2908 antibiot Antibiotics Antibiotics (Basel) Multidisciplinary Digital Publishing Institute (MDPI) PMC9405191 9405191 9405191 36010000 10.3390/antibiotics11081131 Biochemical Characterizations of the Putative Endolysin Ecd09610 Catalytic Domain from Clostridioides difficile Sekiya Hiroshi 1 Yamaji Hina 1 Yoshida Ayumi 1 Matsunami Risa 1 Kamitori Shigehiro 2 Tamai Eiji 1 2 * Zhu Kui Academic Editor 1 Department of Infectious Disease, College of Pharmaceutical Science, Matsuyama University, 4-2 Bunkyo-cho, Matsuyama 790-8578, Ehime, Japan 2 Research Facility Center for Science and Technology, Faculty of Medicine, Kagawa University, 1750-1 Ikenobe, Miki-cho, Kita-gun, Takamatsu 761-0793, Kagawa, Japan * Correspondence: etamai@g.matsuyama-u.ac.jp ; Tel.: +81-89-926-7217 20 8 2022 11 8 1131 1131 26 8 2022 © 2022 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license ( https://creativecommons.org/licenses/by/4.0/ ). Abstract Clostridioides difficile is the major pathogen of pseudomembranous colitis, and novel antimicrobial agents are sought after for its treatment. Phage-derived endolysins with species-specific lytic activity have potential as novel antimicrobial agents. We surveyed the genome of C. difficile strain 630 and identified an endolysin gene, Ecd09610, which has an uncharacterized domain at the N-terminus and two catalytic domains that are homologous to glucosaminidase and endopeptidase at the C-terminus. Genes containing the two catalytic domains, the glucosaminidase domain and the endopeptidase domain, were cloned and expressed in Escherichia coli as N-terminal histidine-tagged proteins. The purified domain variants showed lytic activity almost specifically for C. difficile , which has a unique peptide bridge in its peptidoglycan. This species specificity is thought to depend on substrate cleavage activity rather than binding. The domain variants were thermostable, and, notably, the glucosaminidase domain remained active up to 100 °C. In addition, we determined the optimal pH and salt concentrations of these domain variants. Their properties are suitable for formulating a bacteriolytic enzyme as an antimicrobial agent. This lytic enzyme can serve as a scaffold for the construction of high lytic activity mutants with enhanced properties. Keywords: Clostridioides difficile , endolysin, antimicrobial agent, antimicrobial resistance status released display-pdf yes is-olf no is-manuscript no is-preprint no is-journal-matter no is-scanned no is-retracted no Received 2022 Jul 13; Accepted 2022 Aug 18; Collection date 2022 Aug. 1. Introduction Clostridioides difficile is a gram-positive, spore-forming, and anaerobic bacterium that causes infections leading to antibiotic-associated diarrhea, pseudomembranous colitis, and C. difficile -associated diarrhea [ 1 ]. For severe C. difficile infections, vancomycin or metronidazole are used as first-line treatments [ 2 ], but these adversely affect the gut microbiota. Fidaxomicin, a narrow-spectrum antibiotic [ 3 ], is another option that is less toxic to obligate anaerobic commensal bacteria, but its high cost limits its clinical use [ 4 ]. In addition, fecal microbiota transplantation [ 5 ], probiotic therapy [ 6 ], and monoclonal antibody treatment are available as alternative options to antimicrobial agents. However, each of these methods still has issues to be resolved and reasons why they cannot be easily introduced [ 7 ], so specific antimicrobials targeting C. difficile are required. Lytic enzymes can kill bacteria by hydrolyzing the peptidoglycan of bacterial cell walls via their catalytic domains. Despite performing the same peptidoglycan cleavage function, lytic enzymes have significantly different structures and underlying mechanisms of action [ 8 ]. They are divided into four classes: glucosaminidases, muramidases, amidases, and endopeptidases, depending on the hydrolyzing sites. Autolysin and endolysin are well-known lytic enzymes. Bacterial endogenous autolysins are involved in different physiological functions that require bacterial cell wall remodeling, such as cell wall expansion, peptidoglycan turnover, daughter cell separation, sporulation, germination, peptidoglycan recycling, and/or autolysis [ 9 , 10 , 11 ]. Phage-derived endolysins are expressed in the final stage of infection to hydrolyze cell wall peptidoglycans, which facilitates bacterial lysis and progeny phage release [ 12 ]. In general, phage endolysins exhibit species-specific lytic activity [ 13 ]. The molecular mechanisms of this species specificity are not well understood, but some are derived from the binding domain [ 14 , 15 ] and others from the structure of the substrate binding site of the catalytic domain [ 16 ]. Especially in C. difficile , the peptide bridge of its peptidoglycan is composed of amino acids that are different from those of other bacteria, and its structure is also thought to be different. The peptide bridge of C. difficile has been reported to be composed of the following four amino acids: L-Ala-γ-D-Glu-mDAP-D-Ala (mDAP: meso-2,6-diaminopimelic acid), and the glycan backbones are connected by direct 3–4 cross-links [ 17 ]. Therefore, autolysins generally have no species specificity, but the autolysin in C. difficile , Acd24020, which has endopeptidase activity, has species specificity, and we have proposed a particular mechanism for this [ 16 ]. Lytic enzymes, especially those with species-specific lytic activity, are potential therapeutic agents that can provide an alternative to standard drug therapy [ 18 , 19 , 20 ]. In group A Streptococcus infections, an endolysin specific for this organism has been shown to be effective in vivo when applied directly to the site of infection [ 21 ]. However, for a protein to be used as a drug, it should have the properties of being able to be purified in large quantities in a solubilized state, be resistant to protease degradation, and be suitable for formulation. For example, in intestinal infections of C. difficile , a therapeutic enzyme must be delivered to the intestinal tract without the loss of enzymatic activity. Enteric capsules and coatings make this possible, but to adapt these technologies, it is important than an enzyme does not lose its activity upon lyophilization. In a survey of genes of the C. difficile strain 630, we found an endolysin gene (gene ID: CD09610). The corresponding protein, named Ecd09610 (endolysin of C. difficile gene ID CD09610), has glucosaminidase and endopeptidase catalytic domains at the C-terminal end belonging to the GH73 family and NlpC/P60 family, respectively. In addition, the gene CD29030, which has the same sequence as CD09610, is present in C. difficile 630, and there are many genes related to phage proteins around these genes. Mondal et al. discovered a cell wall hydrolase (CWH) lysin encoded in the genome of the C. difficile phage phiMMP01, which is similar to this endolysin, and characterized its properties, including the species specificity of its two successive catalytic domains [ 22 ]. However, there are few reports of glucosaminidase endolysins of the GH73 family [ 23 , 24 ], most of which are autolysins [ 25 , 26 , 27 , 28 ], and only some of which have even been structurally characterized [ 29 , 30 , 31 , 32 , 33 , 34 ]. In contrast, the endopeptidases of the NlpC/P60 family are found in endolysins and autolysins [ 35 , 36 , 37 ], some of which have been structurally characterized [ 38 , 39 , 40 ]. Here, we report the detailed biochemical properties of each of the two catalytic domains of Ecd09610, including their optimal pH and salt concentrations and the effects of metal ions, temperature, and lyophilization. 