Mitochondrial population structure and post-glacial dispersal of longnose sucker Catostomus catostomus in Labrador, Canada: evidence for multiple refugial origins and limited ongoing gene flow.

Two hundred and eighty-seven longnose sucker Catostomus catostomus were collected from 14 lakes in Labrador, 52 from three lakes in Ontario, 43 from two lakes in British Columbia and 32 from a lake in Yukon; a total of 414 in all. The resulting 34 haplotypes (20 in Labrador) contained moderate haplotypic diversity (h = 0·657) and relatively low nucleotide diversity (π = 3·730 × 10(-3) . Mean ϕST (0·453, P < 0·05) over all populations revealed distinct genetic structuring among C. catostomus populations across Canada, based on province, which was validated by the analysis and spatial analysis of molecular variance (c. 80% variation between provinces). These results probably reflect the historical imprint of recolonization from different refugia and possibly indicate limited ongoing gene flow within provinces. A haplotype network revealed one major and two minor clades within Labrador that were assigned to the Atlantic, Beringian and Mississippian refugia, respectively, with tests of neutrality and mismatch distribution indicative of a recent population expansion in Labrador, dated between c. 3500 and 8300 years ago.

Effects of anastomotic angle on vascular tissue responses at end-to-side arterial grafts.

OBJECTIVE: Hemodynamics has been implicated in the late failure of arterial bypass grafts, which frequently occurs at the distal anastomosis site. This study was designed to assess the relationship between local hemodynamics and pathologic responses of the distal anastomosis by manipulation of the angle of anastomosis of the graft, a major determinant of local hemodynamics. METHODS: End-to-side anastomoses of the right carotid to the left carotid arteries of rabbits were performed at anastomotic angles of less than 10 degrees (acute), 45 degrees (intermediate), or 90 degrees (right angle), and then the upstream left carotid arteries were ligated to simulate pathologic occlusion. We examined tissue responses on the wall of the recipient vessel opposite the anastomosis site (the bed), where unusual hemodynamic forces are imposed. RESULTS: Three months after surgery, intimal thickening was observed on the upstream portion of the acute, and more rarely, the intermediate anastomoses only. Medial thinning caused by loss of cells and matrix, and an aneurysm-like dilation, was observed in the right angle and some intermediate anastomoses, but not in the acute anastomoses. En face confocal microscopy at 3 weeks after surgery revealed severe disruption of the internal elastic lamina in all anastomotic models. Zymography and Western immunoblotting demonstrated gelatinolytic activity, caused by expression and activation of MMP-2, that was lowest in the acute anastomoses, higher in the intermediate anastomoses, and highest in the right-angle anastomoses. CONCLUSIONS: We infer that very different pathologic changes to the vessel wall are elicited when local hemodynamics is manipulated by altering the anastomotic branch angle.

Morphologic responses of endothelium to shear stress: reorganization of the adherens junction.

Shear stresses induce marked morphologic responses from endothelium which include alterations to cell shape and orientation and changes to cytoskeletal organization. These morphologic changes necessitate remodeling of cell-cell adhesion complexes that are important to control of endothelial cell physiology. Reorganization of endothelial adherens junctions has been characterized, and there are some data that pertain to the signaling pathways that regulate this reorganization. Shear-induced activation of Src, mitogen-activated protein (MAP) kinase (ERK1/2 and p38), and PI 3'-kinase pathways are important candidate pathways, and there is evidence for a role for the Rho GTPases. Very little is known concerning shear-dependence of other junctional complexes, but available data indicates a high degree of shear sensitivity. Given the continuous changes in hemodynamics which occur physiologically in vivo, sensitivity of endothelial cell-cell adhesion complexes to shear will likely prove important to vascular pathophysiology.

Apoptosis during cardiovascular development.

