Abstract
Membrane-embedded proteins are critical to the establishment, survival and persistence in the host of the Lyme disease bacterium Borrelia burgdorferi (Bb), but to date, there are no solved structures of transmembrane proteins representing these attractive therapeutic targets. All available structures from the genus Borrelia represent proteins expressed without a membrane-targeting signal peptide, thus avoiding conserved pathways that modify, fold and assemble membrane protein complexes. Towards elucidating structure and function of these critical proteins, we directed translocation of eleven expression-optimized Bb virulence factors, including the signal sequence, to the Escherichia coli membrane, of which five, BBA57, HtrA, BB0238, BB0323, and DipA, were expressed with C-terminal His-tags. P66 was also expressed using the PelB signal sequence fused to maltose binding protein. Membrane-associated BBA57 lipoprotein was solubilized by non-ionic and zwitterionic detergents. We show BBA57 translocation to the outer membrane, purification at a level sufficient for structural studies, and evidence for an α-helical multimer. Previous studies showed multiple critical roles of BBA57 in transmission, joint arthritis, carditis, weakening immune responses, and regulating other Bb outer surface proteins. In describing the first purification of membrane-translocated BBA57, this work will support subsequent studies that reveal the precise mechanisms of this important Lyme disease virulence factor.
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Introduction
Lyme borreliosis is the most prevalent tick-borne disease in the Northern Hemisphere1. The disease is caused by certain spirochetal species within Borrelia burgdorferi sensu lato. In the U.S., Lyme borreliosis is diagnosed in over 300,000 people annually2, and the primary cause is the species Borrelia burgdorferi sensu stricto (Bb)3. In Europe, the major agents include Borrelia afzelii and Borrelia garinii3. Transmission of the spirochete to mammals, including humans, occurs from ticks in the genus Ixodes. Infection at the skin often leads to erythema migrans. Dissemination of the spirochete in mammalian hosts leads to infection of the heart, joints, brain, and nervous system. Critical to resolving the disease is proper diagnosis, which includes clinical manifestations and may include laboratory tests, followed by treatment with the appropriate antibiotic(s)4.
Bb is a spirochete that possesses a double-membrane5 and proliferates extracellularly in its hosts by modulating its outer surface proteins. Bb is rich in outer surface lipoproteins that change in response to environmental triggers (pH; temperature; nutrient density) and that allow evasion of host immune responses via active immune suppression, antigenic variation, and physical seclusion6,7. Because Bb’s reduced genome lacks the ability to synthesize amino acids, lipids, nucleotides, and cofactors8, Bb’s survival is completely dependent on membrane-integral proteins to transport nutrients across its inner and outer membranes. Passage of ions, nutrients, as well as many drugs across biological membranes requires recognition and transport by membrane-spanning proteins.
Several membrane-translocated proteins are important for Bb transmission and persistence. In ticks, OspA is essential for colonization and survival9 and Lmp1 facilitates dissemination10. BB0405 is necessary for transmission from tick to mouse and for establishing infection in mice11. In mammals, infection requires OspC12, P6613 and BesC14. P66 also plays a role in dissemination15,16. DbpA and DbpB are critical for colonizing all tissues17. Lmp1 is required for Bb persistence18 and contributes to complement-independent serum resistance18. Some of these proteins also function as adhesins. In ticks, OspA binds the TROSPA receptor19, and OspC binds the saliva protein Salp1520. In mammals, OspC also binds plasminogen21, Lmp1 binds mammalian glycosaminoglycan22, and P66 binds β3-chain integrins23,24. DbpA and DbpB bind decorin and glycosaminoglycans that are important in the host extracellular matrix and connective tissues25. Some of these proteins also have demonstrated porin activity, including BB040526, P6627 and BesC14, although it is unknown what are the in vivo roles of the porin activity15,28 and what are the pore substrate(s)29. BesC has been modeled as a trimeric β-barrel and is a homolog of the Escherichia coli TolC multidrug efflux pump14. Thus, membrane-translocated proteins are critical to the establishment, survival and persistence of Bb in the host.
The Bb genome encodes ≥20% proteins that are targeted to the membrane by N-terminal signal peptide sequences8. These signal peptide containing proteins are directed from the translating ribosome in the cytoplasm to the inner and outer membranes (OM). About 14% of Bb genes are lipoproteins30. These lipoproteins are also directed to the inner membrane and, after signal peptide removal, are covalently lipidated, which anchors the protein to the membrane. Some translocated (lipo)proteins are further directed to the OM, where folding and assembly may be aided by periplasmic chaperones and the spirochetal β-barrel assembly machine (BAM) complex31,32. In this paper, we used the term membrane-translocated protein to refer to proteins that are directed from the cytoplasm to the inner membrane by a signal peptide sequence. This term does not specify whether the protein stays in the inner membrane, is further directed to the periplasm or to the outer membrane, or is secreted.
While membrane-translocated proteins are very important for the pathogenesis of Bb, information on their structures is lacking, which represents a critical barrier in understanding disease pathogenesis. None of the genus Borrelia protein structures available in the Protein Data Bank33 include transmembrane domains34, even though transmembrane activities have been shown for P66, P13, BesC, BamA, BB0405, BB0406, DipA and Oms286,26,32,35,36. The lack of such structures mainly reflects technical challenges. Furthermore, it has been suggested that transmembrane domains exist in BB0017, BB0164, BB0202, BB0412, BB0473, BB0631, and ChbB37. Many of the important outer surface virulence proteins in Bb, including OspA, OspB, OspC, OspD, P13, P66 and Lp6.6, are common components of OM multiprotein complexes38 that function in pathogenesis, but the structural arrangement of these complexes is unknown. There exist many structures (Supplementary Table S1) for the soluble domains of outer surface proteins (Osps), primarily lipoproteins, which are from the Lyme disease agents B. burgdorferi sensu stricto, B. garinii, Borrelia bavariensis and Borrelia spielmanii39 and the tick-borne relapsing fever agent Borrelia turicatae40 (Supplementary Table S1, column 3). However, each of these proteins was expressed in the cytoplasm of E. coli (Supplementary Table S1, column 5).
In other bacteria, several exciting structures demonstrate the necessity of membrane translocation for determining the pathogenic function of an OM protein. In these structures, small lipoproteins assemble to form large homo-multimeric channels, but only when translocated to the membrane. In the enterobacteria, these lipoproteins include the 42 kDa Wza, which assembles into a 340 kDa octamer that secretes the polysaccharides that form an immune-evading bacterial capsule41, and the 31 kDa CsgG, which assembles into a 250 kDa nonameric amyloid secretion channel that causes biofilm formation in the host42. For both Wza and CsgG, multimerization requires the lipid modification42,43. Additionally, the 28 kDa MlaA lipoprotein from Klebsiella pneumoniae forms multiprotein complexes with OmpF and OmpC/K and functions as a phospholipid translocation channel, but only when MlaA is expressed with its signal peptide44. Other proteins that form homo-multimeric OM channels only upon membrane translocation include the Haemophilus influenzae Hia adhesin45 and the E. coli TolC multidrug efflux pump46. Despite these important examples, to date, none of the available structures of Bb proteins that contain signal peptides was derived from protein that was directed to the cell membrane (Supplementary Table S1).
The aim of this study is to identify membrane-translocation upon heterologous expression in E. coli within eleven OM target proteins from Bb: BBA57, RevA, P13, HtrA, Lmp1, BB0238, BB0323, BB0405, BB0406, DipA and P66, which have roles in pathogenesis (Supplementary Table S2, shaded column), in order to support future structural studies of their membrane directed forms. Here we show, for the first time, translocation of the BBA57 lipoprotein to the E. coli OM, purification of this form, and evidence for its multimerization in a primarily α-helical form. BBA57 is a surface exposed47, immunogenic48,49 virulence determinant and an inflammatory agent in Lyme arthritis and carditis47,50. BBA57 is necessary for Bb transmission from tick to humans50 and to mice47 and is upregulated by temperature and by cultivation in mice51,52. BBA57 is encoded by the linear plasmid lp54 and is not a highly abundant protein53. BBA57 has homologues (>61% identity across 99% of the protein sequence) in the other Lyme disease pathogens B. afzelii, Borrelia mayonii, B. garinii, B. bavariensis and B. spielmanii. In potential pathogens, the presence of BBA57 is mixed, with one homolog in each Borrelia valaisiana (67% identity) and Borrelia bissettii (73% identity), but none in Borrelia lusitaniae. BBA57 homologs are absent in the tick-borne relapsing fever bacteria. Mutational analyses showed that BBA57 is upregulated 4- to 11-fold by the components of the Rrp2/RpoN/RpoS infection regulatory cascade, a major transcriptional response to the mammalian host environment and one that controls OM proteins, transporters and other proteins important for infection, colonization and transmission52. The Pal group recently demonstrated multiple critical roles for BBA57 in weakening host complement, neutrophil and interferon responses; in decreasing transcription of antimicrobial peptides and interferon genes; and in regulating expression of the Bb outer surface lipoproteins OspC, ErpP and ErpB50. Despite these multiple important roles, no structure has been determined for BBA57. These diverse and complex roles do not point to an obvious, discrete function for BBA57 that can be easily assayed. We expect that structures will reveal its mechanisms in pathogenesis.
