Single-fluorescent protein biosensors (SFPBs) are an important class of probes that enable the single-cell quantification of analytes in vivo. Despite advantages over other detection technologies, their use has been limited by the inherent challenges of their construction. Specifically, the rational design of green fluorescent protein (GFP) insertion into a ligand-binding domain, generating the requisite allosteric coupling, remains a rate-limiting step. Here, we describe an unbiased approach, termed domain-insertion profiling with DNA sequencing (DIP-seq), that combines the rapid creation of diverse libraries of potential SFPBs and high-throughput activity assays to identify functional biosensors. As a proof of concept, we construct an SFPB for the important regulatory sugar trehalose. DIP-seq analysis of a trehalose-binding-protein reveals allosteric hotspots for GFP insertion and results in high-dynamic range biosensors that function robustly in vivo. Taken together, DIP-seq simultaneously accelerates metabolite biosensor construction and provides a novel tool for interrogating protein allostery.
Probing metabolism in situ is critical to understanding the molecular physiology of the cell1,2. Current analytical techniques, such as mass spectrometry, have proven extremely informative but are also limited by their low spatial resolution, low throughput, and invasiveness3. Alternatively, an expanding array of genetically encoded biosensors allows quantification of individual metabolites with high spatiotemporal resolution in the native cellular context3,4,5. These protein- and RNA-based biosensors detect metabolites with exquisite specificity and trigger real-time fluorescent or chemiluminescent output signals.
Single-fluorescent protein biosensors (SFPBs) are particularly promising for their combination of linear response to substrate concentration and high dynamic range. SFPBs are composed of a circularly permuted green fluorescent protein (cpGFP) inserted into the primary sequence of a specific ligand-binding domain (LBD) (Fig. 1a)6. Allosteric coupling between the LBD and cpGFP domains engenders a ligand-dependent fluorescence change on metabolite binding. For example, the GCaMP family of genetically encoded calcium indicators is constructed by inserting cpGFP between calmodulin and the M13 peptide7. However, despite their potential, the palette of existing SFPBs is limited due to the difficulty of rationally designing an allosteric connection between cpGFP and a given LBD.
Randomized, library-based approaches have successfully created functional allosteric linkages between protein domains, but have not been applied to biosensors8. Compared with the rational design of a few carefully selected fusions, random domain-insertion methods are advantageous because they potentially sample all possible insertion-site variants without prior structural or mechanistic knowledge. This mimics natural gene fusion, the mechanism used by evolution to generate modular, multi-domain proteins9.
Here, motivated by recent work exploring the sequence-function space of proteins in a high-throughput fashion10,11, we describe a library-based approach, incorporating fluorescent screening and next-generation sequencing (NGS), that aims to identify allosteric hotspots as a means of accelerating the development of protein biosensors. It was previously shown that in vitro transposition can be used to randomly insert one protein domain into another12,13. We have refined this approach to improve efficiency and minimize the transposon ‘scar’ sequence in fusion proteins. Using the Escherichia coli D-maltose-binding protein (MBP)14 as a proof of concept, we demonstrate that transposon-mediated insertion of cpGFP creates diverse domain-insertion libraries containing allosterically coupled biosensors. To further enhance our method for generating SFPBs, we construct a library of cpGFP insertions within the Thermococcus litoralis D-trehalose/D-maltose-binding protein (TMBP)15, subject it to successive rounds of functional enrichment using fluorescence-activated cell sorting (FACS), and monitor this process using DNA sequencing (Fig. 1b). Tracking of the libraries with NGS reveals that enrichment correlates closely with biosensor function, which leads to the facile isolation of high-dynamic-range biosensors that function well in vivo. Taken together, domain-insertion profiling with sequencing (DIP-seq) allows for the rapid construction of functional SFPBs and, more broadly, the identification of allosteric hotspots within any protein.
Creating random domain-insertion libraries using transposons
A method for randomized insertion of one protein domain into another was developed using transposons. Synthetic Mu transposition into plasmid DNA can be catalysed in vitro (refs 16, 17) and so a number of Mu variants, possessing internal DNA type IIS restriction sites, was assayed for function (Supplementary Fig. 1). The location of these sites provided programmable cut sites with minimal scarring. One variant with BsaI sites (Mu-BsaI), encoding alanine–serine linkers at either end, was used to introduce insertions throughout our target LBDs (Fig. 1c and Supplementary Fig. 1c). After transposition, the open reading frame (ORF) insertion library was subcloned into a new expression vector to eliminate insertions outside of the target ORF. The Mu-BsaI cassette was then excised and replaced with cpGFP by Golden Gate assembly with BsaI (Fig. 1c)18. This technique provides efficient construction of complete domain-insertion libraries and precise control of connecting linker sequences.
An SFPB fashioned around MBP was used as a proof of concept to validate the utility of domain-insertion libraries. This LBD served as a benchmark for our approach because previous studies used MBP to generate allosteric fusions8,19. MBP-cpGFP libraries were created in duplicate using the engineered-transposon method. Notably, the initial naive library included insertions in all six reading frames due to the inherent randomness of Mu transposition. Because only productive (forward and in-frame) and correctly folded cpGFP insertions will result in fluorescent constructs, the libraries were screened with FACS in the presence of maltose to deplete unproductive (reverse or out-of-frame) insertions and misfolded constructs (Fig. 2a). NGS sequencing of the sorting process revealed that FACS enriched for forward oriented, in-frame insertions, with 95 productive and only 4 unproductive insertions showing significant enrichment (P<0.1). In all, 210 (of 370 possible) productive insertions were detected in the final library (Fig. 2b, Supplementary Fig. 2a,b). These data show that our transposon technique rapidly builds diverse domain-insertion libraries.
Assay of the MBP-cpGFP domain-insertion libraries revealed the presence of several functional maltose biosensors. Constructs from the sorted libraries were expressed and tested for in vivo biosensor activity in 96-well plate format. Activity was evaluated by the fluorescent change of cells after addition of saturating maltose to the medium and calculated as ΔF/F (that is, (Fligand−F0)/F0). Two 96-well plates were screened from each library, and twelve unique cpGFP insertion sites were found to have marked activity (ΔF/F⩾0.5, Supplementary Fig. 2c). Interestingly, mapping these insertion sites onto the structure of MBP revealed that the sites were three-dimensionally clustered despite being noncontiguous in primary sequence (Fig. 2c). In addition, even though maltose binding causes MBP to close its two domains together in a rigid-body hinge motion20,21, active insertion sites were not exclusively found in these areas of macroscopic conformational change (Supplementary Fig. 3). These results show that testing a diverse library can locate, and reveal trends of, allosteric hotspots of biosensor function.
