Genetically altered mice: phenotypes,no phenotypes,and Faux phenotypes

Phenotype means different things, but whatever the measure, phenotype can be profoundly influenced by genetic, environmental and infectious variables. The laboratory mouse is a complex multisystemic organism which, despite its genetically inbred nature, as highly variable pathophysiologic characteristics. Mouse strains have background characteristics that can influence genomics research. In addition to the mouse itself, different approaches toward creating mutant mice each create variables that influence phenotype. Different background strains of mice are utilized for these different approaches, and various strains are preferred among different laboratories. Background genotype significantly influences phenotype of gene mutations, as can insufficient genetic stabilization of a mutation. Research programs engaged in functional mouse genomics not only must use genetically well-defined mice, but also must incorporate environmental and infectious disease quality assurance/prevention programs. Laboratory mice are subject to over 60 different infectious disease agents, including a wide variety of viruses, bacteria, protozoa, and metazoa. Although these agents can be readily diagnosed and prevented, a number of forces are resulting in their rise in prevalence in mouse colonies. Infectious disease, including clinically silent infections, can and do influence phenotype, and can jeopardize research considerably through lost time, wasted effort, cost, and even loss of valuable strains.     

Phenotypic screening of hepatocyte nuclear factor (HNF) 4-gamma receptor knockout mice

Using the mouse as a model organism in pharmaceutical research presents unique advantages as its physiology in many ways resembles the human physiology, it also has a relatively short generation time, low breeding and maintenance costs, and is available in a wide variety of inbred strains. The ability to genetically modify mouse embryonic stem cells to generate mouse models that better mimic human disease is another advantage. In the present study, a comprehensive phenotypic screening protocol is applied to elucidate the phenotype of a novel mouse knockout model of hepatocyte nuclear factor (HNF) 4-gamma. HNF4-gamma is expressed in the kidneys, gut, pancreas, and testis. The first level of the screen is aimed at general health, morphologic appearance, normal cage behaviour, and gross neurological functions. The second level of the screen looks at metabolic characteristics and lung function. The third level of the screen investigates behaviour more in-depth and the fourth level consists of a thorough pathological characterisation, blood chemistry, haematology, and bone marrow analysis. When compared with littermate wild-type mice (HNF4-gamma(+/+)), the HNF4-gamma knockout (HNF4-gamma(-/-)) mice had lowered energy expenditure and locomotor activity during night time that resulted in a higher body weight despite having reduced intake of food and water. HNF4-gamma(-/-) mice were less inclined to build nest and were found to spend more time in a passive state during the forced swim test.     