Results
Positive expression in E. coli of B. burgdorferi BBA57, HtrA, BB0238, BB0323, and DipA proteins with C-terminal His12-tags
In contrast to the existing available structures for soluble domains of membrane-anchored proteins (Supplementary Table S1), the expression clones in this paper retained an N-terminal membrane localization sequence, so that the full-length targets could be translocated to the membrane for proper folding. Each of the 11 targets contained the C-terminal sequence ENLYFQGHHHHHHHHHHHH (Fig. 1a). In this paper, these proteins are referred to as “Target-His12”. Expression results in this paper are summarized in Table 1. The Bb genes were also optimized for expression in E. coli. Schematics and DNA sequences are in Supplementary Figs. S1a,b and S2a,b, respectively. Sequences for the His12 and PelB constructs are in Supplementary Figs. S3a,b and S4a,b, respectively. The His12 constructs were transformed into the E. coli expression strain BL21(DE3), as well as into four strains (Table 2) that are typically used to overcome problems of membrane protein unfolding and toxicity by modulating expression levels through various mechanisms. For P66-His12, no colonies could be obtained upon transformation into any of the five strains (Table 1), even upon increasing the amount of plasmid DNA transformed from 20 to 400 ng. BB0323 colonies were obtained in C43(DE3) only upon increasing the DNA added to competent cells from 70 to 800 ng. For the other targets that failed to yield colonies in some of the strains, such as RevA, HtrA, BB0238, and DipA (Table 1), we did not systematically pursue transforming with higher amounts of DNA.
Expression of Bb BBA57, HtrA, BB0238, BB0323, DipA and P66 membrane proteins in E. coli. (a,b) Schematic of the expression constructs. (a) The full-length target (pre-protein) with a TEV protease cleavable C-terminal His12-tag. (b) The mature target protein with its predicted Bb signal peptide substituted with the PelB signal peptide (PelBsp), a His10 tag, maltose binding protein (MBP), and TEV protease cleavage site. (c) Expression in BL21-AI cultures grown at 37 °C to OD600 0.5, induced with 0.2% arabinose, and harvested after 3 hr. Shown are Western blots (anti-His) of total cellular protein. Arrows indicate the possible target protein based on the expected MW, listed below each blot and lacking the cleaved signal peptide. The asterisk (*) indicates KTD101(DE3); all other cultures are BL21-AI. Per lane are cells from 10 µL of culture. Lane 2 contains a positive control for expression and purification, CapA from Francisella tularensis107, and lane 14 contains purified GFP-His6107. (d) Positive expression of PelB-P66, PelB-BB0238, and HtrA-His12 in E. coli BL21-AI grown at 37 °C in M9 minimal media to OD600 0.8–0.9, induced with 0.1% arabinose and decreased temperature to 25 °C, and harvested after 14 h or 22 h. Per lane is 6.25 µL of culture. (e) Positive expression of BB0238-His12 and DipA-His12 in E. coli BL21-AI grown at 37 °C to OD600 0.5, induced with 0.2% arabinose with a temperature change to 18 °C, and harvested after 18–20 h. Per lane is 7.5 µL of culture either before harvesting the cells by centrifugation (whole culture, W) or after centrifugation and removal of the cells (culture supernatant, S). Full gel images for (d,e) are in Supplementary Fig. S6. Abbreviations: MW, molecular weight.
Positive expression for the His12 constructs targets was observed primarily in BL21-AI, although BBA57-His12 was expressed in several strains (Table 1). Expression in BL21-AI was obtained for five targets: HtrA-His12 (Fig. 1c, lane 4; and Fig. 1d, lanes 19 and 20; expected 51.4 kDa, observed ~52 kDa), BBA57-His12 (Fig. 1c, lane 6; expected 47.5 kDa, observed ~55 kDa), BB0323-His12 (Fig. 1c, lane 7; expected 44.5 kDa, observed ~45 kDa), BB0238-His12 (Fig. 1e, lane 27; expected 29.7 kDa, observed ~31 kDa) and DipA-His12 (Fig. 1e, lane 29; expected 39.0 kDa, observed ~37 kDa). Of these, BBA57-His12 ran farthest from its expected size. The expected size of mature BBA57-His12 (i.e., BBA57-His12 lacking the signal peptide due to processing at the inner membrane) is 47.5 kDa. Here BBA57-His12 migrated at ~55 kDa (Fig. 1c, lane 6), which importantly reproduces the results done in Bb in a previous study54 that observed BBA57-His6 migrating in a Western blot at 56 kDa. The finding that membrane proteins migrate differently from the expected size is not unusual due to incomplete denaturation by detergents55. For BBA57-His12, we also observed a minor band at ~110 kDa (Fig. 1c, lane 6), which suggests a possible dimer that is partially stable in sodium dodecyl sulfate (SDS). That both bands in Fig. 1c, lane 6, represent BBA57 was supported by absence of these bands in lane 5 (Fig. 1c), which contains a duplicate culture but lacked the inducer arabinose.
Negative expression results are shown in Supplementary Figs. S5a–c and S6a,b, and S7. No expression was apparent at any time for the three targets RevA, BB0405 and P13. RevA-His12 lacked visible expression (Fig. 1c, lane 3; Supplementary Fig. S5b, lanes 15 and 16). BB0405-His12 was not visible (Fig. 1c, lane 8; Supplementary Fig. S5b, lanes 5–13; Supplementary Fig. S6a, lanes 10–11; Supplementary Fig. S6b, lane 12). Also, P13-His12 was not visible (Fig. 1c, lanes 10 and 11; Supplementary Fig. S5a, lanes 2–8; Supplementary Fig. S6a, lanes 8–9; Supplementary Fig. S6b, lane 10). Expression in Lemo(DE3) did not yield visible targets, as was tested only for BB0405-His12, DipA-His12 and BBA57-His12 (Supplementary Fig. S7, lanes 2–10). Also, there was no evidence of secretion into the culture supernatant for those samples that were tested (Fig. 1e, lanes 24, 26 and 28; and Supplementary Fig S6b, lanes 9, 11, 13, and 15). Of these, where the target was visible in the unharvested culture (BB0238-His12 in Fig. 1e, lane 27; and DipA-His12 in Fig. 1e, lane 29), these results show that these targets were associated with the cells and were not secreted (compare to Fig. 1e, lane 28; and Supplementary Fig. S6b, lane 9).
Expression of some targets was obtained only upon analyzing various expression conditions. Interestingly, the four targets HtrA-His12, BB0238-His12, BB0323-His12, and DipA-His12 could only be expressed in BL21-AI. Negative results in other strains are in Fig. 1c, lane 11; Supplementary Figure S5a, lanes 9–14; Supplementary Figure S5b, lane 2; and Supplementary Fig. S5c, lanes 10–16. BBA57-His12 was the most widely expressed target, and was the only target that could be expressed in strains other than BL21-AI (Table 1). BBA57-His12 was observed in BL21(DE3) (Supplementary Fig. S5c, lanes 5–6) and KTD101(DE3) (Supplementary Fig. S5c, lanes 7–8). Even in BL21-AI, varying the induction conditions could eliminate expression: DipA-His12 was visible only at 18 °C (Fig. 1e, lane 29) but not 37 °C (Supplementary Fig. S5b, lanes 3–4). When minimal medium was used, neither BBA57-His12 nor DipA-His12 were visible in BL21-AI (Supplementary Fig. S6a, lanes 12–15; this condition includes a shift from 37 °C to 25 °C at induction, plus incubation for 14 h or 22 h), while HtrA-His12 continued to be expressed at this condition (Fig. 1d, lanes 19–20).
Expression in E. coli of B. burgdorferi BB0238 and P66 was achieved using the N-terminal PelB signal peptide and maltose binding protein tag
Because several targets lacked visible expression in E. coli (Table 1), we pursued expression driven by an alternative N-terminal membrane targeting sequence (Fig. 1b) containing the powerful PelB signal peptide from Erwinia carotovora56 plus the stabilizing MBP sequence57. In this paper, these proteins are referred to as “PelB-target”. A similar PelB-MBP expression construct supported crystal structure determination of cyanobacterial and Erwinia ion channels by successfully directing high levels of expression to the E. coli membrane58. The PelB signal peptide also successfully directed other spirochetal OM proteins to the E. coli OM, like the Treponema β-barrel porins TprC, TprI, and MOSP59. With the PelB-MBP sequence, we observed expression in E. coli of a sixth Bb target, PelB-P66 (Fig. 1d, lanes 15–16; expected 110 kDa, observed ~115 kDa), in addition to expression of PelB-BB0238 (Fig. 1d, lanes 17–18; expected 71.3 kDa, observed ~68 kDa). Both targets had higher protein levels at 22 h post-induction (Fig. 1d, lanes 16 and 18) compared to 14 h (Fig. 1d, lanes 15 and 17). Expression of PelB-P66 also depended on expression conditions, since PelB-P66 and PelB-BB0238 were not visible in BL21-AI after overnight growth in LB at 18 °C (Fig. 1e, lanes 23–26).
BBA57-His12 is translocated to the E. coli membrane from which it is soluble in non-ionic and zwitterionic detergents
We focused on BBA57-His12 after we identified this protein in the detergent soluble fraction (1% DDM) that was derived from total cellular protein of BL21-AI (Supplementary Fig. S8, lane 2) when we applied a rapid screen (Supplementary Methods) to the small scale expression cultures from Fig. 1c and Supplementary Fig. S5c. In contrast to this positive result in the BL21-AI strain (Supplementary Fig. S8, lane 2), strains KTD101(DE3) and BL21(DE3) did not yield visible detergent soluble BBA57-His12 (Supplementary Fig. S8, lanes 3 and 4). From this rapid screen, BBA57-His12 was also the only expressed target from Fig. 1c that was detergent soluble. For example, HtrA-His12 and BB0323-His12 that were visible in total protein (Fig. 1c, lanes 4 and 7) were not visible in the 1% DDM fraction (Supplementary Fig. S8, lanes 5 and 6).
