SCO6992, a Protein with β-Glucuronidase Activity, Complements a Mutation at the absR Locus and Promotes Antibiotic Biosynthesis in Streptomyces coelicolor

Streptomyces coelicolor is a filamentous soil bacterium producing several kinds of antibiotics. S. coelicolor abs8752 is an abs (antibiotic synthesis deficient)-type mutation at the absR locus; it is characterized by an incapacity to produce any of the four antibiotics synthesized by its parental strain J1501. A chromosomal DNA fragment from S. coelicolor J1501, capable of complementing the abs- phenotype of the abs8752 mutant, was cloned and analyzed. DNA sequencing revealed that two complete ORFs (SCO6992 and SCO6993) were present in opposite directions in the clone. Introduction of SCO6992 in the mutant strain resulted in a remarkable increase in the production of two pigmented antibiotics, actinorhodin and undecylprodigiosin, in S. coelicolor J1501 and abs8752. However, introduction of SCO6993 did not show any significant difference compared to the control, suggesting that SCO6992 is primarily involved in stimulating the biosynthesis of antibiotics in S. coelicolor. In silico analysis of SCO6992 (359 aa, 39.5 kDa) revealed that sequences homologous to SCO6992 were all annotated as hypothetical proteins. Although a metalloprotease domain with a conserved metal-binding motif was found in SCO6992, the recombinant rSCO6992 did not show any protease activity. Instead, it showed very strong β-glucuronidase activity in an API ZYM assay and toward two artificial substrates, p-nitrophenyl-β-D-glucuronide and AS-BI-β-D-glucuronide. The binding between rSCO6992 and Zn2+ was confirmed by circular dichroism spectroscopy. We report for the first time that SCO6992 is a novel protein with β-glucuronidase activity, that has a distinct primary structure and physiological role from those of previously reported β-glucuronidases.

coelicolor [6]. Besides, the global defect in antibiotic synthesis in the absBmutant was due to a deficiency in RNase III (rnc) [7] which regulates the production of antibiotics through its double strand-specific endoRNase activity [8]. Finally, the absC locus exerts pleiotropic, zinc-dependent effects on antibiotic biosynthesis [9]. Interestingly, it was shown that the production of actinorhodin and undecylprodigiosin was abolished when absC was deleted, but this phenomenon was only observed when zinc concentrations were low. AbsC also represses the expression of the coelibactin biosynthetic gene cluster by binding to an operator sequence adjacent to the zinc-responsive regulatory protein Zur binding site [9]. Although these three mutations such as absA -, absB -, and absCare categorized into the same absmutation, the molecular properties of them are quite different, implying that the control machinery for secondary metabolism in Streptomyces is extraordinarily complex [10].
We previously reported on the genetic analysis of a new abs-like mutation at the absR locus of the mutant strain S. coelicolor abs8752 [11]. The absRmutation was complemented with multiple copies of the actII-ORF4 gene encoding for a pathway specific regulator for actinorhodin biosynthesis [3] and by the afsR gene encoding a global regulator for morphological and physiological differentiation [12], but not with absA. Therefore, as absR was considered an abs-type mutation distinct from absAor absBmutations [11], the chromosomal DNA fragment that could complement strain abs8752 for antibiotic biosynthesis was cloned from its parental strain, S. coelicolor J1501. In this fragment, two complete ORFs, namely ORF-1 (equivalent to SCO6992) and ORF-2 (equivalent to SCO6993), were identified. In this report, we describe the functional analysis of the SCO6992 gene; a gene that is able to restore and stimulate antibiotic biosynthesis in S. coelicolor.

Media and Culture Conditions
E. coli was maintained on M9 minimal agar and routinely cultured in Luria broth [13] at 37 o C with agitation. Streptomyces strains were maintained on R2YE agar or liquid medium at 30 o C [13]. For the cultivation of S. coelicolor strains, histidine and uracil were used as supplements at final concentrations of 50 and 7.5 μg/ml, respectively [11].

