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. 2014 Sep 25;6(1):209–213. doi: 10.1039/c4sc02882a

Regulating signal enhancement with coordination-coupled deprotonation of a hydrazone switch

Justin T Foy a, Debdas Ray b, Ivan Aprahamian c,
PMCID: PMC5433045  PMID: 28553470

graphic file with name c4sc02882a-ga.jpgRegulating signal amplification using a switchable catalytic cycle.

Abstract

Proton relay plays an important role in many biocatalytic pathways. In order to mimic such processes in the context of molecular switches, we developed coordination-coupled deprotonation (CCD) driven signaling and signal enhancement sequences. This was accomplished by using the zinc(ii)-initiated CCD of a hydrazone switch to instigate an acid catalyzed imine bond hydrolysis that separates a quencher from a fluorophore thus leading to emission amplification. Because CCD is a reversible process, we were able to show that the catalysis can be regulated and turned “on” and “off” using a metalation/demetalation cycle.

Introduction

Signal transduction in biological systems relies on receptors that respond to specific inputs in the environment, and then use catalytic reactions to amplify the signal into useful information.1 This complex signaling network is regulated by reversible feedback mechanisms that switch their activity “on” and “off” to maintain homeostasis.2 Recently, there has been interest in designing multicomponent systems3 that use signaling cascades, whereupon one molecule acts as the input to another, as a method towards mimicking the complexity4 of biological processes. Such research is expected to shed light on the origins of life,5 and lead to molecular computing,6 and systems chemistry,7 among other developments. Molecular switches and machines8 have been pursued in this context as enzyme mimics that are capable of controlling through their reversible, stimuli-dependent (mainly light) processes, the active sites of catalysts.9 In doing so, these systems mimic the regulatory activity demonstrated by enzymes.

We have recently developed hydrazone-based rotary switches10 that undergo configurational switching (i.e., E/Z isomerization) through a bio-inspired, zinc(ii)-initiated coordination-coupled deprotonation (CCD) process.10d We have also demonstrated that CCD can be used in activating two different switches through a sequence of proton relays.10f We reasoned that the CCD induced reversible acid formation could be used to drive a catalytic hydrolysis reaction, similar to what is observed in many biological signaling pathways (e.g. GTPases and phospholipases),1 to yield signal enhancement (Scheme 1).11,12 Herein, we demonstrate how the proton released in CCD can be used in mimicking such processes through the acid catalyzed hydrolysis of anthracen-9-yl-N-(4-nitrophenyl)methanimine13 (ANI). Furthermore, we show that the imine hydrolysis (i.e., catalysis) can be toggled “on” and “off” through metalation/demetalation cycles.

Scheme 1. The imidazolyl containing switch 1(E) undergoes CCD upon addition of zinc(ii) resulting in the release of a proton to the environment. The acidification of the solution can be used to turn “on” pH-sensitive dyes (S → P), which lead to fluorescence output. The coupling of this process to a catalytic cycle leads to signal amplification. This process is reversible as the molecular switch 1(Zn-E) can be deactivated through demetalation.

Scheme 1

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Results and discussion

The 1H NMR spectrum of 1(E) (ref. 14) (Fig. 1b) shows the presence of two deshielded resonances at δ = 15.22 and 11.39 ppm, originating from the intramolecularly H-bonded hydrazone and imidazolyl protons, respectively. The crystal structure of 1(E) (Fig. 2a)15 also shows the existence of the intramolecular H-bond between the hydrazone NH proton and quinolinyl (N3) and imidazolyl nitrogens (N5) (H1(N1)···N3, 2.35(1) Å, 102.5(1)°, and H1(N1)···N5, 1.93(1) Å, 135.8(1)°, respectively). The ester carbonyl oxygen also forms an intramolecular hydrogen bond with the imidazolyl NH proton (H4(N4)···O2, 2.21(1) Å, 117.9(1)°). This additional intramolecular H-bond changes the outcome of zinc(ii)-initiated CCD in 1(E): instead of an instantaneous EZ isomerization upon coordination to zinc(ii)10d,f the intramolecular H-bond locks the system in its E configuration to form 1(Zn-E). This process was monitored and characterized using 1H NMR spectroscopy (Fig. S5 in ESI), which shows the disappearance of the hydrazone NH proton, and an up-field shift of the imidazolyl NH signal (δ = 11.93 ppm) upon coordination with zinc(ii). Analysis of the crystal structure of 1(Zn-E) (Fig. 2b)16 reveals a shorter intramolecular H-bond between the imidazolyl NH proton and ester oxygen (H5(N5)···O1, 2.03(1) Å, 123.9(1)°). The binding of zinc(ii) with 1(E) was also studied using UV/Vis spectroscopy (Fig. S25–S27 in ESI). A Job's plot analysis showed a 1 : 1 binding stoichiometry between 1(E) and zinc(ii), with a binding constant of K a = 1.6 × 104 M–1.

