Abstract
Hemerythrin-like proteins are oxygen-carrying non-heme di-iron binding proteins and their functions have effect on oxidation-reduction regulation and antibiotic resistance. Recent studies using bioinformatic analyses suggest that multiple hemerythrin-like protein coding sequences might have been acquired by lateral gene transfer and the number of hemerythrin-like proteins varies amongst different species. Mycobacterium smegmatis contains three hemerythrin-like proteins, MSMEG_3312, MSMEG_2415 and MSMEG_6212. In this study, we have systematically analyzed all three hemerythrin-like proteins in M. smegmatis and our results identified and characterized two functional classes: MSMEG_2415 plays an important role in H2O2 susceptibility and MSMEG_3312 and MSMEG_6212 are associated with erythromycin susceptibility. Phylogenetic analysis indicated that these three proteins have different evolutionary origins, possibly explaining their different physiological functions. Here, combined with biological and phylogenetic analyses, our results provide new insights into the evolutionary divergence of the hemerythrin-like proteins in M. smegmatis.
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Introduction
Hemerythrin-like proteins are non-heme, di-iron and O2-binding proteins that are ubiquitous from bacteria to mammals and function in oxygen storage and transport. Bioinformatic evidence indicates that prokaryotic genomes collectively encode hundreds of hemerythrin-like proteins1,2,3. Based on the structural characterization of hemerythrin-like proteins, their functions are correlated with redox regulation in bacteria. One study showed that the hemerythrin-like protein in Methylococcus capsulatus functions as an oxygen-carrier4, while the hemerythrin-like protein in Campylobacter jejuni acts to protect iron-sulfur cluster enzymes from oxidative damage5. Although hundreds of hemerythrin-like proteins have been predicted in bacteria, studies on the biological functions of hemerythrin-like proteins are few. One study showed that the multi domain protein VcBhr-DGC (with a hemerythrin domain and a diguanylate cyclase GGDEF domain) functions as a regulatory oxygen sensor for switching between reducing or anaerobic environments in Vibrio cholerae6. This is the first demonstration of a regulatory function for a hemerythrin domain and hints that hemerythrin-like proteins might have other unannotated functions.
The number of hemerythrin-like proteins differs from strain to strain and this variation is predicted to be related to differences in the oxygen concentration of the environment2. A number of hemerythrin-like proteins have been found in magnetotactic bacteria and their functions are predicted to be correlated with bacterial physiological conditions (survival under certain oxygen tensions or high concentrations of iron in vivo)2. However, the functions predicted for many hemerythrin-like proteins are simply based on their molecular sequences. The functions of multiple hemerythrin-like proteins in one organism have not previously been identified. Multiple homologs are common in bacteria and understanding the functional divergence of paralogs in one organism is a challenge in biology, as the multiplicity of genes for hemerythrin-like proteins is an obstacle to study their distinctive individual functions.
The genus Mycobacterium is comprised of a number of Gram-positive bacteria, including both pathogens, such as Mycobacterium tuberculosis and Mycobacterium leprae and nonpathogens, such as the soil microorganism Mycobacterium smegmatis, which is commonly used in laboratory experiments as a model organism for M. tuberculosis7. Mycobacterium is capable to survive under environmental stresses, such as oxidative stress, hypoxia and exposure to multiple antimicrobial agents8,9. The identification of undefined proteins and pathways involved into oxidative stress and antimicrobial response might give new insights to understanding the pathogenesis of M. tuberculosis and response to antibiotic exposure in mycobacteria10,11. Mycobacteria are predicted to contain many hemerythrin-like proteins. For example, M. tuberculosis (NC_000962.3) has been predicted to contain three hemerythrin-like proteins. Five genes have been predicted to encode hemerythrin-like proteins in Mycobacterium avium (NC_008595). M. smegmatis possesses three hemerythrin-like proteins, MSMEG_3312, MSMEG_2415 and MSMEG_6212. In this study, we sequentially overexpressed and deleted each of the three genes encoding hemerythrin-like proteins in M. smegmatis. We showed that MSMEG_6212 and MSMEG_3312 modulated erythromycin susceptibility and that the resistance of msmeg_3312 and the msmeg_6212 double-knockout strain, mc2155:Δ3312-6212, was similar to single-knockout strains mc2155:Δ3312 and mc2155:Δ6212. MSMEG_2415 plays a major role in H2O2 susceptibility but not in erythromycin susceptibility. MSMEG_3312 exhibited only a mild H2O2 response in mc2155:Δ2415.
In addition, MSMEG_6212 was not associated with H2O2 susceptibility; overexpression of msmeg_6212 in both mc2155:Δ2415 and the mc2155:Δ2415-3312 double-knockout strain did not influence H2O2 susceptibility relative to the corresponding parental strains. Phylogenetic analysis of bacterial hemerythrin-like proteins showed that three mycobacterial hemerythrin-like proteins are likely derived from different lineages, possibly explaining their different biological functions. Here, combined with analyses of biological function and phylogenetic analyses our results provide new insights into the evolutionary divergence of the hemerythrin-like proteins in M. smegmatis.