Several of these biosensors possessed a high dynamic range (ΔF/F⩾1). Activity screening revealed that cpGFP insertion at amino acids 169 and 171 produced highly functional biosensors (ΔF/F=2.4±0.2 and ΔF/F=1.6±0.1, (mean±s.d.), respectively; Fig. 2d). The intervening site, 170, was not detected in the few plates screened but was found to be enriched in the NGS analysis (Supplementary Fig. 2a). When constructed and assayed, this fusion was shown to be an equally active biosensor (ΔF/F=2.5±0.3, s.d.; Fig. 2d). These constructs showed greater dynamic range than the best-reported MBP-cpGFP biosensor, EcMBP165-cpGFP.PPYF.T203V (ΔF/F=0.5±0.1, s.d.; Fig. 2d)19. As with previous work, we found that biosensor function could be markedly improved through LBD-cpGFP linker engineering (ΔF/F=8.1±0.3, s.d.; Supplementary Figs 4 and 5)22. Taken together, these experiments with MBP validate the hypothesis that diverse domain-insertion libraries can be used to map allosteric hotspots and construct functional SFPBs.
DIP-seq robustly generates trehalose biosensors
We next tested whether two enhancements could improve our ability to identify the best biosensors and provide a profile of functional domain-insertion sites: (i) additional rounds of FACS, enriching for the desired switching behaviour in the presence and absence of ligand; and (ii) NGS analysis to detect functional biosensors that are enriched but which are in low abundance due to non-uniform libraries. This enhanced approach, which we term DIP-seq, was used to assess the potential of TMBP as a biosensor scaffold for trehalose. Trehalose is a molecule of biological interest that is implicated in stress tolerance and metabolic regulation of yeast and plants but for which there is no available SFPB23,24,25. Independent transposon libraries, in triplicate, were used to create libraries of cpGFP insertions into the TMBP ligand-binding domain. The libraries were then taken through three iterative rounds of FACS screening. An initial round of positive sorting in the presence of trehalose was followed by a negative round without trehalose to enrich for active, switchable biosensors. A final round of positive sorting in the presence of trehalose was conducted to enrich switches still capable of binding trehalose (Fig. 3a–c).
NGS of the library population, in time, revealed FACS applied a strong selective pressure towards constructs with forward, in-frame cpGFP insertions. Two of the libraries were sequenced before and after every sort, and comparison of the final sort to the initial, naive library revealed that productive insertions were broadly enriched while non-productive insertions were strongly depleted (Fig. 3d). Since a large majority of productive insertions were enriched, fold-change values were recalculated relative to only productive insertions for further analysis. These enrichments were mapped to the primary sequence of TMBP and show that TMBP is enriched for insertions throughout its primary sequence (Fig. 3e).
Functional assay of the final libraries revealed a strong correlation between enrichment and dynamic range of a biosensor. In vivo activity screening of individual clones after the third sort identified several biosensors (cutoff of ΔF/F⩾0.5) but sequencing revealed only a limited diversity of insertion sites (Supplementary Fig. 6). This observation agreed with NGS data, which confirmed that a small number of constructs dominated the library. As a result, there was no significant correlation between biosensor activity (that is, the ΔF/F value) and final NGS read count (Fig. 4a). Analysis of construct abundance in the NGS data revealed an ∼1,000-fold variation in the naive library, suggesting initial bias in a library limited the utility of this metric (Supplementary Fig. 7). In contrast, there was a very strong correlation between activity and the fold enrichment of individual biosensors between the final sorted library and the initial naive library (Fig. 4b). Analysis of biosensor activity versus fold-enrichment at individual rounds did not reveal this trend (Supplementary Fig. 8). The correlation only emerged as a result of multiple sorting rounds (Fig. 4b). Thus, our data indicate that successive rounds of profiling with FACS and NGS are crucial to enrich and track functional, in-frame, fluorescent biosensors. Specifically, DIP-seq analysis of the initial and final libraries may be crucial in identifying rare variants that are nonetheless highly functional biosensors.
Mapping of NGS fold-enrichment data (Fig. 4c), as well as biosensor activity (Supplementary Fig. 9 a,b) on the structure of TMBP, revealed that the most enriched—and the most active—sites were three-dimensionally clustered in two distinct regions of the protein. Interestingly, although MBP and TMBP are homologous (28% sequence identity15), functional insertion sites for each protein did not overlap substantially (Supplementary Fig. 9c). In addition, some of the best insertion sites from one protein backbone did not produce significant biosensors in the other. These included site 302 in MBP, representing Tre-334 in TMBP (Fig. 2d) and sites 196/197 in TMBP, representing Mal-169/Mal-170 in MBP (Supplementary Fig. 10). These observations further underscore the utility of DIP-seq and the inconsistent linkage between homology and allostery26.
Improving in vivo activity and dynamic range of biosensing
To demonstrate the potential of our novel biosensors, one insertion site was optimized for use in physiological experiments. Specifically, Tre-334—a biosensor found in all three replicate libraries—was optimized by varying the amino-acid linkers connecting cpGFP and TMBP (Supplementary Fig. 11a), and subsequently screened for enhanced function. We generated a library of variants containing zero to three amino acid linkers at this insertion site and subjected the library to a single round of FACS screening in the presence of saturating trehalose (Supplementary Fig. 11b). In vivo screening of three 96-well plates revealed that the vast majority of variants were functional biosensors and had dynamic ranges greater than the parental biosensor (Supplementary Fig. 11d). This suggests that performing DIP-seq with a fixed linker is sufficient to identify allosteric hotspots within proteins. Then, once hotspots are identified, linker optimization can be used to further increase the dynamic range as needed.
