Introduction
Xenorhabdus, an endosymbiont of Steinernema, has a unique life cycle causing pathogenicity in the insect host [1,3]. The infective juveniles (IJ’s) of Steinernematidae release the bacterium into the nutrient-rich hemolymph within 5 h of invasion [4,31]. The bacteria proliferate and produce a wide range of toxins, antibiotics, bacteriocins, and hydrolytic exoenzymes, resulting in a bacterial septicemia and death of the host within 24-48 h [12,18]. The bacteria also provide a suitable nutrient-rich environment for nematode growth and reproduction. The immature nematode develops in the IJ’s that again carry away the bacteria, in search of a new insect host to continue the cycle. A very interesting significant feature of bacterium Xenorhabdus is that there are two phenotypic variants, primary (Phase-I) and secondary form (Phase-II). They differ in their antibiotic production profile, outer membrane proteins (fimbriae and flagellae), symbiotic capabilities with nematode partner, and exoenzyme production potential. The complete genomic analysis of Xenorhabdus has shown that it has many genes that encode different toxins, proteases, and lipases [9]. The protease enzyme plays an important role in the pathogenicity of the nematodebacteria complex. It is a well accepted phenomenon that secreted proteolytic enzymes of Xenorhabdus play a significant role in virulence by suppressing the immune response of the insect host and helping in tissue penetration [23]. Unraveling such systems of the pathogen, secreted proteases can provide insight regarding their role in a host’s defense mechanism. Surprisingly, despite the importance of proteases in insect pathogenesis, only a few studies have been undertaken to explore the nature of protease and its production under axenic cultivation based upon their substrate specificity [11].
In this paper, we have for the first time reported the isolation and characterization of an alkaline metalloprotease from different isolates of Xenorhabdus species. X. indica has been found to produce the maximum of secreted alkaline protease. The MALDI-TOF/TOF analysis of the homogeneously purified protease confirmed its identity as secreted alkaline metalloprotease from Xenorhabdus. The bioefficacy of the purified protease was evaluated against H. armigera (cotton bollworm).
Materials and Methods
Bacterial Strain and Growth Condition
The strains of Xenorhabdus sp. were isolated from IJ’s of different Steinernema sp. The primary form was differentiated on the basis of characteristic blue colony on NBTA medium (Peptone 5; Beef extract 3; NaCl 4; Bromothymol blue 0.025; Triphenyl-2,3,4- tetrazolium chloride 0.04 in g/l), unlike the secondary form, which had a chocolate brown color.
Screening of Xenorhabdus Isolates for Protease Enzyme
Qualitative assay. Qualitative assay of protease enzyme was carried out on gelatin agar plates (Peptone 5; Beef extract 3; NaCl 4; Gelatin 12 in g/l, pH 7.2.) by spot inoculating 2 μl of cell suspension and incubation at 28℃ [21]. After 48 h, the plates were flooded with 5 ml of HgCl2 solution and the zone of hydrolysis observed. On the basis of the qualitative assay, the most promising Xenorhabdus strain was selected for further studies.
Selection of Medium for Protease Enzyme
For optimum production of protease enzyme, five different media were evaluated: skim milk (1%) in nutrient broth (NB), skim milk (1%) in NB (Half strength), gelatin (1%) in NB, gelatin (1%) in NB (half strength), soya casein digest medium. The media were inoculated with 2% (v/v) cell suspension and incubated at 28℃, 150 rpm for 24 h. Samples were withdrawn at intervals of 3 h upto 24 h for the enzyme assay.
Enzyme Assay
The culture suspension was centrifuged at 10,000 rpm for 5 min and culture supernatant was used as the enzyme source. Protease activity was assayed by incubating 250 μl of azocasein (Megazyme, 2% (w/v)) with 150 μl of enzyme solution in a water bath at 30℃ for 30 min [28]. After incubation 1.2 ml of 10% trichloroacetic acid was added to stop the reaction and the mixture was allowed to stand for 15 min. Enzyme blanks were prepared by mixing buffer, azocasein, trichloroacetic acid, and enzyme. The content was centrifuged at 10,000 rpm for 5 min to remove any undigested azocasein. The optical density of reaction supernatant was determined by adding 1.4 ml of NaOH (1 N) in supernatant (1.2 ml). One unit of enzyme is defined as the amount of enzyme required to produce an absorbance change of 0.01 in a 1 cm cuvette under the standard assay conditions.
