The etiology of autism spectrum disorders (ASD) is believed to be multifactorial and to involve genetic and environmental components. Environmental chemical exposures are increasingly understood to be important in causing neurotoxicity in fetuses and newborns. Recent data from the Centers for Disease Control and Prevention in the United States suggest a substantial increase in ASD prevalence, only partly explicable by factors such as diagnostic substitution. Bisphenol A (BPA) is an ubiquitous xenoestrogen widely employed in a variety of consumer products including plastic and metal food and beverage containers, dental sealants and fillings, medical equipment and thermal receipts. Therefore, most people are exposed almost continuously to BPA in industrialized countries. Sources of BPA exposure are predominantly diet, but also through inhalation or dermal absorption. BPA can be measured in many human fluids and tissues including saliva, serum, urine, amniotic fluid, follicular fluid, placental tissue and breast milk. There is concern that BPA exposure may influence human brain development and may contribute to the increasing prevalence of neurodevelopmental and behavioural problems. Epigenetic mechanisms are suggested by a mouse study that demonstrated that BPA exposure during gestation had long lasting, transgenerational effects on social recognition. Previous epidemiological studies suggested a relationship between maternal BPA exposure and ASD. A recent study of 46 children with ASD and 52 controls found for the first time a direct association between children with ASD and BPA exposure and demonstrated that BPA is not metabolized well in children with ASD. The metabolomic analyses showed a correlation between ASD and essential amino acid metabolism pathways. Essential amino acids are precursors of neurotransmitters, for example tryptophan for serotonin. Fetal and prenatal BPA exposure was suggested to perturb the serotonergic system in rat and mice models. On the other hand, hyperserotonemia was reported in approximately one-third of autistic patients and also in relatives. Moreover, neuroimaging studies revealed two fundamentally different types of serotonin synthesis abnormality in children with autism compared to age-matched nonautistic children, a difference in whole-brain capacity and focal abnormalities. Finally, decreased serotonin transporter and serotonin receptor binding have been reported in both children and adults with autism. So, the link between BPA and autism could be a defect of the normal in utero or perinatal serotonergic system development. In France, BPA was banned in baby bottles in 2010 and in any food or beverage packaging since January 2015. Therefore, there is an urgent need to find safe alternatives in the use of BPA in the manufacture of industrial products.

Chromatin structure in eukaryotes and its modulation by epigenetic mechanisms enable the regulation of the different nuclear processes. Perturbation of epigenetic mechanisms can thus affect the proper functioning of cells, and numerous diseases have been linked to the deregulation of the activity of epigenetic effectors in human. The reversibility of epigenetic mechanisms has allowed the development of "Epigenetic drugs" or "Epidrugs". In a chemical biology approach, we have made use of the importance of eukaryotic epigenetic mechanisms to find drug leads that specifically affect pathogens responsible for neglected diseases. Our work on histone deacetylase 8 from Schistosoma mansoni (smHDAC8) has enabled us to design drug leads that show stronger selectivity for the pathogen enzyme than for its human homologs. Specifically, we have used a structure-based approach to understand the structural specificities of the smHDAC8 enzyme compared to the human enzymes, notably human HDAC8. The structure of smHDAC8 in complex with various pan-HDAC drugs led to the design of inhibitors that make use of all the structural specificities of this enzyme and that can be stabilized in the smHDAC8 catalytic pocket through a pathogen-specific clamp. Collectively, our results provide the proof of concept that epigenetic enzymes from pathogens can be targeted to develop anti-pathogenic epidrugs in the fight against neglected diseases. Our results also provide information that can be used to develop epidrugs to fight human diseases, including cancer.

Type I interferons play a central role in the establishment of an innate immune response against viral infections and tumor cells. Shortly after their discovery in 1957, several groups have looked for small molecules capable of inducing the expression of these cytokines with therapeutic applications in mind. A set of active compounds in mice were identified, but because of their relative inefficiency in humans for reasons not understood at the time, these studies fell into oblivion. In recent years, the characterization of pathogen recognition receptors and the signaling pathways they activate, together with the discovery of plasmacytoid dendritic cells, have revolutionized our understanding of innate immunity. These discoveries and the popularization of high-throughput screening technologies have renewed the interest for small molecules that can induce type I interferons. Proofs about their therapeutic potency in humans are expected very soon.

An imbalance of protein homeostasis caused by external or internal stress in the endoplasmic reticulum triggers the initiation of signalling pathways downstream of the IRE1, ATF6 and PERK sensors to a translational or transcriptional adaptive response known as UPR (Unfolded Protein Response). According to the intensity and duration of stress, the dual function of the UPR leads to either cell adaptation or cell death. UPR pathways in cancer cells are often altered and generally lead to an adaptation to an hostile environment. As the UPR becomes an emerging therapeutic target due to its increasing contribution to various diseases, we describe in this review various strategies that have been developed to discover new compounds enabling to manipulate the magnitude of ER stress in the context of cancer.

Since the early 1970's, investigators at Station Biologique de Roscoff (SBR), France, have been using marine organisms as models to describe molecular pathways conserved through evolution in mammalian cells (e.g. the cyclin-dependent kinases involved in the control of the cell division cycle). Some kinases are misregulated in various human pathologies, including cancers. Using a specialized screening approach, chemical libraries were analysed, using on-site facilities at Roscoff, in order to identify small chemical inhibitors of protein kinases. Eight chemical scaffolds produced by marine organisms were characterized as candidate drugs by our screening facility, some of which are being considered as chemical tools to pinpoint specific cellular functions of the targeted kinases. In this review, we describe our existing screening facilities and we discuss new perspectives related to marine bioprospecting.

