Heat shock factor 5 is essential for spermatogenesis in mice: Detected by a new monoclonal antibody.

OBJECTIVES: Here, we examined the function of our produced monoclonal antibody (mAb10C3) to recognize one of the most important members of the HEAT shock factor family, Hsf5, in embryonic development and in spermatogenic cells of adult mouse testis. MATERIALS AND METHODS: The targeting effects of mAb10C3 were investigated by immunohistochemistry analysis in the different phases of the embryo and in the adult testis tissue sections. RESULTS: The results of immunohistochemistry staining on the mouse embryos by the supernatant of hybridoma clone that produced mAb10C3, in the early and late phases (E7.5 and E14.5) of embryonic development, indicated that mAb10C3 could only detect Hsf5 in E7.5 and it did not have any targeting activity in the late phase of development. Therefore, we showed that the hsf5 gene has expressed in early mouse embryonic development. On the other hand, mAb10C3 could detect Hsf5 in spermatogonia and spermatocytes of adult testis in comparison with a known anti-Hsf5 antibody (ab98939) and an anti-PCNA antibody as a marker of spermatogonia cells. CONCLUSION: Taken together, these data indicated that generated anti-testis mAb10C3 was generated against anti-testis proteins, specifically to target Hsf5, and can be useful as a scientific tool to investigate the critical genes in the development and spermatogenesis.

Optimized protocol for soluble prokaryotic expression, purification and refolding of the human inhibin α subunit, a cysteine rich peptide chain.

BACKGROUND: Inhibin A, a member of TGF-ß superfamily, consists of α and ß subunits. These subunits contain several cysteine residues in amino acid sequence that forms inter- and intra-subunits disulfide bonds. Due to the reducing environment of the bacterial cytoplasm, disulfide bonds formation in E.coli cytoplasm is not possible. Therefore, this can cause misfolding, aggregation and inclusion bodies formation during protein expression. As a result, the expression of inhibin subunits in E.coli produces inclusion bodiesOBJECTIVE: We aimed at identification of an optimized protocol for expression and recovery of inhibin α-subunit from inclusion bodies. METHODS: Two vectors, four different E.coli strains, and six solubilization conditions for were used for the optimization of inhibin α-subunit production. Then, the solubilized proteins were purified through Ni-NTA affinity chromatography, characterized by SDS-PAGE and Western blotting (WB) using anti-his tag antibody, and refolded by dilution. RESULTS: The results showed that inhibin α-subunits were successfully expressed in both vectors and the pET22b+inhibin α-subunit in ShuffleTM T7 strain had the highest expression; however, most of the expression was in an insoluble form. Among solubilization buffers examined, a buffer containing 2M urea with pH 12 was the best buffer to dissolve the insoluble protein. The high purity of protein was confirmed by SDS-PAGE and WB. Non-reducing SDS-PAGE demonstrating inhibin α-subunit refolded well. CONCLUSION: The current protocol is an efficient method for protocol for expression and recovery of inhibin α-subunit from inclusion bodies.

Obtaining and characterization of anti-testis monoclonal antibodies: Invaluable tools toward the identification of testis antigens involved in fertilization.

BACKGROUND: Generation and utilization of the specific monoclonal antibodies against testis antigens is reported to identify the antigens that are important in reproductive field. OBJECTIVE: Current study aimed to introduce a hybridoma that producing a specific anti-testis monoclonal antibody to identify the testis antigens that can be important in the reproduction field. METHODS: To make hybridoma against testis antigens, mice were immunized with testis cell lysate. After cell fusion, resulted hybridomas were screened by indirect ELISA, then cloned by limiting dilution and finally the produced monoclonal antibody were characterized by some of the molecular laboratory techniques such as immunohistochemistry, immunocytochemistry and western blot. RESULTS: By using hybridoma technique, cell fusion was performed and ten (8A11, 8D6, 8D7, 9F6, 9G11, 10C3, 10B3, 10B2, 10C2 and 10H7) antibodies specific to the testis antigens were produced finally. Among the produced antibodies, 10C3 was found to cross-react with testis, but not detected in other tissues. mAb 10C3 recognized the sperm and testis antigens, specifically the intertestitial tissue of testis, spermatogonia, primary and secondary spermatocyte antigens, so they were most likely the target of generated mAb. Also our mAb could totally detect the mouse sperm antigens and the specific antigens of head and tail of human sperm. In western blotting analysis, mAb 10C3 could recognize the specific protein bands of sperm and testis extracts. Also in this study the testis specific genes that were target of generated mAb, were selected according to the mouse EST profile available at UniGene part of NCBI. CONCLUSIONS: So this stable anti-testis mAb has a potential for laboratory researches and also for diagnostic procedures in fertilization. Thus it could be exploited as a suitable tool for target-specific diagnosis and research in several diseases.

Effect of the Hydroalcoholic Extract of Heracleum persicum (Golpar) on Folliculogenesis in Female Wistar Rats.

OBJECTIVE: Medicinal plants are widely used throughout the world. Since these plants are known to have minimal side effects, many people embrace them. The golpar plant, scientifically known as Heracleum persicum (H. persicum), is a common Asian and Iranian medicinal plant. The use of golpar is recommended in traditional medicine as a contraceptive medication for females; however, no scientifically documented evidence has been reported. This study investigates the effects of the golpar plant on ovarian tissue and folliculogenesis. MATERIALS AND METHODS: In this experimental study, H. persicum hydroalcoholic extract (HPHE) was used at 400 mg/kg and 1600 mg/kg doses. Adult female rats were divided into three groups: control, sham, and experimental(I, II). The control group did not receive any injection, the sham group received saline solution, and the experimental group received IP injections of HPHE for 21 days, once every other day, during the sexual cycle. At the end of the injection period, ovarian samples were harvested for histological studies. The FSH assay was performed according to the chemiluminescence immunoassay (CLIA) method. Data were statistically analyzed by the Instat3 program and one-way ANOVA. A p value of <0.05 was considered significant. RESULTS: In the experimental group the numbers of primordial and primary follicles increased (p <0.001), while the number of preantral and antral follicles decreased (p <0.01). The atretic follicles decreased in the experimental group, but this decrease was not significant. There was no statistical difference in FSH concentration when compared with the control group. CONCLUSION: This report gives primary information on the in vivo effects of the HPHE on the ovarian follicles of the female Wistar rat. The results suggest that administration of HPHE may have inhibitory effects on folliculogenesis and cause infertility in females.