Purification of Protease Enzyme
Extracellular protease enzyme was extracted by centrifugation of cell suspension grown in soya casein digest medium at 10,000 rpm after 18 h of incubation. Cell-free supernatant was saturated with ammonium sulfate (80%), and precipitate was collected after centrifugation at 10,000 rpm, dissolved in 0.1 M TrisHCl buffer (pH 7.6.), and dialyzed overnight at 4℃ against the same buffer. The dialysate was ultrafiltered using a 30 kDa Amicon ultra filtration unit (Millipore) followed by anion-exchange chromatography using a Macro-Prep High Q (Biorad) pre-packed column equilibrated with the same buffer. The protein was eluted with a NaCl gradient (0.5-1.5 M) in the same buffer at a flow rate of 1ml/min. Fractions having protease activity were pooled and concentrated using a 3 kDa Amicon ultra filtration unit. The purified fraction was stored at -20℃, and its purity verified using SDS-PAGE and zymography [19,30].
Characterization of Protease Enzyme
Determination of optimum pH and temperature. The optimal pH of partially purified protease enzyme was determined in 0.1 M sodium phosphate buffer (pH 6.2-7.4), 0.1 M TrisHCl buffer (pH 7.8-8.6), and 0.1 M Glycine NaOH buffer (pH 9.0-9.8). The optimal temperature was investigated by exposure of enzyme to temperatures in the range of 26-42℃. After exposing the enzyme to different pH and temperature values for 30 min, the protease activity was estimated as per the standard protocol described earlier.
Effect of metal ions and inhibitors. The effect of metal ions were determined in the presence of different metals such as Mn2+, Ca2+, Zn2+, Co2+, Cu2+, Fe3+, and Mg2+ at a concentration range 5- 25 mM. The effect of inhibitors was studied using EDTA, PMSF, and 1,10-phenanthroline (10-25 mM) on the protease activity.
Enzyme kinetics. Kinetic constants such as Vmax and Km were identified under steady-state conditions using various concentrations of azocasein (5-30 mg/ml) as substrate [29].
Matrix-Assisted Laser Desorption/Ionization-Time of Flight (MALDI-TOF/TOF)
Purified protein sample was digested with sequencing grade trypsin according to the manufacturer protocol [20]. In brief, purified protein was denatured with 8M urea and disulfide bridges were cleaved using 10 mM DTT at 55℃ for 30 min. Cysteine was alkylated using 25 mM iodoacetamide (IAA) at room temperature for 30 min in the dark. The denatured and alkylated protein was digested with MS-grade trypsin in the ratio of 50:1 for 3 h. Digested peptides were extracted using 5% ACN and 0.1% TFA in water. Peptides were desalted and concentrated by speed vac before analysis. Digested peptides (1 μg) were injected onto the chromolith Caprod RP-18e (150-0.1 mm) column [20,34]. The extracted peptides were spotted with α-cyano-4- hydroxycinnamic acid matrix in the ratio of 1:1 and spot analyzed on an Absciex 4800 Plus TOF/TOF analyzer in reflector positiveion mode for PMF spectra MS/MS. Data were converted from the 4000 series explorer file in the form of a peak list using the Mascot peak converter. The data were searched using the online Mascot server in the NCBI database for identification. Samples were similarly processed in ESI LC-MS for protein ID and its peaks were also searched using the same data server in the NCBI database for protein ID.
Table 1.Qualitative assay of protease in different Xenorhabdus isolates on the basis of zone of clearing on gelatin agar plates.
