A patent review of histone deacetylase 8 (HDAC8) inhibitors (2013-present).

INTRODUCTION: The processes and course of several fatal illnesses, such as cancer, inflammatory diseases, and neurological disorders, are closely correlated with HDAC8. Therefore, novel HDAC8 inhibitors represent effective therapeutic possibilities that may help treat these conditions. To yet, there aren't any such particular HDAC8 inhibitors available for sale. This review was conducted to examine recent HDAC8 inhibitors that have been patented over the last ten years. AREAS COVERED: This review focuses on HDAC8 inhibitor-related patents and their therapeutic applications that have been published within the last ten years and are accessible through the Patentscope and Google Patents databases. EXPERT OPINION: A handful of HDAC8 inhibitor-related patents have been submitted over the previous ten years, more selective, and specific HDAC8 inhibitors that are intended to treat a variety of medical diseases. This could lead to the development of novel treatment approaches that target HDAC8. Employing theoretical frameworks and experimental procedures can reveal the creation of new HDAC8 inhibitors with enhanced pharmacokinetic characteristics. A thorough understanding of the role that HDAC8 inhibitors play in cancer including the mechanisms behind HDAC8 in other disorders is necessary.

Planejamento, síntese, modelagem molecular e avaliação biológica de novos potenciais inibidores duais HDAC/ MMP não-hidroxamatos / Design, synthesis, molecular modeling and biological evaluation of novel potential non-hydroxamate dual HDAC/ MMP inhibitors

A inibição de alvos específicos como metaloproteinase de matriz (MMP) e histona desacetilase (HDAC) é amplamente estudada para impedir o progresso do câncer. Foi estabelecido que a inibição concomitante de MMP e HDAC é eficaz no combate de tumores sólidos e hematológicos. Ambos os alvos possuem um íon Zn2+ em seu sítio ativo, fundamental para a atividade destas enzimas. A alta afinidade dos inibidores conhecidos de MMP e de HDAC é conferida, principalmente, por um potente grupo ligante de zinco (ZBG). O ácido hidroxâmico é o ZBG mais potente conhecido atualmente, entretanto, este apresenta instabilidade farmacocinética, levando a ineficácia e genotoxicidade em testes clínicos. Frente a este contexto, o presente trabalho teve como objetivo o planejamento, síntese, modelagem molecular e avaliação biológica de novos inibidores duais MMP/HDAC não-hidroxamatos. Os compostos foram planejados utilizando estratégias de hibridação molecular, a partir de arcabouços provenientes inibidores de HDAC e MMP, gerando compostos arilsulfonamídicos com variações no tipo de ZBG inserido e na sua respectiva posição relativa na estrutura geral. Foram sintetizados sete análogos, em duas a três etapas reacionais, utilizando métodos de sulfonilação e acoplamento com agentes condensantes, partindo dos ésteres para e meta aminobenzoicos. Os rendimentos globais variaram de 25% a 55% e os produtos obtidos foram caracterizados por RMN 1H e 13C, LC/MS, CLAE e ponto de fusão. Os compostos tiveram sua atividade citotóxica avaliada em células HOG (oligodendroma) e T98G (glioblastoma), dentre os quais o 6a, que possui o ZBG 2-amino anilida, foi o mais promissor, apresentando atividade nas duas linhagens na casa de nM. Ensaios de coordenação com Fe2+ comprovaram a capacidade quelante dos análogos contendo ácido hidroxâmico e dos demais compostos citotóxicos, 4a e 4b (ZBG-2, salicilal-hidrazona), o que não foi observado para o composto 6a. Os estudos de ancoramento molecular permitiram sugerir um modo de interação para todos os ZBG propostos frente aos respectivos alvos (HDAC e MMP), sendo observado que o ZBG 4 (2-amino anilida) faria a interação de modo monodentado com a HDAC, enquanto não seria possível o encaixe no sítio catalítico da MMP. Conclui-se, portanto, que o planejamento proposto permitiu a obtenção de compostos promissores como antitumorais, e que a substituição do ácido hidroxâmico por outros ZBG fornece moléculas ativas frente a células tumorais. Entretanto, a avaliação biológica frente à MMP e HDAC é necessária para confirmar o mecanismo de ação proposto

Inhibition of specific targets such as matrix metalloproteinase (MMP) and histone deacetylase (HDAC) is extensively studied regarding arrest cancer growth. Particularly, concomitant inhibition of MMP and HDAC is effective against solid and hematologic tumors. Both targets have an ion Zn2+ at their catalytic site, which is essential for respective enzymatic activity. High affinity of known MMP and HDAC inhibitors is mainly provided by a potent zinc binding group (ZBG). Hydroxamic acid is the most potent ZBG currently known; however, it presents low pharmacokinetics stability, which results in its ineffectiveness and genotoxicity along clinical trial. So, the aim of this work comprised the design, synthesis, molecular modeling and biological evaluation of novel potential non-hydroxamate dual HDAC/ MMP inhibitors. Compounds were designed by molecular hybridation, employing scaffolds from HDAC and MMP inhibitors, which provided arylsulfonamides with variation about the ZBG type and its respective relative position in the general structure. Seven compounds were synthesized, in two to three reaction steps, through methods that comprise sulfonilation and coupling with condensing agents, using para and meta-aminobenzoic esters as starting material. Compounds showed global yields around 25-55 % and were characterized by 1H and 13C NMR, LC/MS, HPLC and melting point. Compounds were evaluated about their cytotoxicity against HOG (oligodendroma) and T98G (glioblastoma) cells, which 6a, with ZBG 2-aminobenzamide, was the most promising molecules, presenting activity against both cell lines at nM range. Coordination assays with Fe2+ proved the chelating capacity of hydroxamate analogues as well as the cytotoxic compounds, 4a and 4b (ZBG-2, salicylal-hydrazone), which was not observed about 6a. Molecular docking allowed to suggest an interaction model for all proposed ZBG with the respective targets (MMP and HDAC), showing that (ZBG-4) 2-aminobenzamide interacts with HDAC by monodentate way, but does not docks at MMP catalytic site. We conclude that the proposed design allowed obtaining promising compounds as antitumors agents, and the replacement of hydroxamic acid by other ZBG provide active molecules against tumor cells. However, biological evaluation against MMP and HDAC is necessary to confirm the proposed action mechanism

Structure-activity relationships of HDAC8 inhibitors: Non-hydroxamates as anticancer agents.

Histone deacetylase inhibitors (HDACIs) have a paramount importance in the acetylation process of histone and non-histone proteins that are crucial players in the cellular epigenetic modifications. HDACIs exert effective antiproliferation through DNA repairing, cell cycle arrest, apoptosis induction and alteration of genetic expression. HDAC8 is one of the crucial HDACs, affects the epigenetic gene silencing process and cancer progression. Hence, HDAC8 is one of the key cancer targets among class I HDACs that may be effectively blocked as a benchmark therapy to combat malignancy. In the current review, a special emphasis has been given for the non-hydroxamate type of HDAC8 inhibitors. It may provide some fruitful structural information to design newer better active candidates to fight against target specific malignancies in future.