Abstract
The portal vein of the rat is immature at birth, and is composed of an endothelium surrounded by undifferentiated cells of mesenchymal origin. Three days after birth, these cells have begun to differentiate and aggregate around the lumen to form two separate layers of perpendicularly oriented myoblasts, while a rich calcitonin gene-related peptide (CGRP) innervation is present around the vessel. In the internal circular muscle layer of the media myofibrils first develop on the endothelial side of the myoblasts, and then progressively reach the other side. In the longitudinal muscular layer of the media, which is separated from the circular layer by a connective lamina as early as 3 days after birth, myofibrils develop randomly in the cells. At the time of the enlargement of the longitudinal layer, long close contacts and intermediate junctions between external myoblasts and adventitial fibroblast-like cells were noted, suggesting that recruitment of this cell type is necessary for the maturation of the vessel wall. At about 28 days, the vein has reached its final structure and the smooth muscle cells are fully differentiated. The dense CGRP perivascular innervation already present at birth persists for the first 14 days of postnatal life when most of the cells have not yet acquired their complete contractile differentiation and are still capable of division. This innervation decreases transiently between 15–17 days, when the vessel acquires its spontaneous contractile activity, then rises to a peak between 20 and 25 days, and falls again. CGRP innervation, which is very scarce at 28 days, slowly increases during the peripubescent stage, by which time the adult structure of the vessel is established. Similar fluctuations in the density of peptidergic innervation were observed for substance P and neuropeptide Y, although these peptides were not yet present at birth and occurred only after 5 days. Vasoactive intestinal polypeptide- and bombesin-immunoreactive fibres were not found at any stage investigated. In addition to a description of the different cell-to-cell contacts which could play a role in the maturation of the vessel wall, we discuss the possible implication of the different peptides in the differentiation, maturation or maintenance of the vessel wall.
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References
Aiyar N, Mattern MR, Hofmann GA, Edwards RM, Nambi P (1991) Down regulation of calcitonin gene-related peptide (CGRP)-mediated cAMP accumulation in ras transformed 3T3 fibroblasts. Regul Pept 34:99
Aprigliano O, Hermsmeyer K (1977) Trophic influence of the sympathetic nervous system on the rat portal vein. Circ Res 41:198–206
Barja F, Mathison R (1982) Adrenergic and peptidergic (substance P and vasoactive intestinal polypeptide) innervation of the rat portal vein. Blood Vessels 19:263–272
Beal MF, Walker LC, Swartz KJ, Casanova MF, Price DL (1988) Developmental changes of neuropeptides and amino acids in baboon cortex. Dev Brain Res 44:156–159
Bény J-L, Connat J-L (1992) An electron-microscopic study of smooth muscle cell dye coupling in the pig coronary arteries: role of gap junctions. Circ Res 70:49–55
Bevan RD (1976) An autoradiographic and pathological study of cellular proliferation in rabbit arteries correlated with an increase in arterial pressure. Blood Vessels 13:100–128
Bevan RD (1984) Trophic effects of peripheral adrenergic nerves on vascular structure. Hypertension 6 [Suppl 3]:19–26
Bevan RD, Tsuru H (1979) Long term denervation of vascular smooth muscle causes not only functional but structural change. Blood Vessels 16:109–112
