Reducing gut microbiome-driven adipose tissue inflammation alleviates metabolic syndrome.

BACKGROUND: The gut microbiota contributes to macrophage-mediated inflammation in adipose tissue with consumption of an obesogenic diet, thus driving the development of metabolic syndrome. There is a need to identify and develop interventions that abrogate this condition. The hops-derived prenylated flavonoid xanthohumol (XN) and its semi-synthetic derivative tetrahydroxanthohumol (TXN) attenuate high-fat diet-induced obesity, hepatosteatosis, and metabolic syndrome in C57Bl/6J mice. This coincides with a decrease in pro-inflammatory gene expression in the gut and adipose tissue, together with alterations in the gut microbiota and bile acid composition. RESULTS: In this study, we integrated and interrogated multi-omics data from different organs with fecal 16S rRNA sequences and systemic metabolic phenotypic data using a Transkingdom Network Analysis. By incorporating cell type information from single-cell RNA-seq data, we discovered TXN attenuates macrophage inflammatory processes in adipose tissue. TXN treatment also reduced levels of inflammation-inducing microbes, such as Oscillibacter valericigenes, that lead to adverse metabolic phenotypes. Furthermore, in vitro validation in macrophage cell lines and in vivo mouse supplementation showed addition of O. valericigenes supernatant induced the expression of metabolic macrophage signature genes that are downregulated by TXN in vivo. CONCLUSIONS: Our findings establish an important mechanism by which TXN mitigates adverse phenotypic outcomes of diet-induced obesity and metabolic syndrome. TXN primarily reduces the abundance of pro-inflammatory gut microbes that can otherwise promote macrophage-associated inflammation in white adipose tissue. Video Abstract.

Metabotypes with elevated protein and lipid catabolism and inflammation precede clinical mastitis in prepartal transition dairy cows.

Clinical mastitis (CM), the most prevalent and costly disease in dairy cows, is diagnosed most commonly shortly after calving. Current indicators do not satisfactorily predict CM. This study aimed to develop a robust and comprehensive mass spectrometry-based metabolomic and lipidomic workflow using untargeted ultra-performance liquid chromatography high-resolution mass spectrometry for predictive biomarker detection. Using a nested case-control design, we measured weekly during the prepartal transition period differences in serum metabolites, lipids, inflammation markers, and minerals between clinically healthy Holstein dairy cows diagnosed with mastitis postcalving (CMP; n = 8; CM diagnosis d 1 = 3 cows, d 2 = 2 cows, d 4 = 1 cow; d 25 = 1 cow, and d 43 = 1 cow that had subclinical mastitis since d 3) or not (control; n = 9). The largest fold differences between CMP and control cows during the prepartal transition period were observed for 3'-sialyllactose in serum. Seven metabolites (N-methylethanolamine phosphate, choline, phosphorylcholine, free carnitine, trimethyl lysine, tyrosine, and proline) and 3 metabolite groups (carnitines, AA metabolites, and water-soluble phospholipid metabolites) could correctly classify cows for their future CM status at both 21 and 14 d before calving. Biochemical analysis using lipid and metabolite-specific commercial diagnostic kits supported our mass spectrometry-based omics results and additionally showed elevated inflammatory markers (serum amyloid A and visfatin) in CMP cows. In conclusion, metabolic phenotypes (i.e., metabotype) with elevated protein and lipid metabolism and inflammation may precede CM in prepartal transition dairy cows. The discovered serum metabolites and lipids may assist in predictive diagnostics, prevention strategies, and early treatment intervention against CM, and thereby improve cow health and welfare.

SUV39H1/H3K9me3 attenuates sulforaphane-induced apoptotic signaling in PC3 prostate cancer cells.

The isothiocyanate sulforaphane is a promising molecule for development as a therapeutic agent for patients with metastatic prostate cancer. Sulforaphane induces apoptosis in advanced prostate cancer cells, slows disease progression in vivo and is well tolerated at pharmacological doses. However, the underlying mechanism(s) responsible for cancer suppression remain to be fully elucidated. In this investigation we demonstrate that sulforaphane induces posttranslational modification of histone methyltransferase SUV39H1 in metastatic, androgen receptor-negative PC3 prostate cancer cells. Sulforaphane stimulates ubiquitination and acetylation of SUV39H1 within a C-terminal nuclear localization signal peptide motif and coincides with its dissociation from chromatin and a decrease in global trimethyl-histone H3 lysine 9 (H3K9me3) levels. Exogenous SUV39H1 expression leads to an increase in H3K9me3 and decreases sulforaphane-induced apoptotic signaling. SUV39H1 is thus identified as a novel mediator of sulforaphane cytotoxicity in PC3 cells. Our results also suggest SUV39H1 dynamics as a new therapeutic target in advanced prostate cancers.