Importantly, we verified that BBA57-His12 was in the cellular membrane fraction of E. coli by performing detergent extractions of the membrane fraction isolated as described here. Figure 2a shows the results of detergent extraction experiments that are detailed in the Methods. The full detergent screen for Fig. 2 is shown in Supplementary Fig. S9. We were able to partially solubilize BBA57-His12 from the E. coli membrane using four detergents. An anti-His Western blot identified that BBA57-His12 was present mainly in the cellular membrane fraction (Fig. 2a, lane 6). Approximately half of the BBA57-His12 from the membrane fraction was solubilized in the detergents DM (Fig. 2a, lane 9), OG (Fig. 2a, lane 12), and CYMAL-6 (Fig. 2a, lane 15), and partially solubilized in CHAPS (Fig. 2a, lane 20).
Full-length, C-terminally His-tagged BBA57 is solubilized by detergents from a cell membrane fraction of E. coli and can be purified by nickel affinity. Shown are Western immunoblots (anti-His). (a) Fractions from a cell membrane preparation, and 2% detergent extraction with BBA57-solubilizing detergents. M, membrane pellet fraction, which represents one suspended aliquot from lane 6. I, detergent-insoluble portion of the membrane fraction. D, detergent-soluble portion of the membrane fraction (yellow arrows). Lanes M, I, and D all contain 47 µL culture equivalent per lane. (b) Purification by nickel affinity of the detergent-soluble portions of the membrane fraction by two methods. Lanes c, Ni-NTA silica spin columns (93 µL culture equivalent per lane). Lanes b, nickel sepharose magnetic beads (469 µL). Purified GFP-His6 (lanes 16, 30) was used as a Western positive control. Abbreviations: MW, molecular weight; sup., supernatant.
BBA57-His12 was isolated by metal affinity chromatography from a detergent-solubilized membrane fraction
To verify metal-binding, the detergent-solubilized protein fractions in Fig. 2a were tested for binding to two different nickel affinity formats. BBA57 that was solubilized in DM, OG, CYMAL-6, and CHAPS bound to both nickel silica spin columns (Fig. 2b, lanes 22, 24, 26 and 28) and nickel sepharose magnetic beads (Fig. 2b, lanes 23, 25, 27 and 29). Comparing detergents, the highest yield was obtained in DM, CYMAL-6 and CHAPS (Fig. 2b, lanes 23, 27 and 29) compared to OG (lane 25). Also, we noted that the ~110 kDa ‘dimer’ of BBA57-His12 (Fig. 2a) diminished throughout the membrane/detergent purification, and was no longer visible throughout in the nickel purification samples (Fig. 2b). Despite any differences in yields, it will be important to also determine the quality and the membrane localization of the protein prior to structure determination. Nevertheless, nickel affinity will be a useful first purification step.
PelB-P66 is not translocated to the E. coli membrane and is not detergent-soluble
We also determined whether the PelB-P66 that was expressed (Fig. 1d, lane 16) was also membrane-localized. PelB-BB0238 was not analyzed due to low expression levels (Fig. 1d, lanes 17–18). We evaluated expression of PelB-P66 in BL21-AI under different inducer concentrations, induction times and temperatures. Immunoblots of total protein showed increased expression with increasing concentrations of arabinose in the presence of IPTG (Supplementary Fig. S10a,b). IPTG was necessary to remove the bound LacI protein, which is also encoded in this vector, from the lacO sequence in the vector’s T7lac promoter. To determine membrane localization of PelB-P66, a membrane fraction was isolated (Fig. 3, lanes 2–6) from a culture grown at the same conditions as Supplementary Fig. S10a (0.001% arabinose, 8 h expression) and then extracted with several nonionic and zwitterionic detergents (Fig. 3, lanes 7–12, 16–25). In the low speed centrifugation of cell lysate, most of the PelB-P66 was found in the pellet (Fig. 3, lane 4), suggesting that a significant fraction of the target was in inclusion bodies. Upon subjecting the low speed supernatant (Fig. 3, lane 3) to the high speed centrifugation, most PelB-P66 was in the membrane fraction (Fig. 3, lane 6) rather than the soluble fraction (Fig. 3, lane 5). Upon extraction of the membrane fraction with several detergents, Western blot analysis showed that the majority of PelB-P66 was in the detergent insoluble fraction (Fig. 3, lanes 8, 9, 12, 17, 19, 21, 23, 25).
PelB-P66 is not solubilized by detergents from the E. coli cell membrane fraction. Shown are anti-His-tag Western immunoblots. Each lane contains sample from 23.4 µL of culture. I, detergent-insoluble portion of the membrane fraction. D, detergent-soluble portion of the membrane fraction. Most of PelB-P66 (110 kDa) is not membrane localized (yellow arrow). Purified GFP-His6 was used as a Western positive control. Abbreviations: MW, molecular weight marker.
BBA57-His12 is translocated to the E. coli outer membrane, detergent solubilized, and purified by nickel affinity
Translocation of BBA57-His12 to the OM fraction of E. coli was revealed after incubating the cell membrane fraction with N-lauroyl sarcosine, which solubilizes the inner membrane and thus allows isolation of an OM fraction. The cell membrane fraction is shown by Coomassie-stained SDS-PAGE in Fig. 4a, lane 4, and by Western blot in Fig. 4b, lane 16. The inner membrane fraction is shown in Fig. 4a, lane 5, and Fig. 4b, lane 17. The Coomassie stain indicates that the OM (i.e., the pellet from the sarkosyl solubilization) contained approximately a quarter of the total BBA57-His12 (Fig. 4a, lane 6) that had been in the membrane pellet (Fig. 4a, lane 4), while the other three-quarters was in the inner membrane (i.e., the sarkosyl soluble supernatant; Fig. 4a, lane 5). The OM fraction (Fig. 4a, lane 6; Fig. 4b, lane 18) was then solubilized by DDM detergent (Fig. 4a, lane 9; Fig. 4b, lane 21). Coomassie stain showed that approximately half of the BBA57-His12 that was in the in the OM (Fig. 4a, lane 6) was solubilized in 2% DDM (Fig. 4a, lane 9). The BBA57-His12 in the form of a DDM-protein detergent micelle was then purified using nickel affinity chromatography. The results are in Fig. 4c, which shows that we were able to isolate pure BBA57-His12 (Fig. 4c, lanes 30–33). Less than 10% of BBA57-His12 did not bind to the nickel as was visible in the column flowthrough (Fig. 4c, lane 25), and no BBA57-His12 was visible in the wash steps at 50 and 80 mM imidazole (Fig. 4c, lanes 26–27). BBA57-His12 that was eluted from the column with high imidazole (Fig. 4c, lane 31) was verified by anti-His Western (Fig. 4d, lane 35) and by LC/MS/MS following trypsin digestion, which identified 85 peptides (461 peptide spectrum matches) representing 89% coverage of the BBA57-His12 sequence. The yield in Fig. 4c was 0.28 mg of purified BBA57-His12 per liter of E. coli culture.
Full-length, C-terminally His-tagged BBA57 is isolated from the outer membrane fraction of E. coli, solubilized by detergent, and purified by affinity chromatography. Shown are Coomassie blue stained SDS-PAGE (a,c) and anti-His Western immunoblots (b,d). (a,b) Fractions from a cell membrane preparation showing BBA57 localized in the OM and extracted with 2% DDM (yellow arrows). Purified BSA and GFP-His6 were used as positive controls. (c,d) Detergent-solubilized, OM BBA57 purified by nickel affinity (boxed lanes). Lanes 28–33 and 35 contain 7 µL of each elution fraction. Abbreviations: BSA, bovine serum albumin; MW, molecular weight marker; IM, inner membrane; OM, outer membrane; supt., supernatant.
BBA57-His12 isolated from the outer membrane forms a large homo-multimeric complex composed mainly of α-helices
BBA57-His12 that was isolated from the outer membrane and purified by nickel affinity was further purified by size exclusion chromatography. Silver stained SDS-PAGE (Fig. 5a) showed that a highly pure band migrating like BBA57-His12, which was verified by anti-His immunoblot (Fig. 5a), was present in a size exclusion peak (Fig. 5b) that migrated near the 440 kDa ferritin standard (Fig. 5b). Circular dichroism of this BBA57 peak (Fig. 5c) indicated structural features of 69.0% (±5.7%) α-helices, 2.5% (±1.7%) β-strands, 10.4% (±3.4%) turns, and 18.7% (±5.7%) unordered. Negative stain (Fig. 5d) gave evidence of uniformly sized particles with a diameter of approximately 10 nm.
Full-length, C-terminally His-tagged BBA57 forms a large homo-multimeric complex composed mainly of α-helices. (a) Silver stained SDS-PAGE and and anti-His Western immunoblot from (b) a 280 nm absorbance peak (9.5–10.5 mL) obtained on size exclusion chromatography following nickel affinity purification. Also shown is the peak from a ferritin molecular weight standard run on this column. The BBA57 peak was subjected to (c) circular dichroism and (d) negative stain electron microscopy. The length of the black bar is 50 nm. Abbreviations: BSA, bovine serum albumin; MW, molecular weight marker.
