Enzyme characterization and biological activities of a resuscitation promoting factor from an oil degrading bacterium Rhodococcus erythropolis KB1

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Microbiology

Introduction

Bacteria can adopt a dormant state when they are in harmful environments by reducing metabolic activity and ceasing to divide. Dormancy can take different forms, and some low G+C Gram-positive bacteria such as Clostridium and Bacillus have adopted sporulation as a means of surviving adverse environmental conditions (Rittershaus, Baek & Sassetti, 2013; Dworkin & Shah, 2010). The other bacteria, including some Gram-positive and most Gram-negative bacteria, enter a viable but nonculturable state (VBNC) in which the bacterial cells are viable as evidenced by their intact cell membranes and continued gene expression, but fail to replicate on routine laboratory media (Sachidanandham & Yew-Hoong Gin, 2009; Oliver, 2010). Upon encounter with favorable conditions, these dormant bacteria are activated and resumed growth, thereby becoming culturable (Ayrapetyan & Oliver, 2016).

Mukamolova et al. (2002b) found that a secreted protein named resuscitation-promoting factor (Rpf) from Micrococcus luteus culture can effectively promote recovery and growth of Micrococcus luteus and Mycobacterium tuberculosis cells in VBNC state. They reported that picomolar concentration of the protein was sufficient to convert dormant Micrococcus cells into actively growing cells (Mukamolova et al., 2002a, 2006). The Rpf of Micrococcus luteus was found to possess a c-type lysozyme like domain and show muralytic activity (Cohen-Gonsaud et al., 2004, 2005). The function of the Rpf was recognized as cleaving peptidoglycan. The rpf gene of Micrococcus luteus encoded 223 amino acid residues. A segment of 70 amino acids residue of the Rpf from Micrococcus luteus was known as the Rpf domain, in which a conserved glutamate and two highly conserved cysteine residues were found to be important in maintaining enzyme activity. The Rpf domain was both necessary and sufficient for biological activity. Besides the Rpf specific domain, a peptidoglycan attachment site (LysM domain) (Buist et al., 2008), secretory signal sequence or transmembrane helices were also found in the Rpf of Micrococcus luteus.

Genes resembling Micrococcus luteus rpf are widely spread among high G+C Gram-positive bacteria (Kell & Young, 2000; Ravagnani, Finan & Young, 2005). Some bacteria contain several representatives. Mycobacterium tuberculosis and Mycobacterium bovis contain five rpf-like genes (Kana et al., 2008; Garnier et al., 2003). Streptomyces coelicolor also encodes five Rpfs (Sexton et al., 2015). All of the Rpf proteins structurally possess the c-type lysozyme-like domain with a conserved glutamate in their active sites, but they share some functional redundancy. For example, the solution structure of RpfB of Mycobacterium tuberculosis showed a protein fold similar with both lysozyme and lytic transglycosidase. The RpfB was reported to cooperate with an endopeptidase RipA to cleave cell wall peptidoglycan and promote resuscitation of the dormant mycobacteria (Hett et al., 2007; Nikitushkin et al., 2015). They are also suggested to be the important virulence factors of Mycobacterium tuberculosis with roles in bacillary replication during acute disease and reactivation of chronic persistent infection (Rosser et al., 2017). Deletion all of the five rpf genes did not affect the viability of Mycobacterium tuberculosis cells, but the rpf deletion mutants lost their abilities to recovery from dormant state, and their abilities to initiate infections also decreased (Downing et al., 2005; Kondratieva et al., 2011). Homology studies of the enzymatic activity and interaction with other cell wall-modifying enzymes suggest that Rpf can modify peptidoglycan, but the mechanism of the Rpf-mediated recovery from dormancy remain to be fully elucidated.

