Affinity Precipitation of Active Rho-GEFs Using a GST-tagged Mutant Rho Protein (GST-RhoA(G17A)) from Epithelial Cell Lysates

Proteins of the Rho family of small GTPases are central regulators of the cytoskeleton, and control a large variety of cellular processes, including cell migration, gene expression, cell cycle progression and cell adhesion ¹. Rho proteins are molecular switches that are active in GTP-bound and inactive in GDP-bound state. Their activation is mediated by a family of Guanine-nucleotide Exchange Factor (GEF) proteins. Rho-GEFs constitute a large family, with overlapping specificities ². Although a lot of progress has been made in identifying the GEFs activated by specific signals, there are still many questions remaining regarding the pathway-specific regulation of these proteins. The number of Rho-GEFs exceeds 70, and each cell expresses more than one GEF protein. In addition, many of these proteins activate not only Rho, but other members of the family, contributing further to the complexity of the regulatory networks. Importantly, exploring how GEFs are regulated requires a method to follow the active pool of individual GEFs in cells activated by different stimuli. Here we provide a step-by-step protocol for a method used to assess and quantify the available active Rho-specific GEFs using an affinity precipitation assay. This assay was developed a few years ago in the Burridge lab ^3,4 and we have used it in kidney tubular cell lines ^5,6,7. The assay takes advantage of a "nucleotide free" mutant RhoA, with a high affinity for active GEFs. The mutation (G17A) renders the protein unable to bind GDP or GTP and this state mimics the intermediate state that is bound to the GEF. A GST-tagged version of this mutant protein is expressed and purified from E. coli, bound to glutathione sepharose beads and used to precipitate active GEFs from lysates of untreated and stimulated cells. As most GEFs are activated via posttranslational modifications or release from inhibitory bindings, their active state is preserved in cell lysates, and they can be detected by this assay⁸. Captured proteins can be probed for known GEFs by detection with specific antibodies using Western blotting, or analyzed by Mass Spectrometry to identify unknown GEFs activated by certain stimuli.     

The DSL1 complex: the smallest but not the least CATCHR

The DSL1 complex is a conserved tethering complex at the endoplasmic reticulum that recognizes Golgi-derived COPI vesicles and hands them over to the fusion machinery. The DSL1 complex is the simplest tethering complex of the complexes associated with tethering containing helical rods (CATCHR) family. CATCHR tethering complexes play a role at compartments along the exocytic and endocytic pathways. In this review, different functions of the DSL1 complex are discussed, some open questions with the seemingly straightforward picture are pointed out and alternative functions of the DSL1 complex members are mentioned.     

Up-regulation of BMP-2 antagonizes TGF-β1/ROCK-enhanced cardiac fibrotic signalling through activation of Smurf1/Smad6 complex

Rho‐associated kinase (ROCK) plays a critical role in pressure overload‐induced left ventricular remodelling. However, the underlying mechanism remains unclear. Here, we reported that TGF‐β1‐induced ROCK elevation suppressed BMP‐2 level and strengthened fibrotic response. Exogenous BMP‐2 supply effectively attenuated TGF‐β1 signalling pathway through Smad6‐Smurf‐1 complex activation. In vitro cultured cardiomyocytes, mechanical stretch up‐regulated cardiac TGF‐β1, TGF‐β1‐dependent ROCK and down‐regulated BMP‐2, but BMP‐2 level could be reversed through blocking TGF‐β1 receptor by SB‐431542 or inhibition of ROCK by Y‐27632. TGF‐β1 could also activate ROCK and suppress endogenous BMP‐2 level in a dose‐dependent manner. Knock‐down BMP‐2 enhanced TGF‐β1‐mediated PKC‐δ and Smad3 signalling cascades. In contrast, treatment with Y‐27632 or SB‐431542, respectively suppressed ROCK‐dependent PKC‐δ and Smad3 activation, but BMP‐2 was only up‐regulated by Y‐27632. In addition, BMP‐2 silencing abolished the effect of Y‐27632, but not SB‐431542 on suppression of TGF‐β1 pathway. Further experiments showed that Smad6 Smurf1 interaction were required for BMP‐2‐evoked antagonizing effects. Smad6 overexpression attenuated TGF‐β1‐induced activation of PKC‐δ and Smad3, promoted TGF‐β RI degradation in BMP‐2 knock‐down cardiomyocytes, and could be abolished after knocking‐down Smurf‐1, in which Smad6/Smurf1 complex formation was critically involved. In vivo data showed that pressure overload‐induced collagen deposition was attenuated, cardiac function was improved and TGF‐β1‐dependent activation of PKC‐δ and Smad3 was reduced after 2 weeks treatment with rhBMP‐2(0.5 mg/kg) or Y‐27632 (10 mg/kg) in mice that underwent surgical transverse aortic constriction. In conclusion, we propose that BMP‐2, as a novel fibrosis antagonizing cytokine, may have potential beneficial effect in attenuating pressure overload‐induced cardiac fibrosis.     

