Structural Analysis and Antimicrobial Mechanism of a Protein GBSPI-A from Ginkgo Biloba Seed

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Introduction
Antibiotic tolerance, as an increasingly serious problem, could constitute a danger to human health.Terefore, the new substitute goods of antibiotic have been widely concerned to solve this problem.Antimicrobial protein, a micromolecule polypeptide extensively existing in the natural world, plays a crucial role in the biological immune system [1,2].
Since the cecropin with the antimicrobial character was found [3], more antimicrobial peptides from diferent sources, such as cytokines, animal, and plants sources, were further discovered [4][5][6].Te peptides produced by the previous resource could restrain the growth of numerous microorganisms [7].
Te antimicrobial protein is deemed to the promising alternative to antibiotic and has wide application prospect in medicine, food, and agriculture due to the stabilization and difculty to produce tolerance for target bacteria [8,9].Te research of antibacterial mechanism on protein is mainly concentrated on protein from animal origin.Te antimicrobial peptides from animal have been restricted to employ on account of food safety, hence, the protein from vegetable has received more attention [10].
Te antimicrobial protein separated from botany such as corn peptide and soybean peptide could inhibit the activity of pathogens including bacteria, fungus, and viruses [11,12].Te mechanism of antimicrobial protein on bacteria is multiple due to the diversity of sources [13].
Ginkgo, the ancient living fossils, is one of the oldest trees and possesses a very strong resistance ability.In this study, the GBSPI-A separated from ginkgo biloba seeds was separated and identifed, and the result of LC-MS-MS was researched in the NCBInr protein database.In our previous studies, Hai-xia et al. [14] found that GBSPI-A has antibacterial activity by evaluating the inhibition zone and measuring the minimum inhibitory concentration (MIC) values.However, the antimicrobial mechanism of GBSPI-A was not further research.Te aim of this study is to explore the antimicrobial mechanism of GBSPI-A.Firstly, ginkgo proteins were separated and identifed.Secondly, the interaction between protein and bacteria was researched by studying the bacterial membrane integrity, the cell damage, the synthetic ability of DNA and protein, the content of ATP, and the activity of ATPase, β-galactosidase, and Alkaline phosphatase (AKP), which will provide a practical and theoretical basis for exploiting novel antimicrobial peptide derived from plant.

Materials and Methods
2.1.Bacterial Strains and Chemicals.Ginkgo biloba seeds were purchased from Jiangsu Taixing in October 2011 and stored at −80 °C for nine years.Dialysis tubes and lysozyme were purchased from Golden Spike Biotechnology Co., Ltd (Shanghai, China).DEAE-Cellulose 52 was purchased from Whatman Co., Ltd (Mettlestone, England).Sephadex G-75 was obtained from Pharmacia Co., Ltd (NY, USA).Te standard substances of the amino acid were obtained from Sigma Co., Ltd (MD, USA).All of the other chemicals and reagents used were of analytical grade.
Te K. pneumoniae and S. aureus were obtained from the Institute of Chemical Industry of Forest Products, CAF (Nanjing, China) and inoculated in fresh sterilized nutrient broth (NB) medium (pH � 7.2) and cultivated at 37 °C, with the shaking table in 130 rpm for 24 h, the bacterial concentration was reached to 10 8 cfu/mL for further experiments.

Preparation and Purifcation of Ginkgo Protein.
Te GBSPI-A with antibacterial activity was extracted and purifed from ginkgo biloba seeds according to the method of our previously reported [14].Te ginkgo biloba seed proteins were extracted by phosphate bufer (0.07 mol/L, pH 7.0).Te mixed proteins were seriatim purifed using DEAE-cellulose 52 column and Sephadex G-75.

Structural Characterization of Protein Analysis
2.3.1.Amino Acid Composition Analysis.Te amino acid composition was measured according to the method of Misurcova et al. [15] described previously.Proteins (50 mg) were dissolved with 20 mL HCl (6 mol/L) and hydrolyzed at 110 °C for 24 h after being transferred to hydrolyzing tube.Te volume of hydrolysate was titrated to 50 mL.Ten, the amino acid composition was analyzed by the amino acid automatic analyzer (L-8900, Hitachi Limited Co., Tokyo, Japan).