Morphogenesis and developmental remodeling of cardiovascular tissues involve coordinated regulation of cell proliferation and apoptosis. In the heart, clear evidence points toward focal apoptosis as a contributor to development of the embryonic outflow tract, cardiac valves, conducting system, and the developing coronary vasculature. Apoptosis in the heart is likely regulated by survival and death signals that are also present in many other tissues. Cell type-specific regulation may be superimposed on general cell death/survival machinery through tissue-specific transcriptional pathways. In the vasculature, apoptosis almost certainly contributes to developmental vessel regression, and it is of proven importance in remodeling of arterial structure in response to local changes in hemodynamics. Physical forces, growth factors, and extracellular matrix drive vascular cell survival pathways, and considerable evidence points to local nitric oxide production as an important but complex regulator of vascular cell death. In both the heart and vasculature, progress has been impeded by inadequate information concerning the incidence of apoptosis, its relative importance compared with the diverse cell behaviors that remodel developing tissues, and by our primitive knowledge concerning regulation of cell death in these tissues. However, tools are now available to better understand apoptosis in normal and abnormal development of cardiovascular structures, and a framework has been established that should lead to considerable progress in the coming years.

Embryonic development is disrupted by modest increases in vascular endothelial growth factor gene expression.

Previous work has shown that heterozygocity for a null mutation of the VEGF-A gene, resulting in a 50% reduction in VEGF-A expression, is embryonic lethal at embroyonic day (E) 9.5 in mice. We now show that two- to threefold overexpression of VEGF-A from its endogenous locus results in severe abnormalities in heart development and embryonic lethality at E12.5-E14. The mutant embryos displayed an attenuated compact layer of myocardium, overproduction of trabeculae, defective ventricular septation and abnormalities in remodeling of the outflow track of the heart. In addition, aberrant coronary development was characterized by formation of oversized epicardial vessels, apparently through vasculogenesis. We infer that embryonic survival requires a narrow window of VEGF-A expression.

Determinants of mechanical properties in the developing ovine thoracic aorta.

We previously reported changes in mechanical properties and collagen cross-linking of the ovine thoracic aorta during perinatal development and postnatal maturation, and we now report changes in biochemical composition (elastin, collagen, and DNA contents per mg wet wt) over the same developmental intervals. A comparison of results from the present and previous studies has yielded novel and important observations concerning the relationship between aortic mechanics and composition during maturation. Developmental changes in aortic incremental elastic modulus at low tensile stress (E(low)) closely followed changes in relative elastin content (i.e., per mg wet wt). An 89% increase in E(low) during the perinatal period was associated with a 69% increase in relative elastin content, whereas neither variable changed during postnatal life. Incremental elastic modulus at high tensile stress (E(high)) did not change during the perinatal period but increased 88% during postnatal life. This pattern closely paralleled changes in collagen cross-linking index, which did not change perinatally but almost doubled postnatally. In contrast, relative collagen content (per mg wet wt) increased only slightly from fetal to adult life, a trend that was unrelated to aortic mechanics. Substantial, progressive decreases in measures of wall viscosity (pressure wave attenuation coefficient and viscoelastic phase angle) from fetal to adult life followed the pattern observed for relative DNA (smooth muscle cell) content (per mg wet wt). Our findings suggest that accumulation of elastin per milligram wet weight contributes most to developmental changes in E(low), change in collagen cross-linking is the primary determinant of developmental changes in E(high), and cell accumulation contributes most to developmental changes in wall viscosity.

Transient and steady-state effects of shear stress on endothelial cell adherens junctions.

Endothelial cells exhibit profound changes in cell shape in response to altered shear stress that may require disassembly/reassembly of adherens junction protein complexes that mediate cell-cell adhesion. To test this hypothesis, we exposed confluent porcine aortic endothelial cells to 15 dyne/cm(2) of shear stress for 0, 8.5, 24, or 48 hours, using a parallel plate flow chamber. Cells were fixed and stained with antibodies to vascular endothelial (VE) cadherin, alpha-catenin, beta-catenin, or plakoglobin. Under static conditions, staining for all proteins was intense and peripheral, forming a nearly continuous band around the cells at cell-cell junctions. After 8.5 hours of shear stress, staining was punctate and occurred only at sites of continuous cell attachment. After 24 or 48 hours of shear, staining for VE-cadherin, alpha-catenin, and beta-catenin was intense and peripheral, forming a band of "dashes" (adherens plaques) that colocalized with the ends of stress fibers that inserted along the lateral membranes of cells. Staining for plakoglobin was not observed after 24 hours of shear stress, but returned after 48 hours. Western blot analysis indicated that protein levels of VE-cadherin, alpha-catenin, and plakoglobin decreased, whereas beta-catenin levels increased after 8.5 hours of shear stress. As cell shape change reached completion (24 to 48 hours), all protein levels were upregulated except for plakoglobin, which remained below control levels. The partial disassembly of adherens junctions we have observed during shear induced changes in endothelial cell shape may have important implications for control of the endothelial permeability barrier and other aspects of endothelial cell function.