2. Results 2.1. Identification, Cloning, Expression, and Purification of Ecd09610 and Its Derivatives Gene ID CD09610 in the C. difficile 630 genome was identified as a putative endolysin by sequence similarity searches of glucosaminidase and endopeptidase, and the corresponding protein was named Ecd09610 (endolysin of C. difficile gene ID CD09610). This gene has an uncharacterized domain in the N-terminal region and a glucosaminidase domain (Pfam number: PF01832) and endopeptidase domain (Pfam number: PF00877) in the C-terminal region ( Figure 1 a). Residues essential for catalysis (Cys, His, Asp) in the NlpC/P60 family of endopeptidases are also conserved in Ecd09610 ( Supplementary Materials Figure S1 ). The genes encoding Ecd09610 and its domains were cloned into an Escherichia coli expression vector (pColdII) that is able to fuse a His-tag at the N-terminus. The entire region (Ecd09610), the glucosaminidase domain (Ecd09610CD53), the endopeptidase domain (Ecd09610CD3), and the C-terminal domain with both catalytic domains (Ecd09610CD1) were successfully expressed and purified by Ni-affinity chromatography ( Figure 1 b). In the purification of Ecd09610CD53, Ecd09610CD3, and Ecd09610CD1, approximately 11.6 mg, 3.0 mg, and 3.7 mg, respectively, were recovered from 400 mL of culture. However, in the purification of the wild-type, the purification itself was performed as successfully as the purification of each domain variant, but 40% of the purified protein was precipitated by dialysis and only 60% was recovered (1.1 mg/400 mL culture). In contrast, for Ecd09610CD53, Ecd09610CD3, and Ecd09610CD1, the protein loss on dialysis was 10%. Taken together, the solubility of Ecd09610 was significantly improved by dividing it into domain variants. To examine the lytic and binding activity of the purified proteins, turbidity reduction assays and binding assays were performed using C. difficile 630 as a substrate. As shown in Figure 1 c, Ecd09610 and each domain variant had lytic activity. Compared with the wild-type Ecd09610, Ecd09610CD3, which has only the endopeptidase domain, showed almost the same activity, while Ecd09610CD53, which has only the glucosaminidase domain, showed lower lytic activity, and Ecd09610CD1, which has both catalytic domains, showed the highest activity. Furthermore, binding activity assays of the wild-type and each domain variant against C. difficile 630 showed that the catalytic domain itself can bind to the cells ( Figure 1 d). Figure 1 SDS-PAGE analysis, lytic activities, and binding ability of Ecd09610, Ecd09610CD1, Ecd09610CD3, and Ecd09610CD53. ( a ) Schematic diagrams of Ecd09610, Ecd09610CD1, Ecd09610CD3, and Ecd09610CD53. Ecd09610 has two catalytic domains of glucosaminidase (GL) and endopeptidase (EP) at the C-terminus. These proteins have His-tags at the N-terminus. ( b ) SDS-PAGE analysis of purified Ecd09610, Ecd09610CD1, Ecd09610CD3, and Ecd09610CD53 (1 μg each). The gel was stained with Coomassie blue R. ( c ) Lytic activities of protein (0.1 μM) were determined by the turbidity reduction assay against C. difficile 630 cells. Ecd09610 (filled circles), Ecd09610CD1 (open circles), Ecd09610CD3 (filled triangles), Ecd09610CD53 (open triangles), and control (filled diamond) are shown. ( d ) Binding ability of purified proteins to C. difficile 630 cells. Purified protein and nonbinding internal standard (ovalbumin: Alb) were incubated with (+) or without (−) cells. After centrifuging samples, supernatants were analyzed by 13.5% SDS-PAGE. 2.2. Characterization of the Lytic Activity of Ecd09610 and Its Derivatives To characterize the enzymatic activity of Ecd09610 and its domain variants, we determined the effects of pH, salt, metal ions, and temperature on the lytic activity using C. difficile 630 as a substrate ( Figure 2 a–d). As shown in Figure 2 a, the optimal pH of wild-type Ecd09610, Ecd09610CD1, and Ecd09610CD53 was 6, while Ecd09610CD3 had its highest lytic activity at a pH of 8. Note that at pH 8, Ecd09610CD3, which is only an endopeptidase, showed high lytic activity, whereas the activity by the endopeptidase was counteracted in Ecd09610CD1 and Ecd09610, which have two catalytic domains. This phenomenon is seen at pH 7 and above. At pH 6 and 5, glucosaminidase and endopeptidase work together, and the two domains of Ecd09610CD1 show additive lytic activity. Figure 2 Lytic activity of Ecd09610, Ecd09610CD1, Ecd09610CD3, and Ecd09610CD53 against C. difficile 630 as determined by the turbidity reduction assay. The lytic activity was calculated after 30 min as follows: [ΔOD 600 test (protein added) − ΔOD 600 control (buffer only)]/µmol protein. ( a ) The optimal pH for lytic activity was determined using borate-phosphate universal buffer. The relative activity at pH 6.0 of Ecd09610CD3 was set as 1. ( b ) The effect of NaCl on lytic activity was determined using 25 mM Tris-HCl (pH 7.0). The relative activity at 75 mM NaCl of Ecd09610CD1 was set as 1. Ecd09610 (filled circles), Ecd09610CD1 (open circles), Ecd09610CD3 (filled triangles), and Ecd09610CD53 (open triangles) are shown. ( c ) The effects of divalent metal cations on lytic activity were determined by the addition of 1 mM CaCl 2 , MgCl 2 , ZnCl 2 , MnCl 2 , CuCl 2 , or EDTA. The relative activities are shown with activity in the absence of divalent cations set as 1. The lytic activity with no divalent cations was 35,011 (Ecd09610CD1, white), 16,788 (Ecd09610CD3, gray), and 11,190 (Ecd09610CD53, black). ( d ) The thermal stability of lytic activity was determined by measuring lytic activity after 10 min of heat treatment at 37, 45, 60, 75, or 100 °C, or with no treatment. The relative activities with no treatment for Ecd09610CD1, Ecd09610CD3, and Ecd09610CD53 were set as 1. The lytic activities with no treatment were 104,200 (Ecd09610CD1, white), 62,917 (Ecd09610CD3, gray), and 5288 (Ecd09610CD53, black). Means in all experiments were calculated based on three independent experiments. Standard deviations were calculated by three independent experiments, each with triplicate samples. The effects of salt (NaCl) concentrations on the lytic activity of Ecd09610 and each domain variant were also examined ( Figure 2 b). Ecd09610 and Ecd09610CD53 showed high lytic activity below 50 mM, decreased activity above 50 mM, and almost no activity above 150 mM. In Ecd09610CD1 and Ecd09610CD3, the lytic activity was highest at 75 mM. Moreover, the activity of Ecd09610CD1 was reduced above 75 mM, while that of Ecd09610CD3 was not reduced up to 200 mM. In addition, the effects of metal ions were examined ( Figure 2 c). The addition of CaCl 2 and ethylenediaminetetraacetic acid did not significantly affect the lytic activity, but the addition of MgCl 2 slightly increased activity, and the addition of ZnCl 2 , MnCl 2 , and CuCl 2 significantly reduced the lytic activity. To clarify the thermal stability of each domain variant, their activities were measured with purified proteins that were preincubated for 10 min at varying temperatures ( Figure 2 d). The results showed that the activities of Ecd09610CD1 and Ecd09610CD3 decreased significantly as the temperature increased, but maintained some activity above 60 °C. However, Ecd09610CD53, which contains only the glucosaminidase domain, had low activity, but showed no decrease in activity up to 100 °C. 2.3. Bacterial Specificity of Ecd09610 Derivatives In general, phage endolysins exhibit species-specific lytic activity [ 13 ]. Therefore, the species specificity of each domain was determined by turbidity reduction assay using various bacterial strains as substrates ( Table 1 and Figure S2 ). Each of the three domain variants showed lytic activity against three strains of C. difficile . Ecd09610CD3 also showed weak lytic activity against Clostridium histolyticum , Clostridium ramosum , Clostridium tetani , Atopobium fossor , and Bacillus subtilis , but showed no lytic activity against the other gram-positive bacteria tested in this study. Ecd09610CD1 and Ecd09610CD53 showed weak lytic activity against Clostridium novyi in addition to the above-mentioned bacteria. The species specificity of binding was also tested ( Figure S3 ). The three domain variants bound to most of the bacteria tested in this study, but Ecd09610CD3 and Ecd09610CD53 exhibited reduced binding activity against Clostridium perfringens and Eubacterium cylindroides . Table 1 Species specificity of Ecd09610 domain variant lytic activity. Bacteria Relative Activity (%) Ecd09610CD1 Ecd09610CD3 Ecd09610CD53 C. difficile 630 100.0 ± 14.1 100.0 ± 20.8 100.0 ± 10.00 C. difficile ATCC43255 104.9 ± 9.00 97.6 ± 15.6 15.6 ± 5.20 C. difficile ATCC9689 101.7 ± 21.8 119.3 ± 21.0 96.3 ± 21.0 C. acetobutylicum ATCC824 −10.2 ± 0.90 −6.8 ± 4.10 −16.9 ± 4.90 C. coccoides ATCC29236 −1.3 ± 0.70 −0.8 ± 0.90 −2.3 ± 7.40 C. histolyticum JCM1403 12.6 ± 4.30 8.1 ± 2.10 5.8 ± 1.50 C. lituseburense ATCC25759 3.0 ± 5.10 4.5 ± 3.80 3.3 ± 1.50 C. novyi ATCC17861 22.4 ± 11.0 −2.3 ± 6.10 10.9 ± 17.40 C. perfringens strain13 5.6 ± 0.60 1.3 ± 3.50 3.7 ± 5.20 C. ramosum ATCC25582 65.3 ± 1.70 17.3 ± 2.90 7.5 ± 2.30 C. tetani KZ1113 34.8 ± 3.00 38.9 ± 1.00 11.0 ± 1.80 A. fossor ATCC43386 15.0 ± 2.20 11.0 ± 2.50 5.0 ± 2.00 B. adolescentis ATCC15703 0.3 ± 2.10 −2.4 ± 3.50 −4.9 ± 0.80 E. cylindroides ATCC27805 1.4 ± 5.00 −2.6 ± 2.20 −2.3 ± 2.60 B. subtilis ATCC6633 16.8 ± 3.20 8.9 ± 10.0 8.5 ± 3.90 S. aureus FDA209P 1.8 ± 1.90 2.6 ± 2.00 −1.1 ± 4.90 The lytic activity was calculated after 10 min as follows: {ΔOD 600 test (0.14 μM Ecd09610CD1, 0.2 μM Ecd09610CD3, or 0.3 μM Ecd09610CD53 added) − ΔOD 600 control (buffer only)}/μmol protein. The relative activity of the bacteria is shown with the lytic activity of C. difficile 630 set as 100%. Means and standard deviations in all experiments were calculated by three independent experiments each with triplicate samples. The lytic activities of C. difficile 630 [{ΔOD 600 test − ΔOD 600 control (buffer only)}/μmol protein] were 12,858 (Ecd09610CD1), 7957 (Ecd09610CD3), and 6102 (Ecd09610CD53). 