Franco Mangia

Evaluation of the elevated plus-maze and open-field tests for the assessment of anxiety-related behaviour in inbred mice.

The elevated plus-maze test (PM) and open-field test (OF) are routinely used to study anxiety-related behaviour in mouse. However, the data obtained with these tests have often been contradictory, probably because of differences between laboratories in the selection and analysis of behavioural parameters. We have characterised the pattern of mouse anxiety by analysing a number of behavioural parameters with both PM and OF in BALB/c and C57BL/6 mice, two behaviourally distant mouse strains. Twenty-eight variables (15 analysed with PM and 13 with OF) were selected by correlation analysis from those initially recorded with both tests. The scores of the selected variables were first analysed by MANOVAs, and then by principal component analysis (PCA). PCA extracted five factors for PM and four factors for OF. These factors were subjected to a correlation analysis, which showed significant correlation between four of them. The factorial scores of BALB/c and C57BL/6 mice were analysed by MANOVAs, which showed significant effects of both the strain and test used. Our results confirm the multidimensional structure of mouse anxiety-related behaviour as regards both simple components and functional interactions, and comprehensively represent strain- and test-specific features of mouse anxiety-related behaviour.

TCL1 participates in early embryonic development and is overexpressed in human seminomas

Overexpression of the TCL1 oncogene has been shown to play a causative role in T cell leukemias of humans and mice. The characterization of Tcl1-deficient mice in these studies indicates an important developmental role for Tcl1 in early embryogenesis. In wild-type embryos, Tcl1 is abundant in the first three mitotic cycles, during which it shuttles between nuclei and the embryo cortical regions in a cell-cycle-dependent fashion. The absence of this protein in early embryogenesis results in reduced fertility of female mice. The present studies elucidate the mechanism responsible for the reduced female fertility through analysis of the oogenesis stages and early embryo development in Tcl1-deficient mice. Even though Tcl1−/− females display normal oogenesis and rates of oocyte maturation/ovulation and fertilization, the lack of maternally derived Tcl1 impairs the embryos ability to undergo normal cleavage and develop to the morula stage, especially under in vitro culture conditions. Beyond this crisis point, differentiative traits of zygotic genome activation and embryo compaction can take place normally. In contrast with this unanticipated role in early embryogenesis, we observed an overexpression of TCL1 in human seminomas. This finding suggests that TCL1 dysregulation could contribute to the development of this germinal cell cancer as well as lymphoid malignancies.

S-adenosylmethionine reduces the progress of the Alzheimer-like features induced by B-vitamin deficiency in mice

Methylation reactions linked to homocysteine in the one-carbon metabolism are increasingly elicited in Alzheimers disease, although the association of hyperhomocysteinemia and of low B vitamin levels with the disease is still debated. We previously demonstrated that hyperhomocysteinemia and DNA hypomethylation induced by B vitamin deficiency are associated with PSEN1 and BACE1 overexpression and amyloid production. The present study is aimed at assessing S-adenosylmethionine effects in mice kept under a condition of B vitamin deficiency. To this end, TgCRND8 mice and wild-type littermates were assigned to control or B vitamin deficient diet, with or without S-adenosylmethionine supplementation. We found that S-adenosylmethionine reduced amyloid production, increased spatial memory in TgCRND8 mice and inhibited the upregulation of B vitamin deficiency-induced PSEN1 and BACE1 expression and Tau phosphorylation in TgCRND8 and wild-type mice. Furthermore, S-adenosylmethionine treatment reduced plaque spreading independently on B vitamin deficiency. These results strengthen our previous observations on the possible role of one-carbon metabolism in Alzheimers disease, highlighting hyperhomocysteinemia-related mechanisms in dementia onset/progression and encourage further studies aimed at evaluating the use of S-adenosylmethionine as a potential candidate drug for the treatment of the disease.

Lack of heat-shock response in preovulatory mouse oocytes☆

The response to heat (hs response) of preovulatory mouse oocytes was compared with that of mouse granulosa cells and characterized in regard to in vitro resumption of meiosis, amino acid incorporation into total protein, and qualitative analysis of protein synthesized before and after the shock. Granulosa cells displayed a hs response typical of other mammalian systems. When incubated at 43 degrees C for 20-40 min, these cells maintained a normal level of amino acid incorporation into total protein, responded to stress by new synthesis of 33- and 68-kDa heat-shock proteins (hsps), and enhanced synthesis of 70-kDa heat-shock cognate protein (hsc70) and of 89- and 110-kDa hsps. In contrast to granulosa cells, preovulatory mouse oocytes were very sensitive to hyperthermia. Incubation at 43 degrees C for 20-40 min strongly inhibited oocyte resumption of meiosis and protein synthesis and did not induce a new or enhanced synthesis of hsps. Unstressed preovulatory mouse oocytes constitutively synthesized 70- and 89-kDa polypeptides resembling hsc70 and hsp89 of granulosa cells.