Enzymes and Chemicals
Restriction endonucleases and other DNA modifying enzymes were purchased from DyneBio Inc. (Korea). Unless specified, any other fine chemical was from Sigma-Aldrich Corporation (USA).

DNA Manipulation and Transformation
DNA preparation and manipulation were performed by the methods described by Kieser et al. [13]. All kits and enzymes were used according to the manufacturer's recommendations. Preparation of competent E. coli cells and transformations were performed as described [13]. Protoplast preparation and PEG-mediated transformation of Streptomyces cells were carried out as described [13]. Streptomyces transformants were selected by overlaying with 0.6% soft agar containing 25 μg/ml of thiostrepton.

Cloning of a DNA Fragment with absR-Complementing Activity
S. coelicolor J1501 was cultured in R2YE medium and used for chromosomal DNA isolation, as described previously [16]. To clone the absRcomplementing DNA fragment, the chromosomal DNA was partially digested with restriction enzyme Sau3A1, and separated elctrophoretically on a 1% agarose gel. The pool of 4-6 kb DNA fragments recovered from the gel was ligated with the pWHM3 vector digested with BamHI to construct a mini library by shotgun cloning. Ligated plasmids were transformed into S. coelicolor abs8752. Among the 1,650 transformants, one colony with an abs + phenotype (pigment production) was selected to isolate the recombinant plasmid, pWHM3-α3, which carried a 3,919-bp insert (GenBank accession number; AF136167) that included two ORFs, according to DNA sequencing analysis (Fig. 1). The two ORFs, ORF-1 and ORF-2, were identified as SCO6992 and SCO6993 annotated from the S. coelicolor A3(2) genome sequence [5], respectively.

Quantitative Analysis of Antibiotic Production
Each ORF was individually subcloned. A SmaI fragment, 1,894 bp long, containing the entire SCO6992 including its promoter region was subcloned into pWHM3 to yield pWHM3-O1. In addition, a SphI-PstI digested fragment, 2,711 bp long, containing the entire SCO6993 and its promoter region was cloned into pWHM3 to yield pWHM3-O2 (Fig. 1). The capacity of producing pigmented antibiotics actinorhodin (blue) and undecylprodigiosin (red) by S. coelicolor and S. lividans TK24 transformants could be easily checked with the naked eye on a solid medium. Quantitation of actinorhodin and undecylprodigiosin in liquid culture was performed as previously described [12]. Briefly, an exponential phase culture of S. coelicolor was transferred to 100 ml of R2YE medium containing 25 μg/ml of thiostrepton in a 500 ml baffled flask, and incubated at 30 o C on a reciprocal shaker. At indicated intervals, 5 ml aliquots of the culture broth were extracted with 5 ml of chloroform for 30 min at 20 o C, with shaking. Then, 5 ml of 1 N NaOH was added, and the tubes were vortexed and spun in a microcentrifuge for 15 s. Actinorhodin, distributed to the aqueous phase, had a blue color at alkaline pH, and was quantified by measuring the absorbance at 640 nm (A 640 ). Undecylprodigiosin had a yellow color at alkaline pH and remained in the chloroform layer; it was acidified with HCl, and turned to red at acidic pH. It was quantified by measuring the A 530 . The concentrations of actinorhodin and undecylprodigiosin were calculated using the molar extinction coefficients ε 640 = 25,320 M -1 cm -1 and ε 530 = 100,150 M -1 cm -1 , respectively.

