Man K S Lee1,2,3, Michael J Kraakman1, Dragana Dragoljevic1,3, Nordin M J Hanssen1,2,4,5, Michelle C Flynn1,6, Annas Al-Sharea1, Gopalkrishna Sreejit7, Camilla Bertuzzo-Veiga1,8, Olivia D Cooney1,2, Fatima Baig1, Elizabeth Morriss1, Mark E Cooper2, Emma C Josefsson9,10, Benjamin T Kile11,12, Prabhakara R Nagareddy7, Andrew J Murphy1,6,3,8. 1. Haematopoiesis and Leukocyte Biology, Baker Heart and Diabetes Institute, Melbourne, Australia (M.K.S.L., M.J.K., D.D., N.M.J.H., M.C.F., A.A.-S., C.B.-V., O.D.C., F.B., E.M., A.J.M.). 2. Department of Diabetes (M.K.S.L., N.M.J.H., O.D.C., M.E.C.), Monash University, Melbourne, Australia. 3. Department of Cardiometabolic Health (M.K.S.L., D.D., A.J.M.), University of Melbourne, Australia. 4. Department of Internal Medicine, CARIM, School of Cardiovascular Diseases, Maastricht University, Maastricht, the Netherlands (N.M.J.H.). 5. Amsterdam Diabetes Centrum, Internal and vascular medicine, Amsterdam UMC, AMC, the Netherlands (N.M.J.H.). 6. Department of Immunology (M.C.F., A.J.M.), Monash University, Melbourne, Australia. 7. Division of Cardiac Surgery, Department of Surgery, Ohio State University, Columbus (G.S., P.R.N.). 8. Department of Physiology (C.B.-V., A.J.M.), University of Melbourne, Australia. 9. Department of Medical Biology (E.C.J.), University of Melbourne, Australia. 10. The Walter and Eliza Hall Institute of Medical Research, Parkville, Australia (E.C.J.). 11. Monash Biomedicine Discovery Institute (B.T.K.), Monash University, Melbourne, Australia. 12. Faculty of Health and Medical Sciences, University of Adelaide, Australia (B.T.K.).
Abstract
OBJECTIVE: People with diabetes are at a significantly higher risk of cardiovascular disease, in part, due to accelerated atherosclerosis. Diabetic subjects have increased number of platelets that are activated, more reactive, and respond suboptimally to antiplatelet therapies. We hypothesized that reducing platelet numbers by inducing their premature apoptotic death would decrease atherosclerosis. Approach and Results: This was achieved by targeting the antiapoptotic protein Bcl-xL (B-cell lymphoma-extra large; which is essential for platelet viability) via distinct genetic and pharmacological approaches. In the former, we transplanted bone marrow from mice carrying the Tyr15 to Cys loss of function allele of Bcl-x (known as Bcl-xPlt20) or wild-type littermate controls into atherosclerotic-prone Ldlr+/- mice made diabetic with streptozotocin and fed a Western diet. Reduced Bcl-xL function in hematopoietic cells significantly decreased platelet numbers, exclusive of other hematologic changes. This led to a significant reduction in atherosclerotic lesion formation in Bcl-xPlt20 bone marrow transplanted Ldlr+/- mice. To assess the potential therapeutic relevance of reducing platelets in atherosclerosis, we next targeted Bcl-xL with a pharmacological strategy. This was achieved by low-dose administration of the BH3 (B-cell lymphoma-2 homology domain 3) mimetic, ABT-737 triweekly, in diabetic Apoe-/- mice for the final 6 weeks of a 12-week study. ABT-737 normalized platelet numbers along with platelet and leukocyte activation to that of nondiabetic controls, significantly reducing atherosclerosis while promoting a more stable plaque phenotype. CONCLUSIONS: These studies suggest that selectively reducing circulating platelets, by targeting Bcl-xL to promote platelet apoptosis, can reduce atherosclerosis and lower cardiovascular disease risk in diabetes. Graphic Abstract: A graphic abstract is available for this article.
OBJECTIVE: People with diabetes are at a significantly higher risk of cardiovascular disease, in part, due to accelerated atherosclerosis. Diabetic subjects have increased number of platelets that are activated, more reactive, and respond suboptimally to antiplatelet therapies. We hypothesized that reducing platelet numbers by inducing their premature apoptotic death would decrease atherosclerosis. Approach and Results: This was achieved by targeting the antiapoptotic protein Bcl-xL (B-cell lymphoma-extra large; which is essential for platelet viability) via distinct genetic and pharmacological approaches. In the former, we transplanted bone marrow from mice carrying the Tyr15 to Cys loss of function allele of Bcl-x (known as Bcl-xPlt20) or wild-type littermate controls into atherosclerotic-prone Ldlr+/- mice made diabetic with streptozotocin and fed a Western diet. Reduced Bcl-xL function in hematopoietic cells significantly decreased platelet numbers, exclusive of other hematologic changes. This led to a significant reduction in atherosclerotic lesion formation in Bcl-xPlt20 bone marrow transplanted Ldlr+/- mice. To assess the potential therapeutic relevance of reducing platelets in atherosclerosis, we next targeted Bcl-xL with a pharmacological strategy. This was achieved by low-dose administration of the BH3 (B-cell lymphoma-2 homology domain 3) mimetic, ABT-737 triweekly, in diabetic Apoe-/- mice for the final 6 weeks of a 12-week study. ABT-737 normalized platelet numbers along with platelet and leukocyte activation to that of nondiabetic controls, significantly reducing atherosclerosis while promoting a more stable plaque phenotype. CONCLUSIONS: These studies suggest that selectively reducing circulating platelets, by targeting Bcl-xL to promote platelet apoptosis, can reduce atherosclerosis and lower cardiovascular disease risk in diabetes. Graphic Abstract: A graphic abstract is available for this article.
Entities:
Keywords:
atherosclerosis; bone marrow; cardiovascular disease; leukocyte; mice
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