Multiple sclerosis (MS) is a complex disease that seems to depend on several pathophysiological processes. Because of its varied clinical presentation, natural history, and response to therapeutic interventions, MS can be considered to be a group of diseases that have not been yet characterized, thus resulting in difficult evaluation of prognosis. In the last few years, the role of autoAbs in MS has been reevaluated, and, therefore, their identification as specific biomarkers became a relevant target. In this paper, we demonstrate that an aberrant N-glucosylation is a fundamental determinant of autoAb recognition in MS. Thus, we developed CSF114(Glc), an antigenic probe accurately measuring IgM autoAbs in the sera of a patient population, as disease biomarker. The relevance of CSF114(Glc) is demonstrated by its clinical application and correlation with disease activity and prognosis. In fact, CSF114(Glc), a structure-based designed glycopeptide, is able to recognize, by ELISA, the presence of specific IgM autoAbs in the sera of a MS patient population but not in blood donors and other autoimmune conditions. AutoAbs specific for CSF114(Glc) isolated from MS patients recognized myelin and oligodendrocyte antigens by immunohistochemistry but not other nonrelevant tissues. We demonstrate that CSF114(Glc) is a reliable, specific probe in a longitudinal study of untreated MS patients. Development of IgG͞IgM anti-CSF114(Glc) Abs paralleled clinical activity and brain lesions positive to MRI. Therefore, a CSF114(Glc)-based immunoassay on sera may have important prognostic value in monitoring MS disease progression guiding optimal therapeutic treatment.aberrant glycosylation ͉ prognostic probe ͉ synthetic antigen ͉ -hairpin
In the complex scenario of cancer, treatment with compounds targeting multiple cell pathways has been emerging. In Glioblastoma Multiforme (GBM), p53 and Translocator Protein (TSPO), both acting as apoptosis inducers, represent two attractive intracellular targets. On this basis, novel indolylglyoxylyldipeptides, rationally designed to activate TSPO and p53, were synthesized and biologically characterized. The new compounds were able to bind TSPO and to reactivate p53 functionality, through the dissociation from its physiological inhibitor, murine double minute 2 (MDM2). In GBM cells, the new molecules caused Δψm dissipation and inhibition of cell viability. These effects resulted significantly higher with respect to those elicited by the single target reference standards applied alone, and coherent with the synergism resulting from the simultaneous activation of TSPO and p53. Taken together, these results suggest that TSPO/MDM2 dual-target ligands could represent a new attractive multi-modal opportunity for anti-cancer strategy in GBM.
In this work, the naturally occurring antimicrobial peptides temporin A (TA) and L (TL) are studied by spectroscopic (CD and NMR) techniques and molecular dynamics simulation. We analyzed the interactions of TA and TL with sodium dodecyl sulfate (SDS) and dodecylphosphocholine (DPC) micelles, which mimic bacterial and mammalian membranes, respectively. In SDS, the peptides prefer a location at the micelle-water interface; in DPC, they prefer a location perpendicular to the micelle surface, with the N-terminus imbedded in the hydrophobic core. TL shows higher propensity, with respect to TA, in forming alpha-helical structures in both membrane mimetic systems and the highest propensity to penetrate the micelles. Hence, we have proposed a different molecular mechanism underlying the antimicrobial and hemolytic activities of the two peptides. We also designed new analogues of TA and TL and found interesting differences in their efficacy against microbial species and human erythrocytes.
We describe synthesis, conformational studies, and binding to the five somatostatin receptors (sst 1-5) of a few analogues of the cyclic octapeptide octreotide (1), where the disulfide bridge was replaced by a dicarba group. These analogues were prepared by on-resin RCM of linear hepta-peptides containing two allylglycine residues; first- and second-generation Grubbs catalyst efficiencies were compared. The C=C bridge was hydrogenated via two different methods. Binding experiments showed that two analogues had good affinity and high selectivity for the sst5 receptor. Three-dimensional structures of the active analogues were determined by (1)H NMR spectroscopy. Conformation-affinity relationships confirmed the importance of D-Phe(2) orientation for sst2 affinity. Moreover, helical propensities well correlates with the peptide sst5 affinity. The presence of the bulky aromatic side chain of Tyr(Bzl)(10) favored the formation of a 3(10)-helix and enhanced the sst5 selectivity suppressing the sst2 affinity. Finally, a new pharmacophore model for the sst5 was developed.
Temporins are naturally occurring peptides with promising features, which could lead to the development of new drugs. Temporin-1Tl (TL) is the strongest antimicrobial peptide, but it is toxic on human erythrocytes and this fact makes the design of synthetic analogues with a higher therapeutic index vital.We studied the structure-activity relationships of a library of TL derivatives focusing on the correlation between the α-helix content of the peptides, the nature of their cationic residues, and their antibacterial/antiyeast/hemolytic activities. We found that the percentage of helicity of TL analogues is directly correlated to their hemolytic activity but not to their antimicrobial activity. In addition, we found that the nature of positively charged residues can affect the biological properties of TL without changing the peptide's helicity. It is noteworthy that a single amino acid substitution can prevent the antimicrobial activity of TL, making it a lytic peptide presumably due to its self-association. Last, we identified a novel analogue with properties that make it an attractive topic for future research.
Replacing Cys(5) by Pen (penicillamine, beta,beta-dimethylcysteine) in the cyclic C-terminal U-II octapeptide, U-II(4-11), we have obtained a potent urotensin II (U-II) receptor agonist. Conformational analysis of solution NMR data indicated that the putative biologically active conformation of U-II is stabilized by introduction of a Pen residue. To the best of our knowledge, this is the most potent U-II receptor agonist reported to date.
Chem., Int. Ed. 2002, 41, 2940-2944 reported a structure-function study of U-II that established its minimal active size and key structural features. They used this information, in conjunction with molecular modeling of the GPCR, to derive a three-dimensional structure of the U-II-receptor complex. From visual inspection, the receptor-bound conformation found by these authors shows the WKY pharmacophoric region to be less geometrically compact compared to our model. Since the pharmacophoric distances in our structure nicely agree with those measured in a semirigid nonpeptide agonist, we believe that the "active" U-II conformation is more consistent with our NMR-derived conformation than with the fully theoretical receptorbond conformation found by Kinney and co-workers.
Temporins constitute a family of amphipathic alpha-helical antimicrobial peptides (AMPs) and contain some of the shortest cytotoxic peptides, comprised of only 10-14 residues. We have recently investigated two members of this family, temporin A (TA) and temporin L (TL), because of their different spectra of antimicrobial activity and toxicity. Consequently, we developed new analogues with promising biological activities named Pro(3)-TL and Gln(3)-TA. In this work, we performed a detailed NMR analysis of the new analogues in SDS and DPC micelles, which mimic bacterial and mammalian membranes, respectively. NMR studies reveal that strongly hemolytic Gln(3)-TA was in a stable helical conformation along the entire sequence, while weakly hemolytic but antimicrobial Pro(3)-TL showed conformational averaging at the N-terminus. Furthermore, molecular dynamics (MD) simulations on TL and Pro(3)-TL were performed in explicit water and DPC micelles. Simulations indicated that both peptides prefer a location at the micelle-water interface; however, Phe(1) of strongly hemolytic TL was embedded more in depth into DPC, and only TL caused a significant distortion of the micelle shape. By combining NMR and computational analyses, we obtained a molecular-level resolution of the interactions between TL and its analogues with membrane mimicking micelles.
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