ABSTRACT
The mode of outgrowth of the pronephric duct has been investigated by examining the mitotic index and migratory propensities of duct cells.
There is no indication of duct elongation through terminal proliferation or of high proliferative activity throughout the duct that does not merely reflect the generally high growth rate of the embryo as a whole.
Explants of the trunk region cultured in plasma clots showed cylindrical extensions of pronephric duct cords into the clot prior to outgrowth of other cell types.
It is concluded that in the species studied, duct outgrowth is an essentially migratory phenomenon, and that the nephric epithelial cells have the ability to form cords of roughly normal diameter in a non-cellular environment.
INTRODUCTION
Although the manner in which the developing amphibian pronephric duct extends posteriorly has been studied rather extensively, it has not been clear whether this posterior outgrowth is largely the result of proliferative activity or whether it is due to migration of cells from an anterior level (Cambar, 1949). Holtfreter (1939) has demonstrated a marked migratory tendency in these cells from early gastrula stages in Rana esculenta, but a high mitotic count towards the posterior duct tip has been reported in Triton alpestris (Mollier, 1890), suggesting that proliferation may play a significant role. Furthermore, proliferation appears to be an important factor in elongation of the pronephric duct of the chick (Overton, 1958). This problem has now been examined more closely in a number of amphibian species in the hope that a more precise understanding of the mode of duct outgrowth might throw some light on the question of how the direction taken by the outgrowing duct is controlled. In experiments with anuran and urodele embryos (for reviews, see Holtfreter, 1944; Cambar, 1949; Fraser, 1950; Burns, 1955) there is evidence that the normal duct path exerts some influence on the direction in which the duct extends. Conceivably such an influence could be exerted in part through enhancement of terminal proliferation; however, counts of resting and dividing cells throughout the duct in various developmental stages, together with the behaviour of explants grown in plasma clots, strongly suggest that duct outgrowth in the species studied is an essentially migratory phenomenon.
MATERIALS AND METHODS
Experimental material consisted of Ambystoma opacum, A. punctatum, and A. tigrinum embryos, Ambystoma species collected locally (probably A. punctatum and A. jeffersonianum), and R. pipiens embryos obtained by the method of Rugh (1934). Embryos were kept on a water table where the temperature range was obtained by recording the temperature three to four times during a 24-hour period.
For mitotic studies urodele embryos were fixed in Bouin’s at Harrison stages 29 to 34 (Rugh, 1948), stage 34 being the time at which the duct reaches the cloaca. Embryos were cut in cross-section and stained in Harris’ haematoxylin. Mitotic figures in late prophase through telophase were counted in every section of the duct, those occurring in more than one section being recorded only once. The number of resting nuclei in each section was also counted. The relative frequency of mitotic figures was obtained for each successive group of ten sections, or 100 μ. lengths of the duct, and expressed as mitoses /1,000 nuclei. This index, although adequate as a basis for comparing mitotic activity in one part of the duct with that in another, is, of course, not an accurate measure of mitotic frequency (see Abercrombie, 1946). Since ducts were of different lengths in different embryos, or even on right and left sides of the same embryo, in averaging counts from different cases the posterior end of the duct was taken as the point of reference. The posterior tip of the duct could be clearly distinguished in A. tigrinum embryos, but this was not always true in A. opacum and A. punctatum embryos. In such cases several sections beyond the point where the duct could be clearly identified were included in the examination. Mitotic counts were made in epidermis of these same embryos for purposes of comparison. Cell counts were made in epidermis of one section of the trunk, and mitoses were counted in five alternate sections. Mitotic indexes arrived at on this basis are not comparable with indexes as determined for the pronephric duct for purposes of assessing relative mitotic frequency, but are nevertheless useful in comparing trends towards greater or less activity in different developmental stages.
