雄激素受体的结构和功能

雄激素受体(AR)属于核受体超家族中的类固醇受体.AR一般由四个结构域组成:N端转录激活区(NTD)、DNA结合区(DBD)、铰链区和配体结合区(LBD).AR的配体,雄激素是主要的内源性性类固醇激素,而更多的研究却表明雄激素在鱼类性分化过程中不起作用,AR在此过程中的作用尚不清楚.本文讨论了雄激素受体的起源、进化,并着重阐述了雄激素受体各个结构域的功能.     

黑素皮质素受体1的结构和功能

黑色素生成反应是受黑素皮质素受体l（MClR）调节的。MClR是G蛋白偶联受体（GPCR）超家族的成员之一,它在表皮和毛囊的黑色素细胞中表达。被促肾上腺皮质激素和α-促黑素激活的MClR,积极地与cAMP信号通路偶联,刺激黑色素合成,它也是褐黑素形成的一个通道。MClR的功能行为与GPCR信号出现的概念一致,包括聚合体偶联到更多的信号通路。另外,MClR也显示了独特的性质,如不寻常的高数量的自然变异通常与表型有关。因此,MClR是研究GPCR功能的一个理想模型。对MClR的结构和功能进行了简要综述。     

NMDA受体通道的结构与功能

近来用分子克隆方法对N-甲基-门冬氨酸受体(NMDA受体)通道的分子结构进行了广泛的研究.这些研究清楚地显示了NMDA受体通道的分子多样性,为NMDA受体通道的在体功能多样性提供了基础.已获得的克隆为研究这些受体通道分布和生理作用提供了有价值的工具.     

胰岛素受体家族的结构与功能研究

胰岛素（insulin）与胰岛素样生长因子-1（IGF-1）分别是由胰岛β细胞和肝细胞分泌的 多肽类激素.它们通过结合并激活位于细胞膜上的受体酪氨酸激酶(RTKs),发挥重要的生理作用. 作为起始信号传导的第一步,胰岛素与IGF-1是如何与各自受体的膜外区域（ectodomain） 结合并进一步激活受体的细胞膜内酪氨酸激酶活性一直属于科学研究的关键基础问题.本文 概述了胰岛素受体家族（IR和IGF-1R）及其配体的结构与功能的特点和关系,并重点介绍 了近年来国内外在胰岛素受体家族复合体结构和功能上的研究手段和取得的突破性进展.     

Immunobiotic Bifidobacteria Strains Modulate Rotavirus Immune Response in Porcine Intestinal Epitheliocytes via Pattern Recognition Receptor Signaling

In this work, we aimed to characterize the antiviral response of an originally established porcine intestinal epithelial cell line (PIE cells) by evaluating the molecular innate immune response to rotavirus (RVs). In addition, we aimed to select immunomodulatory bacteria with antiviral capabilities. PIE cells were inoculated with RVs isolated from different host species and the infective titers and the molecular innate immune response were evaluated. In addition, the protection against RVs infection and the modulation of immune response by different lactic acid bacteria (LAB) strains was studied. The RVs strains OSU (porcine) and UK (bovine) effectively infected PIE cells. Our results also showed that RVs infection in PIE cells triggered TLR3-, RIG-I- and MDA-5-mediated immune responses with activation of IRF3 and NF-κB, induction of IFN-β and up-regulation of the interferon stimulated genes MxA and RNase L. Among the LAB strains tested, Bifidobacterium infantis MCC12 and B. breve MCC1274 significantly reduced RVs titers in infected PIE cells. The beneficial effects of both bifidobacteria were associated with reduction of A20 expression, and improvements of IRF-3 activation, IFN-β production, and MxA and RNase L expressions. These results indicate the value of PIE cells for studying RVs molecular innate immune response in pigs and for the selection of beneficial bacteria with antiviral capabilities.     