Results
MSMEG_6212 is associated with erythromycin susceptibility
To investigate whether the three M. smegmatis hemerythrin-like proteins, MSMEG_3312, MSMEG_2415 and MSMEG_6212, have distinct or overlapping functions, we used a series of strains overexpression individual genes and knockout mutants. The specialized transduction strategy for the sequential deletion of the three genes encoding hemerythrin-like proteins in M. smegmatis and the overexpression of individual genes encoding hemerythrin-like proteins is shown in Fig. 1. We have previously shown that MSMEG_2415 is involved in the SigF-mediated H2O2 pathway and that MSMEG_3312 is associated with erythromycin susceptibility12,13. Here, to characterize the function of MSMEG_6212, we constructed a msmeg_6212 knockout strain (mc2155:Δ6212). Knockout mutants were confirmed by PCR analysis (Fig. 2B). A msmeg_6212 gene fragment was not amplified and no msmeg_6212 mRNA was detected in an assay of its mRNA expression (data not shown). The msmeg_6212 mutant, mc2155:Δ6212, was complemented with a single integrated copy using pMV361-6212. The constructed M. smegmatis mutant strain mc2155:Δ6212 was initially tested for growth in rich 7H9 medium and defined Sauton medium. Growth of mc2155:Δ6212 appeared to have no discernable phenotypic difference from the wild type strain mc2155, in either rich (Fig. 3A) or defined media (data not shown). These results indicate that msmeg_6212, like the previous investigated msmeg_3312 and msmeg_2415, is not an essential gene for M. smegmatis growth in either 7H9 rich medium or Sauton defined medium. In order to characterize the potential roles of MSMEG_6212, we compared the minimum inhibitory concentrations (MICs) of eleven antibiotic drugs and H2O2 in the msmeg_6212 knockout strain mc2155:Δ6212 and wild type strain mc2155 (Table S1). Surprisingly, a difference in MIC values was detected only for the macrolides erythromycin and azithromycin (AZM) (Table S1). To clarify the effect of MSMEG_6212 on erythromycin susceptibility, we performed drug exposure experiments to compare the growth rates of wild-type strain mc2155, msmeg_6212 knockout strain mc2155:Δ6212 and the complemented strain pMV361-6212/mc2155:Δ6212 in the presence of 1.56mg/L erythromycin (Fig. 3B). The strain mc2155:Δ6212 showed a growth advantage compared with wild type mc2155, which was partially reversed in the complemented strain pMV361-6212/ mc2155:Δ6212 in the presence of erythromycin (Fig. 3B). Furthermore, we compared the survival of various M. smegmatis strains every few hours under treatment with 31.2 mg/L (10x MIC) erythromycin. As shown in Fig. 3C and Fig. S1, the percentage survival of mc2155:Δ6212 was greater than that of wild type mc2155, whereas the complemented strain pMV361-6212/mc2155:Δ6212 did not grow well and its survival was partially reversed to that of the wild-type. As overexpression of MSMEG_6212 increased susceptibility to erythromycin, we used 15.6 mg/L (5 × MIC) to perform the killing experiment: overexpression of msmeg_6212 caused greater susceptibility to erythromycin and lower survival than in wild type mc2155 under the same treatment (Fig. 3D and Fig. S1). Taken together, these results show that, like MSMEG_3312, MSMEG_6212 negatively impacts erythromycin resistance.
Both MSMEG_3312 and MSMEG_6212 affect MtrA-mediated erythromycin susceptibility and MSMEG_3312, but not MSMEG_6212, has a redundant role in the H2O2 response
Both mc2155:Δ3312 and mc2155:Δ6212 mutant cells were found to be slightly resistant than the wild type strain mc2155 under erythromycin treatment (Table S1). When we compared the mRNA levels of transcriptional regulators MtrA and WhiB7, known to affect erythromycin susceptibility14,15,16, among mc2155, mc2155:Δ6212 and mc2155:Δ3312, we found no difference in the level of WhiB7 mRNA between the mc2155, mc2155:Δ6212 and mc2155:Δ3312 strains with or without erythromycin treatment (data not shown). This result suggests that WhiB7 responds to erythromycin independent of MSMEG_3312 and MSMEG_6212. In contrast, knockout of msmeg_3312 led to a 2.19 ± 0.07 fold increase in the mRNA level of mtrA relative to wild type mc2155 and a 1.94 ± 0.05 fold increase in mtrA mRNA in mc2155:Δ6212 (Fig. 4A,D). These increases were partially reversed in the complemented strains pMV361-3312/mc2155:Δ3312 and pMV361-6212/mc2155:Δ6212 (Fig. 4A,D). These results suggest that both msmeg_3312 and msmeg_6212 affect the mRNA level of mtrA. We then examined the influence of MSMEG_3312/MSMEG_6212 on the MtrA-mediated erythromycin response pathway. We compared the mRNA level of mtrA between mc2155, mc2155:Δ6212 and mc2155:Δ3312 after treatment with 3.125 mg/L erythromycin for 30 min. As shown in Fig. 4A,D, mtrA mRNA was induced by erythromycin in mc2155, while induction of mtrA mRNA by erythromycin was not detected in either mc2155:Δ6212 or mc2155:Δ3312. Induction of mtrA mRNA was restored in the complemented strains pMV361-3312/mc2155:Δ3312 and pMV361-6212/mc2155:Δ6212. These results show that MSMEG_6212 and MSMEG_3312 are required for the mtrA-mediated response to erythromycin.
