Microbial enzymes induce colitis by reactivating triclosan in the mouse gastrointestinal tract

Emerging research supports that triclosan (TCS), an antimicrobial agent found in thousands of consumer products, exacerbates colitis and colitis-associated colorectal tumorigenesis in animal models. While the intestinal toxicities of TCS require the presence of gut microbiota, the molecular mechanisms involved have not been defined. Here we show that intestinal commensal microbes mediate metabolic activation of TCS in the colon and drive its gut toxicology. Using a range of in vitro, ex vivo, and in vivo approaches, we identify specific microbial β-glucuronidase (GUS) enzymes involved and pinpoint molecular motifs required to metabolically activate TCS in the gut. Finally, we show that targeted inhibition of bacterial GUS enzymes abolishes the colitis-promoting effects of TCS, supporting an essential role of specific microbial proteins in TCS toxicity. Together, our results define a mechanism by which intestinal microbes contribute to the metabolic activation and gut toxicity of TCS, and highlight the importance of considering the contributions of the gut microbiota in evaluating the toxic potential of environmental chemicals.

Azelaic Acid Esters as Pluripotent Immunomodulatory Molecules: Nutritional Supplements or Drugs

Azelaic acid and its esters, the azelates, occur naturally in organisms ranging from plants to humans. We have shown that diethyl azelate (DEA) exhibits a broad range of immunomodulatory activities in vitro and in vivo, and mitigates insulin resistance. To further investigate the therapeutic utility of DEA, we evaluated its mutagenicity in Salmonella typhimurium strains, examined metabolism of DEA in rat, dog, monkey and human primary hepatocytes and in human saliva, determined pharmacokinetics of DEA after an oral dose in rats, and queried its physicochemical properties for drug-like characteristics. DEA was not mutagenic in bacterial strains ± rat liver metabolic activation system S-9. It was chemically unstable in hepatocyte culture medium with a half-life of <1 h and was depleted by the hepatocytes in <5 min, suggesting rapid hepatic metabolism. DEA was also quickly degraded by human saliva in vitro. After an oral administration of DEA to rats, the di- and monoester were undetectable in plasma while the levels of azelaic acid increased over time, reached maximum at <2 h, and declined rapidly thereafter. The observed pharmacological properties of DEA suggest that it has value both as a drug or a nutritional supplement.

Amino acid and biogenic amine adductions derived from reactive metabolites

: Reactive metabolites (RMs) are products generated from the metabolism of endogenous and exogenous substances. RMs are characterized as electrophilic species chemically reactive to nucleophiles. Those nucleophilic species may be nitrogen-containing bio-molecules, including macro-biomolecules, such as protein and DNA, and small biomolecules, i.e., amino acids (AAs) and biogenic amines (BAs). AAs and BAs are essential endogenous nitrogen-containing compounds required for normal development, metabolism, and physiological functions in organisms, through participating in the intracellular replication, transcription, translation, division and proliferation, DNA and protein synthesis, regulation of apoptosis, and intercellular communication activities. These biological amines containing an active lone pair of electrons on the electronegative nitrogen atom would be the proper N-nucleophiles to be attacked by the abovementioned RMs. This review covers an overview of adductions of AAs and BAs with varieties of RMs. These RMs are formed from metabolic activation of furans, naphthalene, benzene, and products of lipid peroxidation. This article is designed to provide readers with a better understanding of biochemical mechanisms of toxic action.

