Association of annexin V with prolactin in the rat anterior pituitary gland

Gonadotropin-releasing hormone stimulation of annexin A5 expression in the thymus of male rats

As gonadotropin-releasing hormone (GnRH) is expressed in the thymus, its direct action on thymic cells, including thymic involution, has been suggested. Annexin A5 (ANXA5), a biomarker of GnRH, was used to determine whether GnRH affects the thymus of male rats. Immunohistochemistry showed positive reactions for ANXA5 in large medullary epithelial cells at 30 days of age, and the expression continued until 180 days of age. Organ culture of thymus pieces was performed to examine the direct action of a GnRH agonist (GnRHa) on the expression of Anxa5 and Gnrh mRNA. Thymus tissues obtained from male rats (40–60 days old) were cut into small pieces (2–3 mm³) and incubated for 3 hr with the GnRHa. The expression levels of Anxa5 and Gnrh mRNA were augmented by the GnRHa. Immunohistochemistry of these tissue fragments showed that ANXA5 expression was enhanced, especially in medullary epithelial cells. These results revealed that GnRH synthesis in the thymus could affect thymic epithelial cells after puberty.

The relevance of ANXA5 genetic variants on male fertility

PURPOSE

To investigate the effect of the anticoagulation factor annexin A5 on male fertility and to provide perspective on the influence of members of the coagulation cascade on fertility.

METHODS

Patients with normozoospermia and with unexplained severe oligozoospermia were retrospectively selected and their genomic DNA sequenced for the promoter region of ANXA5. The genotypes proportions and the odds ratio for carriership of the haplotype M2 were compared between the groups and population control. The clinical data used were gathered from parameters determined during routine clinical assessment and were compared between carriers and non-carriers within the patient groups.

RESULTS

The carrier rates for the haplotype M2/ANXA5 were of 25.73%, 20.81%, and 15.3% in the severe oligozoospermic, the normozoospermic, and the general population control groups, respectively. The OR between patients groups was of 1.31 (95% CI 0.88 to 1.96 p = 0.176). Oligozoospermic and normozoospermic patients compared with the control group had an OR of 1.9 (95% CI 1.33 to 2.73 p < 0.001) and 1.45 (95% CI 0.99 to 2.10 p = 0.054) respectively. The clinical parameters that differed between the carriers and non-carriers of the haplotype M2/ANXA5 were prolactin, α-glucosidase, and fructose. The differences were only statistically significant in the normozoospermic group.

CONCLUSIONS

Athough the infertile patient groups had a higher prevalence of promoter variants, we could not demonstrate any biologically relevant effect of lower levels of annexin A5 on most male fertility parameters. A deficiency in an anticoagulation factor does not seem to impact male fertility.

Annexin A1 is a novel target gene of gonadotropin-releasing hormone in LβT2 gonadotrope cells

Gonadotropin-releasing hormone (GnRH) regulates gonadotropin secretion. We previously demonstrated that the expression of annexin A5 (ANXA5) is stimulated by GnRH in gonadotropes and has a significant role in gonadotropin secretion. It is therefore of interest to know whether other members of the ANXA family, which consists of twelve structurally related members, are also regulated by GnRH. Therefore, the expression of all annexins was examined in LβT2 gonadotrope cells. ANXA4, A5, A6, A7 and A11 were detected in LβT2 cells. The expression of ANXA5 and A1 mRNA was stimulated by a GnRH agonist. An increase in ANXA1 protein by this agonist was demonstrated by western blotting. Immunohistochemistry showed that ANXA1 was present in the nucleus and to a lesser extent in the cytoplasm of some rat pituitary cells. The GnRH agonist induced translocation of ANXA1 to the periphery of LβT2 cells. The presence of ANXA1 in gonadotropes and its increase upon GnRH agonist treatment were confirmed in a primary pituitary cell culture. ANXA1 expression was also demonstrated in the ovary, the testis, the thyroid gland and the pancreas in a different manner to that of ANXA5. These data suggest that ANXA1 is a novel GnRH target gene in gonadotropes. ANXA1 also may be a target of local GnRH in peripheral tissues and may have a different role than that of ANXA5.