高频度微卫星不稳定性大肠癌"修饰型"微卫星变化与MLH1及KRAS基因突变密切相关

本研究通过方法学的改良和观察方式的创新试图阐明这种现象的原因.微卫星非传统的检测方法仅能实现微卫星定性检测,我所在的研究组开发了自动片段分析双荧光标识技术,提高了微卫星检测的感度和重复性,并实现了微卫星片段变化长度的定量.小于6碱基的微卫星变化被定义为修饰型微卫星不稳定,大于8碱基的变化被定义为跳跃型微卫星不稳定,它们的电泳谱截然不同.前者表现为在非肿瘤来源微卫星位点基础上的增加或减少,后者表现为距离非肿瘤微卫星片段远隔部位的新波形的出现.通过研究我们发现,在DNA错配修复缺陷细胞系及基因敲除大鼠自发肿瘤样本,仅有修饰型微卫星不稳定性检出;在人类DNA错配修复缺陷细胞系连续80次传代也没有检出跳跃型变化.跳跃型变化不能通过简单重复序列不稳定基础上的增加或减少的累加而获得.在76例散发大肠癌,我们检测了微卫星不稳定性,KRAS基因突变,并对高频度微卫星不稳定性病例的两个主要DNA错配修复基因MSH2和MLHl进行了全长测序.我们发现,在大肠癌,按频度的传统分类与按波形变化的分类有高度的一致性,高频度微卫星不稳定性病例均检测到跳跃型表现,低频度微卫星不稳定性都表现为修饰型变化.在12例高频度微卫星不稳定病例,有三例检出了跳跃型和修饰型同时存在微卫星不稳定的特殊表型,这3例均检出KRAS的突变,更有趣的是该3例病例也同时检出了DNA错配修复基因MLH1的变异.而在其他9例高频度微卫星不稳定病例,KRAS突变及MLH1、MSH2交变未检出.通过对突变谱的分析我们还发现,修饰型微卫星不稳定与KTAS基因12号密码子的转换型突变高度相关,而微卫星稳定的病例检出的KRAS基因12号密码子突变多为颠换型突变.修饰型微卫星不稳定表型检出的高频度转换突变可由DNA错配修复缺陷的分子背景解释.通过本研究,我们认为以波形为基础的微卫星不稳定新分型可能是解决目前微卫星研究领域矛盾的一个选项.一直公认为高频度微卫星不稳定性是"真正"的DNA错配修复缺陷表型,我们的研究提示实际上高频度微卫星的可能是多元的.修饰型微卫星不稳定与DNA错配修复缺陷直接关联,而跳跃型微卫星不稳定的原因尚未阐明.在高频度为微型不稳定中,携带修饰型变化的病例可以通过DNA错配修复系统缺陷来解释其病因.     

人工高盐环境中可培养嗜盐菌的分离与分析

嗜盐菌属于极端微生物中的一种,其结构与理化性质的研究受到国内外同行的关注.国际同行在嗜盐菌的研究领域已经做了大量的工作,而国内的研究工作相对较少.     

Isolation of the gene encoding pilin of Bacteroides nodosus (strain 198), the causal organism of ovine footrot

The gene for pilin, the monomeric protein subunit from which the pilus of Bacteroides nodosus is constructed, has been isolated. Isolation was achieved by cloning the fragmented genome of B. nodosus in Escherichia coli RR1 using the plasmid vector pBR322. Pilin-producing colonies were identified by screening with a colony immunoassay using antiserum from a sheep immunized against purified pili from B. nodosus strain 198, and were further characterized by immunoblot analysis. Final confirmation of the presence of the pilin gene was by nucleotide sequence data which translated to the known pilin amino acid sequence.     

A conceptual review on systems biology in health and diseases: from biological networks to modern therapeutics

Human physiology is an ensemble of various biological processes spanning from intracellular molecular interactions to the whole body phenotypic response. Systems biology endures to decipher these multi-scale biological networks and bridge the link between genotype to phenotype. The structure and dynamic properties of these networks are responsible for controlling and deciding the phenotypic state of a cell. Several cells and various tissues coordinate together to generate an organ level response which further regulates the ultimate physiological state. The overall network embeds a hierarchical regulatory structure, which when unusually perturbed can lead to undesirable physiological state termed as disease. Here, we treat a disease diagnosis problem analogous to a fault diagnosis problem in engineering systems. Accordingly we review the application of engineering methodologies to address human diseases from systems biological perspective. The review highlights potential networks and modeling approaches used for analyzing human diseases. The application of such analysis is illustrated in the case of cancer and diabetes. We put forth a concept of cell-to-human framework comprising of five modules (data mining, networking, modeling, experimental and validation) for addressing human physiology and diseases based on a paradigm of system level analysis. The review overtly emphasizes on the importance of multi-scale biological networks and subsequent modeling and analysis for drug target identification and designing efficient therapies.     

