Luigi Russo

Optimized ratiometric calcium sensors for functional in vivo imaging of neurons and T lymphocytes

The quality of genetically encoded calcium indicators (GECIs) has improved dramatically in recent years, but high-performing ratiometric indicators are still rare. Here we describe a series of fluorescence resonance energy transfer (FRET)-based calcium biosensors with a reduced number of calcium binding sites per sensor. These Twitch sensors are based on the C-terminal domain of Opsanus troponin C. Their FRET responses were optimized by a large-scale functional screen in bacterial colonies, refined by a secondary screen in rat hippocampal neuron cultures. We tested the in vivo performance of the most sensitive variants in the brain and lymph nodes of mice. The sensitivity of the Twitch sensors matched that of synthetic calcium dyes and allowed visualization of tonic action potential firing in neurons and high resolution functional tracking of T lymphocytes. Given their ratiometric readout, their brightness, large dynamic range and linear response properties, Twitch sensors represent versatile tools for neuroscience and immunology.

Interdomain dynamics explored by paramagnetic NMR.

An ensemble-based approach is presented to explore the conformational space sampled by a multidomain protein showing moderate interdomain dynamics in terms of translational and rotational motions. The strategy was applied on a complex of calmodulin (CaM) with the IQ-recognition motif from the voltage-gated calcium channel Ca(v)1.2 (IQ), which adopts three different interdomain orientations in the crystal. The N60D mutant of calmodulin was used to collect pseudocontact shifts and paramagnetically induced residual dipolar couplings for six different lanthanide ions. Then, starting from the crystal structure, pools of conformations were generated by free MD. We found the three crystal conformations in solution, but four additional MD-derived conformations had to be included into the ensemble to fulfill all the paramagnetic data and cross-validate optimally against unused paramagnetic data. Alternative approaches led to similar ensembles. Our ensemble approach is a simple and efficient tool to probe and describe the interdomain dynamics and represents a general method that can be used to provide a proper ensemble description of multidomain proteins.

The structural role of the zinc ion can be dispensable in prokaryotic zinc-finger domains

The recent characterization of the prokaryotic Cys2His2 zinc-finger domain, identified in Ros protein from Agrobacterium tumefaciens, has demonstrated that, although possessing a similar zinc coordination sphere, this domain is structurally very different from its eukaryotic counterpart. A search in the databases has identified ≈300 homologues with a high sequence identity to the Ros protein, including the amino acids that form the extensive hydrophobic core in Ros. Surprisingly, the Cys2His2 zinc coordination sphere is generally poorly conserved in the Ros homologues, raising the question of whether the zinc ion is always preserved in these proteins. Here, we present a functional and structural study of a point mutant of Ros protein, Ros56–142C82D, in which the second coordinating cysteine is replaced by an aspartate, 5 previously-uncharacterized representative Ros homologues from Mesorhizobium loti, and 2 mutants of the homologues. Our results indicate that the prokaryotic zinc-finger domain, which in Ros protein tetrahedrally coordinates Zn(II) through the typical Cys2His2 coordination, in Ros homologues can either exploit a CysAspHis2 coordination sphere, previously never described in DNA binding zinc finger domains to our knowledge, or lose the metal, while still preserving the DNA-binding activity. We demonstrate that this class of prokaryotic zinc-finger domains is structurally very adaptable, and surprisingly single mutations can transform a zinc-binding domain into a nonzinc-binding domain and vice versa, without affecting the DNA-binding ability. In light of our findings an evolutionary link between the prokaryotic and eukaryotic zinc-finger domains, based on bacteria-to-eukaryota horizontal gene transfer, is discussed.

Correlating Calcium Binding, Förster Resonance Energy Transfer, and Conformational Change in the Biosensor TN-XXL

Genetically encoded calcium indicators have become instrumental in imaging signaling in complex tissues and neuronal circuits inxa0vivo. Despite their importance, structure-function relationships of these sensors often remain largely uncharacterized due to their artificial and multimodular composition. Here, we describe a combination of protein engineering and kinetic, spectroscopic, and biophysical analysis of the Förster resonance energy transfer (FRET)-based calcium biosensor TN-XXL. Using fluorescence spectroscopy of engineered tyrosines, we show that two of the four calcium binding EF-hands dominate the FRET output of TN-XXL and that local conformational changes of these hands match the kinetics of FRET change. Using small-angle x-ray scattering and NMR spectroscopy, we show that TN-XXL changes from a flexible elongated to a rigid globular shape upon binding calcium, thus resulting in FRET signal output. Furthermore, we compare calcium titrations using fluorescence lifetime spectroscopy with the ratiometric approach and investigate potential non-FRET effects that may affect the fluorophores. Thus, our data characterize the biophysics of TN-XXL in detail and may form a basis for further rational engineering of FRET-based biosensors.