2.4. Long-Term Stability of Ecd09610 Derivatives For enzymes to be used as drugs, their stability, both long-term and under dry conditions, needs to be verified. Each purified Ecd09610 derivative was lyophilized, stored at either room temperature or 4 °C, and then dissolved again in water to determine its lytic activity ( Figure 3 ). There was no loss of the activity due to lyophilization among the three domain variants. There was a slight decrease in the activity for Ecd09610CD1 when stored at 4 °C for 4 weeks, but no decrease in activity was observed for the other two domain variants. Furthermore, when stored at room temperature for 4 weeks, there was a decrease in activity of about 49% and 40% for Ecd09610CD1 and Ecd09610CD3, respectively, but no decrease in activity for Ecd09610CD53 Figure 3 Effect of lyophilization on the lytic activity of proteins. Ecd09610CD1 (0.08 μM), Ecd09610CD3 (0.15 μM), and Ecd09610CD53 (0.3 μM) or buffer was added to the cells, and OD 600 was measured at 1-min intervals for 30 min. No lyophilized protein (green), lyophilized protein (blue), lyophilized and stored at 4 °C, for 4 weeks (yellow), lyophilized and stored at room temperature for 4 weeks (gray), and buffer (black) are shown. 3. Discussion The gene ecd09610 (gene ID CD09610) was identified by a homology search for glucosaminidase and endopeptidase from the genome of C. difficile 630. This gene product is quite similar to the recently reported endolysin CWH of C. difficile phage phiMMP01 [ 22 ]. The similarity and identity between Ecd09610 and CWH in the N-terminal uncharacterized domain, the glucosaminidase domain, and the endopeptidase domain were 98% and 90%, 87% and 65%, and 99% and 99%, respectively ( Figure S1 ). There were also genes associated with phages around the Ecd09610 gene ( Figure S4 ). This suggests that a phiMMP01-like phage had infected and lysogenized in C. difficile 630. The lytic activities of wild-type Ecd09610 and its domain variants against C. difficile 630 were measured, revealing that Ecd09610CD1 had the highest activity per molecule, wild-type and Ecd09610CD3 were comparable, and Ecd09610CD53 had the lowest ( Figure 1 c). These results are similar to those of Mondal et al. [ 22 ]. The catalytic domain may have high affinity for the substrate since each domain variant binds to C. difficile even without the N-terminal uncharacterized domain, which is the putative binding domain [ 22 ] ( Figure 1 d). In addition, Ecd09610CD1, a variant lacking the N-terminal uncharacterized domain, exhibited higher activity than the wild-type. We also consider that this domain is not a meaningful binding domain since Mondal et al. reported that this region has similarities with the bacteriophage tail protein [ 22 ]. To address whether domain variants without the putative binding domain are more active, we cloned and purified the N-terminal uncharacterized domain of Ecd09610 alone and performed cell binding assays against C. difficile 630. We found that the N-terminal uncharacterized domain binds slightly to C. difficile 630 ( Figure S5 ). Taken together, these data suggest that the N-terminal uncharacterized domain may prevent the normal binding of the catalytic domain to C. difficile 630, thereby reducing its lytic activity. It will be necessary to clarify the function of this uncharacterized domain in the future. The results for the optimum pH assays for each domain variant were complicated. Notably, the activity of the endopeptidase was highest at pH 8, but despite the presence of endopeptidase domains in Ecd09610CD1 and in the wild-type, their activity was greatly reduced at pH 8 ( Figure 2 b). This may be due to the binding of the glucosaminidase, which does not exhibit lytic activity at pH 8, to the cells, resulting in diminished binding of the endopeptidase to the cells and, consequently, reduced endopeptidase lytic activity. These data suggest that the substrate affinity of the glucosaminidase is higher than that of the endopeptidase. The most effective pH is pH 8 when the endopeptidase alone is used to lyse bacteria, and pH 6 when used with the glucosaminidase alone or with the endopeptidase. In addition, regarding the effect of salt, the decrease in activity of the wild-type, Ecd09610CD1, and Ecd09610CD53 at high salt concentrations (>100 mM) is thought to be due to the decreased activity and binding of glucosaminidase to the cells ( Figure S6 ). However, C. difficile -infected patients suffer from severe diarrhea, and the colon, which is the site of C. difficile infection, is thought to be inflamed with fluid seeping into the intestinal tract, so the salt concentration at the site is thought to be as high as or lower than that of saline solution. Therefore, the endolysin, which acts at low salt concentrations, should be effective. The results of the temperature tolerance study show that, interestingly, the Ecd09610 domain variants are relatively resistant to high temperatures, especially Ecd09610CD53, which was not inactivated by heating at 100 °C for 10 min, and the activity of Ecd09610CD1 above 45 °C seems to come from the glucosaminidase domain. Whether this thermostability is due to the speed of refolding or to heat tolerance of the protein itself remains unclear, but we intend to clarify this issue through further structural analysis. Furthermore, the domain variants of Ecd09610 do not lose activity by lyophilization and can be stored for long periods at 4 °C in a dried state ( Figure 3 ). These properties may be advantageous for formulation as an antimicrobial agent. Moreover, it is difficult to obtain the purified wild-type endolysin in large quantities; however, the purified domain variants can be easily obtained in large amounts in soluble form. This property of the domain variants is also an advantage in industrial production. The domain variants of Ecd09610 had weak lytic activity against some bacteria, but it is basically a C. difficile -specific endolysin ( Table 1 ). The mechanism of the species specificity is known to depend on the binding domain [ 14 , 15 ] or on the structure of the substrate recognition groove [ 16 ]. In the case of Ecd09610, its substrate specificity mechanism is thought to be the latter, i.e., dependent on the structure of the substrate recognition groove since various domain variants of Ecd09610 exhibited specific lytic activity against C. difficile even though they bound to a variety of bacterial species without the binding domain. To elucidate the species-specificity mechanism, we intend to perform structural analysis of each domain. This specificity for C. difficile could be used to develop antimicrobial agents that can treat C. difficile infectious diseases, such as pseudomembranous colitis, without affecting the intestinal microbiota. However, the issue for using Ecd09610CD53 as an antimicrobial agent is its low lytic activity, so it may be necessary to create mutants with increased lytic activity. To achieve this, it is necessary to determine the structure of the catalytic domain and clarify the amino acids constituting its active center. Then, mutants can be constructed by substituting the amino acids so that the active center structure will be more catalytically active. In addition, we would like to increase tolerance to proteases by amino acid substitutions based on structural information. It has been reported that a synergistic effect can be achieved by combining lytic enzymes with different cleavage sites [ 41 , 42 ]. In Ecd09610CD1, each catalytic domain with a different cleavage site is linked, so we thought that they might act synergistically and that the linkage of the two domains might make sense. Therefore, we compared the lytic activity of Ecd09610CD1 with that of simultaneously added Ecd09610CD3 and Ecd09610CD53 ( Figure S7 ). The results suggested that they seem to act synergistically in the initial phase of the reaction, but the final lytic activity was considered to be additive. No effect of the linkage of the two catalytic domains was observed. This result may be due to the low activity of the glucosaminidase and the differences in optimum pH and salt concentration of the respective catalytic domains. 