Tre-C04 was identified in this screen as a high dynamic range biosensor (ΔF/F=6.3±0.6, s.d.; Fig. 5a and Supplementary Fig. 11c) and chosen for further characterization. Biochemical analysis of purified Tre-C04 confirmed that it was a high-affinity and high-selectivity biosensor with a preference for trehalose (KD=53±1 nM, s.d.) and lower affinity towards the related maltose (KD=81±1 nM, s.d.) (Supplementary Fig. 12d). Related sugars displayed little or no activation, even at high concentrations (Supplementary Fig. 12e). The trehalose-activated biosensor was found to be 44% as bright as sfGFP (Methods section) providing further evidence of its utility in vivo.
Initial in vivo testing verified Tre-C04 responded to trehalose with high activity (Fig. 5a), and so we attempted to determine whether the biosensor was reversible and responded to real-time, dynamic changes. We found that during exponential phase, when E. coli do not normally produce trehalose27, trehalose addition resulted in an immediate, dose-dependent increase in biosensor fluorescence (Fig. 5b). At intermediate trehalose levels, the fluorescent response eventually diminished with trehalose catabolism and this behaviour repeated on further trehalose additions (Fig. 5b). To demonstrate the linkage between trehalase activity and the observed decrease in fluorescence response with time, cultures were treated with the trehalase inhibitor validamycin A (ref. 28). At all non-saturating concentrations of trehalose tested, validamycin A treatment resulted in a sustained fluorescence response (Supplementary Fig. 13). These experiments confirmed the capacity of our Tre-C04 biosensor to monitor dynamic changes in in vivo trehalose levels in real-time and in a dose-dependent manner.
Physiological changes in endogenous E. coli trehalose levels can also be monitored with this optimized biosensor. It is known that the trehalose biosynthetic genes are upregulated during the transition to stationary phase27. The expression of these genes is also induced to a greater extent during osmotic upshift by the addition of 300 mM sodium chloride during exponential growth27,29. As expected, Tre-C04 fluorescence levels do not begin rising until the cells enter stationary phase and the addition of sodium chloride potentiates trehalose levels by osmotic upshift (Fig. 5c). In previous reports of stationary phase trehalose accumulation, trehalose levels were undetectable due to limitations in the sensitivity of the thin-layer chromatography assay29. Using high-performance anion-exchange chromatography with pulsed amperometric detection (HPAEC-PAD), a significantly more time- and labour-intensive method that does not permit real-time monitoring, we independently measured trehalose levels and found a correlation between Tre-C04 fluorescence signal and intracellular trehalose (Supplementary Fig. 14). Tre-C04, as a real-time biosensor, thus appears to be an extremely sensitive and faithful reporter of trehalose levels.
Here we present DIP-Seq as a robust and generalizable method that couples comprehensive domain-insertion library creation with FACS and NGS to rapidly identify allosteric sites within target protein domains. This method allowed us to create functional, high-dynamic-range biosensors that probed dynamic changes in in vivo metabolite concentrations. Collectively, the unbiased and high-throughput nature of DIP-seq sidesteps the difficult task of predicting optimal insertion sites for coupling independent proteins.
Relatedly, DIP-seq provides the ability to elucidate trends that would be invisible to traditional functional screening. Previous studies engineering SFPBs garnered functional data on very few insertion sites because of the laborious nature of their methods19. Alternatively, sequencing-based enrichment analysis, such as that previously used in saturation mutagenesis studies, yields a rich landscape of structure–function information10,11. The low-stringency screening approach of DIP-seq similarly provides a comprehensive view of allosteric hotspots in a binding protein. A high-stringency screen (or continued rounds of screening) would likely enrich a handful of functional biosensors, but the decreased library diversity would also lead to loss of structure–function NGS data. In addition, sequencing-based enrichment analysis is advantageous when the initial abundance of variants is non-uniform. We observe an ∼1,000-fold variation in construct abundance in the initial library pool (Supplementary Fig. 7a). Although this may be specific to our technique, creating a uniform library is a general problem of molecular biology methods30. DIP-seq thus generates a broad picture of allosteric coupling regardless of each variant’s abundance in a library.
Furthermore, comprehensive mapping of allosteric hotspots may prove helpful in the construction of optimal biosensors. An important consideration is that libraries in this study had fixed inter-domain linker sequences. Subsequent optimization of these sequences in highly enriched variants, a known technique for SFPB improvement19,31, led to higher dynamic ranges. Further study is therefore needed to determine if less-enriched allosteric hotspots could produce superior biosensors with similar optimization methods. Similarly, while highly enriched members of this fixed-linker library showed robustness to linker sequence diversity (Supplementary Figs 4b and 11d), it is unclear if DIP-seq with a different fixed sequence would result in the same rank order of hotspots. Therefore, the comprehensive dataset DIP-seq provides is a potentially valuable roadmap in constructing the ‘best’ biosensor with a given LBD.
As a method for the rapid construction of metabolite biosensors, DIP-seq should prove useful in expanding the palette of SFPBs. This raises the question: can current ligand-binding domains span the space of known metabolites? More than 25,000 bacterial ligand-binding proteins are found in the PFAM database32. These include bacterial periplasmic binding proteins from the ATP-binding cassette family of transporters, which are known to bind many diverse ligands4,33. Given the scalability of DIP-seq, and the potential for computational redesign of ligand-binding proteins34, we believe that fluorescent biosensors can readily be fashioned for many molecules of interest.
We show this method can be used to interrogate the periplasmic binding proteins MBP and TMBP for allosteric potential and ultimately, to isolate high-dynamic-range and specific biosensors for the molecules maltose and trehalose. There is no SFPB for trehalose; the biosensor constructed here allows for real-time trehalose detection without the need for lengthy sugar extraction and analysis. Interestingly, despite homology between MBP and TMBP, identified allosteric sites in one homologue are not functional in another (Fig. 2d and Supplementary Fig. 10). This agrees with previous work26 and underscores the utility of applying DIP-seq across a family of closely related proteins.