Discussion
In this study, we endeavored to heterologously express in E. coli several Bb virulence determinants with their signal peptides, thus pursuing the pathways that fold, process, and multimerize membrane-translocated proteins60. These pathways include the inner membrane translocases, primarily SecY61, that recognize, fold and move α-helices laterally into the membrane bilayer62. At the inner membrane, signal peptides are removed after translocation; lipoproteins are processed by the Lol system30,63; periplasmic chaperones like Skp and DegP maintain proteins in an unfolded state, refold protein (peptidyl-prolyl isomerases), or form disulfide bonds (disulfide oxidoreductases)64; and OM β-barrels are assembled, possibly one β-strand at a time, by the β-barrel assembly machine60 and may also form multimers65. These pathways are moderately conserved from E. coli to Bb32,66,67,68, making E. coli a reasonable starting system for heterologous overexpression of membrane-translocated proteins. In fact, surface expression in E. coli has been reported for full-length forms of Bb OspA, P66 and OspB23,69,70. That BBA57-His12 was localized in the E. coli OM fraction (Fig. 4a, lane 6) using conventional sarkosyl solubilization of the inner membrane71 suggests that BBA57 was sent through the proper membrane folding and processing pathways.
Importantly, the purified, membrane-translocated BBA57 showed evidence of multimerization (Fig. 5d). The approximate particle diameter of 10 nm (Fig. 5d) is consistent with its migration on size exclusion (Fig. 5b) and is similar to the diameters of the multimeric structures of Wza (10.5 nm)41 and CsgG (12 nm)42. The α-helical nature of BBA57 is reminiscent of the E. coli capsule-forming Wza homo-multimer that secretes polysaccharides. It is possible that multimerization of BBA57 also requires lipidation and thus membrane-translocation, as is the case for Wza43 and CsgG42. There is currently published evidence for a second α-helical homo-oligomer in Bb. Porin-active P13 forms a ~300 kDa homo-oligomer72 with a predicted α-helical structure73. Unlike for Wza, the membrane-spanning helices in P13 were sufficiently hydrophobic to be identified73 using programs, HMMTOP74, TMHMM75, and PSORT76 that identify inner membrane α-helices.
In this study, eleven target proteins were selected (Supplementary Table S2) in order to support future structural studies of their membrane directed forms. The approximate number of targets was based on the proportion of successful membrane-translocation in our previous work with targets from another tick-borne pathogen, Francisella tularensis77. The Bb targets were identified from the published literature and chosen based on some or all of the following criteria. (1) All of the targets have a demonstrated role in pathogenesis (Supplementary Table S2). Mutation of nine of the targets reduces pathogenesis (Supplementary Table S2). For the remaining two targets, P13 is a dominant component of the multiprotein complexes in the Bb OM, but its role in these complexes is unclear38; and BB040628 has demonstrated porin activity and is coexpressed with BB040526, with which it has 46% sequence identity. (2) All targets are associated with the inner or outer membrane (Supplementary Table S2). Three of the targets are predicted lipoproteins: BBA5751, RevA54 and BB032354. However, actual lipidation and the type of lipid have yet to be demonstrated. (3) The targets are unique to Borrelia species. Sequence searches using BLASTp were used to identify the absence of homologous structures in the Protein Data Bank (PDB)33. Only the High Temperature Requirement A (HtrA) protein has homologous structures in the PDB, all of which are from non-Borrelia species, and which contain less than 35% sequence identity. Functions and substrates of Htr proteins vary remarkably between species’ forms despite similar structures, and are often unique virulence factors in pathogens, making them attractive targets78. In general, the selected targets are also highly conserved across the genus Borrelia, making the results of this work possibly applicable to multiple Borrelia species. (4) Another criterion was the lack of structures in the PDB. RevA has a structure in the PDB33, a 1.80 Å crystal structure (accession no. 5EQZ, unpublished [J.K. Yano, A.H. Sullivan, J. Abendroth, D.D. Lorimer, and T.E. Edwards]), which is of the soluble domain that was expressed in the cytoplasm of E. coli. Recently the crystal structure of the N-terminal 27 kDa fragment of BB032379 was solved at 2.35 Å, following its expression in the E. coli cytoplasm and also lacking the signal peptide. This effort revealed structural homology to the spectrin superfamily, members of which function as linkers in bacterial cell division and the eukaryotic cytoskeleton80. Importantly, for all other membrane-translocated proteins from Borrelia spp., the available structures in the PDB have also been solved for only the soluble domain (Supplementary Table S1): each of these proteins was expressed without a signal peptide and therefore was not directed to the membrane or to the membrane protein folding pathways. For the other targets in Supplementary Table S2, no atomic-resolution structures are available. The β-barrel fold that is expected in BB0405, BB0406, DipA and P66 is based on sequence predictions and porin activity26,29,36, but no experimental structure has been determined. (5) Finally, the lack of experimental structures will be important to unravel the function on a molecular basis of many of the eleven targets. RevA, Lmp1 and P66 act as adhesins10,24,81. However, molecular functional activities have not been determined for BBA57, BB0238 or BB0323, and the functional roles of the porin activities are unknown for P13, BB0405, BB0406 and P66. Future structures will better illuminate how these important proteins function in Borrelia species’ pathogenesis.
Of the targets expressed, two were analyzed for membrane localization. BBA57-His12 was found in the E. coli membrane, while PelB-P66 was not. There are several possible contributing factors for lack of membrane localization. One is interference with membrane protein processing by the presence of even small purification tags, as has been demonstrated82,83. This interference could be overcome in the future with tag-free purification from the relatively pure OM fraction (Fig. 4a, lane 6), possibly aided by antibodies51. Other factors include differences between E. coli and Bb in the membrane protein processing components31,84. Additionally, Bb is unable to synthesize fatty acids, and instead, exchanges lipids with its eukaryotic host, resulting in a lipid composition reflective of the surrounding host tissue85. The Borrelia species also lacks lipopolysaccharides and is one of the few prokaryotes that contains cholesterol and cholesterol glycolipids84,86,87. Specifically, cholesterol located in the OM of Borrelia species may assist in formation of tightly packed lipid microdomains (lipid rafts), which are known to play roles in protein sorting and receptor signaling88. Also, some targets are processed by Bb specific proteases. In Bb, the HtrA protease processes BB032379, P6689, and Lmp190. Lmp1 is processed into three separate domains (N-terminal, middle, and C-terminal) that confer unique pathogenic properties90. Lmp1 constructs could not be generated (Table 1), possibly due to instability at the DNA level of the expression-optimized DNA. The C-terminal 28 residues73 of P13 are removed by the CtpA C-terminal protease91. BB0323 undergoes complex processing: BB0323 is proteolyzed by HtrA to yield a C-terminal ~15 kDa fragment79 plus an N-terminal 27 kDa fragment79 that interacts with BB023892,93 and forms a 48.5 kDa dimer93. BB0323 is also proteolyzed by CtpA91. Here we showed recombinant expression in E. coli BL21-AI of the unprocessed size of BB0323 (Fig. 1c, lane 7) but could not extract BB0323 from total cellular protein using 1% DDM (Supplementary Fig. S8, lane 6).
It is possible that additional targets can be solubilized with somewhat higher detergent concentrations, such as 1.5–2%, which have been used in structure determination of other OM proteins94,95. Previously, 2% LDAO was used to solubilize natively folded P66 from the Bb OM96. Although PelB-P66 could not be detergent-solubilized under the conditions explored, use of a harsher detergent extraction may lead to solubilized protein. However, we did not explore these conditions as harsh detergent treatment often leads to protein that is only partially folded and therefore not suitable for structure determination.
Surprisingly, among the tested targets, expression of Bb proteins was highly strain-dependent (Table 1). Expression of the selected Bb targets was most successful in E. coli strain BL21-AI (Fig. 1c–e; Table 1). BL21-AI is a derivative of the BL21(DE3) line, with more tightly regulated expression through the araBAD promoter (PBAD), which controls expression of T7 RNA polymerase and reduces the likelihood of leaky expression in uninduced cells97. Leaky expression of proteins toxic to E. coli could kill the bacterium before it would be able to form colonies. The inability of some transformed strains to form colonies suggests that many of these membrane-translocated targets may be toxic to the E. coli strains listed in Table 1, possibly due to inadvertent disruption of the inner membrane. Interestingly, BBA57-His12 was the only target to express in more than one of the tried strains (Table 1), but was detergent-soluble only when expressed in BL21-AI cells. P66-His12 was especially toxic to the cells, yielding no colonies in any of the E. coli strains (Table 1). Expression of P66 was successful only after changing the construct to include the PelB signal sequence fused with MBP (Table 1). The BB0406-His12 expression construct may also be unstable as this clone could not be made (Table 1).
E. coli is often the go-to system for structural biology of bacterial membrane proteins, some methods of which require near-milligram amounts of purified protein. Further improvements in expression of some of the targets here may be achieved by systematically varying the culture medium, temperature, induction time and inducer concentration, as was suggested upon obtaining positive expression for HtrA-His12 (Fig. 1c, lane 4; Fig. 1d, lanes 19–20), BB0238-His12 (Fig. 1e, lane 27), BB0323-His12 (Fig. 1c, lane 7) and DipA-His12 (Fig. 1e, lane 29). These approaches may be promising for the remaining samples in Supplementary Fig. S10. Adding the PelB-MBP sequence to P66 (Fig. 1d, lanes 15–16) supports the approach of using alternative N-terminal membrane targeting sequences. In fact, a previous study reported integration of P66 in the E. coli OM when the E. coli OmpT signal peptide was used, although expression was also reported as inefficient23. Future studies will assess whether the PelB sequence without MBP is sufficient for expressing P66 or other difficult expression targets, and if these proteins are translocated to the membrane. While it is possible that alternate constructs, strains and expression conditions could direct expression of some of these targets to the E. coli membrane, the results described in this paper, plus the importance of processing pathways and unique lipids to proper folding of transmembrane proteins, suggest the necessity to develop overexpression systems within non-virulent strains of Borrelia to allow structural studies of more membrane-translocated Bb proteins. High expression levels in Bb will be facilitated by the developed genetics systems and the availability of strong, inducible promoters (reviewed in98).
