Focal adhesion kinase is a regulator of F-actin dynamics: New insights from studies in the testis.

During spermatogenesis, spermatogonia (2n, diploid) undergo a series of mitotic divisions as well as differentiation to become spermatocytes, which enter meiosis I to be followed by meiosis II to form round spermatids (1n, haploid), and then differentiate into spermatozoa (1n, haploid) via spermiogenesis. These events take place in the epithelium of the seminiferous tubule, involving extensive junction restructuring at the Sertoli-Sertoli and Sertoli-germ cell interface to allow the transport of developing germ cells across the epithelium. Although structural aspects of these cell-cell junctions have been studied, the underlying mechanism(s) that governs these events has yet to be explored. Earlier studies have shown that a non-receptor protein tyrosine kinase known as focal adhesion kinase (FAK) is a likely regulator of these events due to the stage-specific and spatiotemporal expression of its various phosphorylated/activated forms at the testis-specific anchoring junctions in the testis, as well as its association with actin regulatory proteins. Recent studies have shown that FAK, in particular its two activated phosphorylated forms p-FAK-Tyr407 and p-FAK-Tyr397, are crucial regulators in modulating junction restructuring at the Sertoli cell-cell interface at the blood-testis barrier (BTB) known as the basal ectoplasmic specialization (basal ES), as well as at the Sertoli-spermatid interface called apical ES during spermiogenesis via its effects on the filamentous (F)-actin organization at the ES. We herein summarize and critically evaluate the current knowledge regarding the physiological significance of FAK in regulating BTB and apical ES dynamics by governing the conversion of actin filaments at the ES from a "bundled" to a "de-bundled/branched" configuration and vice versa. We also provide a molecular model on the role of FAK in regulating these events based on the latest findings in the field.

Introduction

Spermatogenesis takes place in the seminiferous tubule—the functional unit in the testis—to produce spermatozoa (haploid, 1n) from spermatogonia (diploid, 2n) via spermatogenesis.- This highly complex cellular process contains four distinct events, namely mitosis, meiosis, spermiogenesis, and spermiation that constitute the seminiferous epithelial cycle. The seminiferous epithelium, on the other hand, is anatomically segregated into two compartments, the basal and the apical compartment, by the blood-testis barrier (BTB) (Fig. 1). The BTB is constituted by multiple co-existing junctions: (1) testis-specific adherens junction (AJ) called basal ectoplasmic specialization (basal ES), (2) tight junction (TJ), and (3) gap junction (GJ), which together with (4) desmosome at the Sertoli cell-cell interface near the basement membrane of the tunica propria, create one of the tightest blood-tissue barriers in mammals (Fig. 1).- Thus, in the mammalian testis, endothelial TJ barrier of the microvessels in the interstitium contributes virtually no barrier function of the BTB., The hallmark ultrastructural feature of the BTB, unlike all other blood-tissue barriers, is the tightly packed actin filament bundles that line perpendicular to the Sertoli cell plasma membrane, which are sandwiched in-between cisternae of endoplasmic reticulum and the apposing Sertoli cell plasma membranes. This unusual ultrastructural feature of the BTB was first described in the early 1970s in the testis., The term ectoplasmic specialization (ES) was subsequently used in the late 1970s when similar bundles of actin filaments were also found at the Sertoli-spermatid and Sertoli cell-cell interface and designated apical and basal ES, respectively.- The only ultrastructural difference between the apical and basal ES is that the actin filament bundles are not found in the spermatid (step 8–19 spermatids) but restricted only to the Sertoli cell, such that there are only a single array of actin filament bundles at the apical ES vs. two layers of these F-actin bundles at the basal ES (Fig. 1). It is also these actin filament bundles that confer the unusual adhesive strength to the ES in the testis,, making the BTB one of the tightest blood-tissue barriers. However, the basal ES/BTB undergoes extensive restructuring at stage VIII of the epithelial cycle to facilitate the transit of preleptotene spermatocytes across the BTB to enter the adluminal compartment to prepare for meiosis., Furthermore, the apical ES also restructures extensively during spermiogenesis to facilitate the transport of spermatids across the seminiferous epithelium during the epithelial cycle. Once the apical ES forms at the Sertoli-step 8 spermatid interface, it is the only anchorage device, replacing desmosome and GJ, and persists until step 19 spermatids that line up at the luminal edge of the seminiferous tubule to prepare for the release of sperm at spermiation.- Thus, it is conceivable that during spermatogenesis, extensive junction restructuring and cytoskeletal reorganization take place in the seminiferous epithelium to facilitate the transport of: (1) preleptotene spermatocytes across the BTB and (2) spermatids across the epithelium during the epithelial cycle, yet the regulatory biomolecules and/or mechanism(s) remain elusive until recently.