In addition, we measured changes in the mRNA levels of MtrA regulon genes msmeg_1875 (encoding sensor histidine kinase MtrB) and msmeg_0637 (encoding iron-sulfur binding oxidoreductase)17 in response to erythromycin treatment in mc2155, mc2155:Δ6212, mc2155:Δ3312 and complemented strains pMV361-3312/mc2155:Δ3312 and pMV361-6212/mc2155:Δ6212. The level of msmeg_1875 and msmeg_0637 mRNA increased in mc2155 in response to erythromycin, but induction of msmeg_1875 and msmeg_0637 was abrogated in both mc2155:Δ6212 and mc2155:Δ3312 in response to erythromycin (Fig. 4B,C,E,F). Correspondingly, induction of msmeg_1875 and msmeg_0637 was restored in both the complemented strain pMV361-3312/ mc2155:Δ3312 and pMV361-6212/mc2155:Δ6212 in response to erythromycin (Fig. 4B,C,E,F). Taken together, those results indicate that both MSMEG_6212 and MSMEG_3312 are required for the MtrA-mediated erythromycin response. To characterize the relationship between MSMEG_3312 and MSMEG_6212, we constructed a double knockout mutant strain mc2155:Δ3312-6212 and assayed its resistance to erythromycin. As shown in Figs 5A and 6A, the resistance of the double-knockout mutant mc2155:Δ3312-6212 to erythromycin appeared to be comparable to mc2155:Δ3312. Moreover, a significant increase of mtrA mRNA in mc2155 was observed in response to erythromycin (Fig. 5B), while no significant changes of mRNA level in mc2155:Δ3312-6212 was observed in response to erythromycin (Fig. 5B)
The unchanged level of erythromycin resistance in the double-knockout mutant strain mc2155:Δ3312-6212 suggested that there was no cumulative effect in the double-knockout mutant mc2155:Δ3312-6212. Our results thus indicate that MSMEG_3312 and MSMEG_6212 fall in the same pathway. To determine the order of MSMEG_3312 and MSMEG_6212, we analyzed the level of msmeg_6212 mRNA expression in mc2155:Δ3312 and of msmeg_3312 expression in mc2155:Δ6212. As shown in Fig. 5C, the level of msmeg_6212 mRNA decreased 4.86 ± 0.70 fold in mc2155:Δ3312 compared with the wild type strain mc2155, while the level of msmeg_3312 mRNA was not significantly different in the msmeg_6212 knockout strain mc2155:Δ6212 (Fig. 5D). We thus reason that MSMEG_3312 is upstream of MSMEG_6212. Knockout of msmeg_3312 decreased the level of msmeg_6212 mRNA and thus dysregulated mtrA mRNA.
As the remaining M. smegmatis hemerythrin-like protein MSMEG_2415 is involved in the H2O2 stress response13, we also examined the effects of MSMEG_3312 and MSMEG_6212 on H2O2 susceptibility. Cells of strain mc2155:Δ3312 were treated with 5 mM H2O2 for 3 hour then spotted onto 7H10 medium. No growth defects were observed after H2O2 treatment relative to the wild type strain mc2155 (Fig. 5E). In addition, no differences in growth were observed between the wild type strain mc2155 and the msmeg_3312 overexpression strain after H2O2 treatment (Fig. 5E). Increased susceptibility to H2O2 was detected only when msmeg_3312 was overexpressed in mc2155:Δ2415 (Fig. 5E). In contrast, we did not detect any growth difference between the wild type strain mc2155, the msmeg_6212 knockout strain mc2155:Δ6212 and the msmeg_6212 overexpression strain pMV261-6212/mc2155 after H2O2 treatment. Moreover, overexpression MSMEG_6212 in mc2155:Δ2415 and the mc2155:Δ2415-3312 double-knockout strain did not influence H2O2 resistance relative to the corresponding parental strains (Fig. S2A). As MSMEG_2415 is involved in the SigF-mediated H2O2 response13, we also measured changes in the mRNA level of sigF and SigF regulon components msmeg_1782 (encoding oxidoreducatse) and msmeg_4753 (encoding antioxidant) in mc2155:Δ6212 and mc2155:Δ3312 relative to that in mc2155. Consistent with results for H2O2 survival assays, there were no significant changes in the levels of sigF, msmeg_1782 and msmeg_4753 mRNA (Fig. S2B). Taken together, our results show that MSMEG_3312 has no effect on the H2O2 response in the presence of MSMEG_2415 and that MSMEG_3312 contributes to the mild H2O2 susceptibility in mc2155:Δ2415. MSMEG_6212 is not involved in the H2O2 response.