It is important to note that the rapid screen used in Supplementary Fig. S8 (lane 2) to identify detergent soluble BBA57-His12 does not prove that BBA57 was integrated into the cell membrane, because the source of the extracted protein included soluble cytoplasmic and periplasmic proteins. Therefore we had addressed this issue by first isolating the membrane fractions and then extracting protein from these isolated membrane fractions. That BBA57-His12 was associated with the E. coli membranes was indicated by the presence of BBA57-His12 in the pellet of a high-speed centrifugation of cellular fragments (Fig. 2a, lane 6) and in the pellet of a sarkosyl solubilization (Fig. 4a, lane 6). The sarkosyl solubilization and nickel affinity purification in Fig. 2b,c strongly suggests that recombinant BBA57 is associated with the OM and can be purified at a level sufficient for structural analyses.
Other groups have characterized BBA57 subcellular localization in Bb. Native BBA57 was shown to be OM-localized using either proteinase K digestion of whole cells or isolation of the OM with hypotonic citrate buffer plus sucrose gradient47. One study also used the citrate/sucrose method99 to localize C-terminally His6-tagged BBA57 to the Bb OM54, while another study51 found BBA57 in the insoluble fraction of whole cell lysates after extraction with Triton X-114. Structural information on BBA57 is expected to illuminate these results.
The BBA57 sequence does not suggest an obvious structure. It contains a single conserved protein domain (pfam05058; residues 52–141 of GenBank accession number AAC66270.1) that has 29% identity to the ActA actin assembly inducing protein, a cell surface virulence factor from the Gram-positive Listeria monocytogenes. ActA is implicated in biofilm formation and dissemination via actin polymerization100, but like BBA57, there are no structures determined yet for this protein. BBA57 has a relatively low hydrophobicity of 27% and is not predicted (Supplementary Table S2, column 6) to form transmembrane α-helices or a β-barrel, using the standard programs that rely on high hydrophobicity or monomeric β-barrels. Secondary structure predictions that are not based on a membrane environment (e.g., PSIPRED) suggest that the protein would contain 50% α-helices, which is consistent with the results in Fig. 5c. Unlike inner membrane α-helices, OM α-helices are often amphipathic, where the hydrophobic side of the α-helices face the membrane, and the hydrophilic amino acids align along the inner structure. Two α-helical OM proteins have so far been demonstrated structurally using protein directed to the membrane: the polysaccharide translocon Wza41 and the phospholipid translocon MlaA44. The homo-multimeric OM β-barrel structures determined for CsgG, Hia and TolC also cannot be predicted from their primary protein sequence42,45,46. These fascinating proteins, that function in immune evasion, lipid transport, biofilm formation, adhesion, and drug resistance, serve as powerful examples for future structural studies of membrane translocated virulence proteins in the Lyme disease pathogen.
This work is the first reported purification of membrane-translocated BBA57, the first evidence of its localization in the E. coli membrane, and the first evidence of possible multimerization. BBA57-His12 was solubilized in several different detergents, including DDM and OG, and reproducibly purified by affinity chromatography, indicating its potential as a future structural target. Future studies will focus on functional and structural studies of the purified recombinant BBA57-His12 that will complement in vivo studies. We suggest that its detailed structure may indicate that BBA57 functions as an assembly factor, chaperone, or scaffold. Availability of the lipidated forms of these purified virulence determinants will also allow novel vaccination studies: it has been reported that lipidated OspA yields a greater immune response than non-lipidated101. Unfortunately, this study omitted details on preparation of the lipidated OspA. The results described here also highlight the non-trivial technical hurdles required to screen membrane fractions in order to begin to identify proper membrane protein folding and processing, and perhaps provide some justification for the lack of membrane-integral structures from Borrelia species. As structure determination methods continually improve, as recently seen with femtosecond nanocrystallography and single particle cryoelectron microscopy, protein yields will likely become much less important than protein quality, such that even modest improvements in yields will result in important new structures. This work contains significant first steps towards what we expect will be the first structure determination of a membrane-translocated form of any protein from Borrelia species.
Methods
Generation of expression constructs
Sequence analysis methods are in the Supplementary Methods. To obtain significant expression levels, we obtained genes optimized for expression in E. coli from GenScript. To minimize cost, the genes were obtained as tandem sequences on two plasmids (Supplementary Fig. S1) that were used as PCR template DNA for the expression subclones. The optimized DNA sequences are provided in Supplementary Fig. S2a,b. The genes were provided on plasmids pUC57-BBclone1 and pCC1-4k-BBclone2, containing 7 and 4 genes, respectively (Supplementary Fig. S1). The latter plasmid has optimized genes for BB0323, P13, DipA and Lmp1. Because cloning into pUC57 was problematic for this plasmid, these optimized genes may contain DNA sequence that is unstable in the high copy pUC57 plasmid (>100 plasmids/cell). Unlike pUC57, pCC1-4k-BBclone2 has a low copy RK2 origin of replication (<10 plasmids/cell).
Each of the 11 targets was cloned into the pRSET-TEV-12His vector that allows T7 promoter based expression. The C-terminal sequence ENLYFQ*GHHHHHHHHHHHH allows removal of the His12 tag by cleavage (*) with tobacco etch virus (TEV) protease (Fig. 1a). Long polyhistidine tags are often necessary for efficient binding of membrane proteins to the nickel affinity column during metal affinity purification. The complete DNA and protein sequences for the BBA57-His12 construct are provided as an example in Supplementary Fig. S3a,b. Two Bb targets, Lmp1 and BB0406, could not be cloned into pRSET-TEV-12His (Table 1). Because Lmp1 was also present in the low copy pCC1-4k-BBclone2, it is possible that the expression-optimized Lmp1 gene may contain a DNA sequence that is unstable in the high copy pRSET and pUC57 vectors.
Because some targets lacked visible expression under any condition, select targets were additionally cloned into the novel pelB-MBP vector, which replaces the Bb signal peptide with the PelB signal peptide, followed by a His10 tag, the mature maltose binding protein (MBP), and a TEV protease cleavage site designed to generate the native N-terminus of the mature target protein (Fig. 1b). The complete DNA and protein sequences for PelB-P66 are provided in Supplementary Fig. S4a,b.
Cloning and transformation
Plasmids in this paper are listed in Supplementary Table S3. Genes optimized for expression in E. coli were acquired from GenScript. This optimization includes codon usage bias, GC content, CpG dinucleotides content, mRNA secondary structure, internal ribosomal binding sites, and repeat sequences. Sequences for all of the optimized genes are in Supplementary Fig. S2a,b. Ligation-independent cloning was accomplished as described previously77 and using the E. coli Stellar cloning strain (Clontech # 636766). Plasmid bearing cells were selected on LB Miller agar plates with the appropriate antibiotic (50 µg/mL carbenicillin, 30 µg/mL kanamycin, and/or 25 µg/mL chloramphenicol, according to Table 2 and Supplementary Table S3) with incubation at 37 °C overnight. Subclones were isolated by single colony isolation, and the DNA region that was generated by PCR was verified by Sanger sequencing at the DNA Laboratory core facility at Arizona State University. Complete sequences for the unique empty vectors pRSET-TEV-12His and pelB-MBP are in Supplementary Figs. S11 and S12, respectively. These vectors were designed to allow cloning into two BseRI sites that flank a removable 0.4 kb fragment (“stuffer”). Importantly, because cleavage occurs outside of the BseRI recognition site, cloning into these BseRI-digested vectors avoids the need to include any of the restriction site recognition sequence in the expressed protein sequence. Complete sequences for representative subclones in each vector are shown in Supplementary Figs. S3 and S4.
The expression strains (Table 2) included C43(DE3), a BL21(DE3) mutant derivative that displays improved membrane protein expression102. Lemo21(DE3) is the same as BL21(DE3) but contains the pLemo plasmid that modulates expression from T7 promoters by rhamnose-inducible co-expression of T7 lysozyme (LysY)103. KTD101(DE3) is a (DE3) derivative of the trigger factor deficient (Δtig) strain KTD101, which is from the E. coli K-12 lineage104. BL21-AI is a BL21 derivative that moderates expression from the T7 promoter due to a chromosomal copy of an arabinose-inducible gene encoding the T7 RNA polymerase105. To make the KTD101 strain104 compatible with expression from the T7 promoter, we used the λDE3 Lysogenization Kit (EMD Millipore #69734-3) to generate strain KTD101(DE3). Competent expression cells were generated and were transformed as described previously106 using 20–170 ng DNA and plating 10–100% of cells, or according to BL21-AI manufacturer instructions using 5–50 ng DNA and 15 µL cells. Petri plates with colonies were stored at 4 °C for up to 1 month.
Expression growths
Unless specified, growths in liquid medium and on plates (1.5% agar) used LB Miller medium (10 g tryptone, 5 g yeast extract, and 10 g sodium chloride per liter) with the appropriate antibiotic (50 µg/mL carbenicillin, 30 µg/mL kanamycin, and/or 25 µg/mL chloramphenicol, according to Table 2 and Supplementary Table S3). The growth described in Fig. 4 used Terrific Broth (per liter: 12 g tryptone, 24 g yeast extract, 4 mL glycerol, 2.31 g KH2PO4, 12.54 g K2HPO4). In liquid medium, chloramphenicol was at 34 µg/mL. Large scale expression growths in BL21-AI were done as follows. An isolated colony from a transformation plate was used to inoculate 10 mL medium with 50 µg/mL carbenicillin. This culture was incubated overnight at 37 °C and with shaking at 250 rpm (230 rpm for Fig. 4). The next day, the overnight culture was added to 1 L of pre-warmed medium with 50 µg/mL carbenicillin in a 2 L flask. Incubation continued about 5 h until the culture OD600 was about 0.5 (in LB) or 1.3 (in Terrific Broth). Cultures were induced with arabinose (0.003% for Fig. 2; 0.2% for Fig. 4) and incubated 18 h at 25 °C. Cells were harvested by centrifugation at 8,000 × g for 20 min at 4 °C, and cell pellets were flash frozen in liquid nitrogen and stored at −80 °C.
