Wall Remodeling During Luminal Expansion of Mesenteric Arterial Collaterals in the Rat

Unthank, Joseph L.; Fath, Steven W.; Burkhart, Harold M.; Miller, Scott C.; Dalsing, Michael C.

doi:10.1161/01.res.79.5.1015

Cited by 112 publications

(199 citation statements)

References 32 publications

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“…24 In various previous experimental settings, chronic flow increases and flow decreases have been reported to result in outward and inward arterial remodeling, respectively. 3,4,8,10,13,17 The structural diameter changes were observed to lead to a normalization of wall shear stress and to be accompanied by a compensatory change in medial mass, which restores circumferential wall stress. Changes in arterial smooth muscle cell size and number have been suggested to participate in these compensatory or adaptive forms of arterial remodeling in response to altered BF.…”

Section: Discussionmentioning

confidence: 99%

“…[1][2][3][4][5][6][7][8] Arterial structural responses to changes in shear stress operate during physiological adaptations to postnatal development, 9,10 exercise, 11 and pregnancy 12 and in pathological conditions, such as arteriovenous shunting 13 and arterial occlusive disease. 14,15 They have been suggested to be endothelium dependent 16 and to display similarities to acute shear-induced vasodilatation in response to an increase in arterial blood flow (BF).…”

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confidence: 99%

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Altered Flow–Induced Arterial Remodeling in Vimentin-Deficient Mice

Schiffers

Henrion

Boulanger

et al. 2000

ATVB

110

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Abstract-The endothelial cytoskeleton plays a key role in arterial responses to acute changes in shear stress. We evaluated whether the intermediate filament protein vimentin is involved in the structural responses of arteries to chronic changes in blood flow (BF). In wild-type mice (Vϩ/ϩ) and in vimentin-deficient mice (VϪ/Ϫ), the left common carotid artery (LCA) was ligated near its bifurcation, and 4 weeks later, the structures of the occluded and of the contralateral arteries were evaluated and compared with the structures of arteries from sham-operated mice. 3 m 2 for LCA and RCA, respectively). In Vϩ/ϩ, LCA ligation eliminated BF in the occluded vessel (before ligation, 0.35Ϯ0.02 mL/min) and increased BF from 0.34Ϯ0.02 to 0.68Ϯ0.04 mL/min in the RCA. In VϪ/Ϫ, the BF change in the occluded LCA was comparable (from 0.38Ϯ0.05 mL/min to zero-flow rates), but the BF increase in the RCA was less pronounced (from 0.33Ϯ0.02 to 0.50Ϯ0.05 mL/min). In the occluded LCA of Vϩ/ϩ, arterial diameter was markedly reduced (Ϫ162 m), and CSAm was significantly increased (5ϫ10 3 m 2 ), whereas in the high-flow RCA of Vϩ/ϩ, carotid artery diameter and CSAm were not significantly modified. In the occluded LCA of VϪ/Ϫ, arterial diameter was reduced to a lesser extent (Ϫ77 m) and CSAm was increased to a larger extent (10ϫ10 3 m 2 ) than in Vϩ/ϩ. In contrast to Vϩ/ϩ, the high-flow RCA of VϪ/Ϫ displayed a significant increase in diameter (52 m) and a significant increase in CSAm (5ϫ10 3 m 2 ). These observations provide the first direct evidence for a role of the cytoskeleton in flow-induced arterial remodeling.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Altered Flow–Induced Arterial Remodeling in Vimentin-Deficient Mice

Schiffers

Henrion

Boulanger

et al. 2000

ATVB

110

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“…The concept of an arterial homeostatic wall shear stress magnitude (ie, shear stress set point) at which vessels maintain a steady‐state luminal diameter72 arises from Murray's principle of minimum work 73. Outward collateral artery growth is therefore hypothesized to stop once normalization to the shear stress set point has been achieved 2, 3, 4, 5. Premature normalization to the shear stress set point has been a predominant rationalization for the failure of collateral arteries to realize full arteriogenic capacity, frequently reaching only 30% to 40% of the maximal conductance 74.…”

