Aristolactam BIII, a naturally derived DYRK1A inhibitor, rescues Down syndrome-related phenotypes.

BACKGROUND: Dual-specificity tyrosine phosphorylation-regulated kinase 1A (DYRK1A) is a significant pathogenic factor in Down syndrome (DS), wherein DYRK1A is overexpressed by 1.5-fold because of trisomy of human chromosome 21. Thus, DYRK1A inhibition is considered a therapeutic strategy to modify the disease. PURPOSE: This study aims to identify a novel DYRK1A inhibitor and validate its therapeutic potential in DS-related pathological conditions. STUDY DESIGN: In order to identify a novel DYRK1A inhibitor, we carried out two-step screening: a structure-based virtual screening of > 300,000 chemical library (first step) and cell-based nuclear factor of activated T-cells (NFAT)-response element (RE) promoter assay (second step). Primary hits were evaluated for their DYRK1A inhibitory activity using in vitro kinase assay and Tau phosphorylation in mammalian cells. Confirmed hit was further evaluated in pathological conditions including DYRK1A-overexpressing fibroblasts, flies, and mice. RESULTS: We identified aristolactam BIII, a natural product derived from herbal plants, as a novel DYRK1A inhibitor. It potently inhibited the kinase activity of DYRK1A in vitro (IC50 = 9.67 nM) and effectively suppressed DYRK1A-mediated hyperphosphorylation of Tau in mammalian cells. Aristolactam BIII rescued the proliferative defects of DYRK1A transgenic (TG) mouse-derived fibroblasts and neurological and phenotypic defects of DS-like Drosophila models. Oral administration of aristolactam BIII acutely suppressed Tau hyperphosphorylation in the brain of DYRK1A TG mice. In the open field test, aristolactam BIII significantly ameliorated the exploratory behavioral deficit of DYRK1A TG mice. CONCLUSION: Our work revealed that aristolactam BIII as a novel DYRK1A inhibitor rescues DS phenotypes in cells and in vivo and suggested its therapeutic potential for the treatment of DYRK1A-related diseases.

Improvement of spinal muscular atrophy via correction of the SMN2 splicing defect by Brucea javanica (L.) Merr. extract and Bruceine D.

BACKGROUND: Spinal muscular atrophy (SMA) is a rare neuromuscular disease and a leading genetic cause of infant mortality. SMA is caused primarily by the deletion of the survival motor neuron 1 (SMN1) gene, which leaves the duplicate gene SMN2 as the sole source of SMN protein. The splicing defect (exon 7 skipping) of SMN2 leads to an insufficient amount of SMN protein. Therefore, correcting this SMN2 splicing defect is considered to be a promising approach for the treatment of SMA. PURPOSE: This study aimed to identify active compounds and extracts from plant resources to rescue SMA phenotypes through the correction of SMN2 splicing. STUDY DESIGN: Of available plant resources, candidates with SMA-related traditional medicine information were selected for screening using a robust luciferase-based SMN2 splicing reporter. Primary hits were further evaluated for their ability to correct the splicing defect and resultant increase of SMN activity in SMA patient-derived fibroblasts. Confirmed hits were finally tested to determine the beneficial effects on the severe Δ7 SMA mouse. METHODS: SMN2 splicing was analyzed using a luciferase-based SMN2 splicing reporter and subsequent RT-PCR of SMN2 mRNAs. SMA phenotypes were evaluated by the survival, body weights, and righting reflex of Δ7 SMA mice. RESULTS: In a screen of 492 selected plant extracts, we found that Brucea javanica extract and its major constituent Bruceine D have SMN2 splicing-correcting activity. Their ability to correct the splicing defect and the resulting increased SMN activity were further confirmed in SMA fibroblasts. Importantly, both B. javanica and Bruceine D noticeably improved the phenotypic defects, especially muscle function, in SMA mice. Reduced expression of heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1) contributed to the correction of splicing by B. javanica. CONCLUSION: Our work revealed that B. javanica and Bruceine D correct the SMN2 splicing defect and improve the symptoms of SMA in mice. These resources will provide another possibility for development of a plant-derived SMA drug candidate.