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Insights into Endophytic and Rhizospheric Bacteria of Five Sugar Beet Hybrids in Terms of Their Diversity, Plant-Growth Promoting, and Biocontrol Properties
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Insights into Endophytic and Rhizospheric Bacteria of Five Sugar Beet Hybrids in Terms of Their Diversity, Plant-Growth Promoting, and Biocontrol Properties
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Journal Article
Insights into Endophytic and Rhizospheric Bacteria of Five Sugar Beet Hybrids in Terms of Their Diversity, Plant-Growth Promoting, and Biocontrol Properties
2024
Overview
Sugar beet is the most important crop for sugar production in temperate zones. The plant microbiome is considered an important factor in crop productivity and health. Here, we investigated the bacterial diversity of seeds, roots, and rhizosphere of five sugar beet hybrids named Eduarda (ED), Koala (KO), Tibor (T), Tajfun (TF), and
Cercospora
-resistant (C). A culture-independent next-generation sequencing approach was used for the further investigation of seed-borne endophytes. Hybrid-associated bacteria were evaluated for their plant growth–promoting (PGP) characteristics, antagonistic activity towards
Cercospora beticola
and several
Fusarium
strains in dual culture assays, and drought and salinity tolerance. High-throughput sequencing revealed that the
Proteobacteria
phylum was most dominant in the seeds of all hybrids, followed by
Cyanobacteria
and
Actinobacteriota
. The predominant genus in all hybrids was
Pantoea
, followed by
Pseudomonas
,
Acinetobacter
,
Chalicogloea
,
Corynebacterium
,
Enterobacter
,
Enterococcus
,
Glutamicibacter
,
Kosakonia
, and
Marinilactibacillus
. Unique genera in the hybrids were
Pleurocapsa
and
Arthrobacter
(T),
Klebsiella
(TF),
Apibacter
(ED), and
Alloscardovia
(KO). The genera that were most represented in one hybrid were
Weissella
and
Staphylococcus
(TF);
Streptococcus
(T);
Gardnerella
,
Prevotella
, and
Rothia
(KO); and
Gilliamella
,
Lactobacillus
, and
Snodgrassella
(ED). Thirty-two bacteria out of 156 isolates from the rhizosphere, roots, and seeds were selected with respect to various plant growth–promoting activities
in vitro
, i.e., nitrogen fixation, phosphate solubilization, siderophore production, indole-3-acetic acid production, 1-aminocyclopropane-1-carboxylic acid deaminase activity, hydrogen cyanide production, exoenzymatic activity (amylase, protease, lipase, cellulase, xylanase, mannanases, gelatinase, and pectinase), mitigation of environmental stresses, and antifungal activity.
Mixta theicola
KO3-44,
Providencia vermicola
ED3-10,
Curtobacterium pusillum
ED2-6, and
Bacillus subtilis
KO3-18 had the highest potential to promote plant growth due to their multiple abilities (nitrogen fixation, phosphate solubilization, production of siderophores, and IAA). The best antagonistic activity towards phytopathogenic fungi was found for
Bacillus velezensis
C3-19,
Paenibacillus polymyxa
C3-36 and
Bacillus halotolerans
C3-16/2.1. Only four isolates
B. velezensis
T2-23,
B. subtilis
T3-4,
B. velezensis
ED2-2, and
Bacillus halotolerans
C3-16/2.1 all showed enzymatic activity, with the exception of xylanase production.
B. halotolerans
C3-16/2.1 exhibited the greatest tolerance to salinity, while two
B. subtilis
strains (C3-62 and TF2-1) grew successfully at the maximum concentration of PEG. The current study demonstrates that sugar beet–associated bacteria have a wide range of beneficial traits and are therefore highly promising for the formulation of biological control and PGP agents.
Publisher
Springer US,Springer Nature B.V
Subject
1-aminocyclopropane-1-carboxylate deaminase
/ amylases
/ Bacillus
/ Bacteria
/ Biomedical and Life Sciences
/ Cyanides
/ Drought
/ Ecology
/ Enzymes
/ Fungi
/ Fusarium
/ genus
/ Geoecology/Natural Processes
/ Hybrids
/ Pantoea
/ Plants
/ Roots
/ Salinity
/ Seeds
/ Sugar
/ sugars
/ Water Quality/Water Pollution
/ Xylanase