While the work presented here is specifically in the context of SFBPs, DIP-seq may prove useful in probing the general phenomenon of protein allostery. Many forms and mechanisms of protein allostery have been discovered, all of which transmit information from one protein site to another35. This field of study has moved from classic, structure-based views of proteins36,37 to include statistical and thermodynamic perspectives informed by protein dynamics38,39. This revised view of allostery predicts that most proteins have inherent allosteric potential if correctly coupled and/or perturbed40,41. Thus, using DIP-seq we can create populations of allosteric couplings between a specific ‘input’ and ‘output’ domain to investigate the potential for allostery. For example, DIP-seq could be used to query output domains with other functions such as genome editing, like the CRISPR-Cas9 protein, as opposed to the GFP used in this work42,43.
Overall, DIP-seq allows for the interrogation of protein allostery through the identification of potential hotspots without concern for the underlying mechanism. Using controlled sets of domains with diverse allosteric connections gives insight that extant naturally evolved proteins may not. This high-throughput approach allows for the generation of data that cannot be ascertained from the engineering of a single insertion site or target protein. Ultimately, such data may uncover trends that illuminate and inform the structural and dynamical determinants of protein allostery.
The DNA sequence of MBP (malE), encoding amino acids 1–370 of the mature peptide, not including the signal peptide, was amplified from the E. coli genome. A point mutation was used to remove a BsaI recognition site (Gly19, GGT->GGA; see Supplementary Table 1 for ORF sequences). The DNA sequence corresponding to amino acids 46–450 of T. litoralis TMBP (malE) C-terminally fused to the five N-terminal amino acids of mature MBP15 was codon optimized for expression in E. coli and synthesized as a gBlocks gene fragment (IDT). Numbering of TMBP amino acids follows Diez et al.15, where the fusion protein is numbered consecutively 1–410. cpGFP was created from standard EGFP44 to match the amino-acid sequence of the cpGFP used in previous maltose biosensor constructs19. Briefly, EGFP 147–238 was fused N-terminally to EGFP 1–146 with a GGTGGS linker in between. Mutations made, relative to EGFP, were H148Y, Y151F, V163A, D180Y, T203V, V93I and Y145F.
The minimal transposon Entranceposon (M1-CamR) was purchased from Thermo Fisher Scientific (catalogue # F-760). Using F-760 as template, Golden Gate cloning18 was used to remove two internal BsmBI restriction sites along with the NotI sites at the transposon ends (returning the ends to the native Mu R1R2 sequences). The F-760 template was amplified in three pieces (see Supplementary Table 1 for primers) and cloned into pET47b (Novagen) using BsaI enzyme (New England Biolabs). This new plasmid was used as template for creating all modified transposons.
Minimal transposons have ends that are exact reverse compliments (R1R2 sequences). Therefore, amplification as two halves (with at least 3% dimethylsulfoxide in PCR reactions) and reassembly into a destination vector was necessary to create modified transposons and to provide a way to create asymmetric modifications. Splitting the CmR resistance gene between the two cloning inserts also allowed for the selection of the correctly assembled transposon. Internal primers, annealing within CmR, were combined with R1R2 (ref. 45) primers that introduced modifications (see Supplementary Fig. 1b for modifications and Supplementary Table 1 for primers). The two modified transposon halves were cloned into a pUC19 backbone with BsaI or BsmBI (New England Biolabs) to form a transposon-propagation plasmid. R1R2 primers included restriction sites (BglII and HindIII, Thermo Fisher Scientific) that were used to excise the transposons from transposon-propagation plasmids. This created ‘pre-cut’ transposon DNA that, once gel purified from the plasmid backbone, was used in minimal in vitro transposition reactions16. The transposon used for creating domain-insertion libraries, an asymmetric version of BsaI-1 that includes mutations to the cut sites (Supplementary Fig. 1b,c), was cloned in the same way and named Mu-BsaI. Its transposition efficiency was equivalent to the parent construct, BsaI-1. Primers were designed to amplify cpGFP for Golden Gate cloning into the BsaI sites of Mu-BsaI (Supplementary Table 1).
Transposition efficiency of modified transposons was tested in 10 μl reactions with the following: 2 μl 5 × MuA reaction buffer; 100 ng modified transposon (purified from transposon-propagation plasmid); 100 ng pUC19 plasmid; and 0.5 μl 0.22 μg μl−1 MuA transposase enzyme (Thermo Fisher Scientific). Reactions were carried out for 18 h at 30 °C followed by 20 min at 75 °C to heat inactivate MuA transposase. The entire reaction was added to 100 μl XL1-Blue chemically competent cells and transformed by standard heat-shock procedures. Dilutions of the recovered transformation cells were spotted onto lysogeny broth (LB) agar plates with 15 μg ml−1 chloramphenicol and 25 μg ml−1 carbenicillin. Efficiency was calculated by comparing colony count of modified transposons with the count from unmodified R1R2 transposon.
The ORF of the target gene was cloned into the staging plasmid using BsaI (New England Biolabs). The same 4-basepair cut sites used to clone into the staging plasmid are also flanked on the opposite side by BsmBI recognitions sites, permitting excision of the ORF-transposon library after transposition.
Transposition reactions were a total volume of 20 μl with the following components: 4 μl 5 × MuA reaction buffer; 100 ng Mu-BsaI (purified from transposon-propagation plasmid); staging plasmid DNA (∼0.5 molar ratio to transposon DNA); and 1 μl 0.22 μg μl−1 MuA transposase enzyme (Thermo Fisher Scientific). Reactions were incubated for 18 h at 30 °C followed by 10 min at 75 °C to heat inactivate MuA transposase. Completed reactions were cleaned up with a DNA Clean & Concentrator-5 Kit (Zymo Research Corp.), eluting with 6 μl of water. A volume of 2 μl was transformed into 25 μl of electrocompetent 10G E. coli cells (Lucigen Corp.) according to the manufacturer’s instructions. An aliquot of the recovery culture was spread on an LB agar plate with appropriate antibiotics to assess reaction efficiency. Each transformation produced ∼105 constructs with successful insertions, which covers the number of possible insertion positions in the plasmid (∼6,000) over 15-fold. Cells were then pelleted and resuspended in 50 ml LB with 25 μg ml−1 chloramphenicol and 50 μg ml−1 carbenicillin to select for transposon insertions and the staging-plasmid backbone, respectively. The culture was grown overnight at 37 °C, 250 r.p.m., and the staging library DNA was collected with a HiSpeed Plasmid Midi Kit (Qiagen).
