Mariana Leão

Discovery of a new small-molecule inhibitor of p53-MDM2 interaction using a yeast-based approach.

The virtual screening of a library of xanthone derivatives led us to the identification of potential novel MDM2 ligands. The activity of these compounds as inhibitors of p53-MDM2 interaction was investigated using a yeast phenotypic assay, herein developed for the initial screening. Using this approach, in association with a yeast p53 transactivation assay, the pyranoxanthone (3,4-dihydro-12-hydroxy-2,2-dimethyl-2H,6H-pyrano[3,2-b]xanthen-6-one) (1) was identified as a putative small-molecule inhibitor of p53-MDM2 interaction. The activity of the pyranoxanthone 1 as inhibitor of p53-MDM2 interaction was further investigated in human tumor cells with wild-type p53 and overexpressed MDM2. Notably, the pyranoxanthone 1 mimicked the activity of known p53 activators, leading to p53 stabilization and activation of p53-dependent transcriptional activity. Additionally, it led to increased protein levels of p21 and Bax, and to caspase-7 cleavage. By computational docking studies, it was predicted that, like nutlin-3a, a known small-molecule inhibitor of p53-MDM2 interaction, pyranoxanthone 1 binds to the p53-binding site of MDM2. Overall, in this work, a novel small-molecule inhibitor of p53-MDM2 interaction with a xanthone scaffold was identified for the first time. Besides its potential use as molecular probe and possible lead to develop anticancer agents, the pyranoxanthone 1 will pave the way for the structure-based design of a new class of p53-MDM2 inhibitors.

New insights into cancer‐related proteins provided by the yeast model

Cancer is a devastating disease with a profound impact on society. In recent years, yeast has provided a valuable contribution with respect to uncovering the molecular mechanisms underlying this disease, allowing the identification of new targets and novel therapeutic opportunities. Indeed, several attributes make yeast an ideal model system for the study of human diseases. It combines a high level of conservation between its cellular processes and those of mammalian cells, with advantages such as a short generation time, ease of genetic manipulation and a wealth of experimental tools for genome‐ and proteome‐wide analyses. Additionally, the heterologous expression of disease‐causing proteins in yeast has been successfully used to gain an understanding of the functions of these proteins and also to provide clues about the mechanisms of disease progression. Yeast research performed in recent years has demonstrated the tremendous potential of this model system, especially with the validation of findings obtained with yeast in more physiologically relevant models. The present review covers the major aspects of the most recent developments in the yeast research area with respect to cancer. It summarizes our current knowledge on yeast as a cellular model for investigating the molecular mechanisms of action of the major cancer‐related proteins that, even without yeast orthologues, still recapitulate in yeast some of the key aspects of this cellular pathology. Moreover, the most recent contributions of yeast genetics and high‐throughput screening technologies that aim to identify some of the potential causes underpinning this disorder, as well as discover new therapeutic agents, are discussed.

Contribution of Yeast Models to Neurodegeneration Research

As a model organism Saccharomyces cerevisiae has greatly contributed to our understanding of many fundamental aspects of cellular biology in higher eukaryotes. More recently, engineered yeast models developed to study endogenous or heterologous proteins that lay at the root of a given disease have become powerful tools for unraveling the molecular basis of complex human diseases like neurodegeneration. Additionally, with the possibility of performing target-directed large-scale screenings, yeast models have emerged as promising first-line approaches in the discovery process of novel therapeutic opportunities against these pathologies. In this paper, several yeast models that have contributed to the uncovering of the etiology and pathogenesis of several neurodegenerative diseases are described, including the most common forms of neurodegeneration worldwide, Alzheimers, Parkinsons, and Huntingtons diseases. Moreover, the potential input of these cell systems in the development of more effective therapies in neurodegeneration, through the identification of genetic and chemical suppressors, is also addressed.

Medicinal Chemistry Strategies to Disrupt the p53-MDM2/MDMX Interaction.

The growth inhibitory activity of p53 tumor suppressor is tightly regulated by interaction with two negative regulatory proteins, murine double minute 2 (MDM2) and X (MDMX), which are overexpressed in about half of all human tumors. The elucidation of crystallographic structures of MDM2/MDMX complexes with p53 has been pivotal for the identification of several classes of inhibitors of the p53–MDM2/MDMX interaction. The present review provides in silico strategies and screening approaches used in drug discovery as well as an overview of the most relevant classes of small‐molecule inhibitors of the p53–MDM2/MDMX interaction, their progress in pipeline, and highlights particularities of each class of inhibitors. Most of the progress made with high‐throughput screening has led to the development of inhibitors belonging to the cis‐imidazoline, piperidinone, and spiro‐oxindole series. However, novel potent and selective classes of inhibitors of the p53–MDM2 interaction with promising antitumor activity are emerging. Even with the discovery of the 3D structure of complex p53–MDMX, only two small molecules were reported as selective p53–MDMX antagonists, WK298 and SJ‐172550. Dual inhibition of the p53–MDM2/MDMX interaction has shown to be an alternative approach since it results in full activation of the p53‐dependent pathway. The knowledge of structural requirements crucial to the development of small‐molecule inhibitors of the p53–MDMs interactions has enabled the identification of novel antitumor agents with improved in vivo efficacy.

