室温下保存的小鼠屠体卵巢GV卵的发育能力

将ICR系雌性小鼠处死并在10℃、15℃、20℃和25℃下依次保存8、14、24和48 h后,采集其体内的卵巢GV期卵,采用常规方法进行体外成熟和体外受精,获得的2细胞期胚经体外培养或胚胎移植观察其发育能力.其结果,在10℃下保存24 h、15℃下保存14 h、20℃下保存8h和25℃下保存4 h后,其体内附有卵丘细胞的GV卵的体外成熟-体外受精后的2细胞率分别为14%、9%、10%和10%,随着保存温度的提高和保存时间的延长,带有颗粒细胞GV期卵的比率明显降低,同时其GV期卵经体外成熟及体外受精后的2细胞率明显降低.在20℃下保存24 h和25℃下保存14 h时,难以获得形态正常的GV期卵;体外受精获得的2细胞期胚经体外培养,总体上有64%的胚胎发育至扩张囊胚,未见有保存温度和保存时间的显著影响,且利用在15℃保存8 h后的GV卵获得2细胞期胚的移植获得正常新生小鼠.上述结果表明,雌性动物室温条件下死亡后,若能短时间及时采集其体内GV期卵并体外成熟、体外受精,体外培养及胚胎移植技术,就有可能获得新生后代.     

Genetic mouse models to investigate cell cycle regulation

Early studies on cell cycle regulation were based on experiments in model systems (Yeast, Xenopus, Starfish, Drosophila) and have shaped the way we understand many events that control the cell cycle. Although these model systems are of great value, the last decade was highlighted by studies done in human cells and using in vivo mouse models. Mouse models are irreplaceable tools for understanding the genetics, development, and survival strategies of mammals. New developments in generating targeting vectors and mutant mice have improved our approaches to study cell cycle regulation and cancer. Here we summarize the most recent advances of mouse model approaches in dissecting the mechanisms of cell cycle regulation and the relevance to human disease. W. Li and S. Kotoshiba contributed equally.     

Abnormalities in aggression and anxiety in transgenic mice overexpressing activin E

To study the function of activin E, a TGF-β superfamily member, in the regulation of affective behavior, we investigated the behavior of transgenic mice overexpressing activin E (TgActβE mice). Male TgActβE mice showed aggressive behavior in resident-intruder tests. In elevated plus-maze tests, the percentage of open arm entries was significantly increased in female TgActβE mice compared with that in wild-type mice. Furthermore, female TgActβE mice stayed in the central area for a significantly longer time than wild-type mice in open field tests. These results indicated that TgActβE mice had less anxiety-like behavior. The number of restraint-stress-evoked c-Fos-positive cells in the hypothalamic paraventricular nucleus in TgActβE mice was significantly decreased compared with that in wild-type mice. This suggests that synthesis of corticotrophin-releasing hormone induced by stress was decreased in TgActβE mice. Taking these results together, activin E may act as a regulator of the hypothalamic-pituitary-adrenal axis.     

Nectin-3 expression is elevated in limbal epithelial side population cells with strongly expressed stem cell markers

Corneal epithelial stem cells (CESCs) are essential for maintaining the ocular surface. However, the lack of surface markers for CESCs remains a serious obstacle in the identification of CESCs. Previously, we showed that rabbit limbal epithelial side population (rLE-SP) cells exhibited stem cell phenotypes including increased expression of CD61, a marker for mouse hematopoietic stem cells. Here, we demonstrate that nectin-3, an immunoglobulin-like cell-cell adhesion molecule, is highly expressed in rLE-SP cells. Additionally, nectin-3⁺ cells were significantly enriched among CD61⁺rLE-SP cells as compared to CD61⁻rLE-SP cells. In mouse bone marrow side population cells, a correlation between expression of nectin-3 and CD61 was also observed. These data strongly suggest that nectin-3 may contribute to the identification of CESCs.     

Concordant up-regulation of cytochrome P450 Cyp3a11, testosterone oxidation and androgen receptor expression in mouse brain after xenobiotic treatment

Inactivation of testosterone by specific hydroxylations is a main function of cytochrome P450 (P450, CYP) in the brain. Recent data imply that induction of brain P450s by neuroactive drugs alters steroid hormone levels and endocrine signalling, giving rise to endocrine disorders. In this study, we investigated this drug–hormone crosstalk in mouse brain. Phenytoin led to a significant increase of 2α-, 2β-, 6β-, 16α- and 16β-hydroxytestosterones, while 6α- and 15α-hydroxytestosterones showed no significant alteration of their metabolism compared with untreated controls. Inhibition of testosterone hydroxylation using the chemical inhibitors orphenadrine, chloramphenicol, ketoconazole and nifedipine as well as antibodies against CYP3A- and 2B-isoforms pointed to major role of Cyp3a11 and an only minor function of Cyp2b9/10 in mouse brain. Cyp3a11 revealed to be the major isoform affected by phenytoin. There was considerable overlap of Cyp3a11 and AR expression in neuronal structures of the limbic system, namely the hippocampus, amygdala, hypothalamus and thalamus. Phenytoin treatment led to an increase of both, Cyp3a11 and AR expression in the limbic system. Additionally, the coherence between CYP3A and AR expression was analysed in PC-12 cells. Inhibition of phenytoin-induced endogenous CYP3A2 and AR by ketoconazole led a reduction of their expression to basal levels. We conclude that Cyp3a11 plays a crucial role in directing drug action to hormonal response within the limbic system of mouse brain in a so-called drug–hormone crosstalk.     

