GLAST基因敲除对小鼠表型及听力功能的影响

目的:观察谷氨酸天冬氨酸转运蛋白(GLAST)缺失对小鼠正常听觉功能的影响。方法:我们选用C57BL/6J背景的GLAST^+/-小鼠进行杂交,用琼脂糖凝胶电泳进行后代小鼠基因型鉴定。我们选用9～10周龄雄性小鼠,用免疫荧光染色技术检测耳蜗中GLAST蛋白表达,对敲除结果进行验证(n=3)。比较雌雄小鼠出生后7d至30 d体重变化及30 d的体长(n=8)。听性脑干反应(ABR)测试9-10周龄雌性和雄性小鼠听觉阈值及其Ⅰ波振幅的变化(n=5)。结果:雄性GLAST^-/-小鼠与雄性GLAST^+/+和GLAST^+/-小鼠相比,体重及体长均显著降低(P<0.01),其中雄性GLAST^-/-小鼠与GLAST^+/+相比,在P7至P30统计时间里,均表现出明显差异;与雄性GLAST^+/-小鼠相比,P15后均表现出体重显著性降低。而雌性GLAST^-/-小鼠与雌性GLAST^+/+和GLAST^...     

Fmr1基因敲除对小鼠生理发育和繁殖性能的影响

目的对清洁级FVB.KO和FVB的生理发育指标和繁殖性能进行分析比较,探讨Fmr1基因敲除对小鼠生理发育和繁殖性能的影响。方法挑选10周龄清洁级FVB.KO和FVB各20只（雌雄各半）,采取1∶1同居,全部同胞兄妹近交繁殖,测定新生仔鼠生理发育指标和品系繁殖性能。结果 FVB.KO在耳廓分离、体毛长出、门齿萌发、眼睑开裂等生理发育指标上和FVB比较接近,在平均每窝产仔数和离乳率等方面偏低,在雌雄比例上有显著差异。结论 Fmr1基因敲除对小鼠生理发育和繁殖性能影响较小,对后代雌雄比例可能有一定的影响。     

Lats1基因敲除小鼠保种的研究

目的　以Lats1基因敲除小鼠为例 ,研究国家遗传工程小鼠资源库遗传小鼠的保种技术路线及方法。方法　采用了胚胎移植 ,目的基因检测 ,胚胎冷冻等技术。结果　在库内得到 2 4只Lats+ -小鼠 ,扩群后 ,冷冻保存 110枚胚胎。结论　上述方法能确保Lats1基因敲除小鼠资源库保种成功。     

Bmal1时钟基因敲除小鼠的繁育及基因型鉴定

目的 对Bmal1基因敲除小鼠进行繁育及基因型进行鉴定,为生物节律研究提供理想的动物模型.方法 将引进的Bmal1基因敲除小鼠,以1雄2雌的合笼方式进行饲养繁殖,从仔鼠中提取鼠尾基因组DNA,PCR扩增目的基因片段,琼脂凝胶电泳进行基因结果 判定,Western Blot检测心肌组织中Bmal1蛋白表达进行结果 验证....     

复合不育剂EP-1对小鼠空间记忆与焦虑行为的影响

EP-1是由炔雌醚和左炔诺孕酮按照1∶2的比例配制而成的一种用于鼠类不育控制的激素类复合不育剂,对鼠类的繁殖及繁殖行为等有一定影响,但对鼠类空间学习与记忆、焦虑行为等非繁殖行为的影响还没有报道。为此,用0(对照)、1.0、2.0、3.0 mg/kg剂量的EP-1对昆明小鼠(Mus musculus)进行灌胃处理,然后用Morris水迷宫和高架十字迷宫分别测定其空间记忆、焦虑行为。结果发现灌胃后15 d,剂量为2.0 mg/kg的EP-1使小鼠空间记忆能力显著下降,但30 d后其空间记忆能力有所恢复,表明2.0 mg/kg剂量的EP-1可以在一定时间范围内降低小鼠的空间记忆能力。但不同剂量的EP-1对小鼠焦虑行为无显著影响。该结果可以为从对非繁殖行为的影响的角度研究EP-1对鼠类的作用提供一定启示。     