Expression and Purification of the MBP-SCO6992 Fusion Protein in E. coli
The pMAL-c2x vector was used to express the SCO6992 protein in E. coli. The SCO6992 DNA fragment (1,080 bp long) was amplified by PCR as previously described [17] using primers SCO6992-forward (5'-GTCGACATGACCGCACGCTACTGCTCG-3', the SalI site is underlined) and SCO6992-reverse (5'-AAGCTTTCACCAGTACATGACCGCCGTC-3', the HindIII site is underlined). The amplified fragment was then cloned into pMAL-c2x digested with SalI/HindIII restriction enzymes. The resulting plasmid, pMAL-c2x-SCO6992, was designed to express SCO6992 fused to MalE maltose binding protein (MBP). E. coli JM109/pMAL-c2x-SCO6992 cells were inoculated in 1 L of rich medium (Luria broth containing 0.2% glucose) with ampicillin (50 μg/ml) and cultured at 37°C with shaking. When the optical density (OD 600 ) of the culture broth was 0.4, isopropyl-D-thiogalactopyranoside (0.3 mM) was added to induce SCO6992 expression. After culturing for 3 h, the cells were harvested by centrifugation (7,000 ×g, 10 min, 4°C) and resuspended in buffer A (20 mM Tris-HCl pH 7.4, 200 mM NaCl, 1 mM EDTA, 10 mM β-mercaptoethanol). Cells were then disrupted by sonication and centrifuged at 15,000 ×g for 30 min at 4°C to prepare a cell-free lysate that was used for the purification of the MBP-SCO6992 fusion protein (MBP-SCO6992) by using an MBP.Bind Agarose Resin (ELPIS Biotech, Korea). The purified MBP-SCO6992 protein, eluted with buffer A containing 10 mM maltose, was concentrated using an Amicon ultra centrifugal filter 50K device, followed by a buffer exchange for 10 mM Tris-HCl (pH 7.9) for further experimentation. The purified protein was analyzed by 0.1% sodium dodecyl sulfate-10% polyacrylamide gel electrophoresis (SDS-PAGE).

Circular Dichroism (CD) Spectroscopy Analysis
To investigate the complexes formed between the MBP-SCO6992 protein and different metal ions, CD spectroscopy analysis was performed using a J-815 spectropolarimeter (Jasco Corp., Japan), using a wavelength range of 200-260 nm, and a quartz cell with a path length of 0.1 mm [18]. Scanning was performed 10 times per sample at a scan rate of 100 nm per min. Measurements were done at 20°C, with 1 μg/μl protein and 2 mM metal ion (either Fe 2+ , Zn 2+ , Mn 2+ , Ca 2+ , Mg 2+ , or Cu 2+ ).

Protease Activity Determination
A skim milk hydrolysis assay was performed to detect protease activity. Briefly, 20 μl of purified MBP-SCO6992 was dropped onto a 1% skim milk agar plate, and the formation of a clear zone was observed after incubation at 37°C for 24 h.
The azocasein hydrolysis method was then used to measure the total protease activity of the purified MBP-SCO6992 as follows: 120 μl of protein was mixed with 480 μl of 1% azocasein solution in 25 mM Tris-HCl buffer (pH 8.0), and left to react at 37°C for 30 min. Then, the reaction was terminated by adding 600 μl of a 10% (w/v) trichloroacetic acid solution. After centrifugation at 15,000 ×g for 10 min, 800 μl of the supernatant was taken and mixed with 200 μl of 1.8 N NaOH. The concentration of azo dye, a hydrolysis product, was measured spectrophotometrically at 420 nm (A 420 ). The effect of metal ions on protease activity were also investigated by adding various metal ions to the reaction mixture.

Enzyme Activity Analysis
An API ZYM kit (bioMérieux, France) was used to investigate the enzymatic activity of the purified protein. Following the manufacturer's instructions, 200 μl of purified protein was added to each plate well together with the corresponding reaction reagents. The presence or absence of enzymatic activity was determined according to the resultant color change.
For β-glucuronidase zymographic analysis, protein samples were loaded onto a 9% native polyacrylamide gel. Electrophoresis was performed in 25 mM Tris-HCl (pH 8.1) buffer containing 192 mM glycine, at 4°C and 160 V for 2 h. After washing twice with triple distilled water, the gel was immersed in 100 mL of 0.2 M sodium acetate buffer (pH 5.2) containing 40 mg of naphthol AS-BI-β-D-glucuronide (an artificial substrate) and 40 mg of Fast Garnet, and the color change on the zymogram was observed [20].