Bioassay of Purified Protease
Larvae of H. armigera were reared on a chickpea-based semisynthetic diet in the laboratory as described by Nagarkatti and Prakash [24], modified by Kalia et al. [17], at 27 ± 2℃ temperature and 60 ± 5% RH. The adult moths were given 10% honey solution fortified with multivitamins throughout their egg-laying period. Five pairs of adults were kept in each jar covered with rough cotton cloth for egg laying. Neonates were used in bioassays to evaluate the toxicity of protease.
The efficacy of the purified protease was assessed on the neonates of H. armigera by the diet incorporation method as per Gujar et al. [13]. The diet was incorporated with 0.1 ml of solution containing 1, 5, 10, 25, and 100 μg of the purified protease/gm of diet, in three replicates, while equal quantity of 0.1 M TrisHCl buffer (pH8.2) was used in the control. Total cell protein extract was prepared as per Dulmage et al. [10] and was evaluated per os at 100 μg/g concentration (on the basis of total protein content) by the diet incorporation method against neonates of H. armigera. Ten neonates were released per replicate on the purified protease incorporated diet in a plastic container of 2.5 cm diameter. Mortality was observed up to day 7 at 24 h intervals. The median lethal concentration (LC50) value was calculated using the maximum likelihood programme MLP 3.01 [27].
Results
Screening of Xenorhabdus Isolates for Protease Enzyme
Ten isolates of Xenorhabdus were screened for extracellular protease activity on gelatin agar plates. In the qualitative plate assay, all Xenorhabdus strains had shown zone of hydrolysis ranges from 16 to 26 mm (Table 1). The maximum zone of clearance was observed in X. indica strain KB-3 (Supplementary information 1).
Production of Protease Enzyme
X. indica strain KB-3 was selected for further analysis on the basis of qualitative plate assay. The culture was grown aerobically in all five different sets of media at 28℃, 150 rpm. Among the different growth media, proteolytic activity was maximum (1,552 U/ml) at 18 h in soya protein rich medium (soya casein digest broth). Similarly, milk protein (skim milk supplemented nutrient broth) was able to induce only 832 U/ml of protease activity within 18 h (Fig. 1).
Fig. 1.Proteolytic activity during the growth of X. indica strain KB-3 in different growth media.
Table 2.One unit of enzyme is defined as the amount of enzyme required to produce an absorbance change of 0.01 in a 1 cm cuvette under the conditions of the assay.
Purification of Protease Enzyme
The protease enzyme was purified by ammonium sulfate precipitation at 80% saturation. After dialysis, the dialysate was subjected to anion-exchange chromatography using a Macro-Pep High Q column (BioRad). A single peak with protease activity was obtained with a gradient (0.5-1.5 M) of NaCl (Supplementaryinformation2). The total recovery of protease after purification was 22.3% with ~8-fold purification by this step (Table 2). The purified fraction was used for zymography and SDS-PAGE. A single band of ~52 kDa was detected in the zymograph possessing protease activity (Fig. 2).
Characterization of Protease Enzyme
The optimal pH of the purified enzyme was 8.2 as determined by hydrolysis of azocasein (Fig. 3A). The optimal temperature for the protease activity was observed to be 34℃ at pH 8.2. (Fig. 3B). At 50℃, purified protease lost 90% of its proteolytic activity. The purified enzyme was found to be stable for several days at -20℃. Kinetic analysis of the hydrolysis of azocasein was carried out and Vmax and Km were found to be 109.89 U/ml/min and 2.626 mM, respectively (Supplementary information 3). The reaction rate was constant beyond a substrate concentration of 20 mg/ml of azocasein.
Fig. 2.SDS-PAGE and zymogram profile of protease enzyme. Lane 1: Marker; lane 2: crude enzyme; lane 3: ammonium sulfate precipitates after ultrafiltration (30kDa); lane 4: purified enzyme; lane 5: zymogram of purified protease.
Effect of metal ions and inhibitors on protease activity. It was found that among metal ions, Mg+2 significantly increased the activity, whereas higher concentrations 25 mM of Zn+2, Co+2, Cu+2, and Fe+2 resulted in reduction of protease activity (Fig. 3C). EDTA and 1,10-phenanthroline were found to inhibit the protease activity. The complete inhibition of protease was observed at 20 mM concentration by 1,10-phenanthroline. The same concentration of PMSF did not inhibit the protease activity.
