Microscopy-based fluorescence resonance energy transfer (FRET) experiments measure donor and acceptor intensities by isolating these signals with a series of optical elements. Because this filtering discards portions of the spectrum, the observed FRET efficiency is dependent on the set of filters in use. Similarly, observed FRET efficiency is also affected by differences in fluorophore quantum yield. Recovering the absolute FRET efficiency requires normalization for these effects to account for differences between the donor and acceptor fluorophores in their quantum yield and detection efficiency. Without this correction, FRET is consistent across multiple experiments only if the photophysical and instrument properties remain unchanged. Here we present what is, to our knowledge, the first systematic study of methods to recover the true FRET efficiency using DNA rulers with known fluorophore separations. We varied optical elements to purposefully alter observed FRET and examined protein samples to achieve quantum yields distinct from those in the DNA samples. Correction for calculated instrument transmission reduced FRET deviations, which can facilitate comparison of results from different instruments. Empirical normalization was more effective but required significant effort. Normalization based on single-molecule photobleaching was the most effective depending on how it is applied. Surprisingly, per-molecule gamma-normalization reduced the peak width in the DNA FRET distribution because anomalous gamma-values correspond to FRET outliers. Thus, molecule-to-molecule variation in gamma has an unrecognized effect on the FRET distribution that must be considered to extract information on sample dynamics from the distribution width.
Scaffold proteins form a framework to organize signal transduction by binding multiple partners within a signaling pathway. This shapes the output of signal responses as well as providing specificity and localization. The Membrane Associated Guanylate Kinases (MAGuKs) are scaffold proteins at cellular junctions that localize cell surface receptors and link them to downstream signaling enzymes. Scaffold proteins often contain protein-binding domains that are connected in series by disordered linkers. The tertiary structure of the folded domains is well understood, but describing the dynamic inter-domain interactions (the superteritary structure) of such multidomain proteins remains a challenge to structural biology. We used 65 distance restraints from singlemolecule fluorescence resonance energy transfer (smFRET) to describe the superteritary structure of the canonical MAGuK scaffold protein PSD-95. By combining multiple fluorescence techniques, the conformational dynamics of PSD-95 could be characterized across the biologically relevant timescales for protein domain motions. Relying only on a qualitative interpretation of FRET data, we were able to distinguish stable interdomain interactions from freely orienting domains. This revealed that the five domains in PSD-95 partitioned into two independent supramodules: PDZ1-PDZ2 and PDZ3-SH3-GuK. We used our smFRET data for hybrid structural refinement to model the PDZ3-SH3-GuK supramodule and include explicit dye simulations to provide complete characterization of potential uncertainties inherent to quantitative interpretation of FRET as distance. Comparative structural analysis of synaptic MAGuK homologues showed a conservation of this supertertiary structure. Our approach represents a general solution to describing the supertertiary structure of multidomain proteins.intrinsic disorder | protein structure | single molecule fluorescence | fluorescence lifetime | fluorescence correlation spectroscopy N ature relies on scaffold proteins to provide the physical constraints necessary for efficient signal transduction. Scaffold proteins interact with multiple pathway components to hold the signal transduction machinery in close proximity. Scaffolds are often composed of modular, protein-binding domains linked together in series by intrinsically disordered linkers (1). The presence of disorder may be a defining feature for scaffolds and other proteins that interact with multiple binding partners (2).The high effective concentrations brought about by domain tethering can give rise to unexpected interactions between the protein-binding domains. In some cases, canonical protein-binding domains fold together into an inseparable structural supramodule (3). While much has been learned by studying truncated fragments, we need to put the pieces back together. Such questions are difficult to address because disorder presents a fundamental challenge to structural biology.The Membrane-Associated Guanylate Kinase (MAGuK) scaffold proteins regulate signaling at cellular junctions (4). ...
Tandem PDZ domains have been suggested to form structurally-independent supramodules. However, dissimilarity between crystallography and NMR models emphasize their malleable conformation. Studies in full length scaffold proteins are needed to examine the effect of tertiary interactions within their native context. Using single molecule fluorescence to characterize the N-terminal PDZ tandem in PSD-95, we provide the first direct evidence that PDZ tandems can be structurally-independent within a full-length scaffold protein. Molecular refinement using our data converged on a single structure with an antiparallel alignment of the ligand binding sites. Devoid of interaction partners, single molecule conditions captured PSD-95 in its unbound, ground state. Interactions between PDZ domains could not be detected while fluctuation correlation spectroscopy showed that other conformations are dynamically sampled. We conclude that ultra-weak interactions stabilize the conformation providing a “low-relief” energy landscape that allows the domain orientation to be flipped by environmental interactions.
Rab23 has been proven to play a role in membrane trafficking and protein transport in eukaryotic cells. Rab23 is also a negative regulator of the Sonic hedgehog (Shh) signaling pathway in an indirect way. The nonsense mutation and loss of protein of Rab23 has been associated with neural tube defect in mice and aberrant expression in various diseases in human such as neural system, breast, visceral, and cutaneous tumor. In addition, Rab23 may play joint roles in autophagosome formation during anti-infection process against Group A streptococcus. In this review, we give a brief review on the functions of Rab23, summarize the involvement of Rab23 in genetic research, membrane trafficking, and potential autophagy pathway, especially focus on tumor promotion, disease pathogenesis, and discuss the possible underlying mechanisms that are regulated by Rab23.
Abstract. Psoriasis is a chronic inflammatory disease of the skin for which an effective treatment strategy remains to be developed. Characteristics of psoriasis include an altered differentiation of keratinocytes and hyperplasia of the skin. The present study aimed to investigate the role served by miR-520a in psoriasis. The results demonstrated that miR-520a inhibited the proliferation of HaCaT cells. miR-520a directly regulated the mRNA and protein expression of its target gene, protein kinase B (AKT). The siRNA silencing of AKT expression in these cells was also evaluated. miRNA-520a repressed the proliferation and mitotic entry of HaCaT cells, and promoted cell apoptosis. AKT silencing suppressed the proliferation of HaCaT cells. These results suggest that miRNA-520a regulates the survival of HaCaT cells by inhibiting AKT expression. miRNA-520a and AKT may therefore be novel targets for the treatment of patients with psoriasis.
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.