Tricking the guard: exploiting plant defense for disease susceptibility.

Typically, pathogens deploy virulence effectors to disable defense. Plants defeat effectors with resistance proteins that guard effector targets. We found that a pathogen exploits a resistance protein by activating it to confer susceptibility in Arabidopsis. The guard mechanism of plant defense is recapitulated by interactions among victorin (an effector produced by the necrotrophic fungus Cochliobolus victoriae), TRX-h5 (a defense-associated thioredoxin), and LOV1 (an Arabidopsis susceptibility protein). In LOV1's absence, victorin inhibits TRX-h5, resulting in compromised defense but not disease by C. victoriae. In LOV1's presence, victorin binding to TRX-h5 activates LOV1 and elicits a resistance-like response that confers disease susceptibility. We propose that victorin is, or mimics, a conventional pathogen virulence effector that was defeated by LOV1 and confers virulence to C. victoriae solely because it incites defense.

Phosphotyrosine enrichment identifies focal adhesion kinase and other tyrosine kinases for targeting in canine hemangiosarcoma.

Canine hemangiosarcoma (HSA) is an endothelial cell malignancy driven, in part, by activating mutations in receptor and non-receptor tyrosine kinases. Proteomics, Western blots and a tyrosine kinase inhibitor were used to elucidate activating mechanisms in HSA cell lines. Phosphotyrosine peptides from focal adhesion kinase (FAK) STAT3, Lyn, Fyn and other signal transduction kinases were identified by mass spectrometry. FAK was constitutively activated at tyrosine 397, the autophosphorylation site, and this was reversible with high concentrations of a FAK inhibitor. FAK inhibitor-14 suppressed migration and phosphorylation of FAK tyrosine 397 and tyrosines 576/577 and was cytotoxic to HSA cells suggesting FAK signalling may be an important contributor to canine HSA survival.

Organophosphorus pesticide degradation product in vitro metabolic stability and time-course uptake and elimination in rats following oral and intravenous dosing.

Levels of urinary dialkylphosphates (DAPs) are currently used as a biomarker of human exposure to organophosphorus insecticides (OPs). It is known that OPs degrade on food commodities to DAPs at levels that approach or exceed those of the parent OP. However, little has been reported on the extent of DAP absorption, distribution, metabolism and excretion. The metabolic stability of O,O-dimethylphosphate (DMP) was assessed using pooled human and rat hepatic microsomes. Time-course samples were collected over 2 h and analyzed by LC-MS/MS. It was found that DMP was not metabolized by rat or pooled human hepatic microsomes. Male Sprague-Dawley rats were administered DMP at 20 mg kg(-1) via oral gavage and i.v. injection. Time-course plasma and urine samples were collected and analyzed by LC-MS/MS. DMP oral bioavailability was found to be 107 ± 39% and the amount of orally administered dose recovered in the urine was 30 ± 9.9% by 48 h. The in vitro metabolic stability, high bioavailability and extent of DMP urinary excretion following oral exposure in a rat model suggests that measurement of DMP as a biomarker of OP exposure may lead to overestimation of human exposure.

Osteopontin is involved in the initiation of cutaneous contact hypersensitivity by inducing Langerhans and dendritic cell migration to lymph nodes.

Osteopontin (OPN) is a chemotactic protein that attracts immune cells, to inflammatory sites. The sensitization phase of allergic cutaneous contact hypersensitivity (CHS) requires the migration of Langerhans cells/dendritic cells (LCs/DCs) from skin to draining lymph nodes. Characterizing OPN function for LC/DC migration we found upregulated OPN expression in hapten sensitized skin and draining lymph nodes. OPN induces chemotactic LC/DC migration, initiates their emigration from the epidermis, and attracts LCs/DCs to draining lymph nodes by interacting with CD44 and alphav integrin. Furthermore, OPN-deficient mice have a significantly reduced CHS response that correlates with an impaired ability of OPN-deficient mice to attract LCs/DCs to draining lymph nodes. In conclusion, OPN is an important factor in the initiation of CHS by guiding LCs/DCs from skin into lymphatic organs.