The genus Rhodococcus is a diverse group of bacteria, which are distributed widely in natural environments. They are able to survive under extremely harsh conditions, and degrade a large number of organic compounds, including some persistant and toxic compounds, which make them potentially useful in environmental and industrial biotechnology (Van der Geize & Dijkhuize, 2004). They appear to have large genomes and harbor large linear plasmids. In addition, there is increasing evidence that multiple pathways and gene homologues are present, which further increase their catabolic versatility (Larkin, Kulakov & Allen, 2005). We have isolated an oil-degrading bacterium Rhodococcus erythropolis KB1 from oil contaminated soil. It could use different organic substrates as sole carbon sources. The strain grew well at a wide range of temperatures and NaCl concentrations, which suggested that the bacterium could be used for the soil bioremediation in severe environments (Yang et al., 2015). By comparing the genomic sequence, we have found four different rpf genes, among which rpf-1 gene of 564 bp was cloned and its sequence was found to contain the rpf domain and share 28.24% of similarity with that of the rpf C gene of Mycobacterium tuberculosis. The gene of rpf-2 is similar to the rpf B gene of Mycobacterium tuberculosis, in addition to the Rpf domain, there is a G5 superfamily protein domain and two DUF348 domains. Rpf-3 gene is similar to the rpf B gene of S. coelicolor and contains a rpf domain, a G5 superfamily protein domain and three DUF348 domains, no significant signal peptide sequences were found. Rpf-4 gene is similar to the rpf A gene of S. coelicolor and has a LysM domain in addition to the rpf domain. (Yue et al., 2018). In this paper we constructed an expression vector for the rpf-1 gene of R. erythropolis KB1 and expressed it in Escherichia coli. The conserved residues of the rpf-1 protein were respectively replaced and their enzyme and biological activities were analyzed. The muralytic activities and biological activities of the different mutant proteins were studied and compared with that of the wild-type protein. We found that Asp45, Glu51, Cys50, Thr60, Gln69, Thr74, Trp75and Cys114 of the Rpf-1 protein play vital roles in the enzyme activities and growth promoting effects. We also found that the muralytic activities were related to their growth promoting effects.

Material and Methods

Bacteria strains, plasmids and culture conditions

The bacteria strains and plasmids used in this work are listed in Table 1. R. erythropolis KB1 was isolated from oil contaminated soil in southwest China and identified by physiological and biochemical characteristics and 16S rDNA analysis (Yang et al., 2015). R. erythropolis KB1 and E. coil strains were grown on Luria-Bertani (LB) medium at 30 and 37 °C respectively. All chemical reagents were analytical grade.

Table 1:
Bacteria strains and plasmids used in this study.
Strains or plasmids Characteristics Source
Strain
R. erythropolis KB1 Wild-type Laboratory collection
E. coli DH5α TIANGEN, China
E. coli BL21 (DE3) TIANGEN, China
BL21-pET-32a (+)-rpf-1 Ampr, BL21containing pET-32a (+)-rpf-1 This work
Plasmids
pET-32a (+) vector Ampr, 5.9 kb, high-copy-number cloning vector Novagen
pUCm-T-rpf-1 Ampr, pUCm-T with an 564 bp fragment containing rpf-1 This work
pET-32a (+)-rpf-1 Ampr, pET-32a (+) with an 564 bp fragment containing rpf-1 This work
DOI: 10.7717/peerj.6951/table-1

Construction of expression vector containing the rpf-1 gene of R. erythropolis KB1 and its purification

To construct the expression vector of the rpf-1 gene of R. erythropolis KB1, a specific pair of primers (forward primer 5′-AAGCTTATGAGCGGACGCCATCGC-3′ with an HindIII site, reverse primer 5′-GAATTCCTTGAGGAACGTCTTCGC-3′ with a EcoRI site) was designed based on the sequences of rpf-1 gene of R. erythropolis KB1. The pUCm-T vector containing the rpf-1 gene of R. erythropolis KB1 was used as a template. The PCR reaction condition was as follows: 98 °C for 5 min, one cycle; 98 °C for 10 s, 55 °C for 15 s, 68 °C for 90 s, 35 cycles; with a final extension at 72 °C for 10 min. The PCR product was purified and digested with HindIII and EcoRI, it was then inserted into the pET-32a (+) vector (Novagen, Merck, Germany) digested with the same enzymes. The constructed ligation product pET-32a (+)-rpf-1 was transformed into E. coli DH5α and then into E. coli BL21 (DE3).

The E. coli BL21 (DE3) containing the pET-32a (+)-rpf-1 were inoculated into 100 mL LB medium supplemented with ampicillin antibiotics and cultivated at 37 °C overnight, it was then added to 1,800 mL of the same LB medium, continued to grow to an OD595nm of 0.6 and were induced with 0.8 mmol/L isopropyl-β-D-thiogalactopyranoside (IPTG) at 25 °C for 3 h. The bacterial broth was placed in centrifuge tubes and centrifuged at 8,500×g for 20 min at 4 °C, and the bacterial cells were collected and re-suspended in 50 mL of lysis buffer (pH 8.0, 20 mM Tris–HCl, 10 mM imidazole, 500 mM NaCl). The mixture was then sonicated with Ultrasonic Processor (SCIENTZ-950E; Ningbo Xinzhi Biotechnology Co., Ltd, Ningbo, China) in an ice bath (power 240 W, work 8 s, interval 12 s, 99 cycles). The broken cell solution was then centrifuged at 8,500×g for 20 min at 4 °C. The supernatant was collected and filtered through a 0.22 μm sterile filter (Millipore, Burlington, MA, USA). The recombinant protein was purified with Ni2+-affinity chromatography (Novagen, Merck, Germany) according to the manufacturer’s instructions and analyzed by SDS-polyacrylamide gel.