Mass Spectrometry Analysis
The MALDI-TOF/TOF analysis of digested protein revealed its similarity with secreted alkaline metalloproteinase from X. nematophila (Accession No. gi/300724813) in the NCBI database. This protein is not documented in the Swiss Prot database. The reported molecular mass of this protein is 52.5 kDa, and it matched well with our observation from SDS-PAGE data (Fig. 2). We could not detect any other protein in the MALDI-TOF/TOF analysis with significant score (Fig. 4). This further authenticated our anion-exchange purification analysis (Supplementary information 2) about the purity of protein, which was subsequently used for downstream experiments. The protein sequence alignment using ClustalW revealed alkaline metalloprotease from X. indica had 99%, 79%, 65%, 65%, and 51% identical amino acid residues with X. nematophila (YP_003714138), X. bovienii (YP_003466436), Photorhabdus temperata (AAX99100), P. lumnescens (AA039316), and Pseudomonas aeruginosa (WP_003150973) respectively (Fig. 5).
Bioefficacy of Purified Protease
The LC50 of protease was 16.56 μg/gm of diet against neonates of H. armigera after 7 days. A positive correlation (r = 0.920) was observed between the concentration of protease and insect mortality. The perusal of results showed that purified protease gave higher mortality (67.9 ± 0.64%) as compared with total protein of X. indica (33.33 ± 1.04%) at 100 μg/gm of diet concentration.
Fig. 3.Proteolytic activity of protease at different (A) pH, (B) temperatures, (C) metal ions, and (D) inhibitors.
Discussion
Xenorhabdus sp., a member of family Enterobacteriacea, is mutually associated with the nematode Steinernema. The IJ’s nematode serves as a vector to carry bacteria into insect larvae. The nematode releases bacterial symbiont Xenorhabdus sp. inside the insect and rapidly kills the insect larvae. The tripartite relationship of bacteria-nematode and insect has been studied extensively, and the role of Xenorhabdus sp. in killing of insects has been documented [5]. Xenorhabdus sp. is highly virulent against a wide range of insect larvae and possesses the capacity to produce many toxins and antibiotics [6,15], which makes it a very potent insect killer when associated with nematodes. Besides toxins and antibiotics, it also produces many enzymes, including lipase, lecithinase, esterase, and protease, which are also implicated in killing insect larvae [26]. However, data on the bio-efficacy of purified enzymes on insect are lacking and hence this study was undertaken to assess and establish the insecticidal capacity of purified protease from X. indica.
The initial screening of Xenorhabdus sp. isolated from different locations of India was performed on the basis of gelatin liquefaction and zone of hydrolysis due to protease production, a method previously used by Marokházi et al. [21]. The zone of hydrolysis varied from strain to strain and provided a very clear idea about the most promising strain for protease production. X. indica was explored for protease production with different substrates; namely, gelatin, skim milk, and casein hydrolysate medium (soya casein digest medium). In our study, the highest protease activity was observed in casein hydrolysate medium.
The enzyme production in Xenorhabdus differs qualitatively and quantitatively and depends on the strains, species of bacteria, and their culture conditions. Many environmental factors, including temperature and aeration, affect enzyme production in Xenorhabdus sp. [2,7]. In the earlier studies of enzyme secretion by Xenorhabdus strains, protease activity was assayed by nonspecific and relatively insensitive methods, which were based on the release of amino acids from substrate proteins like gelatin. Now, with the availability of nonselective chromogenic protein substrates like azocoll, azocasein, hide powder azure, etc., the sensitivity of protease assays has increased several folds. Gelatin zymography, which can detect even small amounts of protease, was employed for detection of protease in SDSPAGE. The crude protease was purified by different techniques like ammonium sulfate precipitation, Amicon ultra filtration, and ion-exchange chromatography techniques. The single band on SDS-PAGE and zymography revealed that the preparation contains a single protease of approximately 52 kDa. The nature of the protease was further confirmed using MALDI-TOF/TOF data, which also strengthened our claim for the purified protease. The molecular mass of this kind of protease ranges from 51-60 kDa in different species and strains of Xenorhabdus sp. [5,23].