核受体转录辅激活蛋白：结构与功能

核受体超家族大体可分为 3个亚类 :(1 )由雌激素 (ｅｓｔｒｏｇｅｎ ,ＥＲ)、孕激素 (ｐｒｏ ｇｅｓｔｉｎ ,ＰＲ)和糖皮质激素 (ｇｌｕｃｏｃｏｒｔｉｃｏｉｄ ,ＧＲ)等类固醇激素受体构成的Ｉ类受体 ;(2 )由甲状腺素 (ｔｈｙｒｏｉｄｈｏｒｍｏｎｅ ,ＴＲ)、维生素Ｄ(ｖｉｔａ ｍｉｎＤ ,ＶＤＲ)、9 顺 /反式视黄酸 (9 ｃｉｓ/ｔｒａｎｓ ｒｅｔｉｎｏｉｃａｃｉｄ ,ＲＸＲ ,ＲＡＲ)等构成的ＩＩ类受体 ;(3)天然配体未知或不需要的孤儿受体。三类核受体的作用方式虽然不同 ,但在结构上却有共同的特点 ,它们的典型结构分为6个部分 ,即Ａ、…     

Identification of a Putative Receptor for Porcine Reproductive and Respiratory Syndrome Virus on Porcine Alveolar Macrophages

To identify the receptor which may determine the macrophage tropism of porcine reproductive and respiratory syndrome virus (PRRSV), monoclonal antibodies (MAbs) against porcine alveolar macrophages (PAM) were produced. Two MAbs (41D3 and 41D5) which completely blocked PRRSV infection of PAM were further characterized. It was found that they reduce the attachment of PRRSV to PAM and immunoprecipitate a 210-kDa membrane protein from PAM. This protein was detected on the cell membranes of PAM but not of PRRSV-nonpermissive cells. A colocalization was found between the reactive sites of MAb 41D3 and PRRSV on PAM membranes. All PRRSV-infected cells in tissues of experimentally infected pigs reacted with MAb 41D3. Taken together, all these data suggest that the identified 210-kDa membrane protein is a putative receptor for PRRSV on porcine macrophages.     

Ganglioside Function in Calcium Homeostasis and Signaling

Ganglioside function in eukaryotic cells encompasses a variety of modulatory interactions related to both development and mature cellular behavior. In relation to the nervous system this includes induction of neurite outgrowth and trophic/neuroprotective phenomena; more generally this applies to ganglioside effects on receptor function, adhesion reactions, and signal transduction mechanisms in neural and extraneural systems. Underlying many of these trophic effects are ganglioside-induced changes in cellular calcium, accomplished through modulation of Ca²⁺ influx channels, Ca²⁺ exchange proteins, and various Ca²⁺-dependent enzymes that are altered through association with gangliosides. A clear distinction needs to be drawn between intrinsic functions of gangliosides as naturally expressed by the cell and activities created by application of exogenous ganglioside(s) that may or may not reflect natural function. This review attempts to summarize findings in this area and point to possible future directions of research.     

Lipid Sorting by Ceramide Structure from Plasma Membrane to ER for the Cholera Toxin Receptor Ganglioside GM1

The glycosphingolipid GM1 binds cholera toxin (CT) on host cells and carries it retrograde from the plasma membrane (PM) through endosomes, the trans-Golgi (TGN), and the endoplasmic reticulum (ER) to induce toxicity. To elucidate how a membrane?lipid can specify trafficking in these pathways, we synthesized GM1 isoforms with alternate ceramide domains and imaged their trafficking in live cells.?Only GM1 with unsaturated acyl chains sorted efficiently from PM to TGN and ER. Toxin binding, which effectively crosslinks GM1 lipids, was dispensable, but membrane cholesterol and the lipid raft-associated proteins actin and flotillin were required. The results implicate a protein-dependent mechanism of lipid sorting by ceramide structure and provide a molecular explanation for the diversity?and specificity of retrograde trafficking by CT in?host cells.     

猪流行性腹泻病毒功能性受体的鉴定

为研究猪氨基肽酶(Porcine Aminopeptidase N,pAPN)是否作为猪流行性腹泻病毒(Porcine epidemic diarrhea virus,PEDV)的细胞感染受体,通过转染技术,使PEDV非容许性细胞MDCK表达pAPN,并用PEDV感染转染细胞。结果发现转染的MDCK细胞可以感染PEDV,并且该病毒可以在转染细胞中连续传代。免疫荧光法鉴定存在病毒抗原。进一步实验证实,抗pAPN血清可以抑制PEDV感染转染的MDCK细胞。这些结果展示转染的MDCK细胞、pAPN表达及PEDV病毒复制之间存在直接联系,证明pAPN是PEDV的细胞感染受体之一。     