Atrophic remodeling of the artery-cuffed artery.

Increased arterial wall tension stimulates growth and remodeling of arteries, but little is known about the effects of decreased wall tension, despite its developmental and pathological significance. Consequently, we cuffed 1 carotid artery in rabbits with a portion of the contralateral artery to off-load circumferential wall tension. The model produced rapid and extensive atrophy of the cuffed artery that yielded decreases in the DNA content of the cuffed artery (a measure of cell number) from 8.0+/-0.5 microgram/cm of in situ vessel length to 5.6+/-0.5 microgram/cm at 21 days postoperatively. The elastin content of the cuffed artery was also significantly reduced, from 399+/-17 to 283+/-17 microgram/cm, and collagen content was reduced from 468.0+/-59.0 to 154+/-24 microgram/cm (P<0.05) at 21 days postoperatively. Detection of DNA oligonucleosomes by gel electrophoresis implicated apoptotic cell death in remodeling due to cuffing. Upregulation of matrix metalloproteinases (MMPs), including MMP-2, MMP-9, and unidentified gelatinases, indicated that these enzymes may also be involved in remodeling. No further changes in wall structure were seen between 3 weeks and 6 months, and the excised artery that was used as a cuff exhibited normal medial morphology for at least 6 months postoperatively. We infer from these experiments that off-loading of arterial wall tension induces rapid and extensive atrophy of the arterial media.

Cardiovascular responses attenuate with repeated NO synthesis inhibition in conscious fetal sheep.

The cardiovascular effects of repeated administration of the nitric oxide (NO) synthesis inhibitor N omega-nitro-L-arginine methyl ester (L-NAME) were assessed daily for 3 days in fetal sheep near term (124-126 days gestation) beginning 4 days after surgery (n = 7). In the first hour on day 1, fetal infusion of L-NAME (30 mg bolus, 6 mg/min infusion iv for 3 h) significantly increased fetal arterial pressure from 41 +/- 2 to 58 +/- 3 mmHg, decreased heart rate from 173 +/- 5 to 134 +/- 3 beats/min, increased umbilicoplacental resistance from 0.16 +/- 0.02 to 0.28 +/- 0.07 mmHg.ml-1.min, and inhibited the hypotensive response to acetylcholine (ACh; 2 micrograms iv bolus). All changes were sustained except for arterial pressure, which decreased significantly to 50 +/- 3 mmHg in the third hour. Within 17 h, all cardiovascular variables returned to control. L-NAME readministered on days 2 and 3 had no effect on cardiovascular variables. L-NAME did not potentiate the pressor response to angiotensin II on day 2 and caused a surprising attenuation of the pressor response to endothelin-1 on day 3. We conclude that, whereas NO normally contributes to low arterial pressure, high heart rate, and low umbilicoplacental vascular resistance in fetal sheep near term, the role of NO in these functions is replaced by an alternate mechanism within 17 h after NO synthesis inhibition with L-NAME.

In vivo and in vitro mechanical properties of the sheep thoracic aorta in the perinatal period and adulthood.

