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Nonlinear correlations between metamorphosis-associated bioamplification and the octanol-water partition coefficients of SCCPs and MCCPs were observed for insects, whereas negative linear correlations were observed for amphibians, which suggested species-specific alterations to the chemicals during metamorphosis.There is a critical need to find safe therapeutics to treat an increasingly obese population and diseases associated with an imbalance in energy homeostasis. The melanocortin-3 receptor (MC3R) and melanocortin-4 receptor (MC4R) ligands have long been the focus to help scientists understand energy homeostasis and the regulation of feeding behavior. Herein, we use a nanomolar macrocyclic melanocortin receptor agonist ligand MDE6-5-2c (c[Pro-His-DPhe-Arg-Trp-Dap-Ala-DPro) to examine metabolic and energy hemostasis profiles upon intrathecal (IT) administration directly into the spinal cord as compared to intracerebroventricular (ICV) administration directly into the brain. Overall, central ICV administration of MDE6-5-2c resulted in decreased food intake, in a dose-dependent manner, and decreased respiratory exchange ratio (RER). SR-2156 Comparison of IT versus ICV routes of MDE6-5-2c administration resulted in MDE6-5-2c possessing a longer duration of action on both feeding behavior and RER via IT. The C-peptide, ghrelin, GIP, leptin, IL-6, and resistin plasma hormones and biomarkers were compared using IT versus ICV MDE6-5-2c routes of administration. Plasma resistin levels were decreased upon ICV treatment of MDE6-5-2c, as compared to ICV vehicle control treatment. Intrathecal treatment resulted in significantly decreased inflammatory cytokine interleukin-6 (IL-6) levels compared to ICV administration. Investigation of the nonselective MC3R and MC4R macrocyclic agonist MDE6-5-2c molecule revealed differences in food intake, RER, and plasma biomarker profiles based upon ICV or IT routes of administration and characterize this novel molecular chemotype as a molecular probe to study the melanocortin system in vivo.Chitosan is a biodegradable, antibacterial, and nontoxic biopolymer used in a wide range of applications including biotechnology, pharmacy, and medicine. The physicochemical and biological properties of chitosan have been associated with parameters such as the degree of polymerization (DP) and the fraction of acetylation (FA). New methods are being developed to yield chitosans of specific acetylation patterns, and, recently, a correlation between biological activity and the distribution of the acetylated units (PA pattern of acetylation) has been demonstrated. Although there are numerous well-established methods for the determination of DP and FA values, this is not the case for PA. The methods available are either not straightforward or not sensitive enough, limiting their use for routine analysis. In this study, we demonstrate that by applying HOmodecoupled Band-Selective (HOBS) decoupling NMR on signals assigned by multidimensional Pure Shift NMR methods, PA can be easily and accurately determined on various chitosan samples. This novel methodology-easily implemented for routine analysis-could become a standard for chitosan PA assessment. In addition, by applying Spectral Aliased Pure Shift HSQC, the analysis was enhanced with the determination of triads.Increasing charge state of protein complexes from native solutions while preserving noncovalent interactions in native mass spectrometry (MS) offers great opportunity to gain deeper insights into gas-phase protein structures. Several previous studies have disclosed the possibility of high pressure in supercharging small proteins, whereas its capability to supercharge large protein assemblies under native conditions and how it might affect protein structures remain open questions. Herein, we demonstrated that the high-pressure-induced supercharging strategy affords unique advantages of supercharging protein complexes with the highest charge state surpassing the Rayleigh limit (ZR) and concurrently preserving native-like topology. By examining 32 proteins and protein complexes with molecular weights (MWs) ranging from 8.58 to 801 kDa, we demonstrated that the increased average charge states of macromolecular ions have a strong dependence on the surface areas of native protein conformations and MWs. Factors that might contribute to the high-pressure-induced supercharging capability toward macromolecular ions were discussed. Furthermore, using collision cross section (CCS) variation as a function of charge state, we investigate the effects of gas pressure and charge states on gas-phase structures of proteins and protein complexes. Smaller proteins have the largest CCS variations once supercharged, while macromolecular protein complexes are less affected. The results revealed that both surface density of charge and charged surface basic residues contribute to the observed CCS-charge disciplines for all the macromolecules investigated. Taken together, the results presented here indicate that increasing gas pressure in the ion source affords a rapid, simple, and controlled supercharging method, offering the potency of facilitating further applications of native top-down MS analysis with improved transmission, fragmentation, and detection efficiency.HIV-1 protease (HIVPR) is an important drug target for combating AIDS. This enzyme is an aspartyl protease that is functionally active in its dimeric form. Nuclear magnetic resonance reports have convincingly shown that a pseudosymmetry exists at the HIVPR active site, where only one of the two aspartates remains protonated over the pH range of 2.5-7.0. To date, all HIVPR-targeted drug design strategies focused on maximizing the size-shape complementarity and van der Waals interactions of the small molecule drugs with the deprotonated, symmetric active site envelope of crystallized HIVPR. However, these strategies were ineffective with the emergence of drug resistant protease variants, primarily due to the steric clashes at the active site. In this study, we traced a specificity in the substrate binding motif that emerges primarily from the asymmetrical electrostatic potential present in the protease active site due to the uneven protonation. Our detailed results from atomistic molecular dynamics simulations show that while such a specific mode of substrate binding involves significant electrostatic interactions, none of the existing drugs or inhibitors could utilize this electrostatic hot spot.

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