Equine CRISP3 Modulates Interaction Between Spermatozoa and Polymorphonuclear Neutrophils1

Doty, Andria; Buhi, William C.; Benson, Stephen C.; Scoggin, Kirsten E.; Pozor, Małgorzata A.; Macpherson, M. L.; Mutz, Mitchell W.; Troedsson, Mats H.T.

doi:10.1095/biolreprod.110.084491

Cited by 70 publications

(42 citation statements)

References 35 publications

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“…Consistent with a cytosolic orientation [54,55], we found GLIPR2 to be protected from protease treatment. CRISPs are particularly highly expressed in the male reproductive tract and have been implicated in sperm development, capacitation, motility, and fertilization [56] as well as in protection against phagocytosis by neutrophils [57]. Seminal plasma is known to modulate both innate and acquired immune responses locally within the female reproductive tract to prevent immune-mediated destruction of healthy sperm cells [19].…”

Section: Discussionmentioning

confidence: 99%

Identification of Distinct Populations of Prostasomes That Differentially Express Prostate Stem Cell Antigen, Annexin A1, and GLIPR2 in Humans1

Aalberts

Dissel‐Emiliani

Adrichem

et al. 2012

Biology of Reproduction

197

141

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In addition to sperm cells, seminal fluid contains various small membranous vesicles. These include prostasomes, membrane vesicles secreted by prostate epithelial cells. Prostasomes have been proposed to perform a variety of functions, including modulation of (immune) cell activity within the female reproductive tract and stimulation of sperm motility and capacitation. How prostasomes mediate such diverse functions, however, remains unclear. In many studies, vesicles from the seminal plasma have been categorized collectively as a single population of prostasomes; in fact, they more likely represent a heterogeneous mixture of vesicles produced by different reproductive glands and secretory mechanisms. We here characterized membranous vesicles from seminal fluid obtained from vasectomized men, thereby excluding material from the testes or epididymides. Two distinct populations of vesicles with characteristic sizes (56 ± 13 nm vs. 105 ± 25 nm) but similar equilibrium buoyant density (∼1.15 g/ml) could be separated by using the distinct rates with which they floated into sucrose gradients. Both types of vesicle resembled exosomes in terms of their buoyant density, size, and the presence of the ubiquitous exosome marker CD9. The protein GLIPR2 was found to be specifically enriched in the lumen of the smaller vesicles, while annexin A1 was uniquely associated with the surface of the larger vesicles. Prostate stem-cell antigen (PSCA), a prostate-specific protein, was present on both populations, thereby confirming their origin. PSCA was, however, absent from membrane vesicles in the seminal fluid of some donors, indicating heterogeneity of prostasome characteristics between individuals.

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Section: Discussionmentioning

confidence: 99%

Identification of Distinct Populations of Prostasomes That Differentially Express Prostate Stem Cell Antigen, Annexin A1, and GLIPR2 in Humans1

Aalberts

Dissel‐Emiliani

Adrichem

et al. 2012

Biology of Reproduction

197

141

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“…Treatment of human endometrial epithelial cells in vitro with recombinant IL8 at physiological levels can induce IL1B , IL6 , and LIF (Gutsche et al 2003 ). Outside of mice and humans, other novel seminal fl uid signalling molecules that have been examined are porcine sperm adhesion proteins (PSP)1 and PSP2, which contribute in part to the infl ux of neutrophils in pigs and can preserve sperm viability, motility, and mitochondrial activity (Rodriguez-Martinez et al 2010 ;Caballero et al 2006 ), and cysteine-rich secretory protein-3 (CRISP3) in horses, which mediates the interaction between sperm and neutrophils (Doty et al 2011 ). Positive correlations between specifi c seminal plasma proteins and fertility have been observed in the horse (Brandon et al 1999 ) and bull (Killian et al 1993 ).…”

Section: Active Factors In Seminal Fluidmentioning

confidence: 99%

Seminal Fluid Signalling in the Female Reproductive Tract: Implications for Reproductive Success and Offspring Health

Schjenken

Robertson

2015

Advances in Experimental Medicine and Biology

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Carriage of sperm is not the only function of seminal fluid in mammals. Studies in mice show that at conception, seminal fluid interacts with the female reproductive tract to induce responses which influence whether or not pregnancy will occur, and to set in train effects that help shape subsequent fetal development. In particular, seminal fluid initiates female immune adaptation processes required to tolerate male transplantation antigens present in seminal fluid and inherited by the conceptus. A tolerogenic immune environment to facilitate pregnancy depends on regulatory T cells (Treg cells), which recognise male antigens and function to suppress inflammation and immune rejection responses. The female response to seminal fluid stimulates the generation of Treg cells that protect the conceptus from inflammatory damage, to support implantation and placental development. Seminal fluid also elicits molecular and cellular changes in the oviduct and endometrium that directly promote embryo development and implantation competence. The plasma fraction of seminal fluid plays a key role in this process with soluble factors, including TGFB, prostaglandin-E, and TLR4 ligands, demonstrated to contribute to the peri-conception immune environment. Recent studies show that conception in the absence of seminal plasma in mice impairs embryo development and alters fetal development to impact the phenotype of offspring, with adverse effects on adult metabolic function particularly in males. This review summarises our current understanding of the molecular responses to seminal fluid and how this contributes to the establishment of pregnancy, generation of an immune-regulatory environment and programming long-term offspring health.