Complementation of the absR -Mutation by the pWHM3-α3 Clone
S. coelicolor abs8752 was used as the host strain to identify the gene complementing the absphenotype. First, one thiostrepton-resistant transformant with abs + phenotype on an agar plate was selected, and the recombinant plasmid (named pWHM3-α3) carrying a 4-kb insert was isolated from it ( Fig. 1).
pWHM3-α3 was able to restore actinorhodin and undecylprodigiosin biosynthesis in S. coelicolor abs8752 on R2YE plates ( Fig. 2A). Judging by the color of the bacterial growth, undecylprodigiosin (red color) and Production of pigmented antibiotics by S. coelicolor J1501 (left) and S. coelicolor abs8752 (right) transformants carrying different plasmids. Transformants were grown on R2YE plates for 5 days before being photographed. Compared to wild type S. coelicolor J1501/pWHM3, S. coelicolor abs8752/pWHM3 did not produce any pigment. However, S. coelicolor abs8752/ pWHM3-α3 shows a dark-reddish color, indicating a restoration in the production of pigmented antibiotics. Complementation with individual ORFs showed that only ORF-1 (plasmid pWHM3-O1) could remarkably stimulate antibiotic production (especially actinorhodin pigment) in both strains. (B) Pigmented antibiotic production by S. coelicolor cultured in R2YE broth. Culture samples were taken at regular intervals of time and processed, as described in Materials and Methods. Then, quantification of actinorhodin (left) and undecylprodigiosin (right) was done by measuring the absorbance at 640 and 530 nm, respectively. ○, S. coelicolor J1501/pWHM3; •, S. coelicolor abs8752/pWHM3; ■ , S. coelicolor abs8752/ pWHM3-α3; ▲ , S. coelicolor abs8752/pWHM3-O1; △, S. coelicolor abs8752/pWHM3-O2. All experiments were repeated at least 3 times, and their average values were calculated. actinorhodin (blue color) were mixed, though the final color was more similar to that of undecylprodigiosin than to that of actinorhodin. The transformant also showed that its ability to produce the non-pigmented antibiotics methylenomycin and CDA was restored (data not shown). This result strongly supports that the cloned fragment has the ability to complement the pleiotropic antibiotic production deficiency of S. coelicolor abs8752.

Chromosomal Location of the ORF-1 and ORF-2 in S. coelicolor
We previously reported that the absR locus exists near absA locus on the chromosomal DNA of S. coelicolor. Based on the genomic sequence of S. coelcicolor A3(2), AbsA1 (SCO3225) and AbsA2 (SCO3226) were located between the base sequences 3536945 and 3539347, and ORF-1 (SCO6992) and ORF-2 (SCO6993) were placed between 7759825 and 7762803 of chromosomal DNA. Therefore, it was assumed that absA1/A2 and putative absR1/R2 are separated by more than 4.2 million bp on the chromosome. In addition, the nucleotide sequencing of the DNA fragments revealed that S. coelicolor J1501 and abs8752 strains had the same nucleotide sequence in ORF-1 and ORF-2 coding region. These results clearly indicate that although ORF-1 and ORF-2 can restore the antibiotic-producing ability of absR mutant, they are different from the actual gene corresponding to the absR locus. Therefore, we marked SCO6992 and SCO6993 assigned by genomic sequencing for ORF-1 and ORF-2, respectively.