The mammalian aorta undergoes rapid remodeling during the perinatal period and more gradual remodeling during subsequent development, but the implications of this remodeling for arterial mechanics are poorly understood. In this study in vivo and in vitro techniques were used to determine the static and viscoelastic properties of the thoracic aortas of 119-day-gestation fetal sheep (full term = 145 days), 21-day-old lambs, and adult sheep at control distending pressures and after 70% increases or 30% decreases in pressure. In the weeks surrounding birth, aortic wall tissue became substantially stiffer (static elastic modulus in vitro increased by 28%, and pressure wave velocity in vivo increased by 61%) but less viscous (pressure wave attenuation in vivo decreased by 46%, and viscoelastic phase angle in vitro decreased by 15%), whereas the wall thickness-to-radius ratio was unchanged. By contrast, modest changes in tissue viscoelasticity from neonatal to adult life were accompanied by a halving of the wall thickness-to-radius ratio from 0.19 +/- 0.01 to 0.10 +/- 0.01. The relative thinning of the vessel wall, combined with a doubling of blood pressure after birth, resulted in a 265% increase in aortic wall tensile stress over the period of study. We concluded that rapid remodeling in the perinatal period primarily alters the viscoelastic properties of aortic wall tissues, whereas more gradual postnatal remodeling largely affects vessel geometry.

Regulation of vascular connexin43 gene expression by mechanical loads.

Vascular tissues respond to changes in the mechanical forces imposed on them with changes in vasomotor tone in the short term and with structural remodeling in the long term. Since these responses involve intercellular communication, we have investigated regulation of the gap junction proteins, connexin26 (Cx26), connexin37 (Cx37), connexin40 (Cx40), and connexin43 (Cx43), by mechanical loads. Results were compared with parallel experiments on c-fos and GAPDH. Twenty percent stretch of cultured vascular smooth muscle cells caused a 3-fold increase in Cx43 mRNA levels by 2 hours. Cx26 was expressed at low levels but failed to respond to stretch, and Cx37 and Cx40 were not detected. c-fos mRNA levels increased after 30 minutes of stretch, whereas GAPDH mRNA did not change. Protein levels of Cx43 increased by 4 hours and remained elevated for 16 hours. Nuclear run-on experiments confirmed that Cx43 and c-fos were transcriptionally regulated by stretch. New protein synthesis was not a requirement for the stretch-induced rise in Cx43 expression, since mRNA levels were unaffected by treatment with cycloheximide. To examine transcriptional control of Cx43, stretched and unstretched vascular smooth muscle cells were transfected with a variety of promoter-reporter gene constructs. Cx43 sequences extending from within exon 1 (+162) to -1686 in the 5'-flanking region were coupled to the chloramphenicol acetyl transferase reporter gene. Deletions from the 5' end of these sequences differentially regulated reporter gene expression and indicated multiple potential regulatory sites. In particular, a putative activator protein-1 site at the -42 to -48 region was required for basal reporter activity. None of the promoter constructs revealed stretch sensitivity, indicating that the site of transcriptional control by stretch lies outside the -1686 to +162 region. Finally, Cx43 mRNA levels were assessed in cultured endothelial cells subjected to laminar shear stress of 15 dynes/cm2. Cx43 mRNA levels increased by approximately 4-fold at 1 hour and remained elevated for the duration of shear force. In conclusion, both mechanical strain and fluid shear stress caused increased expression of the gap junction protein Cx43.

Modulation of arterial growth of the rabbit carotid artery associated with experimental elevation of blood flow.

We examined the growth of the right common carotid artery of young rabbits after ligating the left common carotid artery at 3 weeks of age, a procedure that approximately doubled right carotid blood flows. Flow increased from 0.065 +/-0.003 to 0.096+/-0.009 ml/s within 1 h and, at 15 weeks of age, carotid blood flows in experimental animals (0.747+/-0.102 ml/s) were more than double of those of sham-operated control animals (0.334+/-0.053 ml/s). Contralateral carotid ligation resulted in more rapid increases in diameter of the artery with growth in the experimental animals. At 15 weeks of age, the vessel was 15% larger than that of sham-operated controls (2.70+/-0.09 vs. 2.34+/-0.05 mm). This more rapid growth of diameter resulted in shear stresses that were not different from controls despite the higher blood flow rates. Interestingly, however, shear stresses in control arteries fell from 17.4+/-3.4 to 9.19+/-1.16 dyn/cm2 over the experimental period (p < 0.05). Elastin accumulation in the experimental artery was much more rapid than in controls and elastin contents were 49% more than in controls at 15 weeks of age. DNA and collagen contents were not significantly affected by contralateral carotid ligation. Previously, we found that experimental manipulations that decreased flow in the same artery of weanling rabbits substantially affected elastin and DNA accumulation, but had no effect on collagen contents. We conclude that increased blood flow is associated with arterial growth and specifically with accumulation of elastin, a wall constituent that bears much of the wall tension at resting blood pressure, and therefore is a primary determinant of resting vessel dimensions.