Oxazoloisoindolinones with in vitro antitumor activity selectively activate a p53-pathway through potential inhibition of the p53-MDM2 interaction

One of the most appealing targets for anticancer treatment is the p53 tumor suppressor protein. In half of human cancers, this protein is inactivated due to endogenous negative regulators such as MDM2. Actually, restoring the p53 activity, particularly through the inhibition of its interaction with MDM2, is considered a valuable therapeutic strategy against cancers with a wild-type p53 status. In this work, we report the synthesis of nine enantiopure phenylalaninol-derived oxazolopyrrolidone lactams and the evaluation of their biological effects as p53-MDM2 interaction inhibitors. Using a yeast-based screening assay, two oxazoloisoindolinones, compounds 1b and 3a, were identified as potential p53-MDM2 interaction inhibitors. The molecular mechanism of oxazoloisoindolinone 3a was further validated in human colon adenocarcinoma HCT116 cells with wild-type p53 (HCT116 p53(+/+)) and in its isogenic derivative without p53 (HCT116 p53(-/-)). Indeed, using these cells, we demonstrated that oxazoloisoindolinone 3a exhibited a p53-dependent in vitro antitumor activity through induction of G0/G1-phase cell cycle arrest and apoptosis. The selective activation of a p53-apoptotic pathway by oxazoloisoindolinone 3a was further supported by the occurrence of PARP cleavage only in p53-expressing HCT116 cells. Moreover, oxazoloisoindolinone 3a led to p53 protein stabilization and to the up-regulation of p53 transcriptional activity with increased expression levels of several p53 target genes, as p21(WAF1/CIP1), MDM2, BAX and PUMA, in p53(+/+) but not in p53(-/-) HCT116 cells. Additionally, the ability of oxazoloisoindolinone 3a to block the p53-MDM2 interaction in HCT116 p53(+/+) cells was confirmed by co-immunoprecipitation. Finally, the molecular docking analysis of the interactions between the synthesized compounds and MDM2 revealed that oxazoloisoindolinone 3a binds to MDM2. Altogether, this work adds, for the first time, the oxazoloisoindolinone scaffold to the list of chemotypes activators of a wild-type p53-pathway with promising antitumor activity. Moreover, it may open the way to the development of a new class of p53-MDM2 interaction inhibitors.

A tryptophanol-derived oxazolopiperidone lactam is cytotoxic against tumors via inhibition of p53 interaction with murine double minute proteins

Inactivation of the p53 tumor suppressor protein by interaction with murine double minute (MDM) proteins, MDM2 and MDMX, is a common event in human tumors expressing wild-type p53. In these tumors, the simultaneous inhibition of these interactions with MDMs, for a full p53 reactivation, represents a promising anticancer strategy. Herein, we report the identification of a dual inhibitor of the p53 interaction with MDM2 and MDMX, the (S)-tryptophanol derivative OXAZ-1, from the screening of a small library of enantiopure tryptophanol-derived oxazolopiperidone lactams, using a yeast-based assay. With human colon adenocarcinoma HCT116 cell lines expressing wild-type p53 (HCT116 p53(+/+)) and its p53-null isogenic derivative (HCT116 p53(-/-)), it was shown that OXAZ-1 induced a p53-dependent tumor growth-inhibitory effect. In fact, OXAZ-1 induced p53 stabilization, up-regulated p53 transcription targets, such as MDM2, MDMX, p21, Puma and Bax, and led to PARP cleavage, in p53(+/+), but not in p53(-/-), HCT116 cells. In addition, similar tumor cytotoxic effects were observed for OXAZ-1 against MDMX-overexpressing breast adenocarcinoma MCF-7 tumor cells, commonly described as highly resistant to MDM2-only inhibitors. In HCT116 p53(+/+) cells, the disruption of the p53 interaction with MDMs by OXAZ-1 was further confirmed by co-immunoprecipitation. It was also shown that OXAZ-1 potently triggered a p53-dependent mitochondria-mediated apoptosis, characterized by reactive oxygen species generation, mitochondrial membrane potential dissipation, Bax translocation to mitochondria, and cytochrome c release, and exhibited a p53-dependent synergistic effect with conventional chemotherapeutic drugs. Collectively, in this work, a novel selective activator of the p53 pathway is reported with promising antitumor properties to be explored either alone or combined with conventional chemotherapeutic drugs. Moreover, OXAZ-1 may represent a promising starting scaffold to search for new dual inhibitors of the p53-MDMs interaction.

