William H. Kinsey

Role of FYN Kinase in Spermatogenesis: Defects Characteristic of Fyn-Null Sperm in Mice

ABSTRACT FYN kinase is highly expressed in the testis and has been implicated in testis and sperm function, yet specific roles for this kinase in testis somatic and germ cells have not been defined. The purpose of the present investigation was to identify aspects of spermatogenesis, spermiation, or sperm fertilizing capacity that required FYN for normal reproductive function. Matings between Fyn-null males and wild-type females resulted in normal litter sizes, despite the fact that Fyn-null males exhibited reduced epididymal size and sperm count. Morphological analysis revealed a high frequency of abnormal sperm morphology among Fyn-null sperm, and artificial insemination competition studies demonstrated that Fyn-null sperm possessed reduced fertilizing capacity. Fyn-null sperm exhibited nearly normal motility during capacitation in vitro but reduced ability to undergo the acrosome reaction and fertilize oocytes. The typical pattern of capacitation-induced protein tyrosine phosphorylation was slightly modified in Fyn-null sperm, with reduced abundance of several minor phosphoproteins. These findings are consistent with a model in which FYN kinase plays an important role in proper shaping of the head and acrosome within the testis and possibly an additional role in the sperm acrosome reaction, events required for development of full fertilizing capacity in sperm.

Protein tyrosine kinase‐dependent release of intracellular calcium in the sea urchin egg

The aminoguanide, methylglyoxal bis(guanylhydrazone) (MGBG), was shown to stimulate phosphorylation of RR‐SRC, a synthetic protein tyrosine kinase (PTK) substrate, and different levels of tyrosyl phosphorylation of endogenous proteins in a sea urchin egg membrane‐cortex preparation. Stimulating protein tyrosine kinase activity in the sea urchin egg stimulated intracellular Ca2+ release, because microinjection of 1–5 mM of MGBG into unfertilized eggs triggered a transient rise in intracellular Ca2+ activity ([Ca2+]i) after a brief latent period. Pretreating eggs with PTK‐specific inhibitors, genistein or tyrphostin B42+, significantly inhibited the MGBG‐induced rise in [Ca2+]i. Methylglyoxal bis(guanylhydrazone) stimulation of PTK activities in the unfertilized sea urchin egg appeared to trigger Ca2+ release through phospholipase C (PLC)‐dependent inositol 1,4,5‐trisphosphate (InsP3) production. The MGBG‐induced Ca2+ response could be suppressed in eggs preloaded with the InsP3 receptor antagonist, heparin, and was reduced in eggs pretreated with U7312+, a PLC inhibitor. However, the response was unchanged in eggs treated with nicotinamide, an inhibitor of ADP‐ribosyl cyclase, or nifedipine, an inhibitor of nicotinic acid adenine dinucleotide phosphate activity. These results suggest that MGBG may be useful as a chemical agonist of PTK in sea urchin eggs and allow direct testing of the PTK requirement for the transient rise in [Ca2+]i in sea urchin eggs during fertilization. Although genistein was observed to significantly delay the onset, the sperm‐induced Ca2+ response in PTK inhibitor‐loaded eggs otherwise appeared normal. Therefore, it was concluded that sea urchin eggs contain a PTK‐dependent pathway that can mediate intracellular Ca2+ release, but PTK activity does not appear to be required for the fertilization response.

Protein tyrosine kinase signaling during oocyte maturation and fertilization.

The oocyte is a highly specialized cell capable of accumulating and storing energy supplies as well as maternal transcripts and pre‐positioned signal transduction components needed for zygotic development, undergoing meiosis under control of paracrine signals from the follicle, fusing with a single sperm during fertilization, and zygotic development. The oocyte accomplishes this diverse series of events by establishing an array of signal transduction pathway components that include a select collection of protein tyrosine kinases (PTKs) that are expressed at levels significantly higher than most other cell types. This array of PTKs includes cytosolic kinases such as SRC‐family PTKs (FYN and YES), and FAK kinases, as well as FER. These kinases typically exhibit distinct patterns of localization and in some cases are translocated from one subcellular compartment to another during meiosis. Significant differences exist in the extent to which PTK‐mediated pathways are used by oocytes from species that fertilize externally versus internally. The PTK activation profiles as well as calcium signaling pattern seems to correlate with the extent to which a rapid block to polyspermy is required by the biology of each species. Suppression of each of the SRC‐family PTKs as well as FER kinase results in failure of meiotic maturation or zygote development, indicating that these PTKs are important for oocyte quality and developmental potential. Future studies will hopefully reveal the extent to which these factors impact clinical assisted reproductive techniques in domestic animals and humans. Mol. Reprod. Dev. 78:831–845, 2011.

Fyn kinase activity is required for normal organization and functional polarity of the mouse oocyte cortex.

