lncRNA DNM3OS在喉鳞状细胞癌组织和细胞中的表达及其临床和生物学意义

目的:检测lncRNA DNM3OS在喉鳞状细胞癌(laryngeal squamous cell carcinoma,LSCC)组织和LSCC细胞株中的表达及其临床意义,探讨其对LSCC TU177细胞体外增殖、迁移及侵袭的影响,并分析DNM3OS与EMT的关系.方法:从河北医科大学第四医院生物标本库选取2014年3...     

Regulation of postsynaptic AMPA responses by synaptojanin 1

Endocytosis of postsynaptic AMPA receptors is a mechanism through which efficiency of neurotransmission is regulated. We have genetically tested the hypothesis that synaptojanin 1, a phosphoinositide phosphatase implicated in the endocytosis of synaptic vesicles presynaptically, may also function in the endocytosis of AMPA receptors postsynaptically. Electrophysiological recordings of cultured hippocampal neurons showed that miniature excitatory postsynaptic current amplitudes were larger in synaptojanin 1 knockout (KO) neurons because of an increase of surface-exposed AMPA receptors. This change did not represent an adaptive response to decreased presynaptic release in KO cultures and was rescued by the expression of wild type, but not catalytically inactive synaptojanin 1, in the postsynaptic neuron. NMDA-induced internalization of pHluorin-tagged AMPA receptors (GluR2) was impaired in KO neurons. These results reveal a function of synaptojanin 1 in constitutive and triggered internalization of AMPA receptors and thus indicate a role for phosphatidylinositol(4,5)-bisphosphate metabolism in the regulation of postsynaptic AMPA responses.     

转基因小鼠脑组织中突触素和发动蛋白Ⅰ及衔接蛋白180表达的变化

目的探讨瑞典型淀粉样前体蛋白突变基因转基因小鼠脑组织中突触素(synaptophysin)、发动蛋白Ⅰ(dynamin Ⅰ)及衔接蛋白180(AP180)表达变化。方法选择6只瑞典型淀粉样前体蛋白突变基因转基因小鼠为转基因组,另选5只小鼠为对照组。采用免疫组织化学染色法检测小鼠海马及颞叶皮质synaptophysin、dynamin Ⅰ及AP180的表达,图像分析半定量;免疫组织化学双染法观察转基因小鼠脑组织中synaptophysin与β淀粉样蛋白(Aβ)_(1-42)在老年斑表达部位的关系。结果与对照组比较,转基因组小鼠脑组织齿状回分子层、海马CA1、CA3及内嗅区皮质各层synaptophysin平均灰度值明显增高(P0.05,P0.01);齿状回颗粒细胞、海马CA1锥体细胞及内嗅区皮质各层dynamin Ⅰ平均灰度值明显增高(P0.05,P0.01);齿状回分子层、海马CA4、CA1、内嗅区皮质各层及颞叶皮质Ⅱ～Ⅴ层AP180平均灰度值明显增高(P0.05,P0.01)。免疫组织化学双染显示转基因组小鼠老年斑内有synaptophysin和Aβ_(1-42)共同存在。结论转基因小鼠脑组织中synaptophysin、dynamin Ⅰ及AP180表达降低,提示出现不同程度突触丧失及突触囊泡回收功能缺陷,可能是该小鼠认知功能障碍的原因之一。     

Nanoconjugation modulates the trafficking and mechanism of antibody induced receptor endocytosis

Treatment with monoclonal antibody (mAbs) is a viable therapeutic option in cancer. Recently, these mAbs such as cetuximab, herceptin, etc., have been used as targeting agents to selectively deliver chemotherapeutics to cancerous cells. However, mechanisms of nanoparticles-mAbs interactions with the target cells and its effect on intracellular trafficking and mechanism are currently unknown. In this paper, we demonstrate that the distinct patterning and dynamics of anti-EGFR (epidermal growth factor receptor) antibody cetuximab (C225)- induced EGFR internalization in pancreatic cancer cells with variable receptor expression is altered upon nanoconjugation. Nanoconjugation uniformly enhanced C225-induced EGFR endocytosis in PANC-1, AsPC-1, and MiaPaca-2 cells, influenced its compartmentalization and regulated the involvement of dynamin-2 in the endocytic processes. Receptor endocytosis and its intracellular trafficking were monitored by confocal microscopy and transmission electron microscopy. The role of dynamin-2 in EGFR endocytosis was determined after overexpressing either wild-type dynamin-2 or mutant dynamin-2 in pancreatic cancer cells followed by tracking the receptor-antibody complex internalization by confocal microscopy. Significantly, these findings demonstrate that the nanoconjugation cannot be construed as an innocuous reaction involved in attaching the targeting agent to the nanoparticle, instead it may distinctly alter the cellular processes at the molecular level, at least antibody induced receptor endocytosis. This information is critical for successful design of a nanoparticle-based targeted drug delivery system for future clinical translation.     

