Cell type-specific functions of Rho GTPases revealed by gene targeting in mice

Mammalian Rho family GTPases are intracellular signal transducers known to regulate multiple signaling pathways involved in actin organization and cell proliferation. However, previous knowledge of their cellular functions came mostly from studies using a dominant-negative or constitutively active mutant expression approach in various clonal cell lines. Such an approach has increasingly been recognized to impose experimental limitations related to specificity, dosage and/or clonal variation. Recent progress in mammalian Rho GTPase cell biology by gene targeting individual Rho GTPases in mice has provided more convincing evidence of their physiological roles and signaling pathways in diverse primary cells. Although adaptive compensation by related Rho GTPase members remains a potential concern in the gene targeting approach, in many cases these studies enable an elucidation of the unique functions of individual Rho GTPases in different cell types in vivo.     

The p120 family of cell adhesion molecules

p120 is the prototypic member of the p120 subfamily of armadillo-related proteins that includes p0071, delta-catenin/NPRAP, ARVCF and the more distantly related plakophilins 1-3. Like armadillo, beta-catenin and plakoglobin these proteins are involved in mediating cell-cell adhesion. Besides their junctional localization they also reveal a cytoplasmic and nuclear localization. Non-cadherin-associated, cytoplasmic p120 functions in Rho signaling and regulation of cytoskeletal organization and actin dynamics. The nuclear function remains largely unsolved. Some characteristics seem to be shared by the various members of the family but it seems unlikely that p120-related proteins have solely redundant functions and compete for interactions with identical binding partners. Stabilization of cadherins at the membrane seems a common function of p120, p0071, delta-catenin and ARVCF but it is not yet known if and how these proteins confer distinct properties to cellular junctions. Moreover, p0071, NPRAP and ARVCF have a C-terminal PDZ-binding motif that is lacking in p120 pointing to distinct roles of these proteins. PDZ domains are found in a series of proteins involved in establishing cell polarity in epithelial cells. Thus, p120 proteins may not only be master regulators of cadherin abundance and activity but play additional roles in regulating cell polarity. This review focuses on the putative roles of p120 proteins in cell polarity.     

Small G-protein networks: their crosstalk and signal cascades

Small GTP-binding proteins (G-proteins) exist in eukaryotes from yeast to human and constitute a superfamily consisting of more than 100 members. This superfamily is structurally classified into at least five families: the Ras, Rho/Rac/Cdc42, Rab, Sar1/Arf, and Ran families. They play key roles not only in temporal but also in spatial determination of specific cell functions. It has become clear that multiple small G-proteins form signalling cascades that are involved in various cellular functions, such as budding processes of the yeast and regulation of the actin cytoskeleton in fibroblasts. In addition, two distinct small G-proteins regulate specific cellular functions in a cooperative or antagonistic manner. A single small G-protein exerts various biological responses through different downstream effectors. Moreover, some of these downstream effectors sequentially activate further downstream effector proteins. Thus, small G-proteins appear to exert their functions through their mutual crosstalk and multiple downstream effectors in a variety of cellular functions.     

Rho Family GTPase modification and dependence on CAAX motif-signaled posttranslational modification

Rho GTPases (20 human members) comprise a major branch of the Ras superfamily of small GTPases, and aberrant Rho GTPase function has been implicated in oncogenesis and other human diseases. Although many of our current concepts of Rho GTPases are based on the three classical members (RhoA, Rac1, and Cdc42), recent studies have revealed the diversity of biological functions mediated by other family members. A key basis for the functional diversity of Rho GTPases is their association with distinct subcellular compartments, which is dictated in part by three posttranslational modifications signaled by their carboxyl-terminal CAAX (where C represents cysteine, A is an aliphatic amino acid, and X is a terminal amino acid) tetrapeptide motifs. CAAX motifs are substrates for the prenyltransferase-catalyzed addition of either farnesyl or geranylgeranyl isoprenoid lipids, Rce1-catalyzed endoproteolytic cleavage of the AAX amino acids, and Icmt-catalyzed carboxyl methylation of the isoprenylcysteine. We utilized pharmacologic, biochemical, and genetic approaches to determine the sequence requirements and roles of CAAX signal modifications in dictating the subcellular locations and functions of the Rho GTPase family. Although the classical Rho GTPases are modified by geranylgeranylation, we found that a majority of the other Rho GTPases are substrates for farnesyltransferase. We found that the membrane association and/or function of Rho GTPases are differentially dependent on Rce1- and Icmt-mediated modifications. Our results further delineate the sequence requirements for prenyltransferase specificity and functional roles for protein prenylation in Rho GTPase function. We conclude that a majority of Rho GTPases are targets for pharmacologic inhibitors of farnesyltransferase, Rce1, and Icmt.     

