Autophagy modulates the stability of Wee1 and cell cycle G2/M transition

Hepatic HSD17B6 is dispensable for diet-induced fatty liver disease in mice

Metabolic dysfunction-associated fatty liver disease (MAFLD) affects up to a third of the global population, which causes huge both clinical and economic burdens. However, its therapeutic strategy is still limited. Steroid dysregulation plays a pivotal role in the homeostasis of lipid metabolism. 17-beta-hydroxysteroid dehydrogenase type 6 (HSD17B6)-one member of 17β-HSDs, encoded by the gene Hsd17b6, catalyzes the synthesis of androsterone and estrone-steroid hormones. However, whether the manipulation of HSD17B6 could ameliorate diet-induced fatty liver disease remains unknown. Here, we found that the expression of Hsd17b6 is enriched in the liver in both humans and mice. The data of single-cell RNA-seq suggests that Hsd17b6 appears to be exclusively expressed in hepatocytes-the parenchymal cells of the liver. Furthermore, the hepatic expression of Hsd17b6 is correlated with fatty liver disease. A mouse model with Hsd17b6 deletion in the liver (HLKO) is successfully generated via the administration of AAV8 expressing Cre recombinase (driven by TBG-a liver-specific promoter) and sgRNAs of Hsd17b6 to Cre-dependent Cas9 mice. Control and HLKO mice were challenged with the high-fat choline-deficient diet-a diet widely used for the model generation of fatty liver disease. Interestingly, the HLKO liver shows a special proteome signature, with the altered proteins enriched in the Golgi apparatus. However, the deletion of Hsd17b6 does not affect fatty liver disease in terms of fat accumulation, inflammation, and hepatic fibrosis. Taken together, our study suggests that the expression of Hsd17b6 is enriched in the liver and correlated with fatty liver disease but its hepatic deletion does not affect diet-induced fatty liver disease.

Evaluation of the role of hepatic Gstm4 in diet-induced obesity and dyslipidemia

Obesity and its related diseases continue to rise worldwide, necessitating further investigation to develop new therapeutic strategies. The dysregulation of redox homeostasis is tightly associated with metabolic diseases. Glutathione, an antioxidant, acts as a cofactor for antioxidant and detoxification enzymes such as glutathione S-transferases (GSTs)-a superfamily including Gstm4. So far, the physiological role of Gstm4 remains largely unknown. Human genetics is a powerful tool to discover novel therapeutic targets for metabolic diseases. The single nucleotide polymorphism rs650985, located within the sixth intron of the human gene Gstm4, was associated with plasma lipids, indicating that targeting Gstm4 might intervene in the progression of dyslipidemia. Furthermore, we found that Gstm4 is highly expressed in the liver and enriched in hepatocytes-the parenchymal cells of the liver. We established the mouse model with the hepatic deletion of Gstm4 and found that this mouse model did not present altered body weight, serum lipid profile, or liver fat content in the context of chow or high-fat high cholesterol diet feeding, indicating that hepatic Gstm4 is dispensable for diet-induced obesity and dyslipidemia. Further analysis revealed that hepatic deletion of Gstm4 upregulates the level of protein but not mRNA of Npc1l1-a critical protein mediating cholesterol uptake, suggesting that there might be a link between Gstm4 and lipid metabolic diseases in certain contexts.

Blockage of TMEM189 induces G2/M arrest and inhibits the growth of breast tumors

Cancer is the major cause of premature death in humans worldwide, demanding more efficient therapeutics. Aberrant cell proliferation resulting from the loss of cell cycle regulation is the major hallmark of cancer, so targeting cell cycle is a promising strategy to combat cancer. However, the molecular mechanism underlying the dysregulation of cell cycle of cancer cells remains poorly understood. TMEM189, a newly identified protein, plays roles in the biosynthesis of ethanolamine plasmalogen and the regulation of autophagy. Here, we demonstrated that the expression level of TMEM189 was negatively correlated with the survival rate of the cancer patients. TMEM189 deficiency significantly suppresses the cancer cell proliferation and migration, and causes cell cycle G2/M arrest both in vitro and in vivo. Furthermore, TMEM189 depletion suppressed the growth of breast tumors in vivo. Taken together, our work indicated that TMEM189 promotes cancer progression by regulating cell cycle G2/M transition, suggesting that it is a promising target in cancer therapy.

Fatty liver disease protective MTARC1 p.A165T variant reduces the protein stability of MTARC1

Non-alcoholic fatty liver disease (NAFLD) is one of the most common causes of liver disease worldwide. MTARC1, encoded by the MTARC1 gene, is a mitochondrial outer membrane-anchored enzyme. Interestingly, the MTARC1 p.A165T (rs2642438) variant is associated with a decreased risk of NAFLD, indicating that MTARC1 might be an effective target. It has been reported that the rs2642438 variant does not have altered enzymatic activity so we reasoned that this variation may affect MTARC1 stability. In this study, MTARC1 mutants were generated and stability was assessed using a protein stability reporter system both in vitro and in vivo. We found that the MTARC1 p.A165T variant has dramatically reduced the stability of MTARC1, as assessed in several cell lines. In mice, the MTARC1 A168T mutant, the equivalent of human MTARC1 A165T, had diminished stability in mouse liver. Additionally, several MTARC1 A165 mutants, including A165S, A165 N, A165V, A165G, and A165D, had dramatically decreased stability as well, suggesting that the alanine residue of MTARC1 165 site is essential for MTARC1 protein stability. Collectively, our data indicates that the MTARC1 p.A165T variant (rs2642438) leads to reduced stability of MTARC1. Given that carriers of rs2642438 show a decreased risk of NAFLD, the findings herein support the notion that MTARC1 inhibition may be a therapeutic target to combat NAFLD.

Dormant cancer cells and polyploid giant cancer cells: The roots of cancer recurrence and metastasis

Tumour cell dormancy is critical for metastasis and resistance to chemoradiotherapy. Polyploid giant cancer cells (PGCCs) with giant or multiple nuclei and high DNA content have the properties of cancer stem cell and single PGCCs can individually generate tumours in immunodeficient mice. PGCCs represent a dormant form of cancer cells that survive harsh tumour conditions and contribute to tumour recurrence. Hypoxic mimics, chemotherapeutics, radiation and cytotoxic traditional Chinese medicines can induce PGCCs formation through endoreduplication and/or cell fusion. After incubation, dormant PGCCs can recover from the treatment and produce daughter cells with strong proliferative, migratory and invasive abilities via asymmetric cell division. Additionally, PGCCs can resist hypoxia or chemical stress and have a distinct protein signature that involves chromatin remodelling and cell cycle regulation. Dormant PGCCs form the cellular basis for therapeutic resistance, metastatic cascade and disease recurrence. This review summarises regulatory mechanisms governing dormant cancer cells entry and exit of dormancy, which may be used by PGCCs, and potential therapeutic strategies for targeting PGCCs.