Figure 1. An schematic drawing illustrating the regulatory events mediated by the β1-integrin/FAK signaling cascades during apical ES degeneration at spermiation. This is a schematic drawing of the seminiferous epithelium in the rat testis in which the blood-testis barrier (BTB) physically divides the epithelium into the adluminal (apical) and the basal compartment with the base of the Sertoli cell lies on the basement membrane of the tunica propria. Apical ES first appears at the interface of step 8 spermatids and Sertoli cells at stage VIII of the epithelial cycle, once it forms, it is the only anchoring device in these spermatids, replacing desmosome and gap junction at the Sertoli-spermatid interface, and to confer spermatid polarity. Also, apical ES is found in step 8–19 spermatids, and it begins to undergo degeneration at stage VII of the cycle until it is disintegrated entirely at late stage VIII to allow the release of sperm at spermiation.,, In stage VII-early stage VIII tubules (left panel) as shown herein, spermatids attach to the Sertoli cell through an adhesion protein complex containing α6β1-integrin and laminin-α3β3γ3 (other adhesion protein complexes at the apical ES are: JAM-C-ZO-1, nectin2/3-afadin, and N-cahderin-β-catenin). This complex is known to associate with a large number of regulatory proteins,,, which include PKB, DOCK180, PI3K, and most notably FAK, in particular p-FAK-Tyr397, p-FAK-Tyr407, and p-FAK-Tyr576, which recruit actin cross-linking and bundling proteins, such as Eps8, palladin, and filamin A, to maintain the integrity of the actin filament bundles at the ES. Collectively, these proteins to confer the integrity of the apical ES. At late stage VIII of the epithelial cycle, to prepare for spermiation, the expression of FAK, in particular p-FAK-Tyr397 and -Tyr407, at the apical ES is downregulated.,, This loss of FAK at the apical ES fails to retain the actin filament cross-linking, barded end-capping and bundling proteins (e.g., Eps8, palladin, filamin A) at the apical ES to maintain the integrity of the actin filament bundles, instead, N-WASP activated-Arp2/3 protein complex induces branched actin polymerization, converting the actin filaments from their “unbundled” and their “de-bundled” configuration, destabilizing the apical ES, facilitating endocytic vesicle-mediated protein trafficking to further destabilize apical ES adhesion. Furthermore, apical ES disruption involves also the PI3K/PKB signaling cascades in which ERK1/2, a downstream signaling protein, is activated via phosphorylation (arrow),,,, which further enhances apical ES disruption and, thus, facilitating the release of sperm at spermiation.

Focal adhesion kinase (FAK), a non-receptor protein tyrosine kinase, was first shown in the late 1980s to be highly expressed in the testis with an expression level significantly higher than that of other non-gonadal tissues. Although this finding suggested its physiological significance in regulating cellular event in testes, its function has remained unexplored until almost 15 y later when FAK was first reported to be a crucial regulator of junction dynamics in spermatogenesis. Herein, we summarize and critically evaluate the recent findings on the role of FAK in the testis.