Mutation analysis of the conserved amino acid resides in the active site of the Rpf-1

The rpf-1 gene sequence of R. erythropolis KB1 was analyzed and compared with those of the related bacteria. The hypothetical conserved amino acid resides for the enzymatic activities were selected and the encoding cordons corresponding to each of the conserved amino acid residues were substituted with those of the other amino acids. The sequences containing the site-directed mutagenesis were commercially synthesized by Sangon Biotech (Shanghai, Co., Ltd., Shanghai, China). Each mutation was confirmed by nucleotide sequence analysis. The sequences containing the site-directed mutagenesis were listed in Table 2. Then the mutant plasmids were transformed into E. coli BL21 (DE3). The mutant proteins were expressed and purified in the same way as described above.

Table 2:
The conserved amino acid resides for substitution and the related oligo nucleotide sequences.
Mutant proteins Mutations Oligo nucleotides (5′–3′)
E51A Glu51→Ala GTCTCGCCCAGTGTGCGGCCGGCGGAAACTG
D45A+E51K Asp45→Ala CCGACTCCGACTGGTATCGTCTCGCCCAGTG
Glu51→Lys GTCTCGCCCAGTGTAAGGCCGGCGGAAACTG
C50G+C114T Cys50→Gly ATCGTCTCGCCCAGGGTGAGGCCGGCGGAAA
Cys114→Thr GCGCATGGCCGTCCACCTCCTCCAGCCTCGG
T60A Thr60→Ala ACTGTGCCATCAACGCGGGCAACGGTTACCA
Q69K Gln69→Lys ACCAGGGCGGACTGAAGTTCTCCCCCAGCAC
T74A Thr74→Ala AGTTCTCCCCCAGCGCGTGGAACGCACACGG
W75V Trp75→Val GTTCTCCCCCAGCACGGTGAACGCACACGGCGGCG
DOI: 10.7717/peerj.6951/table-2

Protein electrophoresis and Western blotting

SDS-PAGE on 12% acrylamide gels was performed as described by Laemmli (1970). After electrophoresis, proteins were transferred to a nitrocellulose membrane (Millipore, Burlington, MA, USA) using semidry western transfer apparatus (Bio-Rad Laboratories, Hercules, CA, USA). Western blot analysis was carried out using a rabbit anti-His taq antibody (1:1,000 dilution), followed by a horseradish peroxidase-conjugated goat anti-rabbit IgG. Dianilino benzene substrate was used for detection.

Muralytic activity analysis of the purified recombinant proteins

To determine muralytic activity of the recombinant Rpfs, the artificial fluorogenic substrate, 4-methylumbelliferyl-β-D-N,N′,N″-triacetylchitotrioside (4-MUF-3-NAG) (Sigma, Neustadt an der Weinstraße, Germany) was used and the enzyme activity was analyzed as reported before (Mukamolova et al., 2006). Briefly, 100 μL of the recombinant protein (0.02 mg mL−1) was added to 300 μL of 22 μM Mcllvaine’s phosphate buffer (100 mM citric acid, 200 mM sodium phosphate, pH 5.2 containing 4-MUF-3-NAG). The mixture was then incubated at 37 °C for 30 min. Three mL of 0.3 M glycine/NaOH buffer (pH 10.6) was added to the mixture. The fluorescence intensity was detected with Varioskan LUX Multimode Microplate Reader (Thermo Fisher, Waltham, MA, USA) using excitation wavelength of 360 nm and a read-out of 455 nm. The result was compared with a standard curve of standard substance 4-methylumbelliferone. One unit of enzyme activity was defined as the amount of enzyme that generates 1.0 nmol of the product in 1.0 mL of reaction solution per minute.

To determine the effect of metal ions and chemical agents on enzyme activities of the recombinant Rpf-1, Mg2+, Ca2+, Zn2+, Co2+, dithiothreitol (DTT), phenylmethanesulfonyl fluoride (PMSF), ethylene diamine tetra acetic acid (EDTA) and ethylene glycol tetra acetic acid (EGTA) were added to the reaction mixtures respectively. The mixtures were then incubated at 37 °C for 30 min and the muralytic activities were determined.

Protease activity of the purified recombinant Rpfs

Protease activity was determined with azocasein as substrate by the method of Kreger and Lockwood (Inamura, Nakai & Muroga, 1985). Reaction solution consisted of 0.5 mL of azocasein solution (five mg mL−1), 0.1 mL of the enzyme solution and 0.4 mL of DDW. The mixture was incubated for 20 min at 25 °C. Then 3.5 mL of 5% trichloroacetic acid was added to the mixture and centrifugated at 2,000×g for 5 min. The supernatant was collected and mixed with 4.5 mL of 0.5 M NaOH, the optical density was determined at 440 nm (OD440). One unit of protease activity was defined as the amount of enzyme producing an increase of 0.001 OD440 under the conditions.