Isolation of a total cell membrane fraction and a screen for detergent extraction
A cell membrane fraction (containing both inner and outer membranes) was isolated and a detergent screen of this fraction (Fig. 2a) was performed as follows. A cell pellet from a 1 L expression growth culture was thawed and suspended in 10 mL (the volume is per gram wet weight of cells) of Protein Buffer (PBS [137 mM NaCl, 2.7 mM KCl, 10 mM Na2HPO4, 1.8 mM KH2PO4, pH 7.5] with one SIGMAFAST Protease Inhibitor Cocktail Tablet, EDTA-Free, for each 200 mL). Egg white lysozyme was added (final concentration 2 mg/mL) and the suspension was shaken at room temperature for 30 min. The lysate was sonicated on ice using a Branson Sonifier (10 s ON, 30 s OFF, total 1 min ON, at 60% power), and a cell lysate sample was collected for later analysis (Fig. 2a, lane 2). A low speed centrifugation step (8000 × g for 10 min at 4 °C) yielded supernatant (Fig. 2a, lane 3) and pellet (Fig. 2a, lane 4). The supernatant was centrifuged at high speed (100,000 × g for 1 h at 4 °C) to isolate the cell membranes. The supernatant (Fig. 2a, lane 5), containing soluble proteins (i.e., non-membrane-bound cytoplasmic and periplasmic proteins) was separated from the pellet (Fig. 2a, lane 6), containing the cell membrane fraction. The membrane pellet was suspended using a homogenizer (glass vessel tissue grinder with polytetrafluoroethylene pestle) in 32 mL Protein Buffer. A sample was collected from both fractions for later analysis. Eight 4 mL suspensions were aliquoted into 15 mL tubes, and detergent was added to each sample to a final concentration of 2% DM (n-decyl-β-D-maltoside), DDM (n-dodecyl β-D-maltoside), C12E8 (octaethylene glycol monododecyl ether), OG (n-octyl-β-D-glucopyranoside), CHAPS (3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate), LDAO (lauryldimethylamine-N-oxide), CYMAL-2 (2-cyclohexyl-1-ethyl-β-D-maltoside), or CYMAL-6 (6-cyclohexyl-1-hexyl-β-D-maltoside), and shaken overnight at 4 °C. The detergent/membrane solubilized suspensions were centrifuged at 100,000 × g at 4 °C for 1 h to yield a detergent-soluble supernatant and a detergent-insoluble pellet fraction. For gel loading, the detergent-insoluble pellet fraction was homogenized in 4 mL of 8 M urea. All other gel-loading samples were suspended in SDS-PAGE loading buffer (1X XT Sample Buffer [Bio-Rad #161-0791], 715 mM 2-mercaptoethanol). PelB-P66 was similarly treated except that the low-speed centrifugation steps was done at 20,000 × g, and the high-speed was at 50,000 × g for 2 h. All eight detergents screened are shown in Supplementary Fig. S9. The Supplementary Methods describes SDS-PAGE, Western blot analyses, silver stain, and the small-scale purification by nickel affinity in Fig. 2b.
Isolation of a cell outer membrane fraction, detergent extraction, and purification of BBA57
A sarkosyl-insoluble cell OM fraction was isolated with N-lauroyl sarcosine, and BBA57 was solubilized with 2% DDM (Fig. 4a,b) as follows. Cell pellets from 1 L expression growth cultures were thawed and suspended in Protein Buffer (all pellets in prep were resuspended in 10 mL Protein Buffer per 1 g pellet mass) with 20 mM imidazole (without lysozyme). The lysate was sonicated on ice using a Branson Sonifier (5 s ON, 5 s OFF, total 1 min ON, at 60% power, repeated 3x). A low speed centrifugation step (5,000 × g for 10 min at 4 °C) yielded supernatant and pellet. The supernatant was centrifuged at high speed (150,000 × g for 1 h at 4 °C). The supernatant, containing soluble proteins (i.e., non-membrane-bound cytoplasmic and periplasmic proteins), was separated from the pellet, containing the cell membrane fraction. The membrane pellet was suspended using a homogenizer in Protein Buffer. N-Lauroyl sarcosine sodium salt (sarkosyl) was added to the suspension to a final concentration of 0.5% and incubated with shaking for 30 min at room temperature. The sarkosyl-insoluble OM pellet was collected by high speed centrifugation (150,000 x g for 1 h at 4 °C). The OM pellet was washed by homogenizing in Protein Buffer with 20 mM imidazole, and centrifuged at high speed (150,000 × g for 1 h at 4 °C). The washed OM pellet was resuspended in Protein Buffer with 2% DDM and 20 mM imidazole and incubated overnight with shaking at 4 °C. The solution was centrifuged at 150,000 × g at 4 °C for 1 h to yield a detergent-soluble supernatant and a detergent-insoluble pellet fraction. The detergent-soluble BBA57 was purified over a 5 mL GE Healthcare HisTrap HP column on an ÄKTA pure system at 4 °C. Insoluble particles were removed by centrifugation at 17,000 × g for 10 min prior to loading. The bound protein was washed with chilled 20 mM Tris pH 8.0, 500 mM NaCl, 0.05% DDM, 20 mM imidazole, and then washed with chilled buffer containing 80 mM imidazole. BBA57 was eluted with the same buffer containing 500 mM imidazole and collected in 1 mL fractions. LC/MS/MS using an Orbitrap Fusion Lumos Tribrid was performed by the Mass Spectrometry Facility at Arizona State University.
Gel filtration chromatography
Nickel purified DDM-soluble BBA57 was purified by gel filtration chromatography from nickel-purified fractions that were pooled and concentrated down to 1 mL using a 30 K cutoff spin filter. The concentrated sample was purified over a GE Superdex 200 Increase 10/300 column on an ÄKTA pure system. Circular dichroism is described in Supplementary Methods.
Negative stain imaging
BBA57 at 0.01 mg/mL was diluted 2-fold before applying on a glow-discharged homemade carbon coated grid. The grid was washed several times with water that was removed by side blotting, followed by a staining step with 0.75% uranyl formate solution. For imaging, the grid was inserted into a Phillips CM12 microscope at the Eyring Materials Center at Arizona State University. The image was obtained in 140 kX magnification.
Data availability
No datasets were generated or analyzed during the current study.
Change history
02 March 2020
An amendment to this paper has been published and can be accessed via a link at the top of the paper.
References
Mead, P. S. Epidemiology of Lyme disease. Infect. Dis. Clin. North Am. 29, 187–210 (2015).
Centers for Disease Control and Prevention. Lyme disease: data and surveillance, https://www.cdc.gov/lyme/datasurveillance/ (2019).
Steere, A. C. et al. Lyme borreliosis. Nat. Rev. Dis. Primers 2, 16090 (2016).
Stanek, G. & Strle, F. Lyme borreliosis-from tick bite to diagnosis and treatment. FEMS Microbiol. Rev. 42, 233–258 (2018).
Liu, J. et al. Intact flagellar motor of Borrelia burgdorferi revealed by cryo-electron tomography: evidence for stator ring curvature and rotor/C-ring assembly flexion. J. Bacteriol. 191, 5026–5036 (2009).
Kenedy, M. R., Lenhart, T. R. & Akins, D. R. The role of Borrelia burgdorferi outer surface proteins. FEMS Immunol. Med. Microbiol. 66, 1–19 (2012).
Pulzova, L. & Bhide, M. Outer surface proteins of Borrelia: peerless immune evasion tools. Curr. Protein Pept. Sci. 15, 75–88 (2014).
Fraser, C. M. et al. Genomic sequence of a Lyme disease spirochaete, Borrelia burgdorferi. Nature 390, 580–586 (1997).
Yang, X. F., Pal, U., Alani, S. M., Fikrig, E. & Norgard, M. V. Essential role for OspA/B in the life cycle of the Lyme disease spirochete. J. Exp. Med. 199, 641–648 (2004).
Koci, J., Bernard, Q., Yang, X. & Pal, U. Borrelia burgdorferi surface protein Lmp1 facilitates pathogen dissemination through ticks as studied by an artificial membrane feeding system. Sci. Rep. 8, 1910 (2018).
Kung, F. et al. A Borrelia burgdorferi surface-exposed transmembrane protein lacking detectable immune responses supports pathogen persistence and constitutes a vaccine target. J. Infect. Dis. 213, 1786–1795 (2016).
Tilly, K. et al. Borrelia burgdorferi OspC protein required exclusively in a crucial early stage of mammalian infection. Infect. Immun. 74, 3554–3564 (2006).
Ristow, L. C. et al. The β3-integrin ligand of Borrelia burgdorferi is critical for infection of mice but not ticks. Mol. Microbiol. 85, 1105–1118 (2012).
Bunikis, I. et al. An RND-type efflux system in Borrelia burgdorferi is involved in virulence and resistance to antimicrobial compounds. PLoS Pathog. 4, e1000009 (2008).
Curtis, M. W. et al. Characterization of stress and innate immunity resistance of wild-type and Δp66 Borrelia burgdorferi. Infect. Immun. 86, e00186–00117 (2018).
