Michela Serresi

Green fluorescent protein based pH indicators for in vivo use: a review

Green fluorescent protein (GFP) and its variants have been used as fluorescent reporters in a variety of applications for monitoring dynamic processes in cells and organisms, including gene expression, protein localization, and intracellular dynamics. GFP fluorescence is stable, species-independent, and can be monitored noninvasively in living cells by fluorescence microscopy, flow cytometry, or macroscopic imaging techniques. Owing to the presence of a phenol group on the chromophore, most GFP variants display pH-sensitive absorption and fluorescence bands. Such behavior has been exploited to genetically engineer encodable pH indicators for studies of pH regulation within specific intracellular compartments that cannot be probed using conventional pH-sensitive dyes. These pH indicators contributed to shedding light on a number of cell functions for which intracellular pH is an important modulator. In this review we discuss the photophysical properties that make GFPs so special as pH indicators for in vivo use and we describe the probes that are utilized most by the scientific community.

Dendrimer internalization and intracellular trafficking in living cells.

The ability of dendrimers to cross cell membranes is of much interest for their application in drug and gene delivery. Recent studies demonstrate that dendrimers are capable to enter cells by endocytosis, but the intracellular pathway following their internalization remains controversial. In this study we use confocal fluorescence microscopy to elucidate the intracellular trafficking properties of PAMAM dendrimers with high spatial and temporal resolution in living HeLa cells. Macromolecules of different chemical functionality (neutral, cationic and lipidated), size (from G2 up to G6) and surface charge are investigated and their internalization properties correlated with the molecular structure. Toxicity and internalization data are discussed that allow the identification of dendrimers maximizing intracellular uptake with the minimum effect on cell viability. Time-lapse imaging and colocalization assays with fluorescent biomarkers for endocytic vesicles demonstrate that dendrimers are internalized by both clathrin-dependent endocytosis and macropinocytosis and are eventually delivered to the lysosomal compartment. Moreover we analyzed the uptake of dendrimers in additional cell lines of practical interest for therapeutic purposes. These measurements together with a direct comparison with TAT peptides demonstrate that PAMAM dendrimers possess similar properties to these widely used cell-penetrating peptides and thanks to their chemical tunability may represent a valid alternative for drug and gene delivery.

Neuronal polarity selection by topography-induced focal adhesion control

Interaction between differentiating neurons and the extracellular environment guides the establishment of cell polarity during nervous system development. Developing neurons read the physical properties of the local substrate in a contact-dependent manner and retrieve essential guidance cues. In previous works we demonstrated that PC12 cell interaction with nanogratings (alternating lines of ridges and grooves of submicron size) promotes bipolarity and alignment to the substrate topography. Here, we investigate the role of focal adhesions, cell contractility, and actin dynamics in this process. Exploiting nanoimprint lithography techniques and a cyclic olefin copolymer, we engineered biocompatible nanostructured substrates designed for high-resolution live-cell microscopy. Our results reveal that neuronal polarization and contact guidance are based on a geometrical constraint of focal adhesions resulting in an angular modulation of their maturation and persistence. We report on ROCK1/2-myosin-II pathway activity and demonstrate that ROCK-mediated contractility contributes to polarity selection during neuronal differentiation. Importantly, the selection process confined the generation of actin-supported membrane protrusions and the initiation of new neurites at the poles. Maintenance of the established polarity was independent from NGF stimulation. Altogether our results imply that focal adhesions and cell contractility stably link the topographical configuration of the extracellular environment to a corresponding neuronal polarity state.

Tuning the Transport Properties of HIV‐1 Tat Arginine‐Rich Motif in Living Cells

A large body of work is currently devoted to the rational design of new molecular carriers for the controlled delivery of cargoes (e.g. proteins or nucleic acids) to relevant subcellular domains, particularly the nucleus. In this article, we show that rational mutagenesis of the human immunodeficiency virus type 1 Tat‐derived peptide (YGRKKRRQRRR) affords variants with finely tuned intercompartmental dynamics and controllable transport mechanisms. Our findings are made possible by the demonstration that the Tat peptide possesses two competing functionalities capable of active nuclear targeting and additional binding to intracellular moieties. By altering the competition between these two functions, we show how to control cargo localization of Tat peptide chimeras. Our investigation provides a unified, coherent description of previous conflicting in vivo and in vitro results and lets the true nature of the Tat peptide emerge.

Real-time measurement of endosomal acidification by a novel genetically encoded biosensor

AbstractGenetically encoded fluorescent proteins are optimal reporters when used to monitor cellular processes as they can be targeted to any subcellular region by fusion to a protein of interest. Here, we present the pH-sensitive fluorescent protein E1GFP which is ideally suited to monitor pH changes in dynamic intracellular structures in real time with high spatio temporal resolution. E1GFP is a ratiometric pH indicator by emission with a pK close to 6.0. We describe an application of this novel pH reporter in the measurement of pH changes along the endo-lysosomal pathway. By fusing E1GFP to the HIV-Tat protein which is endowed with cell-penetrating properties, we were able to monitor multi-step endocytosis from the initial cell-surface binding through to the intracellular endocytic network in real time. This represents a framework for the application of E1GFP to the in situ detection of pH changes involved in dynamic biological phenomena. FigureThe green fluorecent protein variant, E1GFP, is a ratiometric pH-indicator by emission with a pK close to 6.0 and is therefore particularly suitable for pH detection below neutrality. Upon excitation of the neutral state of the chromophore (~400-410 nm), E1GFP emission properties are strongly dependent on the environmental pH. We describe an application of this novel pH-reporter in the measurement of pH changes along the endo-lysosomal pathway. By fusing E1GFP to the HIV-Tat protein, which is endowed with cell-penetrating properties, we were able to monitor in real-time multi-step endocytosis from the initial cell-surface binding through to the intracellular endocytic network.

