Whilst Zn2+ ions are critical regulators of many fundamental cellular processes, methods to monitor the free concentrations of these ions dynamically within living cells are presently limited. We have developed a series of genetically-encoded Förster Resonance Energy Transfer (FRET)-based sensors that display a large ratiometric change upon Zn2+ binding, have affinities that span the pico- to nanomolar range, and can readily be targeted to subcellular organelles. These sensors reveal that the free cytosolic Zn2+ concentration of fibroblasts and pancreatic islet β-cells is tightly buffered at ~400 pM, a level at least 103-fold lower than that in secretory granules.
Copper is a transition metal that plays critical roles in many life processes. Controlling the cellular concentration and trafficking of copper offers a route to disrupt these processes. Here we report small molecules that inhibit the human copper-trafficking proteins Atox1 and CCS, and so provide a selective approach to disrupt cellular copper transport. The knockdown of Atox1 and CCS or their inhibition leads to a significantly reduced proliferation of cancer cells, but not of normal cells, as well as to attenuated tumour growth in mouse models. We show that blocking copper trafficking induces cellular oxidative stress and reduces levels of cellular ATP. The reduced level of ATP results in activation of the AMP-activated protein kinase that leads to reduced lipogenesis. Both effects contribute to the inhibition of cancer cell proliferation. Our results establish copper chaperones as new targets for future developments in anticancer therapies.
Aptamers are useful for allosteric regulation because they are nucleic acid-based structures in which ligand binding induces conformational changes that may alter the function of a connected oligonucleotide at a distant site. Through this approach, a specific input is efficiently converted into an altered output. This property makes these biomolecules ideally suited to function as sensors or switches in biochemical assays or inside living cells. The ability to select oligonucleotide-based recognition elements in vitro in combination with the availability of nucleic acids with enzymatic activity has led to the development of a wide range of engineered allosteric aptasensors and aptazymes. Here, we discuss recent progress in the screening, design and diversity of these conformational switching oligonucleotides. We cover their application in vitro and for regulating gene expression in both prokaryotes and eukaryotes.
Many recognition events important in biology are mediated via multivalent interactions between relevant oligosaccharides and multiple saccharide receptors present on lectins, viruses, toxins, and cell surfaces. Because of the important role played by protein-carbohydrate interactions in these pathogenic recognition events and in other human diseases, considerable effort has been devoted toward the development of multivalent polymeric ligands for carbohydrate-binding proteins. In this work, we report the synthesis of new polypeptide-based glycopolymers produced via a combination of protein engineering and chemical methods. These methodologies permit control over the number and the spacing of saccharides on the scaffold, as well as the conformation of the polymer backbone, and allow a more purposeful design of polymers for manipulation of multivalent binding events. Two families of galactose-bearing glycopolypeptides with random coil conformations, [(AG)(3)PEG](y) (y = 10 and 16) and {[(AG)(2)PSG](2)[(AG)(2)PEG][(AG)(2)PSG](2)}(y) (y = 6), have been synthesized. The carboxylic acid functionality of the glutamic acid residues allowed subsequent modification with amino-saccharides to yield the desired glycopolypeptides; selective placement of the glutamic acid group permitted investigation of the effects of multivalency and saccharide spacing on toxin inhibition. In addition, a family of galactose-functionalized PGA-based glycopolymers of varying molecular weights was also synthesized to compare the effects of backbone flexibility and hydrodynamic volume, relative to the recombinant glycopolypeptides, on toxin inhibition. Glycopolypeptides were characterized via (1)H NMR, MALDI-TOF mass spectrometry, SDS-PAGE analysis, and spectrophotometric assays. They were tested as inhibitors of the binding of the cholera toxin B subunit via direct enzyme-linked assays. The data from these experiments confirm the relevance of appropriate saccharide spacing on controlling the binding event and also indicate the influence of chain extension in improving inhibition.
Real-time imaging of molecular events in living cells is important for understanding the basis of physiological processes and diseases. [1][2][3] Genetically encoded sensors that use fluorescence resonance energy transfer (FRET) [4] between two fluorescent proteins are attractive in this respect because they do not require cell-invasive procedures, can be targeted to different locations in the cell, and are easily adapted through mutagenesis and directed evolution approaches. [5][6][7] Following the pioneering work of Roger Tsien and others, on genetically encoded protease and calcium sensors, FRET-based imaging probes have been developed for many other small molecules and cell signaling events. [8][9][10][11][12][13] In these probes, conformational changes in a sensor domain are translated into a change in energy-transfer efficiency between donor and acceptor fluorescent domains, which is detected by a change in the ratio of donor and acceptor emission. This ratiometric response is independent of the sensor concentration, which is an important advantage of FRET-based sensors. In practice, however, most FRET-based sensors display only a relatively small difference in emission ratio upon activation. Improvement of these ratiometric changes has been recognized as an important prerequisite for use of these sensor systems in high-throughput applications based on fluorescence plate readers and fluorescence assisted cell sorting (FACS). [14,15] Recently a pair of CFP (cyan fluorescent protein) and YFP (yellow fluorescent protein) variants, CyPet and YPet, respectively, have been reported that were optimized for FRET through a process of directed evolution.[16] When incorporated in a protease sensor, a 20-fold change in emission ratio was observed upon cleavage of a flexible peptide that linked CyPet and YPet, compared to only a fourfold change for the same construct with enhanced CFP (ECFP) and enhanced YFP (EYFP) domains. However, the mechanism behind their remarkable FRET properties has remained unclear. A total of eighteen mutations were introduced in the course of their development, many of which were at the exterior of the protein, at a large distance from the fluorophore. Moreover, no large differences in quantum yield or extinction coefficient were reported; this suggests that the photophysical properties of the fluorescent proteins were not significantly altered. We therefore hypothesized that the increase in FRET observed for CyPet and YPet could be due to an enhanced tendency to interact when connected by a peptide linker. The parent green fluorescent protein (GFP) has a known tendency to dimerize, [17] and analysis of the mutations in YPet have identified two residues, S208F and V224L, that are present at the dimer interface, as shown by the X-ray structure of the GFP dimer. Here, we show that A C H T U N G T R E N N U N G introduction of just these two mutations in both fluorescent domains of ECFP-linker-EYFP constructs results in a fourfold increase in the EYFP-to-ECFP emission ratio, which yields a 16-fol...
A most able label: Labeled aptamers can be cross-linked to their target structures in a light-dependent and highly specific manner as a result of a new strategy termed aptamer-based affinity labeling (ABAL) of proteins. The aptamer-protein complexes can be enriched in vitro, from a cellular lysate and from the surface of living cells, opening new ways to study aptamer interactions in biological contexts.
SummaryZinc plays a central role in all living cells as a cofactor for enzymes and as a structural element enabling the adequate folding of proteins. In eukaryotic cells, metals are highly compartmentalized and chelated. Although essential to characterize the mechanisms of Zn 2+ homeostasis, the measurement of free metal concentrations in living cells has proved challenging and the dynamics are difficult to determine.Our ] in response to external supply suggests the involvement of high-and low-affinity uptake systems as well as release from internal stores.In this study, we demonstrate that the combination of genetically encoded FRET sensors and microfluidics provides an attractive tool to monitor the dynamics of cellular metal ion concentrations over a wide concentration range in root cells.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.