Sílvia Bronsoms

Complementary positional proteomics for screening substrates of endo- and exoproteases

We describe a positional proteomics approach to simultaneously analyze N- and C-terminal peptides and used it to screen for human protein substrates of granzyme B and carboxypeptidase A4 in human cell lysates. This approach allowed comprehensive proteome studies, and we report the identification of 965 database-annotated protein C termini, 334 neo–C termini resulting from granzyme B processing and 16 neo–C termini resulting from carboxypeptidase A4 processing.

Role of Kinetic Intermediates in the Folding of Leech Carboxypeptidase Inhibitor

The oxidative folding and reductive unfolding pathways of leech carboxypeptidase inhibitor (LCI; four disulfides) have been characterized in this work by structural and kinetic analysis of the acid-trapped folding intermediates. The oxidative folding of reduced and denatured LCI proceeds rapidly through a sequential flow of 1-, 2-, 3-, and 4-disulfide (scrambled) species to reach the native form. Folding intermediates of LCI comprise two predominant 3-disulfide species (designated as III-A and III-B) and a heterogeneous population of scrambled isomers that consecutively accumulate along the folding reaction. Our study reveals that forms III-A and III-B exclusively contain native disulfide bonds and correspond to stable and partially structured species that interconvert, reaching an equilibrium prior to the formation of the scrambled isomers. Given that these intermediates act as kinetic traps during the oxidative folding, their accumulation is prevented when they are destabilized, thus leading to a significant acceleration of the folding kinetics. III-A and III-B forms appear to have both native disulfides bonds and free thiols similarly protected from the solvent; major structural rearrangements through the formation of scrambled isomers are required to render native LCI. The reductive unfolding pathway of LCI undergoes an apparent all-or-none mechanism, although low amounts of intermediates III-A and III-B can be detected, suggesting differences in protection against reduction among the disulfide bonds. The characterization of III-A and III-B forms shows that the former intermediate structurally and functionally resembles native LCI, whereas the III-B form bears more resemblance to scrambled isomers.

Designing out disulfide bonds of leech carboxypeptidase inhibitor: implications for its folding, stability and function

Leech carboxypeptidase inhibitor (LCI) is a 67-residue, tight-binding metallocarboxypeptidase inhibitor composed of a compact domain with a five-stranded beta-sheet and a short alpha-helix that are strongly stabilized by four disulfide bonds. In this study, we investigated the contribution of each particular disulfide to the folding, stability and function of LCI by constructing a series of single and multiple mutants lacking one to four disulfide bonds. The results allow a better understanding of how individual disulfide bonds shape and restrict the conformational space that LCI must explore before attaining its native conformation. The work also dissected the role played by intramolecular rearrangements of disulfides during LCI folding, providing a new kinetic scheme in which the 2S ensemble suffers a non-specific oxidation into the 3S ensemble. These 3-disulfide-bonded species reshuffle to preferentially form III-A and III-B, two major native-like folding intermediates that need structural rearrangements through the formation of scrambled isomers to finally render native LCI. The designed multiple mutants of LCI are unable to fold correctly, displaying a highly unstructured conformation and a very low inhibitory capability, which indicates the importance of disulfide bonds in LCI for both correct folding and achievement of a functional structure. In contrast, the elimination of a single disulfide bond in LCI only results in a significant reduction of conformational stability, but the mutations have a rather moderate impact on carboxypeptidase inhibition, allowing the possibility to target the intrinsic stability and specific activity of LCI independently. In this way, the findings reported provide a basis for the design of novel variants of the molecule with improved therapeutic properties.

Characterizing the tick carboxypeptidase inhibitor : Molecular basis for its two-domain nature

Tick carboxypeptidase inhibitor (TCI) is a small, disulfide-rich protein that selectively inhibits metallocarboxypeptidases and strongly accelerates the fibrinolysis of blood clots. TCI consists of two domains that are structurally very similar, each containing three disulfide bonds arranged in an almost identical fashion. The oxidative folding and reductive unfolding pathways of TCI and its separated domains have been characterized by kinetic and structural analysis of the acid-trapped folding intermediates. TCI folding proceeds through a sequential formation of 1-, 2-, 3-, 4-, 5-, and 6-disulfide species to reach the native form. Folding intermediates of TCI comprise two predominant 3-disulfide species (named IIIa and IIIb) and a major 6-disulfide scrambled isomer (Xa) that consecutively accumulate along the reaction and are strongly prevented by the presence of protein disulfide isomerase. This study demonstrates that IIIa and IIIb are 3-disulfide species containing the native disulfide pairings of the N- and C-terminal domains of TCI, respectively, and explains why the two domains of TCI fold sequentially and independently. Also, we show that the reductive unfolding of TCI undergoes two main independent unfolding events through the formation of IIIa and IIIb intermediates. Together, the comparison of the folding, stability, and inhibitory activity of TCI with those of the isolated domains reveals the reasons behind the two-domain nature of this protein: both domains contribute to the specificity and high affinity of its double-headed binding to carboxypeptidases. The results obtained herein provide valuable information for the design of more potent and selective TCI molecules.