Gene Dosage Effect of SCO6992 and SCO6993 on Antibiotics Production
The introduction of pWHM3-O1 containing SCO6992 in S. coelicolor abs8752 and S. coelicolor J1501 could restore and remarkably stimulate pigment production (mainly blue) on R2YE plates, respectively; pigment production was not observed among transformants carrying either pWHM3-O2 (containing SCO6993) or pWHM3 ( Fig. 2A).
When the amount of actinorhodin and undecylprodigiosin produced in R2YE liquid media at day 10 was compared, it was seen that S. coelicolor abs8752/pWHM3-O1 produced 24.2 times more actinorhodin than transformants with either pWHM3 or pWHM3-O2, and 8.6 times more actinorhodin than that produced by S. coelicolor abs8752/pWHM3-α3 (Fig. 2B, left). Moreover, the amount of undecylprodigiosin produced by S. coelicolor abs8752/pWHM3-O1 was slightly higher than that produced by S. coelicolor abs8752/pWHM3-α3, and at least 4 times higher than those of the transformants with either pWHM3 or pWHM3-O2 (Fig. 2B, right). This fact clearly indicates that the SCO6992 gene is responsible for inducing the biosynthesis of actinorhodin and undecylprodigiosin in S. coelicolor strains. Interestingly, the stimulatory effect by SCO6992 on antibiotic production (especially on actinorhodin) was severely suppressed by the presence of SCO6992 as shown in S. coelicolor abs8752 and S. coelicolor J1501 transformed with pWHM3-α3, implying that SCO6993 may be a repressor.

In silico Analysis of SCO6992
The top 100 genes with high homology to SCO6992, resulting from a Blastp search (BLAST: Basic Local Alignment Search Tool (nih.gov)), belonged to Streptomyces species; their identity ranged between 77% and 99%. However, they are all annotated as hypothetical proteins and their functions have not been elucidated. For example, SCO6992 has 99% identity with the unidentified AIJ11880.1 protein (361 aa) from S. lividans TK24. Moreover, many hypothetical proteins from various gram-positive and gram-negative bacteria and even fungi were also listed as homologous to SCO6992 with lower scores, suggesting that SCO6992 orthologue is widely distributed in bacteria and other organisms.
Interestingly, SCO6992 has an MMP-like sub-family 3 domain (cd04327), common in zinc-dependent metalloproteases, in the region spanning Ala-33 through Pro-254, with an E-value of 2.36 × e -88 [21]. The MMPlike sub-family 3 domain is constituted by a group of bacterial and fungal metalloprotease domains whose structure is similar to those of matrix metalloproteases and astacin (Fig. 3A). Additionally, SCO6992 has a wellconserved metal binding domain composed of three His-residues that are important elements of the active site of metalloproteases (Fig. 3B) [22].

Expression and Purification of an MBP-SCO6992 Fusion Protein
To investigate its biochemical function, we tried to express SCO6992 in E. coli in various ways. Due to the difficulty in forming inclusion bodies of the protein alone, an MBP-SCO6992 fusion protein was constructed, by linking SCO6992 (39.5 kDa) to MBP (42.5 kDa), to obtain a soluble form in E. coli. The soluble MBP-SCO6992 fusion protein was successively purified by amylose affinity column chromatography. The purified protein had an approximated molecular weight of 82 kDa, as predicted (Fig. 4A).

Analysis of the Metal Binding Ability of the MBP-SCO6992 Protein
Whether SCO6992, which has a metal binding motif, could bind metal ions was investigated using CD spectroscopy. The MBP-SCO6992 protein showed its minimum CD value (mdeg) between 210 and 222 nm.  1-4, left). Then, the recombinant protein was purified from the cell-free extract by an amylose-affinity column chromatography (lanes 5-8, right). The MBP-SCO6992 protein is indicated by arrows. Lanes: M, molecular weight size markers; 1, E. coli JM109/pMAL-c2x before induction; 2, E. coli JM109/pMAL-c2x after induction; 3, E. coli JM109/pMAL-c2x-SCO6992 before induction; 4, E. coli JM109/pMAL-c2x-SCO6992 after induction; 5, cell-free extract of E. coli JM109/pMAL-c2x-SCO6992 after induction; 6, sample after being passed through column; 7, sample after washing the column; 8, purified MBP-SCO6992 protein.  However, after reacting with Zn 2+ , the intensity of the CD band within this wavelength range decreased, suggesting that the secondary structure of the protein had changed after binding Zn 2+ (Fig. 4B). Furthermore, no significant changes in the CD spectrum were observed that could indicate that the protein was binding any other of the metal ions tested (Fe 2+ , Mn 2+ , Mg 2+ ) (data not shown). These data suggested that SCO6992 might be a zincbinding metalloprotein.