To isolate ORF DNA that contained a transposon insert, the staging library DNA was treated with BsmBI (New England Biolabs) and size selected on a Tris acetate EDTA (TAE) 1% agarose gel. The band corresponding to the size of the target gene ORF plus a single transposon insertion was gel extracted and the DNA recovered using a Zymoclean Gel DNA Recovery Kit (Zymo Research Corp.). The recovered DNA was then cloned into an expression plasmid (pTKEI-Dest—Supplementary Fig. 15—for MBP and pTKE-Dest for TMBP) using BsmBI enzyme. Briefly, 40 fmoles of extracted ORF-transposon was mixed with 40 fmoles expression plasmid, 10 units BsmBI (NEB), 800 units T4 DNA Ligase (NEB) and 1 × T4 DNA Ligase Reaction Buffer (NEB) in a total volume of 20 μl. The reaction was incubated 2 min at 45 °C, 5 min at 16 °C (first two steps cycled 50 times), 20 min at 60 °C and 20 min at 80 °C. Reactions were purified using a DNA Clean & Concentrator-5 Kit and eluted with 6 μl water. A volume of 2 μl was transformed into 25 μl of electrocompetent 10G E. coli cells. An aliquot of the recovery culture was spread on an LB agar plate containing 5-bromo-4-chloro-3-indoyl-β-D-galactopyranoside/isopropyl β-D-1-thiogalactopyranoside (X-gal/IPTG) to assess reaction efficiency. Plasmids still containing a lacZ drop-out cassette made up <0.1% of the population for every sample. Cells were then pelleted and resuspended in 6 ml LB with 1% glucose and 25 μg ml−1 chloramphenicol. The culture was grown overnight at 37 °C, 250 r.p.m., and the transposon-insertion library DNA was collected with a QIAprep Spin Miniprep Kit (Qiagen).
Golden Gate cloning was used to exchange the modified transposon cassette with the PCR-amplified cpGFP to create the final domain-insertion library. Briefly, 40 fmoles of each DNA component was mixed with 10 units BsaI (NEB), 800 units T4 DNA Ligase (NEB) and 1 × T4 DNA Ligase Reaction Buffer (NEB) in a total volume of 20 μl. The reaction was incubated 2 min at 37 °C, 5 min at 16 °C (first two steps cycled 50 times), 20 min at 60 °C and 20 min at 80 °C. Reactions were purified using a DNA Clean & Concentrator-5 Kit and eluted with 6 μl water. A volume of 5 μl was transformed into 50 μl of electrocompetent Tuner cells (for TMBP libraries, also containing MiniF lacIq isolated from NEB Express Iq cells). An aliquot of the recovery culture was spread on an LB agar plate containing 25 μg ml−1 chloramphenicol to assess reaction efficiency. Cells were then pelleted and resuspended in 6 ml LB supplemented with 1% glucose and 60 μg ml−1 kanamycin. The culture was grown overnight at 37 °C, 250 r.p.m., and used the next day to inoculate samples for FACS. A glycerol freezer stock was also made, and the remaining culture used to extract the library DNA (for use in NGS) with a QIAprep Spin Miniprep Kit (Qiagen).
Two MBP-cpGFP libraries were created with independent transposition and cloning steps. Three TMBP-cpGFP libraries were created with independent transposition and cloning steps. Each library replicate is named with a consecutive numbering system, for example, TMBP libraries 1, 2 and 3.
Fluorescence-activated cell sorting
A 100 μl aliquot of the overnight library culture was used to inoculate 5 ml of MOPS EZ Rich Defined Medium (Teknova) containing 60 μg ml−1 kanamycin and 0.4% glycerol as a carbon source instead of glucose. The culture was grown at 37 °C, 250 r.p.m. until the OD600 was ∼0.6 and then protein expression induced with IPTG (0.5 mM, Teknova). After 4 h, an aliquot from each library was moved to a new tube where ligand was added to a final concentration of 1 mM, either trehalose (Sigma-Aldrich) or maltose (Fisher Chemical). All samples were incubated at 37 °C, 250 r.p.m. for a further 30 min before FACS. Just before FACS, the samples were diluted 1:100 in phosphate-buffered saline (PBS) or 1:100 in PBS with 1 mM ligand and kept on ice. FACS was performed using a Sony SH800 cell sorter (Sony Biotechnology) equipped with a 488-nm excitation laser and an FL1 (525/50 nm) emission filter. In all, 25,000 events of each sample were recorded for analysis. Expressed ligand-binding protein (MBP or TMBP) was used as a negative control to establish a lower boundary of the gate used for sorting fluorescent events. The same instrument and procedure was used to make single-cell measurements of biosensors with and without ligand.
Cells were sorted into 5 ml LB medium supplemented with 1% glucose. Immediately after sorting, samples were incubated at 37 °C, 250 r.p.m. for 1 h. Following this, the volume was adjusted to 15 ml with LB media and 1% glucose. A volume of 100 μl of a 1:50 dilution of the cells in the same media was plated on to LB agar plates supplemented with either 60 μg ml−1 kanamycin or (for MiniF plasmid containing cells) both 30 μg ml−1 kanamycin and 12.5 μg ml−1 chloramphenicol. The remaining, recovered cell cultures were supplemented with 60 μg ml−1 kanamycin and incubated at 30 °C, 250 r.p.m. overnight. If samples were to be sorted again, overnight cultures were used to inoculate new FACS samples, repeating the steps above. A glycerol freezer stock was made from the overnight growth and the remaining culture used to extract library DNA (for use in NGS) with a QIAprep Spin Miniprep Kit (Qiagen).
For the two MBP-cpGFP libraries, each naive pool was treated and sorted with 1 mM maltose. An initial filtering sort was used on ‘yield’ sorting mode of the instrument and sorted cells were collected in a fresh tube with no medium. This gate was set at the low-fluorescence threshold, collecting above ∼550 arbitrary fluorescence units (AFU). The collected cells were put through the sorter a second time on ‘purity’ sorting mode. The gate was set just above the low-fluorescence threshold, collecting above ∼850 AFU. Approximately 1.5 × 105 cells were collected from each library.