The objective of the present study was to determine whether Fyn kinase participated in signaling events during sperm–egg interactions, sperm incorporation, and meiosis II. The functional requirement of Fyn kinase activity in these events was tested through the use of the protein kinase inhibitor SKI‐606 (Bosutinib) and by analysis of Fyn‐null oocytes. Suppression of Fyn kinase signaling prior to fertilization caused disruption of the functional polarity of the oocyte with the result that sperm were able to fuse with the oocyte in the immediate vicinity of the meiotic spindle, a region that normally does not allow sperm fusion. The loss of functional polarity was accompanied by disruption of the microvilli and cortical granule‐free zone that normally overlie the meiotic spindle. Changes in the distribution of cortical granules and filamentous actin provided further evidence of disorganization of the oocyte cortex. Rho B, a molecular marker for oocyte polarity, was unaffected by suppression of Fyn activity; however, the polarized association of Par‐3 with the cortex overlying the meiotic spindle was completely disrupted. The defects in oocyte polarity in Fyn‐null oocytes correlated with a failure of the MII chromosomes to maintain a position close to the oocyte cortex which seemed to underlie the above defects in oocyte polarity. This was associated with a delay in completion of meiosis II. Pronuclei, however, eventually formed and subsequent mitotic cleavages and blastocyst formation occurred normally. Mol. Reprod. Dev. 76: 819–831, 2009.

Functions of Fyn kinase in the completion of meiosis in mouse oocytes

Oocyte maturation invokes complex signaling pathways to achieve cytoplasmic and nuclear competencies for fertilization and development. The Src-family kinases FYN, YES and SRC are expressed in mammalian oocytes but their function during oocyte maturation remains an open question. Using chemical inhibitor, siRNA knockdown, and gene deletion strategies the function of Src-family kinases was evaluated in mouse oocytes during maturation under in vivo and in vitro conditions. Suppression of Src-family as a group with SKI606 greatly reduced meiotic cell cycle progression to metaphase-II. Knockdown of FYN kinase expression after injection of FYN siRNA resulted in an approximately 50% reduction in progression to metaphase-II similar to what was observed in oocytes isolated from FYN (-/-) mice matured in vitro. Meiotic cell cycle impairment due to a Fyn kinase deficiency was also evident during oocyte maturation in vivo since ovulated cumulus oocyte complexes collected from FYN (-/-) mice included immature metaphase-I oocytes (18%). Commonalities in meiotic spindle and chromosome alignment defects under these experimental conditions demonstrate a significant role for Fyn kinase activity in meiotic maturation.

Loss of the repressor REST in uterine fibroids promotes aberrant G protein-coupled receptor 10 expression and activates mammalian target of rapamycin pathway

Uterine fibroids (leiomyomas) are the most common tumors of the female reproductive tract, occurring in up to 77% of reproductive-aged women, yet molecular pathogenesis remains poorly understood. A role for atypically activated mammalian target of rapamycin (mTOR) pathway in the pathogenesis of uterine fibroids has been suggested in several studies. We identified that G protein-coupled receptor 10 [GPR10, a putative signaling protein upstream of the phosphoinositide 3-kinase–protein kinase B/AKT–mammalian target of rapamycin (PI3K/AKT–mTOR) pathway] is aberrantly expressed in uterine fibroids. The activation of GPR10 by its cognate ligand, prolactin releasing peptide, promotes PI3K–AKT–mTOR pathways and cell proliferation specifically in cultured primary leiomyoma cells. Additionally, we report that RE1 suppressing transcription factor/neuron-restrictive silencing factor (REST/NRSF), a known tumor suppressor, transcriptionally represses GPR10 in the normal myometrium, and that the loss of REST in fibroids permits GPR10 expression. Importantly, mice overexpressing human GPR10 in the myometrium develop myometrial hyperplasia with excessive extracellular matrix deposition, a hallmark of uterine fibroids. We demonstrate previously unrecognized roles for GPR10 and its upstream regulator REST in the pathogenesis of uterine fibroids. Importantly, we report a unique genetically modified mouse model for a gene that is misexpressed in uterine fibroids.

Regionalized calcium signaling in zebrafish fertilization

Fertilization involves an initial, highly localized signal delivered by the sperm, which becomes amplified by a signal transduction cascade to impact the entire oocyte cytoplasm. The zebrafish oocyte presents a unique opportunity to study this process since fertilization always occurs at the micropyle, allowing the investigator to image the earliest steps in the oocyte activation process. The objective of the present study was to characterize the amplification of the sperm-induced calcium transient in the zebrafish oocyte and test the role of Fyn kinase in this process. Confocal fluorescence microscopy revealed that the sperm-induced calcium transient was composed of two elements, one of which was unique to the oocyte cortex and a second, slower transient that occurred in the central cytoplasm of the oocyte. The cortical transient was initiated immediately deep to the micropyle, became amplified at the animal pole, and progressed peripherally through the oocyte cortex. This was followed by a slower transient that occurred in the central cytoplasm of the oocyte. Several lines of evidence indicate that calcium release in these two compartments may be regulated differently. The calcium transient in the oocyte cortex is highly sensitive to inhibition by Fyn-SH2 domain containing fusion proteins, while the central cytoplasmic transient is relatively resistant to this treatment. Oocytes stimulated by injection of a soluble extract prepared from zebrafish sperm respond only with a cortical calcium transient initiated at the micropyle, while oocytes stimulated parthenogenetically by hypotonic shock exhibit a defective cortical transient but a normal transient in the central cytoplasm. Analysis of the subcellular distribution of Fyn kinase and the IP3 receptor reveal that these important signaling components are highly enriched in the oocyte cortex, a factor which may facilitate a faster propagation of the calcium transient in this compartment. In summary, analysis of calcium signaling in the zebrafish oocyte requires attention to morphologically distinct compartments of the oocyte and it is likely that these compartments are controlled by different biochemical events.