4. Materials and Methods 4.1. Construction of Plasmids The overlap extension PCR method [ 43 ] using Tks Gflex™ DNA Polymerase (TakaRa Bio, Inc., Shiga, Japan) was used for the construction of expression vectors for N-terminal His-tagged Ecd09610. PCR was performed using the primers listed in Supplemental Table S1 and genomic DNA of C. difficile 630 as a template. The 2nd PCR products were digested with Nde I and Bam HI and then cloned into the expression vector pColdII (TakaRa Bio, Inc.) at the Nde I- Bam HI site. The resultant plasmid was designated as pColdIICD09610. The plasmids expressing both glucosaminidase and endopeptidase, glucosaminidase only, and endopeptidase only, (pColdIICD09610CD1, pColdIICD09610CD53, and pColdIICD09610CD3, respectively), were constructed by the same method using the primers listed in Supplemental Table S1 and pColdIICD09610 as a template. PCR-amplified fragments in all constructs were verified with an ABI PRISM 3130xl genetic analyzer (Thermo Fisher Scientific, Waltham, MA, USA). 4.2. Preparation of Proteins E. coli BL21-CodonPlus-RIL transformed with pColdIICD09610, pColdIICD09610CD1, pColdIICD09610CD3, or pColdIICD09610CD53 were cultured in M9 medium containing 0.2% ( w / v ) glucose, 0.2% ( w / v ) tryptone, 0.001% thiamine, 100 μg/mL ampicillin, 30 μg/mL chloramphenicol, and 10 μg/mL tetracycline at 37 °C until the middle-logarithmic phase, then incubated on ice for 30 min. After the addition of a final concentration of 1 mM isopropyl-β-D-thiogalactopyranoside, the cells were further incubated at 15 °C for 20–24 h. The harvested cells were suspended in buffer A (50 mM Tris-HCl, pH 7.0, 500 mM NaCl, and 20 mM imidazole), and the suspension was sonicated on ice for 30 s for a total of five times at power level 5 by an ultrasonic disruptor (UD-200, TOMY Co, Ltd., Tokyo, Japan). The suspension was then centrifuged at 22,300× g at 4 °C for 10 min, and the supernatant was filtrated with a 0.2-μm pore size syringe filter (Minisalt ® , Sartorius, Göttingen, Germany). The protein solution was applied to an Ni + -charged Chelating Sepharose Fast Flow (GE Healthcare Bio-Sciences AB, Uppsala, Sweden). The column was washed with buffer A and then eluted by a stepwise gradient or a linear gradient of 50–350 mM imidazole. The elutant from the resin was dialyzed against buffer B (25 mM phosphate buffer, pH 6.0, 100 mM NaCl, and 10% glycerol) for CD09610 and buffer C (25 mM Tris-HCl, pH 7.0, 100 mM NaCl, and 10% glycerol) for the others, and filtrated with a 0.2-μm syringe filter. 4.3. Lytic Activity Assay The lytic activity of proteins was tested by the method of Gerova et al. with some modifications [ 44 ]. Briefly, C. difficile strains cultured in TY medium and the other strains cultured in GAM medium at 37 °C for 16 h were washed twice and suspended in wash buffer (25 mM Tris-HCl, pH 7.0), then adjusted to 1.25 optical density at 600 nm (OD 600 )/mL. The lytic activity was started by the addition of 20 μL protein or assay buffer into 180 μL of a preincubated cell suspension. Their OD 600 was measured at 37 °C for 1-min intervals (SpectraMax ® M5e Multi-Mode Microplate Readers, Molecular Devices Corp., Sunnyvale, CA, USA). In testing for thermal stability, samples were heated for 10 min and then left at room temperature for several minutes before measurement. 4.4. Cell Binding Assay Cell binding assays were carried out with purified Ecd09610, Ecd09610CD1, Ecd09610CD3, and Ecd09610CD53. The purified protein and ovalbumin were incubated for 15 min on ice either with or without heat-inactivated cells in binding buffer (25 mM Tris pH 7.0) containing 100 mM NaCl ( Figure 1 d) or without NaCl ( Figure S3 ). The samples were centrifuged at 22,300× g at 4 °C for 3 min. SDS-PAGE sample buffer was added to the supernatant, and the mixture was incubated at 95 °C for 5 min then analyzed by SDS-PAGE. Supplementary Materials The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/antibiotics11081131/s1 , Figure S1: Multiple sequence alignment of the catalytic domains of Ecd09610; Figure S2: Species specificity of Ecd09610CD1, Ecd09610CD3, and Ecd09610CD53 lytic activities; Figure S3: Binding assay for Ecd09610CD1, Ecd09610CD3, and Ecd09610CD53 with various bacteria; Figure S4: Genes around ecd09610 (CD09610) in the C. difficile 630 genome; Figure S5: Binding ability of the purified N-terminal uncharacterized region of Ecd09610 to C. difficile 630 cells; Figure S6: Effect of NaCl on the binding ability of purified proteins to C. difficile 630; Figure S7: Effect of the two catalytic domains; Table S1: Primers used in this study. Click here for additional data file. Author Contributions E.T. and H.S. conceived of and supervised the study; E.T. and H.S. designed experiments; H.S. and R.M. constructed the expression plasmids for the proteins and purified the proteins; H.S., H.Y., and A.Y. performed the biochemical characterization; E.T., H.S., and S.K. wrote the manuscript. All authors have read and agreed to the published version of the manuscript. Institutional Review Board Statement Not applicable. Informed Consent Statement Not applicable. Data Availability Statement The data that support the findings of this study are available from the corresponding authors upon request. Conflicts of Interest The authors declare no conflict of interest. Funding Statement This work was supported in part by JSPS KAKENHI Grant Numbers 18K07131 and 22K07061 from the Japan Society for the Promotion of Science (JSPS). Footnotes Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. References 1. 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Biochemical Characterizations of the Putative Endolysin Ecd09610 Catalytic Domain from Clostridioides difficile
来自艰难梭菌的推定内溶素Ecd09610催化结构域的生物化学表征
📄 中文摘要 Chinese Abstract
📋 英文结构化总结 English Structured Summary
全文整理
Background:
Clostridioides difficile is a major cause of antibiotic-associated diarrhea and pseudomembranous colitis, with current treatments like vancomycin and metronidazole disrupting the gut microbiota. There is a need for species-specific antimicrobials that target C. difficile without harming commensal bacteria. Phage-derived endolysins, which hydrolyze bacterial peptidoglycan, offer a promising alternative due to their specificity and lytic activity. The C. difficile strain 630 genome contains an endolysin gene, Ecd09610, with two catalytic domains—glucosaminidase and endopeptidase—but its biochemical properties and potential as a therapeutic agent remain underexplored.
Methods:
The genes encoding full-length Ecd09610 and its individual catalytic domains (glucosaminidase-only Ecd09610CD53, endopeptidase-only Ecd09610CD3, and both domains together Ecd09610CD1) were cloned into the pColdII expression vector with N-terminal His-tags and expressed in Escherichia coli. Proteins were purified using Ni-affinity chromatography. Lytic activity was assessed via turbidity reduction assays against C. difficile 630 and other bacterial strains. Optimal pH, salt concentration, metal ion effects, thermal stability, and lyophilization tolerance were evaluated. Binding assays were conducted to assess cell wall affinity.
Results:
All domain variants exhibited strong lytic activity specifically against C. difficile, with Ecd09610CD1 showing the highest activity. The glucosaminidase domain (Ecd09610CD53) retained full activity after heating at 100 °C for 10 minutes, indicating exceptional thermostability. Optimal pH was 6 for glucosaminidase-containing variants and 8 for the endopeptidase-only variant. Activity was highest at low salt concentrations (≤75 mM NaCl), and divalent cations like Zn²⁺ and Cu²⁺ inhibited activity. Lyophilization did not reduce activity, and proteins remained stable for 4 weeks at 4 °C or room temperature (with some loss in Ecd09610CD1 and Ecd09610CD3 at room temperature). Binding assays confirmed that catalytic domains alone could bind C. difficile cells, suggesting substrate recognition is mediated by the catalytic domains rather than the N-terminal region.
Data Summary:
Ecd09610CD1 showed the highest specific lytic activity (12,858 ΔOD₆₀₀/μmol protein), followed by Ecd09610CD3 (7,957) and Ecd09610CD53 (6,102). The glucosaminidase domain retained 100% activity after 10 min at 100 °C, while Ecd09610CD1 and Ecd09610CD3 retained partial activity above 60 °C. Lyophilization caused no immediate activity loss; after 4 weeks, Ecd09610CD53 retained full activity, whereas Ecd09610CD1 and Ecd09610CD3 retained ~51% and ~60% activity, respectively, at room temperature. Species specificity testing showed activity primarily against C. difficile, with weak activity against a few other Clostridium species and no activity against non-clostridial gram-positive bacteria.
