Proteomics as a Tool to Identify New Targets Against Aspergillus and Scedosporium in the Context of Cystic Fibrosis

Mycopathologia - Cystic fibrosis (CF) is a genetic disorder that increases the risk of suffering microbial, including fungal, infections. In this paper, proteomics-based information was collated...     

病毒miRNA与免疫逃逸

微小RNA（microRNA,miRNA）是一种非编码的小分子RNA,长度一般在22 nt左右,通过与mRNA 3＇UTR的特异性结合介导转录后调控过程。现已鉴定出的miRNA涵盖了从植物到人类的多个物种,并参与了调节生长、免疫、凋亡等多种生命活动。最近发现,DNA病毒感染宿主时也能编码产生miRNA,并在病毒免疫逃逸中扮演着重要角色。病毒感染是一个复杂的过程,病毒需要逃脱免疫系统才能对宿主产生持续性感染,而病毒miRNA能调控宿主和自身基因表达,帮助病毒感染宿主,且因其本身没有免疫原性,而成为病毒逃避免疫应答的重要工具,但其中的分子机制尚不十分清楚。该文就病毒miRNA如何调控病毒自身与宿主基因进行免疫逃逸的近期研究作一综述。     

Golgi and Related Vesicle Proteomics: Simplify to Identify

Despite more than six decades of successful Golgi research, the fundamental question as to how biosynthetic material is transported through the secretory pathway remains unanswered. New technologies such as live cell imaging and correlative microscopy have highlighted the plastic nature of the Golgi, one that is sensitive to perturbation yet highly efficient in regaining both structure and function. Single molecule-microscopy and super resolution-microscopy further adds to this picture. Various models for protein transport have been put forward, each with its own merits and pitfalls but we are far from resolving whether one is more correct than the other. As such, our laboratory considers multiple mechanisms of Golgi transport until proven otherwise. This includes the two classical modes of transport, vesicular transport and cisternal progression/maturation as well as more recent models such as tubular inter- and intra-cisternal connections (long lasting or transient) and inter-Golgi stack transport. In this article, we focus on an emerging inductive technology, mass spectrometry-based proteomics that has already enabled insight into the relative composition of compartments and subcompartments of the secretory pathway including mechanistic aspects of protein transport. We note that proteomics, as with any other technology, is not a stand-alone technology but one that works best alongside complementary approaches.     

miRNA体内作用靶标鉴定的策略

miRNAs是一类重要的基因表达调节因子,近年的研究表明miRNA在控制细胞的生长发育、分化、凋亡等过程中发挥着十分重要的作用。但对miRNA作用机制和分子功能的研究却进展缓慢,归其原因是miRNA和靶标之间非完全配对,缺乏快捷有效的靶标鉴定方法。因此,就miRNA靶标鉴定的策略作一综述。miRNA调节靶标的鉴定有助于揭示一些疾病的致病机理,发现可用于治疗的新分子靶标,为基因治疗奠定基础。     

Bottom-up and Shotgun Proteomics to Identify a Comprehensive Cochlear Proteome

Proteomics is a commonly used approach that can provide insights into complex biological systems. The cochlear sensory epithelium contains receptors that transduce the mechanical energy of sound into an electro-chemical energy processed by the peripheral and central nervous systems. Several proteomic techniques have been developed to study the cochlear inner ear, such as two-dimensional difference gel electrophoresis (2D-DIGE), antibody microarray, and mass spectrometry (MS). MS is the most comprehensive and versatile tool in proteomics and in conjunction with separation methods can provide an in-depth proteome of biological samples. Separation methods combined with MS has the ability to enrich protein samples, detect low molecular weight and hydrophobic proteins, and identify low abundant proteins by reducing the proteome dynamic range. Different digestion strategies can be applied to whole lysate or to fractionated protein lysate to enhance peptide and protein sequence coverage. Utilization of different separation techniques, including strong cation exchange (SCX), reversed-phase (RP), and gel-eluted liquid fraction entrapment electrophoresis (GELFrEE) can be applied to reduce sample complexity prior to MS analysis for protein identification.     

