Cellular Signaling Pathways and Posttranslational Modifications Mediated by Nematode Effector Proteins

Plant-parasitic cyst and root-knot nematodes synthesize and secrete a suite of effector proteins into infected host cells and tissues. These effectors are the major virulence determinants mediating the transformation of normal root cells into specialized feeding structures. Compelling evidence indicates that these effectors directly hijack or manipulate refined host physiological processes to promote the successful parasitism of host plants. Here, we provide an update on recent progress in elucidating the molecular functions of nematode effectors. In particular, we emphasize how nematode effectors modify plant cell wall structure, mimic the activity of host proteins, alter auxin signaling, and subvert defense signaling and immune responses. In addition, we discuss the emerging evidence suggesting that nematode effectors target and recruit various components of host posttranslational machinery in order to perturb the host signaling networks required for immunity and to regulate their own activity and subcellular localization.The root-knot (Meloidogyne spp.) and cyst (Globodera and Heterodera spp.) nematodes are sedentary endoparasites of the root system in a wide range of plant species. These obligate parasites engage in intricate relationships with their host plants that result in the transformation of normal root cells into specialized feeding sites, which provide the nematodes with all the nutrients required for their development. The initiation and maintenance of functional feeding cells by root-knot nematodes (giant cells) and cyst nematodes (syncytia) seems to be a dynamic process involving active dialogue between the nematodes and their host plants. The nematodes use their stylet, a needle-like apparatus, to deliver effector proteins into the host cells (Williamson and Hussey, 1996; Davis et al., 2004). These effector proteins are mainly synthesized in the nematode esophageal glands, which consist of one dorsal cell and two subventral cells. The activity of these glands is developmentally regulated, with secretions from the two subventral glands being most dynamic during the early stage of infection, consisting of root penetration, migration, and feeding site initiation. Secretions from the single dorsal cell seem to be more active during the sedentary stage of nematode feeding (Hussey and Mims, 1990).Recent progress in the functional characterization of effector proteins from a number of phytonematodes has elucidated diverse mechanisms through which these effectors facilitate the nematode parasitism of host plants. One such mechanism involves depolymerization of the main structural polysaccharide constituents of the plant cell wall by using a diverse collection of extracellular effector proteins (Davis et al., 2011; Wieczorek, 2015). Another mechanism includes the molecular mimicry of host proteins in both form and function (Gheysen and Mitchum, 2011). This strategy could be highly successful when the nematode-secreted effectors imitate host functions to subvert cellular processes in favor of nematodes while escaping the regulation of host cellular processes. Another mechanism of effector action is the modulation of central components of auxin signaling to apparently generate unique patterns of auxin-responsive gene expression, leading to numerous physiological and developmental changes required for feeding site formation and development (Cabrera et al., 2015). In addition, cyst and root-knot nematodes have evolved to efficiently suppress defense responses during their prolonged period of sedentary biotrophic interaction with their hosts. Accordingly, a large number of nematode effectors are engaged in suppressing host immune responses and defense signaling (Hewezi and Baum, 2013; Goverse and Smant, 2014). Finally, there is accumulating evidence that nematode effector proteins target and exploit the host posttranslational machinery to the parasite’s advantage. Posttranslational modifications (PTMs) are tightly controlled and highly specific processes that enable rapid cellular responses to specific stimuli without the requirement of new protein synthesis (Kwon et al., 2006). Phosphorylation, ubiquitination, and histone modifications, among others, have recently been identified as fundamental cellular processes controlling immune signaling pathways (Stulemeijer and Joosten, 2008; Howden and Huitema, 2012; Marino et al., 2012; Salomon and Orth, 2013). This finding underscores the importance of targeting and coopting host posttranslational machinery by pathogen effectors to exert their virulence functions. Here, we review recent progress in the functional characterization of nematode effector proteins and the parasitic strategies that involve modifications of the plant cell wall, molecular mimicry of host factors, alteration of auxin signaling, subversion of defense signaling, and targeting and utilizing the host posttranslational machinery.     

