Antimicrobial activity and spectroscopic characterization...
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Antimicrobial activity and spectroscopic characterization of surfactin class oflipopeptides from Bacillus amyloliquefaciens SR1
Nanjundan Jaivel, Rajesh Ramasamy, Uthandi Sivakumar, Ponnusamy Marimuthu
PII: S0882-4010(18)30844-1
DOI: https://doi.org/10.1016/j.micpath.2019.01.037
Reference: YMPAT 3379
To appear in: Microbial Pathogenesis
Received Date: 10 May 2018
Revised Date: 23 January 2019
Accepted Date: 23 January 2019
Please cite this article as: Jaivel N, Ramasamy R, Sivakumar U, Marimuthu P, Antimicrobial activity andspectroscopic characterization of surfactin class of lipopeptides from Bacillus amyloliquefaciens SR1,Microbial Pathogenesis (2019), doi: https://doi.org/10.1016/j.micpath.2019.01.037.
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Antimicrobial activity and Spectroscopic characterization of Surfactin class of
Lipopeptides from Bacillus amyloliquefaciens SR1
Nanjundan Jaivel*, Rajesh Ramasamy, Uthandi Sivakumar and Ponnusamy Marimuthu
Department of Agricultural Microbiology, Tamil Nadu Agricultural University, Coimbatore, 641
003, Tamil Nadu, India
*Corresponding author email: [email protected]
Abstract
A bacterial isolate screened from wet land soil sample, found to posses antimicrobial
activity against an array of fungal plant pathogens viz., Rhizoctonia solani, Sclerotium rolfsii
Alternaria solani, Fusarium oxysporium under in vitro dual culture plate assay. Further the
isolate was identified into Bacillus amyloliquefaciens based on 16S rRNA sequencing studies.
The antimicrobial fraction from the extracellular supernatant of the isolate comprises chiefly of
surfactin molecules and also iturin and fengycin group of compounds. The surfactins were
partially purified by tangential flow ultra-filtration and quantified with liquid chromatography
yielding 316.1 mg L-1. Further the surfactin molecules were characterized by HPLC separation,
FT-IR, LC-MS spectroscopy and PCR amplification of antibiotic genes. The surfactin molecule
with m/z 1022 performed for ms-ms fragmentation and produced two different patterns of ion
dissociation.
Key words: Antifungal, Bacillus amyloliquefaciens SR1, LC-MS, lipopeptides, surfactin, PCR
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1. Introduction
Control of plant diseases by biological control agents is emerging as an alternative
strategy mainly depends on colonization of the microbe in the host phyllosphere or rhizosphere,
or by induction of induced resistance. Bacteria belonging to the genus Bacillus are known for
their widespread distribution in nature, ability to produce diverse secondary metabolites and
capable of endospore formation make them to survive under different adverse conditions [1,2,3].
Several strains of Bacillus adopt different mechanisms of action to cater plants from the plant
diseases. Synthesizing of antimicrobial secondary metabolites, induction of defense responses in
the host plant, and competition for nutrient sources and space are some of them [4,5,6].
The Bacillus strains are also known for production of several antimicrobial peptides
characterized by a wide antimicrobial spectrum and intense surfactant activities. In relation to
biocontrol of plant diseases, the three families of Bacillus lipopeptides - surfactins, iturins and
fengycins were at first mostly studied for their antagonistic activity for a wide range of potential
phytopathogens, including bacteria, fungi and oomycetes [7,8]. Antimicrobial peptides (AMPs)
are short sequence peptides with generally fewer than 50 amino acid residues, most of which
have antimicrobial activity against a broad spectrum of pathogens including Gram-positive and
Gram-negative bacteria and fungi [9]. AMPs produced by Bacillus spp. have been implicated in
the biocontrol of several plant pathogens causing aerial, soil, and postharvest diseases and in the
promotion of plant growth [10,11,12]. Recent investigations showed that these lipopeptides
influencing the colonization and persistence of Bacillus in rhizosphere and have a key role in the
beneficial interaction of Bacillus species with plants by stimulating host defense mechanisms [8].