黏蛋白1基因敲除小鼠模型的构建

黏蛋白1(MUC1)属黏蛋白家族成员,分布于上皮细胞膜表面,由于在免疫炎症反应以及肿瘤发生中的重要作用而日益受到重视.为了进一步深入研究MUC1的生物学功能,构建了Muc1基因敲除小鼠模型.首先,根据小鼠Muc1基因组序列设计基因剔除策略,将2个loxP位点分别插在外显子2和3两侧,构建基因剔除载体Muc1-ABRLFn-pBR322.以电穿孔方法将载体导入胚胎干细胞(ES细胞),用G418和更昔洛韦进行正负筛选获得4个同源重组的ES细胞克隆.挑选其中一个阳性ES克隆行囊胚显微注射,获得16只嵌合率大于50%的雄鼠;其次,利用嵌合雄鼠与C57BL/6J野生型雌鼠交配后获得11只floxP杂合子小鼠(10雄1雌),通过杂合子小鼠回交,并进一步与EⅡa-Cre小鼠交配,最终成功得到Muc1全身敲除小鼠,其中纯合子小鼠未出现胚胎致死现象.初步表型观察未发现Muc1基因敲除相关器官组织结构的异常改变.本研究为MUC1的生物学功能的挖掘,尤其是MUC1在肿瘤发生转移中的作用机制的揭示提供了实验平台.     

Fmr1基因敲除小鼠脏器重量和脏器系数的比较分析

目的通过对Fmr1基因敲除小鼠雌雄两性和FVB小鼠的脏器重量和脏器系数进行比较分析,了解其脏器重量的差异,探讨Fmr1基因对动物生长发育等方面的影响。方法分别测定Fmr1基因敲除小鼠雌雄两性和FVB小鼠内脏器官的绝对重量和脏器系数,并进行统计学处理和分析。结果相同年龄的Fmr1基因敲除小鼠雄性的体重、心、肺、肝和肾的绝对重量均极显著的大于雌性（P〈0.01）。雌雄间脏器系数除肾脏（P〈0.05）和脑（P〈0.01）外,其余无显著差异。与FVB小鼠比较,Fmr1基因敲除小鼠心脏较轻（P〈0.01）,肾脏（P〈0.01）、体重和脑较重（P〈0.05）。脏器系数肾脏较大（P〈0.01）,心脏（P〈0.01）、脑和脾（P〈0.05）较小。结论Fmr1基因可影响动物的某些脏器重量和脏器系数。     

应用CRISPR/Cas9技术构建YOD1基因敲除小鼠

目的:应用CRISPR/Cas9技术构建去泛素化酶YOD1基因敲除小鼠。方法:针对YOD1基因设计单链向导RNA(sg RNA)识别序列,构建sg RNA质粒,与Cas9质粒体外转录、纯化后注射入受精卵,通过PCR和测序验证得到F0代阳性小鼠。配繁两代后,取同窝对照的野生型(WT)和敲除(KO)小鼠的主要组织器官研磨,使用免疫印迹(WB)技术检测各组织YOD1蛋白的表达,确证YOD1敲除小鼠模型是否成功建立。统计YOD1杂合子(HET)自交存活后代各基因型比例,分析是否有胚胎致死表型。解剖小鼠分析主要组织器官的表型,进一步利用H.E.染色分析KO小鼠是否存在自发的病理改变。通过血糖耐受实验(GTT)分析KO小鼠的血糖调控能力。结果:基因组测序和WB检测结果显示KO小鼠中YOD1被明显敲除,YOD1敲除小鼠模型成功建立。YOD1杂合子自交后代各基因型比例符合孟德尔定律,提示KO小鼠非胚胎致死。YOD1敲除小鼠肝脏显著小于WT小鼠。GTT结果表明敲除YOD1不影响小鼠的血糖稳态。结论:应用CRISPR/Cas9技术成功构建YOD1基因敲除小鼠。KO小鼠正常出生,无任何胚胎发育缺陷。与WT小鼠相比,KO小鼠肝脏显著减小,但无显著的自发病理变化,KO小鼠血糖控制亦无显著差异。     

转基因小鼠和基因敲除小鼠

能够把基因功能作为生物体表现来观察的改变了基因的小鼠。即使在基因组信息泛滥的今天,这也是最重要的工具之一,基本原理的研究虽然很早,但目前仍在进行改良法的开发工作。本文由基因控制株式会社的三谷匡董事予以阐述。[编者按]     