Focal adhesion kinase (FAK)

Focal adhesion kinase (FAK, ~120 kDa), also called protein tyrosine kinase 2 (PTK2), is a non-receptor protein tyrosine kinase, which has been found to be expressed ubiquitously in mammalian tissues including brain, lymphocytes, and testes., FAK contains four linearly arranged functional domains from its N terminus: the band 4.1, Ezrin, Radixin, Moesin (FERM) domain, the catalytic kinase domain, three proline-rich regions, and the focal adhesion targeting (FAT) domain., FAK, as its name implies, is restricted to the focal contact (or focal adhesion complex, FAC), which is an actin-based anchoring junction limited to the cell-extracellular matrix (ECM) interface in mammalian tissues. It is mostly used by motile cells such as fibroblasts, lymphocytes, and metastatic cancer cells for their movement over basal lamina under physiological (e.g., growth, inflammation, combat bacterial/viral infection) or pathophysiological conditions (e.g., tumorigenesis). In the testis, however, FAC is absent in the seminiferous tubules at the Sertoli cell-basement membrane (BM) interface since the BM is a modified form of ECM in the testis., Instead, FAK is found at the Sertoli cell-cell interface at the basal ES in the BTB and also at the Sertoli-spermatid interface at the apical ES.,, FAK, besides being a kinase that phosphorylates downstream signaling target proteins, also functions as a scaffolding and adaptor protein that mediates the assembly of signaling protein complexes via its protein-protein-interacting domains along its polypeptide sequence, in particular, to transducing the integrin-based signals.- It plays an important role in regulating cell proliferation, apoptosis, and cell motility., An elevated expression of FAK also correlates with tumor cell proliferation and metastasis.- In fact, FAK is an oncogene and a therapeutic target of cancer therapy., Collectively, these findings illustrate the pivotal role of FAK in cellular functions, both in health and in disease.

In order to exert its intrinsic kinase activity, FAK must first be activated. There are six putative tyrosine phosphorylation sites in FAK, including Tyr-397, -407, -576, -577, -861, and -925,, and among them, Tyr-397 is the only autophosphorylation site. Upon phosphorylation of Tyr-397, a high-affinity binding site for Src homology 2 (SH2) domain is exposed that allows FAK to act as an adaptor protein to assemble various SH2 domain-containing regulatory proteins, such as Src family kinases,,, to assemble a multiprotein functional complex. While Tyr-397 is autophosphorylated, other Tyr residues in FAK are phosphorylated by Src family kinases and, in turn, lead to respective downstream effects, illustrating the tight physiological relationship between FAK and Src kinases. In fact, the FAK-Src dual kinase complex is an emerging target in cancer therapy, and a crucial functional protein complex in cellular physiological events. Apart from tyrosine phosphorylation, FAK can also be phosphorylated on several Ser residues. For instance, Ser-722 phosphorylation inhibits the intrinsic FAK kinase catalytic activity, while Ser-732 phosphorylation leads to changes in microtubule organization, nuclear movement, and neuronal migration.

