ResearchGap junction communication plays an essential role in follicle growth. Immunocytochemistry and confocal microscopy were used to examine the expression of gap junction connexins of the α and β subfamilies in follicles from primordial to preovulatory stages in the ovaries of prepubertal and adult mice. Connexin-specific antibodies detected α 1 , α 4 , α 6 , β 1 , β 2 and β 4 connexins within follicles. In adult ovaries connexin immunolabelling was stronger in larger (more mature) follicles than it was in smaller follicles, with comparatively reduced labelling detected in prepubertal ovaries. In healthy follicles, labelling for α subfamily connexins was detected between granulosa cells, whereas labelling for β subfamily connexins was found in the theca. Labelling for β subfamily connexins and α 4 connexin (preantral stage) was detected on the oocyte surface membrane. In atretic follicles, labelling for β 4 connexin appeared between the granulosa cells. These results demonstrate that α and β connexin subfamilies are segregated to separate cellular compartments in the mouse follicle. The results are discussed in the light of possible roles for differential gap junctional communication in the regulation of folliculogenesis, oocyte maturation and atresia.
Oestradiol increases the protein expression of connexin43 (Cx43) gap junctions in myometrium but the effect of oestriol on gap junction expression has not been described previously. Oestriol is the most abundant free oestrogen in pregnant women and there is a marked surge in oestriol concentrations before term and idiopathic preterm labour. In order to determine whether oestriol may have a physiological action on the myometrium, cultured human myometrial cells obtained from non-pregnant hysterectomy specimens were exposed to 10 nmol/l oestradiol or oestriol. Intercellular communication between myometrial cells was investigated by microinjection of confluent cultured cells with the gap junction-permeant tracer Cascade Blue. There was a progressive increase in coupling after exposure to oestradiol or oestriol (P < 0.0005). An increase in Cx43 protein expression was demonstrated by immunocytochemistry after 1 h (P < 0.01) and 3 days (P < 0.01) exposure, and by Western blotting after 1 h (P < 0.01) and 3 days (P < 0.05) exposure, to both oestradiol and to oestriol. We conclude that oestriol increases gap junction communication in human myometrium by increasing gap junction expression. Elevated oestriol concentrations may thus play a role in the initiation of labour in women, by increasing cell-cell communication in the myometrium.
We have found that basic fibroblast growth factor (bFGF), applied to cortical progenitor cells in vitro, produces an increase in the expression of the gap junction protein connexin (Cx) 43 and in the mRNA encoding Cx 43. This effect was evident in both proliferating and nonproliferating cells. The elevated levels of mRNA suggest that bFGF is likely to exert its effect by upregulating the rate of transcription of the Cx 43 gene. We have further shown that the increase in Cx 43 expression is mediated through the receptor tyrosine kinase pathway and is associated with enhanced intercellular dye-coupling mediated by gap junctions. These results suggest that gap junction channels provide a direct conduit for mitogens released in response to bFGF to effectively regulate proliferation during corticogenesis.
Gap junctions allow direct communication between cells without recourse to the extracellular space and have been widely implicated as important mediators of cell-cell signalling. They are constructed from the connexin proteins, which form a large family, and individual connexins show complex spatial and temporal variations in their expression patterns. Understanding how this variation contributes to the control of intercellular signalling, both in the adult and during embryonic development, is an important problem that would be aided by reagents that interfere with gap junctional communication through specific connexins. We have begun to address this issue by raising antibodies to peptides derived from connexin43 and connexin32. Connexin43 peptides were located in the amino terminus, cytoplasmic loop and carboxytail. Connexin32 peptides came from the cytoplasmic loop and the first extracellular loop. Immunoblotting and immunostaining properties of purified IgGs were characterized on mouse heart, liver and the 8- to 16-cell mouse embryo. Effects on transfer through gap junctions were assessed in the fully compacted 8-cell mouse embryo by co-injection with Lucifer Yellow or Cascade Blue. Embryos were maintained in culture to assess the developmental consequences of injection. Peptide competition was used to confirm the specificity of immunostaining and inhibition of dye transfer. All connexin specific antibodies recognized their parent connexin on immunoblots and showed no 43/32 cross-reactivity. The connexin32 extracellular loop antibody recognized both connexin 32 and 43 on immunoblots, as predicted by the amino acid sequence homology in this region, but did not immunostain intact gap junctions. Connexin specific antibodies that immuno-stained showed the predicted connexin specificity. Antibodies to either connexin43 amino acids (AA) 1–16 (amino terminus) or AA 101–112 (cytoplasmic loop) neither immunostained nor prevented functional communication through 8-cell embryo gap junctions. Antibodies to AA 123–136 and AA 131–142 in the cytoplasmic loop immunostained heart and 8-cell embryo gap junctions and blocked transfer through them with high efficiency. Fab' fragments were equally effective. Peptide competition showed that both antibodies contained epitopes within AA 131–136 of connexin43. Antibodies against AA 313–324 in the carboxytail immunostained heart and the 8-cell embryo and, as IgGs, prevented dye transfer. Fab' fragments were ineffective. All connexin43 antibodies that blocked gap junctional communication between cells of the 8-cell mouse embryo induced non-communicating cells subsequently to withdraw from compaction.(ABSTRACT TRUNCATED AT 400 WORDS)
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