Oxidative folding and structural analyses of a Kunitz-related inhibitor and its disulfide intermediates: functional implications.

Tick-derived protease inhibitor (TdPI) is a tight-binding Kunitz-related inhibitor of human tryptase β with a unique structure and disulfide-bond pattern. Here we analyzed its oxidative folding and reductive unfolding by chromatographic and disulfide analyses of acid-trapped intermediates. TdPI folds through a stepwise generation of heterogeneous populations of one-disulfide, two-disulfide, and three-disulfide intermediates, with a major accumulation of the nonnative three-disulfide species IIIa. The rate-limiting step of the process is disulfide reshuffling within the three-disulfide population towards a productive intermediate that oxidizes directly into the native four-disulfide protein. TdPI unfolds through a major accumulation of the native three-disulfide species IIIb and the subsequent formation of two-disulfide and one-disulfide intermediates. NMR characterization of the acid-trapped and further isolated IIIa intermediate revealed a highly disordered conformation that is maintained by the presence of the disulfide bonds. Conversely, the NMR structure of IIIb showed a native-like conformation, with three native disulfide bonds and increased flexibility only around the two free cysteines, thus providing a molecular basis for its role as a productive intermediate. Comparison of TdPI with a shortened variant lacking the flexible prehead and posthead segments revealed that these regions do not contribute to the protein conformational stability or the inhibition of trypsin but are important for both the initial steps of the folding reaction and the inhibition of tryptase β. Taken together, the results provide insights into the mechanism of oxidative folding of Kunitz inhibitors and pave the way for the design of TdPI variants with improved properties for biomedical applications.

Structure and dynamics of the potato carboxypeptidase inhibitor by 1H and 15N NMR.

The solution structure and backbone dynamics of the recombinant potato carboxypeptidase inhibitor (PCI) have been characterized by NMR spectroscopy. The structure, determined on the basis of 497 NOE‐derived distance constraints, is much better defined than the one reported in a previous NMR study, with an average pairwise backbone root‐mean‐square deviation of 0.5 Å for the well‐defined region of the protein, residues 7–37. Many of the side‐chains show now well‐defined conformations, both in the hydrophobic core and on the surface of the protein. Overall, the solution structure of free PCI is similar to the one that it shows in the crystal of the complex with carboxypeptidase A. However, some local differences are observed in regions 15–21 and 27–29. In solution, the six N‐terminal and the two C‐terminal residues are rather flexible, as shown by 15N backbone relaxation measurements. The flexibility of the latter segment may have implications in the binding of the inhibitor by the enzyme. All the remaining residues in the protein are essentially rigid (S2 > 0.8) with the exception of two of them at the end of a short 3/10 helix. Despite the small size of the protein, a number of amide protons are protected from exchange with solvent deuterons. The slowest exchanging protons are those in a small two‐strand β‐sheet. The unfolding free energies, as calculated from the exchange rates of these protons, are around 5 kcal/mol. Other protected amide protons are located in the segment 7–12, adjacent to the β‐sheet. Although these residues are not in an extended conformation in PCI, the equivalent residues in structurally homologous proteins form a third strand of the central β‐sheet. The amide protons in the 3/10 helix are only marginally protected, indicating that they exchange by a local unfolding mechanism, which is consistent with the increase in flexibility shown by some of its residues. Backbone alignment‐based programs for folding recognition, as opposite to disulfide‐bond alignments, reveal new proteins of unrelated sequence and function with a similar structure. Proteins 2003;50:410–422.

A novel metallocarboxypeptidase-like enzyme from the marine annelid Sabellastarte magnifica--a step into the invertebrate world of proteases.

After screening 25 marine invertebrates, a novel metallocarboxypeptidase (SmCP) has been identified by activity and MS analytical approaches, and isolated from the marine annelid Sabellastarte magnifica. The enzyme, which is a minor component of the molecularly complex animal body, as shown by 2D gel electrophoresis, has been purified from crude extracts to homogeneity by affinity chromatography on potato carboxypeptidase inhibitor and by ion exchange chromatography. SmCP is a protease of 33792 Da, displaying N‐terminal and internal sequence homologies with M14 metallocarboxypeptidase‐like enzymes, as determined by MS and automated Edman degradation. The enzyme contains one atom of Zn per molecule, is activated by Ca2+ and is drastically inhibited by the metal chelator 1,10‐phenanthroline, as well as by excess Zn2+ or Cu2+, but moderately so by EDTA. SmCP is also strongly inhibited by specific inhibitors of metallocarboxypeptidases, such as benzylsuccinic acid and the protein inhibitors found in potato and leech (i.e. recombinant forms, both at nanomolar levels). The enzyme displays high peptidase efficiency towards pancreatic carboxypeptidase‐A synthetic substrates, such as those with hydrophobic residues at the C‐terminus but, remarkably, also towards the acidic ones. This property, previously described as for carboxypeptidase O‐like activity, has been shown on long peptide substrates by MS. The results obtained in the present study indicate that SmCP is a novel member of the M14 metallocarboxypeptidases family (assignable to the M14A or pancreatic‐like subfamily) with a wider specificity that has not been described previously.