In experiments with explants embryos of R. pipiens were used as well as those of the three urodele species. In preliminary experiments the nephric ridge was isolated from embryos in Harrison stages 23 to 28, or in equivalent stages in frog embryos, and cultured in a variety of media. In a few cases R. pipiens explants cultured in Holtfreter’s solution on glass developed sprout-like extensions, although such explants generally developed very poorly. Therefore another method was devised in which a sizable portion of the embryo was explanted (see Text-fig. 1). A saddle of mesoderm, including the notochord and neural tube, was removed and stripped of ectoderm. The posterior edge of the explant was usually cut to include, but in some cases to exclude, the posterior duct tip. Such explants were cultured first in a variety of media, and finally in a soft clot consisting of Holtfreter’s solution (modified by the addition of dextrose, 1 part per thousand, and 0-5 per cent, sodium sulphadiazine), amphibian peritoneal fluid (see Rugh, 1948, p. 228), and freshly drawn chick plasma, 1:1:1. Chick embryo extract suitably diluted was later substituted for peritoneal fluid, and used with commercially prepared desiccated chick plasma, giving essentially the same results, although the first medium appeared somewhat more satisfactory. Explants were cultured on coverslips in depression slides. Cultures were maintained at room temperature (20–23° C.) except for a single series cultured at 27° C.
RESULTS
Spatial mitotic distribution. Counts of resting and dividing cells were made throughout the pronephric duct in three urodele species. These counts included 29 cases in A. opacum, stages 29–34 (14–15° C.); 23 cases in A. tigrinum, stages 29– 33 (16– 18° C.); and six cases in A. punctatum, stage 30 (18°C.). Although there were differences in the mitotic frequency between embryos of different species, and between different cases within the same species, there appeared to be no trend in individual cases towards anything other than a random spatial distribution of mitotic activity. Since the cell count in any single 100-(u length of the duct is small, it seemed possible that combined counts would show some trend. However, as illustrated in Text-fig. 2, combined values for the three species indicate no tendency towards high terminal proliferation. On the contrary, the mitotic frequency is fairly regular throughout the length of the duct. Differences in overall mitotic activity which occur presumably reflect differences in growth rates of the three species.
Spatial distribution of mitotic activity in the elongating pronephric duct. Solid circles, A. tigrinum’, open circles, A. punctatum’, open squares, A. opacum. For explanation see text.
Temporal mitotic distribution
If earlier and later stages are compared within the same species, although no spatial pattern in mitotic activity is evident, there is a definite trend towards lower mitotic frequency in later stages. Counts in A. tigrinum and A. opacum for entire pronephric ducts are grouped by stages and compared in Text-fig. 3.
Temporal mitotic pattern in the developing pronephric duct compared with that in epidermis. See text.
In the two species studied, it can be seen that the mitotic index is high in earlier stages, while the duct is growing posteriorly towards the cloaca. It drops gradually to a lower level as the duct reaches the cloaca at about stage 34. This drop, however, probably reflects only a general decrease in growth rate of the embryo, since the mitotic frequency in epidermis in these same embryos shows a similar trend (see Text-fig. 3).
In evaluating the role of proliferation in outgrowth of the duct, although no terminal proliferative region is present, the possibility must be considered that the entire duct material grows at a rather higher rate than the rest of the embryo during this period at which it is extending. Although Text-fig. 3 would suggest that there is no very marked difference between pronephric duct and epidermis, as was indicated above, the duct cell count was subject to a counting error while the mitotic count was not. Since nuclear size is large (c. 10 μ) compared to section thickness, this makes the actual difference in mitotic frequency between epidermis and duct considerable (see Abercrombie, 1946). Duct cells, then, have a higher mitotic index than epidermis, but a comparison with epidermis alone is incomplete and provides very little basis for evaluating the role of proliferation. It must also be remembered that the mitotic index, however accurate, is not itself a measure of proliferation. Although it is clear that proliferation occurs during duct outgrowth, there is no good evidence from mitotic data presented here that proliferation is a critical factor in permitting elongation of the duct. On the contrary, the observation that in a dissection, in surface view, the elongating strand of pronephric duct material appears to decrease in diameter by almost one-half between stages 29 and 34, suggests that elongation occurs largely through shifting of cells rather than proliferation.
