Robert F. Payette

Neurofilament expression in vagal neural crest-derived precursors of enteric neurons☆

In order to gain insight into the potential role of the enteric microenvironment in the neuronal determination of the neural crest-derived precursor cells of enteric neurons, an attempt was made to ascertain when and where along the migratory route of these cells that they first express neuronal properties. The immunocytochemical detection of the 160-kDa component of the triplet of the chick neurofilament peptides served as a neuronal marker. In addition, neurogenic potential was assessed by growing explants of tissue suspected of containing presumptive neuroblasts in culture or as grafts on the chorioallantoic membrane of chick embryonic hosts. Neurofilament immunoreactivity was first detected in the foregut by Day 4 of development and spread to the hindgut by Day 7. Within the hindgut, development was more advanced within the colorectum than within the more proximal terminal ileum and caecal appendages. This probably reflects the distal-proximal migration of sacral neural crest cells in the postumbilical bowel. The ability of enteric explants to show neuronal development in vitro correlated with whether or not cells containing neurofilament immunoreactivity had reached that segment of gut at the age of explantation. These data suggest that enteric neuronal precursors have already begun to differentiate as neurons by the time they colonize the gut. Prior to the appearance of fibrillar neurofilament immunoreactivity in the foregut, cells that express this marker were found transiently within the mesenchyme of branchial arches 3, 4, and 5. These cells had disappeared from this region by developmental Day 6. The neurogenic potential of branchial arches 3 and 4 was demonstrated by the correlation that was found between the ability of explants of these arches to show neuronal development in vitro and the presence within them of cells that display neurofilament immunoreactivity. No similar neurogenic potential was found in the more rostral branchial arches which lacked the masses of neurofilament-immunoreactive cells. The location of the caudal branchial arches below the migrating vagal neural crest, the transience of the neurofilament immunoreactivity in them, and the coincident transience of their neurogenic potential in vitro, suggested that the masses of neurofilament immunoreactive cells in the caudal branchial arches might be vagal neural crest-derived neuronal precursor cells en route to the pharynx and the rest of the gut.(ABSTRACT TRUNCATED AT 400 WORDS)

Accumulation of components of basal laminae: Association with the failure of neural crest cells to colonize the presumptive aganglionic bowel of lsls mutant mice☆

Aganglionosis occurs in the terminal colon of the ls/ls mouse because an intrinsic defect of the presumptive aganglionic tissue prevents the entry and colonization of this portion of the bowel by migrating neural crest cells. The current study was undertaken to determine if abnormalities of the extracellular matrix could be identified in this segment that might account for migratory failure. Since basal laminae of the muscularis mucosa are overproduced in the aganglionic segment of adult ls/ls mice, we examined components of basal laminae in fetal gut from Day E 11 to Day E 16 of gestation. This period spans the time of enteric ganglion formation. Laminin and collagen type IV were studied by immunocytochemistry and proteoglycans by staining glycosaminoglycans with Alcian blue. Abnormalities of each of these components occur during development of the presumptive aganglionic bowel in the ls/ls mouse and could be detected as early as Day E 11. These defects consist mainly of an overabundance of these materials, both in defined basal laminae and throughout the extracellular space of the mesenchyme. Electron microscopic observations in the presumptive aganglionic ls/ls colon revealed a thickening of basal laminae and exceptionally wide intercellular spaces between smooth muscle myoblasts that contained an irregular fibrillar material, consisting of 4.5- to 6.0-nm filaments associated with 14- to 20-nm granules. Fibrillar and flocculant material was continuous with formed basal laminae, and was concentrated in the same areas found to have an overabundance of laminin immunoreactivity. These observations indicate that there is an accumulation of extracellular matrix material, including components of basal laminae, that (i) precedes the formation of enteric ganglia, (ii) is in the path through which enteric neural precursors from the crest would have to migrate, and (iii) is limited to the aganglionic and hypoganglionic ls/ls bowel. These data are consistent with the hypothesis that components of basal laminae contribute to the inability of crest cells to colonize the terminal bowel of ls/ls mice.

Thyroid medullary carcinoma of the Djungarian hamster Phodopus sungorus: ultrastructural evidence for the production of normal and atypical intracellular granules

We have carried out an electron microscopic and immunocytochemical study of thyroid medullary carcinoma arising spontaneously in the Djungarian hamster, Phodopus sungorus. At the ultrastructural level the cytoplasm of tumor cells contained numerous round to slightly elongated, dense-cored secretory granules. The number of secretory granules differed from cell to cell in the tumor, being scanty in some cells but more or less abundant in most. Electron microscopic-immunocytochemistry demonstrated that all dense-cored secretory granules in all tumor cells exhibited calcitonin immunoreactivity. In approximately 10% of the tumor cells, unusual star-shaped secretory vesicles were also found in the cytoplasm. These vesicles contained a small, but well-defined, lucent core surrounded by a region of finely granular material of greater electron density. The outer contour of these unusual vesicles was stellate rather than smooth. They appeared to originate not from the Golgi complex, but from the rough endoplasmic reticulum. These atypical stellate vesicles did not show any calcitonin immunoreactivity. Furthermore, in a small number of tumor cells (approximately 1%) a third type of membrane enclosed structure was found. These were conspicuous rods 1-5 micron in length with tapering ends and a crystalline substructure. The presence of both normal and atypical secretory granules in some tumor cells suggests that carcinogenic transformation may interfere with the normal synthesis and assembly of secretory products by the cell.SummaryWe have carried out an electron microscopic and immunocytochemical study of thyroid medullary carcinoma arising spontaneously in the Djungarian hamster,Phodopus sungorus. At the ultrastructural level the cytoplasm of tumor cells contained numerous round to slightly elongated, dense-cored secretory granules. The number of secretory granules differed from cell to cell in the tumor, being scanty in some cells but more or less abundant in most. Electron microscopic-immunocytochemistry demonstrated that all dense-cored secretory granules in all tumor cells exhibited calcitonin immunoreactivity. In approximately 10% of the tumor cells, unusual star-shaped secretory vesicles were also found in the cytoplasm. These vesicles contained a small, but well-defined, lucent core surrounded by a region of finely granular material of greater electron density. The outer contour of these unusual vesicles was stellate rather than smooth. They appeared to originate not from the Golgi complex, but from the rough endoplasmic reticulum. These atypical stellate vesicles did not show any calcitonin immunoreactivity. Furthermore, in a small number of tumor cells (∼1%) a third type of membrane enclosed structure was found. These were conspicuous rods 1–5 μm in length with tapering ends and a crystalline substructure. The presence of both normal and atypical secretory granules in some tumor cells suggests that carcinogenic transformation may interfere with the normal synthesis and assembly of secretory products by the cell.