FAK is a regulator of the apical ES

Apical ES is an F-actin-rich cell-cell AJ restricted to the Sertoli-spermatid (step 8–19 and 8–16 spermatids in the rat and mouse testis, respectively) interface. FAK was first identified in the rat testis by fluorescence microscopy and shown to be a component in the basal compartment of the seminiferous epithelium as well as at the apical ES. Further studies have shown that the activated forms of FAK, phosphorylated (p)-FAK-Tyr397 and also p-FAK-Tyr576, are restricted to the apical ES and display stage-specific and spatiotemporal expression at the apical ES at stage VI‒VIII of the epithelial cycle, whereas FAK is most predominant at the BTB in virtually all stages of the cycle. Furthermore, p-FAK-Tyr397 forms a complex with the apical ES-associated proteins such as β1-integrin, c-Src, and vinculin complex, indicating its role in mediating β1-integrin signaling pathway at the apical ES. Subsequent studies have confirmed that p-FAK-Tyr397 is an integrated component of the α6β1-integrin-based adhesion complex at the apical ES, which persists until spermiation. Thus, p-FAK-Tyr397 is likely a crucial protein in conferring spermatid adhesion and also a regulator during the release of sperm at spermiation. Furthermore, FAK that works in concert with its partner proteins can create a giant regulatory protein complex composed of p130Cas (p130 Crk-associated substrate), DOCK180 (Dedicator of cytokinese 180), RhoA and vinculin (and its associated partners such as Crk, R-ras, and Grb2), which, in turn, is associated with β1-integrin. In studies using Sertoli-germ cell co-cultures and rats treated with adjudin (a contraceptive drug known to induce apical ES and other anchoring junction restructuring in the testis) to investigate spermatid adhesion, the β1-integrin-p-FAK-p130Cas-DOCK180-RhoA-vinculin complex emerges as a crucial role in mediating alterations on the actin-based cytoskeleton and subsequently modulating spermatid transport and spermiation during spermatogenesis.

With the discoveries of the structural components (e.g., integral membrane protein β1-integrin, adaptor proteins vinculin, and paxillin) that are associated with FAK at the apical ES, in particular, its three activated forms p-FAK-Tyr397,, p-FAK-Tyr576, and p-FAK-Tyr407, and their unique stage-specific and spatiotemporal expression in the seminiferous epithelium,, these observations implicate their likely roles in regulating apical ES dynamics during spermatid transport and spermiation via a modulation of actin filament network in the seminiferous epithelium. For instance, while p-FAK-Tyr397 and -Tyr407 are both highly expressed at the apical ES at stage VII of the epithelial cycle, p-FAK-Tyr397 is restricted to the convex side of the spermatid head and co-localized with β1-integrin,, whereas p-FAK-Tyr407 is expressed almost exclusively to the concave side of the spermatid head and co-localized with Arp3. Arp3 (actin-related protein 3, which together with Arp2 forms the Arp2/3 complex, which can be by N-WASP, neuronal Wiskott-Aldrich syndrome protein,) is known to induce barbed end nucleation of an existing actin filament, thus effectively creating an extensive branched actin network. In short, the N-WASP/Arp2/3 protein complex effectively converts actin filaments from a “bundled” to a “de-bundled/branched” configuration, thereby destabilizing the ES-based cell adhesion and to facilitate endocytic vesicle-mediated protein trafficking., Indeed, recent studies have shown that this site of the apical ES at the