Department of Pathology, Anatomy & Cell Biology, Thomas Jefferson University, Philadelphia, PA, USA.
Cole Eye Institute, Cleveland Clinic, Cleveland, OH, USA.
Exp Eye Res. 2018 Jul;172:45-53. doi: 10.1016/j.exer.2018.03.021. Epub 2018 Mar 28.
The primary energy substrate of the lens is glucose and uptake of glucose from the aqueous humor is dependent on glucose transporters. GLUT1, the facilitated glucose transporter encoded by Slc2a1 is expressed in the epithelium of bovine, human and rat lenses. In the current study, we examined the expression of GLUT1 in the mouse lens and determined its role in maintaining lens transparency by studying effects of postnatal deletion of Slc2a1. In situ hybridization and immunofluorescence labeling were used to determine the expression and subcellular distribution of GLUT1 in the lens. Slc2a1 was knocked out of the lens epithelium by crossing transgenic mice expressing Cre recombinase under control of the GFAP promoter with Slc2a1 mice to generate Slc2a1;GFAP-Cre (LensΔGlut1) mice. LensΔGlut1 mice developed visible lens opacities by around 3 months of age, which corresponded temporally with the total loss of detectable GLUT1 expression in the lens. Spectral domain optical coherence tomography (SD-OCT) imaging was used to monitor the formation of cataracts over time. SD-OCT imaging revealed that small nuclear cataracts were first apparent in the lenses of LensΔGlut1 mice beginning at about 2.7 months of age. Longitudinal SD-OCT imaging of LensΔGlut1 mice revealed disruption of mature secondary fiber cells after 3 months of age. Histological sections of eyes from LensΔGlut1 mice confirmed the disruption of the secondary fiber cells. The structural changes were most pronounced in fiber cells that had lost their organelles. In contrast, the histology of the lens epithelium in these mice appeared normal. Lactate and ATP were measured in lenses from LensΔGlut1 and control mice at 2 and 3 months of age. At 2 months of age, when GLUT1 was still detectable in the lens epithelium, albeit at low levels, the amount of lactate and ATP were not significantly different from controls. However, in lenses isolated from 3-month-old LensΔGlut1 mice, when GLUT1 was no longer detectable, levels of lactate and ATP were 50% lower than controls. Our findings demonstrate that in vivo, the transparency of mature lens fiber cells was dependent on glycolysis for ATP and the loss of GLUT1 transporters led to cataract formation. In contrast, lens epithelium and cortical fiber cells have mitochondria and could utilize other substrates to support their anabolic and catabolic needs.
晶状体的主要能量底物是葡萄糖,葡萄糖从房水的摄取依赖于葡萄糖转运蛋白。GLUT1,即 Slc2a1 编码的易化葡萄糖转运蛋白,在牛、人和大鼠晶状体的上皮细胞中表达。在本研究中,我们研究了 Slc2a1 缺失对晶状体透明性的影响,以确定其在维持晶状体透明性中的作用。通过使用原位杂交和免疫荧光标记来确定 GLUT1 在晶状体中的表达和亚细胞分布。通过将表达 Cre 重组酶的转基因小鼠与 Slc2a1 小鼠杂交,使 GFAP 启动子控制的 Cre 重组酶在晶状体上皮细胞中特异性敲除 Slc2a1,从而产生 Slc2a1;GFAP-Cre (LensΔGlut1) 小鼠。LensΔGlut1 小鼠在大约 3 月龄时出现明显的晶状体混浊,这与晶状体中可检测到的 GLUT1 表达完全丧失时间上一致。光谱域光学相干断层扫描 (SD-OCT) 成像用于随时间监测白内障的形成。SD-OCT 成像显示,大约 2.7 月龄时,LensΔGlut1 小鼠的晶状体中首先出现小核白内障。LensΔGlut1 小鼠的纵向 SD-OCT 成像显示,3 月龄后成熟的次级纤维细胞遭到破坏。来自 LensΔGlut1 小鼠眼睛的组织学切片证实了次级纤维细胞的破坏。在失去细胞器的纤维细胞中,结构变化最为明显。相比之下,这些小鼠的晶状体上皮组织学看起来正常。在 2 和 3 月龄时,测量 LensΔGlut1 和对照小鼠晶状体中的乳酸和 ATP。在 2 月龄时,尽管 GLUT1 在晶状体上皮细胞中仍可检测到,但水平较低,乳酸和 ATP 的量与对照组无显著差异。然而,在从 3 月龄的 LensΔGlut1 小鼠中分离的晶状体中,当 GLUT1 不再可检测到时,乳酸和 ATP 的水平比对照组低 50%。我们的发现表明,在体内,成熟晶状体纤维细胞的透明性依赖于糖酵解产生的 ATP,而 GLUT1 转运蛋白的缺失导致白内障形成。相比之下,晶状体上皮细胞和皮质纤维细胞具有线粒体,可利用其他底物来满足其合成代谢和分解代谢的需求。
