Vacuolar system-associated protein-60: a protein characterized from bovine granulosa and luteal cells that is associated with intracellular vesicles and related to human 80K-H and murine beta-glucosidase II.

It has been suggested that proteins of molecular size 56-58 kDa play an important role in bovine ovarian follicular development and oocyte maturation. A polyclonal antibody was raised against a 56- to 58-kDa protein band purified from bovine granulosa cells and was used to screen granulosa or luteal cell cDNA expression libraries. This work resulted in the identification of a cDNA encoding for a protein of 60.1 kDa with a signal peptide of 13 residues. The bovine 60.1-kDa protein shared an overall 86.7% and 81.8% identity with, respectively, the human 80K-H protein and the mouse putative beta subunit of glucosidase II (beta-GII), and was named vacuolar system-associated protein-60 (VASAP-60). Marked differences in sequence identity were noted in a putative molecular adapter domain containing a tandem D and E amino acid stretch flanked by proline-rich sequences presenting the minimal PXXP SH3 motif. VASAP-60 was shown to be unglycosylated using endoglycosidase H treatment and was found mainly in a cellular membrane fraction of bovine corpus luteum. VASAP-60 was localized in a rat hepatic Golgi/endosome fraction and in wheat germ agglutinin (WGA) affinity chromatographic eluates, thereby suggesting the presence of interactions with membrane glycoproteins. A polyclonal antibody was raised against the putative adapter domain of the recombinant VASAP-60; this was shown to recognize a major 88-kDa and two minor 58-kDa and 50-kDa proteins, suggesting that the major 88-kDa protein band represents the complete VASAP-60 protein whereas the 58-kDa and the 50-kDa bands represent its proteolytic fragments. Northern blot analysis demonstrated the presence of a single 2.3-kilobase transcript in all the bovine tissues analyzed with variation in the steady state level between tissues. Immunohistochemical observations showed that VASAP-60 was widely distributed in bovine tissues and was localized in pericytoplasmic and perinuclear membranes. In epithelial cells, the staining presented a basolateral or apical polarity associated with intracellular vacuoles. In conclusion, we have characterized a novel acidic membrane protein, associated with organelles of the vacuolar system, that is widely and histospecifically expressed in bovine tissues. VASAP-60 represents either the bovine ortholog or a new family member of the previously characterized human 80K-H and murine beta-GII proteins. Our results suggest that VASAP-60 presents characteristics of a molecular adaptor protein with functions in membrane-trafficking events.

High expression of bovine alpha glutathione S-transferase (GSTA1, GSTA2) subunits is mainly associated with steroidogenically active cells and regulated by gonadotropins in bovine ovarian follicles.

We have previously shown that a major group of 28-30 kDa proteins decreases after the LH surge in bovine granulosa cells (GC). In the present study, we have characterized two proteins in this group in search of factors that may intervene in folliculogenesis and oocyte maturation. Polyclonal antibodies raised against 28 kDa or 29 kDa bovine GC proteins were used to screen a complementary DNA (cDNA) expression library. This resulted in the characterization of two isoenzyme subunits for alpha class glutathione S-transferase, named bGSTA1 and bGSTA2. Both bGSTA1 (25.4 kDa, pI 8.9; 791 bp cDNA; GenBank Accession No. BTU49179) and bGSTA2 (25.6 kDa, pI 7.2; 959 bp cDNA; GenBank Accession No. AF027386) have 222 amino acids. The deduced amino acid sequences were compared and showed 82% (bGSTA1) and 74% (bGSTA2) identity to human GSTA1, whereas bGSTA1 and bGSTA2 are 81% identical to each other. The bGSTA2 represents a novel GSTA subunit because it harbors a specific 16 amino acid sequence not found in any other species and GST classes. Northern blots showed that bGSTA1 and bGSTA2 are coexpressed and are tissue specific with single transcripts of 1.2 kb and 1.4 kb, respectively for bGSTA1 and bGSTA2. The messenger RNA (mRNA) were detected in GC, corpus luteum, adrenal gland, testis, liver, lung, thyroid, kidney and cotyledon, and the relative abundance of their mRNA varied. Ratios of bGSTA1/bGSTA2 mRNA vary between tisssues, indicating that expression of these genes is controlled differently. Immunohistochemistry observations revealed that expression of GSTA is cell specific, being associated with GC and theca cells, small luteal cells, Leydig cells, hepatocytes, adrenal cortex, specific chromaffin cells in the adrenal medulla, renal proximal convoluted tubular cells, and Clara cells in the bronchioles. Studies in vivo showed that levels of mRNA for bGSTA1 were elevated in follicular wall of preovulatory follicles before hCG treatment, but decreased by 77% 12 h after hCG injection. However, in FSH stimulated preovulatory follicles, the decrease in mRNA for both GSTAs was only 21% at 24 h following hCG injection. We concluded that bGSTA1 and bGSTA2 expression is tissue- and cell-specific, is associated with steroidogenically active cells, and is hormonally regulated by gonadotropins in the bovine ovarian follicle.