乙酰胆碱受体结构与功能的研究进展

乙酰胆碱受体是一种神经递质介导的离子通道受体 ,由 5个同源亚基组成。乙酰胆碱受体包括肌肉型和神经型两种。肌肉型乙酰胆碱受体是肌肉神经传导中的重要媒介物质以及自身免疫疾病重症肌无力的主要免疫原 ,神经型乙酰胆碱受体的突变也可导致某些疾病的发生。扼要介绍了近年来乙酰胆碱受体结构与功能的研究进展。     

Ganglioside GT1b Is a Putative Host Cell Receptor for the Merkel Cell Polyomavirus

The Merkel cell polyomavirus (MCPyV) was identified recently in human Merkel cell carcinomas, an aggressive neuroendocrine skin cancer. Here, we identify a putative host cell receptor for MCPyV. We found that recombinant MCPyV VP1 pentameric capsomeres both hemagglutinated sheep red blood cells and interacted with ganglioside GT1b in a sucrose gradient flotation assay. Structural differences between the analyzed gangliosides suggest that MCPyV VP1 likely interacts with sialic acids on both branches of the GT1b carbohydrate chain. Identification of a potential host cell receptor for MCPyV will aid in the elucidation of its entry mechanism and pathophysiology.Members of the polyomavirus (PyV) family, including simian virus 40 (SV40), murine PyV (mPyV), and BK virus (BKV), bind cell surface gangliosides to initiate infection (2, 8, 11, 15). PyV capsids are assembled from 72 pentamers (capsomeres) of the major coat protein VP1, with the internal proteins VP2 and VP3 buried within the capsids (7, 12). The VP1 pentamer makes direct contact with the carbohydrate portion of the ganglioside (10, 12, 13) and dictates the specificity of virus interaction with the cell. Gangliosides are glycolipids that contain a ceramide domain inserted into the plasma membrane and a carbohydrate domain that directly binds the virus. Specifically, SV40 binds to ganglioside GM1 (2, 10, 15), mPyV binds to gangliosides GD1a and GT1b (11, 15), and BKV binds to gangliosides GD1b and GT1b (8).Recently, a new human PyV designated Merkel cell PyV (MCPyV) was identified in Merkel cell carcinomas, a rare but aggressive skin cancer of neuroendocrine origin (3). It is as yet unclear whether MCPyV is the causative agent of Merkel cell carcinomas (17). A key to understanding the infectious and transforming properties of MCPyV is the elucidation of its cellular entry pathway. In this study, we identify a putative host cell receptor for MCPyV.Because an intact infectious MCPyV has not yet been isolated, we generated recombinant MCPyV VP1 pentamers in order to characterize cellular factors that bind to MCPyV. VP1 capsomeres have been previously shown to be equivalent to virus with respect to hemagglutination properties (4, 16), and the atomic structure of VP1 bound to sialyllactose has demonstrated that the capsomere is sufficient for this interaction (12, 13). The MCPyV VP1 protein (strain w162) was expressed and purified as described previously (1, 6). Briefly, a glutathione S-transferase-MCPyV VP1 fusion protein was expressed in Escherichia coli and purified using glutathione-Sepharose affinity chromatography. The fusion protein was eluted using glutathione and cleaved in solution with thrombin. The thrombin-cleaved sample was then rechromatographed on a second glutathione-Sepharose column to remove glutathione transferase and any uncleaved protein. The unbound VP1 was then chromatographed on a P-11 phosphocellulose column, and peak fractions eluting between 400 and 450 mM NaCl were collected. The purified protein was analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), followed by Coomassie blue staining (Fig. ​(Fig.1A,1A, left) and immunoblotting using an antibody (I58) that generally recognizes PyV VP1 proteins (Fig. ​(Fig.1A,1A, right) (9). Transmission electron microscopy (Philips CM10) analysis confirmed that the purified recombinant MCPyV VP1 formed pentamers (capsomeres), which did not assemble further into virus-like particles (Fig. ​(Fig.1B).1B). In an initial screening of its cell binding properties, we tested whether the MCPyV VP1 pentamers hemagglutinated red blood cells (RBCs). The MCPyV VP1 pentamers were incubated with sheep RBCs and assayed as previously described (5). SV40 and mPyV recombinant VP1 pentamers served as negative and positive controls, respectively. We found that MCPyV VP1 hemagglutinated the RBCs with the same efficiency as mPyV VP1 (protein concentration/hemagglutination unit) (Fig. ​(Fig.1C,1C, compare rows B and C from wells 1 to 11), suggesting that MCPyV VP1 engages a plasma membrane receptor on the RBCs. The recombinant murine VP1 protein used for comparison was from the RA strain, a small plaque virus (4). Thus, MCPyV VP1 has the hemagglutination characteristics of a small plaque mPyV (12, 13).Open in a separate windowFIG. 