Structural Zn(II) implies a switch from fully cooperative to partly downhill folding in highly homologous proteins.

In the funneled landscape, proteins fold to their native states through a stochastic process in which the free energy decreases spontaneously and unfolded, transition, native, and possible intermediate states correspond to local minima or saddle points. Atomic description of the folding pathway appears therefore to be essential for a deep comprehension of the folding mechanism. In metallo-proteins, characterization of the folding pathways becomes even more complex, and therefore, despite their fundamental role in critical biological processes, little is known about their folding and assembly. The study of the mechanisms through which a cofactor influences the protein folding/unfolding reaction has been the rationale of the present study aimed at contributing to the search for cofactors general roles in protein folding reactions. In particular, we have investigated the folding pathway of two homologous proteins, Ros87, which contains a prokaryotic zinc finger domain, and Ml452-151, lacking the zinc ion. Using a combination of CD, DSC and NMR techniques, we determined the thermodynamics and the structural features, at an atomic level, of the thermal unfolding of Ros87 and compared them to the behavior of Ml452-151. Our results, also corroborated by NMR (1)H/(2)H exchange measurements, show that the presence of the structural Zn(II) in Ros87 implies a switch from the Ml452-151 fully cooperative to a two-step unfolding process in which the intermediate converts to the native state through a downhill barrierless transition. This observation, which has never been reported for any metal ion so far, may have a significant role in the understanding of the protein misfolding associated with the presence of metal ions, as observed in neurodegenerative diseases.

Identification of binding sites of Lactobacillus plantarum enolase involved in the interaction with human plasminogen

The enolase EnoA1 of Lactobacillus plantarum is here shown to interact with human plasminogen (Plg). By sequence alignment of EnoA1 with Streptococcus pneumoniae and Bifidobacterium lactis enolases, we identified BS1 and BS2 Plg-binding sites. A structure prediction of EnoA1 showed lysine residues in position 255 (BS2), and 422 (BS1) exposed on protein surface. A lysine residue in position 259 was as well identified as surface-exposed amino acid. The enoA1 gene was site directed-mutagenized to generate four mutated proteins, carrying K255A, K259A, K422A and K259A/K422A substitutions. The functional role of these lysine residues was assessed evaluating specific Plg-binding activity of the mutated proteins. While the binding activity of the mutated proteins was drastically reduced, the residual enzymatic activity was more than 50% of EnoA1. Our results show that L. plantarum EnoA1 exhibits the Plg-BS1, and the Plg-BS2 extending up to the lysine residue in position 259, therefore consisting of 12-aa residues instead of 9-aa residues described in S. pneumoniae. A test performed on whole cells of L. plantarum, demonstrated that after inducing conversion of the cell-bound plasminogen to plasmin, this was released into the medium, unlike the mechanism reported for most pathogens, that retained plasmin bound to the cell surface.

Deciphering the zinc coordination properties of the prokaryotic zinc finger domain: The solution structure characterization of Ros87 H42A functional mutant

The zinc coordination sphere in prokaryotic zinc finger domain is extremely versatile and influences the stability and the folding property of the domain. Of a particular interest is the fourth zinc coordinating position, which is frequently occupied by two successive histidines, both able to coordinate the metal ion. To clarify their structural and functional role we report the NMR solution structure and the dynamics behavior of Ros87 H42A, which is a functional mutant of Ros87, the DNA binding domain of the Ros protein containing a prokaryotic Cys2His2 zinc finger domain. The structural analysis indicates that reducing the spacer among the two coordinating histidines from 4 (among His37 and His42) amino acids to 3 (among His37 and His41) increases the helicity of the first α-helix. At the same time, the second helix appears more mobile in the μs-ms timescale and the hydrophobic core is reduced. These data explain the high frequency of three-residue His spacers in the eukaryotic zinc finger domain and their absence in the prokaryotic counterpart. Furthermore, the structural comparison shows that the second coordination position is more sensitive to H42A mutation with respect to the first and the third position, providing the rationale of the high variability of the second and the fourth zinc coordinating position in Ros homologs, which adopt different metal coordination but preserve similar tertiary structures and DNA binding activities. Finally, H/D exchange measurements and NMR thermal unfolding analysis indicate that this mutant likely unfolds via a different mechanism with respect to the wild-type.