Fourier Transformed Infrared Spectroscopy.
GBSPI-A (0.5 mg) was slowly ground with 50 mg of KBr powder in an agate bowl under an infrared lamp.Te uniform grinding powders were measured on the machine after being pressed into thin slice using tablet press.Finally, the slice was scanned by IR-360 fourier transform infrared spectrometer (Termo Nicolet Co., Madison, USA) in the range of 400-4000 cm −1 .

Liquid Mass Spectrometry.
Te molecular weight of the protein was measured by two-dimensional liquid phaseultra high resolution quadrupole time of fight mass spectrometry (LC-MS-MS) [16].Te analysis of two-dimensional liquid was proceeded on UltiMate 3000 (Termo Fisher Co., Massachusetts, USA) at 200-400 nm.Te detector and analytical column of the liquid chromatograph was Bruker Q-TOF and BEH C 18 (2.1 × 100 mm, 1.7 μm), respectively.Te 0.2% TFA (solvents A) and acetonitrile (solvents B) were used as mobile phases.Te samples (3 μL) were injected into the column and eluted with solvents A and B at 45 °C using a fow rate of 0.3 mL/min.Te mass spectrometry of GBSPI-A was analyzed using Q-TOF (Bruker Co., Karlsruhe, Germany).Te ion mode of the mass spectrometer was ESI+.Te voltage of the capillary, cone, and detector was successively 3500 Volts, 30 Volts, and 1700 Volts.Te temperature of the source block and desolvation was, respectively, 100 °C and 250 °C.Te gas fow of desolvation and the cone was successively 500 l/h and 50 l/h.Ten, the qualitative data of measured peptides were compared to the NCBInr protein data bank.

Efects on Growth of Bacteria
2.4.1.Growth Curve of Bacteria Measure.Te antibacterial efect of GBSPI-A had been observed in K. pneumoniae and S. aureus, and the MIC value of the previously bacteria was 20 mg/mL as our previously reported [14].Te growth curve was measured by turbidimetry, and the growth curves of the normal cultured test bacteria and those treated with GBSPI-A were drawn.Te activated bacteria solution for 24 h was, respectively, put into the nutrient broth medium and another medium contained GBSPI-A (20 mg/mL) using a sterile pipette according to 1% of the inoculation amount and mixed uniformly.Te bacteria were taken into 13 labeled sterile tubes and cultivated at 130 rpm at 37 °C.Te OD value of bacteria was measured at 600 nm by the molecular device (SpectraMax I3X, Molecular Devices Co., Shanghai, China) per 4 hours and persistently measured for 48 h [17].

Electron Microscopy of Bacteria
Observe.Te ginkgo protein was mixed with a liquid medium making the fnal concentration reach to MIC, then K. pneumoniae and S. aureus were added into the medium, respectively according to 2% inoculum size, and the suspension without ginkgo protein was used as control.Te samples were cultivated at 37 °C in the 120 rpm shaking table for 6 h and 12 h, respectively.Te samples were collected and washed thrice with 0.1 mol/L PBS (pH 7.2) every 30 min and then it was fxed with 4% glutaraldehyde at 4 °C for 72 h.Te fxed samples were washed thrice with 0.1 mol/L PBS (pH 7.2) every 30 min and then were dehydrated for 5 h at vacuum state.After gold-coating, the sample was observed by a Quanta-200 SEM (FEI Co., USA) with 25 kV working voltage [18].
For TEM examination, the dehydrated cell was cut into slices by ultramicrotome after infltration and immobilization.Te slices were dyed with uranium acetate and citric After being centrifuged at 3500 rpm, the samples were washed twice using sterile ultrapure water and made into bacterial suspension.Te GBSPI-A was added into bacterial suspension (5 mL) making the concentration of sample reach to MIC.After mixed and dissolved, the samples were taken for 1 mL sample at diferent times (0, 30, 60, 90, and 120 min) in the process of cultivation at 37 °C, and the supernate was preserved at the refrigerator after being centrifuged at 4000 rpm.Te 0.1 mL of liquid supernatant was joined to 9.9 mL ultrapure water, and its Na + concentration was measured with PinAAcle 900 atomic absorption spectrometer (Perki-nElmer, USA) [21].Tere were three parallel experiments in each group.