concave side of the spermatid head is where endocytic vesicle-mediated protein trafficking takes place to facilitate endocytosis, transcytosis, and recycling of apical ES proteins, such that “old” apical ES proteins can be used to assemble “new” apical ES derived from step 8 spermatids via spermiogenesis., On the other hand, the convex side of the spermatid head is being used to confer spermatid adhesion at stage VII of the epithelial cycle since both Eps8 (epidermal growth factor receptor pathway substrate 8, an actin barbed end capping and bundling protein) and palladin (an actin cross-linking and bundling protein) are also highly expressed at this site, when p-FAK-Tyr397 is upregulated. These actin bundling proteins can thus be used to maintain the integrity of the actin filament bundles at the convex side of the spermatid head to anchor these spermatids onto the Sertoli cell in the epithelium. Interestingly, at late stage VIII of the epithelial cycle, the expression of p-FAK-Tyr397, Eps8, and palladin; as well as p-FAK-Tyr407 and Arp3 are all subsided considerably and they are virtually non-detectable at the apical ES to facilitate the release of sperm at spermiation.,- In short, it is highly likely that these two forms of p-FAK regulate the intrinsic activity of these actin bundling and nucleation proteins to induce re-organization of the network of actin filament bundles at the apical ES during the epithelial cycle to facilitate both spermatid transport across the epithelium during spermiogenesis and the release of sperm at spermiation. This conclusion is supported by findings in a recent report, which have demonstrated that overexpression of a p-FAK-Tyr407 phosphomimetic mutant FAK Y407E in Sertoli cells with an established TJ-permeability barrier significantly enhances the kinetics of actin polymerization, illustrating that p-FAK-Tyr407 at the apical ES can indeed modify the organization of the F-actin network. Furthermore, the knockdown of c-Yes by ~70% in the testis in vivo by RNAi also impedes the localization and downregulates the expression of p-FAK-Tyr407 at the apical ES, causing defects in spermiation in which elongated spermatids are trapped deep inside the seminiferous epithelium in stage VIII tubules, failing to undergo spermiation and these spermatids also display a loss of polarity in which their heads are no longer pointing toward the basement membrane but aligned randomly in the seminiferous epithelium. More important, this downregulation of p-FAK-Tyr407 following the knockdown of c-Yes in the testis also associates with changes in actin polymerization. Taken collectively, these findings have unequivocally demonstrated that the regulating roles of these phosphorylated FAK forms in F-actin reorganization at the apical ES. Furthermore, several protein kinases (e.g., PKB), lipid kinases (e.g., PI3K), and regulatory proteins (e.g., RhoA GTPase, DOCK180) that are known to be involved in regulatory actin dynamics are also binding partners of FAK and/or its phosphorylated forms (Table 1). Figure 1 summarizes these latest findings in the field, regarding the role of FAK in particular p-FAK-Tyr397, -Tyr407, and -Tyr576, in regulating apical ES dynamics during spermatogenesis, depicting a likely regulatory model. Obviously, much work is needed to define the role of FAK in relation to other protein kinases and actin regulatory proteins in conferring F-actin organization at the apical ES as well as other cellular events of spermatogenesis, such as apoptosis, mitosis, meiosis, and cell metabolism.

