Understanding the fluorescence of complex systems such as small nanocrystals with various surface terminations in solution is still a scientific challenge. Here we show that the combination of advanced time-resolved spectroscopy and ab initio simulations, aided by surface engineering, is able to 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 2 identify the luminescence centers of such complex systems. Fluorescent water soluble silicon carbide (SiC) nanocrystals have been previously identified as complex molecular systems of silicon, carbon, oxygen and hydrogen held together by covalent bonds that made the identification of their luminescence centers unambiguous. The aqueous solutions of molecular-sized SiC nanocrystals are exceedingly promising candidates to realize bioinert non-perturbative fluorescent nanoparticles for in vivo bioimaging, thus the identification of their luminescent centers is of immediate interest. Here we present identification of two emission centers of this complex system: surface groups involving carbon -oxygen bonds and a defect consisting of silicon -oxygen bonds which becomes the dominant pathway for radiative decay after total reduction of the surface. The identification of these luminescent centers reconciles previous experimental results on the surface and pH dependent emission of SiC nanocrystals and helps design optimized fluorophores and nanosensors for in vivo bioimaging.
Transient Receptor Potential (TRP) cation channels, like the TRP Vanilloid 1 (TRPV1) and TRP Ankyrin 1 (TRPA1), are expressed on primary sensory neurons. These thermosensor channels play a role in pain processing. We have provided evidence previously that lipid raft disruption influenced the TRP channel activation, and a carboxamido-steroid compound (C1) inhibited TRPV1 activation. Therefore, our aim was to investigate whether this compound exerts its effect through lipid raft disruption and the steroid backbone (C3) or whether altered position of the carboxamido group (C2) influences the inhibitory action by measuring Ca2+ transients on isolated neurons and calcium-uptake on receptor-expressing CHO cells. Membrane cholesterol content was measured by filipin staining and membrane polarization by fluorescence spectroscopy. Both the percentage of responsive cells and the magnitude of the intracellular Ca2+ enhancement evoked by the TRPV1 agonist capsaicin were significantly inhibited after C1 and C2 incubation, but not after C3 administration. C1 was able to reduce other TRP channel activation as well. The compounds induced cholesterol depletion in CHO cells, but only C1 induced changes in membrane polarization. The inhibitory action of the compounds on TRP channel activation develops by lipid raft disruption, and the presence and the position of the carboxamido group is essential.
Retinoids,
such as all-trans-retinoic acid (ATRA),
are endogenous signaling molecules derived from vitamin A that influence
a variety of cellular processes through mediation of transcription
events in the cell nucleus. Because of these wide-ranging and powerful
biological activities, retinoids have emerged as therapeutic candidates
of enormous potential. However, their use has been limited, to date,
due to a lack of understanding of the complex and intricate signaling
pathways that they control. We have designed and synthesized a family
of synthetic retinoids that exhibit strong, intrinsic, solvatochromatic
fluorescence as multifunctional tools to interrogate these important
biological activities. We utilized the unique photophysical characteristics
of these fluorescent retinoids to develop a novel in vitro fluorometric binding assay to characterize and quantify their binding
to their cellular targets, including cellular retinoid binding protein
II (CRABPII). The dihydroquinoline retinoid, DC360, exhibited particularly
strong binding (K
d = 34.0 ± 2.5 nM),
and we further used X-ray crystallography to determine the structure
of the DC360–CRABPII complex to 1.8 Å, which showed that
DC360 occupies the known hydrophobic retinoid binding pocket. Finally,
we used confocal fluorescence microscopy to image the cellular behavior
of the compounds in cultured human epithelial cells, highlighting
a fascinating nuclear localization, and used RNA sequencing to confirm
that the compounds regulate cellular processes similar to those of
ATRA. We anticipate that the unique properties of these fluorescent
retinoids can now be used to cast new light on the vital and highly
complex retinoid signaling pathway.
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