key: cord-0026176-x66xg5eq authors: Guallar-Garrido, Sandra; Almiñana-Rapún, Farners; Campo-Pérez, Víctor; Torrents, Eduard; Luquin, Marina; Julián, Esther title: BCG Substrains Change Their Outermost Surface as a Function of Growth Media date: 2021-12-29 journal: Vaccines (Basel) DOI: 10.3390/vaccines10010040 sha: 5be320a82cd2099e54ca3b424dfec43d514bba18 doc_id: 26176 cord_uid: x66xg5eq Mycobacterium bovis bacillus Calmette-Guérin (BCG) efficacy as an immunotherapy tool can be influenced by the genetic background or immune status of the treated population and by the BCG substrain used. BCG comprises several substrains with genetic differences that elicit diverse phenotypic characteristics. Moreover, modifications of phenotypic characteristics can be influenced by culture conditions. However, several culture media formulations are used worldwide to produce BCG. To elucidate the influence of growth conditions on BCG characteristics, five different substrains were grown on two culture media, and the lipidic profile and physico-chemical properties were evaluated. Our results show that each BCG substrain displays a variety of lipidic profiles on the outermost surface depending on the growth conditions. These modifications lead to a breadth of hydrophobicity patterns and a different ability to reduce neutral red dye within the same BCG substrain, suggesting the influence of BCG growth conditions on the interaction between BCG cells and host cells. One hundred years after being developed, Mycobacterium bovis bacillus Calmette-Guerin (BCG) is still the preferred prophylactic option for preventing tuberculosis (TB) worldwide. BCG vaccine effectiveness appears to be influenced by several factors including the genetic background and/or immune status of the vaccinated population, BCG substrain used as a vaccine, interference with environmental nontuberculous mycobacteria, etc. [1] . The same paradigm is found when BCG is used to treat bladder cancer (BC) patients, in which approximately 25-30% of them are unresponsive to BCG. To understand the variability of efficacy, a comparison of BCG vaccines needs to be performed using exactly the same parameters through in vitro, ex vivo, and in vivo experiments and in clinical trials to obtain reliable and comparable results. Currently, BCG vaccines comprise several substrains that present genetic differences [1] and, consequently, different phenotypic characteristics. However, modifications to phenotypic characteristics can also be influenced by culture conditions [2] . Accordingly, mycobacteria are prone to lose the ability to synthesize cell wall lipids, which are costly and unnecessary in vitro. To obtain high BCG production, BCG is traditionally grown as a pellicle on the surface of Sauton liquid medium. Cells are then collected, suspended in an aqueous solution, and lyophilized. After several drawbacks such as the loss of viability due to aggressive pellicle disruption [3] , freeze-drying steps, or the difficulty of ensuring reproducibility Vaccines 2022, 10, 40 2 of 8 among batches, the WHO established protocols for standardizing BCG production [4] . However, other parameters, such as the specific compositions of the culture media, are not systematically regulated. Subsequently, different formulations for BCG growth are currently used. A proper comparison among BCG substrains is essential for TB or BC, and BCG is also a plausible tool for the treatment of many immunological disorders, different cancers [5] , and diabetes, as well as nonspecific protection against a broad spectrum of pathogens by inducing trained immunity [6] . Thus, the influence of culture conditions on BCG characteristics needs to be elucidated more than ever. Here, we focused our research on mycobacterial superficial characteristics, because they govern host immune system-mycobacteria interactions. We evaluated the presence of lipids such as phthiocerol dimycocerosates (PDIMs) or phenol glycolipid (PGL), which are distinctively expressed among BCG substrains [7, 8] , physicochemical properties such as hydrophobicity, and the neutral red reducing power of five different BCG substrains grown on two Sauton formulations currently used for BCG production. The BCG substrains Phipps (ATCC 35744) and Tice (ATCC 27289) strains were purchased from the Spanish Type Culture Collection and from the German Collection of Microorganisms and Cell Cultures, respectively. BCG Moreau, BCG Pasteur, and BCG Glaxo were kindly given