Infuence of GBSPI-A on Respiration of Bacterium.
Te respiratory activity of the bacterium was monitored by oxygen consumption as Zheng et al. [22] described previously.Te bacterium suspension was mixed well with 3.6 times the volume of phosphate bufer (pH 7.2, 0.1 mol/L) and 0.4 times the volume of 1% glucose solution.Tree typical inhibitors (iodoacetic acid, malonic acid, and sodium phosphate) and GBSPI-A were added into the tube to make the ultimate density reach 1 mg/mL and 10 mg/mL, respectively.Te dissolved oxygen was measured at the hermetic system after 5 min, and the sample without inhibitor was controlled.Te respiratory depression rate of S. aureus was evaluated using the following equation: where I R is the respiratory depression rate, R 0 is the respiratory rate of control, and R 1 is the respiratory rate of inhibitor, respectively.

Infuence of GBSPI-A on DNA Content of Bacteria.
Te GBSPI-A was added to the bacterial suspensions making the fnal concentration reach to MIC and 2MIC, respectively.Te bacterial suspensions were cultivated for diferent times (0, 30, 60, 90, 120, and 150 min) in the shaking table at 37 °C.
Ten, the suspensions were centrifuged at 5000 rpm for 5 min and the sediments were collected.Te sediment was used for the determination of intracellular DNA, protein, ATP, ATPase, and alkaline phosphatase.
Te DNA was extracted by a Biospin bacterial genome DNA extraction test kit (Bofei Technology Co., Nanjing, China).Te structure of the bacterial cell was destroyed by EL Bufer, RS Bufer, and PK solution, successively, causing the release of DNA.After purifed, the released DNA was combined with the Biospin membrane under the efect of specifc salt and pH in the binding bufer.After further washing, the DNA was eluted from the membrane with the elution bufer.Ten, the DNA was diluted to 100 mg/μL, and the concentration and purity of DNA was measured using protein nucleic acid tester (Eppendorf Co., Hamburg, Germany).Te 10 μL sample was mixed with bromophenol blue indicator bufer and then the mixture was added into a sample hole of agarose (1%) gel plate for an electrophoresis experiment.Te voltage was set as 100-140 V and the time was 30 min.

Infuence of GBSPI-A on Protein Synthesis Ability of
Bacteria.Te sediments were washed with normal saline and added into 500 μL TE bufer solution and then 500 μL lysozyme of 10 mg/mL after centrifugation.Te sample was resuspended and incubated at 37 °C for 20 min.Te bacterium suspension was ice bathed for 5 min after mixed with 400 μL ice water and 500 μL ice TCA of 20%.Te sediments were resuspended with 1 mL ice TCA of 10% and then the sediments were mixed with 100 μL NaCl (0.15 mol/L) and 5 mL CBB G-250 after being centrifuged.Te absorbance value was measured at 595 nm [23,24].

Infuence of GBSPI-A on ATP Content and ATPase Activity of Bacteria.
Te sediments were washed twice with normal saline and added into 500 μL TE bufer solution and 500 μL lysozyme of 10 mg/mL after centrifugation.Te sample was incubated at 37 °C for 20 min after suspension and then diluted with 3 mL of normal saline.Te sample was broken intermittently for 5 min using ultrasonic cell pulverizer (Xinzhi Biotechnology Co., Ningbo, China) at 200 W in ice bath condition.Te ATP content of bacteria was measured using ATP content test kit (Jiancheng Institute of Biological Engineering, Nanjing, China).Te ATP and creatine were catalyzed by creatine kinase to produce phosphocreatine.Te content of ATP was measured by the phosphomolybdic acid colorimetric method.Te activity of ATPase was measured using a highspeed Adenosine triphosphatase assay kit (Jiancheng Institute of Biological Engineering, Nanjing, China).Te ATPase could promote the biolysis of ATP and generate the ADP and inorganic phosphorus, so the activity of ATPase could be measured by the content of inorganic phosphorus.Te ATP content was calculated using the following equation: where OD 0 is the absorbance of blank, OD 1 is the absorbance of standard, OD 2 is the absorbance of control, OD 3 is the absorbance of sample, n 1 is the concentration of the standard (1 × 10 3 μmol/L), M is the dilution rate of sample before measured, and n 2 is the protein concentration of sample (gprot/L).

