A 3D reconstruction of pancreas development in the human embryos during embryonic period (Carnegie stages 15-23).

AIMS: The goal in this paper was to rebuild a three dimensional (3D) reconstruction of the dorsal and ventral pancreatic buds, in the human embryos, at Carnegie stages 15-23. METHOD: The early development of the pancreas is studied by tissue observation and reconstruction by a computer-assisted method, using a light micrograph images from consecutive serial sagittal sections (diameter 7 microm) of ten human embryos ranging from Carnegie stages 15-23, CRL 7-27 mm, fixed, dehydrated and embedded in paraffin, were stained alternately with haematoxylin-eosin or Heindenhain'Azan. The images were digitalized by Canon Camera 350 EOS D. The serial views were aligned automatically by software, manual alignment was performed, the data were analysed following segmentation and threshold. RESULTS: The two buds were clearly identified at stage 15. In stage 16, both pancreatic buds were in final position, and begin to merge in stage 17. From stage 18 to the stage 23, surrounding connective tissue differentiated. In the stage 23, the morphology of the pancreas was definitive. The superior portion of the anterior face of the pancreas's head was arising from the dorsal bud. The rest of the head including the uncinate process emanated from the ventral bud. CONCLUSION: The 3D computer-assisted reconstruction of the human pancreas visualized the relationships between the two pancreatic buds. This explains the disposition and the modality of the components fusion. This embryologic development permits a better understanding of congenital abnormalities.

Contribution to the 3D computer assisted reconstruction of pancreatic buds in the rat embryos.

The aim of this work was to reconstruct, in the rat embryos, stage 12-23, the three dimensional (3D) distribution of the dorsal and ventral pancreatic buds by of a computer assisted method. Ninety-six rat embryos, CRL 3-16 mm, fixed, dehydrated, and paraffin embedded, were submitted to serial histological sections and stained by hematoxylin-eosin and Heidenhain's azan techniques. The images were digitalized by Canon Camera 350 EOS D. The serial views were aligned anatomically by software and the data were analyzed following segmentation and thresholding. The dorsal pancreas developed from the dorsal wall of the duodenum in stage 12, while the ventral pancreas arose from the ventral wall of the hepatic diverticulum in stage 13 and 14. The rotation of ventral pancreas started in stage 15 and was completed in stage 16. The fusion of both buds was evident in stage 17. In stage 23 the limit between dorsal and ventral bud was still marked by the pathway of superior mesenteric vein.

Decrease of bradykinin-induced glomerular contraction in diabetic rat: a new cellular interpretation.

The contractile response to bradykinin (BK), measured by the reduction of the planar surface area, was studied in glomeruli and mesangial cells (MC) isolated from diabetic rats (D) one week after diabetes induction with injection of streptozotocin (STZ; 60 mg kg-1, i.p.). Results were compared with age and weight-matched untreated rats (N) and were expressed by two parameters of cell activity, the mean maximum contraction (MMC) and the proportion of contractile cells (PCC). Glomerular and mesangial contraction were found to be clearly reduced in diabetic rats in response to 100 nM BK. The lower contractile response was associated with a decrease of both glomerular calcium uptake and mesangial cell intracellular calcium mobilization. The fact that cell pretreatment with two protein kinase C (PKC) inhibitors, phorbol 12-13 myristate acetate and calphostin, lowered normal cell contraction at the level of that found in diabetic MC without any significant effect in the latter, suggests the involvement of a PKC pathway, perhaps by a decrease of activatable PKC in diabetes. In addition, our results led to the first description of a possible role of the kallikrein-kinin system in the early glomerular hemodynamic changes occurring in diabetes. Insulin (1-200 nM) increased the contractile response of cultured diabetic cells (MMC), and in this case, it also increased the PCC. It must be stressed that the effect of 1 nM insulin on the former (88% increase) was very much smaller than its effect on the latter (103% increase). The combination of the two parameters (contraction index, CI) provided a realistic evaluation of the contractile capacities of the cell population of the cultures as a whole. The differences in this index between normal and diabetic cell populations, in the absence or presence of insulin, were strictly parallel to those found in intact glomeruli. Finally, our results further confirm (Ouardani et al., Biol. Cell 86, 127, (1996)) the limit of the first five cell passages within which cultured MC can be reasonably used for the study of contractile abnormalities occurring in the early steps of diabetic state.