病毒蛋白质组学及其应用

病毒蛋白质组学是蛋白质组学研究技术在病毒学领域的应用,其研究方法主要是基于质谱鉴定的电泳分离或色谱分离技术。病毒蛋白质组学的研究可以补充基因组注释、纯化单一的病毒成分、研究病毒与其宿主细胞蛋白的相互作用、识别病毒作用的靶位点、鉴定病毒感染的致病因子及病毒的进化关系、识别病毒的免疫源性蛋白。病毒蛋白质组的研究有助于对病毒致病性的了解,加速新的诊断方法及治疗药物的研制,增强对病毒的生物防御。由于一些技术及主观因素的影响,病毒蛋白质组的研究是很有限的,这是一个亟待重视并增强的领域。     

Deep Sequencing to Identify the Causes of Viral Encephalitis

Deep sequencing allows for a rapid, accurate characterization of microbial DNA and RNA sequences in many types of samples. Deep sequencing (also called next generation sequencing or NGS) is being developed to assist with the diagnosis of a wide variety of infectious diseases. In this study, seven frozen brain samples from deceased subjects with recent encephalitis were investigated. RNA from each sample was extracted, randomly reverse transcribed and sequenced. The sequence analysis was performed in a blinded fashion and confirmed with pathogen-specific PCR. This analysis successfully identified measles virus sequences in two brain samples and herpes simplex virus type-1 sequences in three brain samples. No pathogen was identified in the other two brain specimens. These results were concordant with pathogen-specific PCR and partially concordant with prior neuropathological examinations, demonstrating that deep sequencing can accurately identify viral infections in frozen brain tissue.     

Viral RNAi suppressor reversibly binds siRNA to outcompete Dicer and RISC via multiple turnover

RNA interference is a conserved gene regulatory mechanism employed by most eukaryotes as a key component of their innate immune response to viruses and retrotransposons. During viral infection, the RNase-III-type endonuclease Dicer cleaves viral double-stranded RNA into small interfering RNAs (siRNAs) 21-24 nucleotides in length and helps load them into the RNA-induced silencing complex (RISC) to guide the cleavage of complementary viral RNA. As a countermeasure, many viruses have evolved viral RNA silencing suppressors (RSS) that tightly, and presumably quantitatively, bind siRNAs to thwart RNA-interference-mediated degradation. Viral RSS proteins also act across kingdoms as potential immunosuppressors in gene therapeutic applications. Here we report fluorescence quenching and electrophoretic mobility shift assays that probe siRNA binding by the dimeric RSS p19 from Carnation Italian Ringspot Virus, as well as by human Dicer and RISC assembly complexes. We find that the siRNA:p19 interaction is readily reversible, characterized by rapid binding [(1.69 ± 0.07) × 10⁸ M^− 1 s^− 1] and marked dissociation (k_off = 0.062 ± 0.002 s^− 1). We also observe that p19 efficiently competes with recombinant Dicer and inhibits the formation of RISC-related assembly complexes found in human cell extract. Computational modeling based on these results provides evidence for the transient formation of a ternary complex between siRNA, human Dicer, and p19. An expanded model of RNA silencing indicates that multiple turnover by reversible binding of siRNAs potentiates the efficiency of the suppressor protein. Our predictive model is expected to be applicable to the dosing of p19 as a silencing suppressor in viral gene therapy.     

Proteomics and Phosphoproteomic Analysis to Identify Spleen of Takifugu rubripes Infected Cryptocaryon irritans

Marine Biotechnology - Takifugu rubripes is important commercially fish species in China and it is under serious threat from white spot disease (cyptocaryoniasis), which leads to heavy economic...     

Comparison of Human Genomics and Genetic Models of Cancer to Identify Novel Therapeutic Targets

No abstract available.     

EBV编码miRNAs在病毒感染和肿瘤发生中的功能和意义

EB病毒(Epstein-Barr virus,EBV)是一种172 kb大小的线性双链DNA病毒,与鼻咽癌、淋巴瘤、胃癌等恶性肿瘤的发生密切相关. EBV编码的微小RNAs (miRNAs)可以调节病毒和宿主细胞基因的表达,并且在癌症发生发展中起着多种作用.本文综述了EBV编码的miRNAs (EBV-encoded miRNA,EBV miRNAs)在病毒感染和肿瘤发生、侵袭转移、抗凋亡、信号通路等方面的生物学功能,以及对于EBV相关肿瘤诊断标志物的潜在意义. EB病毒编码的miRNAs也可能成为进一步研究EBV相关肿瘤治疗的一个候选靶点.     