Ristow, L. C. et al. Integrin binding by Borrelia burgdorferi P66 facilitates dissemination but is not required for infectivity. Cell. Microbiol. 17, 1021–1036 (2015).
Shi, Y., Xu, Q., McShan, K. & Liang, F. T. Both decorin-binding proteins A and B are critical for the overall virulence of Borrelia burgdorferi. Infect. Immun. 76, 1239–1246 (2008).
Yang, X., Coleman, A. S., Anguita, J. & Pal, U. A chromosomally encoded virulence factor protects the Lyme disease pathogen against host-adaptive immunity. PLoS Pathog. 5, e1000326 (2009).
Pal, U. et al. TROSPA, an Ixodes scapularis receptor for Borrelia burgdorferi. Cell 119, 457–468 (2004).
Ramamoorthi, N. et al. The Lyme disease agent exploits a tick protein to infect the mammalian host. Nature 436, 573–577 (2005).
Önder, Ö. et al. OspC is potent plasminogen receptor on surface of Borrelia burgdorferi. J. Biol. Chem. 287, 16860–16868 (2012).
Yang, X. et al. Middle region of the Borrelia burgdorferi surface-located protein 1 (Lmp1) interacts with host chondroitin-6-sulfate and independently facilitates infection. Cell. Microbiol. 18, 97–110 (2016).
Coburn, J., Chege, W., Magoun, L., Bodary, S. C. & Leong, J. M. Characterization of a candidate Borrelia burgdorferi β3-chain integrin ligand identified using a phage display library. Mol. Microbiol. 34, 926–940 (1999).
Coburn, J. & Cugini, C. Targeted mutation of the outer membrane protein P66 disrupts attachment of the Lyme disease agent, Borrelia burgdorferi, to integrin αVβ3. Proc. Natl. Acad. Sci. USA 100, 7301–7306 (2003).
Guo, B. P., Brown, E. L., Dorward, D. W., Rosenberg, L. C. & Höök, M. Decorin-binding adhesins from Borrelia burgdorferi. Mol. Microbiol. 30, 711–723 (1998).
Kenedy, M. R. et al. Consensus computational network analysis for identifying candidate outer membrane proteins from Borrelia spirochetes. BMC Microbiol. 16, 141 (2016).
Skare, J. T. et al. The Oms66 (p66) protein is a Borrelia burgdorferi porin. Infect. Immun. 65, 3654–3661 (1997).
Shrestha, B., Kenedy, M. R. & Akins, D. R. Outer membrane proteins BB0405 and BB0406 are immunogenic, but only BB0405 is required for Borrelia burgdorferi infection. Infect. Immun. 85, e00803–00816 (2017).
Kenedy, M. R. et al. Structural modeling and physicochemical characterization provide evidence that P66 forms a β-barrel in the Borrelia burgdorferi outer membrane. J. Bacteriol. 196, 859–872 (2014).
Zückert, W. R. Secretion of bacterial lipoproteins: through the cytoplasmic membrane, the periplasm and beyond. Biochim. Biophys. Acta 1843, 1509–1516 (2014).
Iqbal, H., Kenedy, M. R., Lybecker, M. & Akins, D. R. The TamB ortholog of Borrelia burgdorferi interacts with the β-barrel assembly machine (BAM) complex protein BamA. Mol. Microbiol. 102, 757–774 (2016).
Stubenrauch, C., Grinter, R. & Lithgow, T. The modular nature of the β-barrel assembly machinery, illustrated in Borrelia burgdorferi. Mol. Microbiol. 102, 753–756 (2016).
Rose, P. W. et al. The RCSB protein data bank: integrative view of protein, gene and 3D structural information. Nucleic Acids Res. 45, D271–D281 (2017).
Stephen White laboratory at UC Irvine. Membrane proteins of known 3D structure, http://blanco.biomol.uci.edu/mpstruc/ (2019).
Skare, J. T. et al. Porin activity of the native and recombinant outer membrane protein Oms28 of Borrelia burgdorferi. J. Bacteriol. 178, 4909–4918 (1996).
Thein, M. et al. DipA, a pore-forming protein in the outer membrane of Lyme disease spirochetes exhibits specificity for the permeation of dicarboxylates. PLoS One 7, e36523 (2012).
Ramsey, M. E. et al. A high-throughput genetic screen identifies previously uncharacterized Borrelia burgdorferi genes important for resistance against reactive oxygen and nitrogen species. PLoS Pathog. 13, e1006225 (2017).
Yang, X. et al. Characterization of multiprotein complexes of the Borrelia burgdorferi outer membrane vesicles. J. Proteome Res. 10, 4556–4566 (2011).
Stanek, G., Wormser, G. P., Gray, J. & Strle, F. Lyme borreliosis. Lancet 379, 461–473 (2012).
Cadavid, D. & Barbour, A. G. Neuroborreliosis during relapsing fever: review of the clinical manifestations, pathology, and treatment of infections in humans and experimental animals. Clin. Infect. Dis. 26, 151–164 (1998).
Dong, C. et al. Wza the translocon for E. coli capsular polysaccharides defines a new class of membrane protein. Nature 444, 226–229 (2006).
Goyal, P. et al. Structural and mechanistic insights into the bacterial amyloid secretion channel CsgG. Nature 516, 250–253 (2014).
Nesper, J. et al. Translocation of group 1 capsular polysaccharide in Escherichia coli serotype K30. Structural and functional analysis of the outer membrane lipoprotein Wza. J. Biol. Chem. 278, 49763–49772 (2003).
Abellón-Ruiz, J. et al. Structural basis for maintenance of bacterial outer membrane lipid asymmetry. Nat Microbiol 2, 1616–1623 (2017).
Meng, G., Surana, N. K., St. Geme, J. W. III & Waksman, G. Structure of the outer membrane translocator domain of the Haemophilus influenzae Hia trimeric autotransporter. EMBO J. 25, 2297-2304 (2006).
Koronakis, V., Sharff, A., Koronakis, E., Luisi, B. & Hughes, C. Crystal structure of the bacterial membrane protein TolC central to multidrug efflux and protein export. Nature 405, 914–919 (2000).
Yang, X. et al. Novel microbial virulence factor triggers murine Lyme arthritis. J. Infect. Dis. 207, 907–918 (2013).
Barbour, A. G. et al. A genome-wide proteome array reveals a limited set of immunogens in natural infections of humans and white-footed mice with Borrelia burgdorferi. Infect. Immun. 76, 3374–3389 (2008).
Tokarz, R. et al. A multiplex serologic platform for diagnosis of tick-borne diseases. Sci. Rep. 8, 3158 (2018).
Bernard, Q. et al. Plasticity in early immune evasion strategies of a bacterial pathogen. Proc. Natl. Acad. Sci. USA 115, E3788–E3797 (2018).
Brooks, C. S., Vuppala, S. R., Jett, A. M. & Akins, D. R. Identification of Borrelia burgdorferi outer surface proteins. Infect. Immun. 74, 296–304 (2006).
Caimano, M. J. et al. Analysis of the RpoS regulon in Borrelia burgdorferi in response to mammalian host signals provides insight into RpoS function during the enzootic cycle. Mol. Microbiol. 65, 1193–1217 (2007).
Radolf, J. D. Pulling the trigger on lyme arthritis. J. Infect. Dis. 207, 877–879 (2013).
Dowdell, A. S. et al. Comprehensive spatial analysis of the Borrelia burgdorferi lipoproteome reveals a compartmentalization bias toward the bacterial surface. J. Bacteriol. 199, e00658–00616 (2017).
Rath, A., Glibowicka, M., Nadeau, V. G., Chen, G. & Deber, C. M. Detergent binding explains anomalous SDS-PAGE migration of membrane proteins. Proc. Natl. Acad. Sci. USA 106, 1760–1765 (2009).
Sletta, H. et al. The presence of N-terminal secretion signal sequences leads to strong stimulation of the total expression levels of three tested medically important proteins during high-cell-density cultivations of Escherichia coli. Appl. Environ. Microbiol. 73, 906–912 (2007).
Huang, C., Rossi, P., Saio, T. & Kalodimos, C. G. Structural basis for the antifolding activity of a molecular chaperone. Nature 537, 202–206 (2016).
Hilf, R. J. & Dutzler, R. Structure of a potentially open state of a proton-activated pentameric ligand-gated ion channel. Nature 457, 115–118 (2009).
Puthenveetil, R. et al. The major outer sheath protein forms distinct conformers and multimeric complexes in the outer membrane and periplasm of Treponema denticola. Sci. Rep. 7, 13260 (2017).
Konovalova, A., Kahne, D. E. & Silhavy, T. J. Outer membrane biogenesis. Annu. Rev. Microbiol. 71, 539–556 (2017).
Kudva, R. et al. Protein translocation across the inner membrane of Gram-negative bacteria: the Sec and Tat dependent protein transport pathways. Res. Microbiol. 164, 505–534 (2013).
Kuhn, A., Koch, H. G. & Dalbey, R. E. Targeting and insertion of membrane proteins. EcoSal Plus 7, ESP-0012-2016 (2017).
Konovalova, A. & Silhavy, T. J. Outer membrane lipoprotein biogenesis: Lol is not the end. Philos. Trans. R. Soc. Lond. B Biol. Sci. 370, 20150030 (2015).
Merdanovic, M., Clausen, T., Kaiser, M., Huber, R. & Ehrmann, M. Protein quality control in the bacterial periplasm. Annu. Rev. Microbiol. 65, 149–168 (2011).
Meng, G., Fronzes, R., Chandran, V., Remaut, H. & Waksman, G. Protein oligomerization in the bacterial outer membrane (Review). Mol. Membr. Biol. 26, 136–145 (2009).