Developmental regulation of heat-shock response in mouse oogenesis: identification of differentially responsive oocyte classes during Graafian follicle development.

The response to heat (hs response) of dictyate mouse oocytes at various differentiation stages was analyzed in vitro, by determining patterns of oocyte heat-shock (hs) gene expression and heat-shock protein (HSP) synthesis, under both normal conditions and after an hs. Growing oocytes constitutively synthesized HSP89 and HSC70, and, in contrast to preovulatory oocytes which do not display an hs response, displayed a heat-elicited, transcription-dependent synthesis of two HSP68 isoforms, but not of other inducible HSPs. To determine the developmental schedule of hs response disappearance during oogenesis, fully grown oocytes from Graafian follicles were morphologically sorted into three discrete classes related to the follicle development, namely, loosely associated with granulosa cells (LA oocytes, from small Graafian follicles), intermediately associated with granulosa cells (IA oocytes, from medium-sized Graafian follicles), and cumulus-associated (CA oocytes, from mature follicles). LA oocytes displayed an hs response qualitatively similar to, but smaller in extent than, that of growing oocytes, and were able to resume and complete spontaneous meiotic maturation in vitro at a high rate after hs. We conclude that hs response of mouse dictyate oocytes is maximal during growth period, significantly declines with acquisition of full oocyte size and antrum formation within the follicle, and is finally shut off with oocyte/follicle terminal differentiation.

Early Transcriptional Activation of the Hsp70.1 Gene by Osmotic Stress in One-Cell Embryos of the Mouse

Abstract In fertilized mouse eggs, de novo transcription of embryonic genes is first observed during the S phase of the one-cell stage. This transcription, however, is mostly limited to the male pronucleus and possibly uncoupled from translation, making the functional meaning obscure. We found that one-cell mouse embryos respond to the osmotic shock of in vitro isolation with migration of HSF1, the canonical stress activator of mammalian heat shock genes, to pronuclei and by transient transcription of the hsp70.1, but not hsp70.3 and hsp90, heat shock genes. Isolated growing dictyate oocytes also display a nuclear HSF1 localization, but, in contrast with embryos, they transcribe both hsp70.1 and hsp70.3 genes only after heat shock. Intranuclear injection of double-stranded oligodeoxyribonucleotides containing HSE, GAGA box or GC box consensus sequences, and antibodies raised to transcription factors HSF1, HSF2, Drosophila melanogaster GAGA factor, or Sp1 demonstrated that hsp70.1 transcription depends on HSF1 in both oocytes and embryos and that Sp1 is dispensable in oocytes and inhibitory in the embryos. Hsp70.1 thus represents the first endogenous gene so far identified to be physiologically activated and tightly regulated after fertilization in mammals.

The nuclear form of Glutathione Peroxidase 4 is associated with sperm nuclear matrix and is required for proper paternal chromatin decondensation at fertilization

The nuclear isoform of the selenoprotein Phospholipid Hydroperoxide Glutathione Peroxidase (nGPx4) is expressed in haploid male germ cells, contains several cysteines and is able to oxidize protein thiols, besides glutathione. In this study we have investigated the subnuclear localization of this isoform in isolated mouse male germ cells at different steps of maturation. Immunoblotting and confocal microscopy analyses of subnuclear fractions showed that nGPx4 is localized to the nuclear matrix together with well known markers of this subnuclear compartment like lamin B and topoisomerase IIβ at all stages of germ cell differentiation. The peculiar nGPx4 distribution was confirmed by both biochemical and morphological analyses of COS‐1 cells overexpressing Flag‐tagged nGPx4. To test the functional role of nGPx4 in the process of chromatin assembly, sperm isolated from the caput and the cauda epididymides of wild‐type (WT) and genetically deficient in nGPx4 (nGPx4‐KO) mice were analyzed in an in vitro chromatin decondensation assay. Results showed that sperm from nGPx4‐KO mice were more prone to decondense than those from WT mice at all stages of epididymal maturation, providing conclusive evidence that nGPx4 is required for a correct sperm chromatin compaction. We next addressed the issue of whether the lack of nGPx4 impacts on early events occurring at fertilization. Indeed, in vitro fertilization experiments showed an acceleration of sperm chromatin dispersion in oocytes fertilized by nGpx4‐KO sperm compared with control. Overall these data indicate that the absence of nGPx4 leads to sperm nuclear matrix/chromatin instability that may negatively affect the embryo development. J. Cell. Physiol. 227: 1420–1427, 2012.