An hypothesis for the interpretation of the contractile response of vascular smooth muscle at the cellular level.

The long preservation and recovery of functional (contractile) properties in cultured aortic smooth muscle cells, even after replating or deep-frozen storage and the measurement of their responses are now technically settled issues. We could thus study extensively the responses of single cultured cells from rat thoracic aorta. Responses were elicited by the addition of KCl 40 mmol/L without or with a calcium blocker PN 200-100 (10(-6) mol/L); angiotensin II (10(-11)-10(-6) mol/L) without or with antagonist (losartan 10(-5) mol/L); or serotonin (10(-9)-10(-4) mol/L) without or with antagonist (naftidrofuryl 10(-5) mol/L). Results thus obtained enabled us to propose a new hypothesis for the interpretation of the contractile responses of an elastic vascular smooth muscle. The different maximal effects of different agonists result mainly from the different proportions of cells they can mobilize; the agonist concentration-contraction relationship is mainly due to the increase of the proportion of cells involved up to a maximal value typical of the agonist used. An antagonist primarily reduce the proportion of cells an agonist can mobilize. Some of the consequences of this hypothesis are briefly outlined.

Loss of differences in mesangial cell phenotype between diabetic and normal rats: role of culture passages.

In mesangial cells (MC) isolated from streptozotocin (STZ)-induced diabetic rat kidneys, sensitivity to bradykinin (BK) for the induction of cell division and collagen synthesis, was found to be lower than in normal MC. Nevertheless, decreased activities could be reverted in vitro by insulin, at non-proliferative concentration (Girolami et al (1995), Can J Physiol Pharmacol 73, 848-853). The aim of the present study was to determine whether differences in the properties of diabetic MC could be ascribed to the diabetic state per se, and/or to experimental conditions, ie culture replating. Through successive cell replating, normal and diabetic types of MC were compared in terms of proliferation, contraction, free calcium concentration in response to KCl depolarization, and in relation to the expression of two cytoskeleton proteins specific to muscle cells, myosin and dystrophin. Studies of proliferation, contraction and free calcium concentration consistently showed that passage 5 was a limit beyond which differences between the two MC types were very small and sometimes non-significant. We found that the mean maximum contraction (MMC) and especially the proportion of contractile cells (PCC) among diabetic cells was lower than in normal MC. In addition, loss in proliferation activity and in [Ca2+]i concentrations were also found to occur during these five early passages. Dystrophin, a new marker of contractile phenotype recently described in smooth muscle cell (Leis et al (1994) Cell Biol Toxicol 10, 305), was first localized in MC and was compared with myosin also expressed in MC. However, during the course of cell replating and/or with the diabetic state, no visible quantitative changes were detected in the expression of the two contractile proteins. We conclude that cultured mesangial cells undergo phenotype modulations, as observed in other cells, in particular smooth muscle cells and consequently, comparative studies between normal and diabetic MC should not be carried out after the 5th passage.

Parallel expression level of dystrophin and contractile performances of rat aortic smooth muscle.

We have recently shown that the expression of dystrophin was in line with the conservation of contractility in primary and subcultured vascular smooth muscle cells (VSMC). In this report, we provide experimental evidence that shows the existence of a gradient in dystrophin expression from the aortic arch to the region just above the diaphragm, in line with a parallel gradient of contractility. On the contrary, there were no differences in caldesmon and smooth muscle myosin expression, as previously shown for vimentin and alpha-smooth muscle actin [Osborn, M., Caselitz, J., and Weber, K. (1981) Differentiation 20, 196-202]. Overall, this is the first demonstration, in a normal adult smooth muscle, of a differential expression of dystrophin, in line with its contractile performances. In addition, these results suggest that the experimental modulation of dystrophin expression in cultured VSMC in line with their contractility was the manifestation in vitro of an actual physiological property of those cells in vivo.

A simple method for the quantitative evaluation of functional effects of xenobiotics with cultured cells.