Sutcliffe, I. C., Harrington, D. J. & Hutchings, M. I. A phylum level analysis reveals lipoprotein biosynthesis to be a fundamental property of bacteria. Protein Cell 3, 163–170 (2012).
Dunn, J. P., Kenedy, M. R., Iqbal, H. & Akins, D. R. Characterization of the β-barrel assembly machine accessory lipoproteins from Borrelia burgdorferi. BMC Microbiol. 15, 70 (2015).
Wilson, M. M. & Bernstein, H. D. Surface-exposed lipoproteins: an emerging secretion phenomenon in Gram-negative bacteria. Trends Microbiol. 24, 198–208 (2016).
Fikrig, E., Barthold, S. W., Kantor, F. S. & Flavell, R. A. Protection of mice against the Lyme disease agent by immunizing with recombinant OspA. Science 250, 553–556 (1990).
LaRocca, T. J. et al. The bactericidal effect of a complement-independent antibody is osmolytic and specific to Borrelia. Proc. Natl. Acad. Sci. USA 106, 10752–10757 (2009).
Filip, C., Fletcher, G., Wulff, J. L. & Earhart, C. F. Solubilization of the cytoplasmic membrane of Escherichia coli by the ionic detergent sodium-lauryl sarcosinate. J. Bacteriol. 115, 717–722 (1973).
Bárcena-Uribarri, I. et al. Study of the protein complex, pore diameter, and pore-forming activity of the Borrelia burgdorferi P13 porin. J. Biol. Chem. 289, 18614–18624 (2014).
Noppa, L., Östberg, Y., Lavrinovicha, M. & Bergström, S. P13, an integral membrane protein of Borrelia burgdorferi, is C-terminally processed and contains surface-exposed domains. Infect. Immun. 69, 3323–3334 (2001).
Tusnády, G. E. & Simon, I. Principles governing amino acid composition of integral membrane proteins: application to topology prediction. J. Mol. Biol. 283, 489–506 (1998).
Krogh, A., Larsson, B., von Heijne, G. & Sonnhammer, E. L. Predicting transmembrane protein topology with a hidden Markov model: application to complete genomes. J. Mol. Biol. 305, 567–580 (2001).
Nakai, K. & Horton, P. PSORT: a program for detecting sorting signals in proteins and predicting their subcellular localization. Trends Biochem. Sci. 24, 34–36 (1999).
Hansen, D. T. et al. Polyclonal antibody production for membrane proteins via genetic immunization. Sci. Rep. 6, 21925 (2016).
Backert, S., Bernegger, S., Skórko-Glonek, J. & Wessler, S. Extracellular HtrA serine proteases: an emerging new strategy in bacterial pathogenesis. Cell. Microbiol. 20, e12845 (2018).
Kariu, T., Yang, X., Marks, C. B., Zhang, X. & Pal, U. Proteolysis of BB0323 results in two polypeptides that impact physiologic and infectious phenotypes in Borrelia burgdorferi. Mol. Microbiol. 88, 510–522 (2013).
Brangulis, K., Akopjana, I., Kazaks, A. & Tars, K. Crystal structure of the N-terminal domain of the major virulence factor BB0323 from the Lyme disease agent Borrelia burgdorferi. Acta Crystallogr D Struct Biol 75, 825–830 (2019).
Brissette, C. A., Bykowski, T., Cooley, A. E., Bowman, A. & Stevenson, B. Borrelia burgdorferi RevA antigen binds host fibronectin. Infect. Immun. 77, 2802–2812 (2009).
Kozjak-Pavlovic, V., Ross, K., Götz, M., Goosmann, C. & Rudel, T. A tag at the carboxy terminus prevents membrane integration of VDAC1 in mammalian mitochondria. J. Mol. Biol. 397, 219–232 (2010).
Aunkham, A. et al. Structural basis for chitin acquisition by marine Vibrio species. Nat. Commun. 9, 220 (2018).
Zückert, W. R. Protein secretion in spirochetes. Microbiol Spectr 7 (2019).
Crowley, J. T. et al. Lipid exchange between Borrelia burgdorferi and host cells. PLoS Pathog. 9, e1003109 (2013).
Takayama, K., Rothenberg, R. J. & Barbour, A. G. Absence of lipopolysaccharide in the Lyme disease spirochete, Borrelia burgdorferi. Infect. Immun. 55, 2311–2313 (1987).
Huang, Z. & London, E. Cholesterol lipids and cholesterol-containing lipid rafts in bacteria. Chem. Phys. Lipids 199, 11–16 (2016).
LaRocca, T. J. et al. Cholesterol lipids of Borrelia burgdorferi form lipid rafts and are required for the bactericidal activity of a complement-independent antibody. Cell Host Microbe 8, 331–342 (2010).
Coleman, J. L., Toledo, A. & Benach, J. L. Borrelia burgdorferi HtrA: evidence for twofold proteolysis of outer membrane protein p66. Mol. Microbiol. 99, 135–150 (2016).
Zhuang, X., Yang, X., Altieri, A. S., Nelson, D. C. & Pal, U. Borrelia burgdorferi surface-located Lmp1 protein processed into region-specific polypeptides that are critical for microbial persistence. Cell. Microbiol. 20, e12855 (2018).
Östberg, Y. et al. Pleiotropic effects of inactivating a carboxyl-terminal protease, CtpA, in Borrelia burgdorferi. J. Bacteriol. 186, 2074–2084 (2004).
Kariu, T. et al. BB0323 and novel virulence determinant BB0238: Borrelia burgdorferi proteins that interact with and stabilize each other and are critical for infectivity. J. Infect. Dis. 211, 462–471 (2015).
Thakur, M. et al. A protein-protein interaction dictates Borrelial infectivity. Sci. Rep. 7, 2932 (2017).
Clantin, B. et al. Structure of the membrane protein FhaC: a member of the Omp85-TpsB transporter superfamily. Science 317, 957–961 (2007).
Noinaj, N. et al. Structural basis for iron piracy by pathogenic Neisseria. Nature 483, 53–58 (2012).
Pinne, M. et al. Elimination of channel-forming activity by insertional inactivation of the p66 gene in Borrelia burgdorferi. FEMS Microbiol. Lett. 266, 241–249 (2007).
Guzman, L. M., Belin, D., Carson, M. J. & Beckwith, J. Tight regulation, modulation, and high-level expression by vectors containing the arabinose PBAD promoter. J. Bacteriol. 177, 4121–4130 (1995).
Drecktrah, D. & Samuels, D. S. Genetic manipulation of Borrelia spp. Curr. Top. Microbiol. Immunol. 415, 113–140 (2018).
Skare, J. T. et al. Virulent strain associated outer membrane proteins of Borrelia burgdorferi. J. Clin. Invest. 96, 2380–2392 (1995).
Travier, L. et al. ActA promotes Listeria monocytogenes aggregation, intestinal colonization and carriage. PLoS Pathog. 9, e1003131 (2013).
Grosenbaugh, D. A. et al. Characterization of recombinant OspA in two different Borrelia vaccines with respect to immunological response and its relationship to functional parameters. BMC Vet. Res. 14, 312 (2018).
Miroux, B. & Walker, J. E. Over-production of proteins in Escherichia coli: mutant hosts that allow synthesis of some membrane proteins and globular proteins at high levels. J. Mol. Biol. 260, 289–298 (1996).
Schlegel, S. et al. Optimizing membrane protein overexpression in the Escherichia coli strain Lemo21(DE3). J. Mol. Biol. 423, 648–659 (2012).
Puertas, J. M., Nannenga, B. L., Dornfeld, K. T., Betton, J. M. & Baneyx, F. Enhancing the secretory yields of leech carboxypeptidase inhibitor in Escherichia coli: influence of trigger factor and signal recognition particle. Protein Expr. Purif. 74, 122–128 (2010).
Narayanan, A., Ridilla, M. & Yernool, D. A. Restrained expression, a method to overproduce toxic membrane proteins by exploiting operator-repressor interactions. Protein Sci. 20, 51–61 (2011).
Nishimura, A., Morita, M., Nishimura, Y. & Sugino, Y. A rapid and highly efficient method for preparation of competent Escherichia coli cells. Nucleic Acids Res. 18, 6169 (1990).
Martin-Garcia, J. M. et al. Purification and biophysical characterization of the CapA membrane protein FTT0807 from Francisella tularensis. Biochemistry 53, 1958–1970 (2014).
Baba, T. et al. Construction of Escherichia coli K-12 in-frame, single-gene knockout mutants: the Keio collection. Mol. Syst. Biol. 2, 2006.0008 (2006).
Acknowledgements
We thank Dr. Stephen A. Johnston and the Biodesign Center for Innovations in Medicine for their support, and François Baneyx (University of Washington) for providing the KTD101 strain. This work was supported by the Biodesign Center for Applied Structural Discovery at Arizona State University and by the U.S. National Institutes of Health U54 grant GM094599 (P.F.).
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K.E.R. performed most of the work; C.D.T. performed the negative stain with input from P.C.; J.Y.H. performed initial negative stain screening; F.M.C. developed the small scale screen and performed most of the cloning; K.E.R. and D.T.H. wrote the paper with input from P.F.; D.T.H. and P.F. directed the study.
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Robertson, K.E., Truong, C.D., Craciunescu, F.M. et al. Membrane directed expression in Escherichia coli of BBA57 and other virulence factors from the Lyme disease agent Borrelia burgdorferi. Sci Rep 9, 17606 (2019). https://doi.org/10.1038/s41598-019-53830-x
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DOI: https://doi.org/10.1038/s41598-019-53830-x
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