MSMEG_2415 is not associated with erythromycin susceptibility
To further examine the role of MSMEG_2415 in erythromycin susceptibility, we overexpressed msmeg_2415 in the mc2155:Δ3312-6212 strain and examined its susceptibility to erythromycin. We incubated 15.6 mg/L erythromycin with the msmeg_3312 knockout strain harboring a pMV261 empty vector (pMV261/ mc2155:Δ3312-6212) or the msmeg_3312 knockout strain harboring pMV261-2415 (pMV261-2415/ mc2155:Δ3312-6212) for 3h and then spotted the cells on 7H10 media. We did not detect any difference in growth between the pMV261/ mc2155:Δ3312-6212 strain and the pMV261-2415/ mc2155:Δ3312-6212 strain under drug treatment (Fig. S3A). Moreover, no differences in growth were observed between the msmeg_3312 knockout strain (mc2155:Δ3312) and the msmeg_3312 and msmeg_2415 double-knockout strain (mc2155:Δ3312-2415) when treated with erythromycin (Fig. S3A). We also measured the level of mtrA mRNA in mc2155:Δ2415, relative to that in mc2155. Unlike MSMEG_3312 and MSMEG_6212, knockout of msmeg_2415 did not affect the level of mtrA mRNA (Fig. S3B) and no change in the mRNA levels of MtrA regulon genes msmeg_1875 and msmeg_0637 was detected. Taken together, these results suggest that MSMEG_2415 is not associated with erythromycin susceptibility.
The triple hemerythrin-like gene knockout strain mc2155:Δ3312-6212-2415 exhibits comparable erythromycin susceptibility to that of mc2155:Δ3312 and comparable H2O2 susceptibility to that of mc2155:Δ2415
We next constructed a triple hemerythrin-like proteins knockout strain, mc2155:Δ3312-6212-2415 and confirmed it by PCR (Fig. S4). We also compared erythromycin susceptibility and H2O2 susceptibility in mc2155:Δ3312-6212-2415 with that in wild type mc2155, mc2155:Δ3312-6212, and mc2155:Δ2415. The erythromycin susceptibility of the triple mutant strain mc2155:Δ3312-6212-2415 appeared to be indistinguishable from that of the double mutant strain (mc2155:Δ3312-6212) (Fig. 6A). The level of mtrA mRNA and that of its regulon (msmeg_1854 and msmeg_0637) in the triple mutant were comparable to that in mc2155:Δ3312 (Fig. 6B). As expected, the H2O2 susceptibility of mc2155:Δ3312-6212-2415 was comparable to that of mutant mc2155:Δ2415 (Fig. 6C). The level of sigF and SigF regulon (msmeg_4753 and msmeg_1782) mRNA in Δ3312-6212-2415 was comparable to that in mc2155:Δ2415 (Fig. 6D).
Phylogenetic analysis of the hemerythrin-like proteins of M. smegmatis reveals multiple origins and distinct physiological adaptations
The above results demonstrated that the three hemerythrin-like proteins have different roles: MSMEG_3312 is associated with both erythromycin and H2O2 susceptibility, while MSMEG_2415 has a major effect on H2O2 susceptibility and MSMEG_6212 has a role in erythromycin susceptibility. Phylogenetic analysis can help to explain the protein evolution of physiological adaptations3. We thus used phylogenetic analysis to gain new insights into the evolution of the M. smegmatis hemerythrin-like proteins. We first retrieved the sequences of the closest neighbors (top 100BLAST hits) of M. smegmatis MSMEG_6212, MSMEG_2415 and MSMEG_3312 from the UniRef 90 dataset of UniProt18, removing any duplicate sequences and then constructed a boots strapped (1000 replicate) phylogenetic relationships among the resulting 84 downloaded sequences to obtain a unrooted neighbor-joining tree (NJ) using MEGA 5.1. The used protein sequences are listed in supplemental Table S2. Interestingly, MSMEG_3312, MSMEG_2415 and MSMEG_6212 are present in 3 different clades (Fig. 7). All the proteins in the MSMEG_2415 cluster belong to the genus Mycobacterium, while those in the MSMEG_3312 cluster were derived from Mycobacterium, Rhodococcus and Sciscionellas. A large portion of the hemerythrin-like proteins belonging to the Streptomyces, Saccharomonospora and Amycolatopsis were present in the MSMEG_6212 cluster, suggesting that msmeg_6212 may have an independent origin. Taken together, this phylogenetic data suggests that the origins and evolution of MSMEG_3312, MSMEG_2415 and MSMEG_6212 are different. Differences in origins may explain the differences in their physiological functions.
Discussion
In this study, we have systematically evaluated the roles of multiple hemerythrin-like proteins (MSMEG_3312, MSMEG_2415 and MSMEG_6212) on erythromycin and H2O2 susceptibility in M. smegmatis. This study is the first to analyze the function and relationship between multiple hemerythrin-like proteins within one organism.