[Control of terminal follicular maturation during the follicular phase in domestic mammals]. / Contrôle de la maturation terminale des follicules au cours de la phase folliculaire chez les mammifères domestiques.

Terminal follicular maturation in the ovine and the bovine species involves growth and differentiation processes in follicles between 1-2 mm diameter and the preovulatory stage. During this maturation, the follicle acquires the ability to ovulate and the oocyte becomes able to be fertilized and to develop after fertilization. Selection of ovulatory follicles results from the integration of different parameters such as the circulating levels of gonadotropins, the structure of follicular populations and the sensitivity of the hypothalamo-pituitary axis to ovarian hormones. Differences between follicles for FSH and LH responsiveness can be amplified by paracrine intrafollicular regulations. These mechanisms are probably determinant for selection of ovulatory follicles.

Control of in vitro maturation of bovine cumulus-oocyte complex by preovulatory granulosa cells.

The present study was designed to investigate 1) the influence of the secretions of follicular cells on the in vitro maturation of bovine cumulus-oocyte complexes (COCs) and 2) the origin of the factors controlling the metabolic function of cumulus cells during the preovulatory period. Preovulatory granulosa cells were collected from synchronized heifers either before or 7-9 hr after the luteinizing hormone (LH) surge, and their secretions were recovered after a 3 hr incubation. Follicular fluids (FFs) originating from the same follicles and sera from the same animals were also collected. The effects of FFs, sera, and secretions of granulosa cells on COC metabolism were compared during 24 hr of culture. FF stimulated cumulus expansion, progesterone secretion, and overall protein synthesis by COCs but decreased the amount of a major protein of 28 kDa. The time at which FF was collected influenced both cumulus expansion and protein synthesis by COCs. The effects of FF on COC metabolism were detected at the lowest protein concentration studied (0.073 mg/ml) and could be mimicked with serum, but only at a protein concentration 100-fold higher. The inhibitory effect of FF and serum on the amount of the 28 kDa protein was reproduced with the secretions of granulosa cells, acting at protein concentrations five- and 500-fold lower, respectively. However, the secretions of granulosa cells enhanced slightly cumulus expansion and had no effect on progesterone secretion and overall protein synthesis by COCs. These results suggest that COC metabolism is influenced both by endocrine and by local factors secreted by granulosa cells in response to gonadotropins. The paracrine control of COC metabolism by preovulatory granulosa cells could be exerted not only via intercellular contacts but also via substances secreted in FF.

Qualitative and quantitative changes in protein synthesis of bovine follicular cells during the preovulatory period.

To understand the mechanisms governing oocyte maturation better, the effects of the gonadotropin surge were studied on follicular cells of bovine preovulatory follicles. For this purpose, qualitative and quantitative changes in protein synthesis by both granulosa cells and cumulus cells were compared relative to the luteinizing hormone (LH) surge and the resumption of meiosis in the oocyte. Follicular cells were collected at different times before and up to 25 hr after the LH surge. For each individual preovulatory follicle, granulosa and cumulus cells were incubated separately for 3 hr with 3H-methionine or with 35S-methionine. Newly synthesized cytosolic proteins from granulosa and cumulus cells and proteins secreted into the medium were analyzed by polyacrylamide gel electrophoresis. The radioactivity was measured by liquid scintillation counting after slicing of the gels or revealed by fluorography. Three major peaks of the newly synthesized proteins, with molecular weights of 76, 56, and 30 kDa, were studied throughout the preovulatory period. After the LH surge, the overall level of protein synthesis increased in granulosa cells. In addition, the pattern of cytosolic proteins in granulosa cells changed, and, in particular, the relative synthesis of the 30 kDa peak decreased. These changes in cytosolic protein synthesis may be due to the action of LH since they could be reproduced in vitro in LH-stimulated granulosa cells. A predominant peak of 56 kDa was secreted by granulosa cells throughout the experimental period. No significant change was observed in proteins synthesized by cumulus cells under the same experimental conditions. The amounts of radioactivity incorporated into the three major proteins secreted by granulosa cells, however, were correlated significantly with the amounts of radioactivity incorporated by similar proteins synthesized by cumulus cells. These results indicate that cumulus cells respond differently from granulosa cells to the gonadotropin surge but not in an independent manner.