to us by Dr. Carlos Martin (Zaragoza, Spain), Dr. Maria Jesús García (Madrid, Spain), and by Dr. Jun Liu (Toronto, ON, Canada), respectively. All BCG strains were maintained on Middlebrook 7H10 agar (Difco Laboratories, Surrey, UK) supplemented with 10% oleic-albumin-dextrose-catalase enrichment medium at 37 • C. A suspension of each BCG substrain in phosphate-buffer saline was prepared, and 0.3 mL of the suspension containing 1.5 × 10 6 CFU was carefully added to the surface of each liquid medium. Then, BCG substrains were cultured as pellicles under static conditions in glass bottles containing two formulations of Sauton medium (asparagine plus 60 mL/L glycerol (A60) and glutamate plus 15 mL/L glycerol (G15)) as previously described [9] for 4 weeks at 37 • C. Macroscopic appearance is shown in Supplementary Figure S1 . Escherichia coli (ATCC 25922), used as a negative control for hydrophobicity experiments, was cultured in Luria-Bertani medium for one day at 37 • C. To extract superficial lipids from BCG pellicles obtained after static incubation, 20 mL of petroleum ether (40-60 • , PE) was added to the top of the pellicle and rested for 5 min. Then, this PE was recovered, evaporated and analyzed by thin-layer chromatography (TLC). TLC plates were eluted with PE (60-80 • C):diethyl ether (90:10, v/v) or chloroform:methanol (96:4, v/v) and were revealed by spraying with 10% molybdophosphoric acid in ethanol and heating the plates at 120 • C [10] . Three independent pellicles for each condition were analyzed. Neutral red staining was performed on mycobacteria obtained from three independent pellicles for each condition, as previously described [11] . BCG pellicles were filtered, dried, and transferred to glass tubes, and two washes with phosphate urea magnesium sulphate (PUM) buffer were performed [12] . Then, 3 mL of the suspensions were transferred to a new tube containing 2.4 mL of hexadecane vortexed and incubated at 37 • C for 8 min. After 15 min at room temperature (RT), the bottom phase was recovered, and the OD was measured at 400 nm (Infinite 100 PRO, Tecan, Switzerland). The percentage of hydrophobicity was obtained by comparing the OD values of the bacterial Vaccines 2022, 10, 40 3 of 8 suspension with or without hexadecane. Three independent pellicles for each condition were analyzed. BCG cell pellets were resuspended in 300 µL of TE buffer (10 mM Tris-HCl, 1 mM EDTA, pH 8) plus lysozyme (0.4 g/mL). After 5 min at RT, 300 µL of lysis buffer plus β-mercaptoethanol (20 µL/mL) (Sigma-Aldrich, St. Louis, MI, USA) and glass beads (150-200 µm) were added to the tubes. These tubes were heavily shaken through four cycles of 50 s in a rotor stator homogenizer (IKA, Staufen, Germany), and RNA extraction was performed following the GeneJET RNA Purification Kit (Thermo Fisher Scientific, Madrid, Spain). The isolated RNA was treated with 10xTURBO DNase (Life Technologies, Carlsbad, CA, USA), quantified and reverse-transcribed to cDNA using Maxima Reverse Transcriptase (Thermo Fisher Scientific) along with random hexamer primers (Thermo Fisher Scientific). Expression of genes (papA5 and ppsA) involved in the production of PDIM/PGL, and gene Rv0577 responsible for CFP32 protein synthesis, were analyzed by qRT-PCR using PowerUp™ SYBR™ Green Master Mix (Applied Biosystems, Foster City, CA, USA) in a StepOnePlus™ Real-Time PCR System (Applied Biosystems) according to the manufacturer's protocol applying a comparative Ct (∆∆Ct) as quantification method. The primers used in all qRT-PCRs are listed in Supplementary Table S1, results were normalized using the expression of 16S rRNA housekeeping gene. Two independent pellicles for each condition were analyzed. All experiments were performed with at least two (RT-PCR analysis) or three (lipids and hydrophobicity studies) different cultures of each BCG substrain. The hydrophobicity experimental results were analyzed using an ANOVA test, respectively, with GraphPad Prism 9.0 software (San Diego, CA, USA). The data represent the mean ± standard deviation (SD). p < 0.05 was considered significant. As shown by TLC ( Figure 1A ,B and Table 1 ), BCG-Pasteur and BCG-Phipps, which synthesize PDIM and PGL when cultured in 7H10 [8] , also produced these lipids when grown on A60. When the expression of genes involved in the synthesis of PDIM and PGL was assessed [13] , the lipid analysis correlated with a significantly increased expression of ppsA and papA5 genes in both strains grown