Nuclear pores during the cell cycle in a slime mold, physarum polycephalum

Giardia lamblia: behavior of the nuclear envelope

Giardia Lamblia is a flagellar parasite possessing the unusual morphology of bearing two nuclei. New morphological observations on trophozoites and encysting Giardia nuclei using routine transmission electron microscopy, freeze fracture and cytochemistry are presented. Nuclear pores of both nuclei in the same cells were assessed on freeze-fracture replicas from different cell cycle phases, and compared. These techniques showed that (1) both nuclei in the same cell are distinct in nuclear pore number and distribution; (2) nuclear pore complexes are frequently clustered in nuclear envelope domains; (3) dividing nuclei display very few nuclear pores; (4) few ribosomes are found on the outer nuclear envelope of the trophozoite form; (5) nuclear membranes present spots of closely apposed membranes, which are different from the typical diaphragm nuclear pore complexes; (6) in addition to the nuclear pores, membrane blebs are also present in the nuclear envelope; (7) encysting cells show intranuclear inclusions, morphologically similar to the ESV (encystation-specific vesicles) and to the ER membranes, which may be the result of nuclear envelope folding. It is proposed that the two nuclei in Giardia are dissimilar in morphology and activity.

Sertoli cell nuclear pore number changes in some stages of the spermatogenic cycle of the rat seminiferous epithelium

In an earlier study we described changes in the number and distribution of nuclear pores during maturation of germ cells at given stages of the spermatogenic cycle; these changes were related to the activity of nucleus-cytoplasm transport. Similarly, the present work was performed by combining freeze-fracture techniques with Sertoli nuclei identification criteria, using fragments of tubules isolated by transillumination under stereomicroscopy. We studied the density of nuclear pores in freeze-fracture replicas of the Sertoli nuclear envelope at stages XIII-XIV-I compared with stages IX-XII. Pore counts were carried out on photographs of the platinum replicas using a digitalized morphometric board. The results were statistically analyzed using Student's t test. The difference in density (pore number/micron2 +/- SEM) was significant between stages IX-XII (8.25 +/- 0.63) and XIII-XIV-I (10.80 +/- 0.60). We postulate that this density appears to be increased at the time of increased metabolic requirements of the Sertoli cell.

Characterization of nuclear pore distribution in freeze-fracture replicas of seminiferous tubules isolated by transillumination

Transilluminated seminiferous tubules were staged and utilized to determine the distribution of nuclear pore complexes in seminiferous tubules of the rat. Segments of seminiferous tubules of adult albino rats were separated and identified (in stages VII-VIII, IX-XI, XII-XIV, and V-VI), and then processed by freeze-fracture. Type A spermatogonia, the only spermatogonia located in seminiferous segments possessing stages IX-XI and XII-XIV, are oval cells in contact with the basal lamina. They either exhibit a random distribution of nuclear pores or a slight degree of clumping. Type B spermatogonia, found in segments possessing stages V-VI, exhibit, instead, a noticeable pore clustering. The identification of intermediate spermatogonia was not undertaken in this study. Preleptotene spermatocytes are easily identified in freeze-fracture by their location in segments with stages VII-VIII, by their arrangement in numerous groups between the basal lamina and the pachytene spermatocytes, and by their comparatively small size. They exhibit noticeable pore clustering. Leptotene (segments containing stages IX-XI) and zygotene (XII-XIV) spermatocytes show a more homogeneous distribution of nuclear pores. Pachytene spermatocytes are identified by their large size, by consistent detachment from the basal lamina and by being rather numerous and found in all the stages explored. Diplotene spermatocytes have the largest nuclei of all germ cells. They are always detached from the basal lamina and found only in seminiferous segments containing stage XIII. Pachytenes display a regular geometric array of pore aggregation with striking clustering, whereas diplotene nuclear pores takes on a random distribution. Secondary spermatocytes, only present in stage XIV intermingled with metaphase-anaphase profiles, are characterized in replicas by a paucity of evenly distributed nuclear pores.

Androgen-induced changes in nuclear pore number and in tight junctions in rat seminal vesicle epithelium

The numbers of nuclear pore complexes and tight junctions were quantified in the seminal vesicle epithelial cells of castrated and castrated-plus-androgen-treated male rats, which received subcutaneous pellets of testosterone propionate (1 mg/kg body weight) for 1 week. Seminal vesicle weights were 0.284 +/- 0.02 g for castrated, 1.006 +/- 0.006 g for androgen-treated, and 0.918 +/- 0.04 g for untreated groups. Tissue samples were processed for light or electron microscopy and for freeze-fracture techniques. Nuclear areas were measured: controls were 279.34 +/- 8 microns 2; these increased significantly (P less than .001) in castrated-plus-androgen-treated rats (324.66 +/- 11 microns 2) and decreased (P less than .001) in castrated animals (173.14 +/- 6.3 microns 2). Nuclear pore density increased (P less than .001) in castrated-plus-androgen-stimulated rats (5.38 +/- 0.24 pores/microns 2) (control: 4.78 +/- 0.14 pores/microns 2), and decreased (P less than .001) in castrated rats (3.16 +/- 0.14 pores/microns 2). A significant (P less than .001) increase in numbers of tight junction strands that extended in the lateral cell membranes was detected in castrated-plus-androgen-treated rats vs. controls or castrated-only animals.

Nuclear pores in rat hypothalamic arcuate neurons: sex differences and changes during the oestrous cycle

The numerical density of nuclear pores was assessed on freeze-fracture replicas of hypothalamic arcuate neurons from adult male and female rats. In females the nuclear pore density fluctuated during the oestrous cycle and was higher in oestrus than in pro-oestrus, metoestrus and dioestrus. Nuclear pore density in males and in metoestrus and dioestrus females was similar. The nuclear pore density in male rats was significantly less than that in oestrus and pro-oestrus females. The variation of the number of pores per unit nuclear volume and the total number of pores per nucleus was similar to the variation of the numerical density of nuclear pores. These results provide morphological evidence of cyclic changes in neuronal nucleocytoplasmic traffic during the ovarian cycle.