A marked paucity of granule cells in the developing cerebellum of the Npc1(-/-) mouse is corrected by a single injection of hydroxypropyl-β-cyclodextrin.

In this study we show that postnatal development of cerebellar granule neurons (GNs) is defective in Npc1−/− mice. Compared to age-matched wild-type littermates, there is an accelerated disappearance of the external granule layer (EGL) in these mice. This is due to a premature exit from the cell cycle of GN precursors residing at the level of the EGL. As a consequence, the size of cerebellar lobules of these mice displays a 20%–25% reduction compared to that of age-matched wild-type mice. This size reduction is detectable at post-natal day 28 (PN28), when cerebellar GN development is completed while signs of neuronal atrophy are not yet apparent. Based on the analysis of EGL thickness and the determination of proliferating GN fractions at increasing developmental times (PN8–PN14), we trace the onset of this GN developmental defect during the second postnatal week. We also show that during this developmental time Shh transcripts undergo a significant reduction in Npc1−/− mice compared to age-matched wild-type mice. In light of the mitogenic activity of Shh on GNs, this observation further supports the presence of defective GN proliferation in Npc1−/− mice. A single injection of hydroxypropyl-β-cyclodextrin at PN7 rescues this defect, restoring the normal patterns of granule neuron proliferation and cerebellar lobule size. To our knowledge, these findings identify a novel developmental defect that was underappreciated in previous studies. This defect was probably overlooked because Npc1 loss-of-function does not affect cerebellar foliation and causes the internal granule layer and molecular layer to decrease proportionally, giving rise to a normally appearing, yet harmoniously smaller, cerebellum.

Anxiety-related behaviour in C57BL/6↔BALB/c chimeric mice

In a previous study on anxiety-related behaviours of the genetically and behaviourally distant inbred mouse strains C57BL/6 and BALB/c using the Elevated plus-maze (EPM) and Open-field (OF) apparatuses, we identified a number of variables, the factorial scores of which were grouped by principal component analysis (PCA) into factors specifically describing each inbred strain. We have now studied the effect of C57BL/6 and BALB/c haploid sets of genes on this behaviour by comparing EPM and OF variables of C57BL/6 and BALB/c versus C57BL/6 x BALB/c F1 hybrids (B6CBF1) and chimeric C57BL/6 x BALB/c (CHIM) mice. CHIM mice were made by embryo aggregation and the chimerism degree of their brain was inferred from coat black/white distribution. Discriminant analysis of EPM and OF factorial scores of C57BL/6, BALB/c and CHIM mice showed that CHIM mice with an exceeding (> or =80%) C57BL/6 or BALB/c coat component had behaviours similar to those of the predominant strain, whereas CHIM mice with intermediate chimerism differed from both inbred strains. Additional MANOVA analysis showed that the anxiety behaviour of CHIM mice with intermediate chimerism was similar to that of B6CBF1 mice as for factors not describing the inbred strains, including a motor activity mostly limited to protected areas, with attempts to approach the anxiogenic areas while processing/storing the external information. We conclude that the balanced presence of both C57BL/6 and BALB/c genetic backgrounds, either when carried by the same cell or by different cells, gives rise to a novel stress coping strategy described by factors different from those of the inbred strains.

Subcellular TSC22D4 Localization in Cerebellum Granule Neurons of the Mouse Depends on Development and Differentiation

We previously demonstrated that TSC22D4, a protein encoded by the TGF-β1-activated gene Tsc22d4 (Thg-1pit) and highly expressed in postnatal and adult mouse cerebellum with multiple post-translationally modified protein forms, moves to nucleus when in vitro differentiated cerebellum granule neurons (CGNs) are committed to apoptosis by hyperpolarizing KCl concentrations in the culture medium. We have now studied TSC22D4 cytoplasmic/nuclear localization in CGNs and Purkinje cells: (1) during CGN differentiation/maturation in vivo, (2) during CGN differentiation in vitro, and (3) by in vitro culturing ex vivo cerebellum slices under conditions favoring/inhibiting CGN/Purkinje cell differentiation. We show that TSC22D4 displays both nuclear and cytoplasmic localizations in undifferentiated, early postnatal cerebellum CGNs, irrespectively of CGN proliferation/migration from external to internal granule cell layer, and that it specifically accumulates in the somatodendritic and synaptic compartments when CGNs mature, as indicated by TSC22D4 abundance at the level of adult cerebellum glomeruli and apparent lack in CGN nuclei. These features were also observed in cerebellum slices cultured in vitro under conditions favoring/inhibiting CGN/Purkinje cell differentiation. In vitro TSC22D4 silencing with siRNAs blocked CGN differentiation and inhibited neurite elongation in N1E-115 neuroblastoma cells, pinpointing the relevance of this protein to CGN differentiation.