Fig. 4.MALDI TOF-TOF MS/MS spectra of peptides (A) y ion assignment of fragment on the peptide of molecular mass 1,573.74 Da, (B) y ion assignment of fragment of peptide of molecular mass 1,460.78 Da, and (C) y ion assignment of fragment of peptide of molecular mass of 1,533.8 Da.
Fig. 5.Identified peptide sequence (bold red) mapped on alkaline metalloproteases of Xenorhabdus nematophila (Accession No. YP_003714138 in NCBI database).
The optimal pH and temperature of the purified protease were found to be 8.2 and 34℃, respectively, unlike other proteases from Xenorhabdus sp. [22,30]. In our study, the metal ions Mn+2, Ca+2 increased the protease activity slightly whereas the activity was considerably increased by more than 2-fold with Mg+2. Metal ions act as a salt or ion bridge to maintain the structure conformation of the enzyme or to stabilize the binding of the substrate and enzyme complex in metallic proteases [32]. Protease showed maximum inhibition by 1,10-phenanthroline at 20 mM, which is in agreement with a previous report by Schmidt et al. [30]. However, at the same concentration, PMSF did not show significant inhibition, which clearly indicated that protease enzyme produced by Xenorhabdus is a metalloprotease. The calculated Vmax (109.89 U/ml/min) and Km (2.63 mM) for the homogeneously purified protease was comparable to the earlier report of this kind of alkaline metalloprotease [25].
The role of different extracellular metabolites produced by Xenorhabdus sp. like toxins and antibiotics in insect nematode interaction has been well documented [8,33]. Many proteases have also been purified and characterized from these endosymbiotic bacteria, but to the best of our knowledge no report is available on the bioefficacy of these purified proteases against the H. armigera. The bioefficacy of purified protease (100 ppm) was tested using neonates of H. armigera, which showed 70% mortality after 7 days. The blackened dead larvae probably resulted as a result of an activation of enzyme cascade leading to melanization in H. armigera [35]. Proteases are known to damage the peritrophic matrix, which leads to growth retardation of insects and even mortality due to increased permeability of the midgut. In several species of Lepidoptera and Diptera, proteases inhibit inducible antibacterial peptides Cercopin A that specifically inhibit gram-negative bacteria [14]. The inhibition of antibacterial peptides leads to immunosuppression in insects that favor the bacteria to establish itself in the hemolymph, causing septicemia and leading to death of the insect [16]. This is the first report of the identification and characterization of a secreted alkaline metalloprotease from the native species of X. indica and its application as a natural biocide against H. armigera. MALDI-TOF/TOF analysis confirmed the findings of the biochemical and bioefficacy data about the nature of the protein and revealed that the purified protein is a secreted alkaline metalloprotease of Xenorhabdus.
References
- Adams BJ, Fodor A, Koppenhöfer HS, Stackebrandt E, Patricia Stock S, Klein MG. 2006. Biodiversity and systematics of nematode-bacterium entomopathogens. Biol. Control 37: 32-49. https://doi.org/10.1016/j.biocontrol.2005.11.008
- Akhurst RJ. 1982. Antibiotic activity of Xenorhabdus spp., bacteria symbiotically associated with insect pathogenic nematodes of the families Heterorhabditidae and Steinernematidae. J. Gen. Microbiol. 128: 3061-3065.