Conclusions:
The catalytic domains of Ecd09610, particularly when combined (Ecd09610CD1), exhibit high, species-specific lytic activity against C. difficile, likely due to recognition of its unique peptidoglycan structure (L-Ala-γ-D-Glu-mDAP-D-Ala with direct 3–4 cross-links). The exceptional thermostability and lyophilization tolerance of the glucosaminidase domain make it suitable for pharmaceutical formulation. The N-terminal uncharacterized domain appears to hinder catalytic activity, suggesting that truncated variants are more effective. These properties position Ecd09610 derivatives as promising scaffolds for developing targeted antimicrobial agents against C. difficile infections.
Practical Significance:
The Ecd09610 endolysin derivatives, especially Ecd09610CD1 and Ecd09610CD53, represent strong candidates for development as novel therapeutics against Clostridioides difficile infections. Their species-specific lytic activity minimizes disruption to the gut microbiota, addressing a key limitation of conventional antibiotics. Their stability under heat and lyophilization supports practical formulation into oral or enteric-coated delivery systems for targeted intestinal release, potentially improving treatment outcomes for pseudomembranous colitis and recurrent C. difficile-associated diarrhea.
📋 中文结构化总结 Chinese Structured Summary
背景:
艰难梭菌是抗生素相关性腹泻和假膜性结肠炎的主要病因,目前常用的万古霉素和甲硝唑等治疗方案会破坏肠道菌群。因此,需要开发种属特异性抗菌剂,在不伤害共生菌的前提下靶向杀灭艰难梭菌。噬菌体来源的溶菌酶可水解细菌肽聚糖,因其特异性和裂解活性而成为一种极具前景的替代方案。艰难梭菌630菌株基因组中含有一个溶菌酶基因Ecd09610,该基因具有两个催化结构域——氨基糖苷酶和肽链内切酶——但其生化特性及作为治疗剂的潜力尚未得到充分研究。
方法:
将编码全长Ecd09610及其各催化结构域(仅含氨基糖苷酶结构域的Ecd09610CD53、仅含肽链内切酶结构域的Ecd09610CD3,以及两个结构域组合的Ecd09610CD1)的基因克隆至带有N端His标签的pColdII表达载体中,并在大肠杆菌中表达。蛋白质采用镍亲和层析法纯化。通过浊度降低实验评估对艰难梭菌630及其他细菌菌株的裂解活性。对最适pH、盐浓度、金属离子效应、热稳定性和冻干耐受性进行了评估。同时进行了结合实验以评估细胞壁亲和力。
结果:
所有结构域变体均对艰难梭菌表现出强烈的特异性裂解活性,其中Ecd09610CD1活性最高。氨基糖苷酶结构域(Ecd09610CD53)在100°C加热10分钟后仍保持全部活性,表明其具有卓越的热稳定性。含氨基糖苷酶结构域变体的最适pH为6,而仅含肽链内切酶结构域变体的最适pH为8。在低盐浓度(≤75 mM NaCl)下活性最高,Zn²⁺和Cu²⁺等二价阳离子可抑制其活性。冻干处理不会降低活性,蛋白质在4°C或室温下可稳定保存4周(Ecd09610CD1和Ecd09610CD3在室温下活性有所损失)。结合实验证实,单独的催化结构域即可与艰难梭菌细胞结合,表明底物识别由催化结构域而非N端区域介导。
数据总结:
Ecd09610CD1的比裂解活性最高(12,858 ΔOD₆₀₀/μmol蛋白),其次为Ecd09610CD3(7,957)和Ecd09610CD53(6,102)。氨基糖苷酶结构域在100°C加热10分钟后仍保持100%活性,而Ecd09610CD1和Ecd09610CD3在60°C以上保留部分活性。冻干未造成即时活性损失;4周后,Ecd09610CD53在室温下仍保持全部活性,而Ecd09610CD1和Ecd09610CD3在室温下分别保留约51%和约60%的活性。种属特异性测试显示,活性主要针对艰难梭菌,对少数其他梭菌属菌株有微弱活性,对非梭菌属的革兰氏阳性菌无活性。
结论:
Ecd09610的催化结构域,尤其是两个结构域组合时(Ecd09610CD1),对艰难梭菌表现出高且种属特异性的裂解活性,这可能是由于其识别了艰难梭菌独特的肽聚糖结构(L-Ala-γ-D-Glu-mDAP-D-Ala,含直接3-4交联)。氨基糖苷酶结构域卓越的热稳定性和冻干耐受性使其适合用于药物制剂。N端未表征的结构域似乎会阻碍催化活性,表明截短变体更为有效。这些特性使Ecd09610衍生物成为开发针对艰难梭菌感染靶向抗菌剂的有前景的候选骨架。
实际意义:
Ecd09610溶菌酶衍生物,尤其是Ecd09610CD1和Ecd09610CD53,是开发新型艰难梭菌感染治疗药物的有力候选者。其种属特异性裂解活性可最大程度减少对肠道菌群的破坏,克服了传统抗生素的关键局限性。其耐热性和冻干稳定性支持将其制成口服或肠溶包衣递送系统,实现肠道靶向释放,有望改善假膜性结肠炎和复发性艰难梭菌相关性腹泻的治疗效果。
📖 英文全文 English Full Text
📖 中文全文 Chinese Full Text
# 艰难梭菌假定内溶素Ecd09610催化域的生化特性
**Sekiya Hiroshi¹, Yamaji Hina¹, Yoshida Ayumi¹, Matsunami Risa¹, Kamitori Shigehiro², Tamai Eiji¹²\***
¹ 松山大学药学院感染性疾病学系,日本爱媛县松山市文京町4-2,邮编790-8578 ² 香川大学医学院科学技术研究设施中心,日本香川县木田郡三木町池之边1750-1,邮编761-0793
\* 通讯作者:etamai@g.matsuyama-u.ac.jp;电话:+81-89-926-7217
**摘要**
艰难梭菌(*Clostridioides difficile*)是伪膜性结肠炎的主要病原菌,亟需开发新型抗菌剂用于其治疗。具有种属特异性裂解活性的噬菌体来源内溶素作为新型抗菌剂具有广阔前景。我们对艰难梭菌630菌株的基因组进行了筛查,鉴定出一个内溶素基因Ecd09610,该基因N端含有一个未表征的结构域,C端含有两个与糖苷酶和内肽酶同源的催化域。将编码这两个催化域——糖苷酶域和内肽酶域的基因克隆并在大肠杆菌(*Escherichia coli*)中表达为N端组氨酸标签蛋白。纯化的结构域变体对艰难梭菌表现出几乎专一的裂解活性,而艰难梭菌的肽聚糖具有独特的肽桥结构。这种种属特异性被认为取决于底物裂解活性而非结合能力。这些结构域变体具有热稳定性,值得注意的是,糖苷酶域在高达100 °C的条件下仍保持活性。此外,我们还测定了这些结构域变体的最适pH和盐浓度。它们的特性适合作为细菌裂解酶制剂开发为抗菌剂。该裂解酶可作为构建具有高裂解活性突变体的支架,以增强其性能。
**关键词:** 艰难梭菌;内溶素;抗菌剂;抗菌药物耐药性
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## 1. 引言