Migratory propensity
If an explant such as that pictured in Text-fig. 1 is placed in a suitable medium, one might expect outwandering of cells on all sides. However, if the migratory propensity of pronephric duct cells is particularly high one would expect first to find the elongating duct cords extending into the medium from the posterior edge of the explant. This expectation was confirmed when explants were placed in plasma clots, though not usually in the diagrammatic manner illustrated in fig. A of the Plate. Here the two outgrowths extend posteriorly from the same place and in the same direction as they would have in the normal embryo. These extensions tend to be cylindrical in shape and to have a diameter roughly similar to that of the normal developing duct (see fig. B of the Plate). In two cases in which such extensions were sectioned, they appeared to be roughly spherical in cross-section, and to adhere closely to the clot. No particular orientation of cells or polarity is evident within such an outgrowth. This is also the case in very early developmental stages of duct elongation in the embryo. Conceivably, sprouting of blood-vessels into the clot might have occurred also but there was no indication from the character of the outgrowing cells or their arrangement either in living cultures or in sections that this was the case. When explants are grown on the glass surface beneath a clot, the same apparently pure epithelial outgrowth occurs, but it takes a different form. Cells spread out in a sheet, though a tendency towards linear outgrowth is still evident as indicated by occasional tongues of cells which move out from the advancing edge (see fig. C of the Plate). Cylindrical cords may extend into the clot in greater or fewer numbers, and in almost any direction relative to the anteroposterior orientation of the explant, as illustrated in figs. D, E, F, and G of the Plate. The direction of outgrowth from twenty explants (a total of 61 outgrowths) was traced from photographic negatives. These tracings were superimposed and no definite preferential direction of outgrowth was indicated. It seems probable that rather small differences in operative technique determine the particular pattern of the outgrowth in so far as the origin of these extensions is concerned. Cylindrical extensions occurred whether the posterior tip of the duct was included in the explant or not, and so it seems likely that a small cut or tear at the edge of the explant anywhere might permit outgrowth of duct cells into the clot. This would allow outgrowths at anterior levels which sometimes occur. Once outgrowth begins, it does not always continue in the same direction, that is, these extensions may bend (see Plate).
The first outgrowth from explants occurred after 1 to 2 days and these cords usually reached their fullest extent within a 24-hour period. Outwandering of other cell types occurred only later, making the originally smooth external contour of the explant highly irregular (compare figs. D and H of the Plate). In some cases the original epithelial cord became secondarily covered by fibroblasts or chromatophores which migrated out over its surface, and occasionally the nephric outgrowth became entirely concealed by abundant outwandering of all cell types. Such explants, though extremely diffuse, retained the main elements of their original organization. They remained in a healthy condition for as long as 2 weeks and showed indications of neuro-muscular differentiation as evidenced by sporadic twitching. Nephric rudiments developing within the explant became tubular, and often distended. Most cultures were maintained for only a week or less, since by this time all the changes described above had occurred. In one series of cultures kept at 27° C., there was rapid abundant outgrowth from the explant in all directions, so this procedure was abandoned.
Nephric outgrowths were obtained from explants of all three urodele species studied as well as from R. pipiens. Although mitoses occurred in these cultures, they did not appear to be particularly related to outgrowth of nephric cords. When two or more explants, or explants and cloacal rudiments, were placed in the same clot at varying distances and at various angles with respect to one another, no indications were obtained of any specific attractive effects such as occur in vivo (see, for example, Holtfreter, 1944; Bijtel, 1948).