In the present study a bacterium isolated from wet land soil is studied for their in vitro
antimicrobial activity against selected fungal pathogens. The antimicrobial fraction from
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extracellular supernatant of the isolate was studied in detail by spectroscopic characterization and
the findings are presented in this paper.
2. Material and methods
2.1. Microbial culture
The SR1 isolate was grown in Nutrient agar slants for 48 hours and maintained under
refrigerated conditions. The fungal plant pathogens used in this study were obtained from the
Department of Plant Pathology, Tamil Nadu Agricultural University, Coimbatore, India.
2.2. Chemicals
The chemicals used in the present study were of analytical reagent grade. It was
purchased from Himedia, Sigma, Qualigens and SD Fine Chem., India.
2.3. Screening of antimicrobial activity
The bacterial isolate were evaluated for their antimicrobial activity under in vitro against
selected plant pathogens viz., Rhizoctonia solani, Sclerotium rolfsii, Fusarium oxysporum,
Alternaria solani using dual culture plate assay. Both the bacterial isolate and the test pathogen
were allowed to grow on a single petri plate and observations were taken based on the
suppression of the plant pathogen.
2.4. Identification of bacteria by 16S rRNA sequencing
The SR1 isolate were initially categorized by preliminary microscopic examination after
gram staining. Further grouping based on the results of various biochemical tests, the organisms
were identified up to generic level by referring to the Bergy’s manual.
The total genomic DNA from the Bacillus amyloliquefaciens SR1 strain was isolated
using the method given by [13] with slight modifications. The genomic DNA subjected to PCR
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using the forward primer 5'- AGAGTTTGATCCTGGCTCAG -3' and reverse primer 5'-
ACGGCTACCTTGTTACGACTT-3' for the amplification of 16S rRNA gene.
PCR products were sequenced through single pass analysis from forward and reverse
direction [14]. Sequence data was compared with available data by BLAST analysis in NCBI
sequence data bank. Relevant sequences were collected and data was plotted with Mega 7.0
software and phylogenetic tree was constructed [15].
2.5. Multiplication of SR1 isolate in growth media
A seed culture of Bacillus amyloliquefaciens was prepared by inoculating a loop of
biomass into a 250 ml Erlenmeyer flask containing 100 ml of Luria-Bertani broth and then
incubating at 30 ºC for 24 hours. A 5 % level of this inoculum was transferred into 200 ml of
Landy’s broth contained in 500 ml Erlenmeyer flasks and then incubating at 30 ºC for 72 hours
for lipopeptide production.
2.6. Separation of extracellular lipopeptide fractions (ELFs)
The ELFs was isolated from the cell free broth of 72 h grown culture. The bacterial cells
were removed from surfactant containing culture broth by centrifugation at 10000 rpm at 4˚C for
10 min. The supernatant was precipitated overnight at 4˚C by adding 3N HCl to achieve a final
pH of 2.0, to precipitate lipopeptides. The pellets formed by precipitation were collected by
centrifugation at 10000 rpm at 4˚C for 20 min and used for bioactivity studies. The antimicrobial
activity of ELFs evaluated by agar well diffusion experiment and the surfactant property checked
by oil spreading technique.
2.7. Antimicrobial activity of ELFs
The antimicrobial activity of the ELFs against selected fungal plant pathogens was
studied by agar well diffusion method [16]. The sterilized medium was poured into the
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petriplates and allowed to solidify. Then each petriplate was divided into four equal quarters.
Using a sterile cork borer, wells of 6 mm diameter were made in two quadrat of the plate
containing the media. For each organism, 40 µl of the prepared test sample was loaded in each
well. The test samples were prepared in the concentration of 1mg/ml. Three replications were
maintained for each treatment. For each test pathogen the negative control (three replications
each) were also loaded in a separate well. The fungal discs were kept in the petri plates using
cork borer. The plates were incubated for 72 h and the observations were taken. The
antimicrobial spectrum of the crude extract was determined in terms of zone of inhibition. The
observations were made by measuring the inhibition zone (or halo like area), which indicates the
absence of microbial growth around the well. The diameter of inhibition zone (DIZ) was
measured and the mean DIZ was calculated.