Effects of the purified recombinant Rpfs on the growth of R. erythropolis cells

R. erythropolis cells were grown in LB broth at 28 °C with shaking at 150 rpm overnight. The bacterial solution was then inoculated to 500 mL of LB broth and cultured at 28 °C. One mL of the bacterial culture was removed regularly at an interval of 4 h and the cell growth was monitored at a wavelength of 595 nm using an UV-2102PC UV-VIS spectrophotometer (Unico Instrument Co., Ltd., Shanghai, China). To determine the effect of the recombinant Rpfs on the growth of R. erythropolis KB1, the purified proteins were added to the bacterial solutions and cultured under the same conditions. The OD595nm of different groups were detected.

Effect of the purified recombinant Rpfs on the cultural abilities of R. erythropolis cells under cold and starvation conditions

The R. erythropolis cells were grown in LB broth at 28 °C overnight. The bacteria solution was harvested by centrifugation at 5,000 rpm at 4 °C for 10 min and washed three times with normal saline. The washed cells were then inoculated into 500 mL of steriled normal saline and maintained at 4 °C without shaking to induce the VBNC state. A total of 100 μL of the bacteria solution was removed regularly and the culturable cells were estimated by plating 0.1 mL of the samples on LB agar plates.

The recovery of the cold stressed cells was analyzed as reported before. Briefly, five mL of the bacteria solution was removed from the flask which had been kept at 4 °C for more than 1,350 days, and yeast extract was added to the solution at a final concentration of 0.025% (w/v). The bacteria cell mixture was then incubated at 28 °C and the culturable cell counts were estimated by plating 0.1 mL of the samples on LB agar. To determine effect of the recombinant Rpf-1 on the recovery of R. erythropolis cells from the stressed state, the purified recombinant Rpf-1 was added to the stressed cell samples. The mixtures were then incubated at 28 °C and the culturable cells were estimated by plate count method. All experiments were performed in triplicates.

Results

Expression and purification of the recombinant Rpf-1 of R. erythropolis KB1

The rpf-1 gene of R. erythropolis KB1 consisted of 564 bp which encoded a polypeptide of 187 amino acids. The similarities with Rpf-1 of Micrococcus luteus and RpfC of Mycobacterium tuberculosis were 26.11% and 28.24% respectively. The polypeptide contained the Rpf domain of about 70 amino acids, in which a conserved glutamate (Glu51) and two highly conserved cysteine residues (Cys50 and Cys114) were found. But the LysM domain was not found, it did not contain signal sequence either. The rpf-1 gene was inserted into pET-32a (+) to construct an expression vector pET-32a (+)-rpf-1, which was then transformed into E. coli BL21 (DE3) and expressed by introducing with IPTG at 25 °C. The recombinant Rpf-1 was purified by Ni2+-affinity chromatography from the whole-cell lysate preparation. The purified recombinant protein showed a single band with a mass of 37 kDa on SDS-PAGE, which corresponded to the deduced molecular weight of the Rpf-1 (18.80 kDa) and the fusion protein Trx-His-S tag of pET-32a (+) (Fig. 1A). The Western blotting analysis of the purified recombinant protein also showed a specific band of approximately 37 kDa (Fig. 1B). The recombinant Rpf-1 showed muralytic activity when determined with the artificial lysozyme substrate 4-methylumbelliferyl-β-D-N,N′,N″-triacetyl chitotrioside, with a specific activity of 1,760 units mg−1. The muralytic activity was not affected with 0.1 mM of Ca2+, Zn2+ and Co2+, DTT, EDTA, EGTA and serine protease inhibitor PMSF, but 0.1 mM of Zn2+ increased the enzyme activity by almost two fold (Table 3).

SDS-PAGE and Western blotting analysis of the purified recombinant Rpf-1.

Figure 1: SDS-PAGE and Western blotting analysis of the purified recombinant Rpf-1.

(A) SDS-PAGE analysis. (1) Protein molecular weight marker; (2) the purified Rpf-1; (B) Western blotting analysis with three replications.
Table 3:
Effects of metal ions and chemical agents on activities of the purified recombinant Rpf-1 of R. erythropolis KB1.
Chemical reagents Final concentrations (mM) Relative activity (%)
Control 100.00
Zn2+ 0.1 260.83 ± 12.25
Mg2+ 0.1 96.90 ± 3.98
Co2+ 0.1 98.40 ± 2.55
Ca2+ 0.1 110.14 ± 3.59
DTT 0.1 98.88 ± 4.21
PMSF 0.1 109.43 ± 5.07
EDTA 0.1 99.81 ± 3.22
EGTA 0.1 98.49 ± 4.14
DOI: 10.7717/peerj.6951/table-3

Note:

Purified enzyme was pre-incubated with metal ions and biochemical reagents for 30 min. The enzyme activities of the pre-incubated recombinant protein without reagents were taken as 100%. The activities represent the mean of at least two determinations carried out in duplicates, and the value display with the mean ± SD.