Yeast ARMs (DNA at-risk motifs) can reveal sources of genome instability

The genomes of all organisms contain an abundance of DNA repeats which are at-risk for causing genetic change. We have used the yeast Saccharomyces cerevisiae to investigate various repeat categories in order to understand their potential for causing genomic instability and the role of DNA metabolism factors. Several types of repeats can increase enormously the likelihood of genetic changes such as mutation or recombination when present either in wild type or mutants defective in replication or repair. Specifically, we have investigated inverted repeats, homonucleotide runs, and short distant repeats and the consequences of various DNA metabolism mutants. Because the at-risk motifs (ARMs) that we characterized are sensitive indicators, we have found that they are useful tools to reveal new genetic factors affecting genome stability as well as to distinguish subtle differences between alleles.     

模拟失重环境对大肠杆菌K12表型异质性亚群菌株的影响

【背景】我国未来几年深空探索任务将呈"井喷式"发展,微生物对于航天活动的影响越来越引起关注,而国内外少有表型异质性亚群的研究。【目的】从表型异质性的角度探讨低剪切力模拟失重环境(Low-shearmodeledmicrogravity,LSMMG)和低剪切力正常重力环境(Low-shearnormalgravity,LSNG)对大肠杆菌K12造成的影响。【方法】利用旋转细胞培养系统模拟失重环境对大肠杆菌K12进行连续传代培养,从单克隆形态、颜色以及菌体形态等方面挑选出表型异质性的亚群菌株,对不同菌株进行增殖速率、抗生素耐药性、生物被膜形成、环境压力抵抗力以及细胞毒性的测定,以此评估低剪切力和模拟失重环境对大肠杆菌K12的影响。【结果】利用旋转细胞培养系统连续传代培养,总共分离出4株形态不同的表型异质性亚群菌株,其中2株来自模拟失重组(M1,Ma),另外2株来自正常重力对照组(N1,Na);4株亚群与原始菌株(P)相比,在增殖速率、生物被膜形成、环境压力抵抗力和细胞毒性方面均有增强或减弱的明显变化,对于抗生素的耐药性无明显变化。【结论】低剪切力模拟失重环境以及存在低剪切力的正常重力环境均能引起大肠杆菌表型异质性变化,与原始菌株相比,表型异质性亚群菌株在分化上并没有统一的方向,但仍需警惕那些可能对人类造成危害的变化表型。     

Population differentiation related to climate of origin affects the intensity of plant–herbivore interactions in a clonal grass

With ongoing climate change, it is likely that shifts in species distribution ranges will lead to changes in the type and intensity of plant–herbivore interactions. Plants currently exposed to lower levels of herbivory could have less developed defensive mechanisms and therefore could suffer in case of increased herbivore pressure.We performed a common garden experiment using clones of Festuca rubra originating from four populations experiencing contrasting temperature and precipitation regimes. Clones of identical genotype were subjected to both the control and the herbivory treatment using larvae of the nymphalid butterfly Coenonympha pamphilus, a generalist herbivore feeding on several grass species. Various measures of constitutive and induced defence as well as growth response to herbivory were assessed, compared between populations of different climatic origin and related to herbivore performance (larval survival).The four F. rubra populations significantly differed in constitutive defence (content of Si and total phenols), nutritional quality (content of C) and inducibility of defence (change in total phenols), but not in growth response to herbivory. Herbivores survived better on populations from colder climate and better survival was generally related to lower Si content and lower initial plant size.We demonstrated population differentiation in both constitutive and induced defence against insect herbivory, which directly affected survival of a generalist herbivore. Our findings confirmed the expectation that plants from higher elevations are more prone to herbivory. Moreover, differences in various aspects of plant defence between populations from the same altitude stresses the need of considering multiple factors when assessing the effect of climate on plant–herbivore interactions.     

Imaging mass spectroscopy delineates the thinned and thickened walls of intracranial aneurysms

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The wall thickness of intracranial aneurysms (IAs) is heterogeneous. Although thinning of the IA wall is thought to contribute to IA rupture, the underlying mechanism remains poorly understood. Recently, imaging mass spectroscopy (IMS) has been used to reveal the distribution of phospholipids in vascular diseases. To investigate the feature of phospholipid composition of IA walls, we conducted IMS in a rat model of experimentally induced IA.