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Dynamic Nuclear Polarization NMR in Human Cells Using Fluorescent Polarizing Agents Brice J. Albert, Chukun Gao, Erika L. Sesti, Edward P. Saliba, Nicholas Alaniva, Faith J. Scott, Snorri Th. Sigurdsson, and Alexander B. Barnes Biochemistry, Just Accepted Manuscript • DOI: 10.1021/acs.biochem.8b00257 • Publication Date (Web): 20 Jun 2018 Downloaded from http://pubs.acs.org on June 21, 2018

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Biochemistry

Dynamic Nuclear Polarization NMR in Human Cells Using Fluorescent Polarizing Agents

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Brice J. Albert, ‡ Chukun Gao, ‡ Erika L. Sesti, ‡ Edward P. Saliba, Nicholas Alaniva, Faith J. Scott, Snorri Th. b

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Sigurdsson, Alexander B. Barnes ,* a

Department of Chemistry, Washington University in St. Louis, One Brookings Drive, Saint Louis, MO 63130,

USA b

University of Iceland, Department of Chemistry, Science Institute, Dunhaga 3, 107 Reykjavik, Iceland

‡ These authors contributed equally *Corresponding author, Alexander B. Barnes Email: [email protected] Phone: (617)642-3225 Address: One Brookings Drive Department of Chemistry Washington Univeristy in St. Louis St. Louis MO 63130 USA

KEYWORDS: Dynamic nuclear polarization; fluorescent polarizing agents; magic angle spinning; structural biology; in-cell NMR spectroscopy

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ABSTRACT: Solid-state nuclear magnetic resonance (NMR) enables atomic resolution characterization of molecular structure and dynamics within complex heterogeneous samples, but it is typically insensitive. Dynamic nuclear polarization (DNP) increases NMR signal intensity by orders of magnitude and can be performed in combination with magic angle spinning (MAS) for sensitive, high-resolution spectroscopy. Here we report MAS DNP experiments, for the first time, within intact human cells with >40-fold DNP enhancement and a sample temperature below 6 K. In addition to cryogenic MAS results below 6 K, we also show in-cell DNP enhancements of 57-fold at 90 K. In-cell DNP is demonstrated using biradicals and sterically-shielded monoradicals as polarizing agents. A novel trimodal polarizing agent is introduced for DNP, which contains a nitroxide biradical, a targeting peptide for cell penetration, and a fluorophore for subcellular localization with confocal microscopy. The fluorescent polarizing agent provides in-cell DNP enhancements of 63-fold at a concentration of 2.7 mM. These experiments pave the way for structural characterization of biomolecules in an endogenous cellular context.

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Biochemistry

INTRODUCTION:

Solid state nuclear magnetic resonance (NMR) is exquisitely suited to characterize molecular structure within endogenous environments, including in cells

1–5

. However, the concentration of target biomolecules in these

complex preparations is much lower compared to highly purified samples, challenging the sensitivity limit of NMR spectroscopy. Strategies to increase NMR sensitivity are, therefore, an important aspect of improving solid state NMR and in-cell NMR spectroscopy. In-cell NMR experiments typically involve exogenous protein expression in cells or otherwise increasing target protein concentrations beyond endogenous levels and can result in sufficient 6–9

NMR sensitivity

. However, such perturbations alter endogenous biomolecular interactions and their associated

pathways. Alternatively, increasing NMR sensitivity by multiple orders of magnitude will permit in-cell structural characterization of biomolecules at endogenous concentrations. Strategies to increase NMR sensitivity include access to high static magnetic fields 12

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10,11

, cryogenic sample

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temperatures , more sensitive detection schemes , and spin polarization transfers . Such polarization transfer mechanisms most effectively increase NMR sensitivity when the transferring spin has the highest spin 15,16

polarization. Dynamic nuclear polarization (DNP) utilizes electron spins as the originating polarization source

.

Cryogenic operation (7 T), and efficient DNP transfers can result in high NMR 17

polarization and >10,000-fold increases in NMR signals . DNP has been successful at polarizing the outer membrane and cell wall of bacteria

18–20

, but has not been demonstrated within bacteria, most likely due to the

poor bacteria-cell permeability of DNP polarizing agents. Furthermore, magic angle spinning (MAS) DNP has yet to be extended to studies of human cells. Performing DNP in situ within intact cells has many advantages, including repeating experiments quickly for NMR signal averaging and determining the subcellular localization of NMR signals. Here we demonstrate in-cell DNP NMR in intact human cells and characterize the signal enhancements obtained using biradicals, sterically-shielded monoradicals, and a novel trimodal fluorescent polarizing agent. The fluorescent DNP polarizing agent is comprised of a nitroxide biradical, a targeting peptide for cell penetration, and a fluorophore for subcellular localization with confocal microscopy.

MATERIALS AND METHODS:

40 million intact human embryonic kidney cells (HEK293F), grown in Dulbecco’s modified eagle’s medium 13

(DMEM) supplemented with [U- C] glucose, were collected from cell culture and spun down at 300*g for 2 min.