艰难梭菌是一种革兰氏阳性、产芽孢的厌氧菌,可引起感染,导致抗生素相关性腹泻、伪膜性结肠炎和艰难梭菌相关性腹泻[1]。对于严重的艰难梭菌感染,万古霉素或甲硝唑被用作一线治疗药物[2],但这些药物会对肠道菌群产生不利影响。非达霉素是一种窄谱抗生素[3],是另一种选择,其对专性厌氧共生细菌的毒性较小,但其高昂的成本限制了临床应用[4]。此外,粪便微生物群移植[5]、益生菌治疗[6]和单克隆抗体治疗可作为抗菌剂的替代方案。然而,这些方法各自仍存在待解决的问题以及难以广泛推广的原因[7],因此需要开发针对艰难梭菌的特异性抗菌剂。
裂解酶可通过其催化域水解细菌细胞壁的肽聚糖来杀死细菌。尽管执行相同的肽聚糖裂解功能,裂解酶的结构和作用机制存在显著差异[8]。根据水解位点的不同,它们分为四类:糖苷酶、胞壁酸酶、酰胺酶和内肽酶。自溶素和内溶素是众所周知的裂解酶。细菌内源性自溶素参与不同的生理功能,这些功能需要细菌细胞壁重塑,如细胞壁扩展、肽聚糖周转、子代细胞分离、芽孢形成、萌发、肽聚糖再循环和/或自溶[9,10,11]。噬菌体来源的内溶素在感染的最后阶段表达,以水解细胞壁肽聚糖,从而促进细菌裂解和子代噬菌体释放[12]。一般而言,噬菌体内溶素表现出种属特异性裂解活性[13]。这种种属特异性的分子机制尚不完全清楚,但一些来源于结合域[14,15],另一些来源于催化域底物结合位点的结构[16]。特别是在艰难梭菌中,其肽聚糖的肽桥由与其他细菌不同的氨基酸组成,其结构也被认为有所不同。据报道,艰难梭菌的肽桥由以下四种氨基酸组成:L-Ala-γ-D-Glu-mDAP-D-Ala(mDAP:内消旋-2,6-二氨基庚二酸),并且糖骨架通过直接的3-4交联连接[17]。因此,自溶素通常不具有种属特异性,但艰难梭菌中的自溶素Acd24020具有内肽酶活性,表现出种属特异性,我们已为此提出了一种特定机制[16]。裂解酶,特别是具有种属特异性裂解活性的裂解酶,是有潜力的治疗剂,可作为标准药物治疗的替代方案[18,19,20]。在A组链球菌感染中,已证明针对该生物体的内溶素在直接应用于感染部位时在体内有效[21]。然而,要将蛋白质用作药物,其应具备以下特性:能够以溶解状态大量纯化、抗蛋白酶降解以及适合制剂。例如,在艰难梭菌的肠道感染中,治疗酶必须在到达肠道时不丧失酶活性。肠溶胶囊和包衣技术使这成为可能,但要适应这些技术,重要的是酶在冻干后不丧失活性。
在对艰难梭菌630菌株的基因筛查中,我们发现了一个内溶素基因(基因ID:CD09610)。相应的蛋白被命名为Ecd09610(艰难梭菌基因ID CD09610的内溶素),其C端含有属于GH73家族的糖苷酶催化域和属于NlpC/P60家族的内肽酶催化域。此外,在艰难梭菌630中存在与CD09610序列相同的基因CD29030,且这些基因周围存在许多与噬菌体蛋白相关的基因。Mondal等人发现了在艰难梭菌噬菌体phiMMP01基因组中编码的细胞壁水解酶(CWH)溶素,该溶素与该内溶素相似,并表征了其特性,包括其两个连续催化域的种属特异性[22]。然而,关于GH73家族的糖苷酶内溶素的报道很少[23,24],其中大多数为自溶素[25,26,27,28],仅部分已被结构表征[29,30,31,32,33,34]。相比之下,NlpC/P60家族的内肽酶存在于内溶素和自溶素中[35,36,37],其中一些已被结构表征[38,39,40]。在此,我们报道了Ecd09610两个催化域各自的详细生化特性,包括其最适pH和盐浓度以及金属离子、温度和冻干的影响。
## 2. 结果
### 2.1. Ecd09610及其衍生物的鉴定、克隆、表达和纯化
通过糖苷酶和内肽酶序列相似性搜索,将艰难梭菌630基因组中的基因ID CD09610鉴定为假定内溶素,相应的蛋白被命名为Ecd09610(艰难梭菌基因ID CD09610的内溶素)。该基因在N端区域含有一个未表征的结构域,在C端区域含有一个糖苷酶结构域(Pfam编号:PF01832)和一个内肽酶结构域(Pfam编号:PF00877)(图1a)。NlpC/P60家族内肽酶中催化所必需的残基(Cys、His、Asp)在Ecd09610中也保守存在(补充材料图S1)。编码Ecd09610及其结构域的基因被克隆到能够在N端融合His标签的大肠杆菌表达载体(pColdII)中。全长区域(Ecd09610)、糖苷酶结构域(Ecd09610CD53)、内肽酶结构域(Ecd09610CD3)以及含有两个催化域的C端结构域(Ecd09610CD1)均成功表达并通过镍亲和层析纯化(图1b)。在Ecd09610CD53、Ecd09610CD3和Ecd09610CD1的纯化中,分别从400 mL培养物中回收了约11.6 mg、3.0 mg和3.7 mg。然而,在野生型的纯化中,纯化本身与各结构域变体的纯化一样成功,但透析后40%的纯化蛋白发生沉淀,仅回收60%(1.1 mg/400 mL培养物)。相比之下,对于Ecd09610CD53、Ecd09610CD3和Ecd09610CD1,透析过程中的蛋白损失为10%。综上所述,将Ecd09610分割为结构域变体显著改善了其溶解性。
为了检测纯化蛋白的裂解和结合活性,以艰难梭菌630为底物进行了浊度降低实验和结合实验。如图1c所示,Ecd09610及各结构域变体均具有裂解活性。与野生型Ecd09610相比,仅含内肽酶结构域的Ecd09610CD3表现出几乎相同的活性,而仅含糖苷酶结构域的Ecd09610CD53表现出较低的裂解活性,含有两个催化域的Ecd09610CD1表现出最高的活性。此外,野生型及各结构域变体对艰难梭菌630的结合活性实验表明,催化域本身即可结合细胞(图1d)。
**图1** Ecd09610、Ecd09610CD1、Ecd09610CD3和Ecd09610CD53的SDS-PAGE分析、裂解活性和结合能力。(a)Ecd09610、Ecd09610CD1、Ecd09610CD3和Ecd09610CD53的示意图。Ecd09610在C端含有糖苷酶(GL)和内肽酶(EP)两个催化域。这些蛋白在N端具有His标签。(b)纯化的Ecd09610、Ecd09610CD1、Ecd09610CD3和Ecd09610CD53的SDS-PAGE分析(各1 μg)。凝胶用考马斯亮蓝R染色。(c)蛋白(0.1 μM)对艰难梭菌630细胞的裂解活性通过浊度降低实验测定。显示了Ecd09610(实心圆)、Ecd09610CD1(空心圆)、Ecd09610CD3(实心三角)、Ecd09610CD53(空心三角)和对照(实心菱形)。(d)纯化蛋白对艰难梭菌630细胞的结合能力。将纯化蛋白和非结合内标(卵清蛋白:Alb)与细胞(+)或不与细胞(-)一起孵育。离心样品后,通过13.5% SDS-PAGE分析上清液。
### 2.2. Ecd09610及其衍生物裂解活性的表征
为了表征Ecd09610及其结构域变体的酶活性,我们以艰难梭菌630为底物,测定了pH、盐、金属离子和温度对裂解活性的影响(图2a-d)。如图2a所示,野生型Ecd09610、Ecd09610CD1和Ecd09610CD53的最适pH为6,而Ecd09610CD3在pH 8时具有最高的裂解活性。值得注意的是,在pH 8时,仅为内肽酶的Ecd09610CD3表现出高裂解活性,而在含有两个催化域的Ecd09610CD1和Ecd09610中,内肽酶的活性被抵消。这一现象在pH 7及以上时可见。在pH 6和5时,糖苷酶和内肽酶协同作用,Ecd09610CD1的两个结构域表现出叠加的裂解活性。
**图2** 通过浊度降低实验测定的Ecd09610、Ecd09610CD1、Ecd09610CD3和Ecd09610CD53对艰难梭菌630的裂解活性。裂解活性在30分钟后按以下公式计算:[ΔOD₆₀₀测试(添加蛋白)− ΔOD₆₀₀对照(仅缓冲液)]/μmol蛋白。(a)使用硼酸盐-磷酸盐通用缓冲液测定裂解活性的最适pH。将Ecd09610CD3在pH 6.0时的相对活性设为1。(b)使用25 mM Tris-HCl(pH 7.0)测定NaCl对裂解活性的影响。将Ecd09610CD1在75 mM NaCl时的相对活性设为1。显示了Ecd09610(实心圆)、Ecd09610CD1(空心圆)、Ecd09610CD3(实心三角)和Ecd09610CD53(空心三角)。(c)通过添加1 mM CaCl₂、MgCl₂、ZnCl₂、MnCl₂、CuCl₂或EDTA测定二价金属阳离子对裂解活性的影响。相对活性以无二价阳离子时的活性为1表示。无二价阳离子时的裂解活性分别为35,011(Ecd09610CD1,白色)、16,788(Ecd09610CD3,灰色)和11,190(Ecd09610CD53,黑色)。(d)裂解活性的热稳定性通过在37、45、60、75或100 °C热处理10分钟后或不经处理测定裂解活性来确定。将Ecd09610CD1、Ecd09610CD3和Ecd09610CD53未经处理时的相对活性设为1。未经处理时的裂解活性分别为104,200(Ecd09610CD1,白色)、62,917(Ecd09610CD3,灰色)和5288(Ecd09610CD53,黑色)。所有实验的均值均基于三次独立实验计算。标准偏差通过三次独立实验(每次含三个重复样品)计算。
还检测了盐(NaCl)浓度对Ecd09610及各结构域变体裂解活性的影响(图2b)。Ecd09610和Ecd09610CD53在50 mM以下表现出高裂解活性,在50 mM以上活性降低,在150 mM以上几乎没有活性。在Ecd09610CD1和Ecd09610CD3中,裂解活性在75 mM时最高。此外,Ecd09610CD1的活性在75 mM以上降低,而Ecd09610CD3的活性在200 mM以下未降低。另外,还检测了金属离子的影响(图2c)。添加CaCl₂和乙二胺四乙酸对裂解活性无显著影响,但添加MgCl₂略微增加活性,添加ZnCl₂、MnCl₂和CuCl₂则显著降低裂解活性。