DISCUSSION
Any assessment of the role of proliferative activity in duct elongation must, of course, be made on a comparative basis and considered in connexion with the geometric nature of the outgrowth. Although the data presented here are in some respects incomplete, as mentioned above, they are still sufficiently extensive to indicate that proliferation is probably unimportant as a factor in elongation of the duct. There is no indication of terminal proliferation, nor of any high proliferative rate during the period of duct outgrowth which does more than reflect the generally high growth rate of the embryo as a whole.
The migratory propensity of duct cells, although marked, is not unusually great. Migration of chromatophores, for example, appears to be equally rapid and extensive. However, at the developmental period coinciding with posterior extension of the duct, these epithelial cells have a higher migratory propensity than other cell types. Such a propensity has been demonstrated as early as the gastrula stage in R. esculenta (Holtfreter, 1939). Results of experiments in which the posterior part of the duct was excluded from the explant confirm the opinion of Nieuwkoop (1947) that ‘Every single cell of the Wolfian duct rudiment must have the power to migrate caudal wards…Duct elongation thus appears to be an essentially migratory phenomenon.
A tendency towards linear outgrowth of nephric epithelial cells was described by Holtfreter (1939), who observed pure epithelial cells extend in a band from explanted nephric material cultured on glass. Results of the present experiments confirm this observation and also suggest that not only the linear nature of the outgrowth but to some extent the cylindrical form and approximate calibre of the nephric cords can develop independently of a cellular environment.
Typically, epithelium cultured alone grows in sheets, and forms tubules only when embedded in fibroblasts, a phenomenon which has been extensively analysed recently (Grobstein, 1954). Although the outgrowths described here never develop a tubular structure, the ability of the plasma clot to support the development of some aspects of normal morphology is reminiscent of the report of Chlopin (1930) that tubules of the pancreas would form in a plasma clot in the absence of fibroblasts.
ACKNOWLEDGEMENTS
This work was aided by a grant from the American Cancer Society.
REFERENCES
EXPLANATION OF PLATE
FIG. A. A. punctatum explant in plasma clot at 2 days. Two chords of cells extend into the clot from the posterior edge of the explant on the right. Fixed preparation × 29.
FIG. B. A. species explant in plasma clot at 5 days. Outgrowth is limited to pronephric extension. Living preparation × 100.
FIG. C. A. punctatum explant at 4 days. Outgrowth on glass surface beneath clot. Fixed preparation × 100.
FIG. D. A. species explant at 5 days, one posterior and two lateral extensions. Posterior edge of explant is up. Living preparation x 27.
FIG. E. A. species explant at 7 days with six extensions. Posterior edge to the right. Fixed preparation × 22.
FIG. F. R. pipiens explant at day 5. A single posterior extension occurs to the right. Fixed preparation ×29.
FIG. G. R. pipiens explant at day 5. A single posterior extension has become flattened distally where it has grown against the glass surface. Fixed preparation × 29.
FIG. H. A. punctatum explant in plasma clot. By day 7, extensive migration of chromatophores and other cell types has occurred. Living preparation × 27.
FIG. A. A. punctatum explant in plasma clot at 2 days. Two chords of cells extend into the clot from the posterior edge of the explant on the right. Fixed preparation × 29.
FIG. B. A. species explant in plasma clot at 5 days. Outgrowth is limited to pronephric extension. Living preparation × 100.
FIG. C. A. punctatum explant at 4 days. Outgrowth on glass surface beneath clot. Fixed preparation × 100.
FIG. D. A. species explant at 5 days, one posterior and two lateral extensions. Posterior edge of explant is up. Living preparation x 27.
FIG. E. A. species explant at 7 days with six extensions. Posterior edge to the right. Fixed preparation × 22.
FIG. F. R. pipiens explant at day 5. A single posterior extension occurs to the right. Fixed preparation ×29.
FIG. G. R. pipiens explant at day 5. A single posterior extension has become flattened distally where it has grown against the glass surface. Fixed preparation × 29.
FIG. H. A. punctatum explant in plasma clot. By day 7, extensive migration of chromatophores and other cell types has occurred. Living preparation × 27.