Ancient dynamin segments capture early stages of host–mitochondrial integration

Eukaryotic cells use dynamins—mechano-chemical GTPases—to drive the division of endosymbiotic organelles. Here we probe early steps of mitochondrial and chloroplast endosymbiosis by tracing the evolution of dynamins. We develop a parsimony-based phylogenetic method for protein sequence reconstruction, with deep time resolution. Using this, we demonstrate that dynamins diversify through the punctuated transformation of sequence segments on the scale of secondary-structural elements. We find examples of segments that have remained essentially unchanged from the 1.8-billion-y-old last eukaryotic common ancestor to the present day. Stitching these together, we reconstruct three ancestral dynamins: The first is nearly identical to the ubiquitous mitochondrial division dynamins of extant eukaryotes, the second is partially preserved in the myxovirus-resistance-like dynamins of metazoans, and the third gives rise to the cytokinetic dynamins of amoebozoans and plants and to chloroplast division dynamins. The reconstructed sequences, combined with evolutionary models and published functional data, suggest that the ancestral mitochondrial division dynamin also mediated vesicle scission. This bifunctional protein duplicated into specialized mitochondrial and vesicle variants at least three independent times—in alveolates, green algae, and the ancestor of fungi and metazoans—accompanied by the loss of the ancient prokaryotic mitochondrial division protein FtsZ. Remarkably, many extant species that retain FtsZ also retain the predicted ancestral bifunctional dynamin. The mitochondrial division apparatus of such organisms, including amoebozoans, red algae, and stramenopiles, seems preserved in a near-primordial form.Eukaryotes arose through the acquisition of mitochondria by an archaeal host cell about 2 billion y ago (1, 2), a watershed moment in the evolution of the modern compartmentalized cell plan (3). A second transformative endosymbiotic event, the acquisition of a cyanobacterium by a eukaryotic host to form chloroplasts, gave rise to the photosynthetic eukaryotic lineages (4). As the endosymbionts became integrated with their hosts, their growth and division became regulated by host–cellular machinery (5). Proteins of the dynamin superfamily were central to this process: Mitochondria and chloroplasts originally divided using a constricting ring of the prokaryotic cytoskeletal protein FtsZ, but dynamins have been recruited to these roles in all extant eukaryotes (6, 7). By reconstructing the evolutionary history of dynamins, we can probe the process of endosymbiont integration.The dynamin superfamily is diverse (8, 9), and different dynamin variants remodel membranes at different cellular locations (Table S1 and primary references therein). A major class of dynamins is essential for mitochondrial and peroxisomal division. Another large group drives the scission of clathrin-coated vesicles in organisms such as fungi and alveolates. A related group, the so-called “classical” dynamins that drive clathrin-coated vesicle scission in metazoans and land plants, contains a membrane-targeted pleckstrin homology (PH) domain. Members of the phragmoplastin class of dynamins participate in cell plate formation in land plants. The myxovirus-resistance-like dynamins are implicated in antiviral activity in vertebrates. A truncated dynamin variant is involved in cytokinesis in amoebozoans and plants, as well as in chloroplast fission in photosynthetic lineages; another truncated variant drives mitochondrial inner membrane fusion in fungi and metazoans. Finally, mitofusins and the related bacterial dynamin-like proteins (BDLPs) are potentially ancient members of the dynamin superfamily (10); these are excluded from our study because they are highly diverged at the sequence level.Here we present the most comprehensive analysis of dynamin evolution yet reported, including thousands of functionally diverse dynamins from hundreds of broadly sampled eukaryotic species. We reconstruct the series of events that led from the primordial dynamins of the 1.8-billion-y-old last eukaryotic common ancestor (LECA) (11) to the great variety of present-day dynamins. The outcome is a nuanced picture of protein diversification, mirroring key events in the evolution of eukaryotes themselves and shedding light on the earliest stages of endosymbiont integration.     

Differential efficiency of the endocytic machinery in tonic and phasic synapses

Efficient synaptic vesicle membrane recycling is one of the key factors required to sustain neurotransmission. We investigated potential differences in the compensatory endocytic machineries in two glutamatergic synapses with phasic and tonic patterns of activity in the lamprey spinal cord. Post-embedding immunocytochemistry demonstrated that proteins involved in synaptic vesicle recycling, including dynamin, intersectin, and synapsin, occur at higher levels (labeling per vesicle) in tonic dorsal column synapses than in phasic reticulospinal synapses. Synaptic vesicle protein 2 occurred at similar levels in the two types of synapse. After challenging the synapses with high potassium stimulation for 30 min the vesicle pool in the tonic synapse was maintained at a normal level, while that in the phasic synapse was partly depleted along with expansion of the plasma membrane and accumulation of clathrin-coated intermediates at the periactive zone. Thus, our results indicate that an increased efficiency of the endocytic machinery in a synapse may be one of the factors underlying the ability to sustain neurotransmission at high rates.