Table 1. Regulators associate with FAK and/or its phosphorylated/activated form(s) at the apical ES

Regulators	Functions	References
PI3K, PKB,RhoA, DOCK180	Interacts with p-FAK-Tyr397; initiates PI3K/PKB signaling pathway and cross-talks to ERK signaling pathway; facilitates the establishment of AJ in Sertoli-germ cell co-culture	50
sFRP1	Acts upstream of p-FAK-Tyr397; members of Wnt signaling pathway that promotes spermatid adhesion at the apical ES	87
c-Yes	Acts upstream of p-FAK-Tyr407; initiates c-Src signaling pathway and enhances spermiation	58 , 88

AJ, adherens junction; Akt, transforming retrovirus of Ak strain that induces thymoma, spontaneous thymic lymphomas first identified in mouse, also known as protein kinase B (PKB) which is a Ser/Thr-specific protein kinase; DOCK180, dedicator of cytokinesis; ERK, extracellular signal-regulated kinase; PI3K, phosphoinositide 3-kinase; sFRP1, secreted Frizzled-related protein 1; Wnt, Wingless-MMTV Integration Site.

FAK is a regulator of the blood-testis barrier (BTB)

In the mammalian testis, the BTB is different from other blood-tissue barriers (e.g., the blood-brain barrier, the blood-retina barrier). The blood-brain and the blood-retina barriers are constituted almost exclusively by the endothelial TJ-barrier of the microvessels in the brain and the eye, respectively.- Instead, the BTB is morphologically marked by the presence of a testis-specific F-actin-rich adherens junction (AJ) called basal ectoplasmic specialization (basal ES), which is restricted between adjacent Sertoli cells near the basement membrane.,,, The basal ES is ultrastructurally identical to the apical ES when examined by electron microscopy, except that bundles of actin filaments that line perpendicular to the plasma membrane are found on both sides of the Sertoli cells and are sandwiched in-between cisternae of endoplasmic reticulum and the plasma membrane, instead of limiting only to the Sertoli cell at the apical ES.,,, Thus, two layers of actin filament bundles are found at the BTB. Furthermore, basal ES coexists with tight junction (TJ) and gap junction (GJ), which together with desmosome constitute the BTB, making it one of the tightest blood-tissue barriers., Previous studies have identified multiple adhesion protein complexes, such as TJ-protein complexes: occludin-zonula occludens 1 (ZO-1), JAM-A-ZO-1, JAM-B-ZO-1, and claudins-ZO-1; basal ES-protein complexes: N-cadherin-β-catenin, nectin-2-afadin; GJ-protein complexes: connexin43-plakophilin-2; and desmosome protein complexes: desmoglein-2‒desmocollin-2, which constitute the BTB., Interestingly, FAK is structurally associated with the occludin-ZO-1 protein complex at the BTB instead of restricted to the Sertoli cell-basement membrane since FAC is absent in the testis. Subsequent studies have shown that occludin is a putative substrate of FAK, since the knockdown of FAK at the Sertoli cell BTB alters the phosphorylation status of occludin, impeding occludin-ZO-1 association, thereby destabilizing the Sertoli cell TJ-permeability barrier. These findings thus illustrate the pivotal role of FAK in conferring adhesion function at the Sertoli cell BTB via its effects on the phosphorylation status of the occludin-ZO-1 complex.

A more recent report using various mutants of p-FAK-Tyr397 and -Tyr407 for their overexpression in Sertoli cells cultured in vitro with a functional TJ-permeability barrier that mimics the BTB in vivo has shown that p-FAK-Tyr407 is promoting the Sertoli cell BTB function, tightening the TJ-barrier. However, p-FAK-Tyr397 is promoting the BTB disruption, making the Sertoli TJ-permeability barrier “leaky.” In short, the p-FAK-Tyr407 and -Tyr397 forms of FAK have antagonistic effects on the Sertoli cell BTB, illustrating these two non-receptor protein tyrosine kinases may serve as molecular switches to turn “on” and “off” the TJ-barrier during the transit of preleptotene spermatocytes across the BTB at stage VIII of the epithelial cycle. This concept, besides supported by the antagonistic effects of these two forms of FAK, is also strengthened by the stage-specific and spatiotemporal expression of p-FAK-Tyr407 at the BTB as well as its association with Arp3 of the Arp2/3 protein complex. For instance, p-FAK-Tyr407 is structurally associated with N-WASP, suggesting N-WASP is also a substrate of FAK and overexpression of p-FAK-Tyr407 phosphomimetic mutant in the Sertoli cell epithelium that promotes the Sertoli TJ-barrier function also induces an increase in the association of Arp3 and N-WASP. These findings are important because they illustrate that FAK exerts its effects via its p-FAK-Tyr407 and -Tyr397 forms to regulate F-actin organization at the BTB by modulating the conversion of actin filaments from a “bundled” to a “debundled/branched” configuration, conferring plasticity to the F-actin network at the ES. Furthermore, the two phosphorylated forms of FAK are known to interact with several regulatory proteins. For instance, SHP2 (Src homology domain-containing phosphatase-2, a ubiquitously expressed non-receptor protein tyrosine phosphatase in mammalian cells, also known as PTPN11, tyrosine-protein phosphatase non-receptor type 11, an enzyme encoded by PTPN11 gene in humans) is known to downregulate the expression of p-FAK-Tyr397 and initiates the mitogen-activated kinase (MAPK) signaling pathway, subsequently modulating actin cytoskeleton.Figure 2 is a schematic drawing which depicts a hypothetical model on the role of FAK in regulating F-actin organization at the BTB during the epithelial cycle of spermatogenesis.