Cramp基因敲除对小鼠骨髓造血干细胞的影响

目的研究Cramp基因敲除在衰老过程中对小鼠造血干细胞的作用。方法应用流式细胞仪分析3月龄及12月龄Cramp基因敲除小鼠及同窝野生型小鼠的骨髓造血干细胞的比例及不同发育阶段B淋巴细胞的比例。结果与野生型小鼠相比,12月龄Cramp基因敲除小鼠的骨髓长期造血干细胞增多,多潜能造血祖细胞减少;前体B淋巴细胞和未成熟B淋巴细胞减少,成熟B淋巴细胞增多。结论在衰老过程中,Cramp基因敲除对骨髓造血干细胞及B淋巴细胞发育有重要影响。     

Rat and Drosophila Synaptotagmin 4 Have Opposite Effects during SNARE-catalyzed Membrane Fusion

Synaptotagmins (Syt) are a large family of proteins that regulate membrane traffic in neurons and other cell types. One isoform that has received considerable attention is SYT4, with apparently contradictory reports concerning the function of this isoform in fruit flies and mice. SYT4 was reported to function as a negative regulator of neurotrophin secretion in mouse neurons and as a positive regulator of secretion of a yet to be identified growth factor from muscle cells in flies. Here, we have directly compared the biochemical and functional properties of rat and fly SYT4. We report that rat SYT4 inhibited SNARE-catalyzed membrane fusion in both the absence and presence of Ca²⁺. In marked contrast, fly SYT4 stimulated SNARE-mediated membrane fusion in response to Ca²⁺. Analysis of chimeric molecules, isolated C2 domains, and point mutants revealed that the C2B domain of the fly protein senses Ca²⁺ and is sufficient to stimulate fusion. Rat SYT4 was able to stimulate fusion in response to Ca²⁺ when the conserved Asp-to-Ser Ca²⁺ ligand substitution in its C2A domain was reversed. In summary, rat SYT4 serves as an inhibitory isoform, whereas fly SYT4 is a bona fide Ca²⁺ sensor capable of coupling Ca²⁺ to membrane fusion.     

Maternal behavior deficits in nulliparous oxytocin knockout mice

The first observations of postpartum oxytocin knockout (OTKO) mice found no maternal behavior deficits. However, it is unclear how detailed those observations were. In this study, we compared maternal behavior exhibited by OTKO and wild-type (WT) nullipara toward six 2-4-day-old foster pups during test sessions conducted on 3 successive days. Each day, subjects were placed in a clean cage 30 min prior to introduction of pups which were deposited in a clump adjacent to the middle of a long wall of each test cage. Behavior was measured for 3.5 h after which pups and test subjects were returned to their home cages. On test days 1 and 3, a significantly smaller proportion of OTKO females retrieved pups to a corner of their cage. Also, significantly fewer pups were retrieved to corners by OTKO females. In contrast to most WTs, most OTKO females mothered pups in the center of the cage where they were initially deposited. Pup-licking frequencies were significantly lower in OTKO females. Their self-grooming frequencies also trended toward being lower. Latencies to retrieve and lick pups, latencies to and frequencies of still crouching over pups and proportion of time in nest did not differ between groups. Our findings suggest that OT stimulates a significant proportion of pup-licking in nulliparous mice, a situation similar to lactating rat mothers. Our results also indicate that OT may play a role in the motivation to retrieve pups to a more secure location.     

Immunocytochemical Analysis of Axonal Outgrowth in Synaptotagmin Mutations

Abstract: Synaptotagmin is a synaptic vesicle specific protein that binds calcium and phospholipids in vitro and is required for calcium-regulated fusion of synaptic vesicles with the presynaptic membrane. We have examined the possible requirement for synaptotagmin in axonal outgrowth by following neuronal development in Drosophila embryos deficient for the synaptotagmin gene. We find that synaptotagmin is expressed abundantly in axons and growth cones before synapse formation in wild-type embryos. Using antibodies to the intravesicular domain of synaptotagmin to label live embryos, we demonstrate that vesicle populations containing synaptotagmin actively undergo exocytosis during axonogenesis. We have used immunocytochemical techniques to examine the distribution of the axonal protein Fasciclin II, the presynaptic membrane protein syntaxin, and the synaptic vesicle protein cysteine string protein, in synaptotagmin null mutations. The distribution of these proteins is similar in wild-type and synaptotagmin mutant embryos, suggesting that synaptotagmin is not required for axonogenesis in the CNS or PNS. Based on these findings, we suggest that the molecular mechanisms underlying vesicular-mediated membrane expansion during axonal outgrowth are distinct from those required for synaptic vesicle fusion during neurotransmitter release.     

