Diletta Ami

Secondary structure, conformational stability and glycosylation of a recombinant Candida rugosa lipase studied by Fourier-transform infrared spectroscopy

The secondary structure of lipase 1 from Candida rugosa, a model system for large monomeric enzymes, has been studied by FTIR (Fourier-transform infrared) spectroscopy in water and 2H2O. The secondary structure content, determined by the analysis of the amide I band absorption through second derivative and curve fitting procedures, is in agreement with that estimated by X-ray data and predicts, in addition, the existence of two classes of alpha-helices. We have also investigated the enzyme stability and aggregation at high temperature by following the protein unfolding. The thermal stability determined by FTIR is in excellent agreement with the temperature dependence of the lipase activity. Furthermore, new insights on the glycosylation of the recombinant protein produced in Pichia pastoris and on its heterogeneity related to different fermentation batches were obtained by the analysis of the IR absorption in the 1200-900 cm(-1) carbohydrate region. A drastic reduction of the intensity of this band was found after enzymic deglycosylation of the protein. To confirm that the FTIR absorption in the 1200-900 cm(-1) region depends on the carbohydrate content and glycoform distribution, we performed an MS analysis of the protein sugar moieties. Glycosidic structures of the high mannose type were found, with mannoses ranging from 8 to 25 residues.

Immunological applications of single-domain llama recombinant antibodies isolated from a naïve library.

We describe the rapid isolation of single-domain recombinant antibodies in VHH format from a pre-immune llama library created in our laboratory. Such naïve library has demonstrated to be a versatile tool and enabled the isolation of several different antibodies for any of the six proteins panned in parallel. The binders specific for human fibroblast growth factor receptor 1 (FGFR1) were successively analyzed in more detail and resulted suitable for both western blot and immunofluorescence analyses. Several milligrams per liter of antibodies were purified by affinity chromatography and used for kinetic and thermodynamic characterization. Their K(D) was in the nanomolar range and they apparently bound a FGF receptor 1 domain not overlapping the region recognized by its physiological ligand FGF. Altogether, the collected data indicate that the new library can enable the recovery of binders of high affinity, specificity and functionality in the conventional immunological tests, avoiding the necessity of further maturation steps. Such results confirmed recent reports of high affinity pre-immune IgNARs and supported the choice of using large single-domain recombinant antibody naïve libraries as an alternative to the preparation of immune libraries for selecting monoclonal antibodies, at convenient cost and time conditions.

Tetracycline and its analogues protect Caenorhabditis elegans from β amyloid-induced toxicity by targeting oligomers.

The accumulation and deposition of amyloid beta (Aβ) peptide in extracellular dense plaques in the brain is a key phase in Alzheimers disease (AD). Small oligomeric forms of Aβ are responsible for the toxicity and the early cognitive impairment observed in patients before the amyloid plaque deposits appear. It is essential for the development of an efficient cure for AD to identify compounds that interfere with Aβ aggregation, counteracting the molecular mechanisms involved in conversion of the monomeric amyloid protein into oligomeric and fibrillar forms. Tetracyclines have been proposed for AD therapy, although their effects on the aggregation of Aβ protein, particularly their ability to interact in vivo with the Aβ oligomers and/or aggregates, remain to be understood. Using transgenic Caenorhabditis elegans as a simplified invertebrate model of AD, we evaluated the ability of tetracyclines to interfere with the sequence of events leading to Aβ proteotoxicity. The drugs directly interact with the Aβ assemblies in vivo and reduce Aβ oligomer deposition, protecting C. elegans from oxidative stress and the onset of the paralysis phenotype. These effects were specific, dose-related and not linked to any antibiotic activity, suggesting that the drugs might offer an effective therapeutic strategy to target soluble Aβ aggregates.

Kinetics of inclusion body formation studied in intact cells by FT-IR spectroscopy.

The aggregation of a recombinant lipase as inclusion bodies (IBs) was studied directly within intact Escherichia coli cells by FT‐IR microspectroscopy. Through this approach, it was possible to monitor in real time the different kinetics of IB formation at 37 and 27 °C, in excellent agreement with the results of the SDS–PAGE analysis. Furthermore, insights on the residual native‐like structure of the expressed protein within IB – both isolated and inside cells – were obtained by the secondary structure analysis of the Amide I band in the IB FT‐IR spectra.

The binding of NCAM to FGFR1 induces a specific cellular response mediated by receptor trafficking

Although FGF-2 causes the FGFR to be internalized and degraded, NCAM gets cells moving by stabilizing the receptor, promoting receptor recycling, and initiating a promigratory signaling cascade.