为了阐明各结构域变体的热稳定性,我们测量了在不同温度下预孵育10分钟的纯化蛋白的活性(图2d)。结果显示,Ecd09610CD1和Ecd09610CD3的活性随温度升高而显著降低,但在60 °C以上仍保持一定活性。然而,仅含糖苷酶结构域的Ecd09610CD53活性较低,但在高达100 °C的条件下活性未降低。
### 2.3. Ecd09610衍生物的细菌特异性
一般而言,噬菌体内溶素表现出种属特异性裂解活性[13]。因此,以各种细菌菌株为底物,通过浊度降低实验测定了各结构域的种属特异性(表1和图S2)。三个结构域变体均对三株艰难梭菌表现出裂解活性。Ecd09610CD3还对溶组织梭菌(*Clostridium histolyticum*)、多枝梭菌(*Clostridium ramosum*)、破伤风梭菌(*Clostridium tetani*)、洞穴口杆菌(*Atopobium fossor*)和枯草芽孢杆菌(*Bacillus subtilis*)表现出较弱的裂解活性,但对本研究测试的其他革兰氏阳性菌无裂解活性。Ecd09610CD1和Ecd09610CD53除对上述细菌外,还对诺维氏梭菌(*Clostridium novyi*)表现出较弱的裂解活性。还测试了结合的种属特异性(图S3)。三个结构域变体与本研究测试的大多数细菌结合,但Ecd09610CD3和Ecd09610CD53对产气荚膜梭菌(*Clostridium perfringens*)和柱状真杆菌(*Eubacterium cylindroides*)的结合活性降低。
**表1** Ecd09610结构域变体裂解活性的种属特异性。
| 细菌 | 相对活性(%) | | | |---|---|---|---| | | Ecd09610CD1 | Ecd09610CD3 | Ecd09610CD53 | | *C. difficile* 630 | 100.0 ± 14.1 | 100.0 ± 20.8 | 100.0 ± 10.00 | | *C. difficile* ATCC43255 | 104.9 ± 9.00 | 97.6 ± 15.6 | 15.6 ± 5.20 | | *C. difficile* ATCC9689 | 101.7 ± 21.8 | 119.3 ± 21.0 | 96.3 ± 21.0 | | *C. acetobutylicum* ATCC824 | −10.2 ± 0.90 | −6.8 ± 4.10 | −16.9 ± 4.90 | | *C. coccoides* ATCC29236 | −1.3 ± 0.70 | −0.8 ± 0.90 | −2.3 ± 7.40 | | *C. histolyticum* JCM1403 | 12.6 ± 4.30 | 8.1 ± 2.10 | 5.8 ± 1.50 | | *C. lituseburense* ATCC25759 | 3.0 ± 5.10 | 4.5 ± 3.80 | 3.3 ± 1.50 | | *C. novyi* ATCC17861 | 22.4 ± 11.0 | −2.3 ± 6.10 | 10.9 ± 17.40 | | *C. perfringens* strain13 | 5.6 ± 0.60 | 1.3 ± 3.50 | 3.7 ± 5.20 | | *C. ramosum* ATCC25582 | 65.3 ± 1.70 | 17.3 ± 2.90 | 7.5 ± 2.30 | | *C. tetani* KZ1113 | 34.8 ± 3.00 | 38.9 ± 1.00 | 11.0 ± 1.80 | | *A. fossor* ATCC43386 | 15.0 ± 2.20 | 11.0 ± 2.50 | 5.0 ± 2.00 | | *B. adolescentis* ATCC15703 | 0.3 ± 2.10 | −2.4 ± 3.50 | −4.9 ± 0.80 | | *E. cylindroides* ATCC27805 | 1.4 ± 5.00 | −2.6 ± 2.20 | −2.3 ± 2.60 | | *B. subtilis* ATCC6633 | 16.8 ± 3.20 | 8.9 ± 10.0 | 8.5 ± 3.90 | | *S. aureus* FDA209P | 1.8 ± 1.90 | 2.6 ± 2.00 | −1.1 ± 4.90 |
裂解活性在10分钟后按以下公式计算:{ΔOD₆₀₀测试(添加0.14 μM Ecd09610CD1、0.2 μM Ecd09610CD3或0.3 μM Ecd09610CD53)− ΔOD₆₀₀对照(仅缓冲液)}/μmol蛋白。细菌的相对活性以*C. difficile* 630的裂解活性为100%表示。所有实验的均值和标准偏差均通过三次独立实验(每次含三个重复样品)计算。*C. difficile* 630的裂解活性[{ΔOD₆₀₀测试 − ΔOD₆₀₀对照(仅缓冲液)}/μmol蛋白]分别为12,858(Ecd09610CD1)、7957(Ecd09610CD3)和6102(Ecd09610CD53)。
### 2.4. Ecd09610衍生物的长期稳定性
对于用作药物的酶,需要验证其长期稳定性和干燥条件下的稳定性。将纯化的各Ecd09610衍生物冻干,在室温或4 °C下保存,然后重新溶解于水中以测定其裂解活性(图3)。三个结构域变体均未因冻干而丧失活性。Ecd09610CD1在4 °C保存4周后活性略有下降,但其他两个结构域变体的活性未降低。此外,在室温保存4周后,Ecd09610CD1和Ecd09610CD3的活性分别下降约49%和40%,但Ecd09610CD53的活性未降低。
**图3** 冻干对蛋白裂解活性的影响。将Ecd09610CD1(0.08 μM)、Ecd09610CD3(0.15 μM)和Ecd09610CD53(0.3 μM)或缓冲液添加到细胞中,在30分钟内以1分钟间隔测量OD₆₀₀。显示了未冻干蛋白(绿色)、冻干蛋白(蓝色)、冻干后在4 °C保存4周(黄色)、冻干后在室温保存4周(灰色)和缓冲液(黑色)。
## 3. 讨论
通过艰难梭菌630基因组中糖苷酶和内肽酶的同源性搜索,鉴定出基因ecd09610(基因ID CD09610)。该基因产物与最近报道的艰难梭菌噬菌体phiMMP01的内溶素CWH非常相似[22]。Ecd09610与CWH在N端未表征结构域、糖苷酶结构域和内肽酶结构域的相似性和一致性分别为98%和90%、87%和65%、99%和99%(图S1)。在Ecd09610基因周围还存在与噬菌体相关的基因(图S4)。这表明类似phiMMP01的噬菌体曾感染并在艰难梭菌630中溶原化。
测定了野生型Ecd09610及其结构域变体对艰难梭菌630的裂解活性,结果显示Ecd09610CD1每分子活性最高,野生型和Ecd09610CD3相当,Ecd09610CD53最低(图1c)。这些结果与Mondal等人的结果相似[22]。由于各结构域变体即使在没有N端未表征结构域(即推定结合域[22])的情况下也能与艰难梭菌结合,催化域可能对底物具有高亲和力(图1d)。此外,缺乏N端未表征结构域的Ecd09610CD1比野生型表现出更高的活性。我们还认为该结构域不是有意义的结合域,因为Mondal等人报道该区域与噬菌体尾部蛋白具有相似性[22]。为了验证缺乏推定结合域的结构域变体是否更具活性,我们单独克隆并纯化了Ecd09610的N端未表征结构域,并对艰难梭菌630进行了细胞结合实验。我们发现N端未表征结构域与艰难梭菌630有轻微结合(图S5)。综上所述,这些数据表明N端未表征结构域可能阻止催化域与艰难梭菌630的正常结合,从而降低其裂解活性。未来有必要阐明该未表征结构域的功能。