RhoD regulates cytoskeletal dynamics via the actin nucleation–promoting factor WASp homologue associated with actin Golgi membranes and microtubules

The Rho GTPases have mainly been studied in association with their roles in the regulation of actin filament organization. These studies have shown that the Rho GTPases are essential for basic cellular processes, such as cell migration, contraction, and division. In this paper, we report that RhoD has a role in the organization of actin dynamics that is distinct from the roles of the better-studied Rho members Cdc42, RhoA, and Rac1. We found that RhoD binds the actin nucleation–promoting factor WASp homologue associated with actin Golgi membranes and microtubules (WHAMM), as well as the related filamin A–binding protein FILIP1. Of these two RhoD-binding proteins, WHAMM was found to bind to the Arp2/3 complex, while FILIP1 bound filamin A. WHAMM was found to act downstream of RhoD in regulating cytoskeletal dynamics. In addition, cells treated with small interfering RNAs for RhoD and WHAMM showed increased cell attachment and decreased cell migration. These major effects on cytoskeletal dynamics indicate that RhoD and its effectors control vital cytoskeleton-driven cellular processes. In agreement with this notion, our data suggest that RhoD coordinates Arp2/3-dependent and FLNa-dependent mechanisms to control the actin filament system, cell adhesion, and cell migration.     

Cellular signaling of Dock family proteins in neural function

Dock180-related proteins are genetically conserved from Drosophila and C. elegans to mammals and are atypical types of guanine–nucleotide exchange factors (GEFs) for Rac and/or Cdc42 of small GTPases of the Rho family. Eleven members of the family occur in mammalian cells, each playing key roles in many aspects of essential cellular functions such as regulation of cytoskeletal organization, phagocytosis, cell migration, polarity formation, and differentiation. This review will summarize the newly accumulated findings concerning the Dock180-related proteins' molecular and cellular functions, emphasizing the roles of these proteins in neuronal cells and glial cells as well as their interactions in the central and peripheral nervous systems.     

Evolution of the Rho family of ras-like GTPases in eukaryotes

GTPases of the Rho family are molecular switches that play important roles in converting and amplifying external signals into cellular effects. Originally demonstrated to control the dynamics of the F-actin cytoskeleton, Rho GTPases have been implicated in many basic cellular processes that influence cell proliferation, differentiation, motility, adhesion, survival, or secretion. To elucidate the evolutionary history of the Rho family, we have analyzed over 20 species covering major eukaryotic clades from unicellular organisms to mammals, including platypus and opossum, and have reconstructed the ontogeny and the chronology of emergence of the different subfamilies. Our data establish that the 20 mammalian Rho members are structured into 8 subfamilies, among which Rac is the founder of the whole family. Rho, Cdc42, RhoUV, and RhoBTB subfamilies appeared before Coelomates and RhoJQ, Cdc42 isoforms, RhoDF, and Rnd emerged in chordates. In vertebrates, gene duplications and retrotranspositions increased the size of each chordate Rho subfamily, whereas RhoH, the last subfamily, arose probably by horizontal gene transfer. Rac1b, a Rac1 isoform generated by alternative splicing, emerged in amniotes, and RhoD, only in therians. Analysis of Rho mRNA expression patterns in mouse tissues shows that recent subfamilies have tissue-specific and low-level expression that supports their implication only in narrow time windows or in differentiated metabolic functions. These findings give a comprehensive view of the evolutionary canvas of the Rho family and provide guides for future structure and evolution studies of other components of Rho signaling pathways, in particular regulators of the RhoGEF family.     

