EIKEN嗜肺军团菌检测卡

广州健仑生物科技有限公司

主要用途：用于检测尿样中嗜肺军团菌血清型1抗原，以支持军团菌感染的诊断。

产品规格：20T/盒

存储条件：2-30℃

EIKEN嗜肺军团菌检测卡

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【产品介绍】

EIKEN

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【公司名称】 广州健仑生物科技有限公司
【】    杨永汉 
【】 
【腾讯 】 2042552662
【公司地址】 广州清华科技园创新基地番禺石楼镇创启路63号二期2幢101-3室
【企业文化】

随着越来越多的结构变得可用，研究人员希望调整AWSEM膜算法。Wolynes说：“我不认为我们已经了解膜的相互作用。”这表明大部分的漏斗形折叠发生在蛋白质进入膜之后，很少是因为疏水性(动力学)相互作用，疏水性相互作用在球状蛋白质折叠中发挥了更大的作用。他说：“我的直觉是，那将是正确的。”
Wolynes说：“本文的意义在于，现在我们有一种运算法则，可根据原始的基因组序列，相当好地预测膜蛋白结构。这对于解释新一代的实验结果将非常的有用。”
从受精卵到成年人，人类细胞需要经历的分裂次数可以说是天文数字。每一次分裂时，母细胞都必须将DNA精确分配给两个子细胞。而着丝粒的完整性是细胞成功分裂的关键。着丝粒是染色体上的一个特殊DNA区域，是纺锤丝微管的附着之处，也是姐妹染色单体在分开前相互连接的地方。分离染色体的微管要识别着丝粒，需要该区域富含一种关键的蛋白——CENP-A。在细胞进行DNA复制准备分裂的时候，需要确保新旧DNA链的着丝粒区域填充有足够的CENP-A。在此之前人们只知道着丝粒在G1期填充CENP-A，但并不了解这一过程的具体调控机制。
在这项研究中，怀特海德研究所的McKinley发现了两种确保CENP-A正确填充的关键激酶，Plk1和CDK。这两种激酶参与了CENP-A填充的不同步骤，只有它们都正常起作用，CENP-A才能填满着丝粒中的所有空隙。McKinley不仅解析了这些激酶的作用途径，还在此基础上干扰了CENP-A的填充时机，研究显示这种干扰会引起严重的染色体分离问题。
“着丝粒的功能处于严格的控制之下，因此人们一直认为CENP-A的填充时机应该很重要。现在，我们终于证实了这一理论，”McKinley说。
“CENP-A填充是着丝粒形成的核心步骤，”Cheeseman说，他也是MIT的生物学副教授。 “这项研究揭示了这一步骤的调控基础，有助于我们深入理解细胞分裂的具体过程。”
干细胞可替代中枢神经系统损伤后丢失的细胞，减少神经组织损害，促进功能恢复。许多脑损伤模型，如大脑中动脉阻塞和创伤性脑损伤模型中均证实神经干细胞可从脑室下区迁移至大脑皮质损伤区。但目前仍不够清晰的问题是，激活缺血大脑内源性神经干细胞的机制何在?
韩国全南国立大学医学院法医学系Hyung-Seok Kim博士所在课题组的研究揭示，局灶性脑缺血后神经干细胞的激活存在时序性，并验证了早期表达的低氧诱导因子1α和血管内皮生长因子组成的微环境提高了脑缺血后激活的内源性神经干细胞神经可塑性。大脑皮质损伤后，神经前体细胞的损失可由损伤周围区域和脑室下区得以补充。

As more and more structures become available, researchers hope to adapt the AWSEM membrane algorithm. Wolynes said: "I do not think we have understood the membrane interactions." This shows that most of the funnel-shaped folds occur after the proteins enter the membrane, seldom because of hydrophobic (kinetic) interactions, hydrophobic interactions in the globular Protein folding has played a greater role. He said: "My intuition is that it will be right."
Wolynes says: "What this article means is that now we have an algorithm that fairly predicts the membrane protein structure based on the original genome sequence, which is very useful to explain the new generation of experiments."
From fertilized eggs to adults, the number of divisions human cells need to go through can be said to be astronomical. Each division, the mother cell must be precisely allocated to two daughter cells. The integrity of the centromere is the key to successful cell division. Centromeres are a special DNA region on chromosomes, where spindle microtubules attach themselves and where sister chromatids are connected before they are separated. Microtubules that separate chromosomes recognize centromeres and require this region to be enriched with a key protein, CENP-A. When the cell is ready for DNA replication, it is necessary to ensure that the centromeric regions of the new and old DNA strands are filled with sufficient CENP-A. Before that, people only knew that centromere filled CENP-A in G1 phase, but did not understand the specific regulation mechanism of this process.
In this study, McKinley at the Whitehead Institute identified two key kinases, Plk1 and CDK, that ensure correct filling of CENP-A. These two kinases are involved in different steps of CENP-A packing, and only if they both function normally, CENP-A can fill all the voids in the centromere. Not only did McKinley interpret the pathway of action of these kinases, but they also interfered with the timing of filling CENP-A, and studies showed that this interference can cause serious chromosomal segregation problems.
"The centromere function is under tight control, so it has been argued that the timing of filling with CENP-A should be important, and we have finally confirmed that," McKinley said.
"CENP-A packing is a central step in centromere formation," said Cheeseman, who is also an associate professor of biology at MIT. "This study reveals the basis for the regulation and control of this step, helping us to understand the specific process of cell division."
Stem cells can replace lost cells after CNS injury, reduce nerve tissue damage and promote functional recovery. Many brain injury models, such as middle cerebral artery occlusion and traumatic brain injury models, have confirmed that neural stem cells can migrate from the subventricular zone to the cerebral cortical lesion. However, the question remains unclear: what is the mechanism of activation of endogenous neural stem cells in ischemic brain?
A study by Dr. Hyung-Seok Kim, MD, from the Department of Forensic Medicine, Jeonnam National University School of Medicine, Korea, revealed that the activation of neural stem cells after focal cerebral ischemia is time-sequential and validates the early expression of hypoxia-inducible factor-1α and vascular endothelial Microenvironment of growth factor enhances the neuroplasticity of endogenous neural stem cells activated after cerebral ischemia. After cortical injury, the loss of neural progenitor cells can be compensated for by the area surrounding the lesion and the subventricular zone.