Copulatory plug formation in animals is a general phenomenon by which competition is reduced among rival males. In mouse, the copulatory plug formation results from the coagulation of highly viscous seminal vesicle secretion (SVS) that is rich in proteins, such as dimers of SVS I, SVS I + II + III, and SVS II. These high‐molecular‐weight complexes (HMWCs) are also reported to be the bulk of proteins in the copulatory plug of the female mouse following copulation. In addition, mouse SVS contributes to the existence of sulfhydryl oxidase (Sox), which mediates the disulfide bond formation between cysteine residues. In this study, flavin adenine dinucleotide (FAD)‐dependent Sox was purified from mouse SVS using ion exchange and high‐performance liquid chromatography. The purified enzyme was identified to be Sox, based on western blot analysis with Sox antiserum and its capability of oxidizing dithiothreitol as substrate. The pH optima and thermal stability of the enzyme were determined. Among the metal ions tested, zinc showed an inhibitory effect on Sox activity. A prosthetic group of the enzyme was identified as FAD. The Km and Vmax of the enzyme was also determined. In addition to purification and biochemical characterization of seminal vesicle Sox, the major breakthrough of this study was proving its cross‐linking activity among SVS I–III monomers to form HMWCs in SVS.
SPINK3 from mouse seminal vesicle is a Kazal-type trypsin inhibitor. It has been shown to bind to the sperm acrosome and modify sperm activity by influencing the sub-cellular Ca2+ influx. Previously, SPINK3 was reported to suppress in vitro sperm capacitation. However, under natural coitus SPINK3 is removed from the mouse acrosome in the female reproductive tract, leading to successful fertilization. Identification of the SPINK3 binding partner becomes essential to develop a contraceptive that works by prolonging the binding of SPINK3 to the sperm acrosome. We identified the SPINK3 receptor by using recombinant SPINK3 (rSPINK3). TESP1 was identified as the receptor for SPINK3 by 2D gel electrophoresis coupled with western blot analysis. To authenticate TESP1 as the receptor for SPINK3, sperm cells were incubated with TESP1 peptide antibody followed by determining the intracellular [Ca2+]i concentration by flow cytometry using fluo 3 AM as calcium probe. Further, the 3D structure of SPINK3 and TESP1 was predicted by homology modelling (Schrodinger suite) using the crystal structure of pancreatic secretory trypsin inhibitor (PDB ID- 1TGS) and human prostasin (PDB ID- 3DFJ) as templates. The modelled protein structures were validated and subjected to molecular dynamics simulation (MDS) using GROMACS v5.0.5. Protein–protein docking was performed using HDOCK and the complex was validated by MDS. The results predicted that SPINK3 and TESP1 had strong binding affinity, with a dock score of -430.70 and 14 hydrogen bonds as key active site residues. If the binding affinity between SPINK3 and TESP1 could be increased, the SPINK3-TESP1 association will be prolonged, which will be helpful in the development of a male contraceptive.
During ejaculation, cauda epididymal spermatozoa are suspended in a protein-rich solution of seminal plasma which is composed of proteins mostly secreted from the seminal vesicle. These seminal proteins interact with the sperm cells and bring about changes in their physiology, so that they can become capacitated in order for the fertilization to take place. Sulfhydryl oxidase (SOX) is a member of the QSOX family and its expression is found to be high in the seminal vesicle secretion of mouse. Previously, it has been reported to cross-link thiol containing amino acids among major seminal vesicle secretion (SVS) proteins. However, its role in male reproduction is unclear. In this study, we determined the role of SOX on epididymal sperm maturation and also disclosed the binding effect of SOX on the sperm fertilizing ability in vitro. In order to achieve the above two objectives, we constructed a Sox clone (1.7 kb) using a pET-30a vector. His-tagged recombinant Sox was over expressed in Shuffle Escherichia coli cells and purified using His-Trap column affinity chromatography along with hydrophobic interaction chromatography. The purified SOX was confirmed by Western blot analysis and by its activity with DTT as a substrate. Results obtained from immunocytochemical staining clearly indicated that SOX possesses a binding site on the sperm acrosome. The influence of SOX on oxidation of sperm sulfhydryl to disulfides during epididymal sperm maturation was evaluated by a thiol labelling agent, mBBr. The SOX protein binds on to the sperm cells and increases their progressive motility. The effect of SOX binding on reducing the [Ca2+]i concentration in sperm head, was determined using a calcium probe, Fluo-3 AM. The inhibitory influence of SOX on sperm acrosome reaction was shown by using calcium ionophore A32187 to induce the acrosome reaction. The acrosome-reacted sperm were examined by staining with FITC-conjugated Arachis hypogaea (peanut) lectin. Furthermore, immunocytochemical analysis revealed that SOX remains bound to the sperm cells in the uterus but disappears in the oviduct during their transit in the female reproductive tract. The results from the above experiment revealed that SOX binding on to the sperm acrosome prevents sperm capacitation by affecting the [Ca2+]i concentration in the sperm head and the ionophore-induced acrosome reaction. Thus, the binding of SOX on to the sperm acrosome may possibly serve as a decapacitation factor in the uterus to prevent premature capacitation and acrosome reaction, thus preserving their fertilizing ability.
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