Analysis of the Protease Activity of the MBP-SCO6992 Protein
Based on in silico analyses and the confirmation of its zinc-binding ability, SCO6992 was presumed to be a zincdependent metalloprotease. In a protease activity test (Fig. 5A), pronase, a commercially available protease mixture, showed a large hydrolysis zone in skim milk agar plate tests, whereas SCO6992 did not show any hydrolysis activity. When the protease activity was measured toward azocasein, pronase also showed a strong activity that increased by the presence of Mg 2+ . In contrast, no protease activity was shown by SCO6992 regardless of the presence or absence of metal ions, including Zn 2+ (Fig. 5B). The above reactivity trend was the same for other substrates such as artificial substrates for trypsin and chymotrypsin (data not shown). Therefore, we determined that SCO6992 was not a metalloprotease.

β-Glucuronidase Activity of SCO6992
In an attempt to identify any enzymatic activity of the SCO6992 protein, we used an API ZYM kit, which analyzes 19 different enzymatic activities, and is routinely used for microbial identification. As a result, a weak acid phosphatase activity and a strong β-glucuronidase activity were detected in MBP-SCO6992 (Fig. 6A). To confirm these results, we further searched for acid phosphatase activity using 2-naphthyl phosphate, an artificial substrate, but no activity was observed regardless of the presence or absence of Zn 2+ ions (data not shown). However, when measuring β-glucuronidase activity using p-nitrophenyl-β-D-glucuronide as substrate, a strong activity was detected (Fig. 6B). Noteworthy, the β-glucuronidase activity of MBP-SCO6992 was slightly increased by the presence of Zn 2+ ions, but the difference was not significant.
Moreover, a zymographic analysis on native polyacrylamide gel confirmed that the purified MBP-SCO6992 protein had β-glucuronidase activity on an artificial substrate such as AS-BI-β-D-glucuronide. Especially, the active band was not observed in the total protein samples obtained from E. coli JM109/pMAL-c2x, but was clearly observed in the total protein samples obtained from E. coli JM109/pMAL-c2x-SCO6992, implying that the βglucuronidase activity of the transformant was caused by heterologous expression of MBP-SCO6992 (Fig. 6C). All these results suggest that SCO6992 is a protein having β-glucuronidase activity and has a great influence on the biosynthesis pathways of the secondary metabolism in S. coelicolor.

