Psoriasis
is an inflammatory disease of the epidermis based on
an immunological mechanism involving Langerhans cells and T lymphocytes
that produce pro-inflammatory cytokines. Genetic factors, environmental
factors, and improper nutrition are considered triggers of the disease.
Numerous studies have reported that in a high number of patients,
psoriasis is associated with obesity. Excess adipose tissue, typical
of obesity, causes a systemic inflammatory status coming from the
inflammatory active adipose tissue; therefore, weight reduction is
a strategy to fight this pro-inflammatory state. This study aimed
to evaluate how a nutritional regimen based on a ketogenic diet influenced
the clinical parameters, metabolic profile, and inflammatory state
of psoriasis patients. To this end, 30 psoriasis patients were subjected
to a ketogenic nutritional regimen and monitored for 4 weeks by evaluating
the clinical data, biochemical and clinical parameters, NMR metabolomic
profile, and IL-2, IL-1β, TNF-α, IFN-γ, and IL-4
concentrations before and after the nutritional regimen. Our data
show that a low-calorie ketogenic diet can be considered a successful
strategy and therapeutic option to gain an improvement in psoriasis-related
dysmetabolism, with significant correction of the full metabolic and
inflammatory status.
A key component to success in structure-based drug design is reliable information on protein-ligand interactions. Recent development in NMR techniques has accelerated this process by overcoming some of the limitations of X-ray crystallography and computational protein-ligand docking. In this work we present a new scoring protocol based on NMR-derived interligand INPHARMA NOEs to guide the selection of computationally generated docking modes. We demonstrate the performance in a range of scenarios, encompassing traditionally difficult cases such as docking to homology models and ligand dependent domain rearrangements. Ambiguities associated with sparse experimental information are lifted by searching a consensus solution based on simultaneously fitting multiple ligand pairs. This study provides a previously unexplored integration between molecular modeling and experimental data, in which interligand NOEs represent the key element in the rescoring algorithm. The presented protocol should be widely applicable for protein-ligand docking also in a different context from drug design and highlights the important role of NMR-based approaches to describe intermolecular ligand-receptor interactions.
Side chain-to-side chain cyclizations
represent a strategy to select
a family of bioactive conformations by reducing the entropy and enhancing
the stabilization of functional ligand-induced receptor conformations.
This structural manipulation contributes to increased target specificity,
enhanced biological potency, improved pharmacokinetic properties,
increased functional potency, and lowered metabolic susceptibility.
The CuI-catalyzed azide–alkyne 1,3-dipolar Huisgen’s
cycloaddition, the prototypic click reaction, presents a promising
opportunity to develop a new paradigm for an orthogonal bioorganic
and intramolecular side chain-to-side chain cyclization. In fact,
the proteolytic stable 1,4- or 4,1-disubstituted [1,2,3]triazolyl
moiety is isosteric with the peptide bond and can function as a surrogate
of the classical side chain-to-side chain lactam forming bridge. Herein
we report the design, synthesis, conformational analysis, and functional
biological activity of a series of i-to-i+5 1,4- and 4,1-disubstituted
[1,2,3]triazole-bridged cyclopeptides derived from MT-II, the homodetic
Asp5 to Lys10 side chain-to-side chain bridged
heptapeptide, an extensively studied agonist of melanocortin receptors.
Viral fusion glycoproteins present a membrane-proximal external region (MPER) which is usually rich in aromatic residues and exhibits a marked tendency to stably reside at the membrane interfaces, leading, through unknown mechanisms, to a destabilization of the bilayer structure. This step has been proposed to be fundamental for the fusion process between target membrane and viral envelope. In the present work, we investigate the interaction between an octapeptide (C8) deriving from the MPER domain of gp36 of feline immunodeficiency virus and POPC bilayers by combining experimental results obtained by neutron reflectivity, electron spin resonance, circular dichroism, and fluorescence spectroscopy with molecular dynamics simulations. Our data indicate that C8 binds to the lipid bilayer adsorbing onto the membrane surface without deep penetration. As a consequence of this interaction, the bilayer thickness decreases. The association of the peptide with the lipid membrane is driven by hydrogen bonds as well as hydrophobic interactions that the Trp side chains form with the lipid headgroups. Upon peptide-bilayer interaction, C8 forms transient secondary structures ranging from 3(10) helices to turn conformations, while acyl chains of the peptide-exposed POPC molecules assume a more ordered packing. At the same time, lipid headgroups' hydration increases. The asymmetric lipid bilayer perturbation is proposed to play a fundamental role in favoring the membrane fusion process.
Abeta (16-35) is the hydrophobic central core of beta-amyloid peptide, the main component of plaques found in the brain tissue of Alzheimer's disease patients. Depending on the conditions present, beta-amyloid peptides undergo a conformational transition from random coil or alpha-helical monomers, to highly toxic beta-sheet oligomers and aggregate fibrils. The behavior of beta-amyloid peptide at plasma membrane level has been extensively investigated, and membrane charge has been proved to be a key factor modulating its conformational properties. In the present work we probed the conformational behavior of Abeta (16-35) in response to negative charge modifications of the micelle surface. CD and NMR conformational analyses were performed in negatively charged pure SDS micelles and in zwitterionic DPC micelles "doped" with small amounts of SDS. To analyze the tendency of Abeta (16-35) to interact with these micellar systems, we performed EPR experiments on three spin-labeled analogues of Abeta (16-35), bearing the methyl 3-(2,2,5,5-tetramethyl-1-oxypyrrolinyl) methanethiolsulfonate spin label at the N-terminus, in the middle of the sequence and at the C-terminus, respectively. Our conformational data show that, by varying the negative charge of the membrane, Abeta (16-35) undergoes a conformational transition from a soluble helical-kink-helical structure, to a U-turn shaped conformation that resembles protofibril models.
C8, a short peptide characterized by three regularly spaced Trp residues, belongs to the membrane-proximal external functional domains of the feline immunodeficiency virus coat protein gp36. It elicits antiviral activity as a result of blocking cell entry and exhibits membranotropic and fusogenic activities. Membrane-proximal external functional domains of virus coat proteins are potential targets in the development of new anti-HIV drugs that overcome the limitations of the current anti-retroviral therapy. In the present work, we studied the conformation of C8 and its interaction with micellar surfaces using circular dichroism, nuclear magnetic resonance and fluorescence spectroscopy. The experimental data were integrated by molecular dynamics simulations in a micelle-water system. Our data provide insight into the environmental conditions related to the presence of the fusogenic peptide C8 on zwitterionic or negatively charged membranes. The membrane charge modulates the conformational features of C8. A zwitterionic membrane surface induces C8 to assume canonical secondary structures, with hydrophobic interactions between the Trp residues and the phospholipid chains of the micelles. A negatively charged membrane surface favors disordered C8 conformations and unspecific superficial interactions, resulting in membrane destabilization.
N6-isopentenyladenosine (i6A), a modified nucleoside belonging to the cytokinin family, has shown in humans many biological actions, including antitumoral effects through the modulation of the farnesyl pyrophosphate synthase (FPPS) activity. To investigate the relationship between i6A and FPPS, we undertook an inverse virtual screening computational target searching, testing i6A on a large panel of 3D protein structures involved in cancer processes. Experimentally, we performed an NMR investigation of i6A in the presence of FPPS protein. Both inverse virtual screening and saturation transfer difference (STD) NMR outcomes provided evidence of the structural interaction between i6A and FPPS, pointing to i6A as a valuable lead compound in the search of new ligands endowed with antitumoral potential and targeting FPPS protein.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.