ω-3 多不饱和脂肪酸对肿瘤细胞Rho GTP 酶翻译后修饰的影响

目的:观察ω-3多不饱和脂肪酸(ω-3 Polyunsaturated fatty acid,ω-3 PUFA)对人前列腺癌PC-3细胞和乳腺癌MDA-MB-231细胞Rho蛋白翻译后修饰的影响。方法:60μmol/L的二十碳五烯酸(eicosapentaenoic acid,EPA)和二十二碳六烯酸(docosahex-aenoic acid,DHA)处理PC-3和MDA-MB-231细胞24h后,检测EPA和DHA对法尼基蛋白转移酶活性的影响,对Rho蛋白的法尼基化修饰的影响,对Rho蛋白与GTP结合能力的影响。结果:EPA及DHA均能显著下调PC-3和MDA-MB-231细胞法尼基蛋白转移酶活性(P<0.01),抑制Rho蛋白(RhoA、Rac1、Rac2和Cdc42)的法尼基化修饰(P<0.01),并降低PC-3细胞Rho蛋白(RhoA、Rac1和Cdc42)与GTP的结合能力(P<0.05)。结论:ω-3 PUFA可能通过抑制肿瘤细胞Rho蛋白翻译后修饰,而影响肿瘤细胞的生物学特性。     

Rab 蛋白调控胞内囊泡运输

细胞内各个细胞器之间通过囊泡的膜转运是真核细胞存在的基本。Rab蛋白确保了转运蛋白被运输至正确的目的地。Rab蛋白是小GTP酶中的一大家族,它通过募集其效应物蛋白,其中包括接头蛋白,栓系因子,激酶,磷酸酶以及动力蛋白等,调控了细胞膜的选取,囊泡出芽,去包被,转运以及膜融合等过程。本文主要从Rab蛋白循环着手,依次论述了Rab蛋白在囊泡出芽,去包被,转运和膜融合等过程中起到的作用,从而使读者对Rab蛋白能有一个更加系统的了解。     

Compensatory and long-range changes in picosecond-nanosecond main-chain dynamics upon complex formation: 15N relaxation analysis of the free and bound states of the ubiquitin-like domain of human plexin-B1 and the small GTPase Rac1

The formation of a complex between Rac1 and the cytoplasmic domain of plexin-B1 is one of the first documented cases of a direct interaction between a small guanosine 5′-triphosphatase (GTPase) and a transmembrane receptor. Structural studies have begun to elucidate the role of this interaction for the signal transduction mechanism of plexins. Mapping of the Rac1 GTPase surface that contacts the Rho GTPase binding domain of plexin-B1 by solution NMR spectroscopy confirms the plexin domain as a GTPase effector protein. Regions neighboring the GTPase switch I and II regions are also involved in the interaction and there is considerable interest to examine the changes in protein dynamics that take place upon complex formation. Here we present main-chain nitrogen-15 relaxation measurements for the unbound proteins as well as for the Rho GTPase binding domain and Rac1 proteins in their complexed state. Derived order parameters, S², show that considerable motions are maintained in the bound state of plexin. In fact, some of the changes in S² on binding appear compensatory, exhibiting decreased as well as increased dynamics. Fluctuations in Rac1, already a largely rigid protein on the picosecond-nanosecond timescale, are overall diminished, but isomerization dynamics in the switch I and II regions of the GTPase are retained in the complex and appear to be propagated to the bound plexin domain. Remarkably, fluctuations in the GTPase are attenuated at sites, including helices α6 (the Rho-specific insert helix), α7 and α8, that are spatially distant from the interaction region with plexin. This effect of binding on long-range dynamics appears to be communicated by hinge sites and by subtle conformational changes in the protein. Similar to recent studies on other systems, we suggest that dynamical protein features are affected by allosteric mechanisms. Altered protein fluctuations are likely to prime the Rho GTPase-plexin complex for interactions with additional binding partners.     

