Benzoyl-CoA conjugate accumulation as an initiating event for male reprotoxic effects in the rat? Structure-activity analysis, species specificity, and in vivo relevance

Toxicological investigation of lilial

Lilial (also called lysmeral) is a fragrance ingredient presented in many everyday cosmetics and household products. The concentrations of lilial in the final products is rather low. Its maximum concentration in cosmetics was limited and recently, its use in cosmetics products was prohibited in the EU due to the classification as reproductive toxicant. Additionally, according to the European Chemicals Agency, it was under assessment as one of the potential endocrine disruptors, i.e. a substance that may alter the function of the endocrine system and, as a result, cause health problems. Its ability to act as an androgen receptor agonist and the estrogenic and androgenic activity of its metabolites, to the best of our knowledge, have not yet been tested. The aim of this work was to determine the intestinal absorption, cytotoxicity, nephrotoxicity, mutagenicity, activation of cellular stress-related signal pathways and, most importantly, to test the ability to disrupt the endocrine system of lilial and its Phase I metabolites. This was tested using set of in vitro assays including resazurin assay, the CHO/HPRT mutation assay, γH2AX biomarker-based genotoxicity assay, qPCR and in vitro reporter assays based on luminescence of luciferase for estrogen, androgen, NF-κB and NRF2 signalling pathway. It was determined that neither lilial nor its metabolites have a negative effect on cell viability in the concentration range from 1 nM to 100 µM. Using human cell lines HeLa9903 and MDA-kb2, it was verified that this substance did not have agonistic activity towards estrogen or androgen receptor, respectively. Lilial metabolites, generated by incubation with the rat liver S9 fraction, did not show the ability to bind to estrogen or androgen receptors. Neither lilial nor its metabolites showed a nephrotoxic effect on human renal tubular cells (RPTEC/TERT1 line) and at the same time they were unable to activate the NF-κB and NRF2 signalling pathway at a concentration of 50 µM (HEK 293/pGL4.32 or pGL4.37). Neither lilial nor its metabolites showed mutagenic activity in the HPRT gene mutation test in CHO-K1 cells, nor were they able to cause double-strand breaks in DNA (γH2AX biomarker) in CHO-K1 and HeLa cells. In our study, no negative effects of lilial or its in vitro metabolites were observed up to 100 µM using different in vitro tests.

Towards the mechanism of spermatotoxicity of p-tert-butyl-alpha-methylhydrocinnamic aldehyde: inhibition of late stage ex-vivo spermatogenesis in rat seminiferous tubule cultures by para-tert-butyl- benzoic acid

Molecules metabolized to para-tert-butyl-benzoic acid (p-TBBA) affect male reproduction in rats through effects on spermatogenesis. This toxicity is specific to p-TBBA and not observed in meta-substituted analogues. The underlying mode of action was evaluated by comparing effects of p-TBBA and the position isomer m-TBBA (2-50 µM) in an ex vivo 3D primary seminiferous tubule cell culture system from juvenile Sprague Dawley rats (Bio-AlteR^®). Treated cultures were evaluated for CoA-conjugate formation, cytotoxicity, blood-testis barrier functionality and different germ cell populations to assess effects on spermatogenesis. In addition, an evaluation of the metabolome of treated cultures was performed by using MxP^® Broad Profiling via a LC-MS/MS and GC-MS platform. Para-TBBA decreased germ cell populations of late stages of spermatogenesis and led to the formation of CoA-conjugates in the ex vivo tissue. In addition, p-TBBA had a pronounced effect on the metabolome by affecting lipid balance and other CoA-dependent pathways contributing to energy production and the redox system. Meta-TBBA did not affect germ cell populations and no m-TBBA related CoA-conjugates were detectable. The metabolic profile of m-TBBA treated cells was comparable to vehicle control treated cultures, indicating that formation of CoA-conjugates, inhibition of spermatogenesis, and effects on the metabolome are mechanistically linked events. Thus, for this specific chemical group an adverse outcome pathway can be postulated, including the formation of benzoic acid metabolites, accumulation of CoA-conjugates to a certain threshold and CoA depletion, which affects the metabolic and lipid profile and leads to tissue specific effects with impaired functionalities such as spermatogenesis.

A species specific metabolism leading to male rat reprotoxicity of Cyclamen aldehyde: in vivo and in vitro evaluation

Cyclamen aldehyde (CA; 3-(4-isopropylphenyl)-2-methylpropanal) is a widely used fragrance material. Repeated dose studies in rats revealed adverse effects on sperm maturation. Here we review all the mechanistic and in vivo evidence, to determine relevancy to human health. The effect on spermatogenesis appears to be linked to the metabolite p-isopropyl-benzoic acid (p-iPBA). Studies in rat, rabbit and human suspended hepatocytes indicated species differences with p-iPBA detected in rat hepatocytes only. In plated rat hepatocytes, p-iPBA is conjugated to Coenzyme A (CoA) and p-iPBA-CoA accumulates to stable levels over 22 h. In vitro accumulation of CoA conjugates is a metabolic hallmark correlated to male rat reproductive toxicity for related compounds. p-iPBA-CoA is formed in vivo in liver and testes of rats dosed with CA. In plated rabbit and human hepatocytes p-iPBA-CoA doesn't accumulate. Correlating to this lack of metabolite accumulation, no effects of CA on spermatogenesis were observed in a rabbit in vivo study. A species specific metabolic fate linked to CA toxicity in male rats is postulated which appears not relevant to the rabbit as non-responder species. Lack of accumulation of p-iPBA-CoA in human hepatocytes indicates that like rabbits, humans are unlikely to be vulnerable to p-iPBA hepatic and testicular toxicity.