Expression and purification of the mutant proteins

Based on the sequence alignments with Rpfs of the other bacteria, including the Rpf of Micrococcus luteus, RpfA-E of Mycobacterium tuberculosis and of S. coelicolor, and lysozyme C from animals, a total of seven highly conserved amino acid residues of the Rpf-1 of R. erythropolis KB1 were selected and substituted with other amino acids. The mutant proteins were expressed in E. coli BL21 (DE3) and purified with Ni2+-affinity chromatography. The purified mutant Rpfs showed single bands with the molecular weight of approximately 37 kDa on SDS-PAGE (Fig. 2), which were as the same size with that of the wild-type Rpf-1, but the muralytic activities of the mutant proteins varied among the different substitutions of amino acid residues (Table 4). For example, substitution of the conserved glutamate in position 51 with alanine (E51A) resulted in partial loss of activity (11.14%). But substitution of the aspartic acid in position 45 with lysine and the glutamate 51 with alanine (D45A+E51K) essentially suppressed the enzymatic activities (84.43%). Substitution of the two cysteines Cys50 and Cys114 (C50G+C114T) inhibited maximally the activities (86.68%). When the glutamine in position 69 was substituted with lysine (Q69K) the activity was greatly decreased (86.11%). However, the substitution of the tryptophan in position 75 with valine (W75V) increased the activity by almost two times.

SDS-PAGE analysis of the mutant and wild-type Rpfs.

Figure 2: SDS-PAGE analysis of the mutant and wild-type Rpfs.

M protein markers; one to seven the purified recombinant Rpfs containing with the different mutations of the conserved amino acid residues of E51A, C50G+C114T, D45A+E51K, T60A, Q69K, and T74A; eight wild-type Rpf-1; 9: pET-32a (+).
Table 4:
The enzymatic activities of the wild-type and mutant Rpfs of R. erythropolis KB1.
Proteins Muralytic activity Protease activity
Specific activity (u mg−1) Percent activity retained (%) Specific activity (u mg−1) Percent activity retained (%)
Rpf-1 1,760 ± 129 100.00 1,630 ± 310 100.00
E51A 1,570 ± 230 88.80 ± 6.60 0 0
D45A+E51K 270 ± 30 15.60 ± 0.60 0 0
C50G+C114T 230 ± 10 13.30 ± 0.40 0 0
T60A 1,700 ± 100 96.70 ± 1.00 1,560 ± 100 98.30 ± 12.80
Q69K 240 ± 20 13.90 ± 0.30 0 0
T74A 1,700 ± 80 96.70 ± 2.20 0 0
W75V 3,430 ± 420 194.40 ± 9.70 0 0
DOI: 10.7717/peerj.6951/table-4

Note:

The activities were determined at three replications and display with the mean ± SD.

Effects of the recombinant Rpfs on the growth of R. erythropolis KB1

The purified recombinant Rpfs of both wild-type and mutant proteins were added to the R. erythropolis KB1 cultures to determine the effect on the growth of the bacteria cells. As seen in Fig. 3, addition of the purified recombinant Rpf-1 efficiently stimulated the growth and obviously reduced the logarithmic phase of R. erythropolis KB1 cells from 24 to 12 h. The growth rate reached the maximum in 48 h, and the promoting effect was correlated with the amount of the Rpf-1. The growth abilities were increased for 301.70% and 382.28% respectively in 48 h by addition of 10 nmol and 100 nmol of the recombinant Rpf-1. The biological activities of the Rpfs were found to be correlated with its muralytic activities. Addition of the recombinant Rpf-1 mutant with W75V increases the growth more effectively when compared with that of the equal amount of the wild type Rpf-1. The growth rates of the bacterial cells added with the wild-type Rpf-1 and mutant Rpf with W75V were 316.18% and 347.22% respectively when compared with that of the control group, with the maximum growths in 48 h. The growth level of the mutant Rpf with E51A group decreased slightly when compared with that of the wild-type group. Addition of the Rpf mutants with the C50G+C114T and Q69K showed less effects on the cell growth (from 105.72–151.45%), with the log phases of about 24 h. The growth rates of the mutants with C50G+C114T, D45A+E51K and the control groups reached to the maximum in 72 h (Table 5).

Growth curves of the R. erythropolis cells in LB medium with addition of different amount of wild-type proteins (A) and different mutant proteins (B).

