William H. Walker

The v-rel oncogene encodes a κB enhancer binding protein that inhibits NF-κB function

Abstract Studies of NF-κB suggest that this enhancer binding activity corresponds to a family of at least four proteins (p50, p55, p75, and p85) differentially induced with biphasic kinetics during T cell activation. While p55 and p50 are closely related to the 50 kd DNA binding subunit of NF-κB, p75 and p85 exhibit DNA binding properties that distinguish them from this 50 kd poly-peptide and its regulatory subunits IκB and p65. All four members of this κB-specific protein family are structurally related to the v-Rel oncoprotein and one, p85, appears identical to human c-Rel. v-Rel, but not nontransforming v-Rel mutants, binds to the κB enhancer and inhibits NF-κB-activated transcription from the IL-2 receptor α promoter and HIV-1 LTR. These findings suggest a Rel-related family of κB enhancer binding proteins and raise the possibility that the transforming activity of v-Rel is Iinked to its inhibitory action on cellular genes under NF-κB control.

The Regulation of Spermatogenesis by Androgens

Testosterone is essential for maintaining spermatogenesis and male fertility. However, the molecular mechanisms by which testosterone acts have not begun to be revealed until recently. With the advances obtained from the use of transgenic mice lacking or overexpressing the androgen receptor, the cell specific targets of testosterone action as well as the genes and signaling pathways that are regulated by testosterone are being identified. In this review, the critical steps of spermatogenesis that are regulated by testosterone are discussed as well as the intracellular signaling pathways by which testosterone acts. We also review the functional information that has been obtained from the knock out of the androgen receptor from specific cell types in the testis and the genes found to be regulated after altering testosterone levels or androgen receptor expression.

Non-classical actions of testosterone and spermatogenesis

Testosterone is essential to maintain spermatogenesis and male fertility. In the absence of testosterone stimulation, spermatogenesis does not proceed beyond the meiosis stage. After withdrawal of testosterone, germ cells that have progressed beyond meiosis detach from supporting Sertoli cells and die, whereas mature sperm cannot be released from Sertoli cells resulting in infertility. The classical mechanism of testosterone action in which testosterone activates gene transcription by causing the androgen receptor to translocate to and bind specific DNA regulatory elements does not appear to fully explain testosterone regulation of spermatogenesis. This review discusses two non-classical testosterone signalling pathways in Sertoli cells and their potential effects on spermatogenesis. Specifically, testosterone-mediated activation of phospholipase C and calcium influx into Sertoli cells is described. Also, testosterone activation of Src, EGF receptor and ERK kinases as well as the activation of the CREB transcription factor and CREB-mediated transcription is reviewed. Regulation of germ cell adhesion to Sertoli cells and release of mature sperm from Sertoli cells by kinases regulated by the non-classical testosterone pathway is discussed. The evidence accumulated suggests that classical and non-classical testosterone signalling contribute to the maintenance of spermatogenesis and male fertility.

Testosterone signaling and the regulation of spermatogenesis

Spermatogenesis and male fertility are dependent upon the presence of testosterone in the testis. In the absence of testosterone or the androgen receptor, spermatogenesis does not proceed beyond the meiosis stage. The major cellular target and translator of testosterone signals to developing germ cells is the Sertoli cell. In the Sertoli cell, testosterone signals can be translated directly to changes in gene expression (the classical pathway) or testosterone can activate kinases that may regulate processes required to maintain spermatogenesis (the non-classical pathway). Contributions of the classical and non-classical testosterone signaling pathways to the maintenance of spermatogenesis are discussed. Studies that may further elaborate the mechanisms by with the pathways support spermatogenesis are proposed.

Molecular mechanisms of testosterone action in spermatogenesis.

Testosterone is required for the maturation of male germ cells, the production of sperm and thus male fertility. However, the mechanisms by which testosterone regulates spermatogenic processes have not been well defined. In this review, classical and non-classical pathways of testosterone signaling in the Sertoli cells of the testis are discussed in relation to testosterone-regulated processes that are required for spermatogenesis.