on A60 compared with those grown on G15 medium ( Figure 1C,D) . However, no traces of PDIM were observed on the BCG-Tice surface when growing in any Sauton composition, despite producing PDIM when cultured on 7H10. BCG-Glaxo was unable to produce PDIM or PGL ( Figure 1A ,B) although high expression of both genes involved in their synthesis was observed ( Figure 1C ). As previously discussed [14] , some still unknown genetic lesions could be responsible for the PDIM/PGL defect in BCG-Glaxo. As expected, BCG-Moreau was unable to produce either PDIM or PGL in any culture media. The deletion of 975 bp that affects in part ppsA in the BCG-Moreau strain leads to PDIM/PGL defects [15] . Additionally, BCG substrains produced glycerol monomycolate (GroMM) only when cultured on A60. Remarkably, the presence of GroMM, PDIM, and PGL on the mycobacterial surface was diminished when mycobacteria grew on G15 compared to their presence on A60. As Figure 1E shows, the cell hydrophobicity increased with increasing glycerol concentration in the culture media. In all cases, cells grown on A60 showed the highest hydrophobicity. When the neutral red dye is prepared in barbital buffer, a color shift from yellow to red is observed in the presence of compounds able to transfer protons to the dye. All tested BCG substrains grown on A60 immediately adopted an intense red coloration, in contrast to the yellowish coloration taken on BCG substrains grown on G15 (Figure 2A ). This result was correlated with a higher expression of the Rv0577 gene, encoding CFP32, in all BCG substrains grown on A60 compared with those grown on G15 ( Figure 2B ). BCG-Phipps (Lines 2 and 2′); BCG-Tice (Lines 3 and 3′); BCG-Glaxo (Lines 4 and 4′); and BCG-Moreau (Lines 5 and 5′). 1-5 BCG substrains grown on A60 Sauton medium and 1′-5′ BCG substrains grown on G15 Sauton medium. (C) Fold ratio of papA5 and ppsA expression in BCG substrains grown on A60 medium relative to that of BCG substrains grown on G15 medium. (D) Scheme of genes involved in PDIM and PGL synthesis. (E) Affinity of BCG substrains towards hexadecane, E. coli was used as a negative control. The results are expressed as a percentage of the initial absorbance at 400 nm. appearance. Data represent the mean ± standard deviation (SD) from three independent experiments. * p < 0.05, **** p <0.0001 (ANOVA test). Table 1 . Superficial lipidic pattern of BCG substrains (Pasteur, Phipps, Tice, Glaxo, and Moreau) grown on two different Sauton compositions (A60 and G15) that differ by amino acid source, Lasparagine (A) or L-glutamate (G), and the glycerol concentration, 60 mL/L (60) or 15 mL/L (15) . PDIM: phthiocerol dimycocerosate; AG: acylglycerol; PGL: phenolic glycolipid; GroMM: glycerol monomycolate. +, present; ++, highly present; +++, abundantly present; -, not present. PDIM A60 +++ ++ - - - G15 - - - - - AG A60 +++ +++ - - + G15 + - - - + PGL A60 ++ + - - - G15 - - - - - GroMM A60 +++ +++ ++ ++ ++ G15 - - + + - When the neutral red dye is prepared in barbital buffer, a color shift from yellow to red is observed in the presence of compounds able to transfer protons to the dye. All tested BCG substrains grown on A60 immediately adopted an intense red coloration, in contrast to the yellowish coloration taken on BCG substrains grown on G15 (Figure 2A ). This result was correlated with a higher expression of the Rv0577 gene, encoding CFP32, in all BCG substrains grown on A60 compared with those grown on G15 ( Figure 2B ). Fold change of Rv0577 expression in BCG substrains grown on A60 medium relative to that of BCG substrains grown on G15 medium. Two independent pellicles for each condition were analyzed. Our results demonstrate that culture media can modify the PDIM/PGL expression, cell wall hydrophobicity, and the neutral red staining of all tested BCG substrains (Pasteur, Phipps, Tice, Glaxo, and Moreau). The lipidic profile of BCG substrains is well known when grown on 7H10 medium [8, 16] , but the usual production of BCG for clinical applications is performed in Sauton media [9, 17] . Here, we describe for the first time a rapid loss of these lipid molecules by BCG after only a shift in culture medium from Middlebrook to Sauton [8] . Previous studies pointed out that consecutive subcultures of M. tuberculosis in Middlebrook Vaccines 2022, 10, 40 6 of 8 medium tended to increase PDIM-depleted mycobacteria [18] , hinting that in vitro cultures could favor the loss of these lipids, which are not necessary