Figure 3: Growth curves of the R. erythropolis cells in LB medium with addition of different amount of wild-type proteins (A) and different mutant proteins (B).

Table 5:
The growth ability of the R. erythropolis cells with addition of different mutant proteins.
Proteins OD595nm at 48 h Relative ability (%) logarithmic time (h)
Inactivated protein (control group) 1.032 ± 0.057 100.00 24
Wild type Rpf-1 3.263 ± 0.101 316.18 ± 7.70 12
E51A 3.079 ± 0.087 298.35 ± 8.08 12
D45A+E51K 2.556 ± 0.125 247.67 ± 1.57 24
C50G+C114T 1.563 ± 0.033 151.45 ± 5.18 24
T60A 3.194 ± 0.317 309.50 ± 13.66 12
Q69K 1.091 ± 0.163 105.72 ± 9.98 24
T74A 3.192 ± 0.211 309.11 ± 3.37 12
W75V 3.587 ± 0.265 347.22 ± 6.50 12
DOI: 10.7717/peerj.6951/table-5

Note:

The growth ability was determined at three replications and display with the mean ± SD.

Recovery of the R. erythropolis KB1 cells from cold and starved condition by addition of the recombinant Rpfs

The R. erythropolis cells were inoculated into 500 mL of sterile normal saline and maintained at 4 °C without shaking for more than 1,350 days to induce the VBNC state. The stressed cells were then determined for their recover abilities at 28 °C with yeast extract. The effects of recombinant Rpfs on recovery of the R. erythropolis cells from the stressed state were also analyzed. As shown in Table 6 and Fig. 4, the culturable cells of R. erythropolis were decreased from 2.37 × 107 to 8.50 × 103 CFU mL−1 when they were maintained at 4 °C for more than 1,350 days, with 99.96% of the bacteria cells becoming unculturable. Addition of recombinant Rpf-1 noticeably increased the culturable counts of the cold stressed bacteria from 8.50 × 103 to 1.67 × 106 CFU mL−1. Addition of the recombinant mutant Rpf with W75V also increased the recovery more effectively when compared with that of the equal amount of the wild type Rpf-1. The mutant Rpfs with E51A and T74A increased the recovery of the bacteria cells at certain degrees, while the mutant Rpfs with D45A+E51K, C50G+C114T, Q69K and T60A did not show obvious promoting effect on the stressed bacterial cells.

Table 6:
Recovery of the R. erythropolis KB1 cells under cold and starved condition by addition of the recombinant Rpfs.
Proteins Culturable counts CFU mL−1 (×103) Percent recovery retained (%)
Inactivated protein 8.50 ± 0.47 100.00
Rpf-1 1,671.28 ± 52.69 19,688.04 ± 468.75
E51A 1,163.74 ± 19.21 13,720.51 ± 532.66
D45A+E51K 8.80 ± 0.32 103.63 ± 1.96
C50G+C114T 9.40 ± 0.92 110.57 ± 4.48
T60A 10.20 ± 0.98 119.66 ± 4.84
Q69K 8.20 ± 1.02 96.10 ± 7.31
T74A 1,120.02 ± 76.39 13,167.27 ± 170.63
W75V 2,742.15 ± 125.07 32,277.73 ± 313.18
DOI: 10.7717/peerj.6951/table-6

Note:

Values are the means of three replication ± SD.

Recovery curves of R. erythropolis KB1 cells under cold stressed condition by addition of the different mutant Rpfs.

Figure 4: Recovery curves of R. erythropolis KB1 cells under cold stressed condition by addition of the different mutant Rpfs.

Discussion

The Rpf proteins are widely distributed in Gram positive bacteria of the Actinobacteria phylum (Finn et al., 2008). The bacteria of Rhodococcus genus belong to the same order as Micrococcus luteus, Actinomycetales. Four rpf genes were found in R. erythropolis KB1, among which the rpf-1 was one of the small genes with 564 bp, encoding 187 amino acids. The sequence of the Rpf-1 showed 26.11%, 28.22% and 32.24% similarities with Rpf of Micrococcus luteus, RpfC of Mycobacterium tuberculosis and RpfA of S. coelicolor respectively. The protein contained only an Rpf domain of about 70 amino acids. A conservative glutamic acid residue in the active center of the lysozyme-like proteins was found in the position 51 (Glu51), which was in the position 54 of the Rpf protein from Micrococcus luteus. The two highly conserved cysteine residues (Cys50 and Cys114) were also found in the Rpf-1 protein. The catalytic aspartic acid residues (Asp70) of the C-type lysozyme (Gallus gallus) and the catalytic threonine residue (Thr50) of the lysozyme of E. coli (Chauviac et al., 2014) were conserved in the Rpf protein (Asp45 and Thr60). The purified recombinant protein showed a 37 kDa band on SDS-PAGE, which corresponded to the deduced molecular weight of the Rpf-1 and the fusion protein Trx-His-S tag of pET-32a (+). The purified recombinant protein showed muralytic activity. The muralytic activity was not affected with 0.1 mM of Ca2+, Mg2+ and Co2+, DTT, EDTA, EGTA and serine protease inhibitor PMSF, but 0.1 mM of Zn2+ increased the enzyme activity by almost two times. In order to confirm the muralytic activity was produced by the recombinant Rpf-1 protein, we also purified and detected the enzyme activities of the purified Trx-His-S tag protein expressed by the empty vector pET-32a (+) under the same conditions, which showed no muralytic activity and biological activities (Dataset S3).

