An In Vitro Cynomolgus Vascular Surrogate System for Preclinical Drug Assessment and Human Translation.

Cole, Banumathi K; Simmers, Michael B; Feaver, Ryan; Qualls, Charles W; Collado, M Sol; Berzin, Erica; Figler, Robert A; Pryor, Andrew W; Lawson, Mark; Mackey, Aaron; Manka, David; Wamhoff, Brian R; Turk, James R; Blackman, Brett R

Cole, Banumathi K; Simmers, Michael B; Feaver, Ryan; Qualls, Charles W; Collado, M Sol; Berzin, Erica; Figler, Robert A; Pryor, Andrew W; Lawson, Mark; Mackey, Aaron; Manka, David; Wamhoff, Brian R; Turk, James R; Blackman, Brett R.

Affiliation

Cole BK; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Simmers MB; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Feaver R; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Qualls CW; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Collado MS; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Berzin E; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Figler RA; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Pryor AW; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Lawson M; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Mackey A; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Manka D; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Wamhoff BR; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Turk JR; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.
Blackman BR; From the NASH Program (B.K.C., R.F.), Technology and Research Platforms (M.B.S.), Rare Diseases Program (M.S.C.), Vascular Program (E.B., D.M.), Pharmacology (R.A.F.), Cell Culture (A.W.P.), Computational Biology (M.L., A.M.), VP of Research and Development (B.R.W.), and Chief Scientific Officer (B.

Arterioscler Thromb Vasc Biol ; 35(10): 2185-95, 2015 Oct.

Article in En | MEDLINE | ID: mdl-26293464

ABSTRACT

ABSTRACT

OBJECTIVES:

The predictive value of animal and in vitro systems for drug development is limited, particularly for nonhuman primate studies as it is difficult to deduce the drug mechanism of action. We describe the development of an in vitro cynomolgus macaque vascular system that reflects the in vivo biology of healthy, atheroprone, or advanced inflammatory cardiovascular disease conditions. APPROACH AND

RESULTS:

We compare the responses of the in vitro human and cynomolgus vascular systems to 4 statins. Although statins exert beneficial pleiotropic effects on the human vasculature, the mechanism of action is difficult to investigate at the tissue level. Using RNA sequencing, we quantified the response to statins and report that most statins significantly increased the expression of genes that promote vascular health while suppressing inflammatory cytokine gene expression. Applying computational pathway analytics, we identified statin-regulated biological themes, independent of cholesterol lowering, that provide mechanisms for off-target effects, including thrombosis, cell cycle regulation, glycogen metabolism, and ethanol degradation.

CONCLUSIONS:

The cynomolgus vascular system described herein mimics the baseline and inflammatory regional biology of the human vasculature, including statin responsiveness, and provides mechanistic insight not achievable in vivo.

Subject(s)

Cardiovascular Diseases/drug therapy; Drug Evaluation, Preclinical/methods; Hydroxymethylglutaryl-CoA Reductase Inhibitors/pharmacology; Lipoproteins, LDL/drug effects; Animals; Cardiovascular Diseases/blood; Cells, Cultured; Endothelial Cells/drug effects; Humans; In Vitro Techniques; Lipoproteins, LDL/metabolism; Macaca fascicularis; Models, Cardiovascular; Muscle, Smooth, Vascular/cytology; Muscle, Smooth, Vascular/drug effects; Species Specificity

Key words

Macaca fascicularis; cell cycle; hemodynamics; hydroxymethylglutaryl-CoA reductase inhibitors; inflammation

Fulltext

Add to My VHL

XML

PubMed Links

Search on Google

Full text: 1 Collection: 01-internacional Database: MEDLINE Main subject: Cardiovascular Diseases / Hydroxymethylglutaryl-CoA Reductase Inhibitors / Drug Evaluation, Preclinical / Lipoproteins, LDL Type of study: Prognostic_studies Limits: Animals / Humans Language: En Journal: Arterioscler Thromb Vasc Biol Journal subject: ANGIOLOGIA Year: 2015 Document type: Article

Fulltext

Add to My VHL

XML

PubMed Links

Search on Google