Summary
In uterine smooth muscles, gap junction plaques rapidly form during the final stages of gestation. To investigate the related mechanisms, regional differences in myometrial gap junction development in rat uterus were examined quantitatively during delivery, using thin-section and freeze-fracture techniques in combination with light- and electron microscopy.
Examination of implanted and nonimplanted horns in the unilaterally ligated rat bicornuate uteri, revealed no differences in the occurrence of gap junction plaques, but after 2 to 4 pups had been delivered, the contracted segments contained more gap junction plaques than did noncontracted segments examined immediately before delivery. In all segments, gap junctions were found more frequently in the circular muscle layers than in the longitudinal muscle layers. Gap junctions ranged in size from 0.002 μm2 to 0.52 μm2, but two-thirds were less than 0.1 μm2. The frequency of small gap junction plaques (less than 0.1 μm2) was higher in the noncontracted segment.
These results suggest that gap junctions are dynamic structures, and that their formation is controlled not only by general hormonal factors, possibly involved in gap junction increases in the myometrium before delivery, but also by local factors, possibly related to the contraction, that may accelerate an increase in gap junction formation during delivery.
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References
Albertini DF, Anderson E (1974) The appearance and structure of intercellular connections during the ontogeny of the rabbit ovarian follicle with particular reference to gap junctions. J Cell Biol 63:234–250
Anderson GF, Kawarabayashi T, Marshall JM (1981) Effect of indomethacin and aspirin on uterine activity in pregnant rats: comparison of circular and longitudinal muscle. Biol Reprod 24:359–372
Bennett MVL, Spira M, Pappas GD (1972) Effects of fixatives for electron microscopy on properties of electrotonic junctions between embryonic cells. J Cell Biol 55:17a
Burghardt R, Gaddy D, Matheson R, Kurten R, Mitchell P (1984) Analysis of estrogen-induced uterine myometrial cell gap junctions. J Cell Biol 99:12a
Demianczuk N, Towell ME, Garfield RE (1984) Myometrial electrophysiologic activity and gap junctions in the pregnant rabbit. Am J Obstet Gynecol 149:485–491
Gabella G, Blundell D (1981) Gap junctions of the muscles of the small and large intestine. Cell Tissue Res 219:469–488
Garfield RE, Sims SM, Kannan MS, Daniel EE (1978) Possible role of gap junctions in activation of myometrium during parturition. Am J Physiol 235:C168-C179
Garfield RE, Rabideau S, Challis JRG, Daniel EE (1979) Ultrastructural basis for maintenance and termination of pregnancy. Am J Obstet Gynecol 133:308–315
Garfield RE, Kannan MS, Daniel EE (1980) Gap junction formation in myometrium: control by estrogens, progesterone, and prostaglandins. Am J Physiol 238:C81-C89
Garfield RE, Puri CP, Csapo AI (1982) Endocrine, structural, and functional changes in the uterus during premature labor. Am J Obstet Gynecol 142:21–27
Hirokawa N, Heuser J (1982) The inside and outside of gap-junction membranes visualized by deep etching. Cell 30:395–406
Larsen WJ (1977) Structural diversity of gap junctions. A review. Tissue Cell 9:373–394
Merk FB, Kwan PWL, Leav I (1980) Gap junctions in the myometrium of hypophysectomized estrogen-treated rats. Cell Biol Int Rep 4:287–294
Miller TM, Goodenough DA (1985) Gap junction structures after experimental alteration of junctional channel conductance. J Cell Biol 101:1741–1748
Peracchia C (1980) Structural correlates of gap junction permeation. Int Rev Cytol 66:81–146
Shibata Y, Yamamoto T (1979) Freeze-fracture studies of gap junctions in vertebrate cardiac muscle cells. J Ultrastruct Res 67:79–88
Shibata Y, Yamamoto T (1986) Cytoplasmic surface ultrastructures of cardiac gap junctions as revealed by quick-freeze, deepetch replicas. Anat Rec 214:107–112
Sikerwar S, Malhotra S (1981) Structural correlates of glutaraldehyde induced uncoupling in mouse liver gap junctions. Eur J Cell Biol 25:319–323
Sims SM, Daniel EE, Garfield RE (1982) Improved electrical coupling in uterine smooth muscle is associated with increased numbers of gap junctions at parturition. J Gen Physiol 80:353–375
Tadvalkar G, Pinto da Silva P (1983) In vitro, rapid assembly of gap junctions is induced by cytoskeleton disruptors. J Cell Biol 96:1279–1287
Verhoeff A, Garfield RE, Ramondt J, Wallenburg HCS (1985) Electrical and mechanical uterine activity and gap junctions in peripartal sheep. Am J Obstet Gynecol 153:447–454
Wathes DC, Porter DG (1982) Effect of uterine distension and oestrogen treatment on gap junction formation in the myometrium of the rat. J Reprod Fertil 65:497–505
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Ikeda, M., Shibata, Y. & Vamamoto, T. Rapid formation of myometrial gap junctions during parturition in the unilaterally implanted rat uterus. Cell Tissue Res. 248, 297–303 (1987). https://doi.org/10.1007/BF00218196
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DOI: https://doi.org/10.1007/BF00218196