We present a simple, noninvasive, nondestructive all-purpose method for the quantitative evaluation of functional effects of xenobiotics with cultured cells and the work station for its routine, easy implementation. At present 1 to 150 cells growing in one to six dishes can be studied in parallel or otherwise at time intervals ranging from 10 s to 6 h or more, over periods of time ranging from a few tens of minutes to 3-4 days. Any aspect of cell physiological behavior can be studied (differentiation-dedifferentiation, migration, division, degeneration, death) without preliminary staining and/or fixation provided it results in optically visible changes.

Dystrophin does not influence regular cytoskeletal architecture but is required for contractile performance in smooth muscle aortic cells.

Cultured vascular smooth muscle cells express distinct histological phenotypes due to a contractile to synthetic stage transition. In this study, we compared the behaviour of cultured aortic smooth muscle cells from young normal and mdx mice. Morphological, immunobiochemical, immunocytochemical analyses and contraction studies of these cells demonstrated that (i) the cell cytoskeleton in mdx mice is not affected by the absence of dystrophin since proteins such as caldesmon, a-actin, and vinculin are expressed similarly in normal mice, (ii) utrophin (or dystrophin-related protein) overexpression does not compensate for the physiological and functional role of the lacking dystrophin. These data suggested that dystrophin and utrophin cannot substitute one another and may play different or complementary roles within smooth muscle cells.

Dystrophin (Xp21), a new phenotype marker of cultured rat aortic myocytes.

Dystrophin is a low-abundance cytoskeletal protein involved in the maintenance of membrane integrity in striated muscle. Very little is known about its role in smooth muscle. Utrophin (a dystrophin-related protein) is an ubiquitous protein whose role is still unclear. Changes in the expression of both proteins (if any) during phenotypic modulation of smooth muscle have not yet been reported. In contrast, modulated expression of heavy-molecular-weight caldesmon (h-CaD), a well-known specific regulatory protein of the contractile apparatus in smooth muscle, is well documented, along with its nonmuscle isoform, low-molecular-weight caldesmon (1-CaD), and other cytoskeletal proteins. We investigated three properties of cultured rat aortic smooth muscle cells: morphology, contractile ability, and expression of dystrophin, utrophin, h-CaD, and 1-CaD. Cells were grown either in serum substitute supplemented medium (U-medium), where they reexpressed contractility, or in fetal calf serum-supplemented medium (F-medium), where they did not. It was found that only cultures grown in U-medium continued expressing dystrophin, even during the proliferation phase, contrary to cells grown in F-medium. However, when F-medium was changed for U-medium the cells recovered their contractility and reexpressed dystrophin. Expression of utrophin, h-CaD, and 1-CaD was similar in both culture types. Dystrophin was demonstrated to be a true phenotype marker of cultured rat aortic smooth muscle cells, particularly with respect to their actual contractility.

High sensitivity of hypertensive aortic myocytes to norepinephrine and angiotensin.

Single-mass primary cultures were used for as long as 5 wk as the source of subcultured vascular smooth muscle cells for the study of their change of shape on the addition of agonists. We have compared the responses to angiotensin II, vasopressin, norepinephrine, and serotonin of myocytes derived from three different areas or the thoracic aorta (aortic arch and midthoracic and diaphragm areas) of adult Wistar-Kyoto normotensive rats (WKY) and spontaneously hypertensive rats (SHR). Once in secondary culture, vascular myocytes displayed different mean sizes according to their origin along the organ, as previously described in freshly dispersed aortic myocyte suspensions. Responses of the cells from the area of the aortic arch of both strains had the maximal amplitude to all agonists. Angiotensin and norepinephrine were more potent on myocytes derived from the three areas in SHR than in WKY. As this hypersensitivity persisted even after 5 wk in culture, it is believed to be pressure independent and thus might have a genetic rather than an adaptive origin.

Differential expression of voltage-gated Ca(2+)-currents in cultivated aortic myocytes.