We showed that MSMEG_6212 is associated with erythromycin susceptibility but not susceptibility to the other drugs tested, including isoniazid (INH), ciprofloxacin (CIP) and rifampin (RFP) (Table S1). Erythromycin is a macrolide, a class of molecules which targets the 50S ribosome and inhibits bacterial protein synthesis19. WhiB7, a transcription factor for the Fe-S cluster, has been shown to be involved in inherent resistance to erythromycin, but not INH20. The MtrA-MtrB system has been confirmed as an essential two-component system in mycobacteria21,22. Several previous studies have shown that MtrA modulates M. tuberculosis proliferation by binding to the dnaA promoter23,24. MrtA has also been shown to be related to antimicrobial resistance in mycobacteria15,16,17,25. MtrA has been predicted to target 264 genes, including ABC transporters, ribosomal proteins and a methyltransferase, all of which are related to drug resistance17. MSMEG_3312 and MSMEG_6212 are required for MtrA-mediated erythromycin susceptibility, but not for WhiB7-mediated erythromycin resistance (Fig. 4). Our results are the first to show that MSMEG_3312 and MSMEG_6212 impact the mRNA level of MtrA and thus affect its regulon, causing drug resistance. It will be interesting to explore the relationship between the WhiB7-mediated and MSMEG_6212-involved-MtrA-mediated pathways in erythromycin susceptibility.
Multiple homologs are common in mycobacteria. For example, M. tuberculosis contains five resuscitation-promoting factor (Rpf)-like proteins and ten universal stress proteins (USPs)26,27,28. It was not possible to determine the exact function of USP proteins Rv1996, Rv2005c, Rv2026c and Rv2028c by knockout of individual usp genes, suggesting that USP proteins in M. tuberculosis have redundant functions26. Similarly, reports on the M. tuberculosis rpf genes indicate that they have redundant roles27. M. smegmatis possesses three hemerythrin-like proteins, MSMEG_3312, MSMEG_2415 and MSMEG_621229. We defined the hierarchy of biological functions among hemerythrin-like proteins (Fig. 8). The double-knockout mutant strain mc2155:Δ3312-6212 showed comparable erythromycin resistance to that of the single-knockout mutant mc2155:Δ3312 (Figs 5A and 6A). In addition, msmeg_3312 influenced the level of msmeg_6212 mRNA, but not vice versa (Fig 5C,D). We thus reasoned that MSMEG_3312 and MSMEG_6212 are in same pathway for erythromycin susceptibility mediated by MtrA. Knockout of the msmeg_3312 gene leads to a decrease in the level of msmeg_6212 mRNA and upregulation of MtrA expression (Fig. 4A). Similarly, knockout of msmeg_6212 disrupted the regulation of MtrA (Fig. 4D). MSMEG_2415 has previously been shown to be important for H2O2 susceptibility13. The contribution of MSMEG_3312 was minor; the overexpression of MSMEG_3312 only slightly increased H2O2 susceptibility in mc2155:Δ2415 (Fig. 5E). Taken together, these results indicate that MSMEG_2415 and MSMEG_6212 are exclusively associated with H2O2 susceptibility and erythromycin susceptibility, respectively, while MSMEG_3312 is associated with both H2O2 and erythromycin susceptibility (Fig. 8).
Phylogenetic analysis of respiratory hemerythrin-like proteins and hemocyanins shows that the distribution of analyzed respiratory proteins may partially explain physiological adaptions3. Comparative genomic analysis of M. indicus prannii suggested that multiple hemerythrin-like protein coding sequences might have been acquired by lateral gene transfer and these proteins help mycobacteria survival in different oxygen concentrations of the environment30. In this study, we showed that the three mycobacterial hemerythrin-like proteins have different functions and that phylogenetic analysis of hemerythrin-like proteins in M. smegmatis indicates that the three proteins are distributed within three distinct clades (Fig. 7). Interestingly, all the proteins in the MSMEG_2415 cluster belong to the genus Mycobacterium, suggesting that MSMEG_2415-like hemerythrin proteins are more conserved in mycobacteria. The role of MSMEG_2415 in H2O2 susceptibility might be an inherent function in Mycobacterium. In contrast, some of the hemerythrin-like proteins in the MSMEG_6212 cluster belong to the genus Mycobacterium, and several belong to Saccharomonospora and Amycolatopsis, suggesting that msmeg_6212 might be of independent origin. Strikingly, the MSMEG_3312 cluster included representatives of the genera Streptomyces, Saccharomonospora, Saccharopolyspora, Nocardiopsis, and Amycolatopsisand a few Mycobacterium species. Of interest, Saccharopolyspora erythraea, an environmental soil actinomycete, can produce the natural antimicrobial agent erythromycin31. Soil is a highly complex and competitive environment, in which interactions between diverse organisms occur. Evolutionary pressures in soil are high due to competition for resources have significant selective advantages over competitors. M. smegmatis is also an environmental soil strain, the acquisition of antimicrobial-related regulatory proteins (MSMEG_3312 and MSMEG_6212) might have a selective advantage facilitating its survival. This independent phylogenetic clade may explain the different roles of MSMEG_2415 (in H2O2 susceptibility), MSMEG_6212 (in erythromycin susceptibility) and MSMEG_3312 (in both erythromycin and H2O2 susceptibility). Further work to identify the functions of M. tuberculosis hemerythrin-like proteins and a comparison of their hemerythrin-like protein with those in M. smegmatis would provide insight into the evolution and selection of virulence and antibiotic susceptibility.