Three FACS screens were carried out on TMBP domain-insertion libraries. For each of the three naive TMBP-cpGFP insertion libraries, expressed libraries were treated with 1 mM trehalose, and 106 fluorescent events above the low-fluorescence threshold (∼550 AFU) were sorted. This sort was defined as sort 1. For the second round of sorting (that is, sort 2), the recovered libraries were processed as described for the initial, naive libraries except that the libraries were not treated or sorted with trehalose. The gate used for these sorts was ∼300–1,100 AFU. In the final round of sorting (sort 3), the expressed libraries were again treated and sorted in the presence of 1 mM trehalose. The gate used was ⩾1,050 AFU.
Screening for biosensors
A 96-well plate of colonies from plated cells on LB agar was picked into 200 μl PBS. No cells, MBP/TMBP, and cpGFP controls were always included. A volume of 5 μl of cell-PBS mix was used to inoculate 200 μl of LB media containing 10% glycerol, 1% glucose and 60 μg ml−1 kanamycin. Plates were incubated at 30 °C, 750 r.p.m. overnight and the following day 5 μl of overnight culture was used to inoculate 200 μl MOPS EZ Rich Defined Medium (Teknova) containing 60 μg ml−1 kanamycin and 0.4% glycerol as a carbon source instead of glucose. The overnight starter-culture plates were frozen at −80 °C for storage. The freshly inoculated samples in a 96-well plate (Costar 3631 with an attached low evaporation lid, Costar 3370) were incubated in an Infinite M1000Pro plate reader (Tecan) at 37 °C and the OD600 and fluorescence (485/5 nm excitation and 515/5 nm emission) monitored. For OD600, 25 flashes were taken. For the fluorescence, the plate was read from the bottom, the gain manually set to 80 and 50 flashes in mode 1 (400 Hz) were taken. After a complete cycle of measuring the OD600 and fluorescence, the plates were shaken for 600 s in double orbital mode with amplitude of 1 mm (frequency 306 r.p.m.) before measurements were again taken. Approximately 2.5 h after starting the measurements, the programme was paused and IPTG added to a final concentration of 0.5 mM. The programme was restarted and allowed to continue for an additional 2 h. After 2 h, the programme was again paused and ligand (maltose or trehalose) in PBS was added to a final concentration of 1 mM or PBS alone was added. The programme was restarted and allowed to continue for at least a further 1.5 h. The data from the plate reader were subsequently analysed using MATLAB (Mathworks). To normalize the data for differences in cell growth, the fluorescence at each time point was divided by the OD600 at the same time point. The normalized fluorescence values for the time point immediately before ligand addition was used as the pre-ligand fluorescence. For the post-ligand fluorescence, the normalized fluorescence from time points 2–6 immediately after ligand addition were averaged and used. The ΔF/F (ΔF/F=(Fligand–F0)/F0) was calculated and normalized to the control protein. The insertion site of a construct was determined by isolation of the plasmid DNA and sequencing (Quintara Biosciences).
For each sorted MBP-cpGFP library, two 96-well plates were tested for biosensor activity. One plate of sorted samples from library 2 had every construct sequenced. The other three plates tested had constructs sequenced if they were found to have an activity measurement of ΔF/F>0.5.
For each of the three TMBP-cpGFP libraries, after sort 3, a 96-well plate of samples was tested for biosensor activity. The top five wells based on activity values (ΔF/F) were sent for sequencing. To identify the insertion sites for a complete 96-well plate of samples, an aliquot of the glycerol stock from library 1 after sort 3 was diluted 1:105 in LB media and plated on to LB agar plates supplemented with 60 μg ml−1 kanamycin. The DNA from a 96-well plate of colonies was isolated and sequenced. To match the insertion site with biosensor activity, the normalized ΔF/F was calculated from three replicates (except for Tre-217, which was in duplicate), as described above.
To evaluate linear correlations between activity and either enrichment or read count, linear least squares regression was performed using the SciPy Python package. A two-sided P value is reported where the null hypothesis is that the slope is zero. Data sets and calculated fit lines were plotted using DataGraph (Visual Data Tools).
Biosensor linker optimization
The Mal-170 construct was tested by varying linkers between MBP and cpGFP. The forward primer set cpEGFP-MBP170-F0,1,2,3,4 and reverse primer set cpEGFP-MBP170-R0,1,2,3,4 (Supplementary Table 1) amplified cpGFP adding zero to four VST codons on either end. Primers were mixed in equal ratios and used in a standard Phusion PCR reaction (New England Biolabs). A pET T7-based expression plasmid (Novagen) containing MBP was amplified with MBP-170-F and MBP-170-R. The purified PCR fragments were cloned together with a BsaI Golden Gate reaction. The completed reaction was purified and concentrated with a PCR clean-up kit, and eluted with 6 μl water. A volume of 2 μl of cleaned-up reaction was transformed into 25 μl of electrocompetent BL21 (DE3) E. coli cells. An aliquot of the recovery culture was spread on LB agar plates with 50 μg ml−1 carbenicillin and 1% w/v glucose. Colonies were picked for inoculation of two 96-well plates, which were screened for biosensor activity as described above. A range of activity was seen (Supplementary Fig. 4b); the top five constructs were sent for sequencing. This identified constructs Mal-F1 and Mal-B2. These constructs were cloned into pTKEI (Trc-promoter plasmid) for further testing (Supplementary Fig. 4c,d) because we found that biosensor expression from T7-based plasmids showed attenuated activity.
For Tre-334 optimization, the forward primer set Tre-333/334-F0,1,2,3 and reverse primer set Tre-333/334-R0,1,2,3 (Supplementary Table 1) were designed to introduce zero to three degenerate VVC codons on both the 5′- and 3′-ends of the amplified cpGFP template. Each primer was prepared at 25 μM then pooled as forward and reverse primers in the ratio 30:31:32:33 (0:1:2:3 linker codons) and used in a standard Phusion PCR with cpGFP as the template. To amplify the TMBP backbone, primers Tre-G334-F and Tre-P333-R were used in a standard Phusion PCR with TMBP in plasmid pTKE-Dest. Each of the PCR products was electrophoresed on a TAE 1% agarose gel and extracted. The purified products were used in a Golden Gate cloning reaction to construct the TMBP-cpGFP (0–3 VVC) linker library. The products of the Golden Gate reaction were purified using a Clean and Concentrator kit (Zymo) and eluted with 6 μl water.