Mukamolova et al. (2006) reported that substitution of the hypothetical catalytic glutamate in Rpf of Micrococcus luteus by alanine (E54A) or lysine (E54K) essentially suppressed the enzymatic activity. Substitution of either Cys53 or Cys114 separately resulted only in partial loss of the activity, but substitution of both amino acids caused virtually complete inactivation of Rpf. The disulfide bond formation between the conservative cysteine residues of RpfC of Mycobacterium tuberculosis was recognized to support and modulate the catalytic domain conformation during catalysis by using NMR analysis (Maione et al., 2015). In GTP cyclohydrolase I, the thiol groups of two cysteine residues are involved in the chelation of Zn2+ in the active center of the enzyme. Addition of mercaptoethanol or DTT in renaturation buffer did not abolish Rpf activity, suggesting that disulphide bridge formation is not essential for the muralytic activity of the Rpf (Mukamolova et al., 2006).

Our results also showed that substitution of the two cysteines Cys50 and Cys114 (C50G+C114T) inhibited maximally the activities, and replacement both of the Asp45and Glu51 (D45A+E51K) greatly suppressed the enzymatic activities, which was consisted with the Rpf of Micrococcus luteus. But substitution of the conserved Glu51 with alanine (E51A) resulted only in partial loss of activity. According to the modeling and the structural data, residue Gln72 would be accessible within the active site cleft and might potentially be involved in the interaction of Rpf with its substrate. The Q72K replacement reduced muralytic activity against Micrococcus luteus cell walls by about 50.00%. But the muralytic and physiological activities of a protein bearing both Q72K and E54K alterations were not more significantly attenuated than those of the E54K mutant. We found that the Gln69 play very important roles and substitution of Gln69 with lysine (Q69K) resulted in the great decrease of the muralytic activity. Substitution of Trp60 with valine (W60V) had little effect on the enzymatic activity. While substitution of Trp75 with valine (W75V) increased the activity by almost two times, which showed the very important roles of this amino acid in enzymatic activities.

The purified recombinant Rpf-1 could efficiently stimulate the growth of R. erythropolis KB1 and reduced the logarithmic phase from 24 to 12 h. And the mutant Rpfs have different growth promoting effects on R. erythropolis KB1. The promoting effect was showed to be correlated with amounts of the Rpf-1. The biological activities of the Rpf-1 were also found to be correlated with its muralytic activities. The mutant Rpfs with low muralytic activities also decreased growth promoting effects and recovery of the bacteria cells from VBNC state. For example, the biological function of the mutant Rpf with substitutions of Cys50 and Cys114 (C50G+C114T) was greatly reduced when it was added to the R. erythropolis KB1 cells. The highest growth promoting effect was founded in the wild type Rpf-1 and the mutant proteins with Trp75, while the lowest promoting effects were founded among the substitutions of Asp45+Glu51 and Cys50+Cys114.

The purified recombinant Rpf-1 also showed weak protease activities when determined with azocasein. Substitutions of Glu51, Gln69, Thr74, Trp75, Asp45+Glu51, Cys50+Cys114 with other amino acids lost their protease activities. Only the mutant protein with Thr60 retained 95.90% of the protease activity of the wild-type protein. The protease activity did not show obvious correlation with the growth promoting and recovery activities. The mutant of Thr74 still retained the most growth promoting effect, although its protease activity was lost completely. It has been reported that the RpfB of Mycobacterium tuberculosis had a partner RipA (Resuscitation promoting factor interacting protein), which was a proteolytic enzyme capable of cleaving peptide bonds within the peptide chain of peptidoglycan. RipA is supposed to play an important role during the final stage of the cell division (Hett et al., 2007). Since RpfB can hydrolyze the glycoside bond between the residues of N-acetylglucosamine and Nacetyl muramic acid, while RipA is active at the D-Glu-meso-DAP sites of the peptide chain of the peptidoglycan, their interaction should result in a synergistic hydrolysis of the bacterial cell wall. It has also been experimentally shown that the combined effect of RpfB and RipA proteins on the hydrolysis of the fluorescently labeled peptidoglycan was stronger than the effects of individual RpfB and RipA proteins (Squeglia et al., 2014). Similarly, addition of both proteins also demonstrated synergistic effect in the procedure of reactivation of the dormant Mycobacterium smegmatis cells. The function of the protease activity of Rpf of R. erythropolis KB1 remains to be studied further.