Neurite outgrowth is enhanced by laminin-mediated down-regulation of the low affinity neurotrophin receptor, p75NTR

Laminin (LN), an extracellular matrix component, is a key factor in promoting axonal regeneration, coordinately regulating growth in conjunction with trophic signals provided by the neurotrophins, including nerve growth factor (NGF). This study investigated potential interactions between the LN and NGF-mediated signaling pathways in PC12 cells and primary neurons. Neurite outgrowth stimulated by NGF was enhanced on a LN substrate. Western blot analysis of pertinent signal transduction components revealed both enhanced phosphorylation of early signaling intermediates upon co-stimulation, and a LN-induced down-regulation of p75NTR which could be prevented by the addition of integrin inhibitory arginine-glycine-aspartate (RGD) peptides. This p75NTR down-regulation was associated with a LN-mediated up-regulation of PTEN and resulted in a decrease in Rho activity. Studies using over-expression or siRNA-mediated knock-down of PTEN demonstrate a consistent inverse relationship with p75NTR, and the over-expression of p75NTR impaired neurite outgrowth on a LN substrate, as well as resulting in sustained activation of Rho which is inhibitory to neurite outgrowth. p75NTR is documented for its role in the transduction of inhibitory myelin-derived signals, and our results point to extracellular matrix regulation of p75NTR as a potential mechanism to ameliorate inhibitory signaling leading to optimized neurite outgrowth.     

Over-expression of GTP-binding proteins and GTPase activity in mouse astrocyte membranes in response to Theiler's murine encephalomyelitis virus infection

Intracerebral infection with Theiler's murine encephalomyelitis virus (TMEV) induces a demyelinating disease that resembles human multiple sclerosis. In order to delineate the early events in this virus-induced neuroinflammatory disease, we have analyzed global GTPases gene activation following TMEV infection of murine brain astrocytes. DNA hybridization microchip analysis demonstrated that 10 sequences described as GTPbinding proteins and GTPases in different protein databases were over-expressed, in response to this infectious agent in astroglial cells. We have first characterized both the GTP-binding and GTPase activities in uninfected astrocyte membranes from a biochemical point of view. The increase in such activities was further validated in TMEV-infected astrocytes, peaking 2-4 h after infection. Over-expression is also induced by the inflammation-related chemokines interleukin-6 and interferon-gamma but not by interleukin-1alpha or tumor necrosis factor-alpha. From the many GTPases that could be over-expressed we have studied two, because of its biological significance; Ras p21 and the subunit alphai2 of G proteins. Western blots revealed increases in both proteins after infection with TMEV, in accordance with the previous enzymologic results. An increase in the active form of Ras (the GTP bound form) in cell lysates was also confirmed by affinity binding to a glutathione-S-transferase-fusion protein, following TMEV infection. A final demonstration of physiological up-regulation is provided by UV cross-linking of membrane proteins with the hydrolysis-resistant GTP agonist GTP [gamma-(35)S]. This technique allow us to detect, after SDS-PAGE, the increase of two further majoritary GTPbinding proteins with MW of 62 and 49 KDa. A quantitative analysis of four selected genes coding for p21 ras, Galphai2 subunit of protein G, Munc-18 and protein interacting with C kinase 1, was performed by real-time RT-PCR to verify the microarray results. The study of GTPase activity and of the above genes by RT-PCR in brains of sick mice, demonstrated a significative increase in mRNA coding for p21ras and protein interacting with C kinase 1 in vivo. Here we demonstrate that one of the mechanisms triggered by TMEV infection of astrocytes is the up-regulation of proteins related to GTP metabolism, one important signal transduction system in mammalian cells.