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“…540 Andrology, 2015, 3, 536-543 may have different effects on spermatozoa: protection, activation, influence on motility and membrane integrity, capacitation and acrosome reaction (Stout et al, 2000;Sostaric et al, 2010;Doty et al, 2011;Barrier-Battut et al, 2013). Time of SP exposure and concentration of SP seem to be of major importance concerning sperm motility, membrane integrity, viability and fertility (Bergeron & Manjunath, 2006).…”

Section: <00001mentioning

confidence: 99%

“…Addition of SP to preserved semen immediately before insemination may be beneficial for some reasons: SP modulates the immune response in the female genital tract to protect spermatozoa (Troedsson et al, 2000(Troedsson et al, , 2005Dahms & Troedsson, 2002;Alghamdi et al, 2004;Doty et al, 2011) and promotes elimination of non-viable spermatozoa (Troedsson et al, 2005); SP is able to increase immediate motility of fresh and frozen-thawed epididymal and ejaculated spermatozoa (Braun et al, 1994;Stout et al, 2000;Heise et al, 2011;Neuhauser et al, 2013;Morrell et al, 2014); SP seems to be important for sperm maturation, plasma membrane remodelling, capacitation, acrosome reaction and fertilization (T€ opfer-Petersen et al, 2005;Rodr ıguez-Mart ınez et al, 2011;Caballero et al, 2012;Barrier-Battut et al, 2013) and could therefore increase fertility of epididymal spermatozoa. Although adding SP to the flushing medium did not improve post-thaw motility of epididymal spermatozoa in all stallions (Heise et al, 2011), there was a significant improvement in motility when added after the freeze-thaw process (Neuhauser et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Dose-dependent effects of homologous seminal plasma on motility and kinematic characteristics of post-thaw stallion epididymal spermatozoa

2015

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SUMMARYPreservation of epididymal spermatozoa is important to save genetic material of endangered species and breeds, or in case of unexpected injury, which will end the breeding career of valuable sires. Seminal plasma (SP) influences sperm quality in a dosedependent manner and its addition to preserved semen immediately before insemination may be beneficial for sperm fertility. Increased plasma membrane stability of epididymal spermatozoa reduces freezing injury of cells, and the addition of SP after freezing and thawing might have activating and protecting effects on spermatozoa within the female genital tract. In this study, epididymal spermatozoa were harvested by retrograde flush of the epididymal cauda immediately after routine castration and frozen. Seminal plasma was collected from other six stallions. Homologous SP (SP from the same species, but from a different animal) was added to frozen-thawed epididymal spermatozoa at concentrations of 0, 5, 20, 50 and 80% SP. Addition of SP increased sperm motility and influenced kinematic values in a dose-dependent manner (p < 0.05). Motility improved at concentrations of 20 and 50% SP, but did not further increase at 80% SP. There was no difference in sperm motility among SP from six different donor stallions regardless of the concentrations of SP (p > 0.05). Total and progressive motility of ten frozen-thawed epididymal spermatozoa samples collected from different stallions after dilution with extender and 5, 20, 50 or 80% SP differed significantly (p < 0.05). In conclusion, addition of homologous SP to frozen-thawed stallion epididymal spermatozoa immediately improved motility in a dose-dependent manner regardless of semen quality of SP donor stallions. This might positively influence fertility when SP is added before insemination. Moreover, there seems to be a threshold level of SP concentration for optimal improvement of sperm motility.

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Equine CRISP3 Modulates Interaction Between Spermatozoa and Polymorphonuclear Neutrophils1

Cited by 70 publications

References 35 publications

Identification of Distinct Populations of Prostasomes That Differentially Express Prostate Stem Cell Antigen, Annexin A1, and GLIPR2 in Humans1

Identification of Distinct Populations of Prostasomes That Differentially Express Prostate Stem Cell Antigen, Annexin A1, and GLIPR2 in Humans1

Seminal Fluid Signalling in the Female Reproductive Tract: Implications for Reproductive Success and Offspring Health

Dose-dependent effects of homologous seminal plasma on motility and kinematic characteristics of post-thaw stallion epididymal spermatozoa

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