各结构域变体最适pH的实验结果较为复杂。值得注意的是,内肽酶在pH 8时活性最高,但尽管Ecd09610CD1和野生型含有内肽酶结构域,它们在pH 8时的活性却大幅降低(图2b)。这可能是由于在pH 8时不表现出裂解活性的糖苷酶与细胞结合,导致内肽酶与细胞的结合减少,从而降低了内肽酶的裂解活性。这些数据表明糖苷酶的底物亲和力高于内肽酶。当单独使用内肽酶裂解细菌时,最有效的pH为pH 8;当与糖苷酶单独或一起使用时,最有效的pH为pH 6。
此外,关于盐的影响,野生型、Ecd09610CD1和Ecd09610CD53在高盐浓度(>100 mM)下活性的降低被认为是由糖苷酶活性和与细胞结合能力降低所致(图S6)。然而,艰难梭菌感染患者患有严重腹泻,而结肠作为艰难梭菌感染的部位,被认为有炎症伴液体渗入肠道,因此该部位的盐浓度被认为与生理盐水相当或更低。因此,在低盐浓度下起作用的内溶素应该是有效的。
耐热性研究结果显示,有趣的是,Ecd09610结构域变体对高温具有相对抗性,特别是Ecd09610CD53在100 °C加热10分钟后未失活,Ecd09610CD1在45 °C以上的活性似乎来自糖苷酶结构域。这种热稳定性是由于复性速度还是蛋白质本身的耐热性尚不清楚,但我们打算通过进一步的结构分析来阐明这一问题。此外,Ecd09610的结构域变体不会因冻干而丧失活性,可在干燥状态下于4 °C长期保存(图3)。这些特性可能有利于其作为抗菌剂的制剂开发。此外,难以大量获得纯化的野生型内溶素;然而,纯化的结构域变体可以容易地以可溶形式大量获得。结构域变体的这一特性在工业生产中也是一个优势。
Ecd09610的结构域变体对某些细菌具有较弱的裂解活性,但它基本上是一种艰难梭菌特异性内溶素(表1)。种属特异性的机制已知取决于结合域[14,15]或底物识别沟的结构[16]。在Ecd09610的情况下,其底物特异性机制被认为是后者,即取决于底物识别沟的结构,因为Ecd09610的各种结构域变体即使在没有结合域的情况下与多种细菌结合,仍表现出对艰难梭菌的特异性裂解活性。为了阐明种属特异性机制,我们打算对每个结构域进行结构分析。这种对艰难梭菌的特异性可用于开发不影响肠道菌群即可治疗艰难梭菌感染性疾病(如伪膜性结肠炎)的抗菌剂。然而,将Ecd09610CD53用作抗菌剂的问题在于其裂解活性较低,因此可能需要创建具有增强裂解活性的突变体。为此,需要确定催化域的结构并阐明构成其活性中心的氨基酸。然后,可以通过替换氨基酸构建突变体,使活性中心结构更具催化活性。此外,我们希望通过基于结构信息的氨基酸替换来增加对蛋白酶的耐受性。据报道,组合具有不同裂解位点的裂解酶可产生协同效应[41,42]。在Ecd09610CD1中,每个具有不同裂解位点的催化域是连接的,因此我们认为它们可能协同作用,两个结构域的连接可能有意义。因此,我们比较了Ecd09610CD1与同时添加的Ecd09610CD3和Ecd09610CD53的裂解活性(图S7)。结果表明,它们在反应初始阶段似乎协同作用,但最终的裂解活性被认为是叠加的。未观察到两个催化域连接的效果。这一结果可能是由于糖苷酶活性较低以及各催化域最适pH和盐浓度的差异所致。
## 4. 材料与方法
### 4.1. 质粒构建
使用Tks Gflex™ DNA聚合酶(TakaRa Bio株式会社,日本滋贺县),采用重叠延伸PCR方法[43]构建N端His标签Ecd09610的表达载体。使用补充表S1中列出的引物和艰难梭菌630基因组DNA作为模板进行PCR。将第二次PCR产物用Nde I和Bam HI消化,然后克隆到表达载体pColdII(TakaRa Bio株式会社)的Nde I-Bam HI位点。所得质粒命名为pColdIICD09610。表达糖苷酶和内肽酶、仅糖苷酶和仅内肽酶的质粒(分别为pColdIICD09610CD1、pColdIICD09610CD53和pColdIICD09610CD3)以相同方法使用补充表S1中列出的引物和pColdIICD09610作为模板构建。所有构建体中的PCR扩增片段均使用ABI PRISM 3130xl基因分析仪(Thermo Fisher Scientific,美国马萨诸塞州沃尔瑟姆)进行验证。
### 4.2. 蛋白制备
将用pColdIICD09610、pColdIICD09610CD1、pColdIICD09610CD3或pColdIICD09610CD53转化的大肠杆菌BL21-CodonPlus-RIL在含有0.2%(w/v)葡萄糖、0.2%(w/v)胰蛋白胨、0.001%硫胺素、100 μg/mL氨苄青霉素、30 μg/mL氯霉素和10 μg/mL四环素的M9培养基中于37 °C培养至对数中期,然后在冰上孵育30分钟。加入终浓度为1 mM的异丙基-β-D-硫代半乳糖苷后,将细胞在15 °C进一步孵育20-24小时。将收获的细胞悬浮在缓冲液A(50 mM Tris-HCl,pH 7.0,500 mM NaCl和20 mM咪唑)中,将悬浮液在冰上超声破碎30秒,共五次,功率等级5,使用超声破碎仪(UD-200,TOMY株式会社,日本东京)。然后将悬浮液在4 °C以22,300×g离心10分钟,上清液用0.2 μm孔径注射器过滤器(Minisart®,Sartorius,德国哥廷根)过滤。将蛋白溶液施加到Ni⁺螯合琼脂糖快速流速柱(GE Healthcare Bio-Sciences AB,瑞典乌普萨拉)上。用缓冲液A洗涤柱子,然后用50-350 mM咪唑的阶梯梯度或线性梯度洗脱。将树脂洗脱液针对缓冲液B(25 mM磷酸盐缓冲液,pH 6.0,100 mM NaCl和10%甘油,用于CD09610)或缓冲液C(25 mM Tris-HCl,pH 7.0,100 mM NaCl和10%甘油,用于其他)透析,并用0.2 μm注射器过滤器过滤。
### 4.3. 裂解活性实验
蛋白裂解活性采用Gerova等人的方法进行实验,并做了一些修改[44]。简而言之,将在TY培养基中培养的艰难梭菌菌株和在GAM培养基中培养的其他菌株于37 °C培养16小时,洗涤两次并重悬于洗涤缓冲液(25 mM Tris-HCl,pH 7.0)中,然后调整至1.25 OD₆₀₀/mL。通过将20 μL蛋白或实验缓冲液加入到180 μL预孵育的细胞悬浮液中开始裂解活性测定。在37 °C以1分钟间隔测量其OD₆₀₀(SpectraMax® M5e多模式微孔板读数仪,Molecular Devices Corp.,美国加利福尼亚州桑尼维尔)。在热稳定性测试中,样品加热10分钟,然后在室温下放置几分钟再进行测量。
### 4.4. 细胞结合实验
使用纯化的Ecd09610、Ecd09610CD1、Ecd09610CD3和Ecd09610CD53进行细胞结合实验。将纯化的蛋白和卵清蛋白与热灭活细胞一起或不与细胞一起在结合缓冲液(25 mM Tris pH 7.0)中于冰上孵育15分钟,缓冲液中含有100 mM NaCl(图1d)或不含NaCl(图S3)。将样品在4 °C以22,300×g离心3分钟。向上清液中加入SDS-PAGE样品缓冲液,将混合物在95 °C孵育5分钟,然后进行SDS-PAGE分析。
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**补充材料**
以下支持信息可在https://www.mdpi.com/article/10.3390/antibiotics11081131/s1下载:图S1:Ecd09610催化域的多序列比对;图S2:Ecd09610CD1、Ecd09610CD3和Ecd09610CD53裂解活性的种属特异性;图S3:Ecd09610CD1、Ecd09610CD3和Ecd09610CD53与各种细菌的结合实验;图S4:艰难梭菌630基因组中ecd09610(CD09610)周围的基因;图S5:纯化的Ecd09610 N端未表征区域与艰难梭菌630细胞的结合能力;图S6:NaCl对纯化蛋白与艰难梭菌630结合能力的影响;图S7:两个催化域的影响;表S1:本研究中使用的引物。
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**作者贡献**
E.T.和H.S.构思并主持了本研究;E.T.和H.S.设计实验;H.S.和R.M.构建蛋白表达质粒并纯化蛋白;H.S.、H.Y.和A.Y.进行生化表征;E.T.、H.S.和S.K.撰写论文。所有作者均已阅读并同意论文的发表版本。
**机构审查委员会声明**
不适用。
**知情同意声明**
不适用。
**数据可用性声明**
支持本研究结果的数据可根据要求从通讯作者处获得。
**利益冲突声明**
作者声明无利益冲突。
**资助声明**
本研究部分由日本学术振兴会(JSPS)科学研究费补助金资助(资助编号:18K07131和22K07061)。
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**脚注**
出版商说明:MDPI对已出版地图和机构隶属关系中的管辖权主张保持中立。