Fig. 1. (a) The compounds involved in the CCD initiated signaling event that turns “on” the emission of MBD. The 1H NMR spectra (500 MHz, CD3CN) of (b) 1(E) and MBD (1 : 1 mixture); (c) 1(Zn-E) and MBD-H+ obtained after the addition of 1 equiv. of zinc(ii); (d) dissolved crystals of 1(Zn-E); and (e) MBD-H+ obtained after addition of TFA (8 equiv.) to MBD.

Fig. 1

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Fig. 2. ORTEP drawings (50% probability ellipsoids) of (a) 1(E) and (b) 1(Zn-E). The protons are placed in calculated positions, except for those of the hydrazone N(1) atom, the imidazolyl nitrogen atoms N(4)/N(5), and the water molecule, which were refined. The counter ion of 1(Zn-E) is not shown for clarity.

Fig. 2

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During the titration of 1(E) with zinc(ii) (Fig. S8 in ESI) we observed that CCD was accompanied by the protonation of non-coordinated 1(E). In order to put the released proton to better use (and simplify the characterization process), the CCD initiated process was coupled with a newly developed pH-responsive fluorophore17 (morpholinyl-containing BODIPY (MBD)), which resulted in the turn “on” of its fluorescence emission (Fig. 1a).18 1H NMR spectroscopy analysis showed that the addition of 1 equiv. of zinc(ii) to a 1 : 1 mixture of 1(E) and MBD (Fig. 1b) yields 1(Zn-E) and the protonated MBD compound (MBD-H+) (Fig. 1c). The formation of the former was confirmed by comparing the spectrum obtained via CCD to the one obtained by the dissolution of crystals used in the X-ray crystallographic analysis of 1(Zn-E) (Fig. 1d). The formation of MBD-H+, on the other hand, was confirmed by protonating MBD separately with TFA (Fig. 1e). As can be seen in Fig. 1c protonation causes a downfield shift of the phenyl signals of MBD; from δ = 7.17 (H11) and 7.05 (H10) ppm in the neutral form, to δ = 7.63 (H11) and 7.78 (H10) ppm in the protonated one. No such shifts are observed when zinc(ii) is added to MBD (Fig. S32 in ESI) confirming that protonation results from CCD.

This intermolecular proton relay was also probed using fluorescence spectroscopy (Fig. 3). Initially, the fluorescence is quenched most likely because of twisted intramolecular charge transfer.17 Upon titration of zinc(ii) into a 1 : 1 mixture of MBD and 1(E), a steady ratiometric increase in fluorescence intensity (λ = 522 nm) was observed as a result of the protonation of MBD. The effect reached saturation when 1 equiv. of zinc(ii) was added to the solution (Fig. 3, inset), resulting in a 1000-fold increase in emission intensity.19 A limit of detection (LOD) of 3.9 μM was determined using this CCD initiated signaling mechanism (Fig. S28 in ESI).20

Fig. 3. Fluorescence spectra (5 × 10–5 M, CH3CN) of a 1 : 1 mixture of 1(E) and MBD as a function of zinc(ii) equivalents. The inset shows the 1000-fold increase in emission intensity.

Fig. 3

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pH-Responsive fluorophores17 have been extensively used in sensing and molecular logic applications, and hence, the above mentioned results are not unexpected.6 However, in most cases the signaling event in such processes relies on one input leading to one output, which is not suitable for designing multicomponent signaling networks.3 In order to expand the scope of our system (i.e., using a single input in generating multiple outputs) and show its ability to reversibly control a catalytic process we explored the potential of coupling the CCD initiated signaling event with an amplification mechanism. We hypothesized that the acid catalyzed hydrolysis of an imine bond could be used to detach a quencher group from a fluorophore. For this purpose, we chose the weakly fluorescent dye ANI, which we speculated will undergo catalytic hydrolysis that will detach the p-nitrophenyl quencher21 and yield the more fluorescent anthraldehyde emitter (Fig. 4a).