SNAREpin Assembly by Munc18-1 Requires Previous Vesicle Docking by Synaptotagmin 1

Regulated exocytosis requires the general membrane fusion machinery-soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) and Sec1/Munc18 (SM) proteins. Using reconstituted giant unilamellar vesicles containing preassembled t-SNARE proteins (syntaxin 1·SNAP-25), we determined how Munc18-1 controls the docking, priming, and fusion of small unilamellar vesicles containing the v-SNARE VAMP2 and the Ca(2+) sensor synaptotagmin 1. In vitro assays allowed us to position Munc18-1 in the center of a sequential reaction cascade; vesicle docking by synaptotagmin 1 is a prerequisite for Munc18-1 to accelerate trans-SNARE complex (SNAREpin) assembly and membrane fusion. Complexin II stalls SNAREpin zippering at a late stage and, hence, contributes to synchronize membrane fusion in a Ca(2+)- and synaptotagmin 1-dependent manner. Thus, at the neuronal synapse, the priming factor Munc18-1 may accelerate the conversion of docked synaptic vesicles into a readily releasable pool by activating SNAREs for efficient membrane fusion.     

Chondrodysplasia of gene knockout mice for aggrecan and link protein

The proteoglycan aggregate of the cartilage is composed of aggrecan, link protein, and hyaluronan and forms a unique gel-like moiety that provides resistance to compression in joints and a foundational cartilage structure critical for growth plate formation. Aggrecan, a large chondroitin sulfate proteoglycan, is one of the major structural macromolecules in cartilage and binds both hyaluronan and link protein through its N-terminal domain G1. Link protein, a small glycoprotein, is homologous to the G1 domain of aggrecan. Mouse cartilage matrix deficiency (cmd) is caused by a functional null mutation of the aggrecan gene and is characterized by perinatal lethal dwarfism and craniofacial abnormalities. Link protein knockout mice show chondrodysplasia similar to but milder than cmd mice, suggesting a supporting role of link protein for the aggregate structure. Analysis of these mice revealed that the proteoglycan aggregate plays an important role in cartilage development and maintenance of cartilage tissue and may provide a clue to the identification of human genetic disorders caused by mutations in these genes. Published in 2003.     

Calcium-Dependent Self-Association of Synaptotagmin I

Abstract: Synaptotagmin I, an integral membrane protein of secretory vesicles, appears to have an essential role in calcium-triggered hormone and neurotransmitter release. The large cytoplasmic domain of synaptotagmin I has two C2 domains that are thought to mediate calcium and phospholipid binding. A recombinant protein (p65 1–5) comprised of the cytoplasmic domain was previously shown to aggregate purified chromaffin granules and artificial phospholipid vesicles in a calcium-dependent manner. p65 1–5 may be able to aggregate membrane vesicles by a self-association reaction. This hypothesis led us to investigate the ability of synaptotagmin I protein fragments to multimerize in vitro. We found that p65 1–5, in the absence of membranes, was able to self-associate to form large aggregates in a calcium-dependent manner as shown by light-scattering assays and electron microscopy. In addition, a recombinant protein comprised of only the second half of the cytoplasmic domain, including the second C2 domain, was also able to self-associate and aggregate phospholipid vesicles in a calcium-dependent manner. A recombinant protein comprised of only the first C2 domain was not able to self-associate or aggregate vesicles. These results suggest that synaptotagmin I is able to bind calcium in the absence of membranes and that the second half of the cytoplasmic domain is able to bind calcium and mediate its multimerization in a calcium-dependent manner. The ability of synaptotagmin I protein fragments to multimerize in a calcium-dependent manner in vitro suggests that multimerization may have an important function in vivo.     