Role of the NF-ATc transcription factor in morphogenesis of cardiac valves and septum.

In lymphocytes, the expression of early immune response genes is regulated by NF-AT transcription factors which translocate to the nucleus after dephosphorylation by the Ca2+-dependent phosphatase, calcineurin. We report here that mice bearing a disruption in the NF-ATc gene fail to develop normal cardiac valves and septa and die of circulatory failure before day 14.5 of development. NF-ATc is first expressed in the heart at day 7.5, and is restricted to the endocardium, a specialized endothelium that gives rise to the valves and septum. Within the endocardium, specific inductive events appear to activate NF-ATc: it is localized to the nucleus only in endocardial cells that are adjacent to the interface with the cardiac jelly and myocardium, which are thought to give the inductive stimulus to the valve primordia. Treatment of wild-type embryos with FK506, a specific calcineurin inhibitor, prevents nuclear localization of NF-ATc. These data indicate that the Ca2+/calcineurin/NF-ATc signalling pathway is essential for normal cardiac valve and septum morphogenesis; hence, NF-ATc and its regulatory pathways are candidates for genetic defects underlying congenital human heart disease.

Alterations in endothelial F-actin microfilaments in rabbit aorta in hypercholesterolemia.

The current study tests whether hypercholesterolemia influences the distribution of endothelial cell microfilaments during the initiation and growth of fatty streak-type lesions. We classified the lesions occurring over a 20-week period into four types based on the location and extent of macrophage infiltration observed microscopically. The earliest lesion was characterized by leukocytes adherent to the endothelial surface. Minimal lesions were characterized by a few cells in the subendothelium. Intermediate lesions consisted of numerous subendothelial leukocytes in a minimally raised lesion. Advanced fatty streak lesions were elevated, with several layers of leukocytes. The organization of peripheral junctional actin (the dense peripheral band) and of central endothelial cell actin microfilament bundles was studied in each of these lesions by using fluorescent microscopy. We found that in the aorta away from branch sites and in areas away from lesions, the central microfilament distribution was unaffected by hypercholesterolemia. The macrophages entered the wall without any identifiable reorganization in the microfilaments. During the accumulation of subendothelial macrophages in minimal and intermediate lesions, stress fibers were initially increased in comparison to lesion-free areas. In raised advanced lesions, the central microfilaments became thinner and disappeared. However, at flow dividers, where central stress fibers are normally prominent, endothelial cells on the surface of intermediate lesions showed a reduction in central fibers, and peripheral bands became prominent. This finding was associated with changes in cell shape from elongated to cobblestone type. Thus, actin microfilament bundles in endothelial cells underwent substantial changes in distribution during the accumulation of subendothelial macrophages, forming hypercholesterolemia-induced fatty streak-type lesions. These changes may influence endothelial substrate adhesion, permeability, or repair after injury.

Thermomechanical analysis of collagen crosslinking in the developing ovine thoracic aorta.