Novel Pancreatic Endocrine Maturation Pathways Identified by Genomic Profiling and Causal Reasoning

We have used a previously unavailable model of pancreatic development, derived in vitro from human embryonic stem cells, to capture a time-course of gene, miRNA and histone modification levels in pancreatic endocrine cells. We investigated whether it is possible to better understand, and hence control, the biological pathways leading to pancreatic endocrine formation by analysing this information and combining it with the available scientific literature to generate models using a casual reasoning approach. We show that the embryonic stem cell differentiation protocol is highly reproducible in producing endocrine precursor cells and generates cells that recapitulate many aspects of human embryonic pancreas development, including maturation into functional endocrine cells when transplanted into recipient animals. The availability of whole genome gene and miRNA expression data from the early stages of human pancreatic development will be of great benefit to those in the fields of developmental biology and diabetes research. Our causal reasoning algorithm suggested the involvement of novel gene networks, such as NEUROG3/E2F1/KDM5B and SOCS3/STAT3/IL-6, in endocrine cell development We experimentally investigated the role of the top-ranked prediction by showing that addition of exogenous IL-6 could affect the expression of the endocrine progenitor genes NEUROG3 and NKX2.2.     

Exploiting Cell Death Pathways by an E. coli Cytotoxin: Autophagy as a Double-Edged Sword for the Host

Cytotoxic necrotizing factor 1 is a bacterial protein toxin from Escherichia coli that is able to activate the Rho GTPases and to hinder apoptosis and mitotic catastrophe. Upon exposure to toxin, cells undergo a complex framework of changes, including cytoskeleton remodeling and multinucleation. These cells also show a high survival rate for long periods of time and improve both their macropinocytotic scavenging activities and microautophagy. Only at the very end, probably when “feeding” materials are exhausted, they do these cells die by autophagy. Taking into account the complex role of bacterial protein toxins in the infectious processes, we indicate the CNF1 activity as a Janus-faced paradigm of those bacteria that hijack cell fate to their own benefit. This could somehow be linked to the hypothesized connection between certain bacterial toxins and cancer onset.

Addendum to:

Is the Rac GTPase-Activating Toxin CNF1 a Smart Hijacker of Host Cell Fate?

W. Malorni and C. Fiorentini

FASEB J 2006; 20:606-9     

从临床肺炎死亡树购中分离到致病性大肠埃希菌

目的对6例1月内因肺炎死亡的树鼢采样进行病原菌分离培养鉴定分析。方法解剖死亡树购,利用无菌刀片切开肺组织,用无菌接种环插入肺内采样接种于营养琼脂培养基,另取两份样品进行细菌涂片革兰氏染色和抗酸染色。培养出来的细菌进行进一步分离和菌落生长情况的观察,并经革兰氏染色、抗酸染色、氧化酶试验、生化编码鉴定和9种药敏试验,初步确定树鼢肺部感染的致病菌及其药敏情况。结果样本革兰氏染色见到大量阴性杆菌,抗酸染色结果显示为非结核分枝杆菌,大小约为0．2μm×2～6μm。营养琼脂培养6例样品中均仅见1株旺盛生长的细菌,进一步分离培养经革兰氏染色为阴性杆菌,抗酸染色为非结核分枝杆菌,大小和染色结果与样本涂片相同,经鉴定为致病性大肠埃希菌。药敏试验表明该菌对头孢哌酮,呋喃妥因,氨苄西林,阿米卡星,氧氟沙星,诺氟沙星,磺胺甲嗯唑／甲氧苄定高度敏感;对庆大霉素和青霉素G为低度敏感。结论6例树鼢死亡原因均为细菌性肺炎,病原菌初步鉴定为致病性大肠埃希菌。药敏实验筛选出的药物可为临床治疗树鼢该类病例用药提供指导。     

Proteome and Phosphoproteome Analysis of Brown Adipocytes Reveals That RICTOR Loss Dampens Global Insulin/AKT Signaling

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Highlights

• •Global and targeted phosphoproteomics in RICTOR-deficient brown adipocytes.
• •RICTOR loss leads to higher levels of many interferon response-associated proteins.
• •RICTOR loss dampens the dynamic insulin-dependent phosphoproteome response.
• •ACLY S455, VIM S39, and EIF4B S422 are among the most dampened phosphosites.