Delivery of a Cyclic Adenosine 3′,5′-Monophosphate Response Element-Binding Protein (CREB) Mutant to Seminiferous Tubules Results in Impaired Spermatogenesis1

FSH binding to Sertoli cells is required for optimal production of sperm in mammals. The cAMP response element-binding protein (CREB) is a major mediator of FSH-induced changes in gene expression. To determine whether CREB is required for spermatogenesis, an adenovirus encoding a phosphorylation-defective CREB mutant (AdCREBm1) was used to inhibit CREB activity in Sertoli cells. Addition of AdCREBm1 to primary rat Sertoli cell cultures completely abolished induction of the CREB-regulated c-fos gene. Injection of an adenovirus encoding ss-galactosidase into the rat testis seminiferous tubules in vivo demonstrated that predominately Sertoli cells were infected by adenovirus. AdCREBm1-directed expression of CREBm1 in seminiferous tubules did not affect Sertoli cell viability, but resulted in the apoptosis of meiotic spermatocyte germ cells within 4 days of adenovirus injection into seminiferous tubules. Disrupted spermatogenesis, defined by at least a 75% reduction of round spermatids, was observed in 42 +/- 5.8% of seminiferous tubules 14 days after AdCREBm1 infection, whereas using this criteria, testes injected with a control adenovirus did not display disrupted spermatogenesis. These data demonstrate that AdCREBm1 causes apoptosis and elimination of germ cells and suggest that CREB is required to produce a Sertoli cell-derived factor that is critical for germ cell survival.FSH binding to Sertoli cells is required for optimal production of sperm in mammals. The cAMP response element-binding protein (CREB) is a major mediator of FSH-induced changes in gene expression. To determine whether CREB is required for spermatogenesis, an adenovirus encoding a phosphorylation-defective CREB mutant (AdCREBm1) was used to inhibit CREB activity in Sertoli cells. Addition of AdCREBm1 to primary rat Sertoli cell cultures completely abolished induction of the CREB-regulated c-fos gene. Injection of an adenovirus encoding ss-galactosidase into the rat testis seminiferous tubules in vivo demonstrated that predominately Sertoli cells were infected by adenovirus. AdCREBm1-directed expression of CREBm1 in seminiferous tubules did not affect Sertoli cell viability, but resulted in the apoptosis of meiotic spermatocyte germ cells within 4 days of adenovirus injection into seminiferous tubules. Disrupted spermatogenesis, defined by at least a 75% reduction of round spermatids, was observed in 42 +/- 5.8% of seminiferous tubules 14 days after AdCREBm1 infection, whereas using this criteria, testes injected with a control adenovirus did not display disrupted spermatogenesis. These data demonstrate that AdCREBm1 causes apoptosis and elimination of germ cells and suggest that CREB is required to produce a Sertoli cell-derived factor that is critical for germ cell survival.

Sex, Age, and Regional Differences in L-Type Calcium Current Are Important Determinants of Arrhythmia Phenotype in Rabbit Hearts With Drug-Induced Long QT Type 2