2.8. Oil spreading technique
In oil spreading assay [17], 10 µl of crude oil was added to the surface of 40 ml of
distilled water in a petri dish to form a thin oil layer. Then, 10 µl of ELF were gently placed on
the centre of the oil layer. The presence of biosurfactant would displace the oil and a clear zone
would form, which can be visualized under visible light indicate the surfactant activity.
2.9. Amplification of antibiotic genes in SR1 isolate
2.9.1. Surfactin
The forward primer SUR3F (5’ACAGTATGGAGGCATGGTC3’) and reverse primer
SUR3R (5’TTCCGCCACTTTTTCAGTTT3’) were used for amplification of surfactin gene
(441 bp) [18]. The 40 µl PCR reaction mixture contained DNA template 50 ng, 1X Taq buffer,
0.2 mM of each of dNTP mixture, 1 µM of each primers, 1.5 mM MgCl2 and 2U of Taq DNA
polymerase. PCR amplification was performed in a Mastercycler with the following conditions
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of initial denaturation at 94°C for 3 min, 40 cycles consisting of 94°C for 1 min (denaturation),
57°C for 1 min (annealing), 72°C for 1 min (primer extension) and final extension 72°C for 10 min.
2.9.2. Iturin A
The forward primer ITUD1F (5’GATGCGATCTCCTTGGATGT3’) and reverse primer
ITUD1R (5’ATCGTCATGTGCTGCTTGAG3’) were used for amplification of iturin A gene
(647 bp) [18]. The 20 µl mixture contained approximately 50 ng of total DNA, 5 mM each dNTPs,
20 pmol of each forward and reverse primer and 0.5 U of Taq DNA polymerase. PCR
amplification was performed with the conditions of initial denaturation at 94°C for 3 min, 40
cycles consisting of 94°C for 1 min (denaturation), 60°C for 1 min (annealing), 72°C for 1 min
(primer extension) and final extension 72°C for 10 min.
2.10. Fourier Transform Infrared Spectroscopy
The FT-IR (Fourier Transform Infrared) spectroscopy of ELFs was performed in a
diffuse reflectance mode at a resolution of 4 cm-1 using JASCO FT-IR-6800 and the absorption
frequencies were expressed in reciprocal centimeters (cm-1). The spectral data were collected
over the range of 450-4500 cm-1. The data collected were the average of 50 scans over the entire
range. The collected data was used to infer the overall nature of chemical bonds and functional
groups in the extracellular fraction. The FT-IR spectrum of a standard lipopeptide biosurfactant,
surfactin (Sigma) was also obtained in parallel. The two spectra were compared in order to
confirm the chemical nature of the lipopeptide fraction from SR1 isolate.
2.11. Purification and quantification of surfactin
The crude ELFs collected from SR1 isolate subjected to ultrafilteration (UF) for partial
purification of surfactin molecules. The miniature Tangenetial Flow Filteration (TFF) module
from PALL Lifesciences was used for purification of surfactin. The UF memebranes with the
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size of 1kDa and 3kDa were used for the filteration purpose. The partially purified surfactin
molecules from SR1 isolate subjected to LC detection along with standard surfactin (Sigma). The
concentration of surfactin derived from the standard graph plotted for the gradient of standard
surfactin molecule.
2.12. LC-MS characterization of ELFs from SR1 isolate
The lipopeptide molecules separated from the fermentation broth of Bacillus
amyloliquefaciens SR1 using acid precipitation technique were subjected to LC-MS
characterization in a Shimadzu LC-8040 system. The LC were carried out in Nexera X2 module
with SIL30AC autosampler injection volume of 10µl. The mobile phase methanol: water (90:10)
with 0.1% TFA enabled by LC30AD Pump were used for the LC separation of crude lipopeptide
fraction. The LC separation was carried out in Shimadzu Shim-pack GIST C18 reverse phase
column with the dimension of 2.1 x 150 mm. The flow rate was maintained at 0.3 ml per minute
and the detection wavelength set at 215 nm in a SPD-M20A prominence diode array detector.
The separated fractions were analyzed for their mass using LC8040 mass spectrometer via
Electrospray Ionization (ESI) Interface in both the positive and negative ion modes.