Infuence of GBSPI-A to Enzyme
2.9.1.β-Galactosidase.Te 1 mL of bacterial suspension induced by the M9 lactose medium was diluted 10 times.Te 5 mL of diluted bacterial suspension was mixed with ginkgo protein making the ultimate density reach to MIC and 2MIC, respectively.Ten, the 1 mL of bacterial suspension was transferred into a centrifuge tube and incubated at 37 °C for diferent times (0, 30, 60, 90, and 120 min).Te sample was centrifuged for 5 min at 5000 rpm, and sediment was mixed with 1000 μL lysozyme (10 mg/mL) and 1000 μL TE bufer solution.Ten, the sample was incubated at 37 °C for 20 min and then added to 8 mL bufer solution of β-galactosidase.Te sample was broken intermittently for 5 min by ultrasonic cell pulverizer (Xinzhi Biotechnology Co., Ningbo, China) at 200 W in ice bath condition.500 μL supernate was mixed with 1000 μL bufer solution of β-galactosidase and 500 μL ONPG (10 mg/mL).Te mixture was incubated at 37 °C for 2 h until presenting yellow, and the absorbance was measured at 405 nm using a spectrophotometer.
2.9.2.Alkaline Phosphatase.Te activity of alkaline phosphatase is measured by an alkaline phosphatase kit (Jiancheng Institute of Biological Engineering, Nanjing, China).Te phenyl disodium phosphate was by alkaline phosphatase to produce free phenol and phosphoric acid.Phenol and 4amino-antipyrine reacts to form a red quinone derivative via the oxidizing reaction of potassium ferricyanide in an alkaline solution.Te sediments were washed twice with normal saline and added into 500 μL TE bufer solution and 500 μL lysozyme of 10 mg/mL after centrifugation.Te sample was incubated at 37 °C for 20 min after suspension, then diluted with 3 mL of normal saline.Te sample was broken intermittently for 5 min using an ultrasonic cell pulverizer (Xinzhi Biotechnology Co., Ningbo, China) at 200 W in ice bath condition.After centrifugation, the supernate (0.5 mL) was adequately mixed with 0.5 mL bufer solution and 0.5 mL basic phosphokinase matrix fuid.Te mixture was heated in a water bath at 37 °C for 15 min, and its absorbance was measured at 520 nm after adding a color developing agent.Te ultrapure water in a blank tube was the negative control.Te standard tube was positive control using phenol standard liquid (0.1 mg/mL), and the blank tube was contrast.

Statistical Analysis.
In this study, data were analyzed by SPSS software (version 26; IBM Corp., Armonk, NY, USA).All experiments were performed in duplicate and repeated three times, and the results were presented as mean-± standard deviation.Graphs were created by Origin software (Origin Lad Co., Pro.17.0, Northampton, MA, USA).

Characterization of GBSPI-A.
Te purifed protein was identifed by the composition analysis of amino acid, infrared spectroscopy, and analysis of LC-MS-MS after purifcation.Te analysis result of protein was shown that the percentage of hydrophobic amino acid for valine, methionine, isoleucine, leucine, and phenylalanine was 5.505%, 1.821%, 2.37%, 4.185%, and 1.932%, respectively (Table 1).Te percentage of alkaline and acidic amino acid was 11.75% and 22.86%, respectively.
To detect the molecular structure, the result of infrared spectroscopy on GBSPI-A is shown in Figure 1.Te result of LC-MS-MS indicated the molecular weight of the samples was 51.40 kDa.Te result of the NCBInr protein data bank indicated that the GBSPI-A was similar to 11-S globulin from ginkgo and the score was 919.5.