We have used hydrothermal isometric tension (HIT) techniques in a sheep model to assess collagen crosslink stability and its contribution to the mechanical properties of the ovine thoracic aorta during perinatal and postnatal development. Aortic tissue was studied from fetal sheep, lambs, and adult sheep. Strips of tissue were loaded under isometric tension and heated to a 90 degrees C isotherm which was sustained for 3 hours. The decrease in load at this temperature is associated with collagen peptide bond hydrolysis and chain slippage, and the rate of this decrease is an inverse indicator of collagen crosslinking. The half-time of load decay (t1/2) was computed before and after tissue was treated with NaBH4 which stabilizes immature, reducible crosslinks. We observed a two-fold increase in t1/2 of untreated tissue from the lamb to the adult, indicating that aortic collagen crosslinking increased during postnatal development. Furthermore, the t1/2 of NaBH4-stabilized lamb tissue was similar to that of the untreated adult tissue, suggesting that much of the immature crosslinking in the lamb is stabilized during postnatal development. These observations suggest (a) increased crosslinking occurs during postnatal development and (b) that this increase is largely due to a conversion of immature crosslinks into their mature heat stable form.

Effects of changes in blood flow rate on cell death and cell proliferation in carotid arteries of immature rabbits.

Spontaneous and experimental changes in arterial blood flow rates affect tissue accumulation in developing arteries. To examine whether cell proliferation and/or cell death are affected by alterations in blood flow, we ligated the left external carotid artery of 3-week-old rabbits, which reduces left common carotid blood flow by 71%. In control arteries and after 2 days of flow reduction, agarose gel electrophoresis of DNA extracted from all carotid arteries resolved multiple low molecular weight bands characteristic of apoptosis; however, DNA fragmentation in arteries carrying reduced blood flow was 2.5-fold higher than that of control arteries. The effect of reduced blood flow on cell death subsequently waned but remained significant at 7 days. Cell death in carotid arteries was also detected by in vivo uptake of propidium iodide, a DNA-binding fluorescent dye that labels the nuclei of nonviable cells. Both smooth muscle and endothelial cells exhibited large and statistically significant increases in labeling index in the flow-reduced artery. Propidium iodide-labeled cells were cleared from the vessel wall within 1 to 4 hours of labeling, and nuclear staining displayed condensation (clumping) of chromatin in all labeled cells at later time points. This time course and nuclear morphology and the rapid clearance of labeled cells are consistent with death via apoptosis. Many propidium iodide-positive cells did not display chromatin condensation immediately after labeling; however, this was also true of cultured endothelial cells that were driven into apoptosis with sphingomyelinase treatment and then double-labeled with propidium iodide and the apoptosis marker annexin V. We infer that propidium iodide can label apoptotic vascular cells before these cells display chromatin condensation that is detectable with fluorescence labeling of DNA. Replication rates of smooth muscle and endothelial cells, determined by 5-bromo-2'-deoxyuridine uptake, were inhibited by >75% with decreased blood flow. The inhibition of proliferation was unabated after 7 days of reduced flow. These findings indicate that the coordinated regulation of cell death and cell proliferation, in response to changes in arterial blood flow rates, contributes to arterial remodeling during development.

Blood flow dynamics, atherosclerosis and bypass graft failure.

Atherosclerosis occurs at reproducible sites in the arterial tree and intimal proliferation that leads to bypass graft occlusion also show a well-defined focal distribution. These observations have led to the hypothesis that local blood flow conditions, especially low or fluctuating shear stresses, are important in the development of both disorders. Basic research using both cell culture and animal models has revealed that endothelial cell biology is very sensitive to local shear stresses and rapid progress is being made in characterizing how endothelial cells transduce shear stress. Endothelial sensitivity to shear stress affects control of hemostasis, leukocyte adherence and transmigration, growth factor production, vasomotor responses, endothelial repair and arterial wall remodeling, all of which can be expected to influence development of vascular pathologies. Also, substantial progress has been made in characterizing complex local hemodynamics at relevant arterial sites; however, further progress is needed in this area, as well as in the extrapolation of advances in basic vascular biology to human vascular disease. (Trends Cardiovasc Med 1997;7:111-118). © 1997, Elsevier Science Inc.

Decreased blood flow rate disrupts endothelial repair in vivo.