The expression of different types of Ca(2+)-channels was studied using the whole-cell patch-clamp technique in cultured rat aortic smooth-muscle myocytes. Ca(2+)-currents were identified as either low- or high voltage-activated (ICa,LVA or ICa,HVA, respectively) based on their distinct voltage-dependences of activation and inactivation, decay kinetics using Ba2+ as the charge carrier and sensitivity to dihydropyridines. The heterogeneity in the functional expression of the two types of Ca(2+)-channels in the cultured myocytes delineated four distinct phenotypes; (i), cells exhibiting only LVA currents; (ii), cells exhibiting only HVA currents; (iii), cells exhibiting both LVA and HVA currents and (iv), cells exhibiting no current. The myocytes exclusively expressed HVA currents both during the first five days in primary culture and after the cells had reached confluence (> 15 days). In contrast, LVA currents were expressed transiently between 5 and 15 days, during which time the cells were proliferating and had transient loss of contractility. Thus, both LVA and HVA Ca(2+)-current types contribute to Ca(2+)-signalling in cultured rat aortic myocytes. However, the differential expression of the two Ca2+ current types associated with differences in contractile and proliferative phenotypes suggest that they serve distinct cellular functions. Our results are consistent with the idea that LVA current expression is important for cell proliferation.

Responses of subcultured rat aortic smooth muscle myocytes to vasoactive agents and KCl-induced depolarization.

We have developed a culture system in which a single-mass primary culture can be used for as long as 6 wk as a source of subcultured smooth muscle myocytes for the study of the changes of their shape upon addition of vasoactive agents (angiotensin, vasopressin, norepinephrine, and serotonin) and KCl depolarization. Responses of subcultivated myocytes were shown to be reproducible with time in primary culture before subculture and consistent with responses of thoracic aorta to the same agents. Effect of KCl depolarization could be blocked with calcium antagonist PN 200-110. Consistently, the presence of calcium L-channels was shown using whole cell patch-clamp recordings. A comparative study of the responses of myocytes derived from two different segments of the thoracic aorta showed that these cells displayed responses with different maximal amplitudes and the same potencies according to their topological origin in the vessel.

Effects of naftidrofuryl on the contraction and proliferation of cultured myocytes evoked by serotonin.

We investigated the effects of 2-(diethylamino)-ethyl-tetrahydro-alpha-(l-naphthylmethyl)-2-furanpro pionate (naftidrofuryl) on both the contraction and the proliferation of cultured rat aortic myocytes elicited by serotonin. Cells were cultured under controlled conditions, both on microcarrier beads and in microwells. The results show that naftidrofuryl alone had no effect on the properties of vascular smooth muscle cells. However, in the presence of serotonin, naftidrofuryl inhibits the contraction and the proliferation of smooth muscle cells.

Modulation of the accumulation of inositol phosphates and the mobilization of calcium in aortic myocytes.

In vascular smooth muscle cells the phorbol ester, 12-O-tetradecanoyl phorbol 13-acetate (TPA), a potent activator of C-kinase, inhibited the accumulation of inositol phosphates and the mobilization of calcium produced by several agonists. In the same way, TPA inhibited the fluoride-induced activation of phosphoinositide metabolism. These results suggest a C-kinase action at a post-receptor level. Moreover, the fluoride-induced accumulation of inositol phosphates shows the presence of one or more guanine nucleotide-binding proteins (G-proteins) in the regulation of receptor-phospholipase C coupling. This was confirmed by the use of N-ethylmaleimide and pertussis toxin. These results support the view that, in addition to the induction of sustained contractions, C-kinase can activate negative feedback mechanisms in aortic myocytes.

Study of living single cells in culture: automated recognition of cell behavior.

An automated system capable of analyzing the behavior, in real time, of single living cells in culture, in a noninvasive and nondestructive way, has been developed. A large number of cell positions in single culture dishes were recorded using a computer controlled, robotized microscope. During subsequent observations, binary images obtained from video image analysis of the microscope visual field allowed the identification of the recorded cells. These cells could be revisited automatically every few minutes. Long-term studies of the behavior of cells make possible the analysis of cellular locomotary and mitotic activities as well as determination of cell shape (chosen from a defined library) for several hours or days in a fully automated way with observations spaced up to 30 minutes. Short-term studies of the behavior of cells permit the study, in a semiautomatic way, of acute effects of drugs (5 to 15 minutes) on changes of surface area and length of cells.

Quantitative method for the study of the morphological changes induced by vasoactive agents in single aortic myocytes grown in primary cultures.