1.Characterization of MCPyV VP1. Recombinant MCPyV VP1 forms pentamers and hemagglutinates sheep RBCs. (A) Coomassie blue-stained SDS-PAGE and an immunoblot of the purified recombinant MCPyV VP1 protein are shown. Molecular mass markers are indicated. (B) Electron micrograph of the purified MCPyV VP1. MCPyV VP1 (shown in panel A) was diluted to 100 μg/ml and absorbed onto Formvar/carbon-coated copper grids. Samples were washed with phosphate-buffered saline, stained with 1% uranyl acetate, and visualized by transmission electron microscopy at 80 kV. Bar = 20 nm. (C) Sheep RBCs (0.5%) were incubated with decreasing concentrations of purified recombinant SV40 VP1 (row A), mPyV VP1 (row B), and MCPyV VP1 (row C). Wells 1 to 11 contain twofold serial dilutions of protein, starting at 2 μg/ml (well 1). Well 12 contains buffer only and serves as a negative control. Well 7 (rows B and C) corresponds to 128 hemagglutination units per 2 μg/ml VP1 protein.To characterize the chemical nature of the putative receptor for MCPyV, total membranes from RBCs were purified as described previously (15). The plasma membranes (30 μg) were incubated with MCPyV VP1 (0.5 μg) and floated on a discontinuous sucrose gradient (15). After fractionation, the samples were analyzed by SDS-PAGE, followed by immunoblotting with I58. VP1 was found in the bottom of the gradient in the absence of the plasma membranes (Fig. ​(Fig.2A,2A, first panel). In the presence of plasma membranes, a fraction of the VP1 floated to the middle of the gradient (Fig. ​(Fig.2A,2A, second panel), supporting the hemagglutination results that suggested that MCPyV VP1 binds to a receptor on the plasma membrane.Open in a separate windowFIG. 2.MCPyV VP1 binds to a protease-resistant, sialic acid-containing receptor on the plasma membrane. (A) Purified recombinant MCPyV VP1 was incubated with or without the indicated plasma membranes. The samples were floated in a discontinuous sucrose gradient, and the fractions were collected from the top of the gradient, subjected to SDS-PAGE, and immunoblotted with the anti-VP1 antibody I58. (B) Control and proteinase K-treated plasma membranes were subjected to SDS-PAGE, followed by Coomassie blue staining. (C) HeLa cells treated with proteinase K (4 μg/ml) were incubated with MCPyV at 4°C, and the resulting cell lysate was probed for the presence of MCPyV VP1. (D) As described in the legend to panel C, except 293T cells were used. (E) Purified MCPyV VP1 was incubated with plasma membranes pretreated with or without α2-3,6,8 neuraminidase and analyzed as described in the legend to panel A.To determine whether the receptor is a protein or a lipid, plasma membrane preparations (30 μg) were incubated with proteinase K (Sigma), followed by analysis with SDS-PAGE and Coomassie blue staining. Under these conditions, the majority of the proteins in the plasma membranes were degraded by the protease (Fig. ​(Fig.2B,2B, compare lanes 1 and 2). Despite the lack of proteins, the proteinase K-treated plasma membranes bound MCPyV VP1 as efficiently as control plasma membranes (Fig. ​(Fig.2A,2A, compare the second and third panels), demonstrating that MCPyV VP1 interacts with a protease-resistant receptor. The absence of VP1 in the bottom fraction in Fig. ​Fig.2A2A (third panel) is consistent with the fact that the buoyant density of the membranes is lowered by proteolysis. Of note, a similar result was seen with binding of the mPyV to the plasma membrane (15). Binding of MCPyV to the cell surface of two human tissue culture cells (i.e., HeLa and 293T) was also largely unaffected by pretreatment of the cells with proteinase K (Fig. 2C and D, compare lanes 1 and 2), further indicating that a nonproteinaceous molecule on the plasma membrane engages the virus.We next determined whether the protease-resistant receptor contains a sialic acid modification. Plasma membranes (10 μg) were incubated with a neuraminidase (α2-3,6,8 neuraminidase; Calbiochem) to remove the sialic acid groups. In contrast to the control plasma membranes, the neuraminidase-treated membranes did not bind MCPyV VP1 (Fig. ​(Fig.2E,2E, compare first and second panels), indicating that the MCPyV receptor includes a sialic acid modification.Gangliosides are lipids that contain sialic acid modifications. We asked if MCPyV VP1 binds to gangliosides similar to other PyV family members. The structures of the gangliosides used in this analysis (gangliosides GM1, GD1a, GD1b, and GT1b) are depicted in Fig. ​Fig.3A.3A. To assess a possible ganglioside-VP1 interaction, we employed a liposome flotation assay established previously (15). When