Differential regulation of Akt/protein kinase B isoforms during cell cycle progression

Phosphatidylinositol 3-kinase pathways play key regulatory roles in cell cycle progression into S phase. In this study, we demonstrated that Akt1/PKBα isoform plays an essential role in G₁/S transition and proliferation. Cells lacking Akt1/PKBα showed an attenuated proliferation as well as G₁/S transition, whereas cells lacking Akt2/PKBβ showed normal proliferation and G₁/S transition. The effect of Akt1/PKBα on cell proliferation and G₁/S transition was completely abolished by swapping pleckstrin homology (PH) domain with that of Akt2/PKBβ. Finally, full activation of Akt/PKB and cyclin D expression was achieved by the Akt1/PKBα or chimeric proteins containing the PH domain of Akt1/PKBα indicating that the PH domain of Akt1/PKBα provides full kinase activity and is necessary for the G₁/S transition.     

Germline expression of H-Ras(G12V) causes neurological deficits associated to Costello syndrome

Costello syndrome (CS) is a rare congenital disorder caused by germline activation of H- Ras oncogenes. A mouse model of CS generated by introduction of an oncogenic Gly12Val mutation in the mouse H- Ras locus using homologous recombination in embryonic stem (ES) cells has been recently described. These mice phenocopied some of the abnormalities observed in patients with CS, including facial dysmorphia and cardiomyopathies. We investigated here their neurological and behavioral phenotype. The analysis of H- Ras ^G12V mice revealed phenotypes that resembled the hyperemotivity, hypersensibility and cognitive impairments observed in children with CS. Stronger neurological deficits were found in the analysis of mice homozygous for this mutation than in the analysis of heterozygous mice, suggesting the existence of a gene dose effect. These mice represent the first mouse model for CS, offering an experimental tool to study the molecular and physiological alterations underlying the neurological manifestations of CS and to test new therapies aimed at preventing or ameliorating the cognitive and emotional impairments associated to this condition.     

Efficient temporally-controlled targeted mutagenesis in smooth muscle cells of the adult mouse

To generate temporally-controlled targeted somatic mutations selectively and efficiently in smooth muscles, we have established a transgenic SMA-Cre-ER(T2) mouse line in which the expression of the Tamoxifen-dependent Cre-ER(T2) recombinase is under the control of a large genomic DNA segment of the mouse smooth muscle alpha actin (SMA) gene, contained in a Bacterial artificial chromosome (Bac). In this transgenic mouse line, Cre-ER(T2)-mediated recombination of LoxP-flanked target DNA is strictly Tamoxifen-dependent, and efficient in both vascular and visceral smooth muscle cells. Moreover, with the exception of few cardiomyocytes, LoxP-flanked DNA excision is restricted to smooth muscle cells. Thus, SMA-Cre-ER(T2) mice should be of great value to analyze gene function in smooth muscles, and to establish new animal models of human smooth muscle disorders.     

Spontaneous activity in the developing mouse midbrain driven by an external pacemaker

Central nervous system (CNS) development depends upon spontaneous activity (SA) to establish networks. We have discovered that the mouse midbrain has SA expressed most robustly at embryonic day (E) 12.5. SA propagation in the midbrain originates in midline serotonergic cell bodies contained within the adjacent hindbrain and then passes through the isthmus along ventral midline serotonergic axons. Once within the midbrain, the wave bifurcates laterally along the isthmic border and then propagates rostrally. Along this trajectory, it is carried by a combination of GABAergic and cholinergic neurons. Removing the hindbrain eliminates SA in the midbrain. Thus, SA in the embryonic midbrain arises from a single identified pacemaker in a separate brain structure, which drives SA waves across both regions of the developing CNS. The midbrain can self‐initiate activity upon removal of the hindbrain, but only with pharmacological manipulations that increase excitability. Under these conditions, new initiation foci within the midbrain become active. Anatomical analysis of the development of the serotonergic axons that carry SA from the hindbrain to the midbrain indicates that their increasing elongation during development may control the onset of SA in the midbrain. © 2009 Wiley Periodicals, Inc. Develop Neurobiol 2009