Figure 2. A schematic diagram illustrating the molecular architecture of the BTB and its restructuring events that are mediated by FAK during the seminiferous epithelial cycle. The panel on the left is a schematic drawing that illustrates the relative location of the BTB in the seminiferous epithelium. The BTB is enlarged and shown in the right panel. The upper part of the diagram on the right displays the molecular architecture of an intact BTB. The relatively high expression of p-FAK-Tyr407 at the BTB, coupled with the upregulation of Eps8 (an actin barbed end capping and bundling protein), and two actin cross-linking and bundling proteins palladin and filamin A at the BTB thus maintain the integrity of the actin filament bundles at the BTB. Occludin/ZO-1 and other TJ proteins (e.g., JAM-B/ZO-1, JAM-A-ZO-1), together with basal ES proteins (e.g., N-cadherin/β-catenin, nectin-2/afadin), gap junction proteins (e.g., connexin-43, connexin-33), and desmosomal proteins (e.g., desmoglein-2), thus confer Sertoli cell-cell adhesion to constitute the blood-testis barrier (BTB). This thus maintains the BTB integrity, such as at stage VII of the epithelial cycle. At stage VIII of the epithelial cycle, BTB undergoes modifications as shown in the lower part of the diagram on the right panel. This is likely mediated via a downregulation of p-FAK-Tyr407, which coupled with an upregulation of the Arp2/3 complex and N-WASP, thereby converting actin filament bundles from their “bundled” to their “unbundled/branched” configuration, destabilizing the BTB to facilitate endocytic vesicle-mediated protein trafficking, facilitating BTB restructuring to allow the transport of preleptotene spermatocytes across the BTB. Other signaling proteins, such as the phosphatase, SHP2 (Src homology domain-containing phosphatase-2) may also take part in this event.

FAK and the apical ES-BTB-BM (apical ectoplasmic specialization-blood-testis barrier-basement membrane) functional axis in the testis

Since the initial discovery of the seminiferous epithelial cycle of spermatogenesis in the 1950–60s in rodents and humans,- it is known that cellular events that occur across the seminiferous epithelium are tightly regulated.,,, However, the molecular basis that coordinates these events is virtually unknown until a report published in 2008, demonstrating for the first time the presence of a local functional axis that coordinates these events known as the apical ES-BTB-BM axis., In this first report, it was shown that overexpression of fragments of laminin chains (note: laminins, such as laminin-α3β3γ3, are components of the adhesion protein complex at the apical ES-) or inclusion of purified recombinant proteins of these fragments in Sertoli cells cultured in vitro with an established TJ-permeability barrier, they both perturbed the Sertoli cell TJ-barrier function. These observations thus suggest that MMP-2 (matrix metalloprotease-2), which is highly expressed at the apical ES at stage VIII of the epithelial cycle, likely cleaves laminin chains at the apical ES during its degeneration at spermiation to generate the biologically active fragments to induce BTB restructuring, thereby coordinating the cellular events of spermiation and BTB restructuring that take place concurrently but at the opposite ends of the epithelium at stage VIII of the epithelial cycle. In short, there is a functional axis between the apical ES and the BTB, which is mediated by the autocrine-based laminin fragments. Since apical ES was absent in these cultures due to the lack of elongating/elongated spermatids, the knockdown of β1-integin by RNAi (note: β1-integrin is a component of the apical ES and also the hemidesmosome at the Sertoli cell-BM interface) was also found to induce BTB restructuring. Thus, the BTB and the hemidesmosome at the BM are also functionally linked. Additionally, recent studies have shown that biologically active fragments are also released by collagen chains in the BM that regulate BTB function, confirming the presence of the BTB-BM axis. This apical ES-BTB-BM functional axis has since been confirmed in which the biologically active domain of at least two laminin chains are identified and they have shown to be potent biologically active peptides to regulate Sertoli BTB function both in vitro and in vivo in a reversible fashion. Furthermore, studies using the phthalate-induced Sertoli cell injury model have also confirmed the presence of this local functional axis in the testis.-

