Diabetes and Metabolism Division, Garvan Institute of Medical Research, 384 Victoria Street, Darlinghurst, NSW, 2010, Australia.
Baker Heart and Diabetes Institute, PO Box 6492, Melbourne, Vic, 3004, Australia.
Mol Metab. 2020 Oct;40:101023. doi: 10.1016/j.molmet.2020.101023. Epub 2020 Jun 3.
Investigations of autophagy in β-cells have usually focused on its homeostatic function. More dynamic roles in inhibiting glucose-stimulated insulin secretion (GSIS), potentially involving remodelling of cellular lipids, have been suggested from in vitro studies but not evaluated in vivo.
We employed temporally-regulated deletion of the essential autophagy gene, Atg7, in β-cells. Mice were fed chow or high-fat diets (HFD), in conjunction with deletion of Atg7 for the last 3 weeks (short-term model) or 9 weeks (long-term model). Standard in vivo metabolic phenotyping was undertaken, and 450 lipid species in islets quantified ex vivo using mass spectroscopy (MS). MIN6 cells were also employed for lipidomics and secretory interventions.
β-cell function was impaired by inhibiting autophagy in the longer-term, but conversely improved by 3-week deletion of Atg7, specifically under HFD conditions. This was accompanied by augmented GSIS ex vivo. Surprisingly, the HFD had minimal effect on sphingolipid and neutral lipid species, but modulated >100 phospholipids and ether lipids, and markedly shifted the profile of polyunsaturated fatty acid (PUFA) sidechains from n3 to n6 forms. These changes were partially countered by Atg7 deletion, consistent with an accompanying upregulation of the PUFA elongase enzyme, Elovl5. Loss of Atg7 separately augmented plasmalogens and alkyl lipids, in association with increased expression of Lonp2, a peroxisomal chaperone/protease that facilitates maturation of ether lipid synthetic enzymes. Depletion of PUFAs and ether lipids was also observed in MIN6 cells chronically exposed to oleate (more so than palmitate). GSIS was inhibited by knocking down Dhrs7b, which encodes an enzyme of peroxisomal ether lipid synthesis. Conversely, impaired GSIS due to oleate pre-treatment was selectively reverted by Dhrs7b overexpression.
A detrimental increase in n6:n3 PUFA ratios in ether lipids and phospholipids is revealed as a major response of β-cells to high-fat feeding. This is partially reversed by short-term inhibition of autophagy, which results in compensatory changes in peroxisomal lipid metabolism. The short-term phenotype is linked to improved GSIS, in contrast to the impairment seen with the longer-term inhibition of autophagy. The balance between these positive and negative inputs could help determine whether β-cells adapt or fail in response to obesity.
β 细胞自噬的研究通常集中在其稳态功能上。但在体外研究中提出了其在抑制葡萄糖刺激的胰岛素分泌(GSIS)方面更具动态的作用,可能涉及细胞脂质的重塑,但尚未在体内进行评估。
我们采用了在β细胞中定时调节自噬必需基因 Atg7 的缺失。用标准的体内代谢表型对小鼠进行检测,并用质谱(MS)法对离体胰岛中的 450 种脂质进行定量。还使用 MIN6 细胞进行脂质组学和分泌干预。
在较长时间内抑制自噬会损害β细胞功能,但相反,在 3 周的 Atg7 缺失时,特别是在高脂肪饮食(HFD)条件下,β细胞功能会得到改善。这伴随着体外 GSIS 的增加。令人惊讶的是,HFD 对鞘脂和中性脂质种类的影响很小,但调节了>100 种磷脂和醚脂,显著改变了多不饱和脂肪酸(PUFA)侧链从 n3 到 n6 形式的分布。这些变化部分被 Atg7 缺失所抵消,这与 PUFA 延长酶 Elovl5 的伴随上调相一致。Lonp2 是一种促进醚脂合成酶成熟的过氧化物酶体伴侣/蛋白酶,Atg7 的缺失分别增加了质体和烷基脂质,这与 Lonp2 的表达增加有关。MIN6 细胞长期暴露于油酸(比棕榈酸更明显)时,也观察到 PUFAs 和醚脂的耗竭。通过敲低编码过氧化物醚脂合成酶的 Dhrs7b,抑制了 GSIS。相反,由于油酸预处理导致的 GSIS 受损,通过 Dhrs7b 的过表达选择性地得到了恢复。
β 细胞对高脂肪喂养的主要反应是醚脂和磷脂中 n6:n3 PUFA 比例的有害增加。这部分被短期自噬抑制所逆转,导致过氧化物体脂质代谢的代偿性变化。短期表型与 GSIS 的改善有关,与长期自噬抑制所导致的损害形成对比。这些正性和负性输入之间的平衡可能有助于确定β细胞在肥胖时是适应还是衰竭。