Efect of GBSPI-A on Growth and Cytomembrane of
Bacteria.To evaluate the antibacterial property of protein on K. pneumoniae and S. aureus, the grow curve was measured using turbidimetry.Optical density was refected the concentration of bacteria.As shown in Figure 2, the growth curve of bacteria untreated with GBSPI-A shows the typical characteristic of bacteria growth.Growth of bacteria treated with GBSPI-A was restrained obviously and never arose logarithmic stage.Terefore, the GBSPI-A could restrain the growth of bacteria.To study the efect of GBSPI-A on structure, the morphology of bacteria was observed using the TEM and SEM, respectively.Te control group showed a smooth surface and unbroken structure without damage and cell debris (Figure 3 a1 and b1).Te bacteria treated with GBSPI-A (20 mg/mL) for 6 h showed an unsharp margin and distorted thallus (Figure 3 a2 and b2).Some thallus were broken and content was outfowed (Figure 3 a3 and b3) after 12 h.Te damage to the ultramicroscopic structure of bacteria was observed using TEM.As shown in Figure 4, clear structure in the control group indicated alive and healthy bacteria.On the contrary, the cell of protein-treated bacteria showed blurry borders indicating that the cytomembrane was damaged.

Te Leakage Rate of Molecule of Bacteria.
To verify the infuence of GBSPI-A on membrane permeability, the leakage of Na + and macromolecule was measured using absorption photometry.As shown in Figure 5, the absorbance at 260 nm and 280 nm in the control group was not a signifcant change, and that in the protein group was increased to double times compared to the control at nucleic acid outfowed the cell.Te electrolyte is one of the important substances during the bacterial metabolism, such as K + , Na + , and Ca + , which plays a signifcant role in bacterial metabolism.Te content of extracellular Na + rose by 60% at 150 min in comparison with the control group (Figures 5 a2 and b2).Te increase in extracellular Na + content indicated that the integrality of the cytomembrane was destroyed by GBSPI-A.

Efect of GBSPI-A on Respiratory Rate of Bacteria.
Te major respiratory metabolic pathways in microorganisms exist three pathways, including Embden-Meyerhof-Parnas (EMP), Tricarboxylic acid (TCA) cycle, and Hexose monophosphate pathway (HMP) pathways.Te typical inhibitor of EMP, TCA, and HMP pathways was iodoacetic acid, malonic acid, and sodium phosphate, successively [25].In this experiment, the respiratory rate of bacteria treated with typical inhibitor and GBSPI-A was lower than that in the control group, which meant that typical inhibitor and GBSPI-A could restrain the respiration of bacteria from Table 2.Although the inhibiting efect of GBSPI-A was lower than the typical inhibitor, the inhibition rate could reach 7.24% when the concentration was 10 mg/mL.

Te DNA Synthetic Ability of Bacteria. As shown in
Figures 6 a1 and b1, the resultant quantity of DNA was increased in the control group, and that in the protein group  Journal of Food Biochemistry showed contrary tendency with the extension of cultured time.Te DNA resultant quantity of K. pneumoniae and S. aureus treated with GBSPI-A (20 mg/mL) was, respectively, decreased by 83.96% and 75.02% compared with the control group.Te result of DNA gel electrophoresis maintained clear and intact, which did not show the phenomenon of dispersion and drag.Terefore, the addition of protein did not destroy the intracellular DNA of bacteria and reduced signifcantly the content of DNA.

Te Protein Synthetic Ability of Bacteria. As shown in
Figures 6 a2 and b2, the absorbance of bacteria treated with GBSPI-A rose in the frst 30 min and then reduced, while control showed an increase of the absorbance in the early stage, and had no evident changes as time prolongs.Te protein content of K. pneumoniae and S. aureus treated with GBSPI-A (20 mg/mL) was, respectively, reduced to 66.34% and 75.31% compared with the control group at 120 min.Te treatment of protein resulted in the content of intracellular protein was not signifcantly reduced in the early stage and decreased after 30 min.