3. Results and Discussion
3.1. Screening and identification of SR1 isolate
Bacillus is a gram positive prokaryote known for synthesizing several bioactive
secondary metabolites including ribosomally synthesized peptides like bacteriocin and the non
ribosomally produced small molecular peptides comprising lipopeptides. These metabolites
exhibiting antimicrobial activity against an array of fungal plant pathogens [19]. Preliminary
screening of SR1 isolate purified from wet land paddy soil sample restricted the growth of
selected fungal plant pathogens in dual culture plate assay (Fig. 1). The elite bacterial isolate
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SR1 observed as short rods under phase contrast microscope and showed gram positive reaction
in staining.
The SR1 isolate was identified into Bacillus amyloliquefaciens based on 16S rRNA
sequencing studies. The obtained gene sequence was analyzed using BLAST software in
GenBank website and the phylogenetic tree were constructed using Mega 7 software (Fig. S1).
The nucleotide sequence of 16S rRNA has been deposited in the NCBI GenBank database under
the accession number GenBank KY963962.
3.2. Characterization of the extracellular lipopeptide fractions (ELFs) from SR1 isolate
The lipopeptide compounds originating from biological samples are known for their
surfactant and antimicrobial properties. The bacterial genus Bacillus is known for production of
several kinds of extracellular lipopeptides. Hence, the extracellular lipopeptides isolated from
Bacillus amyloliquefaciens SR1 by acid precipitation subjected to different assays to analyze its
surfactant and antimicrobial properties. The culture grown in blood agar plates was found to
possess haemolytic activity indicating its surfactant property (Fig. S2).
The lipopeptide also exhibited the zone of inhibition of 2.23 cm in agar well diffusion
assay against Rhizoctonia solani at 1mg/ml concentration, while the inhibition zone varied
between 1.76-2.33 cm against the other tested fungal pathogens (Table 1). The extracellular
lipopeptides was subjected to oil spreading assay and it was found to possess surfactant property
as confirmed by its oil displacement activity i.e., the presence of halo zone formed in the layer of
oil whereas in the water and methanol control no such activity was observed.
The amplified product from the genomic DNA of Bacillus amyloliquefaciens SR1
showed positive results for amplification of surfactin and iturin genes at 441, 647 base pairs
respectively (Fig. 2). [20] reported the PCR based detection of surfactin production in B.
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amyloliquefaciens and B. circulans using sfp gene corresponding to standard B. subtilis sfp gene
(GenBank accession no. X63158) with the oligonucleotide primers sequence of sfp -f (5-ATG
AAG ATT TAC GGA ATT TA-3) and sfp-r (5-TTATAA AAG CTC TTC GTA CG-3).
3.3. HPLC separation of ELFs
The ELFs obtained from Bacillus amyloliquefaciens SR1 isolate through acid
precipitation were subjected to HPLC separation. The lipopeptide sample was dissolved in
methanol and eluted at optimum conditions and the detection was carried out using UV detector
at 215 nm. The retention time observed in the chromatogram indicated the presence of different
surfactin molecules which were compared with standard surfactin (Sigma) under similar
conditions. The distinct peaks obtained at retention times of 3.4, 4.3, 4.9, 7.1 min for C12, C13, C14
and C15 surfactin molecules respectively (Fig. 3). The iturin and fencycin group of compounds
normally got eluted in HPLC separation before to the surfactin molecules [21]. The iturin and
fengycin molecules from SR1 isolate eluted at the retention time between 1.5-2.0 min in LC and
subjected to mass detection. [22] reported the comparison of surfactin isoforms between
surfactin standard and the surfactin fraction from Bacillus subtilis BS5 by LC separation and
diode array detection. The multiple peaks observed for Bacillus subtilis BS5 denoted the
presence of newer isoforms of surfactin apart from standard surfactin. Thus the HPLC profile of
SR1 isolate indicated the presence of mixtures of surfactin and other lipopeptide molecules.
Further the surfactin molecules collected from crude ELFs by ultra-filtration using miniature
Tangential Flow Filtration module with 1kDa and 3kDa UF membranes produced a yield of
316.10 mg L-1 of growth medium.
