Repression of LXRα by a novel member of additional sex comb-like family, ASXL3

Transcriptome analysis of cardiac endothelial cells after myocardial infarction reveals temporal changes and long-term deficits

Endothelial cells (ECs) have essential roles in cardiac tissue repair after myocardial infarction (MI). To establish stage-specific and long-term effects of the ischemic injury on cardiac ECs, we analyzed their transcriptome at landmark time points after MI in mice. We found that early EC response at Day 2 post-MI centered on metabolic changes, acquisition of proinflammatory phenotypes, initiation of the S phase of cell cycle, and activation of stress-response pathways, followed by progression to mitosis (M/G2 phase) and acquisition of proangiogenic and mesenchymal properties during scar formation at Day 7. In contrast, genes involved in vascular physiology and maintenance of vascular tone were suppressed. Importantly, ECs did not return to pre-injury phenotypes after repair has been completed but maintained inflammatory, fibrotic and thrombotic characteristics and lost circadian rhythmicity. We discovered that the highest induced transcript is the mammalian-specific Sh2d5 gene that promoted migration and invasion of ECs through Rac1 GTPase. Our results revealed a synchronized, temporal activation of disease phenotypes, metabolic pathways, and proliferation in quiescent ECs after MI, indicating that precisely-timed interventions are necessary to optimize cardiac tissue repair and improve outcomes. Furthermore, long-term effects of acute ischemic injury on ECs may contribute to vascular dysfunction and development of heart failure.

Compound heterozygous mutation of the ASXL3 gene causes autosomal recessive congenital heart disease

To explore mutations in the additional sex combs-like 3 (ASXL3) gene in two Chinese families with congenital heart disease (CHD). Whole-exome sequencing (WES) was used to reveal a novel compound heterozygous mutation in the ASXL3 gene that was associated with CHD. Sanger sequencing of a further 122 CHD patients was used to determine an additional compound heterozygous mutation in the ASXL3 gene. Cell apoptosis was examined by MTS assay and flow cytometry. The cardiac structure was identified via hematoxylin-eosin (HE), Masson's trichrome, and ultrasound scanning. RNA sequencing was performed to identify a series of differentially expressed mRNAs. The mRNA and protein expressions were identified by quantitative real-time PCR and western blotting, respectively. A compound heterozygous mutation c.2168C > G (p.Pro723Arg) and c.5449C > G (p.Pro1817Ala) in the ASXL3 gene associated with CHD was identified. Overexpression of this compound heterozygous mutation in HL-1 cells resulted in increased apoptosis and reduced cell viability. Moreover, it affected cardiac structure and fibrosis in mice. There were 126 downregulated mRNAs and 117 upregulated mRNAs between the ASXL3 compound heterozygous mutation c.2168C > G (p.Pro723Arg) and c.5449C > G (p.Pro1817Ala) mice and wild-type mice. Ezh2, Slc6a4, and Socs3, which could interact with ASXL3 through proteins, were all upregulated. Another compound heterozygous mutation c.3526C > T (p.Arg1176Trp) and c.4643A > G (p.Asp1548Gly) in the ASXL3 gene was identified by screening a further 122 patients with CHD. The ASXL3 gene is important in cardiac development and may exert this influence by affecting the expression of mRNAs associated with cell apoptosis and cell proliferation.

Role of Asxl1 in kidney podocyte development via its interaction with Wtip

Additional sex comb-like (ASXL) family proteins are chromatin factors that function in transcriptional activation and repression. However, the underlying mechanisms and biological implications have not been well established. Here, we identified a LIM domain-containing protein, Wilms tumor 1-interacting protein (WTIP), as an ASXL1-binding partner. Biochemical assays confirmed an interaction between the murine homologs Asxl1 and Wtip. The suppressive role of Wtip in WT1 function and the expression of Wtip in kidney podocytes prompted us to investigate the role of Asxl1 in the kidney using Asxl1-null mice. In homozygous Asxl1(-/-) embryos, defects in kidney size and glomerular podocyte morphology were observed. Furthermore, up-regulation of Wt1/Wtip target genes was observed in the kidneys of Asxl1-null embryos. Overall, these findings implicate Asxl1 in the maintenance of podocyte structure via its association with Wtip and in the regulation of WT1 signaling during early kidney development.