Cystic fibrosis transmembrane conductance regulator (CFTR) functions as an ion channel in the apical plasma membrane of epithelial cells. Mutations in the gene coding for CFTR cause cystic fibrosis (CF). A major cellular dysfunction is insufficient apical plasma membrane expression of the protein. Its correction is important for developing new CF therapeutics and treatments, which requires a sensitive and precise method for quantifying apical plasma membrane CFTR. We report the first method of liquid chromatography-tandem mass spectrometry for quantifying endogenous and overexpressed CFTR in HT29 and BHK cells. For low level of endogenous CFTR from HT29, the target protein in the cell lysate was enriched by immunoprecipitation using anti-CFTR antibody MAB3484 or M3A7. For overexpressed CFTR from BHK, the cell lysate prepared by differential detergent fractionation or surface biotinylation was used directly without immunoprecipitation. Proteins in the enriched CFTR preparations or cell lysates were digested with proteases, and a surrogate marker peptide designated as CFTR01 (NSILTETLHR) was successfully quantified using the method of multiple reaction monitoring and stable isotope dilution with an (18)O-labeled reference peptide (CFTR01-(18)O(4)) as the internal standard. CFTR quantified in this work ranged from a few tens of picograms to low nanograms per million of cells.
Semiconductor nanocrystals (NCs) possess unique photoluminescent properties which can be used to design fluorescence probes for chemo/biosensing applications. Several have recently emerged that offer excellent turn-on or ratiometric fluorescence chemosensory protocols by sophisticated procedures, but it has been challenging to realize all of these advantages in a single construct. Herein, we develop an intrinsic dual-emitting Mn-doped ZnS nanocrystal-based probe that achieves this goal with turn-on and ratiometric fluorescence response for the determination of organophosphate (diethylphosphorothioate, DEP). The probe relies on the modification of dopamine dithiocarbamate on the surface of NCs and the modulation of dual emission through a photoinduced electron transfer process, which makes use of red fluorescence of Mn(2+) ions doped in the NCs as specific recognition for the target analyte and blue defect emission of the NCs as stable internal reference. In presence of DEP, the red emission of the probe is thus enhanced by switching off the electron transfer pathway, while the blue emission is almost unchanged. With the addition of different amounts DEP, the two emission intensity ratios gradually vary and display color changes from dark-blue to purple to red. Thus, this method generates turn-on and ratiometric fluorescence signals for quantitative and visual detection of the analyte. Significantly, the dual-emitting probe has been used to fabricate paper-based test strips for visual detection of DEP residues, which validate the method for its rapid, on-site, and visual identification.
Highly green emissive gold nanoclusters (Au NCs) are synthesized using glutathione as a stabilizing agent and mercaptopropionic acid as a ligand, and the intensity of fluorescence is specifically sensitive to lead ions. We then fabricated a ratiometric fluorescence nanohybrid by covalently linking the green Au NCs to the surface of silica nanoparticles embedded with red quantum dots (QDs) for on-site visual determination of lead ions. The green fluorescence can be selectively quenched by lead ions, whereas the red fluorescence is inert to lead ions as internal reference. The different response of the two emissions results in a continuous fluorescence color change from green to yellow that can be clearly observed by the naked eyes. The nanohybrid sensor exhibits high sensitivity to lead ions with a detection limit of 3.5 nM and has been demonstrated for determination of lead ions in real water samples including tap water, mineral water, groundwater, and seawater. For practical application, we dope the Au NCs in poly(vinyl alcohol) (PVA) film and fabricate fluorescence test strips to directly detect lead ions in water. The PVA-film method has a visual detection limit of 0.1 μM, showing its promising application for on-site identification of lead ions without the need for elaborate equipment.
Auxin, which has been implicated in multiple biochemical and physiological processes, elicits three classes of genes (Aux/IAAs, SAURs and GH3s) that have been characterized by their early or primary responses to the hormone. A new GH3-like gene was identified from a suppressive subtraction hybridization (SSH) library of pungent pepper (Capsicum chinense L.) cDNAs. This gene, CcGH3, possessed several auxin- and ethylene-inducible elements in the putative promoter region. Upon further investigation, CcGH3 was shown to be auxin-inducible in shoots, flower buds, sepals, petals and most notably ripening and mature pericarp and placenta. Paradoxically, this gene was expressed in fruit when auxin levels were decreasing, consistent with ethylene-inducibility. Further experiments demonstrated that CcGH3 was induced by endogenous ethylene, and that transcript accumulation was inhibited by 1-methylcyclopropene, an inhibitor of ethylene perception. When over-expressed in tomato, CcGH3 hastened ripening of ethylene-treated fruit. These results implicate CcGH3 as a factor in auxin and ethylene regulation of fruit ripening and suggest that it may be a point of intersection in the signaling by these two hormones.
The M‐superfamily with the typical Cys framework (–CC–C–C–CC–) is one of the seven major superfamilies of conotoxins found in the venom of cone snails. Based on the number of residues in the last Cys loop (between C4 and C5), M‐superfamily conotoxins can be provisionally categorized into four branches (M‐1, M‐2, M‐3, M‐4) [Corpuz GP, Jacobsen RB, Jimenez EC, Watkins M, Walker C, Colledge C, Garrett JE, McDougal O, Li W, Gray WR, et al. (2005) Biochemistry44, 8176–8186]. Here we report the purification of seven M‐superfamily conotoxins from Conus marmoreus (five are novel and two are known as mr3a and mr3b) and one known M‐1 toxin tx3a from Conus textile. In addition, six novel cDNA sequences of M‐superfamily conotoxins have been identified from C. marmoreus, Conus leopardus and Conus quercinus. Most of the above novel conotoxins belong to M‐1 and M‐2 and only one to M‐3. The disulfide analyses of two M‐1 conotoxins, mr3e and tx3a, revealed that they possess a new disulfide bond arrangement (C1–C5, C2–C4, C3–C6) which is different from those of the M‐4 branch (C1–C4, C2–C5, C3–C6) and M‐2 branch (C1–C6, C2–C4, C3–C5). This newly characterized disulfide connectivity was confirmed by comparing the HPLC profiles of native mr3e and its two regioselectively folded isoforms. This is the first report of three different patterns of disulfide connectivity in conotoxins with the same cysteine framework.
Cone snails, a group of gastropod animals that inhabit tropical seas, are capable of producing a mixture of peptide neurotoxins, namely conotoxins, for defense and predation. Conotoxins are mainly disulfide‐rich short peptides that act on different ion channels, neurotransmitter receptors, or transporters in the nervous system. They exhibit highly diverse compositions, structures, and biological functions. In this work, a novel Cys‐free 15‐residue conopeptide from Conus marmoreus was purified and designated as conomarphin. Conomarphin is unique because of its d‐configuration Phe at the third residue from the C‐terminus, which was identified using HPLC by comparing native conomarphin fragments and the corresponding synthetic peptides cleaved by different proteases. Surprisingly, the cDNA‐encoded precursor of conomarphin was found to share the conserved signal peptide with other M‐superfamily conotoxins, clearly indicating that conomarphin should belong to the M‐superfamily, although conomarphin shares no homology with other six‐Cys‐containing M‐superfamily conotoxins. Furthermore, NMR spectroscopy experiments established that conomarphin adopts a well‐defined structure in solution, with a tight loop in the middle of the peptide and a short 310‐helix at the C‐terminus. By contrast, no loop in l‐Phe13‐conomarphin was found, which suggests that d‐Phe13 is essential for the structure of conomarphin. In conclusion, conomarphin may represent a new conotoxin family, whose biological activity remains to be identified.
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