Discussion
S. coelicolor is the best characterized strain at both the molecular and genetic levels among the species of the genus Streptomyces. Because it can produce two kinds of pigmented antibiotics, mutants which simultaneously block the biosynthesis of more than one antibiotic can be easily selected with the naked eye, and thus several classes of mutants have been reported in S. coelicolor. For instance, a simultaneous loss of the capacity of synthesizing antibiotics and of morphological differentiation was reported in the bldmutant [3]. However, mutants like abs -, aba -, and afsare pleiotropically defective in antibiotic synthesis but have an almost normal To determine its total protease activity, purified MBP-SCO6992 aliquots were dropped onto a 1% skim milk agar plate, and the formation of clear zones was observed after incubation at 37°C for 24 h. (B) Azocasein hydrolysis assay. The total protease activity of MBP-SCO6992 toward azocasein (1%) was measured spectrophotometrically at 420 nm (A 420 ) after running a reaction at 37°C for 30 min. The effect of metal ions on protease activity was also investigated by adding various metal ions to the reaction mixture. In both (A) and (B), pronase, a commercially available protease mixture, was used as the positive control. All experiments were repeated at least 3 times, and their average values were calculated. morphological development [7,4,23,24].
In this study, we cloned a DNA fragment that restored the ability to produce four antibiotics in S. coelicolor abs8752, a new abs --type mutant [11]. Of the two putative genes in the clone, SCO6992 but not SCO6993 could stimulate antibiotic production in S. coelicolor strains. Furthermore, we observed that SCO6992 also stimulated the production of pigmented antibiotics in S. lividans TK24 to the same extent as in S. coelicolor (data not shown). Phylogenetically, S. lividans is known to be closely related to S. coelicolor, but the biosynthetic genes for actinorhodin and undecylprodigiosin commonly found in S. lividans are usually silent [23]. Like many regulatory genes, such as afsR, afsK, afsQ, absA, and ptpA, SCO6992 highly induced antibiotic biosynthesis in S. lividans, leading us to conclude that SCO6992 played a global regulatory role in antibiotic production in both Streptomyces strains.
The presence of a metalloprotease domain with a putative metal binding motif led us to assume that SCO6992 might be a metalloprotease. Given that several studies have reported that the expression of some proteases have a great influence on both morphological differentiation and the secondary metabolism of Streptomyces strains [17,35], our hypothesis seemed plausible. However, no metalloprotease activity was detected in the purified MBP-SCO6992 fusion protein. Instead, we concluded that SCO6992 is a β-glucuronidase through enzymatic and zymographic assays. β-glucuronidases belong to the glycosidase family 2 of proteins, and are known to hydrolyze complex carbohydrates. In humans, β-glucuronidases hydrolyze glycosaminoglycans, releasing β-D-glucuronic acid residues from their non-reducing end. Increasing pathological evidence has indicated that β-glucuronidases in humans may be sensitive indicators for early identification of cell damage. In fact, an increase in β-glucuronidase levels has been reported in many pathological conditions, such as liver cirrhosis, inflammations, cholestatic jaundice, neoplasms, and tuberculosis [36].
Currently, functional studies on β-glucuronidases in prokaryotes seem to be very rare. The gusA gene (NP_416134) encoding β-glucuronidase (GUS) in E. coli has been widely used as a reporter gene to measure gene expression levels from specific promoters. However, studies on β-glucuronidase enzymes or D-glucuronic acid in Streptomyces are not available in Medline. Rather, it has been reported that Streptomyces does not have any GUS [37], implying that GusA homologues have not been found in this genus.
The amino acid sequences of SCO6992 (359 aa long) and GUS from E. coli (603 aa long) are not similar. Moreover, SCO6992 does not show any homology with any of the previously reported β-glucuronidases. Therefore, SCO6992 should be considered as a novel protein with β-glucuronidase activity. Interestingly, gusA from E. coli has been frequently used as a reporter gene in S. lividans TK24 [37,38] and S. coelicolor [39], however its ability to stimulate pigment production has never been reported.
We placed a paper disc soaked in D-glucuronic acid on a plate spread with spores of S. coelicolor and S. lividans, and searched for changes in pigment production while incubating it. However, no significant difference in color or growth was detected around the disc (Fig. S1). This suggests that the effect of SCO6992 on stimulating antibiotic production is not due to D-glucuronic acid, but to other still unknown substrate modified by the enzyme.
Current knowledge cannot explain how the β-glucuronidase activity of the SCO6992 protein stimulates secondary metabolic pathways. Therefore, studies searching for the intracellular substrate of the SCO6992 protein and on the metabolic pathway linking such substrate with the biosynthesis of antibiotics are needed. These efforts will provide new clues to the functional identification of SCO6992 orthologues, presently listed as hypothetical proteins.