Physiological roles of Rho and Rho effectors in mammals

Rho GTPase is a master regulator controlling cytoskeleton in multiple contexts such as cell migration, adhesion and cytokinesis. Of several Rho GTPases in mammals, the best characterized is the Rho subfamily including ubiquitously expressed RhoA and its homologs RhoB and RhoC. Upon binding GTP, Rho exerts its functions through downstream Rho effectors, such as ROCK, mDia, Citron, PKN, Rhophilin and Rhotekin. Until recently, our knowledge about functions of Rho and Rho effectors came mostly from in vitro studies utilizing cultured cells, and their physiological roles in vivo were largely unknown. However, gene-targeting studies of Rho and its effectors have now unraveled their tissue- and cell-specific roles and provide deeper insight into the physiological function of Rho signaling in vivo. In this article, we briefly describe previous studies of the function of Rho and its effectors in vitro and then review and discuss recent studies on knockout mice of Rho and its effectors.     

植物小G 蛋白功能的研究进展

近年来,小G蛋白的调控途径已经成为人们研究细胞信号转导过程的热点问题。小G蛋白家族包括Ras、Rab、Rho、Arf和Ran亚家族,它们起着许多不同的重要细胞生理作用,例如基因表达、细胞骨架重组装、微管的形成以及囊泡和核孔运输机制。这些小G蛋白作为重要的分子开关,具有一个非常保守的功能区域,即I-IV结构区,它起着关键性作用。从拟南芥(Arabidopsis thaliana)基因组预测分析得出,拟南芥含有93个小G蛋白同源序列,包含Rab、Rho、Arf和Ran亚家族,但没有Ras亚家族。本文主要阐述了迄今在植物中研究小G蛋白各个亚家族功能的最新进展,并对植物、酵母和动物相关的同源蛋白的生理功能进行比较和推测。     

植物小G蛋白功能的研究进展

近年来,小G蛋白的调控途径已经成为人们研究细胞信号转导过程的热点问题.小G蛋白家族包括Ras、Rab、Rho、Arf和Ran亚家族,它们起着许多不同的重要细胞生理作用,例如基因表达、细胞骨架重组装、微管的形成以及囊泡和核孔运输机制.这些小G蛋白作为重要的分子开关,具有一个非常保守的功能区域,即I-Ⅳ结构区,它起着关键性作用.从拟南芥(Arabidopsisthaliana)基因组预测分析得出,拟南芥含有93个小G蛋白同源序列,包含Rab、Rho、Arf和Ran亚家族,但没有Ras亚家族.本文主要阐述了迄今在植物中研究小G蛋白各个亚家族功能的最新进展,并对植物、酵母和动物相关的同 源蛋白的生理功能进行比较和推测.     

Some lessons from the tissue transglutaminase knockout mouse

Transglutaminase 2 (TG2) is an inducible transamidating acyltransferase that catalyzes Ca²⁺-dependent protein modifications. It acts as a G protein in transmembrane signaling and as a cell surface adhesion mediator, this distinguishes it from other members of the transglutaminase family. The sequence motifs and domains revealed in the TG2 structure, can each be assigned distinct cellular functions, including the regulation of cytoskeleton, cell adhesion, and cell death. Though many biological functions of the enzyme have already been described or proposed previously, studies of TG2 null mice by our laboratory during the past years revealed several novel in vivo roles of the protein. In this review we will discuss these novel roles in their biological context.     