The purified libraries were transformed with electrocompetent Tuner-MiniF lacIq cells as described for the domain-insertion TMBP-cpGFP libraries. Expression and sorting of the library was also carried out as detailed for the domain-insertion libraries except that only a single round of sorting in the presence of 1 mM trehalose was performed. The gate used for sorting was a high-fluorescence gate (⩾3,750 AFU).
To determine the range in ΔF/F for the linker library, three 96-well plates of colonies were screened as described for the domain-insertion libraries. Sequencing of the biosensors with the highest ΔF/F values identified biosensor Tre-C04, which was used for further characterization.
Biosensors Tre-334 and Tre-C04 along with the controls TMBP and cpGFP were cloned into the expression plasmid pTKEI-Dest (Supplementary Fig. 15) for all further characterization. Unlike pTKE, pTKEI constitutively expresses the lacI gene to repress expression of target proteins prior to induction. All expression with these plasmids was carried out in Tuner cells (Novagen).
Tre-C04 switching during exponential growth
Colonies of Tuner cells (Novagen) harbouring Tre-C04 in pTKEI were grown overnight in LB media supplemented with 1% glucose and 60 μg ml−1 kanamycin. The following day, 5 μl of the overnight culture was used to inoculate 200 μl MOPS EZ Rich Defined Medium (Teknova) containing 60 μg ml−1 kanamycin and 0.4% glycerol as a carbon source instead of glucose. Samples were grown and monitored as previously described for the in vivo screening of the trehalose biosensors except that 2 h after IPTG induction, the 96-well plate was removed and 5 μl of the culture used to inoculate 200 μl of fresh MOPS EZ Rich Defined Medium (Teknova) containing 60 μg ml−1 kanamycin, 0.4% glycerol as carbon source and 0.5 mM IPTG. Approximately 3–3.5 h after back-dilution and return to the plate reader, the programme was paused and either water or trehalose at final concentration of 1, 10, 100, or 1000 μM was added. Cultures were again returned to the plate reader and monitored for ∼1 h before another aliquot of water or trehalose was added. The difference in fluorescence between cultures in which trehalose was added versus water was calculated and plotted using DataGraph (Visual Data Tools). The experiment was replicated 12 times.
Tre-C04 response to validamycin A
To monitor the response of Tre-C04 to validamycin A treatment, Tuner cells (Novagen) harbouring Tre-C04 in pTKEI were treated as described above for Tre-C04 switching during exponential growth except that the first addition of trehalose or trehalose supplemented with validamycin A (50 μM final concentration, Research Products International Corp.) was ∼1.75 h after back-dilution and the second addition was 1.5 h after the first. For samples with zero trehalose, water was added.
Monitoring in vivo trehalose levels during stationary phase
To monitor the in vivo accumulation of trehalose in E. coli, Tuner cells expressing Tre-C04 were grown and monitored as described for the in vivo switching experiment except that instead of trehalose addition, water, PBS or 300 mM NaCl was added. For NaCl, either one or two aliquots was added. For cultures in which only a single addition was made, water was added at the second addition point. The mean and s.d. for the changes in OD600 and normalized fluorescence for four samples was determined.
Extraction and measurement of free sugars
The in vivo accumulation procedure was replicated using 50 ml cultures to provide enough cell mass for sugar extraction. Cultures were grown at 37 °C, 250 r.p.m. and sampled periodically. The OD600 and fluorescence were measured with an Infinite M1000Pro plate reader using the parameters described above for the in vivo screening of trehalose biosensors. On the basis of OD600 measurements, 5 × 108 cells were removed from the 50 ml culture, pelleted at 5,000g and washed with MOPS EZ Rich Defined Medium containing no carbon source. Cells were treated with 1 ml acetonitrile:methanol:water (40:40:20 by volume). The extraction solution was spiked with 1 μg of arabinose, for use as an internal control, and incubated for 15 min at 50 °C, 1,400 r.p.m. Samples were centrifuged at 20,000g for 10 min. The supernatant was removed and stored at −80 °C until HPAEC-PAD analysis.
Before HPAEC-PAD analysis, extracts were thawed and then dried at 50 °C under nitrogen gas. Dried residue was resuspended in 1 ml water and then 500 μl chloroform added. Samples were vortexed and centrifuged at 20,000g. The aqueous phase was recovered and analysed by HPAEC-PAD. Briefly, a Dionex ICS-5000 system with a CarboPac PA20 analytical column (3 × 150 mm) and CarboPac PA20 guard column (3 × 30 mm) was used with an isocratic 50 mM NaOH eluent and 0.4 ml ml−1 flow rate. Injections were 25 μl per sample. Chromeleon 7 software (Dionex) was used for instrument control, data collection and data analysis. The retention times and calibration curves for maltose, trehalose and arabinose concentrations were determined using pure standards (Sigma-Aldrich).
In vitro biochemistry
A single colony of each of the biosensor and control proteins was transformed into Tuner cells (Novagen) and used to inoculate 10 ml of LB media supplemented with 1% glucose and 60 μg ml−1 kanamycin. Cultures were incubated overnight at 30 °C, 250 r.p.m. and then following day used to inoculate 1 l of Autoinduction media46. Cultures were incubated for 20–24 h at 22 °C, 250 r.p.m. before collecting at 4,000g using a Sorval Legend XTR centrifuge. Cell pellets were resuspended in 30 ml lysis buffer (50 mM sodium phosphate, 300 mM NaCl and 10 mM imidazole, pH7.4) and frozen at −80 °C. Phenylmethylsulfonyl fluoride and DNase I were added to the thawed cell pellets at final concentrations of 1 mM and 10 μg ml−1, respectively. Cells were lysed with an EmulsiFlex C3 (Avestin) at 20,000 psi for three passages. Lysate was centrifuged at 18,000 r.p.m. for 30 min using a JA-20 fixed angle rotor (Beckman Coulter). The clarified lysate was purified using Ni-NTA agarose (Qiagen). The purified proteins were concentrated and exchanged into PBS buffer using a 10,000 Da NMWO Vivaspin Turbo 15 Centrifugal Concentrator (Sartorius). To verify purity, aliquots of purified proteins were analysed by SDS–PAGE.