The Juxtamembrane Linker of Full-length Synaptotagmin 1 Controls Oligomerization and Calcium-dependent Membrane Binding

Synaptotagmin 1 (Syt1) is the calcium sensor for synchronous neurotransmitter release. The two C2 domains of Syt1, which may mediate fusion by bridging the vesicle and plasma membranes, are connected to the vesicle membrane by a 60-residue linker. Here, we use site-directed spin labeling and a novel total internal reflection fluorescence vesicle binding assay to characterize the juxtamembrane linker and to test the ability of reconstituted full-length Syt1 to interact with opposing membrane surfaces. EPR spectroscopy demonstrates that the majority of the linker interacts with the membrane interface, thereby limiting the extension of the C2A and C2B domains into the cytoplasm. Pulse dipolar EPR spectroscopy provides evidence that purified full-length Syt1 is oligomerized in the membrane, and mutagenesis indicates that a glycine zipper/GXXXG motif within the linker helps mediate oligomerization. The total internal reflection fluorescence-based vesicle binding assay demonstrates that full-length Syt1 that is reconstituted into supported lipid bilayers will capture vesicles containing negatively charged lipid in a Ca²⁺-dependent manner. Moreover, the rate of vesicle capture increases with Syt1 density, and mutations in the GXXXG motif that inhibit oligomerization of Syt1 reduce the rate of vesicle capture. This work demonstrates that modifications within the 60-residue linker modulate both the oligomerization of Syt1 and its ability to interact with opposing bilayers. In addition to controlling its activity, the oligomerization of Syt1 may play a role in organizing proteins within the active zone of membrane fusion.     

Regulation of Synaptotagmin I Phosphorylation by Multiple Protein Kinases

Synaptotagmin I has been suggested to function as a low-affinity calcium sensor for calcium-triggered exocytosis from neurons and neuroendocrine cells. We have studied the phosphorylation of synaptotagmin I by a variety of protein kinases in vitro and in intact preparations. SyntagI, the purified, recombinant, cytoplasmic domain of rat synaptotagmin I, was an effective substrate in vitro for Ca2+/calmodulin-dependent protein kinase II (CaMKII), protein kinase C (PKC), and casein kinase II (caskII). Sequencing of tryptic phosphopeptides from syntagI revealed that CaMKII and PKC phosphorylated the same residue, corresponding to Thr112, whereas caskII phosphorylated two residues, corresponding to Thr125 and Thr128. Endogenous synaptotagmin I was phosphorylated on purified synaptic vesicles by all three kinases. In contrast, no phosphorylation was observed on clathrin-coated vesicles, suggesting that phosphorylation of synaptotagmin I in vivo occurs only at specific stage(s) of the synaptic vesicle life cycle. In rat brain synaptosomes and PC12 cells, K+-evoked depolarization or treatment with phorbol ester caused an increase in the phosphorylation state of synaptotagmin I at Thr112. The results suggest the possibility that the phosphorylation of synaptotagmin I by CaMKII and PKC contributes to the mechanism(s) by which these two kinases regulate neurotransmitter release.     

Analysis of quantitative trait loci in mice suggests a role of Enoph1 in stress reactivity

Significant progress in elucidating the genetic etiology of anxiety and depression has been made during the last decade through a combination of human and animal studies. In this study, we aimed to discover genetic loci linked with anxiety as well as depression in order to reveal new candidate genes. Therefore, we initially tested the behavioral sensitivity of 543 F2 animals derived from an intercross of C57BL/6J and C3H/HeJ mice in paradigms for anxiety and depression. Next, all animals were genotyped with 269 microsatellite markers with a mean distance of 5.56 cM. Finally, a Quantitative Trait Loci (QTL) analysis was carried out, followed by selection of candidate genes. The QTL analysis revealed several new QTL on chromosome 5 with a common core interval of 19 Mb. We further narrowed this interval by comparative genomics to a region of 15 Mb. A database search and gene prioritization revealed Enoph1 as the most significant candidate gene on the prioritization list for anxiety and also for depression fulfilling our selection criteria. The Enoph1 gene, which is involved in polyamine biosynthesis, is differently expressed in parental strains, which have different brain spermidine levels and show distinct anxiety and depression‐related phenotype. Our result suggests a significant role in polyamines in anxiety and depression‐related behaviors.