Annexin V-induced rat Leydig cell proliferation involves Ect2 via RhoA/ROCK signaling pathway

This study investigated the effect of annexin V on the proliferation of primary rat Leydig cells and the potential mechanism. Our results showed that annexin V promoted rat Leydig cell proliferation and cell cycle progression in a dose- and time-dependent manner. Increased level of annexin V also enhanced Ect2 protein expression. However, siRNA knockdown of Ect2 attenuated annexin V-induced proliferation of rat Leydig cells. Taken together, these data suggest that increased level of annexin V induced rat Leydig cell proliferation and cell cycle progression via Ect2. Since RhoA activity was increased following Ect2 activation, we further investigated whether Ect2 was involved in annexin V-induced proliferation via the RhoA/ROCK pathway, and the results showed that annexin V increased RhoA activity too, and this effect was abolished by the knockdown of Ect2. Moreover, inhibition of the RhoA/ROCK pathway by a ROCK inhibitor, Y27632, also attenuated annexin V-induced proliferation and cell cycle progression. We thus conclude that Ect2 is involved in annexin V-induced rat Leydig cell proliferation through the RhoA/ROCK pathway.

Annexin 5 inhibits thyrotropin releasing hormone (TRH) stimulated prolactin release in the primary culture of rat anterior pituitary cells

Annexin 5, a novel calcium-phospholipid binding protein, is thought to be involved in hormone secretion by the anterior pituitary gland. Gonadotropin releasing hormone stimulates annexin 5 synthesis, which, in turn, enhances gonadotoropin secretion. On the other hand, annexin 5 was shown to inhibit prolactin release in vitro. To understand the nature of the opposing effects of annexin 5 on these two major pituitary hormones, the present study examines the inhibitory effect of annexin 5 on prolactin release in relation to thyrotropin stimulating hormone (TRH) using primary cultures of anterior pituitary cells of adult female rats. While recombinant rat annexin 5 was found to have little effect on basal prolactin release, it significantly inhibited TRH-stimulated prolactin release. Addition of specific anti-annexin 5 serum to the culture increased basal prolactin release in a concentration dependent manner, and no further increase in prolactin release was observed following application of TRH in the presence of anti-annexin 5. The enhanced basal prolactin release induced by anti-annexin 5 was reversed by the simultaneous administration of indomethacin, an inhibitor of cyclooxygenase. These results demonstrate that endogenous pituitary annexin 5 exerts an inhibitory effect on prolactin release and suggest that this is attained by suppression of eicosanoid synthesis in vitro.

Gonadotropin-releasing hormone stimulates annexin 5 messenger ribonucleic acid expression in the anterior pituitary cells

We previously reported that annexin 5 is found specifically in gonadotropes and that the expression is dramatically enhanced after ovariectomy. In the present study, the expression of annexin 5 was examined in the primary culture of rat anterior pituitary cells using semiquantitative RT-PCR to determine if it is under the direct control of gonadotropin-releasing hormone (GnRH). Continuous administration of GnRH analog for 1 h enhanced the expression of both FSH beta subunit and annexin 5 mRNA. The expression of annexin 5 mRNA was also augmented by phorbol 12-myristate 13-acetate but not by forskolin. Administration of recombinant rat annexin 5 to the culture increased LH beta mRNA expression. These data clearly demonstrate that the expression of annexin 5 mRNA is directly controlled by GnRH and suggest that annexin 5 is involved in mediating GnRH action in the pituitary gland.