Infuence of GBSPI-A on ATP Content and ATPase
Activity.To evaluate the efect of GBSPI-A on the respiration, the ATP content and ATPase activity was measured.Te changes in the ATP content and ATPase activity of the

Infuence of GBSPI-A on Activity of β-galactosidase and AKP.
Te activity of β-galactosidase and AKP was measured to explore the damage of GBSPI-A on bacteria.As shown in Figure 8 a1 and a2, the activity of β-galactosidase and AKP in control increased along with the incubation time of bacteria.
Te AKP activity and β-galactosidase of K. pneumoniae treated with GBSPI-A (20 mg/mL) were, respectively, reduced by 90.47% and 37.65%, and those of S. aureus treated with GBSPI-A (20 mg/mL) were, respectively, reduced by 94.93% and 8.23% compared with the control group at 120 min.Te AKP activity of K. pneumoniae (2MIC) and S. aureus (2MIC) could not be detected at 80 min and 50 min, respectively (Figures 8 a2 and b2).

Discussion
Antibiotic resistance of antibiotics has a serious damage to human health, so it is important to search for natural antibacterial agent.In this study, the antimicrobial mechanism of GBSPI-A separated from ginkgo biloba seeds was explored.
From the result of amino acid composition and content, the acidic amino acid content of GBSPI-A was 87.82% in the medium (pH = 7.2) and exceed that of alkaline amino acid, which was indicated GBSPI-A was an acidic protein.Te infrared spectroscopy is one of the useful methods to measure the molecular structure.Te strength grade at 3420 cm −1 represented the stretching vibration of -OH, O-H, and N-H, which indicated exist of intramolecularly or intermolecular hydrogen bond.Te stretching vibration of C-H resulted in the absorbance at 2887 cm −1 .Te stretching vibration of C=O of carboxylate and -NHCOCH 3 and fexural vibration of N-H bond was observed at 1650 cm −1 .Te strong absorption peak at 1650 cm −1 explained GBSPI-A contained amidogen.Strong alpha type C-H equatorial bonds variable angle vibration and pyranoside C-O-C stretching vibration signal were observed at 840 cm −1 and 1100 cm −1 , respectively.Te signal of beta type pyranoside bond was observed at 960 cm −1 .Tese observations confrmed that GBSPI-A is a pyrano glycoprotein compound containing the alpha and beta type glucosidic bound.Te sequence identifcation result of LC-MS-MS was indicated the molecular weight of GBSPI-A was 51.40 kDa.Te search result of the NCBInr protein database indicated the structure of GBSPI-A was similar to that of an 11-S globulin from ginkgo biloba, and some studies indicated that the 11-S globulin could inhibit the growth of bacteria [26,27].Te antimicrobial activity of GBSPI-A against K. pneumoniae and S. aureus was verifed by Hai-xia et al. [14] and the antimicrobial mechanism was not distinct.So, it was essential to explore the antibacterial mechanism against K. pneumoniae and S. aureus.
Te growth curves of GBSPI-A indicated that GBSPI-A has an obvious antibacterial efect and it could inhibit the growth and reproduction of K. pneumoniae and S. aureus.Te existence of peptidoglycan and lipopolysaccharide, respectively, results the negative charge of gram-positive and negative bacterium.Because the amino acid is an amphoteric substance having isoelectric points, protein, consisted of   Journal of Food Biochemistry amino acid, also possess isoelectric points.Although the GBSPI-A as a whole is negatively charged, it also contain positively charged amino acids.Terefore, protein could absorb on the bacterial membrane surface by electrostatic interaction.
Antibacterial peptides could combine with the negative component of the outer membrane by electrostatic interaction in the presence of cationic amino acid residues [28].Ten, the hydrophobic parts of antimicrobial embed into the plasmalemma and disturbed the membrane structure causing the membrane structure was damaged, then the intracellular material was outfowed, for instance, extravasation of protoplasm, which generated the cell death [29].Te content of cationic amino acid residue in GBSPI-A was 12.18%, which was benefcial to the preliminary combination between GBSPI-A and surface of bacteria.Te Journal of Food Biochemistry proportion of hydrophobic amino acid was 25.18%, which promoted the membrane destruction of GBSPI-A to bacteria.In addition, some arginine-rich antibacterial peptides could be internalized into the cytoplasm via the endocytic and direct translocation pathways [30].Te content of arginine in GBSPI-A was 3.141 g/100 g, which was benefcial to the internalization of GBSPI-A into the cytoplasm.
Te cell membrane is an important protective barrier for bacteria, and the results of SEM showed that the cell wall of bacteria was damaged.Te damage to cell membrane was usually accompanied by the leakage of cell contents [31], so the content of extracellular protein, nucleic acid, and Na + was detected.In this paper, the amount of protein, nucleic acid, and Na + in the extracellular was increased compared