Proteomics to Identify Proteins Interacting with P2X2 Ligand-Gated Cation Channels

Ligand-gated ion channels underlie synaptic communication in the nervous system¹. In mammals there are three families of ligand-gated channels: the cys loop, the glutamate-gated and the P2X receptor channels². In each case binding of transmitter leads to the opening of a pore through which ions flow down their electrochemical gradients. Many ligand-gated channels are also permeable to calcium ions^{3, 4}, which have downstream signaling roles⁵ (e.g. gene regulation) that may exceed the duration of channel opening. Thus ligand-gated channels can signal over broad time scales ranging from a few milliseconds to days. Given these important roles it is necessary to understand how ligand-gated ion channels themselves are regulated by proteins, and how these proteins may tune signaling. Recent studies suggest that many, if not all, channels may be part of protein signaling complexes⁶. In this article we explain how to identify the proteins that bind to the C-terminal aspects of the P2X2 receptor cytosolic domain.P2X receptors are ATP-gated cation channels and consist of seven subunits (P2X1-P2X7). P2X receptors are widely expressed in the brain, where they mediate excitatory synaptic transmission and presynaptic facilitation of neurotransmitter release⁷. P2X receptors are found in excitable and non-excitable cells and mediate key roles in neuronal signaling, inflammation and cardiovascular function⁸. P2X2 receptors are abundant in the nervous system⁹ and are the focus of this study. Each P2X subunit is thought to possess two membrane spanning segments (TM1 & TM2) separated by an extracellular region⁷ and intracellular N and C termini (Fig 1a)⁷. P2X subunits¹⁰ (P2X1-P2X7) show 30-50% sequence homology at the amino acid level¹¹. P2X receptors contain only three subunits, which is the simplest stoichiometry among ionotropic receptors. The P2X2 C-terminus consists of 120 amino acids (Fig 1b) and contains several protein docking consensus sites, supporting the hypothesis that P2X2 receptor may be part of signaling complexes. However, although several functions have been attributed to the C-terminus of P2X2 receptors⁹ no study has described the molecular partners that couple to the intracellular side of this protein via the full length C-terminus. In this methods paper we describe a proteomic approach to identify the proteins which interact with the full length C-terminus of P2X2 receptors.Open in a separate windowClick here to view.^{(104M, flv)}     

蛋白质组学在病毒致病机理研究中的应用

近年来,蛋白质组学技术成为医学研究的热点。蛋白质组学是高通量的分析正常及病理条件下机体、组织、细胞或亚细胞成分中的全部蛋白质。对不同空间、不同时间上动态变化的蛋白质组的整体进行比较,分析不同蛋白质组之间在表达数量、表达水平和修饰状态上的差异。蛋白质组学分析作为对生物代谢调控分析的技术手段,以病毒为研究的对象和工具,该技术的研究主要集中在新蛋白的发现、致病机理、疫苗的研制及耐药机制等方面。本文主要概述了蛋白质组学在一些动物传染病病毒致病方面研究和应用,分析了蛋白质组学技术对蛋白功能研究存在的问题和未来发展趋势,以便使研究者了解该技术使用的现状,提供理论参考。     

Viral Aggregation Resulting in the Failure to Correctly Identify an Unknown Rhinovirus

A seed lot of strain SF 1684 of rhinovirus type 2 prepared in human embryonic lung cells (WI-38) contained aggregates which interfered with its neutralization by homotypic or homologous antisera. The same virus showed no evidence of aggregation at five other passage levels studied. Virus in the seed lot was not identified correctly, and the titer of homologous antiserum was mistakenly considered to be low as a result of neutralization tests conducted with the aggregated virus. Filtration and a more easily effected treatment with sodium deoxycholate (1%) disaggregated the virus and restored its susceptibility to neutralization by homologous and homotypic antiserum.