental microbiome，
［30］ BEAUREGARD P B，CHAI Y R，VLAMAKIS H，et al.Ba⁃ 2024，19（1）：33［2024-06-01］. https：//doi. org/10.1186/
cillus subtilis biofilm induction by plant polysaccharides［J］. s40793-024-00567-4.
PNAS，2013，110（17）：E1621-E1630. ［43］ KJELDGAARD B，LISTIAN S A，RAMASWAMHI V，et
［31］ KHARANGATE-LAD A. Bacteria adhered to particulate al.Fungal hyphae colonization by Bacillus subtilis relies on bio⁃
matter and their role in plant litter mineralization［M］//BORK⁃ film matrix components［J/OL］. Biofilm，2019，1：100007
AR S. Bioprospects of coastal eubacteria. Cham：Springer，［2024-06-01］.https：//doi.org/10.1016/j.bioflm.2019.100007.
2015：195-207. ［44］ BERNE C，DUCRET A，HARDY G G，et al. Adhesins in⁃
［32］ HOFF G，ARIAS A A，BOUBSI F，et al.Surfactin stimulated volved in attachment to abiotic surfaces by gram-negative bac⁃
by pectin molecular patterns and root exudates acts as a key teria［J/OL］.Microbiology spectrum，2015，3（4）：MB-0018-
driver of the Bacillus-plant mutualistic interaction［J/OL］. 2015［2024-06-01］. https：//doi. org/10.1128/microbiolspec.
mBio，2021，12（6）：e0177421［2024-06-01］. https：//doi.org/ mb-0018-2015.
10.1128/mBio.01774-21. ［45］ TAKADA Y，YE X，SIMON S. The integrins［J/OL］. Ge⁃
［33］ AHIMOU F，JACQUES P，DELEU M. Surfactin and iturin nome biology，2007，8（5）： 215［2024-06-01］. https：//doi.
A effects on Bacillus subtilis surface hydrophobicity［J］. En⁃ org/10.1186/gb-2007-8-5-215.
zyme and microbial technology，2000，27（10）：749-754. ［46］ BEDRUNKA P，GRAUMANN P L.Subcellular clustering of
［34］ DEBOIS D，FERNANDEZ O，FRANZIL L，et al.Plant poly⁃ a putative c-di-GMP-dependent exopolysaccharide machinery
saccharides initiate underground crosstalk with bacilli by induc⁃ affecting macro colony architecture in Bacillus subtilis［J］.En⁃
ing synthesis of the immunogenic lipopeptide surfactin［J］.En⁃ vironmental microbiology reports，2017，9（3）：211-222.
vironmental microbiology reports，2015，7（3）：570-582. ［47］ MAAN H，POVOLOTSKY T L，PORAT Z，et al.Imaging
［35］ WU K，FANG Z Y，GUO R，et al.Pectin enhances bio-con⁃ flow cytometry reveals a dual role for exopolysaccharides in
trol efficacy by inducing colonization and secretion of second⁃ biofilms：to promote self-adhesion while repelling non-self-
ary metabolites by Bacillus amyloliquefaciens SQY 162 in the community members［J］.Computational and structural biotech⁃
rhizosphere of tobacco［J/OL］. PLoS One，2015，10（5）： nology journal，2022，20：15-25.
e0127418 ［2024-06-01］. https：//doi. org/10.1371/journal. ［48］ ZHAO X，WANG Y，SHANG Q H，et al. Collagen-like pro⁃
pone.0127418. teins （ClpA，ClpB，ClpC，and ClpD） are required for biofilm for⁃
［36］ LIU Z Z，KIMYON O，MANEFIELD M.Wastewater treat⁃ mation and adhesion to plant roots by Bacillus amyloliquefa⁃
ment bacteria show differential preference for colonizing natu⁃ ciens FZB42［J/OL］.PLoS One，2015，10（2）：e0117414 ［2024-
ral biopolymers［J/OL］.Applied microbiology and biotechnolo⁃ 06-01］.https：//doi.org/10.1371/journal.pone.0117414.
gy，2024，108（1）：321［2024-06-01］. https：//doi. org/ ［49］ XU Z H，ZHANG H H，SUN X L，et al.Bacillus velezensis
10.1007/s00253-024-13162-x. wall teichoic acids are required for biofilm formation and root
［37］ MORRISON M，MIRON J.Adhesion to cellulose by Rumino⁃ colonization［J/OL］.Applied and environmental microbiology，
coccus albus：a combination of cellulosomes and Pil-proteins？ 2019，85（5）：e02116-18［2024-06-01］. https：//doi. org/
［J］.FEMS microbiology letters，2000，185（2）：109-115. 10.1128/AEM.02116-18.
［38］ NGUEMA-ONA E，VICRÉ-GIBOUIN M，CANNESAN M ［50］ MASSALHA H，KORENBLUM E，MALITSKY S，et al.
A，et al.Arabinogalactan proteins in root–microbe interactions Live imaging of root-bacteria interactions in a microfluidics set⁃
［J］.Trends in plant science，2013，18（8）：440-449. up［J］.PNAS，2017，114（17）：4549-4554.
［39］ VICRÉ M，SANTAELLA C，BLANCHET S，et al.Root bor⁃ ［51］ VAN DER WESTEN R，SJOLLEMA J，MOLENAAR R，
der-like cells of Arabidopsis microscopical characterization et al.Floating and tether-coupled adhesion of bacteria to hydro⁃
and role in the interaction with rhizobacteria［J］.Plant physiolo⁃ phobic and hydrophilic surfaces［J］.Langmuir，2018，34（17）：
gy，2005，138（2）：998-1008. 4937-4944.
［40］ HUANG R，FENG H C，XU Z H，et al.Identification of ad⁃ ［52］ CUI M，DUAN Y H，MA Y Y，et al.Real-time QCM-D mon⁃
hesins in plant beneficial rhizobacteria Bacillus velezensis itoring of the adsorption-desorption of expansin on lignin［J］.
SQR9 and their effect on root colonization［J］.Molecular plant- Langmuir，2020，36（16）：4503-4510.
microbe interactions，2022，35（1）：64-72. ［53］ BODEN S，REISE F，KANIA J，et al.Sequence-defined intro⁃
［41］ DIEHL A，ROSKE Y，BALL L，et al.Structural changes of duction of hydrophobic motifs and effects in lectin binding of
TasA in biofilm formation of Bacillus subtilis［J］. PNAS， precision glycomacromolecules［J/OL］. Macromolecular bio⁃
2018，115（13）：3237-3242. science，2019，19（4）：e1800425［2024-06-01］. https：//doi.
［42］ NISHISAKA C S，VENTURA J P，BAIS H P，et al.Role of org/10.1002/mabi.201800425.
Bacillus subtilis exopolymeric genes in modulating rhizosphere ［54］ BERNE C，ELLISON C K，DUCRET A，et al.Bacterial adhe⁃

34 35 36 37 38 39 40 41 42 43 44