Fourier transform infrared spectroscopy analysis of the conformational quality of recombinant proteins within inclusion bodies

The solubility of recombinant proteins produced in bacterial cells is considered a key issue in biotechnology as most overexpressed polypeptides undergo aggregation in inclusion bodies, from which they have to be recovered by solubilization and refolding procedures. Physiological and molecular strategies have been implemented to revert or at least to control aggregation but they often meet only partial success and have to be optimized case by case. Recent studies have shown that proteins embedded in inclusion bodies may retain residual structure and biological function and question the former axiom that solubility and activity are necessarily coupled. This allows for a switch in the goals from obtaining soluble products to controlling the conformational quality of aggregated proteins. Central to this approach is the availability of analytical methods to monitor protein structure within inclusion bodies. We describe here the use of Fourier transform infrared spectroscopy for the structural analysis of inclusion bodies both purified from cells and in vivo. Examples are reported concerning the study of kinetics of aggregation and structure of aggregates as a function of expression levels, temperature and co‐expression of chaperones.

The osmolyte betaine promotes protein misfolding and disruption of protein aggregates

In this work the effect of betaine on the structure and aggregation of the GST‐GFP fluorescent fusion protein was studied by different complementary techniques, including electron microscopy, dynamic light scattering, circular dichroism, and FTIR spectroscopy. Although osmolytes are known to be protein stabilizers in vivo, the effect of betaine on the structure and aggregation of our model protein was found to be strictly concentration dependent. We demonstrated that, by changing betaine concentration, it was possible to tune the formation of protein soluble assemblies and insoluble aggregates, as well as to disaggregate preformed aggregates. In particular, at a critical concentration of betaine between 5 and 7.5 mM, the protein precipitated into macroscopic prefibrillar structures, rich in intermolecular β‐sheets, which were found to bind thioflavine T and to be inaccessible to protease. Instead, at higher betaine concentration (10–20 mM) the misfolded protein lost its fluorescence, but formed soluble assemblies with hydrodynamic radius of about 16 nm. These structures displayed a reduced propensity to further aggregate under thermal treatment. In addition, betaine at this high concentration was also found to disrupt large preformed aggregates, obtained under different conditions, into protein soluble assemblies. It is the first time that a disaggregation process has been described for a chemical chaperone. A mechanism for the betaine concentration‐dependent effect on protein misfolding, aggregation, and disaggregation is proposed and its possible physiological implications are discussed. Proteins 2009.

Concepts and tools to exploit the potential of bacterial inclusion bodies in protein science and biotechnology

Cells have evolved complex and overlapping mechanisms to protect their proteins from aggregation. However, several reasons can cause the failure of such defences, among them mutations, stress conditions and high rates of protein synthesis, all common consequences of heterologous protein production. As a result, in the bacterial cytoplasm several recombinant proteins aggregate as insoluble inclusion bodies. The recent discovery that aggregated proteins can retain native‐like conformation and biological activity has opened the way for a dramatic change in the means by which intracellular aggregation is approached and exploited. This paper summarizes recent studies towards the direct use of inclusion bodies in biotechnology and for the detection of bottlenecks in the folding pathways of specific proteins. We also review the major biophysical methods available for revealing fine structural details of aggregated proteins and which information can be obtained through these techniques.

Effects of recombinant protein misfolding and aggregation on bacterial membranes

The expression of recombinant proteins is known to induce a metabolic rearrangement in the host cell. We used aggregation-sensitive model systems to study the effects elicited in Escherichia coli cells by the aggregation of recombinant glutathione-S-transferase and its fusion with the green fluorescent protein that, according to the expression conditions, accumulate intracellularly as soluble protein, or soluble and insoluble aggregates. We show that the folding state of the recombinant protein and the complexity of the intracellular aggregates critically affect the cell response. Specifically, protein misfolding and aggregation induce changes in specific host proteins involved in lipid metabolism and oxidative stress, a reduction in the membrane permeability, as well as a rearrangement of its lipid composition. The temporal evolution of the host cell response and that of the aggregation process pointed out that the misfolded protein and soluble aggregates are responsible for the membrane modifications and the changes in the host protein levels. Interestingly, native recombinant protein and large insoluble aggregates do not seem to activate stress markers and membrane rearrangements.

Fourier transform infrared microspectroscopy as a new tool for nematode studies

We report the results of a microspectroscopy study on the Fourier transform infrared (FT‐IR) absorption spectra of Caenorhabditis elegans, collected from the different parts of a single intact specimen – pharynx, intestine and tail regions. The principal absorption bands were assigned to the molecular species present in C. elegans, with an excellent reproducibility for the pharynx spectrum. These results enabled us to explore if FT‐IR microspectroscopy could offer a new tool for nematode identification. As an example, the discrimination among four well characterised nematode taxa is reported. The FT‐IR results completely match those obtained by Blaxter and colleagues through molecular biology [Nature 392 (1998) 71].