Both local hemodynamics and endothelial injury have been implicated in vascular disorders including bypass graft failure and atherogenesis, but little is known about the effect of local blood flow conditions on repair of endothelial injury. We decreased blood flow rates and shear stresses in common carotid arteries of rabbits by ligating the ipsilateral external carotid artery. After 24 hours, endothelial cells were less elongated, contained fewer central microfilament bundles, and showed less polarity of the centrosome toward the heart than endothelial cells in unmanipulated carotid arteries. To examine wound repair, we made narrow longitudinal intimal wounds at the time of flow reduction using a nylon monofilament device. In arteries with normal blood flows, endothelial cells at the edge of the wound initially spread and elongated in the direction of the wound. The dense peripheral band of actin was attenuated and central microfilaments became more prominent. Endothelial cells remained in close contact with their neighbors in the monolayer. The centrosome of cells adjacent to the wound was redistributed toward the wound side of the nucleus at 6 and 12 hours. Complete closure occurred by 24 hours, at which time the elongated endothelial cells covering the wound were organized in a herringbone pattern with their downstream ends at the center of the wound. With decreased flow and shear stress, the cells at the wound edge spread less than those in normal vessels at 12 hours after wounding and were randomly oriented and polygonal in shape. Also, re-endothelialization proceeded more slowly and there was a marked reduction of central microfilaments in cells at the wound edge. At 24 hours, the wounds were still open, the endothelial cells covering the central portion of the wound did not maintain intimate contact with their neighbors, and orientation of the centrosome toward the wound was reduced. We hypothesize that loss of cell-cell contact during repair at low flow rates and low shear stress disrupts intercellular communication and results in disruption of cytoskeletal reorganization during repair, thereby slowing the repair process.

Arterial remodeling: relation to hemodynamics.

The structure of the artery wall is exquisitely sensitive to the hemodynamic forces imposed on it by blood pressure and blood flow. This sensitivity regulates growth and remodeling of arteries during development, and it regulates long-term adaptive restructuring of mature vessels. Since many vascular pathologies involve alterations in hemodynamic loads, the sensitivity of arterial structure to these changes inevitably affects the progression of vascular diseases. The processes involved in arterial remodeling involve regulation of vascular cell migration and mitosis and apoptosis rates, control of matrix synthesis and degradation, and regulation of matrix reorganization. Some exciting data have been presented concerning how vascular cells sense mechanical forces, including mechanisms based on shear-sensitive ion channels, control of mass transport of agonists to endothelium by shear strain rate, and modulation of tyrosine phosphorylation of proteins at focal adhesion sites; however, the physiological importance of these mechanisms remains to be elucidated.

Developmental remodeling of the internal elastic lamina of rabbit arteries: effect of blood flow.

We examined remodeling of the internal elastic lamina (IEL) of rabbit arteries from 3 to 23 weeks of age. The IELs were fenestrated at all ages; however, the sizes of the fenestrae increased dramatically during postnatal development. Mean areas occupied by the individual fenestrae of the carotid artery IEL increased from 11.3 +/- 0.7 microns2 in 3-week-old rabbits to 61.2 +/- 5.5 microns2 in adult rabbits. The estimated number of fenestrae per vessel also increased greatly, from 2.68 x 10(5) to 9.27 x 10(5); however, the increased number of fenestrae did not keep pace with growth of the artery, since fenestrae per square millimeter decreased by 26%. Large increases in the size of fenestrae were also observed in the renal and iliac arteries, although greater decreases in fenestrae per square millimeter occurred with age (70% in iliac arteries). Morphological assessments suggested that enlarging fenestrae frequently fuse with neighbors. By contrast with other arteries, the IEL of the abdominal aorta was not a continuous fenestrated sheet in young animals, perhaps reflecting the extensive remodeling that this vessel undergoes in the postnatal period. We decreased common carotid blood flow by 70% in 5 rabbits at 10 weeks of age by ligating the ipsilateral external carotid artery, and we approximately doubled blood flow in 5 others at the same age, by contralateral common carotid ligation. At 15 weeks of age, fenestrae in the artery carrying increased flow were 39% larger than fenestrae in the control artery, whereas fenestrae were 53.5% smaller after 70% decreases in flow (P < .05). We conclude that flow-dependent enlargement of fenestrae contributes to developmental remodeling of the IEL. Remodeling of the IEL may also have important implications for transport of materials and cell-cell communication between the intima and media.