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3.4. FT-IR spectrometric measurement
The spectroscopic analysis using FT-IR indicated the presence of lipopeptides which
were compared with standard surfactin (Sigma) and the chemical nature of the surfactin
molecules derived from the FT-IR spectrum. A broad signal at 3308cm-1 denotes the carbon and
amino group containing compounds. The other absorbance peaks observed at 2928, 2346, 1649
cm-1 indicated the stretching vibrations due to the long alkyl chains, amino, peptide group of
compounds respectively (Fig. 4). The obtained FT-IR spectrum for SR1 isolates resembles the
characteristic signals for surfactin and iturin molecules produced for Bacillus circulans and
Bacillus subtilis respectively [23, 24].
3.5. LC-MS characterization of surfactin molecules
Surfactin isomers from Bacillus genus and its structural characterization by spectroscopy
were extensively studied and reported in number of scientific literatures [25,26,27,28]. In the
present study the total ion chromatogram obtained for the lipopeptides from SR1 isolate showed
the presence of four kinds of surfactins with m/z value of 994, 1008, 1022 and 1036. The four
surfactin molecules produce their retention time at 4.4 to 5.0, 5.0-5.8, 6.0-7.0 and 7.2-8.0
respectively in the total ion chromatogram. They were respectively indicating C12, C13, C14 and
C15 surfactin molecules. The mass range were obtained both in positive and negative ionization
mode, which were depicting the occurrence of C12-C15 surfactin family molecules in the SR1
isolate (Fig. 5; Fig. S3). Apart from surfactin molecules the SR1 isolate also detected for lower
quantities of iturin and fengycin group compounds at the mass range of 1045 for iturin (Fig. S4)
and 1462 for fengycin (Fig. S5) respectively. The mass value for fengycin detected only under
positive ionization mode.
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The surfactin molecule from SR1 isolate with m/z value of 1022 were characterized for
their fragmentation pattern under ESI mode in Shimadzu LCMS 8040 system. The dissociation
of ions by the fragmentation of surfactin observed in two different patterns (Fig. 6; Table 2).
Pattern 1: The major fragment ions were observed at the m/z values of 909, 796, 685,
681, 582, 554, 469, 451, 360, 356, 227, 199. This is in accordance with the report of [29]
considering the fragmentation ions observed at m/z value of 685, 360 and 245 were also
produced in the fragmentation of surfactin molecule from SR1 isolate. The fragmentation pattern
indicates the sequential loss of aminoacid residues and producing the order of Glu-Leu-Leu-Val-
Asp-Leu-Leu. We were unable to distinguish the Leu from Ile with the available data since both
are having the same molecular weight. The molar ratio of aminoacid residues with 1:1:1:4 was
obtained for Glu:Asp:Val:Leu respectively. Whereas, [26] reported that the surfactin molecule
from Bacillus subtilis LSFM 05 produced an fragmentation pattern of Glu(O-Me)-Leu-Leu-Val-
Asp-Leu-Leu with an aminoacid molar ratio of 1:1:1:4 was obtained for Glu:Asp:Val:Leu
respectively.
Pattern 2: The predominant fragment ions were observed at the m/z values of 923, 810,
685, 667, 582, 554, 469, 441, 360, 356, 227 199. The fragmentation ions at m/z values of 685,
360 and 245 were observed similar to the reports of [29]. The fragmentation pattern indicates the
presence of seven aminoacid residues with the order of Glu-Leu-Leu-Val-Asp-Leu-Val. This
aminoacid sequence derived from the sequential loss of aminoacids
Val/Leu/Asp/Val/Leu/Leu/Glu during the fragmentation process. The molar ratio of aminoacid
residues with 1:1:2:3 was obtained for Glu:Asp:Val:Leu respectively. Further it is derived that
the aspartic acid is observed as ester form and produced a cleavage of 143 (810-667) during the
fragmentation process. The presence of methyl ester form of either aspartic acid or glutamate
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was observed by [30] in the surfactin molecules from the culture filtrate of Bacillus subtilis
HSO121.
The antimicrobial activity of Bacillus amyloliquefaciens SR1 and corresponding
amplification of antibiotic genes, FT-IR spectrum, HPLC chromatogram and mass data from LC-
MS confirms the presence of lipopeptides. Among the lipopeptides the surfactin group of
molecules detected chiefly than iturin and fencycin. Thus, Bacillus amyloliquefaciens SR1
isolate can be commercially exploited for management of crop fungal diseases.