liposomes (consisting of phosphatidyl-choline [19 μl of 10 mg/ml], -ethanolamine [5 μl of 10 mg/ml], -serine [1 μl of 10 mg/ml], and -inositol [3 μl of 10 mg/ml]) were incubated with MCPyV VP1 and subjected to the sucrose flotation assay, the VP1 remained in the bottom fraction (Fig. ​(Fig.3B,3B, first panel), indicating that VP1 does not interact with these phospholipids. However, when liposomes containing GT1b (1 μl of 1 mM), but not GM1 (1 μl of 1 mM) or GD1a (1 μl of 1 mM), were incubated with MCPyV VP1, the vesicles bound this VP1 (Fig. ​(Fig.3B).3B). A low level of virus floated partially when incubated with liposomes containing GD1b (Fig. ​(Fig.3B),3B), perhaps reflecting a weak affinity between MCPyV and GD1b. Importantly, MCPyV binds less efficiently to neuraminidase-treated GT1b-containing liposomes than to GT1b-containing liposomes (Fig. ​(Fig.3B,3B, sixth panel), suggesting that the GT1b sialic acids are involved in virus binding. This finding is consistent with the ability of neuraminidase to block MCPyV binding to the plasma membrane (Fig. ​(Fig.2E).2E). The level of virus flotation observed in the neuraminidase-treated GT1b-containing liposomes is likely due to the inefficiency of the neuraminidase reaction with a high concentration of GT1b used to prepare the vesicles.Open in a separate windowFIG. 3.MCPyV VP1 binds to ganglioside GT1b. (A) Structures of gangliosides GM1, GD1a, GD1b, and GT1b. The nature of the glycosidic linkages is indicated. (B) Purified MCPyV VP1 protein was incubated with liposomes only or with liposomes containing the indicated gangliosides. The samples were analyzed as described in the legend to Fig. ​Fig.2A.2A. Where indicated, GT1b-containing liposomes were pretreated with α2-3,6,8 neuraminidase and analyzed subsequently for virus binding. (C to E) The indicated viruses were incubated with liposomes and analyzed as described in the legend to panel B.As controls, GM1-containing liposomes bound SV40 (Fig. ​(Fig.3C),3C), GD1a-containing liposomes bound mPyV (Fig. ​(Fig.3D),3D), and GD1b-containing liposomes bound BKV (Fig. ​(Fig.3E),3E), demonstrating that the liposomes were functionally intact. We note that, while all of the MCPyV VP1 floated when incubated with liposomes containing GT1b (Fig. ​(Fig.3B,3B, sixth panel), a significant fraction of SV40, mPyV, and BKV VP1 remained in the bottom fraction despite being incubated with liposomes containing their respective ganglioside receptors (Fig. 3C to E, second panels). This result is likely due to the fact that in contrast to MCPyV, which are assembled as pentamers (Fig. ​(Fig.1B),1B), the SV40, mPyV, and BKV used in these experiments are fully assembled particles: their larger and denser nature prevents efficient flotation. Nonetheless, we conclude that MCPyV VP1 binds to ganglioside GT1b efficiently.The observation that GD1a does not bind to MCPyV VP1 suggests that the monosialic acid modification on the right branch of GT1b (Fig. ​(Fig.3A)3A) is insufficient for binding. Similarly, the failure of GD1b to bind MCPyV VP1 suggests that the sialic acid on the left arm of GT1b is necessary for binding. Together, these observations suggest that MCPyV VP1 interacts with sialic acids on both branches of GT1b (Fig. ​(Fig.4).4). A recent structure of SV40 VP1 in complex with the sugar portion of GM1 (10) demonstrated that although SV40 VP1 binds both branches of GM1 (Fig. ​(Fig.4),4), only a single sialic acid in GM1 is involved in this interaction. In the case of mPyV, structures of mPyV VP1 in complex with different carbohydrates (12, 13) revealed that the sialic acid-galactose moiety on the left branch of GD1a (and GT1b) is sufficient for mPyV VP1 binding (Fig. ​(Fig.4).4). Although no structure of BKV in complex with the sugar portion of GD1b (or GT1b) is available, in vitro binding studies (8) have suggested that the disialic acid modification on the right branch of GD1b (and GT1b) is responsible for binding BKV VP1 (Fig. ​(Fig.4).4). Thus, it appears that the unique feature of the MCPyV VP1-GT1b interaction is that the sialic acids on both branches of this ganglioside are likely involved in capsid binding.Open in a separate windowFIG. 4.A potential model of the different VP1-ganglioside interactions (see the text for discussion).The identification of a potential cellular receptor for MCPyV will facilitate the study of its entry mechanism. An important issue for further study is to determine whether MCPyV targets Merkel cells preferentially, and if so, whether GT1b is found in higher levels in these cells to increase susceptibility.     

