The preferential
adsorption of SO
x
versus
water in Mg-MOF-74 from a humid SO
x
gas
stream has been investigated via materials studies and nuclear magnetic
resonance (NMR). Mg-MOF-74 has been synthesized and subsequently loaded
simultaneously with water vapor and SO
x
(62–96 ppm) in an adsorption chamber at room temperature
over a time period of 4 days with a sample taken every 24 h. Each
sample was analyzed by powder X-ray diffraction (PXRD), Fourier transform
infrared spectroscopy, thermogravimetric analysis (TGA)–mass
spectrometry, and scanning electron microscopy–energy-dispersive
spectroscopy. The metal–organic framework (MOF) showed retained
crystallinity and peak intensity in PXRD, and after 2 days, it showed
no obvious degradation to the structure. Use of multiple techniques,
including TGA, identified 10% by weight of SO
x
species, specifically H2S and SO2, within
the MOF. 1H solid-state NMR shows a substantial reduction
of H2O when SO
x
is present,
which is consistent with SO
x
preferentially
binding to the oxophilic metal site of the framework. After 14 weeks
aging, the sulfur remains present in the three-dimensional MOF, with
only half being desorbed after 23 weeks in air.
Dynamic
nuclear polarization (DNP) is used to improve the inherently
poor sensitivity of nuclear magnetic resonance spectroscopy by transferring
spin polarization from electrons to nuclei. However, DNP radicals
within the sample can have detrimental effects on nuclear spins close
to the polarizing agent. Chirped microwave pulses and electron decoupling
(eDEC) attenuate these effects in model systems, but this approach
is yet to be applied to intact cells or cellular lysates. Herein,
we demonstrate for the first time exceptionally fast 1H
T1DNP times of just 200 and 300 ms at 90 and 6 K, respectively,
using a newly synthesized methylated trityl radical within intact
human cells. We further demonstrate that eDEC can also be applied
to intact human cells and human and bacterial cell lysates. We investigate
eDEC efficiency at different temperatures, with different solvents,
and with two trityl radical derivatives. At 90 K, eDEC yields a 13C signal intensity increase of 8% in intact human cells and
10% in human and bacterial
cell lysates. At 6 K, eDEC provides larger intensity increases of
15 and 39% in intact human cells and cell lysates, respectively. Combining
the manipulation of electron spins with frequency-chirped pulses and
sample temperatures approaching absolute zero is a promising avenue
for executing rapid, high-sensitivity magic-angle spinning DNP in
complex cellular environments.
We demonstrate for the first time in-cell dynamic nuclear polarization (DNP) in conjunction with flow cytometry sorting to address the cellular heterogeneity of in-cell samples. Utilizing a green fluorescent protein (GFP) reporter of HIV reactivation, we correlate increased 15N resonance intensity with cytokine-driven HIV reactivation in a human cell line model of HIV latency. As few as 10% GFP+ cells could be detected by DNP nuclear magnetic resonance (NMR). The inclusion of flow cytometric sorting of GFP+ cells prior to analysis by DNP-NMR further boosted signal detection through increased cellular homogeneity with respect to GFP expression. As few as 3.6 million 15N-labeled GFP+ cells could be readily detected with DNP-NMR. Importantly, cell sorting allowed for the comparison of cytokine-treated GFP+ and GFP− cells in a batch-consistent way. This provides an avenue for normalizing NMR spectral contributions from background cellular processes following treatment with cellular modulators. We also demonstrate the remarkable stability of AMUPol (a nitroxide biradical) in Jurkat T cells and achieved in-cell enhancements of 46 with 10 mM AMUPol, providing an excellent model system for further in-cell DNP-NMR studies. This represents an important contribution to improving in-cell methods for the study of endogenously expressed proteins by DNP-NMR.
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