- Bode HB. 2009. Entomopathogenic bacteria as a source of secondary metabolites. Curr. Opin. Chem. Biol. 13: 224-230. https://doi.org/10.1016/j.cbpa.2009.02.037
- Caldas C, Cherqui A, Pereira A, Simoes N. 2002. Purification and characterization of an extracellular protease from Xenorhabdus nematophila involved in insect immunosuppression. Appl. Environ. Microbiol. 68: 1297-1304. https://doi.org/10.1128/AEM.68.3.1297-1304.2002
- Chaston JM, Suen G, Tucker SL, Andersen AW, Bhasin A, Bode E, et al. 2011. The entomopathogenic bacterial endosymbionts Xenorhabdus and Photorhabdus: convergent lifestyles from divergent genomes. PLoS ONE 6: e27909. https://doi.org/10.1371/journal.pone.0027909
- Chattopadhyay A, Bhatnagar NB, Bhatnagar R. 2004. Bacterial insecticidal toxins. Crit. Rev. Microbiol. 30: 33-54. https://doi.org/10.1080/10408410490270712
- Chen G, Zhang Y, Li J, Dunphy GB, Punja ZK, Webster JM. 1996. Chitinase activity of Xenorhabdus and Photorhabdus species, bacterial associates of entomopathogenic nematodes. J. Invertebr. Pathol. 68: 101-108. https://doi.org/10.1006/jipa.1996.0066
- Dowling A, Waterfield NR. 2007. Insecticidal toxins from Photorhabdus bacteria and their potential use in agriculture. Toxicon 49: 436-451. https://doi.org/10.1016/j.toxicon.2006.11.019
- Duchaud E, Rusniok C, Frangeul L, Buchrieser C, Givaudan A, Taourit S, et al. 2003. The genome sequence of the entomopathogenic bacterium Photorhabdus luminescens. Nature Biotechnol. 21: 1307-1313. https://doi.org/10.1038/nbt886
- Dulmage HT, Correa JA, Martinez AJ. 1970. Coprecipitation with lactose as a means of recovering the spore-crystal complex of Bacillus thuringiensis. J. Invertebr. Pathol. 15: 15-20. https://doi.org/10.1016/0022-2011(70)90093-5
- Felfoldi G, Marokhazi J, Kepiro M, Venekei I. 2009. Identification of natural target proteins indicates functions of a serralysin-type metalloprotease, PrtA, in anti-immune mechanisms. Appl. Environ. Microbiol. 75: 3120-3126. https://doi.org/10.1128/AEM.02271-08
- Furgani G, Boszormenyi E, Fodor A, Mathe-Fodor A, Forst S, Hogan JS, et al. 2008. Xenorhabdus antibiotics: a comparative analysis and potential utility for controlling mastitis caused by bacteria. J. Appl. Microbiol. 104: 745-758. https://doi.org/10.1111/j.1365-2672.2007.03613.x
- Gujar G, Kumari A, Kalia V, Chandrashekar K. 2000. Spatial and temporal variation in susceptibility of the American bollworm, Helicoverpa armigera (Hübner) to Bacillus thuringiensis var. kurstaki in India. Curr. Sci. 78: 995-1001.
- Han R, Ehlers RU. 2000. Pathogenicity, development, and reproduction of Heterorhabditis bactoriophora and Steinernema carpocapsae u nder a x enic in vivo conditions. J. Invertebr. Pathol. 75: 55-58. https://doi.org/10.1006/jipa.1999.4900
- Herbert EE, Goodrich-Blair H. 2007. Friend and foe: the two faces of Xenorhabdus nematophila. Nature Rev. Microbiol. 5: 634-646. https://doi.org/10.1038/nrmicro1706
- James RR, Xu J. 2012. Mechanisms by which pesticides affect insect immunity. J. Invertebr. Pathol. 109: 175-182. https://doi.org/10.1016/j.jip.2011.12.005
- Kalia V, Chaudhari S, Gujar G. 2001. Changes in haemolymph constituents of American bollworm, Helicoverpa armigera (Hübner), infected with nucleopolyhedrovirus. Indian J. Exp. Biol. 39: 1123.
- Kim D, Forst S. 2005. Xenorhabdus nematophila: mutualist and pathogen. ASM News 71: 174-178.