Cullin3 - BTB Interface: A Novel Target for Stapled Peptides

Cullin3 (Cul3), a key factor of protein ubiquitination, is able to interact with dozens of different proteins containing a BTB (Bric-a-brac, Tramtrack and Broad Complex) domain. We here targeted the Cul3–BTB interface by using the intriguing approach of stabilizing the α-helical conformation of Cul3-based peptides through the “stapling” with a hydrocarbon cross-linker. In particular, by combining theoretical and experimental techniques, we designed and characterized stapled Cul3-based peptides embedding the helix 2 of the protein (residues 49–68). Intriguingly, CD and NMR experiments demonstrate that these stapled peptides were able to adopt the helical structure that the fragment assumes in the parent protein. We also show that some of these peptides were able to bind to the BTB of the tetrameric KCTD11, a substrate adaptor involved in HDAC1 degradation, with high affinity (~ 300–600 nM). Cul3-derived staple peptides are also able to bind the BTB of the pentameric KCTD5. Interestingly, the affinity of these peptides is of the same order of magnitude of that reported for the interaction of full-length Cul3 with some BTB containing proteins. Moreover, present data indicate that stapling endows these peptides with an increased serum stability. Altogether, these findings indicate that the designed stapled peptides can efficiently mimic protein-protein interactions and are potentially able to modulate fundamental biological processes involving Cul3.

Molecular strategies to replace the structural metal site in the prokaryotic zinc finger domain

The specific arrangement of secondary elements in a local motif often totally relies on the formation of coordination bonds between metal ions and protein ligands. This is typified by the ~30 amino acid eukaryotic zinc finger motif in which a β-sheet and an α-helix are clustered around a zinc ion by various combinations of four ligands. The prokaryotic zinc finger domain (found in the Ros protein from Agrobacterium tumefaciens) is different from the eukaryotic counterpart as it consists of 58 amino acids arranged in a βββαα topology stabilized by a 15-residue hydrophobic core. Also, this domain tetrahedrally coordinates zinc and unfolds in the absence of the metal ion. The characterization of proteins belonging to the Ros homologs family has however shown that the prokaryotic zinc finger domain can overcome the metal requirement to achieve the same fold and DNA-binding activity. In the present work, two zinc-lacking Ros homologs (Ml4 and Ml5 proteins) have been thoroughly characterized using bioinformatics, biochemical and NMR techniques. We show how in these proteins a network of hydrogen bonds and hydrophobic interactions surrogate the zinc coordination role in the achievement of the same functional fold.

NMR backbone dynamics studies of human PED⁄PEA-15 outline protein functional sites

PED/PEA‐15 (phosphoprotein enriched in diabetes/phosphoprotein enriched in astrocytes) is a ubiquitously expressed protein and a key regulator of cell growth and glucose metabolism. PED/PEA‐15 mediates both homotypic and heterotypic interactions and is constituted by an N‐terminal canonical death effector domain and a C‐terminal tail. In the present study, the backbone dynamics of PED/PEA‐15 via 15N R1 and R2 and steady‐state [1H]‐15N NOE measurements is reported. The dynamic parameters were analyzed using both Lipari–Szabo model‐free formalism and a reduced spectral density mapping approach. The results obtained define a polar and charged surface of the death effector domain characterized by internal motions in the micro‐ to millisecond timescale, which is crucial for the multiple heterotypic functional protein–protein interactions in which PED/PEA‐15 is involved. The present study contributes to a better understanding of the molecular basis of the PED/PEA‐15 functional interactions and provides a more detailed surface for the design and development of PED/PEA‐15 binders.