     

Integrated Phosphoproteome and Transcriptome Analysis Reveals Chlamydia-Induced Epithelial-to-Mesenchymal Transition in Host Cells

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The Enteropathogenic E. coli Effector EspF Targets and Disrupts the Nucleolus by a Process Regulated by Mitochondrial Dysfunction

The nucleolus is a multifunctional structure within the nucleus of eukaryotic cells and is the primary site of ribosome biogenesis. Almost all viruses target and disrupt the nucleolus—a feature exclusive to this pathogen group. Here, using a combination of bio-imaging, genetic and biochemical analyses, we demonstrate that the enteropathogenic E. coli (EPEC) effector protein EspF specifically targets the nucleolus and disrupts a subset of nucleolar factors. Driven by a defined N-terminal nucleolar targeting domain, EspF causes the complete loss from the nucleolus of nucleolin, the most abundant nucleolar protein. We also show that other bacterial species disrupt the nucleolus, dependent on their ability to deliver effector proteins into the host cell. Moreover, we uncover a novel regulatory mechanism whereby nucleolar targeting by EspF is strictly controlled by EPEC''s manipulation of host mitochondria. Collectively, this work reveals that the nucleolus may be a common feature of bacterial pathogenesis and demonstrates that a bacterial pathogen has evolved a highly sophisticated mechanism to enable spatio-temporal control over its virulence proteins.     

Autotransporter Protein-Encoding Genes of Diarrheagenic Escherichia coli Are Found in both Typical and Atypical Enteropathogenic E. coli Strains

Autotransporter (AT) protein-encoding genes of diarrheagenic Escherichia coli (DEC) pathotypes (cah, eatA, ehaABCDJ, espC, espI, espP, pet, pic, sat, and tibA) were detected in typical and atypical enteropathogenic E. coli (EPEC) in frequencies between 0.8% and 39.3%. Although these ATs have been described in particular DEC pathotypes, their presence in EPEC indicates that they should not be considered specific virulence markers.     

Molecular Subtyping and Genetic Analysis of the Enterohemolysin Gene (ehxA) from Shiga Toxin-Producing Escherichia coli and Atypical Enteropathogenic E. coli

Analyses of the distribution of virulence factors among different Escherichia coli pathotypes, including Shiga toxin-producing E. coli (STEC), may provide some insight into the mechanisms by which different E. coli strains cause disease and the evolution of distinct E. coli types. The aim of this study was to examine the DNA sequence of the gene for enterohemolysin, a plasmid-encoded toxin that readily causes the hemolysis of washed sheep erythrocytes, and to assess the distribution of enterohemolysin subtypes among E. coli isolates from various human and animal sources. The 2,997-bp ehxA gene was amplified from 227 (63.8%) of 356 stx- and/or eae-positive E. coli strains isolated from cattle and sheep and from 24 (96.0%) of 25 STEC strains isolated from humans with diarrheal disease. By using PCR and restriction fragment length polymorphism (RFLP) analysis of ehxA, six distinct PCR-RFLP types (A to F) were observed, with strains of subtypes A and C constituting 91.6% of all the ehxA-positive strains. Subtype A was associated mainly with ovine strains with stx only (P < 0.001), and subtype C was associated with bovine eae-positive strains (P < 0.001). Eleven ehxA alleles were fully sequenced, and the phylogenetic analysis indicated the presence of three closely related (>95.0%) ehxA sequence groups, one including eae-positive strains (subtypes B, C, E, and F) and the other two including mainly eae-negative STEC strains (subtypes A and D). In addition to being widespread among STEC strains, stx-negative, eae-positive strains (atypical enteropathogenic E. coli strains) isolated from cattle and sheep have similar ehxA subtypes and hemolytic activities.     