Bird CC, Willis RA (1965) The production of smooth muscle by the endometrial stoma of the adult human uterus. Pathol Bacteriol 90:75–81
Bråtveit M, Helle KB (1991) Inhibition by VIP and atriopeptin II on the field stimulation evoked release of [3H]noradrenaline in the rat portal vein. Regul Pept 33:331–337
Burnstock G (1981) Development of smooth muscle and its innervation. In: Bülbring E, Brading AF, Jones AW, Tomita T (eds) Smooth muscle: an assessment of current knowledge. Arnold, London, pp 431–457
Campbell GR, Chamley-Campbell JH, Burnstock G (1981) Differentiation and phenotypic modulation of the arterial smooth muscle cell. In: Schwartz CY, Werthessen NT, Wolf S (eds) Structure and function of the circulation, vol 3. Plenum Press, New York, pp 357–399
Chamley JH, Campbell GR (1975) Trophic influences of sympathetic nerves and cyclic AMP on differentiation and proliferation of isolated smooth muscle cells in culture. Cell Tissue Res 161:497–510
Chamley JH, Campbell GR (1976) Tissue culture: interraction between sympathetic nerves and vascular smooth muscle. In: Bevan JA, Burnstock G, Johansson B, Maxwell RA, Nedergaark OA (eds) Vascular neuroneffector mechanisms. Proceedings of the 2nd international symposium. Karger, Basel, pp 10–18
Chemley JH, Campbell GR, Burnstock G (1974) Dedifferentiation, redifferentiation and bundle formation of smooth muscle on tissue culture: the influence of all number and nerve fibers. J Embryol Exp Morphol 32:297–323
Connat J-L, Thiévent A, Carrier N, Huggel HJ (1992) Occurrence of CGRP receptors on dedifferentiated smooth muscle cells from media of rat thoracic aorta. Ann NY Acad Sci USA 657:444–448
Cuttitta F, Carney DN, Mulshine J, Moody TW, Fedorko J, Fischler A, Minna JD (1985) Bombesin-like peptides can function as autocrine growth factors in human small cell lung cancer. Nature 316:823–826
Dalsgaard CJ, Hultgardh-Nilsson A, Haegerstrand A, Nilsson J (1989) Neuropeptides as growth factors. Possible roles in human diseases. Regul Pept 25:1–9
Dhall U, Cowen T, Haven AJ, Burnstock G (1986) Perivascular noradrenergic and peptide-containing nerves show different patterns of changes during development and ageing in the guinea-pig. J Auton Nerv Syst 16:109–126
Dhital KK, Burnstock G (1987) Contrôle neurogène adrénergique et non-adrénergique de la paroi artérielle. In: Camilleri J-P, Berry CL, Fiessinger J-N, Bariéty J (eds) Les maladies de la paroi artérielle. Médecine Science Flammarion, Paris, pp 77–105
Dhital KK, Gerli R, Lincoln J, Milner P, Tanganelli P, Weber G, Fruschelli C, Burnstock G (1988) Increased density of perivascular nerves to the major cerebral vessels of the spontaneously hypertensive rat: differential changes in noradrenaline and neuropeptide Y during development. Brain Res 444:33–45
Dimitriadou V, Aubineau P, Taxi J, Seylaz J (1988) Ultrastructural changes in the cerebral artery wall induced by long-term sympathic denervation. Blood vessels 25:122–143
Duc C, Barakat-Walter I, Philippe E, Droz B (1991) Substance P-like-immunoreactive sensory neurons in dorsal root ganglia of the chick embryo: ontogenesis and influence of peripheral targets. Dev Brain Res 59:209–219
Fraser SE, Green CR, Bode HR, Gilula NB (1987) Selective disruption of gap junctional communication interferes with a patterning process in Hydra. Science 237:49–55
Gibbins IL, Furess JB, Costa M, MacIntyre I, Hilliard CJ, Girgis S (1985) Co-localisation of calcitonin gene-related peptide-like immunoreactivity with substance P in cutaneous, vascular and visceral sensory neurons of guinea pigs. Neurosci Lett 57:125–130
Gutstein WH (1988) Central nervous system and atherogenesis: endothelial injury. Atherosclerosis 70:145–154