for in vitro survival, while maximizing mycobacterial growth. Moreover, the immunostimulatory lipid GroMM [19] was produced only in glycerol-rich media, showing high expression under increasing glycerol concentrations in culture medium [20] . Similar to the relevant role of PDIM/PGL described in M. tuberculosis, the loss of PDIM and PGL in BCG-Pasteur has been associated with a reduction in virulence and protective efficacy against TB [7] . Thus, the same substrain grown under different conditions could trigger different immunomodulatory activities, which are relevant in vaccine efficacy, as demonstrated in a murine model by Venkataswamy and coworkers [21] . In the case of BC, recent studies in our laboratory demonstrated in vitro [9] and in vivo [22] different antitumour effects of BCG-Connaught grown on different media, which could also be related to the superficial characteristics expressed. Our results show that the culture medium also modified mycobacterial surface hydrophobicity. BCG substrains grown on G15 showed significantly less hydrophobicity than those grown on A60, and these observed differences may account for the diminished abundance of lipids. Because BCG-Tice was unable to synthesize PDIM when growing in both Sauton media, GroMM was responsible for the high hydrophobicity. Cell hydrophobicity is related to mycobacterial clump formation, which makes it difficult to achieve a homogeneous suspension in aqueous solution, hindering mycobacteria-host interactions and diminishing BCG efficacy in both TB and BC treatments [17] . Moreover, the necessity of BCG hydrophobicity for TB aerosol vaccination has been recently considered [23] . Additionally, neutral red staining was different among BCG substrains grown on the different culture media. Neutral-red positivity implies the presence of some compounds able to transfer protons to the dye and has been related to virulence in M. tuberculosis [11] . Alterations in the lipidic content of the M. tuberculosis cell wall such as the loss of more than one lipid-containing polymethyl-branched fatty acid [24] lead to a negative neutralred reaction. Here, we observed that all BCG substrains grown on G15 were neutral-red negative, coinciding with those devoid of lipids in the outermost layer. In addition, BCG strains able to produce either PDIM and PGL or a high content of GroMM showed an intense red coloration. Altogether, these results indicate that in BCG, as in M. tuberculosis, the response to neutral red staining could be related to lipid profile modifications, although it cannot be directly attributed to these neutral lipids [24] . Cell wall lipids may confer a structure that allows the entrance of the dye and/or the exposition of other molecules with reducing power capability. CFP32, a protein exclusive to the M. tuberculosis complex [25] , which can be either secreted or present in different mycobacterial cell subfractions, has been related to neutral red staining. The biological function of CFP32 is found in the methylglyoxal detoxification pathway, which is related to glycerol metabolism. Accordingly, M. tuberculosis overproducing CFP32 multiplied 25% faster than the parental strain grown in glycerol-containing medium, suggesting that CFP32 might participate in the detoxification of glycerol metabolism by-products [26] . In our experiments, BCG cells grown on A60 showed the highest red intensity and higher Rv0577 gene expression, which could be related to the abundance of the encoded protein CFP32 [27] . Interestingly, CFP32 regulates the immune response by interacting with TLR2 [28] , which is associated with BCG immunogenicity. Further research is thus needed to clarify the role of this molecule in BCG immunomodulatory capability. One hundred years after BCG development, we are still trying to understand the protective effect against TB disease and the mechanism of BCG in preventing bladder cancer recurrence and progression. Altogether, our results demonstrate that different growth culture media lead to specific outermost surface profiles, providing BCG substrains with specific physico-chemical characteristics that can modify their immunogenicity. Therefore, not only host factors as a variable for BCG efficacy but also BCG culture conditions should be considered. 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The graphical abstract and Figure 1D were created with Biorender.com (accessed on 28 October 2021). The authors declare no conflict of interest.