A recent report has shown that the p-FAK-Tyr397 and p-FAK-Tyr407 are the likely “on” and “off” molecular switches in this apical ES-BTB-BM functional axis that modulate the organization of actin filament bundles at the apical ES, as well as the basal ES. For instance, p-FAK-Tyr407 and p-FAK-Tyr397 promotes and disrupts the Sertoli cell TJ-permeability barrier function, respectively, which is mediated via their effects on the organization of F-actin network at the BTB. In short, biologically active laminin fragments released from the apical ES can alter the spatiotemporal expression of these molecular “switches” in the seminiferous epithelium, which, in turn, affects re-organization of F-actin at the basal ES, promoting BTB restructuring. This hypothesis is supported by findings that following administration of the biologically active laminin F5 peptide, there is a downregulation and mis-localization of p-FAK-Tyr407 at the apical and basal ES, which is also associated with a disruption of F-actin organization at both sites, leading to spermatid loss from the epithelium and BTB disruption. At present, the receptor(s) for the laminin fragments, such as F5 peptide, at the BTB is unknown, but β1-integrin is the likely receptor of the laminin fragments at the BM. It is likely that the p-FAK-Tyr407 and -Tyr397 serve as the downstream regulators of the laminin fragment (ligand)-integrin (receptor) complex in this functional axis that coordinates different cellular events that take place across the seminiferous epithelium during the epithelial cycle. Figure 3 is a schematic drawing that illustrates a hypothetical model, in particular, the early signaling cascades along the apical ES-BTB functional axis in the seminiferous epithelium.

Figure 3. The role of p-FAK-Tyr397 and -Tyr407 in coordinating cellular events at the apical ES-BTB functional axis during the epithelial cycle of spermatogenesis. FAK, in particular its two activated/phosphorylated forms of p-FAK-Tyr397 and -Tyr407 is tightly involved in coordinating the events of spermiation and BTB restructuring that take place simultaneously across the epithelium at stage VIII of the seminiferous epithelial cycle. p-FAK-Tyr397 that is highly expressed at early stage VIII of the cycle may: (1) involve in the activation and/or upregulation of matrix metalloproteinase 2 (MMP-2) which cleaves laminin-β3 and -γ3 chains. (2) This thus generates biologically active laminin fragments which are released from the apical ES to activate BTB restructuring via an “inside-outside-in” signaling cascade, involving p-FAK-Tyr407. (3) It is likely that the biologically active laminin fragments are working in concert with p-FAK-Tyr407 to recruit N-WASP-Arp2/3 complex to the site to induce F-actin re-organization, converting actin filaments from their “bundled” to their “unbundled/branched” configuration, thereby destabilizing the BTB. (4) The “unbundled/branched” F-actin network at the BTB thus favors endocytic vesicle-mediated protein trafficking, inducing protein endocytosis, such as TJ protein occludin, leading to BTB restructuring. It is obvious that this model will be rapidly updated when more functional data are available in the near future.

Concluding remarks and future perspectives

Herein, we briefly summarize the critical role of FAK in the seminiferous epithelium of the rat testis. It is likely that the stage-specific and spatiotemporal expression of p-FAK-Tyr397 and p-FAK-Tyr407 at the apical and/or basal ES serve as the downstream signal transducers of the laminin (ligand)-integrin (receptor) complex in the apical ES-BTB-BM functional axis. These signaling complexes either are working in concert with adhesion protein complexes at the ES (e.g., occludin-ZO-1 complex) or actin regulatory proteins (e.g., the N-WASP-Arp2/3 complex, palladin, drebrin E, Eps8) to modulate cell adhesion function and the organization of F-actin at the ES. A better understanding on FAK in the testis should reveal novel targets for male contraceptive development and also insightful information on toxicant-induced reproductive dysfunction since the apical ES-BTB-BT axis is an emerging target of toxicant-induced male infertility.