Ovariectomy enhances the expression and nuclear translocation of annexin 5 in rat anterior pituitary gonadotrophs

An observation of abundant annexin 5, a novel calcium and phospholipid binding protein, in gonadotrophs of the anterior pituitary gland of ovariectomized rats (Kawaminami et al., 1997 (in press)) led us to investigate the effect of ovariectomy on the subcellular distribution and synthesis of annexin 5. Gonadotrophs, which were identified by immunocytochemistry with anti LHbeta antiserum, dramatically increased their size three weeks after ovariectomy. These 'castration cells' were shown to contain abundant annexin 5 associated with the plasma membrane, nuclear envelope and nucleoplasm. True localization within the nucleus was shown by optical sectioning with a confocal microscope. Northern blot analysis showed that annexin 5 mRNA in the anterior pituitary gland was increased 24 h after ovariectomy. It further increased in parallel with LHbeta mRNA at three weeks and it decreased in parallel with LHbeta mRNA when estradiol (250 microg/animal per day) was given for 3 days. These results show that the expression of pituitary annexin 5 is controlled by ovarian estradiol and imply that annexin 5 plays a physiological role in the nucleus of activated gonadotrophs.

Intrapituitary distribution and effects of annexin 5 on prolactin release

Annexin 5 is expressed by rat anterior pituitary cells and a depolarizing stimulus results in increased extracellular display and, depending on local calcium concentrations, potential release into the extracellular environment. In order to further investigate the role of annexin 5 in anterior pituitary function, we have examined the intracellular distribution by immunocytochemistry and the effects of annexin 5 on the release of a major secretory product, prolactin. Prolactin was chosen because we could easily monitor effects on basal release and effects on the immediate and sustained phases of thyroid stimulating hormone releasing hormone (TRH)-stimulated release. Immunocytochemical localization of annexin 5 showed staining of the majority of anterior pituitary cells. Labeling was predominantly on the nuclear envelope and plasma membrane. For the chosen secretory product, prolactin, annexin 5 was found in most, but not all prolactin positive cells. When recombinant annexin 5 (50 ng/mL) was added to a 3 h static culture incubation of rat anterior pituitary cells, prolactin release was inhibited by about 30% (p<0.05). A lower dose had a reduced effect and higher doses had no further inhibitory effect, indicating that the effect was specific to annexin 5 and not a nonspecific toxic effect of some contaminant in the preparation. This interpretation was further strengthened in a time-course experiment demonstrating that when TRH and annexin 5 were added together, there was no effect of annexin 5 on the amount of prolactin released. After a 3 h preincubation in annexin 5, however, prolactin release, in response to TRH, was suppressed by about 30% in both the acute and sustained phases. These data suggest that annexin 5 may be a local regulator of release in the anterior pituitary, but a slow onset effect on both phases of TRH-stimulated release suggests that this is not an effect at the plasma membrane such as local extracellular calcium depletion by plasma membrane-bound annexin 5.

Characterization of the interaction between annexin I and profilin

Annexin I belongs to a family of calcium-dependent phospholipid-binding and membrane-binding proteins. Although many of the biochemical properties and the three-dimensional structure of this protein are known, its true physiological roles have yet to be thoroughly defined. Its putative functions include participation in the regulation of actin microfilaments dynamics, proposed after the discovery of an interaction with actin. In accordance with this hypothesis, we found that annexin I can also interact with profilin. We used different methods, overlay and surface plasmon resonance (BIAcore), to measure the parameters of the association equilibrium, i.e. k(on), k(off) and k(d). The affinity of annexin I for profilin was between 10(7) M and 10(8) M. High concentrations of KCl did not prevent the interaction, although a slight decrease in affinity was observed. Calcium, a modulator of annexin I functions interfered only marginally with the association, in a manner comparable to magnesium. Proteins or compounds known to interact with annexin I or profilin were found to inhibit the annexin-I--profilin interaction when added in the reaction medium. Recombinant profilin exhibited a slightly lower affinity than natural platelet protein when measured with BIAcore. Due to the submembrane localisation of annexin I and the regulatory activity of profilin on the cytoskeleton, an interaction between annexin I and profilin may therefore be implicated in the regulation of some cellular functions, particularly those governing membrane-cytoskeleton dynamic organization.