In congenital and acquired long QT type 2, women are more vulnerable than men to Torsade de Pointes. In prepubertal rabbits (and children), the arrhythmia phenotype is reversed; however, females still have longer action potential durations than males. Thus, sex differences in K+ channels and action potential durations alone cannot account for sex-dependent arrhythmia phenotypes. The L-type calcium current (ICa,L) is another determinant of action potential duration, Ca2+ overload, early afterdepolarizations (EADs), and Torsade de Pointes. Therefore, sex, age, and regional differences in ICa,L density and in EAD susceptibility were analyzed in epicardial left ventricular myocytes isolated from the apex and base of prepubertal and adult rabbit hearts. In prepubertal rabbits, peak ICa,L at the base was 22% higher in males than females (6.4±0.5 versus 5.0±0.2 pA/pF; P<0.03) and higher than at the apex (6.4±0.5 versus 5.0±0.3 pA/pF; P<0.02). Sex differences were reversed in adults: ICa,L at the base was 32% higher in females than males (9.5±0.7 versus 6.4±0.6 pA/pF; P<0.002) and 28% higher than the apex (9.5±0.7 versus 6.9±0.5 pA/pF; P<0.01). Apex–base differences in ICa,L were not significant in adult male and prepubertal female hearts. Western blot analysis showed that Cav1.2&agr; levels varied with sex, maturity, and apex–base, with differences similar to variations in ICa,L; optical mapping revealed that the earliest EADs fired at the base. Single myocyte experiments and Luo–Rudy simulations concur that ICa,L elevation promotes EADs and is an important determinant of long QT type 2 arrhythmia phenotype, most likely by reducing repolarization reserve and by enhancing Ca2+ overload and the propensity for ICa,L reactivation.

Role of transcription factors CREB and CREM in cAMP-regulated transcription during spermatogenesis

The cAMP response element binding protein (CREB) and the cAMP-responsive element modulator (CREM) are cyclically expressed at high levels during spermatogenesis. Cyclical expression of CREB and CREM in germ and somatic Sertoli cells correlates with the fluctuations in cAMP signaling induced by the pituitary gonadotropic hormones FSH and LH both during sexual maturation of the testis and during the 12-day cycles of spermatogenesis that occur in the adult testis. CREB and CREM are expressed at different times during the spermatogenic cycle, undergo programmed sequential switches from activator to repressor isoforms by mechanisms of alternative exon splicing and promoter usage, and are autoregulated by cAMP signaling in opposing directions. cAMP response elements located in the promoter of the CREB gene upregulate the expression of activator CREBs, whereas cAMP autoregulatory response elements in the internal promoter of the CREM gene induce expression of repressor CREM isoforms. The complex mechanisms for the regulation of the expression of CREB and CREM in the testis appear to reflect critical adaptations for regulating key target genes essential for the development of germ cells.

NF-κB and TNF-α stimulate androgen receptor expression in Sertoli cells

Abstract Germ cell development within the mammalian testis requires testosterone stimulation of somatic Sertoli cells via interaction with intracellular androgen receptors (AR). AR expression levels undergo marked changes during spermatogenesis suggesting that the modulation of AR expression is an important mechanism to regulate Sertoli cell responsiveness to testosterone. An analysis of the AR gene promoter revealed three κB enhancer elements that interacted with Sertoli cell p50 and RelA NF-κB proteins, and the overexpression of these NF-κB subunits in Sertoli cells stimulated AR promoter activity. Moreover, TNF-α, a secretory product of round spermatids, stimulated NF-κB binding to the AR promoter, induced AR promoter activity, and increased endogenous AR expression in primary cultures of Sertoli cells. Given the requirement of testosterone for spermatogenesis and the importance of AR in mediating Sertoli cell responsiveness to testosterone, the stimulation of AR expression by NF-κB and TNF-α may represent an important regulatory mechanism required to maintain efficient spermatogenesis.

Hormonal regulation of the NF-κB signaling pathway

Abstract The NF-κB transcription factor modulates a number of gene responses to hormonal stimuli. NF-κB can be induced by growth promoting hormones and cytokines, has been shown to counteract the effectiveness of steroid hormones and has recently been found to be regulated during mammalian spermatogenesis. Recent advances in the characterization of the NF-κB signaling pathway offer new opportunities to examine how hormonal stimuli regulate NF-κB mediated gene expression. In this mini-review we outline the signal pathways responsible for activating NF-κB, discuss the hormonal regulation of NF-κB and the regulation of hormonal responses by NF-κB, as well as summarize new studies characterizing NF-κB expression and activity in the mammalian testis.