- Laemmli UK. 1970. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227: 680-685. https://doi.org/10.1038/227680a0
- Mann M, Hendrickson RC, Pandey A. 2001. Analysis of proteins and proteomes by mass spectrometry. Annu. Rev. Biochem. 70: 437-473. https://doi.org/10.1146/annurev.biochem.70.1.437
- Marokhazi J, Lengyel K, Pekar S, Felfoldi G, Patthy A, Graf L, et al. 2004. Comparison of proteolytic activities produced by entomopathogenic Photorhabdus bacteria: strain- and phase-dependent heterogeneity in composition and activity of four enzymes. Appl. Environ. Microbiol. 70: 7311-7320. https://doi.org/10.1128/AEM.70.12.7311-7320.2004
- Marokhazi J, Mihala N, Hudecz F, Fodor A, Graf L, Venekei I. 2007. Cleavage site analysis of a serralysin-like protease, PrtA, from an insect pathogen Photorhabdus luminescens and development of a highly sensitive and specific substrate. FEBS J. 274: 1946-1956.
- Massaoud MK, Marokhazi J, Venekei I. 2011. Enzymatic characterization of a serralysin-like metalloprotease from the entomopathogen bacterium, Xenorhabdus. Biochim. Biophys. Acta 1814: 1333-1339. https://doi.org/10.1016/j.bbapap.2011.05.008
- Nagarkatti S, Prakash S. 1974. Rearing Heliothis armigera (Hb.) on artificial diet. Tech. Bull. Commonw. Inst. Biol. Contr. 17: 169-173.
- Patil U, Chaudhari A. 2009. Purification and characterization of solvent-tolerant, thermostable, alkaline metalloprotease from alkalophilic Pseudomonas aeruginosa MTCC 7926. J. Chem. Technol. Biotechnol. 84: 1255-1262. https://doi.org/10.1002/jctb.2169
- Richards GR, Goodrich-Blair H. 2010. Examination of Xenorhabdus nematophila lipases in pathogenic and mutualistic host interactions reveals a role for xlpA in nematode progeny productions. Appl. Environ. Microbiol. 76: 221-229. https://doi.org/10.1128/AEM.01715-09
- Ross GES. 1977. Maximum Likelihood Programme. The Numerical Algorithims Gr. Rothmested Experiment Station, Harpendon, UK.
- Sarath G, Dela Motte RS, Wagner FW. 1989. Protease assay methods. In Beynon RJ, Bond JS (eds.). Proteolytic Enzymes; A Practical Approach. Oxford University Press, Oxford, England.
- Schmidt T, Kopecky K, Nealson K. 1989. Bioluminescence of the insect pathogen Xenorhabdus luminescens. Appl. Environ. Microbiol. 55: 2607-2612.
- Schmidt TM, Bleakley B, Nealson KH. 1988. Characterization of an extracellular protease from the insect pathogen Xenorhabdus luminescens. Appl. Environ. Microbiol. 54: 2793-2797.
- Simoes N, Caldas C, Rosa JS, Bonifassi E, Laumond C. 2000. Pathogenicity caused by high virulent and low virulent strains of Steinernema carpocapsae to Galleria mellonella. J. Invertebr. Pathol. 75: 47-54. https://doi.org/10.1006/jipa.1999.4899
- 32. Tork SE, Shahein YE, El-Hakim AE, Abdel-Aty AM, Aly MM. 2013. Production and characterization of thermostable metallo-keratinase from newly isolated Bacillus subtilis NRC 3. Int. J. Biol. Macromol. 55: 169-175. https://doi.org/10.1016/j.ijbiomac.2013.01.002
- Wang Y, Fang X, An F, Wang G, Zhang X. 2011. Improvement of antibiotic activity of Xenorhabdus bovienii by medium optimization using response surface methodology. Microb. Cell Fact. NOV. 14: 98.
- Wilkinson J. 1986. Fragmentation of polypeptides by enzymic methods, pp. 121-148. In Darbre A (ed.). Practical Protein Chemistry: A Handbook. John Wiley and Sons, New York, NY.
- Yang J, Zeng H-M, Lin H-F, Yang X-F, Liu Z, Guo L-H, et al. 2012. An insecticidal protein from Xenorhabdus budapestensis that results in prophenoloxidase activation in the wax moth, Galleria mellonella. J. Invertebr. Pathol. 110: 60-67. https://doi.org/10.1016/j.jip.2012.02.006
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