Haas CA, Reddington M, Kreutzberg GW (1991) Calcitonin generelated peptide stimulates the induction of c-fos gene expression in rat astrocyte cultures. Eur J Neurosci 3:708–712
Haegerstrand A, Dalsgaard C-J, Jonzon B, Larsson O, Nilsson J (1990) Calcitonin gene-related peptide stimulates proliferation of human endothelial cells. Proc Natl Acad Sci USA 87:3299–3303
Hirata Y, Takagi Y, Takata S, Fukuda Y, Yoshimi H, Fujita T (1988) Calcitonin gene-related peptide receptor in cultured vascular smooth muscle and endothelial cells. Biochem Biophys Res Commun 151:1113–1121
Hooper ML, Subak-Sharpe JH (1981) Metabolic cooperation between cells. Int Rev Cytol 69:45–104
Ishii T, Shimo Y, Minematsu S (1982) Localization of vasoactive intestinal polypeptide immunoreactive nerve fibres in the rat portal vein. Dokkyo J Med Sci 9:89–95
Johansson B (1976) Structural and functional changes in rat portal veins after experimental portal hypertension. Acta Physiol Scand 98:381–383
Komuro T, Burnstock G (1980) The fine structure of smooth muscle cells and their relationship to connective tissue in the rabbit portal vein. Cell Tissue Res 210:257–267
Lash JA, Crister ES, Pressler ML (1990) Cloning of a gap junctional protein from vascular smooth muscle and repression in two-cell mouse embryos. J Biol Chem 265:13113–13117
Lehy T, Puccio F (1988) Influence of bombesin on gastrointestinal and pancreatic cell growth in adult and sukkling animals. Ann NY Acad Sci 547:255–267
Lehy T, Accary JP, Labeille D, Dubrasquet M (1983) Chronic administration of bombesin stimulates antral gastrin cell proliferation in the rat. Gastroenterology 84:914–919
Lennette DA (1978) An improved mounting medium for immunofluorescence microscopy. Am J Clin Pathol 69:647–648
Lhoste EF, Aprahamian M, Balboni G, Damgé C (1989) Evidence for a direct trophic effect of bombesin on the mouse pancreas: in vivo and cell culture studies. Regul Pept 24:45–54
Lichtor T, Davis HR, Johns L, Vasselinovitch D, Wissler RW, Mullan S (1987) The sympathetic nervous system and atherosclerosis. J Neurosurg 67:906–914
Ljung B, Stage D (1975) Postnatal ontogenetic development of neurogenic and myogenic control in the rat portal vein. Acta Physiol Scand 94:112–127
Lobaugh LA, Blackshera PJ (1990) Neuropeptide Y stimulation of myosin light chain phosphorylation in cultured aortic smooth muscle cells. J Biol Chem 265:18393–18399
Loewenstein WR (1979) Junctinal intercellular communication and the control of growth. Biochim Biophys Acta 560:1–65
Lundberg J, Ljung B, Stage D, Dahlström A (1976) Postnatal ontogenetic development of the adrenergic innervation pattern in the rat portal vein. Cell Tissue Res 172:15–27
Malmqvist U, Arner A (1990) Isoform distribution and tissue contents of contractile and cytoskeletal proteins in hypertrophied smooth muscle from rat portal vein. Circ Res 66:832–845
Mehta PP, Bertram JS, Loewenstein WR (1986) Growth inhibition of transformed cells correlates with their junctional communication with normal cells. Cell 44:187–196
Mione MC, Dhital KK, Amenta F, Burnstock G (1988) An increase in the expression of neuropeptidergic vasodilator, but not vasoconstrictor, cerebrovascular nerves in aging rats. Brain Res 460:103–113
Mitsuhashi M, Payan DG (1987) The mitogenic effects of vasoactive neuropeptides on cultured smooth muscle cell lines. Life Sci 40:853–861
Moore SA, Bohlen HG, Miller BG, Evan AP (1985) Cellular and vessel wall morphology of cerebellar cortical arterioles after short term diabetes in adult rats. Blood Vessels 22:265–277
