ABSTRACT
The mammalian sirtuin family, consisting of SIRT1–SIRT7, plays a vital role in various biological processes, including cancer, diabetes, neurodegeneration, cardiovascular disease, cellular metabolism, and cellular homeostasis maintenance. Due to their involvement in these biological processes, modulating sirtuin activity seems promising to impact immune- and aging-related diseases, as well as cancer pathways. However, more understanding is required regarding the safety and efficacy of sirtuin-targeted therapies due to the complex regulatory mechanisms that govern their activity, particularly in the context of multiple targets. In this study, the interaction landscape of the sirtuin family was analyzed using a systems biology approach. A sirtuin protein-protein interaction network was built using the Cytoscape platform and analyzed using the NetworkAnalyzer and stringApp plugins. The result revealed the sirtuin family's association with numerous proteins that play diverse roles, suggesting a complex interplay between sirtuins and other proteins. Based on network topological and functional analysis, SIRT1 was identified as the most prominent among sirtuin family members, demonstrating that 25 of its protein partners are involved in cancer, 22 in innate immune response, and 29 in aging, with some being linked to a combination of two or more pathways. This study lays the foundation for the development of novel therapies that can target sirtuins with precision and efficacy. By illustrating the various interactions among the proteins in the sirtuin family, we have revealed the multifaceted roles of SIRT1 and provided a framework for their possible roles to be precisely understood, manipulated, and translated into therapeutics in the future.
ABSTRACT
@#Introduction: Cancer is one of the main causes of mortality globally and the incidence has been rising over the years. Studies have shown that miRNAs have the potential as cancer biomarkers. The miR-130a has been reported to be upregulated in several types of cancer, which indicate the important roles of miR-130a in cancer development and metastasis. The aim of this study is to identify potential target genes and to predict the regulatory function of miR130a-3p and 5p in cancer. Methods: Three bioinformatics platforms namely miRWalk, the Database for annotations, visualization and integrated discovery (DAVID) Gene Functional Classification Tool and miRanda-miRSVR analysis tools were used to identify possible interaction between miR-130a and its target. Protein-protein interaction (PPI) network for the predicted target genes was then constructed. Results: The analyses have identified nine predicted target genes for miR-130a-3p (RAPGEF4, SOS2, NRP1, RPS6KB1, MET, IL15, ACVR1, RYR2 and ITPR1), and ten for miR-130a-5p (BCL11A, SPOPL, NLK, PPARGC1A, POU4F2, CPEB4, ST18, RSBN1L, ELF5 and ARID4B), that might play an important role in the development of cancer. Findings from this report suggest that miR-130a may involves in controlling cancer related genes; MET, ACVR1 and BCL11A. miR-130a-3p may regulates MET which involves in apoptosis and metastasis, and ACVR1 which involves in metastasis and angiogenesis. miR-130a-5p may regulates BCL11A which involves in apoptosis, proliferation and tumorigenesis. Conclusion: This study has highlighted the molecular interaction of miR-130a with associated genes and pathways, suggesting therapeutic potential of miR130a as personalised targeted therapy for cancer.
ABSTRACT
@#Introduction: OTULIN, OTUB1 and OTUB2 are deubiquitinases, the enzymes responsible for reversing ubiquitination process that occupies key roles in numerous cellular processes. The ubiquitination protein-protein interaction (PPI) network has been extensively explored in order to unravel the complexity of ubiquitin pathway. However, many significant challenges remain to develop a network-based understanding of the ubiquitination complexity including incompleteness of human interactome. Therefore, we aim to construct a pair of yeast two-hybrid (Y2H) vectors using pDEST32/pDEST22 vector system as a preparation for screening OTULIN-, OTUB1- and OTUB2-interacting proteins from human cDNA library, with ultimate aim of expanding the PPI network in human ubiquitome. Methods: OTULIN, OTUB1 and OTUB2 were cloned into entry vector using pCR™8/GW/TOPO® TA Cloning® system and shuttled into pDEST™32 bait vector by LR recombination reaction. To generate Y2H prey library clones, cDNA library was synthesized from HEK293 cells and cloned into donor vector pDONR™222 before transferred into destination vector pDEST™22. Results: DNA sequencing analysis confirmed the correct sequence of OTULIN, OTUB1 and OTUB2 inserts in pDEST32. Meanwhile, generation of cDNA library in pDEST22 produced 5.2 x 106 clones. Randomly picked pDEST22-cDNA clones showed that the recombination rate was 83% and gel electrophoresis indicated that the inserts length ranged from 0.45 to 3.4 kb. Conclusion: OTULIN, OTUB1, OTUB2 and cDNA library were successfully cloned into Y2H bait and prey vectors. The clones have been transfected into competent yeast Saccharomyces cerevisiae strain MaV203 and Y2H experiment to screen novel OTULIN-, OTUB1- and OTUB2-interacting protein from human cDNA library is underway.