新型大肠杆菌裂解系统在重组蛋白回收中的应用

溶菌酶通过降解细菌细胞壁的肽聚糖裂解细菌,利用此特性,构建温度敏感的内源裂解系统,达到高效释放和回收重组蛋白的目的。构建了温度敏感的Ｔ４溶菌酶基因表达质粒ｐＳＣ－ｌｙｓ（ｐＳＣ１０１复制子）和ｐ１５Ａ－ｌｙｓ（ｐ１５Ａ复制子）,质粒与工程菌构成了新型内源裂解系统,系统可以与高拷贝复制子（如ｐＭＢ１,ＣｏｌＥ１）的重组蛋白表达擀粒兼容。结果表明,裂解系统的量适裂解条件由三个要素构成：ｐＳＣ－ｌｙｓ－     

Enteropathogenic E. coli Tir binds Nck to initiate actin pedestal formation in host cells

Enteropathogenic Escherichia coli (EPEC) is a bacterial pathogen that causes infantile diarrhea worldwide. EPEC injects a bacterial protein, translocated intimin receptor (Tir), into the host-cell plasma membrane where it acts as a receptor for the bacterial outer membrane protein, intimin. The interaction of Tir and intimin triggers a marked rearrangement of the host actin cytoskeleton into pedestals beneath adherent bacteria. On delivery into host cells, EPEC Tir is phosphorylated on tyrosine 474 of the intracellular carboxy-terminal domain, an event that is required for pedestal formation. Despite its essential role, the function of Tir tyrosine phosphorylation has not yet been elucidated. Here we show that tyrosine 474 of Tir directly binds the host-cell adaptor protein Nck, and that Nck is required for the recruitment of both neural Wiskott-Aldrich-syndrome protein (N-WASP) and the actin-related protein (Arp)2/3 complex to the EPEC pedestal, directly linking Tir to the cytoskeleton. Cells with null alleles of both mammalian Nck genes are resistant to the effects of EPEC on the actin cytoskeleton. These results implicate Nck adaptors as host-cell determinants of EPEC virulence.     

Comparative Proteomic Analysis of Extracellular Proteins of Enterohemorrhagic and Enteropathogenic Escherichia coli Strains and Their ihf and ler Mutants

Enterohemorrhagic and enteropathogenic Escherichia coli (EHEC and EPEC, respectively) strains are closely related human pathogens that are responsible for food-borne epidemics in many countries. Integration host factor (IHF) and the locus of enterocyte effacement-encoded regulator (Ler) are needed for the expression of virulence genes in EHEC and EPEC, including the elicitation of actin rearrangements for attaching and effacing lesions. We applied a proteomic approach, using two-dimensional polyacrylamide gel electrophoresis in combination with matrix-assisted laser desorption ionization-time of flight mass spectrometry and a protein database search, to analyze the extracellular protein profiles of EHEC EDL933, EPEC E2348/69, and their ihf and ler mutants. Fifty-nine major protein spots from the extracellular proteomes were identified, including six proteins of unknown function. Twenty-six of them were conserved between EHEC EDL933 and EPEC E2348/69, while some of them were strain-specific proteins. Four common extracellular proteins (EspA, EspB, EspD, and Tir) were regulated by both IHF and Ler in EHEC EDL933 and EPEC E2348/69. TagA in EHEC EDL933 and EspC and EspF in EPEC E2348/69 were present in the wild-type strains but absent from their respective ler and ihf mutants, while FliC was overexpressed in the ihf mutant of EPEC E2348/69. Two dominant forms of EspB were found in EHEC EDL933 and EPEC E2348/69, but the significance of this is unknown. These results show that proteomics is a powerful platform technology for accelerating the understanding of EPEC and EHEC pathogenesis and identifying markers for laboratory diagnoses of these pathogens.     