In summary, we have systematically analyzed all three hemerythrin-like proteins in M. smegmatis and our results indicated that the three members of this protein family possess overlapping and distinct functions: MSMEG_2415 plays an important role in H2O2 susceptibility and MSMEG_3312 and MSMEG_6212 can modulate erythromycin resistance. Phylogenetic analysis indicated that these three proteins have different evolutionary origins, possibly explaining their different physiological functions. The functional and phylogenetic analyses of hemerythrin-like proteins in M. smegmatis would provide insight into the evolutionary selection of antimicrobial resistant traits.
Materials and Methods
Reagents and Media
As previously described13, the 7H9 liquid culture medium for M. smegmatis strains consisted of Middlebrook 7H9 medium (Becton Dickinson, Franklin Lakes, New Jersey, U.S.) supplemented with 10% ADS (5% (w/v) bovine serum albumin fraction V, 2% (w/v) dextrose and 8.1% (w/v) NaCl), 0.5% (v/v) glycerol and 0.05% (v/v) Tween80. 7H10 media containing Middlebrook 7H10 medium (Becton Dickinson, Franklin Lakes, New Jersey, U.S.), 10% ADS and 0.5% (v/v) glycerol was used for solid culture to examine growth status. Hygromycin (Hyg) was purchased from GenView, erythromycin (EM) from Merck, hydrogen peroxide (H2O2) and kanamycin (Kan) from Sigma. Restriction enzymes such as Van91I, AlwNI, MfeI and PacI were purchased from Fermentas. T4 DNA ligase and Q5 DNA polymerase were purchased from New England Biolabs.
Construction of knockout hemerythrin-like protein MSMEG_6212 strain and corresponding complemented and overexpression strains
Mycobacteriophage-based specialized transduction was used to generate hemerythrin-like gene knockout strains13,32. Briefly, the 5’ and 3’ sequences flanking the msmeg_6212 gene were amplified from M. smegmatis genomic DNA using the following PCR conditions: 98 °C for 3 min, 32 cycles of 98 °C for 30 s, 60 °C for 30 s and 72 °C for 30 s and 72 °C for 10 min. The primers for msmeg_6212 knockout are listed in Supplemental Table S3 and the corresponding positions are indicated in Fig. 2A. The primers used had a PflMI site on the 5’ end to allow insertion into the pYUB1471 vector and the temperature sensitive phage phAE159 and pYUB1471-6212 were then digested with PacI and ligated using T4 DNA ligase to create a shuttle plasmid. MaxPlax packaging extract (Epicenter Biotechnologies, USA) was used for phage packaging and transformed into E. coli HB101 cells according to the manufacturer’s instructions. Successful phasmids were transduced into M. smegmatis strain mc2155 at 30 °C, which allowed replication and amplified high titer phages. Transduction into M. smegmatis was then performed at 37 °C with the high titer lysate at an MOI of 10:1. Gene knockout was confirmed by PCR screening using primers outside the upstream and downstream flanking regions and the corresponding vector primers. Complemented strain of msmeg_6212 was constructed by cloning the full-length genes into the integrating vector pMV361 to yield pMV361-6212/ mc2155:Δ6212.
To obtain the msmeg_3312 and msmeg_6212 double knockout strain, we unmarked the mc2155:Δ3312 strain used in previous study12 according to a previously published method33. Briefly, plasmid pJH532 was transformed into the mc2155:Δ3312 strain by electroporation and plated onto 7H10 media containing 25 mg/L kanamycin. Kanamycin resistant colonies were screened by a pick-and-patch method for hygromycin sensitivity, streaked on 7H10 media alone and on 7H10 media with 50 mg/L hygromycin. The hygromycin-sensitive colonies were then plated onto 7H10 media with 5% sucrose. The selected colonies were spread on 7H10 media supplemented with 5% sucrose to obtain kanShygS colonies. The unmarked mc2155:Δ3312 strain was used for construction of the msmeg_6212 knockout strain, yielding the mc2155:Δ3312-6212 double-knockout strain. The triple mutant mc2155:Δ3312-6212-2415 was generated from the double-knockout progenitor mc2155:Δ3312-6212.
To overexpress hemerythrin-like proteins, the corresponding full-length coding genes, msmeg_3312, msmeg_2415 and msmeg_6212, were sub-cloned into pMV261 to yield pMV261-3312, pMV261-2415 and pMV261-6212 for transformation into the corresponding M. smegmatis strains (All strains used in this study are listed in Table S4).
