The basalis of the primate endometrium: a bifunctional germinal compartment

Radioautographic analysis of epithelial and stromal cell proliferation in the primate endometrial functionalis and basalis (rhesus monkey) has identified horizontal zonal patterns of mitotic activation and inhibition during natural menstrual cycles. At 1 h after a single i.v. injection of [3H]thymidine, mitotic activity in endometrial biopsies (hysterotomy) was determined on 9 days from the late proliferative to the late luteal phase (-2 days to + 14 days relative to the estrogen [E2]peak). Labeling indices (LIs) were determined within glandular segments of the 4 horizontal endometrial zones: Transient functionalis Zone I (luminal epithelium) and Zone II (uppermost gland); Germinal basalis: Zone III (middle gland) and Zone IV (basal gland). The size of the dividing epithelial populations (LI) differed zonally. During E2 dominance (-2 days to +3 days), the epithelial LIs of functionalis I (10 +/- 0.3%) and II (9.8 +/- 1.0%) were greater than those of basalis III (5.8 +/- 0.2%) and basalis IV (3.7 +/- 0.8%). During progesterone (P) dominance (+5 days to +14 days), epithelial mitosis was strongly inhibited in functionalis I (4.3 +/- 1.9%), functionalis II (0.8 +/- 0.2%), and basalis III (1.4 +/- 0.5%). Thus germinal basalis III was linked functionally with transient functionalis I and II by periovulatory uniformity in epithelial proliferation and postovulatory mitotic inhibition. A unique mitotic pattern set basalis IV apart from other zones by a steady rise in LI from 1% (-2 days) to 11% (+10 days). The LIs for stromal fibroblasts remained quite uniform in basalis IV but varied in other zones. Thus the postovulatory primate basalis was a distinct bipartite compartment in which the mitotic rate in basalis IV glandular epithelium increased steadily whereas that of basalis III was strongly inhibited. The remarkable enhancement of epithelial mitotic activity in basalis IV may reflect expansion of the stem-progenitor cell population for gestational growth or for post-menstrual regeneration.     

Ultrastructural epithelial zonation of the primate endometrium (rhesus monkey)

The uterine endometrium of menstruating primates (rhesus monkey, human) consists of a germinal basalis that regenerates a transient functionalis during each menstrual cycle. The endometrium is further subdivided into 4 zones that differ histologically and in epithelial mitotic rate along the longitudinal axes of the uterine glands and microvasculature (Bartelmez et al: Contrib. Embryol. Carnegie Inst., 34:99-146, 1951; Bartelmez: Am. J. Obstet. Gynecol., 74:931-955, 1957; Padykula et al.: Biol. Reprod., 32:1103-1118, 1118, 1984; Biol. Reprod., in press, 1988). The zones are defined as follows: functionalis I, luminal epithelium; functionalis II (upper straight gland segments); basalis III (middle gland segments), and basalis IV (bottoms of the glands). The surrounding stroma and microvasculature also differ zonally. Ultrastructural epithelial differences are evident among the 4 zones during 3 distinct functional states during natural menstrual cycles and after ovariectomy: 1) basal level after ovariectomy and 2) estrogen dominance and 3) progesterone dominance. Zonal structural differences persist at a minimal level of differentiation after ovariectomy and thus zonation is an inherent property. During estrogen dominance, distinctive ultrastructural differences are evident among the 4 zones, such as epithelial cell heterogeneity in functionalis I and homogeneity in functionalis II. Also a distinctive glandular cell type occurs in basalis III and IV that is recognized by a highly irregular cisternal rough endoplasmic reticulum that permeates the cytoplasm. During progesterone dominance, ultrastructural differences exist among the 4 zones except for similarity between the epithelial cells of functionalis II and basalis III. Postovulatory epithelial cells of functionalis I and II and basalis III become postmitotic via progesterone inhibition but intracellular differentiation continues progressively. Postovulatory epithelial mitotic activity in basalis IV escapes progesterone inhibition as the [3H]thymidine labeling index continues to increase from 1 to 12% during the menstrual cycle (Padykula et al.: Reprod., 30(Suppl.1):92 (Abstr. 123), 1984). This post-ovulatory proliferation coupled with progressive differentiation in basalis IV may represent a stem-progenitor set of cells for postmenstrual endometrial regeneration or alternatively for creation of the maternal placenta.     