For MBP-cpGFP Mal-B2, the protein was diluted to ∼10 μM in PBS. In a standard 384-well plate, 20 μl of 2 × ligand (in PBS) was added to 20 μl of protein. No-ligand measurements were 20 μl PBS added to 20 μl of protein. Excitation/emission (485/515 nm) was measured on an Infinite M1000Pro (Tecan) plate reader after PBS (with or without ligand) addition. Samples were measured in triplicate, and the mean and the s.d. of the ΔF/F values determined. Plots were generated using Prism (GraphPad Software).
For TMBP-cpGFP biosensors, fluorescence images of the purified proteins were obtained by adding either PBS or trehalose at a final concentration of 1 mM to 1 μM protein. Samples were imaged using a ChemiDoc MP (Bio-Rad) using the epi-blue LED module.
To determine Tre-C04’s fluorescence response to sugars, 500 nM of purified protein was treated with PBS or 50 μM glucose, maltose or trehalose. Using an Infinite M1000Pro (Tecan) plate reader, samples were excited at 485/5 nm, and a fluorescence scan was taken from 500 to 550 nm (5 nm bandwidth). Samples were measured in triplicate, and the mean and the s.d. determined. Plots were generated using Prism (GraphPad).
To obtain a dose–response curve, 500 nM purified Tre-C04 biosensor was treated with 0–50 μM glucose, maltose or trehalose. To assess Tre-C04’s response to other possible ligands, the protein was incubated with 1 mM sugar substrates. Using an Infinite M1000Pro (Tecan) plate reader, samples were excited at 485/5 nm and emission measured at 515/5 nm. Samples were measured in triplicate, and the mean and the s.d. determined. Plots were generated using Prism (GraphPad Software), and the fit of log([sugar]) versus response using four parameters are displayed with the dose–response curves. Under these measurement conditions, it was found that purified Tre-C04 saturated with trehalose was 44% as bright as purified sfGFP.
NGS and analysis
Library plasmid DNA was sheared with a Covaris S220 focused-ultrasonicator using AFA microTUBEs (#520052, Covaris) to an approximate size of 250 basepairs. All DNA clean ups of NGS samples were done with Agencourt AMPure XP SPRI beads (Beckman Coulter). MiSeq-compatible fragments were prepared from sheared DNA with a NEBNext DNA Library Prep Reagent Set for Illumina (New England Biolabs) and TruSeq DNA Adaptors (#15025064, Illumina). Sheared DNA and prepared samples were analysed for size distribution on an Agilent 2100 Bioanalyzer using DNA 1000 chips (Agilent Technologies). Double-stranded DNA concentrations of the adaptor-prepared samples were measure with a dsDNA BR Assay Kit on a Qubit Fluorometer (Life Technologies). A normalized pool of samples was run on a MiSeq instrument using a MiSeq Reagent Kit v3 (150 cycles, Illumina).
NGS data was analysed with a custom Python pipeline (available at http://github.com/SavageLab/dipseq). Briefly, an initial filter was used to remove reads that did not contain sequence from both the LDB (either MBP or TMBP) and the inserted domain (cpGFP). The remaining reads were stripped of cpGFP sequence and aligned to the LBD ORF. This alignment determined the insertion site of the cpGFP into the LBD ORF for the given read. Because transposition creates duplicated DNA sequences, the DNA insertion site was defined as the last basepair of the LBD (in the direction of transcription) after which the cpGFP was detected. The cpGFP insertion was designated as forward or reverse based on if its ORF is in the same or opposite direction of the LBD, respectively. The amino-acid insertion site (for forward, in-frame insertions) is then assigned to the codon in which the DNA insertion occurred. If an insert created a forward, in-frame construct, it was categorized as productive. If an insert was out of frame or in the reverse direction, it was categorized as unproductive. The DNA insertion site designation above was used for calculating read counts whether the read detected the N- or C-terminal end of the cpGFP domain. When making enrichment calculations, though, reads identifying N- and C-terminal ends of cpGFP for the same insertion site were used as internal technical replicates. Enrichment values for each insertion site (fold change or log2 fold change) were calculated using the DESeq package and P values were adjusted for multiple testing using the Benjamini–Hochberg procedure47.
For MBP-cpGFP, library 2 was sequenced before and after FACS screening. This resulted in two technical replicates for those two samples when calculating enrichment. For TMBP-cpGFP, two of the three libraries (libraries 1 and 2) were sequenced before and after each sort. Each sample was also sequenced twice on separate MiSeq runs. This resulted in two biological replicates, with four technical replicates each, that were used to calculate enrichment over each FACS screen, and over all three FACS screens (Supplementary Fig. 7b uses enrichment calculated from technical replicates of library 2). For enrichment relative only to productive constructs, the same TMBP-cpGFP data sets were stripped of unproductive insertions and rerun with DESeq to produce new fold changes and P values.
Domain-insertion-profile sequencing data that support the findings of this study have been deposited into the NCBI Sequence Read Archive (SRA) with the accession code SRP076284. Sequencing data were analysed with a custom Python pipeline available at http://github.com/SavageLab/dipseq. Processed sequencing data are included in Supplementary Information (Supplementary Data 1 and 2). Plasmids described in this work are available from Addgene. All other data that support the findings of this study are available from the authors on request.
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We thank R. Yokoo and L. Oltrogge for productive discussions, Y. Chang for assistance with sugar analysis and K. Wetmore for assistance with DNA sequencing. The Energy Biosciences Institute (OO1J25), a NIH New Innovator Award (1DP2EB018658-01) and a Basil O’Connor Starter Scholar Research Award from the March of Dimes to D.F.S. supported this work.
The authors declare no competing financial interests.
Supplementary Figures 1-15, Supplementary Table 1 (PDF 2252 kb)
Supplementary Data 1
Read count data from MBP-cpGFP and TMBP-cpGFP libraries (XLSX 730 kb)
Supplementary Data 2
Calculated enrichment data from MBP and TMBP DIP-seq (XLSX 1382 kb)
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Nadler, D., Morgan, SA., Flamholz, A. et al. Rapid construction of metabolite biosensors using domain-insertion profiling. Nat Commun 7, 12266 (2016). https://doi.org/10.1038/ncomms12266
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