Drug and H2O2 susceptibility testing
The killing curve under erythromycin treatment was determined as indicated. Logarithmic phase cultures (OD600 ~ 0.3) were treated with erythromycin at the indicated concentrations, aliquots (~50 μl) were removed at the indicated times and spread onto 7H10 medium. Colony Forming Units (CFUs) were counted after 3 days of incubation. Experiments were repeated at least 3 times.
Survival under erythromycin and H2O2 treatment was determined as indicated. Logarithmic phase cultures (OD600 ~ 0.3) were treated with erythromycin (15.6 mg/L) or H2O2 (5 mM) at the indicated concentrations for 3 h, serially diluted (1:10) and spotted (3 μl) onto 7H10 medium. Photographs were taken after three days of incubation at 37 °C. Experiments were repeated at least 3 times.
Quantitative real-time PCR analysis
Logarithmic phase (OD600 ~ 0.3)cultures of the corresponding M. smegmatis strains treated with 0 or 3.125 mg/L erythromycin for 30 min were collected. After resuspending in TRIzol (Invitrogen), RNA was purified according to the manufacturer’s instructions. The SuperScriptTM III First-Strand Synthesis System (Invitrogen) was used to synthesize the corresponding cDNA. qRT-PCR was performed on a Bio-Rad iCycler. M. smegmatis rpoD (the coding sequencing of RNA polymerase sigma factor SigA) was used to normalize gene expression. The relative ratio was calculated using the 2−ΔΔCT method34. Experiments were repeated at least 3 times. Primers used for qRT-PCR are listed in Table S3.
Statistical method
Statistical analysis was performed with GraphPad Prism 5.0c software. Significant differences in the data were determined using t-tests. P values of <0.05 were considered significant.
Additional Information
How to cite this article: Li, X. et al. Differential roles of the hemerythrin-like proteins of Mycobacterium smegmatis in hydrogen peroxide and erythromycin susceptibility. Sci. Rep. 5, 16130; doi: 10.1038/srep16130 (2015).
References
Bailly, X., Vanin, S., Chabasse, C., Mizuguchi, K. & Vinogradov, S. N. A phylogenomic profile of hemerythrins, the nonheme diiron binding respiratory proteins. BMC. Evol. Biol 8, 244 (2008).
French, C. E., Bell, J. M. & Ward, F. B. Diversity and distribution of hemerythrin-like proteins in prokaryotes. FEMS. Microbiol. Lett 279, 131–145 (2008).
Martin-Duran, J. M., de Mendoza, A., Sebe-Pedros, A., Ruiz-Trillo, I. & Hejnol, A. A broad genomic survey reveals multiple origins and frequent losses in the evolution of respiratory hemerythrins and hemocyanins. Genome. Biol. Evol 5, 1435–1442 (2013).
Chen, K. H. et al. Bacteriohemerythrin bolsters the activity of the particulate methane monooxygenase (pMMO) in Methylococcus capsulatus (Bath). J Inorg. Biochem 111, 10–17 (2012).
Kendall, J. J., Barrero-Tobon, A. M., Hendrixson, D. R. & Kelly, D. J. Hemerythrins in the microaerophilic bacterium Campylobacter jejuni help protect key iron-sulphur cluster enzymes from oxidative damage. Environ. Microbiol 16, 1105–1121 (2014).
Schaller, R. A., Ali, S. K., Klose, K. E. & Kurtz, D. M., Jr. A bacterial hemerythrin domain regulates the activity of a Vibrio cholerae diguanylate cyclase. Biochemistry 51, 8563–8570 (2012).
Tyagi, J. S. & Sharma, D. Mycobacterium smegmatis and tuberculosis. Trends. in Microbiology 10, 68–69 (2002).
Hingley-Wilson, S. M., Sambandamurthy, V. K. & Jacobs, W. R., Jr. Survival perspectives from the world’s most successful pathogen, Mycobacterium tuberculosis. Nat. Immunol 4, 949–955 (2003).
Zahrt, T. C. & Deretic, V. Reactive nitrogen and oxygen intermediates and bacterial defenses: unusual adaptations in Mycobacterium tuberculosis. Antioxid. Redox. Signal 4, 141–159 (2002).
McKinney, J. D. In vivo veritas: the search for TB drug targets goes live. Nat. Med 6, 1330–1333 (2000).
Li, X. et al. The gain of hydrogen peroxide resistance benefits growth fitness in mycobacteria under stress. Protein Cell 5, 182–185 (2014).
Huang, L., Hu, X., Tao, J. & Mi, K. A hemerythrin-like protein MSMEG_3312 influences erytrhromycin resistance in mycobacteria. Wei Sheng Wu Xue Bao 54, 1279–1288 (2014).
Li, X. et al. A bacterial hemerythrin-like protein MsmHr inhibits the SigF-dependent hydrogen peroxide response in mycobacteria. Front. Microbiol 5, 800 (2014).
Morris, R. P. et al. Ancestral antibiotic resistance in Mycobacterium tuberculosis. Proc. Natl. Acad. Sci. USA 102, 12200–12205 (2005).