α-Mangostin and Gambogic Acid as Potential Inhibitors of the p53–MDM2 Interaction Revealed by a Yeast Approach

α-Mangostin (1) and gambogic acid (2) are natural products with potent cytotoxic activity against several human tumor cells. However, their molecular mechanisms of action remain controversial. In this work, using yeast-based assays, it was shown that both xanthones are potential inhibitors of the p53-MDM2 interaction. This activity on p53-MDM2 interaction was confirmed by a gene reporter assay in a human tumor cell. Additionally, computational docking studies supported the potential of these xanthones to bind to MDM2 and therefore act as putative MDM2 inhibitors. Altogether, this work provides a new insight concerning the molecular basis of activity for these compounds.

Differential regulation of p53 function by protein kinase C isoforms revealed by a yeast cell system

The complexity of the mammalian p53 pathway and protein kinase C (PKC) family has hampered the discrimination of the effect of PKC isoforms on p53 activity. Using yeasts co‐expressing the human wild‐type p53 and a mammalian PKC‐α, ‐δ, ‐ε or ‐ζ, we showed a differential regulation of p53 activity and phosphorylation state by PKC isoforms. Whereas PKC‐α reduced the p53‐induced yeast growth inhibition and cell cycle arrest, PKC‐δ and ‐ε enhanced the p53 activity through p53 phosphorylation, and PKC‐ζ had no effect on p53. This work identified positive and negative p53 regulators which represent promising pharmacological targets in anti‐cancer therapy.

New Therapeutic Strategies for Cancer and Neurodegeneration Emerging from Yeast Cell-based Systems

Despite great advances in understanding the molecular etiology of cancer and neurodegeneration, therapeutic strategies against these diseases are still largely lacking. Hence, acceleration of the discovery of new therapeutic agents against these pathologies is of enormous interest. This review is focused on the role of multi-faceted and expanding yeast cell-based systems in the search for new drugs and therapeutic targets in cancer and neurodegeneration. Though the obvious limitations of using a microorganism to address human diseases, when used in the early phase and with complementary mammalian systems, it can have a tremendous impact in the discovery of new therapeutic opportunities. In this review, many evidence are provided demonstrating the valuable contribution of yeast in this area. Additionally, several yeast target-based drug screening approaches based on a readily screenable phenotype on genomic technologies increasingly oriented towards genetic and chemical high-throughput analysis are addressed. Altogether, with this review, we intend not only to recognize previous successes and ongoing work in this area, but also to point out new opportunities that may be of interest for yeast as a model organism and as a powerful system in the discovery of new lead compounds that have the potential to become novel drugs in cancer and neurodegeneration.

Novel simplified yeast‐based assays of regulators of p53–MDMX interaction and p53 transcriptional activity

Yeast has proven to be an efficient model system for functional and pharmacological studies of the p53 tumour suppressor protein. In this work, the human p53–MDMX regulatory pathway was reconstituted in yeast. Additionally, by using the known inhibitor of p53–MDMX interaction, SJ‐172550, the efficacy of a simplified yeast‐based screening assay to search for inhibitors of p53–MDMX interaction is demonstrated for the first time. Moreover, further insights on p53 transcriptional activity in yeast are provided. In particular, it is shown that the reported wild‐type (wt) p53‐induced yeast growth inhibition and cell cycle arrest is associated with actin depolarization and with an increase of actin mRNA and protein expression levels. The increase of actin protein levels was not observed with the p53 R273H mutant (a loss of function p53 mutation hotspot) and was further intensified with the toxic p53 V122A mutant (reported to exhibit higher transcriptional activity than wt p53 for selected p53 target sequences). Moreover, it is shown that the wt p53‐induced actin protein levels are modulated by natural (MDM2 and MDMX) and chemical (pifithrin‐α, nutlin‐3a and SJ‐172550) regulators of p53 activity. Furthermore, wt p53 could stimulate transcription from a minimal promoter containing a fragment of the ACT1 upstream sequence. Thus, ACT1 is proposed as a putative endogenous p53 target gene. This finding may open the way for the development of simpler yeast p53 transactivation assays, not based on artificial reporter constructs, for the analysis of the impact of mutants, cofactors and small molecules on p53 transcriptional activity.