Structural diversity oriented synthesis aims to fulfill the unoccupied tridimensional "chemical space" gap left by traditional chemical libraries. Through the development of novel synthetic strategies relying on divergent reactions, chemist is now able to realize in only two or three steps such library that ensures the access of a large number of products having a good quality in term of structural diversity. A few examples are presented to illustrate how this can be done in the context of increasing molecular complexity and diversity devoted to the discovery and optimization of bioactive compounds.

The hyperactivity of the brain renin-angiotensin system (RAS) has been implicated in the development and maintenance of hypertension in several types of experimental and genetic hypertension animal models. Among the main bioactive peptides of the brain RAS, angiotensin (Ang) II and Ang III display the same affinity for type 1 and type 2 Ang II receptors. Both peptides, injected intracerebroventricularly, similarly increase arginine vasopressin release and blood pressure (BP); however, because Ang II is converted in vivo to Ang III, the identity of the true effector is unknown. We first identified the enzymes involved in the metabolism of brain angiotensins and developed specific and selective inhibitors. Here we review new insights into the predominant role of brain Ang III in the control of BP, underlining the fact that brain aminopeptidase A (APA), the enzyme generating brain Ang III, may therefore be an interesting candidate target for the treatment of hypertension. This justifies the development of potent systemically active APA inhibitors, such as RB150, as prototypes of a new class of antihypertensive agents for the treatment of certain forms of hypertension.

PML/TRIM19 is the organizer of PML nuclear bodies (NB), large multiprotein structures associated to the nuclear matrix, which recruit a great number of proteins and which are implicated in various cellular processes including antiviral defense. The conjugation of PML to SUMO is required for the formation and function of PML NB. Alternative splicing from a single PML gene generates several PML isoforms (PMLI to PMLVIIb), each harboring a specific carboxy-terminal region. This variability allows each isoform to recruit different partners and thus confers them specific functions. PML gene is directly induced by interferon and certain PML isoforms are implicated in its antiviral properties, as they display intrinsic antiviral activities against RNA or DNA viruses. One isoform, PMLIV, is also implicated in innate immunity by enhancing IFN-β production during a viral infection. Here we review recent findings on PML/TRIM19 implication in interferon response and antiviral defense, at the interface between intrinsic and innate immunity.

The lysosomal storage disorders (LSD) comprise a heterogeneous group of inborn errors of metabolism. The resulting enzymatic defect leads to accumulation of its substrate in the lysosome. Their clinical patterns reflect the site of substrate storage. Central nervous system involvement is often present in the younger patients affected by the most severe phenotypes. Substantial progress has been made in the pathophysiological knowledge, leading to new therapeutic options in LSD. Enzyme replacement therapy (ERT) is the dominant approach and is actually proposed in six LSD: Gaucher disease, Fabry disease, Pompe disease and mucopolysaccharidoisis (MPS) I (Hurler disease), II (Hunter disease) and VI (Maroteaux-Lamy disease). This treatment reduces lysosomal storage, and sometimes reduces, but most often limits the progression of visceral involvement and of its clinical consequences. However, ERT does not cross the blood-brain barrier and is ineffective on neurological symptoms. In the younger patients with MPS I (Hurler disease) and with selected cases of other LSD, haematopoietic stem cell transplantation remains the optimal option. Other strategies using small molecules are being explored in order to cross the blood-brain barrier. This includes substrate reduction or depletion therapies, which decrease the amount of substrate, and the use of pharmacological chaperones, which enhance the residual activity of the mutant enzyme. Miglustat is the proposed substrate reduction therapy in Niemann-Pick C disease and clinical trials are actually performed in several LSD using other substrate reduction or chaperone drugs.

Type 2 diabetes is characterized by a dysfunction of pancreatic β cells producing insulin and by impaired insulin responses in liver and skeletal muscle. This dysregulation of insulin secretion and action leads to chronic hyperglycaemia. The main causes that have been proposed to explain the pathogenesis of type 2 diabetes are lipotoxicity, glucotoxicity, oxidative stress and inflammation. Interestingly, these alterations converge towards the activation of a cellular pathway called "Unfolded Protein Response" which is set up in β cells and insulin-sensitive tissues. This cellular pathway is central to the pathogenesis of type 2 diabetes and emerges as an important therapeutic target in the treatment of this disease.

Glucocorticoids exert their actions at nuclear levels through genomic mechanisms including both transcriptional activation (transactivation) and gene expression repression (transrepression). Transactivation mechanisms are mediated by transcription factors, the main one being the activated glucocorticoid receptor (GR). These mechanisms contribute to both powerful therapeutic effects of glucocorticoids on inflammatory and immune diseases, and adverse effects than can be harmful on vital functions. Non-genomic mechanisms, which act faster than genomic ones, have also been explored. They also involve the GR in different membranous and cytosolic sites. The phenomenon of glucocorticoid resistance is also complex and several different mechanisms may mediate this phenomenon. Among them are alterations in number, binding affinity or phosphorylation status of the GR, changes in capacity of cellular apoptosis, polymorphic changes or expression of proteins involved in the genomic actions of glucocorticoids. Finally, some proteins, which mediate glucocorticoid activity could be therapeutic targets for reducing glucocorticoid-induced adverse effects.

Endocrine disruptors are chemicals substances interfering with the hormonal system. These pollutants, present in environment, can lead to diseases in human being. In this article, we take an interest to some endocrine disrupting substances linked to decrease in sperm quality and testicular dysgenesis syndrome, two pathologies involve in masculine fertility decline. The role of environment in complex diseases as male hypofertility is questioned.