THE SMALL PYRAMIDAL NEURON OF THE RAT CEREBRAL CORTEX : The Axon Hillock and Initial Segment

The axon of the pyramidal neuron in the cerebral cortex arises either directly from the perikaryon or as a branch from a basal dendrite. When it arises from the perikaryon, an axon hillock is present. The hillock is a region in which there is a transition between the cytological features of the perikaryon and those of the initial segment of the axon. Thus, in the hillock there is a diminution in the number of ribosomes and a beginning of the fasciculation of microtubules that characterize the initial segment. Not all of the microtubules entering the hillock from the perikaryon continue into the initial segment. Distally, the axon hillock ends where the dense undercoating of the plasma membrane of the initial segment commences. Dense material also appears in the extracellular space surrounding the initial segment. The initial segment of the pyramidal cell axon contains a cisternal organelle consisting of stacks of flattened cisternae alternating with plates of dense granular material. These cisternal organelles resemble the spine apparatuses that occur in the dendritic spines of this same neuron. Axo-axonal synapses are formed between the initial segment and surrounding axon terminals. The axon terminals contain clear synaptic vesicles and, at the synaptic junctions, both synaptic complexes and puncta adhaerentia are present.     

Identification of the subunit proteins of 10-nm neurofilaments isolated from axoplasm of squid and Myxicola giant axons

Neurofilaments were isolated from the axoplasm of the giant axons of Myxicola infundibulum and squid. The axoplasm was fractionated by discontinuous sucrose gradient centrifugation and gel filtration on Sepharose 4B. The fractions were monitored for neurofilaments by electron microscopy. When isolated in the presence of chelating agents, the neurofilaments of Myxicola are composed almost entirely of protein subunits with mol wt of 150,000 and 160,000. Squid neurofilaments contain two major proteins with mol wt of 200,000 and 60,000. These proteins are compared with other intermediate filament proteins which have been reported in the literature.     

Neurofilamentous network and filamentous matrix preserved and isolated by different techniques from squid giant axon

The contribution of the neurofilamentous network to the structure of the squid giant axon was analyzed electron-microscopically. Axial 10-nm filaments cross-linked by radial 5-nm bridges form a network that is present in preparations prepared by a variety of techniques. The axoplasm is differentiated into dense and less dense regions. In the presence of Co(II) ions, the neurofilamentous network was remarkably well preserved and appeared to be associated with a dense web of fine filament matrix, which also was identified in extracted axoplasm and in fractions enriched with neurofilament protein complex. In the presence of La(III) ions, the neurofilamentous network had a coarse and open appearance. The stereo images of extracted and critical-point dried axoplasm suggested that the neurofilamentous network contains ordered lattice-like regions. Extracted preparations of extruded axoplasm and fractions enriched with neurofilament protein complex suggested that the properties of the network are determined by the neurofilament protein complex. It is proposed that the neurofilamentous network is the essential determinant of the form of the axon, and that the order within the network is determined by the radial components of the network. The structures observed in the different preparations are not artifacts, but rather are related closely to their native state in the axon.     

Helical substructure of neurofilaments isolated from Myxicola and squid giant axons

Neurofilaments purified from invertebrate giant axons have been analyzed with the electron microscope. The neurofilaments have a helical substructure which is most easily observed when the neurofilaments are partially denatured with 0.5 M KCl or 2 M urea. When the ropelike structure comprising the neurofilaments untwists, two strands 4--5.5nm in diameter can be resolved. Upon further denaturation these strands break up into rod-shaped segments and subsequently these segments roll up into amorphous globular structures. Stained, filled densities can be resolved within the strand segments, and these resemble similar structures observed within the intact neurofilaments. The strands appear to consist of protofilaments 2--2.5 nm in diameter. These observations suggest that the neurofilament is a ropelike, helical structure composed of two strands twisted tightly around each other, and they su-port the filamentous rather than the golbular model of intermediate filament structure.     

The small pyramidal neuron of the rat cerebral cortex

Summary The pyramidal neurons in layers II and III of the rat parietal cortex have dendritic spines which form synapses with axon terminals. These synapses have synaptic clefts containing granular material that is concentrated towards the middle of the cleft to form a plaque. Only a small amount of dense material occurs on the cytoplasmic face of the presynaptic membrane, while there is a prominent dense layer, some 300 Å deep, in the dendritic spine. When the synapses formed by the smallest dendritic spines are examined in a frontal or en face plane of section this postsynaptic density has the form of a disc. In the synapses on larger spines, the disc is perforated to form a ring, and in the largest spines a number of perforations may occur. Because of these perforations, in larger synapses sections passing at right angles to the plane of the synaptic junction may show two or more separate postsynaptic densities. The possible significance of these findings is discussed.This work was supported by United States Public Health Service Research Grant No. NB-07016 from the National Institutes of Neurological Diseases and Blindness. The authors wish to express their sincere thanks to Lawrence McCarthy and Charmian Proskauer for their valuable assistance.