Proteins firmly bound to DNA in the E. coli nucleoid

The nucleoid isolated from E. coli cells was subjected to further deletion by treatment with 2 M NaCl. After disintegration of this nucleoid by ultrasonication, two fractions were obtained, i. e., a rapidly (RS) and slowly sedimenting (SS) ones. The protein, RNA and DNA patterns in the RS fraction are similar to that of the eukaryotic cell nuclear matrix. Electrophoretic analysis of total non-dissociating by 2 M NaCl proteins revealed that the RS and SS fractions predominantly contain proteins with Mr 31,27 and 23 kD. The protein with Mr = 31 kD is firmly bound to DNA, does not dissociate in the guanidine hydrochloride (4 M)-urea (5 M) mixture as well as in solution of 1% sodium-dodecyl sulphate and may be responsible for the chromosome binding to the E. coli membrane.     

Novel Targets of Sulforaphane in Primary Cardiomyocytes Identified by Proteomic Analysis

Cardiovascular diseases represent the main cause of mortality in the industrialized world and the identification of effective preventive strategies is of fundamental importance. Sulforaphane, an isothiocyanate from cruciferous vegetables, has been shown to up-regulate phase II enzymes in cardiomyocytes and counteract oxidative stress-induced apoptosis. Aim of the present study was the identification and characterization of novel sulforaphane targets in cardiomyocytes applying a proteomic approach. Two-dimensional gel electrophoresis and mass spectrometry were used to generate protein profiles of primary neonatal rat cardiomyocytes treated and untreated with 5 µM sulforaphane for 1-48 h. According to image analysis, 64 protein spots were found as differentially expressed and their functional correlations were investigated using the MetaCore program. We mainly focused on 3 proteins: macrophage migration inhibitory factor (MIF), CLP36 or Elfin, and glyoxalase 1, due to their possible involvement in cardioprotection. Validation of the time-dependent differential expression of these proteins was performed by western blotting. In particular, to gain insight into the cardioprotective role of the modulation of glyoxalase 1 by sulforaphane, further experiments were performed using methylglyoxal to mimic glycative stress. Sulforaphane was able to counteract methylglyoxal-induced apoptosis, ROS production, and glycative stress, likely through glyoxalase 1 up-regulation. In this study, we reported for the first time new molecular targets of sulforaphane, such as MIF, CLP36 and glyoxalase 1. In particular, we gave new insights into the anti-glycative role of sulforaphane in cardiomyocytes, confirming its pleiotropic behavior in counteracting cardiovascular diseases.     

Molecular Mechanism for Attractant Signaling to DHMA by E. coli Tsr

The attractant chemotaxis response of Escherichia coli to norepinephrine requires that it be converted to 3,4-dihydroxymandelic acid (DHMA) by the monoamine oxidase TynA and the aromatic aldehyde dehydrogenase FeaB. DHMA is sensed by the serine chemoreceptor Tsr, and the attractant response requires that at least one subunit of the periplasmic domain of the Tsr homodimer (pTsr) has an intact serine-binding site. DHMA that is generated in vivo by E. coli is expected to be a racemic mixture of the (R) and (S) enantiomers, so it has been unclear whether one or both chiral forms are active. Here, we used a combination of state-of-the-art tools in molecular docking and simulations, including an in-house simulation-based docking protocol, to investigate the binding properties of (R)-DHMA and (S)-DHMA to E. coli pTsr. Our studies computationally predicted that (R)-DHMA should promote a stronger attractant response than (S)-DHMA because of a consistently greater-magnitude piston-like pushdown of the pTsr α-helix 4 toward the membrane upon binding of (R)-DHMA than upon binding of (S)-DHMA. This displacement is caused primarily by interaction of DHMA with Tsr residue Thr156, which has been shown by genetic studies to be critical for the attractant response to L-serine and DHMA. These findings led us to separate the two chiral species and test their effectiveness as chemoattractants. Both the tethered cell and motility migration coefficient assays validated the prediction that (R)-DHMA is a stronger attractant than (S)-DHMA. Our study demonstrates that refined computational docking and simulation studies combined with experiments can be used to investigate situations in which subtle differences between ligands may lead to diverse chemotactic responses.