Federica Barbagallo

STRA8 Shuttles between Nucleus and Cytoplasm and Displays Transcriptional Activity

Stra8 (stimulated by retinoic acid 8) encodes a protein crucial for mammalian germ cells entering into premeiotic stages. Here, to elucidate the still unknown STRA8 molecular functions, we studied the cellular localization of the protein in several cell types, including premeiotic mouse germ cells and stem cell lines. We reported distinct STRA8 localization in germ and stem cell types and a heterogeneous protein distribution in the cytoplasm and nucleus of such cells suggesting that the protein can shuttle between these two compartments. Moreover, we identified specific protein motifs determining its nuclear import/export. Furthermore, we demonstrated that in transfected cell lines the nuclear import of STRA8 is an active process depending on an N-terminal basic nuclear localization signal. Moreover, its nuclear export is mainly mediated by the Exportin1 (XPO1) recognition of a nuclear export signal. Significantly, we also demonstrated that STRA8 associates with DNA and possesses transcriptional activity. These observations strongly suggest that STRA8 can exert important functions in the nucleus rather than in the cytoplasm as believed previously, likely depending on the cell type and regulated by its nuclear-cytoplasmic shuttling.

PATZ1 gene has a critical role in the spermatogenesis and testicular tumours

PATZ1 is a recently discovered zinc finger protein that, due to the presence of the POZ domain, acts as a transcriptional repressor affecting the basal activity of different promoters. To gain insights into its biological role, we generated mice lacking the PATZ1 gene. Male PATZ1−/− mice were unfertile, suggesting a crucial role of this gene in spermatogenesis. Consistently, most of adult testes from these mice showed only few spermatocytes, associated with increased apoptosis, and complete absence of spermatids and spermatozoa, with the subsequent loss of tubular structure. The analysis of PATZ1 expression, by northern blot, western blot and immunohistochemistry, revealed its presence in Sertoli cells and, among the germ cells, exclusively in the spermatogonia. Since PATZ1 has been indicated as a potential tumour suppressor gene, we also looked at its expression in tumours deriving from testicular germ cells (TGCTs). Although expression of PATZ1 protein was increased in these tumours, it was delocalized in the cytoplasm, suggesting an impaired function. These results indicate that PATZ1 plays a crucial role in normal male gametogenesis and that its up‐regulation and mis‐localization could be associated to the development of TGCTs. Copyright

Increased expression and nuclear localization of the centrosomal kinase Nek2 in human testicular seminomas

Protein kinases that regulate the centrosome cycle are often aberrantly controlled in neoplastic cells. Changes in their expression or activity can lead to perturbations in centrosome duplication, potentially leading to chromosome segregation errors and aneuploidy. Testicular germ cell tumours (TGCTs) are characterized by amplification of centrosomes through unknown mechanisms. Herein, we report that Nek2, a centrosomal kinase required for centrosome disjunction and formation of the mitotic spindle, is up‐regulated in human testicular seminomas as compared to control testes or other types of testicular germ cell tumours. In addition, Nek2 activity is also increased in human seminomas, as demonstrated by immunokinase assays. Analysis by immunohistochemistry indicated that Nek2 is prevalently localized in the nucleus of neoplastic cells of primary human seminomas. Such nuclear localization and the up‐regulation of Nek2 protein were also observed in the Tcam‐2 seminoma cell line. We demonstrate that nuclear localization of Nek2 is a feature of the more undifferentiated germ cells of mouse testis and correlates with expression of the stemness markers OCT4 and PLZF. These studies suggest that up‐regulation of Nek2 is a frequent event in human seminomas and that this may participate in the onset or progression of neoplastic transformation through deregulation of centrosome duplication and/or nuclear events in germ cells. Copyright

The centrosomal kinase NEK2 is a novel splicing factor kinase involved in cell survival

NEK2 is a serine/threonine kinase that promotes centrosome splitting and ensures correct chromosome segregation during the G2/M phase of the cell cycle, through phosphorylation of specific substrates. Aberrant expression and activity of NEK2 in cancer cells lead to dysregulation of the centrosome cycle and aneuploidy. Thus, a tight regulation of NEK2 function is needed during cell cycle progression. In this study, we found that NEK2 localizes in the nucleus of cancer cells derived from several tissues. In particular, NEK2 co-localizes in splicing speckles with SRSF1 and SRSF2. Moreover, NEK2 interacts with several splicing factors and phosphorylates some of them, including the oncogenic SRSF1 protein. Overexpression of NEK2 induces phosphorylation of endogenous SR proteins and affects the splicing activity of SRSF1 toward reporter minigenes and endogenous targets, independently of SRPK1. Conversely, knockdown of NEK2, like that of SRSF1, induces expression of pro-apoptotic variants from SRSF1-target genes and sensitizes cells to apoptosis. Our results identify NEK2 as a novel splicing factor kinase and suggest that part of its oncogenic activity may be ascribed to its ability to modulate alternative splicing, a key step in gene expression regulation that is frequently altered in cancer cells.