Fig. 4. (a) The on/off hydrolysis of ANI using reversible CCD of a catalytic amount of 1(E); the 1H NMR spectra (500 MHz, CD3CN) showing the imine and NH region of (b) ANI and 1(E); (c) hydrolysis of ANI and formation of anthraldehyde after the addition of Zn(ClO4)2; (d) hydrolysis turn “off” and restoration of 1(E) by addition of excess CN; (e) mixture 10 min after the addition of CN, demonstrating that catalysis is deactivated; and (f) the complete hydrolysis of ANI after the re-introduction of zinc(ii).

Fig. 4

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This catalytic process was studied using 1H NMR spectroscopy (Fig. S22 in ESI) with 10 mol% of 1(E). Upon adding 10 mol% of zinc(ii) a catalytic amount of acid is produced through CCD that results in complete hydrolysis of ANI within 20 minutes. The maximum turnover number under these conditions is 10, which means that at best each proton is now leading to 10 outputs! This signal enhancement process was also followed using fluorometry (Fig. 5). Upon the addition of 10 mol% of zinc(ii) to a 1 : 1 mixture of 1(E) and ANI a steady increase in fluorescence was observed (λ = 522 nm), which reached saturation after 180 minutes.22

Fig. 5. The fluorescence spectra (5 × 10–5 M, CH3CN) obtained through the CCD mediated catalytic hydrolysis of ANI.

Fig. 5

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Next we took advantage of the reversible nature of CCD (Fig. S17 in ESI) to regulate the catalysis and toggle it between the “on” and “off” states. To follow this process we focused on the diagnostic imine and aldehyde proton signals of ANI and the anthraldehyde product, respectively (Fig. 4a). The initial mixture (Fig. 4b) shows the characteristic imine signal of ANI at δ = 9.77 ppm, and the hydrazone and imidazole NH proton signals of 1(E) (catalytic amount)23 at δ = 15.25 and 11.38 ppm, respectively. The addition of Zn(ClO4)2 to the mixture affords 1(Zn-E), with its characteristic imidazolyl resonance at δ = 11.93 ppm (Fig. 4c). The concomitant release of acid results in the hydrolysis of the imine bond and production of anthraldehyde, which results in a signal at δ = 11.50 ppm that grows over time.24 The catalysis was turned “off” with the addition of excess CN (5 equiv.), which effectively demetalates 1(Zn-E) and restores 1(E), thus stopping the catalytic cycle (Fig. 4d).25 This mixture was monitored for an additional 10 minutes to ensure that the 1H NMR spectrum does not change during the “off” state (Fig. 4e). The hydrolysis can then be turned back “on” with the reintroduction of excess Zn(ClO4)2 (7 equiv.), which results in the complete hydrolysis of ANI within a few minutes.

Conclusions

We have demonstrated how coordination-coupled deprotonation can be used in signaling and catalysis driven signal amplification. These processes are possible because CCD in 1(E) leads to the acidification of the solution, which when coupled with pH sensitive fluorophores leads to fluorescence turn “on”. This was demonstrated with the activation of a new BODIPY dye (MBD) that led to a 1000-fold increase in emission intensity. More importantly, the reversible CCD process was used in regulating signal enhancement by turning the catalytic hydrolysis of ANI “on” and “off” using a metalation/demetalation cycle. We plan to continue with the development of multicomponent switchable systems, and further complicate the processes they can accomplish by using switches that can be activated by orthogonal inputs.26 We hypothesize that this methodology will lead the way towards chemical systems7 with biological level complexity.

Acknowledgments

We would like to acknowledge the support of the National Science Foundation CAREER program (CHE-1253385), and the Donors of the American Chemical Society Petroleum Research Fund (51842-DNI4). We gratefully acknowledge Prof. Richard Staples (Michigan State University) for X-ray data.

Footnotes

†Electronic supplementary information (ESI) available. CCDC 862857 and 990962. For ESI and crystallographic data in CIF or other electronic format see DOI: 10.1039/c4sc02882a
Click here for additional data file. (2.8MB, pdf)
Click here for additional data file. (39.8KB, cif)

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