Intramolecular interactions in chemically modified Escherichia coli thioredoxin monitored by hydrogen/deuterium exchange and electrospray ionization mass spectrometry.

Site specific amide hydrogen/deuterium content of oxidized and reduced Escherichia colithioredoxin, and alkylated derivatives, Cys-32-ethylglutathionylated and Cys-32-ethylcysteinylated thioredoxins are measured, after exposure for 20 s to D(2)O/phosphate buffer (pH 5.7), by electrospray mass spectrometry. The degree of deuteration of Oxi-TRX and Red-TRX correlated with the rates of H/D exchange measured previously by NMR. The ethylcysteinyl modification was shown to minimally perturb the active site of the reduced protein, but showed more global effects on structures of alpha-helices and beta-strands distant from the site of modification. In contrast, the larger ethylglutathionyl group had little effect on the protein's overall conformation, but significantly affected the structure of loops close to the active site. A molecular model of GS-ethyl-TRX derived from molecular simulation allowed the H/D exchange results to be interpreted in terms of specific interactions between the alkyl chain and the protein surface. The specific conformation of the ethylglutathione modification was predicted to be fixed by salt bridges between the carboxylates of the gamma-Glu and Gly of glutathione and the guanidinium of Arg-73 and epsilon-amino group of Lys-90 of the protein. Specific hydrogen bonding interactions between the glutathione carbonyl oxygens and the amide protons of thioredoxin residues Ile-75 and Ala-93 were predicted. The H/D exchange studies showed low levels of deuterium incorporation at backbone nitrogens of these residues. The data also provided evidence for an unusual amide proton-amide nitrogen hydrogen bond within the ethylglutathionylated chain. These same sets of electrostatic and hydrogen bonding interactions were not predicted or observed for the smaller alkyl modification in Cys-ethyl-TRX.

Structural comparison of recombinant human macrophage colony stimulating factor beta and a partially reduced derivative using hydrogen deuterium exchange and electrospray ionization mass spectrometry.

Hydrogen deuterium exchange, monitored by electrospray ionization mass spectrometry, has been employed to characterize structural features of a derivative of recombinant human macrophage colony stimulating factor beta (rhm-CSFbeta) in which two of the nine disulfide bridges (Cys157/Cys159-Cys'157/Cys'159) were selectively reduced and alkylated. Removal of these two disulfide bridges did not affect the biological activity of the protein. Similarities between CD and fluorescence spectra for rhm-CSFbeta and its derivative indicate that removing the disulfide bonds did not strongly alter the overall three-dimensional structure of rhm-CSFbeta. However, differences between deuterium exchange data of the intact proteins indicate that more NHs underwent fast deuterium exchange in the derivative than in rhm-CSFbeta. Regions located near the disulfide bond removal site were shown to exhibit faster deuterium exchange behavior in the derivative than in rhm-CSFbeta.

Site-specific amide hydrogen/deuterium exchange in E. coli thioredoxins measured by electrospray ionization mass spectrometry.

Mass spectrometry as an analytical tool to study protein folding and structure by hydrogen/deuterium exchange is a relatively new approach. In this study, site-specific amide deuterium content was measured in oxidized and reduced E. coli thioredoxins by using the b(n) ions in electrospray ionization CID MS/MS experiments after 20-s incubation in D(2)O phosphate-buffered solution (pH 5.7). The deuterium levels correlated well with reported NMR-determined H/D exchange rate constants. The deuterium measured by y(n) ions, however, showed much less reliable correlation with rate exchange data. In general, residues in alpha helices and beta sheets, when measured by b(n) ions, showed low incorporation of deuterium while loops and turns had high deuterium levels. Most amide sites in the two protein forms showed similar deuterium levels consistent with the expected similarity of their structures, but there were some differences. The turn consisting of residues 18-22 in particular showed more variability in deuterium content consistent with reported structural differences in the two forms. The deuterium uptake by thioredoxins alkylated at Cys-32 by S-(2-chloroethyl)glutathione and S-(2-chloroethyl)cysteine, in peptides 1-24 and 45-58, was similar to that observed for oxidized and reduced thioredoxins, but several residues, particularly Leu-53 and Thr-54, showed slightly elevated deuterium levels, suggesting that structural changes had occurred from alkylation of the protein at Cys-32. It is concluded that b(n) ions are reliable for determining the extent of site-specific amide hydrogen isotope exchange and that mass spectrometry is useful as a complementary technique to NMR and other analytical methods for probing regional structural characteristics of proteins.