Mulvany MJ, Ljung B, Stolze M, Kjellstedt A (1980) Contractile and morphological properties of the portal vein in spontaneously hypertensive and Wistar-Kyoto rats. Blood Vessels 17:202–215
Nilsson J, Von Euler A, Dalsgaard CJ (1985) Stimulation of connective tissue cell growth by substance P and substance K. Nature 315:61–63
Olson L, Malmfors T (1970) Growth characteristics of adrenergic nerves in the adult rat. Acta Physiol Scand 348 [Suppl]:447–449
Pitts JD (1976) Junctions as channels of direct communication between cells. In: Graham CF, Wareing PF (eds) The developmental biology of plants and animals. Blackwell, Oxford, pp 96–110
Rebuffat P, Malendowicz LK, Belloni AS, Mazzocchi G, Nussdorfer GG (1988) Long-term stimulatory effect of neuropeptide-Y on the growth and steroidogenic capacity of rat adrenal zona glomerulosa. Neuropeptides 11:133–136
Rennick RE, Connat J-L, Burnstock G, Rothery S, Severs NJ, Green CR (1993) Expression of connexin 43 gap junction between cultured vascular smooth muscle cells is dependent upon phenotype. Cell Tissue Res 271:323–332
Rozengurt E, Sinnett-Smith JW (1983) Bombesin stimulation of DNA synthesis and cell division in cultures of swiss 3T3 cells. Proc Natl Acad Sci USA 80:2936–2940
Sasaki Y, Hayashi N, Kasahara A, Matsuda H, Fusamoto H, Sato N, Hillyard CJ, Girgis S, MacIntyre I, Emson PC, Shiosaka S, Tohyama M, Shiotani Y, Kamada T (1986) Calcitonin generelated peptide in the hepatic and splanchnic vascular systems of the rat. Hepatology 6:676–681
Scott TM, Pang SC (1983) The correlation between the development of sympathetic innervation and the development of medial hypertrophy in jejunal arteries in normotensive and spontaneously hypertensive rats. J Auton Nerv Syst 8:25–32
Scott TM, Robinson J, Foote J (1989) The peptidergic innervation of the developing mesenteric vascular bed in the rat. J Anat 162:177–183
Stage MD, Ljung B (1978) Neuroeffector maturity of portal veins from newborn rats, rabbits, cats and guinea-pigs. Acta Physiol Scand 102:218–223
Starke K, Illes P, Ramme D, Ensinger H, Hedler L, Szabo B, von Kügelgen I, Pfeifer N, Limberger N (1987) Peripheral prejunctional opioid receptors in cardiovascular control. In: Nobin A, Owman C, Arneklo-Nobin B (eds) Neuronal messengers in vascular function, vol 10, Elsevier, Amsterdam, pp 247–269
Thiévent A, Connat J-L (1993) Calcitonin gene-related peptide innervation and receptors in rat aorta during development J. Auton Nerv Syst (in press)
Ts'ao CH, Glagov S, Billy B, Kelsey K (1970) Special structural features of the rat portal vein. Anat Rec 166:529–540
Ts'ao CH, Glagov S, Kelsey BF (1971) Structure of mammalian portal vein. Postnatal establishment of two mutually perpendicular medial muscle zones in the rat. Anat Rec 171:457–470
Uvelius B, Arner A, Johansson B (1981) Structural and mechanical alterations in hypetrophic venous smooth muscle. Acta Physiol Scand 112:463–471
Warner AE, Guthrie SC, Gilula NB (1984) Antibdies to gapjunctional protein selectively disrupt junctional communication in the early amphibian embryo. Nature 311:127–131
Wharton J, Gulbenkian S (1987) Peptides in the mammalian cardiovascular system. Experientia 43:821–832
Woolgar J, Scott TM (1989) The relationship between innervation and arterial structure in late prenatal and early postnatal development of the rat jejunal artery. J Anat 167:57–70
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Ody, M., Thiévent, A., Millet, M. et al. Postnatal development of the rat portal vein: correlation with occurrence of peptidergic innervation. Cell Tissue Res 272, 303–314 (1993). https://doi.org/10.1007/BF00302735
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DOI: https://doi.org/10.1007/BF00302735