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Journal of Food Biochemistry with the control group along with incubation time, which demonstrated that the permeability of cell membrane could increase at the existence of GBSPI-A, further causing the leakage of internal material.Reference [32] studied that the addition of cottonseed protein could cause damage of cell membrane and the leakage of cytoplasmic.Te surface of bacteria treated with GBSPI-A was broken while that of the control group was intact from SEM images.
Te SEM image provided morphological evidence of GBSPI-A acting on the cell membranes, which was consistent with previous studies [33,34].Te outer cell wall of bacteria treated with GBSPI-A was attached with many black objections from TEM images, and we speculated that may cause by the attach of GBSPI-A.Te GBSPI-A attaches to the cell membrane of bacteria, causing the changes in the physicochemical property of the cell membrane, further Journal of Food Biochemistry 11 leading to the death of bacteria.Te essence of respiratory metabolism is the oxidative degradation of sugar in organism, which not only provide the energy for vital movement but also supply the carbon skeleton and reducing power during the synthetic process of protein and lipid [35].Te respiratory of bacteria was inhibited to 7.24% upon the concentration of GBSPI-A reached 10 mg/mL.Te restraint of respiratory metabolism could result in the abnormity of physiological metabolism, further inhibiting the growth of bacteria [36].Te changes of protein content in the protein group along with growth time indicated GBSPI-A could inhibit the synthesis of intracellular protein for bacteria, which could be caused by energy shortage produce by respiration and may also be caused by leakage of protein.Nucleic acids are a key macromolecule in the organism carrying unique genetic information.In this study, the content of DNA in the protein group decreased distinctly, while that in the control group increased gradually along with the incubation time.Te DNA bands in the protein group were shallower than that in the control and not appeared trailer.Based on the results, the reason for decreasing DNA is may that the GBSPI-A could destroy the cell membrane leading to the leakage of DNA.It also may cause by the required energy of synthesis DNA being insufcient [36].
Te ATPase activity is closely associated with energy metabolism and the balance of intracellular and extracellular ions [37], playing a crucial role in transmembrane transport and maintaining membrane permeability [38].Tis study found that the ATPase activity in bacteria treated with GBSPI-A was signifcantly lower than that of the control group.ATP, as the most basic carrier of energy conversion, plays an important role in the energy metabolism of the organism and its content could refect the survival status of bacteria [17,39].Te content of ATP appeared similar tendency with the prolong of incubation time compared with the change of ATPase activity.Tis study indicated that GBSPI-A may restrain the respiration by decreasing the activity of ATPase, causing the reducing synthesis of ATP, further leading to energy shortage in the synthetic process of macromolecule.
Enzymes participate in the majority chemical reaction in the internal metabolic system and their activity are regulated by multifactor to adapt the changes of external conditions.Te β-galactosidase, the main supplier of energy for microorganism, provides energy by catalyzing lactose to monosaccharide [40].Te AKP exists between the cell wall and membrane, whose activity could not detect outside the cell under normal conditions.Te addition of GBSPI-A resulted in the decreasing of activity on β-galactosidase and AKP, which may be caused by the inhibition of GBSPI-A on protein synthesis.Te inhibition of β-galactosidase activity could generate abnormal energy metabolism and further afect the vital movement of bacteria.Te reason of decreasing activity on AKP may also be caused by that when the cell wall was damaged, AKP outfows the cell walls [41] causing the decreasing of intracellular AKP and increasing of extracellular protein, which was in agreement with the result of protein leakage.Te result showed that the inhibition efect of GBSPI-A on K. pneumoniae was better than that of GBSPI-A on S. aureus, which was attributed to the thick peptidoglycan layer of S. aureus [42].
Finally, GBSPI-A caused the decreasing activity of ATPase and respiratory rate, leading to the reducing synthesis of ATP.Ten, GBSPI-A inhibited the activity of β-galactosidase, which further made abnormal energy metabolism and not satisfed the needs of physiological metabolic, resulting in the growth inhibition of bacteria.When bacteria were attacked, bacteria did not make the normal repair mechanism causing the damaged cell membrane and the leakage of intracellular content, which led to the death of bacteria.