The effect of the source pressure on the abundance of ions of noncovalent protein assemblies in an electrospray ionization orthogonal time-of-flight instrument.

The effect of elevating the pressure in the interface region of an electrospray ionization orthogonal time-of-flight mass spectrometer on the ion intensity of different noncovalent protein assemblies has been investigated. Elevating the pressure in the interface region generally led to an enhanced detection of high m/z ions. The optimum pressure was found to be dependent on the m/z value of the ions. This pressure effect should be carefully addressed when relating ion abundance in the mass spectra to solution phase abundance of noncovalent protein assemblies.

Electrospray ionization Fourier transform ion cyclotron resonance mass spectrometric analysis of the recombinant human macrophage colony stimulating factor beta and derivatives.

The potential of electrospray ionization (ESI) Fourier transform ion cyclotron mass spectrometry (FTICR-MS) to assist in the structural characterization of monomeric and dimeric derivatives of the macrophage colony stimulating factor beta (rhM-CSF beta) was assessed. Mass spectrometric analysis of the 49 kDa protein required the use of sustained off-resonance irradiation (SORI) in-trap cleanup to reduce adduction. High resolution mass spectra were acquired for a fully reduced and a fully S-cyanylated monomeric derivative (approximately 25 kDa). Mass accuracy for monomeric derivatives was better than 5 ppm, after applying a new calibration method (i.e., DeCAL) which eliminates space charge effects upon high accuracy mass measurements. This high mass accuracy allowed the direct determination of the exact number of incorporated cyanyl groups. Collisionally induced dissociation using SORI yielded b- and y-fragment ions within the N- and C-terminal regions for the monomeric derivatives, but obtaining information on other regions required proteolytic digestion, or potentially the use of alternative dissociation methods.

Thermal denaturation of Escherichia coli thioredoxin studied by hydrogen/deuterium exchange and electrospray ionization mass spectrometry: monitoring a two-state protein unfolding transition.

Thermally denatured oxidized Escherichia coli thioredoxin (TRX) in 2% acetic acid was examined by electrospray ionization mass spectrometry (ESI-MS) and circular dichroism. Conformational dynamics during thermal unfolding were probed by hydrogen/deuterium (H/D) exchange-in experiments. ESI-MS was used to determine the H/D ratios. TRX shows only a marginal change in negative ellipticity at 222 nm during thermal unfolding, but in the near-UV circular dichroism (240-350 nm) a clear transition is observed (Tm = 61 degrees C), and unfolding goes to completion. ESI mass spectra were recorded as a function of temperature, and the observed bimodal charge state distributions were analyzed assuming a two-state unfolding mechanism which allowed an estimation of the midpoint temperature, Tm = 64 degrees C. Under conditions at which the compact, folded conformational state is only marginally stable (80 degrees C, 2% acetic acid-d1), H/D exchange-in experiments in combination with ESI-MS resulted in mass spectra differing in the number of incorporated deuteriums which indicates the presence of two distinct populations of molecules after short incubation periods. As the exchange-in time increases, the population representing the unfolded state increases and the population which is protected against exchange decreases. The rate of conversion was used to estimate the rate constant of unfolding which was 2.1 +/- 0.2 min-1. The results presented here indicate that thermally denatured TRX under the conditions used may represent a collapsed unfolded state with properties often attributed to molten globule-like states, such as pronounced secondary structure but absence of rigid tertiary structure and, hence, lack of protection against H/D exchange.

Conformational properties of the A-state of cytochrome c studied by hydrogen/deuterium exchange and electrospray mass spectrometry.

Hydrogen/deuterium (H/D) exchange studies that were monitored by liquid chromatography-electrospray ionization mass spectrometry (LC-ESIMS) were used to obtain a structural description of the compact acid-denatured state of ferricytochrome c (A-state). Due to the very different solvent conditions necessary to generate the nonnative states, it was essential that after deuterium labeling the nonnative states were refolded to the native state to insure high reproducibility during sample preparation and LC-ESIMS analysis. Approximately 30% lower deuterium was found incorporated in the A-state compared to the acid-denatured (UA) state. The analysis of the width of the mass peak suggests that the distribution of conformers sampled in the A-state was relatively narrow and that the compactness of the A-state was much closer to that of the native state than to the acid-denatured state. The LC-ESIMS study of partially deuterium-labeled peptic fragments derived from the A-state conformer generated under H/D quenching conditions were interpreted in terms of a significant loss of structural integrity within amino acid region 22-46.