SDF-1和及其受体CXCR4的结构与功能

近年基质细胞衍生因子 1(SDF 1)及其受体CXCR4的构效关系与相互作用机制研究进展很快 .研究证实 ,SDF 1N末端 (Nt)氨基酸残基是与CXCR4相互作用的关键区域 .SDF 1的 β链与蛋白聚糖 (GAG)作用而调节SDF 1的功能 ,C端α螺旋有助于维持SDF 1的活性构象 ;CXCR4Nt、ECL2和 (或 )ECL3对于SDF 1和HIVgp12 0对CXCR4的识别和激活都很重要 ,但在识别序列上存在部分交叉重叠 .SDF 1 CXCR4与肿瘤转移密切相关 ,本文还就SDF 1与CXCR4在肿瘤治疗方面的应用进行了讨论 .     

IL－6受体结构与功能的研究进展

ＩＬ－６是一个多功能的细胞因子,其生物学作用在很大程度上受ＩＬ－６受体（ＩＬ－６Ｒ）结构和功能的影响。ＩＬ－６Ｒ由两条多肽链组成,即配体结合链ｇｐ８０和信号传导链ｇｐ１３０。它们在结构和功能上既有分工又有合作。两种亚基组成的高和力ＩＬ－６Ｒ是介导细胞效应所必需的。ＩＬ－６Ｒα中的造血功能区属于造血因子受体超家族成员,它决定着结合ＩＬ－６的能力,然而ｇｐ１３０则是多种细胞因子共用的信号传递分子,其胞     

IL－6受体结构与功能的研究进展

IL-6是一个多功能的细胞因子,其生物学作用在很大程度上受IL-6受体(IL-6R)结构和功能的影响.IL-6R由两条多肽链组成,即配体结合链gp80和信号传导链gp130.它们在结构和功能上既有分工又有合作.两种亚基组成的高亲和力IL-6R是介导细胞效应所必需的.IL-6Rα中的造血功能区属于造血因子受体超家族成员,它决定着结合IL-6的能力.然而gp130则是多种细胞因子共用的信号传递分子,其胞内段含有与酪氨酸激酶活化有关的保守成分.IL-6+IL-6R复合物通过诱导gp130的聚合来活化胞内的多种激酶分子和转录因子并最终导致有关基因的表达.     

Structure and Function of the Intracellular Region of the Plexin-B1 Transmembrane Receptor

Members of the plexin family are unique transmembrane receptors in that they interact directly with Rho family small GTPases; moreover, they contain a GTPase-activating protein (GAP) domain for R-Ras, which is crucial for plexin-mediated regulation of cell motility. However, the functional role and structural basis of the interactions between the different intracellular domains of plexins remained unclear. Here we present the 2.4 Å crystal structure of the complete intracellular region of human plexin-B1. The structure is monomeric and reveals that the GAP domain is folded into one structure from two segments, separated by the Rho GTPase binding domain (RBD). The RBD is not dimerized, as observed previously. Instead, binding of a conserved loop region appears to compete with dimerization and anchors the RBD to the GAP domain. Cell-based assays on mutant proteins confirm the functional importance of this coupling loop. Molecular modeling based on structural homology to p120^GAP·H-Ras suggests that Ras GTPases can bind to the plexin GAP region. Experimentally, we show that the monomeric intracellular plexin-B1 binds R-Ras but not H-Ras. These findings suggest that the monomeric form of the intracellular region is primed for GAP activity and extend a model for plexin activation.