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Cells were washed with 4 mL natural abundance minimal essential media (MEM) and spun down at 800*g for 1 min. The resulting cell pellet was suspended with 100 µL of natural abundance MEM (containing 10% DMSO) 21

with DNP radical (20 mM, 2.7 mM AMUPol, 2.7 mM TotaFAM, 40 mM nitroxide monoradicals ). Of the suspended cell volume, 80 µL was aliquoted for DNP NMR, 40 µL for EPR characterization, and 2 µL for microscopy. Finally, samples were spun, at 800*g for 30 seconds, directly into NMR rotors or EPR tubes. The supernatant from samples was removed and the samples were frozen immediately in a liquid nitrogen bath. Total time taken for sample packing, defined as time from when radicals were added to cell suspension to when samples were frozen, ranged from 1 to 2 min. Sample masses packed into NMR rotors fell in a range of 32 to 35 mg, containing 15-20 million cells. Samples were stored at -80 °C (see further experimental details in Supplementary Section 4). 1

DNP experiments at B0 = 7.05 T (300.184 MHz H) were performed with a custom-built MAS NMR probe housing 3.2 mm outside diameter rotors

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and a frequency-agile gyrotron . Spectra were recorded with a rotor-

synchronized, echo-detected cross polarization (CP) MAS pulse sequence (Supplementary Figure S1). In order to destroy residual polarization, saturation trains (SAT) were implemented before a DNP polarization time (τpol) and the CPMAS sequence, resulting in an overall sequence of SAT-τpol-CPMAS. A microwave irradiation frequency of 197.674 GHz was used for cross effect polarization transfer from nitroxide radicals. See Supplemental Information for more experimental details.

RESULTS AND DISCUSSION:

In-cell NMR with biradicals and monoradicals. Magic angle spinning (MAS) NMR spectra of intact human embryonic kidney cells (HEK293F) were enhanced through DNP using both biradicals and monoradicals at sample temperatures below 6 K, and also at 90 K. We found that nitroxide biradicals and monoradicals effectively enhanced HEK293F carbon signals through DNP and 24

cross polarization. The nitroxide biradical, AMUPol (Figure 1G) , yielded an enhancement of 46 within intact human cells (Figure 1A). Note, preliminary experiments which included a washing step after incubation of the polarizing agent did not show significant DNP enhancements.

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Biochemistry

Figure 1. Characterization of nitroxide radicals in HEK293F cells. DNP CPMAS NMR spectra below 6 K using (A) 20 mM AMUPol, (B) 40 mM sterically-shielded nitroxide monoradical, and (C) 2.7 mM TotaFAM. Black spectra represent no microwave irradiation while red spectra are recorded with microwave irradiation. Asterisks (*) 13 denote spinning side bands. The C resonances in the 50-100 ppm chemical shift range are attributed to sugars (Supplementary Figure S9). Intensity of integrated EPR spectra versus time of cellular samples prepared with (D) AMUPol, (E) sterically-shielded nitroxide monoradical, and (F) TotaFAM. Polarizing agents (G) AMUPol, (H) sterically-shielded nitroxide monoradical, and (I) trimodal polarizing agent, TotaFAM. The three moieties of TotaFAM include a TOTAPOL nitroxide radical (red), 11 residues of the HIV-1 Tat protein (blue), and a 6-FAM fluorophore (green). Sterically-shielded nitroxide monoradicals (Figure 1H), which are less prone to radical reduction in cellular 21

environments , also provided a significant DNP enhancement of 31 (Figure 1B). To compare enhancements from nitroxides, concentrations were kept constant at 20 mM of biradicals and 40 mM of monoradicals. We note that the proton longitudinal relaxation time under microwave irradiation (T1_DNP) was less than 3 s for HEK293F samples prepared with nitroxide radicals (Supplementary Figure S11). This permitted fast repetition of scans and

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reduced

time

needed

for

signal

averaging.

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DNP

enhancements of 57 from intact human cells were also observed at 90 K (See Figure 2).

Electron paramagnetic resonance (EPR) spectroscopy of nitroxide biradicals at room temperature, after incubation with HEK293F cells, was performed to monitor radical reduction in the cellular environment (Figure 1 D-F). After Figure 2. DNP CPMAS NMR of HEK293F cells at 90K. 13C DNP spectra recorded at 90 K of cells washed with phosphate buffered saline (PBS) and the AMUPol nitroxide biradical (Figure 1D), while the suspended in PBS with 20 mM AMUPol. Black spectra represent no microwave irradiation while red sterically-shielded monoradical signal loss was only 2.1% spectra are recorded with microwave irradiation. 30 minutes, 30% loss in signal intensity was observed for

(Figure

1E).

Combined

with

the

successful

DNP

enhancements of >30, these results indicate radical reduction does not prevent in-cell applications of DNP. Nonetheless, our sample preparation protocol minimizes the exposure of radicals to the reducing environment of cells by quickly (