Raman study of chromophore states in photochromic fluorescent proteins.

The photophysical mechanism underlying the photochromic behavior of green fluorescent protein (GFP) mutants is investigated by means of preresonant Raman spectroscopy and model calculations. The studied molecules are reversibly switchable fluorophores that can be repeatedly converted between fluorescent and nonfluorescent states by irradiation and are attracting a broad interest for a number of new applications. Experimental results on chemically synthesized isolated chromophores are analyzed within a density functional theory approach that allows us to link the detected vibrational modes to specific ground-state configurations before and after photoconversion. These data are compared to results obtained for the case of complete folded proteins including the same chromophores. Our results highlight the impact of chromophore cis-trans isomerization and protonation state in the photophysics of these proteins and provide useful guidelines for novel mutant design.

Probing Nuclear Localization Signal-Importin α Binding Equilibria in Living Cells

The regulated process of protein import into the nucleus of a eukaryotic cell is mediated by specific nuclear localization signals (NLSs) that are recognized by protein-import receptors. In this study, we present fluorescence-based methods to quantitatively address the physicochemical details of NLS recognition by the receptor protein importin α (Impα) in living cells. First, by combining fluorescence recovery after photobleaching measurements and protein-concentration calibration, we quantitatively define nuclear import saturability and afford an affinity value for NLS-Impα binding. Second, by fluorescence lifetime imaging microscopy, we directly monitor the occurrence of NLS-Impα interaction and measure its effective dissociation constant (KD) in the actual cellular environment. Our kinetic and thermodynamic analyses independently indicate that the subsaturation of Impα with the expressed NLS cargo regulates nuclear import rates in living cells, in contrast to what can be predicted on the basis of available in vitro data. Finally, our experiments also provide evidence for the regulation of nuclear import mediated by the intrasteric importin β-binding domain of Impα and yield the first estimate of its autoinhibition energy in living cells.

Quantitative Analysis of Tat Peptide Binding to Import Carriers Reveals Unconventional Nuclear Transport Properties

A detailed study of nuclear import mediated by the HIV-1 Tat peptide (47YGRKKRRQRRR57, TatRRR) is reported. Fluorescence-based measurements, calibration of protein concentrations, and binding assays are exploited to address the physicochemical mechanisms of Tat peptide recognition by the classical importin α (Impα) and importin β (Impβ) receptors both in vitro and in intact cells. We show that TatRRR is an unconventional nuclear localization sequence that binds directly to both Impα and Impβ carriers in the absence of competitors (in vitro), whereas this property is silenced in the actual cellular environment. In the latter case, Impα/β-dependent nuclear import can be successfully restored by replacing the “RRR” stretch with “GGG”. We apply a recently developed method to determine quantitatively TatGGG affinity for each receptor. Based on these results, we can rationalize previous controversial reports on the Tat peptide and provide coherent guidelines for the design of novel intracellular targeting sequences.

Fluorescent Recovery after Photobleaching (FRAP) Analysis of Nuclear Export Rates Identifies Intrinsic Features of Nucleocytoplasmic Transport

Background: A dedicated cell machinery oversees energy-dependent nucleocytoplasmic translocation of most proteins. Results: The Fluorescent Recovery after Photobleaching technique reveals high similarity between export and import fluxes, which are nonetheless uncoupled. Conclusion: Our results suggest differential gating properties at individual nuclear pore level. Significance: Our findings can help clarify the mechanism governing energy-dependent translocation through nuclear pores. A quantitative description of carrier-mediated nuclear export in live cells is presented. To this end, we fused a prototypical leucine-rich nuclear export signal (NES) to GFP as a cargo model and expressed the fluorescent chimera in live CHO-K1 cells. By modeling FRAP data, we calculate the NES affinity for the export machinery and the maximum rate of nuclear export achievable at saturation of endogenous carriers. The measured active-export time through the Nuclear Pore Complex (NPC) is 18 ms, remarkably similar to the previously determined active-import rate. Also, our results reveal that active export/import and active export/passive diffusion fluxes are uncoupled, thus complementing previous reports on active import/passive diffusion uncoupling. These findings suggest differential gating at the NPC level.

Channel-interacting PDZ protein ?CIPP? interacts with proteins involved in cytoskeletal dynamics

Neuronal CIPP (channel-interacting PDZ protein) is a multivalent PDZ protein that interacts with specific channels and receptors highly expressed in the brain. It is composed of four PDZ domains that behave as a scaffold to clusterize functionally connected proteins. In the present study, we selected a set of potential CIPP interactors that are involved directly or indirectly in mechanisms of cytoskeletal remodelling and membrane protrusion formation. For some of these, we first proved the direct binding to specific CIPP PDZ domains considered as autonomous elements, and then confirmed the interaction with the whole protein. In particular, the small G-protein effector IRSp53 (insulin receptor tyrosine kinase substrate protein p53) specifically interacts with the second PDZ domain of CIPP and, when co-transfected in cultured mammalian cells with a tagged full-length CIPP, it induces a marked reorganization of CIPP cytoplasmic localization. Large punctate structures are generated as a consequence of CIPP binding to the IRSp53 C-terminus. Analysis of the puncta nature, using various endocytic markers, revealed that they are not related to cytoplasmic vesicles, but rather represent multi-protein assemblies, where CIPP can tether other potential interactors.