Structural insights into semaphorins and their receptors

Ten years ago nothing was known of the three-dimensional structure of members of the semaphorin family of cell guidance cues, nor of their major receptors, the plexins. The structural biology of this cell surface ligand–receptor system has now come of age. Detailed atomic level information is available on the architecture of semaphorin and plexin ectodomains and their recognition complexes. Similarly the structure of the plexin cytoplasmic region, and its interactions with members of the Rho family of small GTPases have been unveiled. These structural analyses, in combination with biochemical, biophysical and cellular studies, have progressed our understanding of this signalling system into the realm of molecular mechanism.     

GEF what? Dock180 and related proteins help Rac to polarize cells in new ways

Rho GTPase activation, which is mediated by guanine nucleotide exchange factors (GEFs), is tightly regulated in time and space. Although Rho GTPases have a significant role in many biological events, they are best known for their ability to restructure the actin cytoskeleton profoundly through the activation of specific downstream effectors. Two distinct families of GEFs for Rho GTPases have been reported so far, based on the features of their catalytic domains: firstly, the classical GEFs, which contain a Dbl homology-pleckstrin homology domain module with GEF activity, and secondly, the Dock180-related GEFs, which contain a Dock homology region-2 domain that catalyzes guanine nucleotide exchange on Rho GTPases. Recent exciting data suggest key roles for the DHR-2 domain-containing GEFs in a wide variety of fundamentally important biological functions, including cell migration, phagocytosis of apoptotic cells, myoblast fusion and neuronal polarization.     

Mammalian Rho GTPases: new insights into their functions from in vivo studies

Rho GTPases are key regulators of cytoskeletal dynamics and affect many cellular processes, including cell polarity, migration, vesicle trafficking and cytokinesis. These proteins are conserved from plants and yeast to mammals, and function by interacting with and stimulating various downstream targets, including actin nucleators, protein kinases and phospholipases. The roles of Rho GTPases have been extensively studied in different mammalian cell types using mainly dominant negative and constitutively active mutants. The recent availability of knockout mice for several members of the Rho family reveals new information about their roles in signalling to the cytoskeleton and in development.     

Extracting Diffusive States of Rho GTPase in Live Cells: Towards In Vivo Biochemistry

Resolving distinct biochemical interaction states when analyzing the trajectories of diffusing proteins in live cells on an individual basis remains challenging because of the limited statistics provided by the relatively short trajectories available experimentally. Here, we introduce a novel, machine-learning based classification methodology, which we call perturbation expectation-maximization (pEM), that simultaneously analyzes a population of protein trajectories to uncover the system of diffusive behaviors which collectively result from distinct biochemical interactions. We validate the performance of pEM in silico and demonstrate that pEM is capable of uncovering the proper number of underlying diffusive states with an accurate characterization of their diffusion properties. We then apply pEM to experimental protein trajectories of Rho GTPases, an integral regulator of cytoskeletal dynamics and cellular homeostasis, in vivo via single particle tracking photo-activated localization microcopy. Remarkably, pEM uncovers 6 distinct diffusive states conserved across various Rho GTPase family members. The variability across family members in the propensities for each diffusive state reveals non-redundant roles in the activation states of RhoA and RhoC. In a resting cell, our results support a model where RhoA is constantly cycling between activation states, with an imbalance of rates favoring an inactive state. RhoC, on the other hand, remains predominantly inactive.     

septin基因家族的研究进展

septin是一个广泛存在于除植物以外所有真核生物中的基因家族。最初认为septin家族是与酵母细胞胞质分裂相关的基因家族。然而随着研究的深入, 人们发现这类基因编码的蛋白质在许多生物体内出现了较大的功能分化, 尤其在哺乳动物细胞中, 他们不仅成员众多, 且参与了细胞分裂、细胞极化、囊泡运输及胞膜重构等多个过程。更引起研究人员重视的是: 最近有大量数据表明, 这一家族的一些成员与肿瘤发生、神经功能障碍和病原微生物感染的过程直接相关。因此, 近年来septin家族的功能研究正逐步成为细胞生物学及病理学研究的新热点。文章将试图从septin基因家族的种类、结构特点、生物学功能及其与人类疾病的关系等方面的研究进展进行综述。