Overcompensation of CoA Trapping by Di(2-ethylhexyl) Phthalate (DEHP) Metabolites in Livers of Wistar Rats

Di(2-ethylhexyl) phthalate (DEHP) is commonly used as a plasticizer in various industrial and household plastic products, ensuring widespread human exposures. Its routine detection in human bio-fluids and the propensity of its monoester metabolite to activate peroxisome proliferator activated receptor-α (PPARα) and perturb lipid metabolism implicate it as a metabolic disrupter. In this study we evaluated the effects of DEHP exposure on hepatic levels of free CoA and various CoA esters, while also confirming the metabolic activation to CoA esters and partial β-oxidation of a DEHP metabolite (2-ethyhexanol). Male Wistar rats were exposed via diet to 2% (w/w) DEHP for fourteen-days, following which hepatic levels of free CoA and various CoA esters were identified using liquid chromatography-mass spectrometry. DEHP exposed rats showed significantly elevated free CoA and increased levels of physiological, DEHP-derived and unidentified CoA esters. The physiological CoA ester of malonyl-CoA and DEHP-derived CoA ester of 3-keto-2-ethylhexanoyl-CoA were the most highly elevated, at eighteen- and ninety eight-times respectively. We also detected sixteen unidentified CoA esters which may be derivative of DEHP metabolism or induction of other intermediary metabolism metabolites. Our results demonstrate that DEHP is a metabolic disrupter which affects production and sequestration of CoA, an essential cofactor of oxidative and biosynthetic reactions.

Establishment of Novel Genotoxicity Assay System Using Murine Normal Epithelial Tissue-Derived Organoids

Short-/middle-term and simple prediction studies for carcinogenesis are needed for the safety assessment of chemical substances. To establish a novel genotoxicity assay with an in vivo mimicking system, we prepared murine colonic/pulmonary organoids from gpt delta mice according to the general procedure using collagenase/dispase and cultured them in a 3D environment. When the organoids were exposed to foodborne carcinogens—2-amino-1-methyl-6-phenylimidazo(4,5-b)pyridine (PhIP) and acrylamide (AA)—in the presence of metabolic activation systems, mutation frequencies (MFs) occurring in the gpt gene dose-dependently increased. Moreover, the mutation spectrum analysis indicated predominant G:C to T:A transversion with PhIP, and A:T to C:G and A:T to T:A transversion with AA. These data correspond to those of a previous study describing in vivo mutagenicity in gpt delta mice. However, organoids derived from the liver, a non-target tissue of PhIP-carcinogenesis, also demonstrated genotoxicity with a potency comparable to colonic organoids. Organoids and PhIP were directly incubated in the presence of metabolic activation systems; therefore, there was a lack of organ specificity, as observed in vivo. Additionally, PhIP-DNA adduct levels were comparable in hepatic and colonic organoids after PhIP exposure. Taken together, the organoids prepared in the present study may be helpful to predict chemical carcinogenesis.

The Positive Enantiomer of a Novel Chiral DNA Alkylating Agent Exhibits Nanomolar Potency in Hematologic Cancers