Conclusion
Tis study showed that GBSPI-A had an efective antibacterial activity on K. pneumoniae and S. aureus.Te result from SEM and TEM indicated that GBSPI-A (20 mg/mL) damaged the cell membrane, causing the leakage of nucleic acid, protein, and Na + and further causing the inhibiting bacterial growth with an inhibition rate of approximately 80%.Simultaneously, GBSPI-A caused the decreasing activity of ATPase and respiratory rate, leading to the reducing synthesis of ATP.GBSPI-A also inhibited the β-galactosidase activity, which further causes the insufcient energy in the synthetic process of macromolecule and the abnormal physiological activity of bacteria.In short, this study indicated that GBSPI-A could be the natural inhibitor against K. pneumoniae and S. aureus.

Figure 5 :
Figure 5: Macromolecular and Na + leakage of K. pneumoniae and S. aureus treated with GBSPI-A.a1 and b1 represent the macromolecular leakage of K. pneumoniae and S. aureus.a2 and b2 represent the Na + leakage of K. pneumoniae and S. aureus.CK: control group, MIC: treated with 20 mg/mL GBSPI-A, and 2MIC: treated with 40 mg/mL GBSPI-A: (a) K. pneumoniae and (b) S. aureus.

Figure 6 :
Figure 6: Te infuence of GBSPI-A on the DNA and protein synthesis of bacteria.a1 and b1 represent the infuence of GBSPI-A on the DNA synthesis of K. pneumoniae and S. aureus.a2 and b2 represent the infuence of GBSPI-A on protein synthesis of K. pneumoniae and S. aureus.CK: control group, MIC: treated with 20 mg/mL GBSPI-A, and 2MIC: treated with 40 mg/mL GBSPI-A: (a) K. pneumoniae and (b) S. aureus.

Figure 7 :
Figure 7: Te efect of GBSPI-A on the ATP content and ATPase activity of bacteria.a1 and b1 represent the infuence of GBSPI-A on the ATP content of K. pneumoniae and S. aureus.a2 and b2 represent the infuence of GBSPI-A on ATPase activity of K. pneumoniae and S. aureus.CK: control group, MIC: treated with 20 mg/mL GBSPI-A, and 2MIC: treated with 40 mg/mL GBSPI-A: (a) K. pneumoniae and (b) S. aureus.

Figure 8 :
Figure 8: Te infuence of GBSPI-A on the β-galactosidase and AKP activity of bacteria.a1 and b1 represent the infuence on the β-galactosidase activity of K. pneumoniae and S. aureus.a2 and b2 represent the infuence on the intracellular AKP activity of K. pneumoniae and S. aureus.CK: control group, MIC: treated with 20 mg/mL GBSPI-A, and 2MIC: treated with 40 mg/mL GBSPI-A: (a) K. pneumoniae and (b) S. aureus.

Table 1 :
Amino acid composition and content of GBSPI-A.

Table 2 :
Inhibiting rate of the representative inhibitor and GBSPI-A to S. aureus.