Morphological changes of aortic myocytes grown in primary cultures on collagen gels, were induced by two adrenergic agonists, in the absence or presence of specific antagonists. Their effects were quantified by means of the measurement of the surface areas of the images of the cells. The alpha-adrenoreceptor agonist phenylephrine induced a concentration-dependent decrease of the surface areas of the images of the cells, which was competitively antagonized by phentolamine, and was reduced in the presence of CdCl2 (an inhibitor of calcium entry). The beta-adrenoreceptor agonist isoproterenol induced an increase in the surface areas of the images of prostaglandin F2-alpha pretreated cells and this effect was antagonized by propranolol. It is concluded that the morphological changes of myocytes in primary culture, induced by phenylephrine or isoproterenol can be quantified by the measurement of the surface areas of their images. These changes were in good agreement with the response of isolated thoracic aorta rings or strips to the same agonists with regard to their sensitivity, specificity, and kinetic features. Thus the measurement of the changes of the surface area of the images of myocytes induced by vasoactive agents constitutes a noninvasive, nondestructive method for the quantification of their responses to these agents at the single cell level.

Differences in myocyte subpopulations from segments of the thoracic aorta and their modifications with age and hypertension in the rat.

Smooth muscle cells obtained from three distinct segments of the thoracic aorta of both Wistar Kyoto (WKY) and Spontaneously Hypertensive Rats (SHR) taken at different stages of development were studied in terms of their volume, DNA content in single cell suspensions, and doubling time in primary cultures. The proliferative activity and mean cell volume of myocytes from WKY rats increase along the thoracic aorta in a gradient from the aortic arch to the diaphragm. The slope of this gradient is increased in SHR because of an extension of the area that contains myocytes with low proliferative activity in primary cell culture and large cell volumes in suspension. Tetraploid myocytes are found in both strains and their proportions are larger in SHR than in WKY, specifically after the onset of hypertension. However, they appear to be evenly distributed along the thoracic aorta with a size distribution that is included in that of the diploid cells from the same area. It is suggested that changes in the structural properties of the aortic-cell compartment, associated with maturation and hypertension, reflect quantitative changes in the relative proportions of several myocyte subpopulations within the aorta of the rat.

V1a vasopressin-induced accumulation of inositol trisphosphate in cultured rat aortic myocytes; modulation by protein kinase C.

Arginine vasopressin stimulated the accumulation of labeled inositol phosphate in cultured rat aortic myocytes prelabeled with tritiated myo-inositol. This accumulation was prevented by pretreating the myocytes with the phorbol ester PMA. The time-course and concentration-effect curves were similar for inositol phosphate formation in myocytes and contractile effects on isolated aorta. Vasopressin agonists also stimulated inositol phosphate formation, whereas vasopressin-induced response could be inhibited by V1a-specific antagonists. These results suggest that stimulation of inositol phosphate formation in myocytes is due to V1a receptor activation and could be modulated by protein-kinase-C-mediated mechanisms.

Mechanical responses of rat vascular smooth muscle cells to rat interferon.

Mechanical responses elicited by rat interferon (IFN) were investigated in rat vascular smooth muscle cells (RVSMC) in primary culture. IFN induced a dose-dependent reduction in the apparent cell surface area, which was quantitatively comparable to, or even greater than, the response elicited by the alpha-adrenergic agent, phenylephrine. Neither mock-IFN nor rat IFN-neutralized with specific antibodies elicited such a response. The sensitivity of RVSMC to the mechanical effect of IFN was species specific. In addition, the effect of IFN was inhibited by the Ca2+ entry blocker, verapamil.

Activation of phosphatidylinositol synthesis by different agonists in a primary culture of smooth muscle cells grown on collagen microcarriers.

Regulation of inositol phosphate synthesis was examined in a primary culture of vascular smooth muscle cells grown on collagen-coated microcarriers. In the presence of LiCl (10 mM), four agonists [serotonin, angiotensin, (arginine) vasopressin and noradrenaline] were found to stimulate the formation of inositol phosphates in a dose-dependent manner. All agonists were found to have identical and additive effects on the time course of inositol phosphate formation. Therefore, our primary cell culture technique was proved to give smooth muscle cells suitable for the study of modulation of phosphoinositide metabolism in response to physiological effectors.