4. Conclusion
The bacteria isolated from the wet land soil exhibited potent antifungal activity against
selected phytopathogens. The extracellular supernatant of the isolate possessing molecules belongs to
lipopeptide family chiefly of surfactins confirmed by FT-IR and LC-MS techniques. The bacterial
isolate was identified into Bacillus amyloliquifaciens SR1 based on 16S rRNA sequencing. The
said bacteria can be efficiently used for phytoprotection against selected fungal diseases of crop
plants. This preliminary work will provide a database for further plant microbe interaction
studies.
Acknowledgement
The authors profusely thank GOI-MHRD (Government of India-Ministry of Human
Resources and Development), NewDelhi for the financial support provided under the scheme of
Centre of Excellence in Frontiers Areas of Science and Technology.
Declare
The authors declare no conflict of interest in this work.
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29. N. Hue, L. Serani, O. Laprevote, Structural investigation of cyclic peptidolipids from
Bacillus subtilis by high-energy tandem mass Spectrometry. Rapid Comm. Mass Spec., 15
(2001) 203-209.
30. X.Y. Liu, S.Z. Yang, B.Z. Mu, Production and characterization of a C15-surfactin-O-methyl
ester by a lipopeptide producing strain Bacillus subtilis HSO121. Process Biochem., 44 (2009)
1144-1151.
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Figures
Sclerotium rolfsii Alternaria solani Fusarium oxysporum Rhizoctonia solani
Figure 1. Dual culture plating of SR1 isolate with test pathogens
Figure 2. Detection of antibiotic genes in Bacillus amyloliquefaciens SR1 strain
Surfactin, 441 bp
Iturin, 647 bp
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Figure 3. HPLC separation of ELFs from SR1 isolate
Figure 4. FT-IR spectrum of ELFs from SR1 isolate
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TIC of surfactin
C12 surfactin
C13 surfactin
C14 surfactin
C15 surfactin
Figure 5. Total Ion Chromatogram and mass spectrum of surfactin molecules from
Bacillus amyloliquefaciens SR1
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a. Mass fragmentation Pattern 1
b. Mass fragmentation Pattern 2
Figure 6. Mass fragmentation of Surfactin molecule from Bacillus amyloliquefaciens SR1
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Tables
Table 1. Antimicrobial activity of ELFs from SR1 isolate
Organism DIZ (cm)
Rhizoctonia solani 2.33
Fusarium oxysporum 1.90
Sclerotium rolfsii 2.06
Alternaria solani 2.23
Macrophomina phaseolina 1.80
Aspergillus niger 2.30
Average of three replications
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Table 2. The major fragmentation ions observed for the surfactin molecule (m/z 1022) from
SR1 isolate
Sl.
No.
Fragment ion
Pattern 1
Particulars Fragment ion
Pattern 2
Particulars
1 199 Fatty acyl side chain 199 Fatty acyl side chain
2 227 Fatty acyl chain + CO 227 Fatty acyl chain + CO
3 338 (356-H2O) 328 (356-CO)
4 356 Glutamate (356-227) 338 (356-H2O)
5 451 (469-H2O) 356 Glutamate (356-227)
6 469 Leucine (469-356) 441 (469-CO)
7 554 (582-CO) 451 (469-H2O)
8 582 Leucine (582-469) 469 Leucine (469-356)
9 681 Valine (681-582) 554 (582-CO)
10 685 Fragment ion observed in
all the isomers of surfactin
582 Leucine (582-469)
11 796 Aspartic acid (796-681) 667 Valine
12 909 Leucine (909-796) 685 Fragment ion observed in all
the isomers of surfactin
13 1022 Leucine (1022-909) 810 Aspartic acid + CO (810-
667)
14 923 Leucine (923-810)
15 1022 Valine (1022-923)
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Highlights
• SR1 isolate exhibited potential antifungal activity against fungal plant pathogens.
• Surfactin class of lipopeptides were chiefly produced by SR1 isolate.
• Biosynthesis of lipopeptides by SR1 isolate were supported with spectroscopic data.