Section: Discussionmentioning

confidence: 99%

“…The resulting increase in shear stress acting on the endothelium initiates a highly coordinated signaling cascade, ultimately resulting in the outward growth of the collateral vessel 1, 2. Outward luminal growth is hypothesized to continue until normalization to the original shear stress level (ie, the shear stress “set point”) has been achieved 2, 3, 4, 5…”

Section: Introductionmentioning

confidence: 99%

DNA Methyltransferase 1–Dependent DNA Hypermethylation Constrains Arteriogenesis by Augmenting Shear Stress Set Point

Heuslein

Gorick

Song

et al. 2017

JAHA

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BackgroundArteriogenesis is initiated by increased shear stress and is thought to continue until shear stress is returned to its original “set point.” However, the molecular mechanism(s) through which shear stress set point is established by endothelial cells (ECs) are largely unstudied. Here, we tested the hypothesis that DNA methyltransferase 1 (DNMT1)–dependent EC DNA methylation affects arteriogenic capacity via adjustments to shear stress set point.Methods and ResultsIn femoral artery ligation–operated C57BL/6 mice, collateral artery segments exposed to increased shear stress without a change in flow direction (ie, nonreversed flow) exhibited global DNA hypermethylation (increased 5‐methylcytosine staining intensity) and constrained arteriogenesis (30% less diameter growth) when compared with segments exposed to both an increase in shear stress and reversed‐flow direction. In vitro, ECs exposed to a flow waveform biomimetic of nonreversed collateral segments in vivo exhibited a 40% increase in DNMT1 expression, genome‐wide hypermethylation of gene promoters, and a DNMT1‐dependent 60% reduction in proarteriogenic monocyte adhesion compared with ECs exposed to a biomimetic reversed‐flow waveform. These results led us to test whether DNMT1 regulates arteriogenic capacity in vivo. In femoral artery ligation–operated mice, DNMT1 inhibition rescued arteriogenic capacity and returned shear stress back to its original set point in nonreversed collateral segments.ConclusionsIncreased shear stress without a change in flow direction initiates arteriogenic growth; however, it also elicits DNMT1‐dependent EC DNA hypermethylation. In turn, this diminishes mechanosensing, augments shear stress set point, and constrains the ultimate arteriogenic capacity of the vessel. This epigenetic effect could impact both endogenous collateralization and treatment of arterial occlusive diseases.

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“…For example, regression of medial thickness may result from the reduction in the levels of angiotensin II or the decrease in wall stress, whereas the widening of the lumen may have resulted from the increase in blood flow associated with the increase in arterial pressure following cessation of therapy. [37][38][39] An additional objective was to determine whether the depressor response or the removal of a trophic factor was the critical component in producing persistent changes in MAP and vascular structure. Two groups of SHR received the same degree of ACE inhibition and therefore a similar reduction in the trophic factor angiotensin II, with one group receiving a diet that was low in sodium.…”

Section: Discussionmentioning

confidence: 99%

Time Course of Vascular Structural Changes During and After Short-Term Antihypertensive Treatment

et al. 2003

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Abstract-The present study characterized the persistent changes (ie, off-treatment) resulting from short-term antihypertensive treatments on mean arterial pressure (MAP) and structurally based vascular resistance. Rats were treated for 14 days with enalapril (30 mg · kg Ϫ1 · d Ϫ1 ) with regular (ENAL, 0.4%) or low salt (ELS, 0.04%) diets, or a triple therapy (Triple: hydralazine 45 mg · kg Ϫ1 · d Ϫ1

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Wall Remodeling During Luminal Expansion of Mesenteric Arterial Collaterals in the Rat

Cited by 112 publications

References 32 publications

Altered Flow–Induced Arterial Remodeling in Vimentin-Deficient Mice

Altered Flow–Induced Arterial Remodeling in Vimentin-Deficient Mice

DNA Methyltransferase 1–Dependent DNA Hypermethylation Constrains Arteriogenesis by Augmenting Shear Stress Set Point

Time Course of Vascular Structural Changes During and After Short-Term Antihypertensive Treatment

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