LP-184, or (-)-hydroxyurea methylacylfulvene, is a potent DNA alkylating agent that effectively kills solid tumors. It belongs to the acylfulvene compound family known to induce DNA lesions repaired by the Transcription-Coupled Nucleotide Excision Repair (TC-NER) pathway. Here, we show that LP-284, the synthetic positive enantiomer of LP-184, exhibited the greatest and broadest hematologic cancer antiproliferative activities among the 6 acylfulvenes, including illudin S, illudin M, Irofulven (LP-100), the semisynthetic racemic LP-184, the synthetic negative enantiomer LP-184, and LP-284. The distinct pharmacological activities of LP-284 may be due to differences in metabolic activation, transport, or affinity to cellular macromolecules. To determine whether metabolic activation plays a role, we compared the correlation between the expression of Prostaglandin Reductase 1 (PTGR1), the NADPH-dependent oxidoreductase known to convert Irofulven into its active metabolite, and the IC50 of LP-184, Irofulven, and LP-284. We found that the expression level of PTGR1 is highly correlated with LP-184 (r=0.88, p=8.4e-20) and Irofulven (r=0.71, p=4.7e-10) sensitivity, but not with LP-284 (r=-0.01, p=0.93). We also found that the average expression level of PTGR1 is significantly lower in hematologic cancer cell lines (n=180) than in solid tumor cell lines (n=856), indicating the existence of an alternative LP-284 activator in hematologic cells. Next, we checked mutation status, RNA expression, protein expression, and DNA methylation of 489 oxidoreductases, but none of the enzymes was highly correlated with LP-284 activity. To further explore the potential clinical application of LP-284 in hematologic cancers, we conducted cell viability assays in 18 hematologic cancer cell lines and found that LP-284 exhibited nanomolar potency in acute lymphocytic leukemia (average IC50: 351 nM), chronic myeloid leukemia (average IC50: 360 nM), B-cell lymphoma (average IC50: 366 nM), and Multiple Myeloma (MM, IC50: 334 nM). We also investigated the therapeutic potential of LP-284 in combination with spironolactone in treating MM. Spironolactone, an FDA approved drug for hypertension, degrades one of the key TC-NER players ERCC3 in MM, which in turn makes cells more vulnerable to helix-distorting DNA lesions likely caused by LP-284. While Spironolactone alone didn't cause cytotoxicity to the MM cell line RPMI8226, it reduced LP-284 IC50 by 2.4 fold. Taken together, we have demonstrated the importance of stereochemistry in acylfulvene activity. LP-284, likely to be activated through a different route, is a unique and potent acylfulvene for hematologic cancers. Additionally, pharmacological inhibition of the TC-NER pathway greatly promoted LP-284 cytotoxicity. We hypothesize that LP-284 induces DNA lesions, which may be lethal to TC-NER deficient cells and may block transcription of short-lived fusion genes that are essential for cancer cell survival until repaired. Therefore, our discovery of the novel enantiomer LP-284 may provide a targeted therapy option for hematologic cancers with compromised DNA repair. Disclosures Zhou: Lantern Pharma: Current Employment. Biyani: Lantern Pharma: Current Employment. Kathad: Lantern Pharma: Current Employment, Current equity holder in publicly-traded company. Kulkarni: Lantern Pharma: Current Employment. McDermott: Lantern Pharma: Current Employment. Bhatia: Lantern Pharma: Current Employment.

Analyses of the Kinetics and Phenotype of Multiple Intraclonal CXCR4/CD5 B Cell Subsets Suggest Differences in Life Cycle Transitioning in CLL