Cangelosi, G. A. et al. The two-component regulatory system mtrAB is required for morphotypic multidrug resistance in Mycobacterium avium. Antimicrob. Agents. Chemother 50, 461–468 (2006).
Nguyen, H. T., Wolff, K. A., Cartabuke, R. H., Ogwang, S. & Nguyen, L. A lipoprotein modulates activity of the MtrAB two-component system to provide intrinsic multidrug resistance, cytokinetic control and cell wall homeostasis in Mycobacterium. Mol. Microbiol 76, 348–364 (2010).
Li, Y., Zeng, J., Zhang, H. & He, Z. G. The characterization of conserved binding motifs and potential target genes for M. tuberculosis MtrAB reveals a link between the two-component system and the drug resistance of M. smegmatis. BMC. Microbiol 10, 242 (2010).
UniProt, C. The universal protein resource (UniProt). Nucleic. Acids. Res 36, D190–195 (2008).
Fair, R. J. & Tor, Y. Antibiotics and bacterial resistance in the 21st century. Perspect. Medicin. Chem 6, 25–64 (2014).
Bowman, J. & Ghosh, P. A complex regulatory network controlling intrinsic multidrug resistance in Mycobacterium smegmatis. Mol. Microbiol 91, 121–134 (2014).
Parish, T. et al. Deletion of two-component regulatory systems increases the virulence of Mycobacterium tuberculosis. Infect. Immun 71, 1134–1140 (2003).
Zahrt, T. C. & Deretic, V. An essential two-component signal transduction system in Mycobacterium tuberculosis. J. Bacteriol 182, 3832–3838 (2000).
Fol, M. et al. Modulation of Mycobacterium tuberculosis proliferation by MtrA, an essential two-component response regulator. Mol. Microbiol 60, 643–657 (2006).
Rajagopalan, M. et al. Mycobacterium tuberculosis origin of replication and the promoter for immunodominant secreted antigen 85B are the targets of MtrA, the essential response regulator. J. Biol .Chem 285, 15816–15827 (2010).
Zhou, L. et al. Transcriptional and proteomic analyses of two-component response regulators in multidrug-resistant Mycobacterium tuberculosis. Int. J .Antimicrob. Agents 46, 73–81 (2015).
Hingley-Wilson, S. M., Lougheed, K. E., Ferguson, K., Leiva, S. & Williams, H. D. Individual Mycobacterium tuberculosis universal stress protein homologues are dispensable in vitro. Tuberculosis (Edinb) 90, 236–244 (2010).
Kana, B. D. et al. The resuscitation-promoting factors of Mycobacterium tuberculosis are required for virulence and resuscitation from dormancy but are collectively dispensable for growth in vitro. Mol. Microbiol 67, 672–684 (2008).
Hu, X. et al. Quantitative proteomics reveals novel insights into isoniazid susceptibility in mycobacteria mediated by a universal stress protein. J Proteome. Res 14, 1445–1454 (2015).
Kapopoulou, A., Lew, J. M. & Cole, S. T. The MycoBrowser portal: a comprehensive and manually annotated resource for mycobacterial genomes. Tuberculosis (Edinb) 91, 8–13 (2011).
Saini, V. et al. Massive gene acquisitions in Mycobacterium indicus pranii provide a perspective on mycobacterial evolution. Nucleic. Acids. Res 40, 10832–10850 (2012).
Oliynyk, M. et al. Complete genome sequence of the erythromycin-producing bacterium Saccharopolyspora erythraea NRRL23338. Nat. Biotechnol 25, 447–453 (2007).
Jain, P. et al. Specialized transduction designed for precise high-throughput unmarked deletions in Mycobacterium tuberculosis. MBio 5, e01245-14 (2014).
Bardarov, S. et al. Specialized transduction: an efficient method for generating marked and unmarked targeted gene disruptions in Mycobacterium tuberculosis, M. bovis BCG and M. smegmatis. Microbiology 148, 3007–3017 (2002).
Livak, K. J. & Schmittgen, T. D. Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. Methods 25, 402–408 (2001).
Acknowledgements
We thank Jiaoyu Deng for the gift of the plasmid pJH532 and Yongfei Hu for instruction in phylogenetic analysis. This work was supported by the Ministry of Science and Technology of China (2014CB744402 and 2012CB518700), National Natural Science Foundation of China (31270178) and the Key Program of the Chinese Academy of Sciences (KJZD-EW-L02).
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K.X.M. and X.J.L. designed the study. X.J.L., J.J.L., X.L.H., L.G.H. and J.X performed the experiments. X.J.L. performed the statistical analysis. K.X.M., J.C. and X.J.L. wrote the manuscript, with all authors contributing to the final draft; all authors contributed to the data interpretation and critically reviewed the manuscript.
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Li, X., Li, J., Hu, X. et al. Differential roles of the hemerythrin-like proteins of Mycobacterium smegmatis in hydrogen peroxide and erythromycin susceptibility. Sci Rep 5, 16130 (2015). https://doi.org/10.1038/srep16130
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DOI: https://doi.org/10.1038/srep16130
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