Our results from R. erythropolis also showed that muralytic activity of the Rpf-1 was greatly related to its physiological function. But the precisely mechanism was not unclear. Rpf of Micrococcus luteus was initially assigned to the group of bacterial cytokines due to its activity in picomolar concentration (Mukamolova et al., 1998; Hett et al., 2008), but relatively high concentration of Rpf in the cultural medium of Micrococcus luteus and the absence of hypothetical receptors on the cell surface failed to confirm this initial hypothesis. Lytic transglycosylases may be important for the transport of macromolecules across the bacterial cell wall (Koraimann, 2003). It has been hypothesized that Rpf could facilitate the penetration of some compounds required for the resuscitation or growth of the bacteria. It is also possible that resuscitation and growth stimulation are indirect manifestations of the hydrolytic activity of Rpf. Nikitushkin proposed that the enzymatic hydrolysis of peptidoglycan under the influence of Rpf could be important for stimulation of growth and resuscitation of the dormant mycobacteria. They suggested three hypotheses for mechanism of action of the Rpf protein (Nikitushkin, Demina & Kaprelyants, 2016). The Rpf may act as a hydrolase to modify the peptidoglycan in the dormant cells and promote synthesis and growth of the cell wall, and stimulate the beginning of division process in the VBNC cells, because the dormant Micrococcus luteus cells have a significantly thickened cell wall. The second hypothesis is based on the ability of recombinant Rpf to disperse bacterial aggregations, which seems due to its hydrolytic activity (Voloshin & Kapreliants, 2005). It was found that aggregation of Micrococcus luteus cells was important for initiation of the growth of the cells at lag-phase as well as during the initial steps of reactivation of Mycobacterium tuberculosis. The Rpf proteins can participate in dispersion of these aggregates before the beginning of cell division. The third, Rpf can release low molecular weight molecules transmitting the signal onto the neighboring cells and acting on a surface cellular receptor. Muropeptides are considered as potential signaling molecules involved in organization of molecular parasite-host cascades (Nikitushkin, Demina & Kaprelyants, 2011). Disintegration of bacterial aggregations under the influence of Rpf can precede the subsequent generation of muropeptides triggering the resuscitation (Shleeva et al., 2003; Boneca, 2005). Because the resuscitation of the dormant bacterial forms is a complex phenomenon and includes several stages, whether the mechanisms of the resuscitation promoting of the dormant cells is same with that of the growth promoting of the normal cells remained to be discovered.

Conclusion

We constructed the recombinant plasmid BL21-pET-32(a)-rpf-1 of the rpf-1 gene of Rhodococcus erythropolis KB1, and used the site-directed mutagenesis technique to rpf-1 gene sequence muralytic activity related amino acids Asp45, Cys50, Glu51, Thr60, Gln69, Thr74, Trp75 and Cys114, several different Rpf amino acid mutant plasmids were constructed, and they were efficiently expressed and purified in E. coli. The molecular weight of the expressed protein was 37 kDa by SDS-PAGE electrophoresis.

The muralytic activity of the recombinant Rpf protein was 1,760 U/mg and the protease activity was 1,634 U/mg. 0.1 mM Zn2+ can increase muralytic activity, but Ca2+, Mg2+, Co2+, DTT, EDTA, PMSF and so on have little effect on muralytic activity. The purified recombinant Rpf protein promoted the growth of R. erythropolis KB1 and promoted the resuscitation of VBNC state KB1 cells. The resuscitation effect was more significant with the increase of recombinant Rpf protein concentration.

It was found that the muralytic activity of Rpf-1 changed after mutation, and the muralytic activity of C50G+C114T mutant lost by 86.68%, D45A+E51K mutant lost by 84.43%, Q69K mutant lost by 86.11%, and E51A mutant lost by 11.14%. While the muralytic activity of the W75V mutant increased by 94.45%. The growth-promoting and revitalizing effects of the C50G+C114T mutant disappeared, and the W75V mutant significantly increased the growth of R. erythropolis cells and the recovery of non-culturable cells. The growth-promoting and resuscitation effects of Rpf are closely related to its muralytic activity.

Supplemental Information

rpf-1 sequence.

DOI: 10.7717/peerj.6951/supp-1

The original data for enzyme activity determination.

DOI: 10.7717/peerj.6951/supp-2

pET-32(a) protein.

DOI: 10.7717/peerj.6951/supp-3
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