Chronic lymphocytic leukemia (CLL) is a heterogeneous disease so that defining the dynamic features of the clone and its intraclonal subpopulations are essential to understand disease pathogenesis and to develop novel, effective therapies. For instance, because cell division is linked with new mutations, the ability to preferentially select cells that recently divided allows studying the subpopulation(s) most likely responsible for disease progression and resistance to therapies. The intraclonal kinetics of CLL B cells have been studied in clonal subgroups defined by reciprocal surface levels of CXCR4 and CD5. In that model, three fractions are identified: recently divided "proliferative" (PF; CXCR4 DimCD5 Bright); "intermediate" (IF; CXCR4 IntCD5 Int) and "resting" (RF; CXCR4 BrightCD5 Dim). Here, we have expanded the examination of subpopulations differing for time since last division ("age"). Unmanipulated CLL cells studied ex vivo from 10 patients who drank 2H 2O for 4 weeks were sorted by the relative densities of CXCR4 and CD5 to isolate the formerly identified PF, IF and RF as well as two fractions not previously characterized, "Double Dim" (DDF: CXCR4 DimCD5 Dim) and "Double Bright" (DBF; CXCR4 BrightCD5 Bright). For each fraction, the amount of deuterium incorporated into cellular DNA in vivo was measured. Consistently, the PF contained significantly higher levels of 2H-labeled DNA and higher calculated cell division rates when compared with the RF and IF. Interestingly, the DDF also contained significantly more 2H-labeled DNA compared to the RF; in contrast, the DBF resembled more closely the RF fraction. The overall 2H-incorporation gradient was: PF&gt;DDF&gt;IF&gt;DBF&gt;RF. In CLL, BCR signaling is fundamental, with the amount of membrane (m) IgM associating with signaling competence and disease aggressiveness. Additionally, when engaged independently, mIgM and mIgD can lead to different signaling sequelae. Therefore, we analyzed the 5 subpopulations for the densities of mIgM and mIgD. This showed a distribution similar to that of 2H-DNA incorporation: for IgM: PF=DDF&gt;IF=DBF=RF, and for IgD: PF&gt;DDF&gt;IF=DBF&gt;RF. Accordingly, we next measured 2H-DNA in subpopulations with low, intermediate and high levels of IgM and IgD. This revealed a direct correlation between IG densities and in vivo DNA synthesis, consistent with intraclonal subpopulations with high IGs having divided more recently than those with low IGs. However, these findings are not in line with cell division being primarily initiated by BCR engagement since that would lower mIgM levels. Therefore, we tested if engagement of TLR9 would affect mIG densities on CLL cells. After stimulation of 32 CLL clones with CpG+IL15, anti-IgM+IL4, anti-IgD+IL4, or anti-IgM-IgD+IL4, there was a significant increase in mIGs only after CpG+IL15 activation; each anti-IG stimulation led to downregulation of mIGs. Finally, we questioned the subclonal responsiveness to BTK inhibition in vivo. CLL samples taken from the same patients, before and during ibrutinib treatment, displayed intraclonal changes in mIG densities and cell size, the latter a marker of cellular and metabolic activation also linked with CLL in vivo birth rates. Ibrutinib treatment normalized mIgM and mIgD intraclonal densities and lead to an overall cell size decrease with larger, 2H-enriched and higher mIG density cells being more affected (PF&gt;DDF&gt;IF&gt;DBF&gt;RF). Collectively, these findings suggest that the most recently born cells enter the circulation as the PF from which they transition to either lower CD5 (DDF) or higher CXCR4 (IF and DBF) phenotypes. Each eventually converge as the RF. Moreover, since mIG densities on the more recently divided populations (PF and DDF) are high, the data imply that successful cell division is not solely a consequence of BCR engagement; the involvement of the TLR pathways, concomitantly or in series with BCR signaling, is more consistent with the higher mIG levels. Finally, ibrutinib treatment appears to preferentially target more recently divided cells with high mIG levels. Disclosures Allen: Alexion: Research Funding; Bristol Myers Squibb: Other: Equity Ownership; C4 Therapeutics: Other: Equity Ownership; Sanofi Genzyme: Membership on an entity's Board of Directors or advisory committees.

Sex differences in embryonic gonad transcriptomes and benzo[a]pyrene metabolite levels after transplacental exposure

Polycyclic aromatic hydrocarbons like benzo[a]pyrene (BaP) are generated during incomplete combustion of organic materials. Prior research has demonstrated that BaP is a prenatal ovarian toxicant and carcinogen. However, the metabolic pathways active in the embryo and its developing gonads and the mechanisms by which prenatal exposure to BaP predisposes to ovarian tumors later in life remain to be fully elucidated. To address these data gaps, we orally dosed pregnant female mice with BaP from E6.5-11.5 (0, 0.2 or 2 mg/kg-day) for metabolite measurement or E9.5-11.5 (0 or 3.33 mg/kg-day) for embryonic gonad RNA-sequencing. Embryos were harvested at E13.5 for both experiments. The sum of BaP metabolite concentrations increased significantly with dose in the embryos and placentas, and concentrations were significantly higher in female than male embryos and in embryos than placentas. RNA sequencing revealed that enzymes involved in metabolic activation of BaP are expressed at moderate to high levels in embryonic gonads and that greater transcriptomic changes occurred in the ovaries in response to BaP than in the testes. We identified 490 differentially expressed genes (DEGs) with FDR p-values &lt;0.05 when comparing BaP-exposed to control ovaries, but no statistically significant DEGs between BaP-exposed and control testes. Genes related to monocyte/macrophage recruitment and activity, prolactin family genes, and several keratin genes were among the most upregulated genes in the BaP-exposed ovaries. Results show that developing ovaries are more sensitive than testes to prenatal BaP exposure, which may be related to higher concentrations of BaP metabolites in female embryos.