Ablation of the Sam68 gene impairs female fertility and gonadotropin-dependent follicle development

Sam68 is a multifunctional RNA-binding protein highly expressed in the gonads, whose ablation causes male infertility. Herein, we have investigated Sam68 expression in the adult ovary and its function in female fertility. Immunohistochemistry showed that Sam68 was localized in the nucleus of oocytes and follicular cells at all stages of folliculogenesis. Sam68(-/-) females were severely subfertile, and they showed a delay in the age of first pregnancy, increased breeding time for successful pregnancy and yielded smaller litters. Morphological analyses indicated a significant reduction in the number of secondary and pre-antral follicles in the ovary. These defects were associated with alteration of oestrous cycles and a reduced number of ovulated oocytes, which were only partially restored by the administration of exogenous gonadotropins. Crosslinking/immunoprecipitation experiments showed that Sam68 directly binds the mRNAs for the follicle-stimulating hormone (FSH) and the luteinizing hormone receptors (Fshr and Lhcgr), which were downregulated in ovaries of adult knockout females. Stimulation of immature females with FSH-like pregnant mare serum gonadotropin (PMSG), or of follicular cells with the FSH second messenger analogue 8Br-cAMP, caused the upregulation of Sam68. The increase in Sam68 levels paralleled that of the Fshr and Lhcgr mRNAs in the pre-ovulatory follicle and was required to allow accumulation of these transcripts in follicular cells. These studies identify a new crucial function for Sam68 in the regulation of female fertility and indicate that this protein is required to insure proper expression of the gonadotropin receptor transcripts in pre-ovulatory follicles in adult ovary.

Identification of Murine Phosphodiesterase 5A Isoforms and their Functional Characterization in HL-1 Cardiac Cell Line

Phosphodiesterase 5A (PDE5A) specifically degrades the ubiquitous second messenger cGMP and experimental and clinical data highlight its important role in cardiac diseases. To address PDE5A role in cardiac physiology, three splice variants of the PDE5A were cloned for the first time from mouse cDNA library (mPde5a1, mPde5a2, and mPde5a3). The predicted amino acidic sequences of the three murine isoforms are different in the N‐terminal regulatory domain. mPDE5A isoforms were transfected in HEK293T cells and they showed high affinity for cGMP and similar sensitivity to sildenafil inhibition. RT‐PCR analysis showed that mPde5a1, mPde5a2, and mPde5a3 had differential tissue distribution. In the adult heart, mPde5a1 and mPde5a2 were expressed at different levels whereas mPde5a3 was undetectable. Overexpression of mPDE5As induced an increase of HL‐1 number cells which progress into cell cycle. mPDE5A1 and mPDE5A3 overexpression increased the number of polyploid and binucleated cells, mPDE5A3 widened HL‐1 areas, and modulated hypertrophic markers more efficiently respect to the other mPDE5A isoforms. Moreover, mPDE5A isoforms had differential subcellular localization: mPDE5A1 was mainly localized in the cytoplasm, mPDE5A2 and mPDE5A3 were also nuclear localized. These results demonstrate for the first time the existence of three PDE5A isoforms in mouse and highlight their potential role in the induction of hypertrophy.