Role of Fyn kinase in oocyte developmental potential

Fyn kinase is highly expressed in oocytes, with inhibitor and dominant-negative studies suggesting a role in the signal transduction events during egg activation. The purpose of the present investigation was to test the hypothesis that Fyn is required for calcium signalling, meiosis resumption and pronuclear congression using the Fyn-knockout mouse as a model. Accelerated breeding studies revealed that Fyn-null females produced smaller litter sizes at longer intervals and exhibited a rapid decline in pup production with increasing age. Fyn-null females produced a similar number of oocytes, but the frequency of immature oocytes and mature oocytes with spindle chromosome abnormalities was significantly higher than in controls. Fertilised Fyn-null oocytes frequently (24%) failed to undergo pronuclear congression and remained at the one-cell stage. Stimulation with gonadotropins increased the number of oocytes ovulated, but did not overcome the above defects. Fyn-null oocytes overexpressed Yes kinase in an apparent effort to compensate for the loss of Fyn, yet still exhibited an altered pattern of protein tyrosine phosphorylation. In summary, Fyn-null female mice exhibit reduced fertility that appears to result from actin cytoskeletal defects rather than calcium signalling. These defects cause developmental arrest during oocyte maturation and pronuclear congression.

Anti-peptide Antibody Identifies a 57 kDa Protein Tyrosine Kinase in the Sea Urchin Egg Cortex

The egg plasma membrane and cortical structures are highly enriched in protein tyrosine kinase activity which is thought to play an important role in the fertilization process. In order to identify the tyrosine protein kinases in the egg cortex, a site directed polyclonal antibody was produced against a peptide duplicating a conserved region of the catalytic domain of the sea urchin c‐abl gene product. The region chosen as an antigen had a high degree of homology (57%) to other protein tyrosine kinases. The antibody was found to bind with a high degree of specificity to a 57 kDa protein tyrosine kinase in S. purpuratus eggs. The antibody was capable of immunoprecipitating the enzyme as a 57 kDa phosphoprotein from purified egg cortex fractions solubilized in NP‐40. Immunoprecipitation was completely inhibited by prior incubation of the antibody with the synthetic peptide used as an antigen. Binding of the antibody completely inhibited kinase activity. However, the immunoprecipitated kinase activity could be eluted from the Sepharose‐coupled antibody and was shown to have catalytic activity towards a tyrosine containing peptide substrate. The enzyme also underwent autophosphorylation on tyrosine in vitro. Ultrastructural localization of the kinase by immuno‐electron microscopy revealed that the enzyme was primarily restricted to the egg plasma membrane.

PYK2: A Calcium-sensitive Protein Tyrosine Kinase Activated in Response to Fertilization of the Zebrafish Oocyte

Fertilization begins with binding and fusion of a sperm with the oocyte, a process that triggers a high amplitude calcium transient which propagates through the oocyte and stimulates a series of preprogrammed signal transduction events critical for zygote development. Identification of the pathways downstream of this calcium transient remains an important step in understanding the basis of zygote quality. The present study demonstrates that the calcium-calmodulin sensitive protein tyrosine kinase PYK2 is a target of the fertilization-induced calcium transient in the zebrafish oocyte and that it plays an important role in actin-mediated events critical for sperm incorporation. At fertilization, PYK2 was activated initially at the site of sperm-oocyte interaction and was closely associated with actin filaments forming the fertilization cone. Later PYK2 activation was evident throughout the entire oocyte cortex, however activation was most intense over the animal hemisphere. Fertilization-induced PYK2 activation could be blocked by suppressing calcium transients in the ooplasm via injection of BAPTA as a calcium chelator. PYK2 activation could be artificially induced in unfertilized oocytes by injection of IP3 at concentrations sufficient to induce calcium release. Functionally, suppression of PYK2 activity by chemical inhibition or by injection of a dominant-negative construct encoding the N-terminal ERM domain of PKY2 inhibited formation of an organized fertilization cone and reduced the frequency of successful sperm incorporation. Together, the above findings support a model in which PYK2 responds to the fertilization-induced calcium transient by promoting reorganization of the cortical actin cytoskeleton to form the fertilization cone.