Simulated gastrointestinal conditions increase adhesion ability of Lactobacillus paracasei strains isolated from kefir to Caco-2 cells and mucin

Gastrointestinal conditions along the digestive tract are the main stress to which probiotics administrated orally are exposed because they must survive these adverse conditions and arrive alive to the intestine. Adhesion to epithelium has been considered one of the key criteria for the characterization of probiotics because it extends their residence time in the intestine and as a consequence, can influence the health of the host by modifying the local microbiota or modulating the immune response. Nevertheless, there are very few reports on the adhesion properties to epithelium and mucus of microorganisms after passing through the gastrointestinal tract. In the present work, we evaluate the adhesion ability in vitro of L. paracasei strains isolated from kefir grains after acid and bile stress and we observed that they survive simulated gastrointestinal passage in different levels depending on the strain. L. paracasei CIDCA 8339, 83120 and 83123 were more resistant than L. paracasei CIDCA 83121 and 83124, with a higher susceptibility to simulated gastric conditions. Proteomic analysis of L. paracasei subjected to acid and bile stress revealed that most of the proteins that were positively regulated correspond to the glycolytic pathway enzymes, with an overall effect of stress on the activation of the energy source. Moreover, it is worth to remark that after gastrointestinal passage, L. paracasei strains have increased their ability to adhere to mucin and epithelial cells in vitro being this factor of relevance for maintenance of the strain in the gut environment to exert its probiotic action.

Profiling and identification of new proteins involved in brain ischemia using MALDI-imaging-mass-spectrometry

The identification of proteins involved in brain ischemia might allow the discovery of putative biomarkers or therapeutic targets for ischemic stroke. Our aim is to study the distribution of proteins within mouse brain after an ischemic insult using MALDI imaging-mass-spectrometry and to identify relevant proteins involved in brain damage. We occluded the middle cerebral artery of C57BL/6J mice. Brain slices were analyzed by MALDI-TOF and infarct (IC) and contralateral (CL) regions were compared using ClinProTools. The ion distribution maps of relevant m/z values were obtained by FlexImagin3.0. Protein identification was conducted through a bottom-up approach consisting on complementary sample fractionation methods. Some identifications were confirmed by immunohistochemistry and western blot. We identified 102 m/z values with different abundances between IC and CL (p<0.05), from which 21 m/z peaks were selected as more relevant. Thirteen of them were found increased in the infarct region and 4 m/z values showed AUC>90% between IC and CL. Identification analyses confirmed altered expressions of ATP5i, COX6C and UMP-CMP kinase in IC compared to CL. BIOLOGICAL SIGNIFICANCE Using MALDI-IMS we identified for the first time new proteins that might be involved in brain ischemia representing potential diagnostic biomarkers or target molecules for neurological recovery.

Lactobacillus kefiri shows inter-strain variations in the amino acid sequence of the S-layer proteins

The S-layer is a proteinaceous envelope constituted by subunits that self-assemble to form a two-dimensional lattice that covers the surface of different species of Bacteria and Archaea, and it could be involved in cell recognition of microbes among other several distinct functions. In this work, both proteomic and genomic approaches were used to gain knowledge about the sequences of the S-layer protein (SLPs) encoding genes expressed by six aggregative and sixteen non-aggregative strains of potentially probiotic Lactobacillus kefiri. Peptide mass fingerprint (PMF) analysis confirmed the identity of SLPs extracted from L. kefiri, and based on the homology with phylogenetically related species, primers located outside and inside the SLP-genes were employed to amplify genomic DNA. The O-glycosylation site SASSAS was found in all L. kefiri SLPs. Ten strains were selected for sequencing of the complete genes. The total length of the mature proteins varies from 492 to 576 amino acids, and all SLPs have a calculated pI between 9.37 and 9.60. The N-terminal region is relatively conserved and shows a high percentage of positively charged amino acids. Major differences among strains are found in the C-terminal region. Different groups could be distinguished regarding the mature SLPs and the similarities observed in the PMF spectra. Interestingly, SLPs of the aggregative strains are 100% homologous, although these strains were isolated from different kefir grains. This knowledge provides relevant data for better understanding of the mechanisms involved in SLPs functionality and could contribute to the development of products of biotechnological interest from potentially probiotic bacteria.