Characterization of three PDE5 isoforms in murine cardiomyocytes

Phosphodiesterase 5 (PDE5A) is responsible for hydrolysis of cGMP, a second messenger regulating many physiological functions in cardiac myocytes. PDE5A involvement in cardiac hypertrophy has been reported and the use of its inhibitor, sildenafil, has reverted the pathological increase of cardiac size in humans and in animal models (Nagendran et al., 2007). In humans, a single PDE5 gene encodes for three isoforms (PDE5A1, A2 and A3), which differ in their N-terminus being translated from alternative initiation sites (Lin et al., 2000). The isoforms exhibit specific tissue expression patterns and different sensitivities to pharmacological inhibitors. However, little is known about their specific biological roles. The existence of three murine PDE5A isoforms was predicted through human gene homology and confirmed by RT-PCR. Tissue expression pattern of each variant was uncovered by RT-PCR and western blot analysis. In adult heart, transcripts encoding for the three isoforms were detected. In cardiomyocytes primary cultures and cell lines PDE5A isoforms localization was revealed by fluorescence microscopy analysis and subcellular fractioning. Their phosphodiesterasic activities and sildenafil sensibilities were measured by radioactive assays. Finally, post-translational modifications were explored. Hypertrophic stimuli resulted in Ser 92 phosphorylation of PDE5A isoforms, possibly through by Protein Kinase A. In summary, the understanding of PDE5A isoforms localization and differential activation and activity might be an important step toward the improvement of the diagnostic, prognostic, and predictive values of PDE5A in hypertrophy treatment.

PDE5 inhibition counteracts β- adrenergic induction of cardiac hypertrophy

The b-adrenoreceptors play important roles in cardiovascular function regulation mediated by the sympathetic nervous system. It is known that sustained b-adrenergic stimulations promotes cardiac hypertrophy (Oleg et al., 2007). Recently an antihypertrophic role of sildenafil, that acts as a phosphodiesterase 5 (PDE5) inhibitor, has been demonstrated in mice where hypertrophy was mechanically induced (Takimoto et al., 2005). We report the results obtained on a cellular system of cardiac hypertrophy in vitro. By using three-dimensional cultures of mouse ventricular cardiomyocytes (Xiang et al., 2005) and isolated cardiomyocytes we show that: 1) these cells express levels of PDE5 comparable with the ones in normal heart, 2) treatment of the cultures with the b-adrenoreceptors agonist isoproterenol induces cell hypertrophy accompanied by an increment of the level of PDE5 expression and 3) sildenafil prevents the development of such hypertrophy through specific b-adrenoreceptors and signaling pathways 4) the inhibition of other members of PDE family might contribute to the prevention of hypertrophy following b-adrenergic stimulation. In summary, we present a test system that may contribute to clarify intracellular signaling pathways leading to cardiac hypertrophy and to identify molecular targets, like the ones involved in PDE5 activity, on which to steer the development of new drugs and to design new clinical therapies.

Characterization of c-Kit receptor function in cardiac regeneration by using transgenic mouse models

Background. Cardiac stem cells expressing the tyrosine kinase receptor c-kit have been recently used in in vivo and in vitro cardiac regenerative studies. However, it remains to be clarified whether the c-kit receptor itself plays a critical role in the process of cardiac regeneration. In order to clarify this point, we will explore whether c-Kit receptor affects cardiac stem cells proliferation, survival, migration and differentiation after heart injury. Methods and Results. We have generated transgenic mice in which an activatory point mutation (c-KitD814Y mice) has been introduced in the kinase domain of the c-kit gene. Initially, we have analyzed c-kit expression in tissues and organs at different stages of embryonal and post-natal development through immunohystochemical and biochemical analyses. We have found that in two transgenic lines the receptor is highly expressed and activated in heart, testis and cerebellum, compared to wild type mice. In order to follow the fate of the c-Kit transgenic stem cells we crossed c-KitD814Y mice with mice expressing GFP under c-Kit regulative sequences control. By cytofluorimetric and fluorescence microscopy analyses, we observed a 2 fold of increase in the number of c-kit positive cells on heart samples from double transgenic mice at different ages. To verify the c-kit role in cardiac regeneration we performed a necrotic heart damage in vivo and monitored cardiac repair in transgenic mice versus wild-type mice. After 9 days the wounded hearts of transgenic mice presented a larger connectival tissue area compared to wild-type mice. On the contrary, after 45 days a consistent reduction of fibrotic area was observed in transgenic mice. These preliminary results suggest a faster repair of damaged heart area that contain stem cells with an activated c-kit receptor. Further in vitro and in vivo experiments will be performed to assess whether transgenic c-kit cells directly transdifferentiate into cardiomyocytes or whether they act in a paracrine manner. In summary, the generation of transgenic mice carrying a constitutively activated c-kit in cardiac stem cells, will allow to investigate the role of the receptor and to highlight the molecular mechanism underlying heart regeneration.