Nuclear membrane ruptures underlie the vascular pathology in a mouse model of Hutchinson-Gilford progeria syndrome
Paul H. Kim, Natalie Y. Chen, Patrick J. Heizer, Yiping Tu, Thomas A. Weston, Jared L.-C. Fong, Navjot Kaur Gill, Amy C. Rowat, Stephen G. Young, Loren G. Fong
Paul H. Kim, Natalie Y. Chen, Patrick J. Heizer, Yiping Tu, Thomas A. Weston, Jared L.-C. Fong, Navjot Kaur Gill, Amy C. Rowat, Stephen G. Young, Loren G. Fong
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Research Article Vascular biology

Nuclear membrane ruptures underlie the vascular pathology in a mouse model of Hutchinson-Gilford progeria syndrome

Abstract

The mutant nuclear lamin protein (progerin) produced in Hutchinson-Gilford progeria syndrome (HGPS) results in loss of arterial smooth muscle cells (SMCs), but the mechanism has been unclear. We found that progerin induces repetitive nuclear membrane (NM) ruptures, DNA damage, and cell death in cultured SMCs. Reducing lamin B1 expression and exposing cells to mechanical stress — to mirror conditions in the aorta — triggered more frequent NM ruptures. Increasing lamin B1 protein levels had the opposite effect, reducing NM ruptures and improving cell survival. Remarkably, raising lamin B1 levels increased nuclear compliance in cells and was able to offset the increased nuclear stiffness caused by progerin. In mice, lamin B1 expression in aortic SMCs is normally very low, and in mice with a targeted HGPS mutation (LmnaG609G), levels of lamin B1 decrease further with age while progerin levels increase. Those observations suggest that NM ruptures might occur in aortic SMCs in vivo. Indeed, studies in LmnaG609G mice identified NM ruptures in aortic SMCs, along with ultrastructural abnormalities in the cell nucleus that preceded SMC loss. Our studies identify NM ruptures in SMCs as likely causes of vascular pathology in HGPS.

Authors

Paul H. Kim, Natalie Y. Chen, Patrick J. Heizer, Yiping Tu, Thomas A. Weston, Jared L.-C. Fong, Navjot Kaur Gill, Amy C. Rowat, Stephen G. Young, Loren G. Fong

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Figure 2

Impact of lamin B1, mechanical stress, and progerin farnesylation on NM ruptures.

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Impact of lamin B1, mechanical stress, and progerin farnesylation on NM ...
(A) Bar graph comparing the effects of prelamin A (PreA), progerin (Prog), lamin B1 knockdown (B1 KD), and nf-Prog on NM ruptures in static (white bars) and stretched (black bars) SMCs (mean ± SEM, n = 5 experiments). Differences were compared with static SMCs expressing prelamin A by 2-way ANOVA (*P < 0.005, **P < 0.0001). The total numbers of cells examined are shown in parentheses above each bar. (B) Bar graph showing transcript levels for genes involved in NM repair (mean ± SEM, n = 3 experiments; Student’s t test, all nonsignificant). (C) Confocal fluorescence microscopy images showing SMCs expressing Nuc-RFP (red) and either GFP-KASH2ext (green) or GFP-KASH2 (green). Scale bar: 20 μm. (DF) Characterization of NM ruptures in live PreA-SMCs and Prog-SMCs expressing KASH2ext (white bars) or KASH2 (blue bars). Bar graphs show the percentage of cells with a NM rupture; the number of NM ruptures per cell; and the percentage of cells with a NM rupture that die (mean ± SEM, n = 3 experiments; Student’s t test, *P < 0.01, **P < 0.005). (G) Confocal fluorescence microscopy images showing increased phosphorylated-STING (p-STING; green) in Progerin-SMCs. SMCs were examined in both static (left) and stretched (right) conditions. PreA-SMCs were included as a control. Lap2β staining is shown in red. Scale bar: 20 μm. (H) Bar graph showing the percentage of cells staining positive for p-STING in PreA-SMCs (white bars) and Prog-SMCs (black bars) in static and stretched conditions in a representative experiment. The ratios above each bar show the number of cells positive for p-STING over the total number of cells assessed.