High molecular weight forms of GTP-binding regulatory proteins from the bovine cerebellum

A new form of a low Km GTPase belonging to the family of regulatory GTP-binding G-proteins has been identified in bovine cerebellum. The molecular weight of this G-protein is several times as high as that of other G-proteins known to be alpha beta gamma heterotrimers: i. e., Gs, Gi, Go, transducin and a new G-protein which had recently been isolated in our laboratory from bovine cerebellum. The high molecular weight G-protein is stable against dissociation; its molecular mass does not change after treatment with DTT, colchicine and NaF. Using antibodies against the alpha-subunit of the formerly isolated cerebellar G-protein and the transducin beta-subunit, it was demonstrated that the both immunoreactive subunits are present in the high molecular weight G-protein. The two forms of the cerebellar G-proteins, i. e., "high" and "low molecular weight" ones, differ drastically in terms of the Mg2+ effect on their GTPase activity. Whereas at submicromolar concentrations of Mg2+ the GTPase activity of the former is virtually absent, the GTPase activity of the latter is more elevated in the presence of EDTA than in the presence of Mg2+.     

Light-dependent redistribution of arrestin in vertebrate rods is an energy-independent process governed by protein-protein interactions

In rod photoreceptors, arrestin localizes to the outer segment (OS) in the light and to the inner segment (IS) in the dark. Here, we demonstrate that redistribution of arrestin between these compartments can proceed in ATP-depleted photoreceptors. Translocation of transducin from the IS to the OS also does not require energy, but depletion of ATP or GTP inhibits its reverse movement. A sustained presence of activated rhodopsin is required for sequestering arrestin in the OS, and the rate of arrestin relocalization to the OS is determined by the amount and the phosphorylation status of photolyzed rhodopsin. Interaction of arrestin with microtubules is increased in the dark. Mutations that enhance arrestin-microtubule binding attenuate arrestin translocation to the OS. These results indicate that the distribution of arrestin in rods is controlled by its dynamic interactions with rhodopsin in the OS and microtubules in the IS and that its movement occurs by simple diffusion.     

Direct binding of visual arrestin to microtubules determines the differential subcellular localization of its splice variants in rod photoreceptors

Proper function of visual arrestin is indispensable for rapid signal shut-off in rod photoreceptors. Dramatic light-dependent changes in its subcellular localization are believed to play an important role in light adaptation of photoreceptor cells. Here we show that visual arrestin binds microtubules. The truncated splice variant of visual arrestin, p44, demonstrates dramatically higher affinity for microtubules than the full-length protein (p48). Enhanced microtubule binding of p44 underlies its earlier reported preferential localization to detergent-resistant membranes, where it is anchored via membrane-associated microtubules in a rhodopsin-independent fashion. Experiments with purified proteins demonstrate that arrestin interaction with microtubules is direct and does not require any additional protein partners. Most importantly, arrestin interactions with microtubules and light-activated phosphorylated rhodopsin are mutually exclusive, suggesting that microtubule interaction may play a role in keeping p44 arrestin away from rhodopsin in dark-adapted photoreceptors.     

CD98hc (SLC3A2) participates in fibronectin matrix assembly by mediating integrin signaling

Integrin-dependent assembly of the fibronectin (Fn) matrix plays a central role in vertebrate development. We identify CD98hc, a membrane protein, as an important component of the matrix assembly machinery both in vitro and in vivo. CD98hc was not required for biosynthesis of cellular Fn or the maintenance of the repertoire or affinity of cellular Fn binding integrins, which are important contributors to Fn assembly. Instead, CD98hc was involved in the cell's ability to exert force on the matrix and did so by dint of its capacity to interact with integrins to support downstream signals that lead to activation of RhoA small GTPase. Thus, we identify CD98hc as a membrane protein that enables matrix assembly and establish that it functions by interacting with integrins to support RhoA-driven contractility. CD98hc expression can vary widely; our data show that these variations in CD98hc expression can control the capacity of cells to assemble an Fn matrix, a process important in development, wound healing, and tumorigenesis.     

A Gs-RhoGEF interaction: An old G protein finds a new job

The heterotrimeric G proteins are known to have a variety of downstream effectors, but G_s was long thought to be specifically coupled to adenylyl cyclases. A new study indicates that activated G_s can also directly interact with a guanine nucleotide exchange factor for Rho family small GTPases, PDZ-RhoGEF. This novel interaction mediates activation of the small G protein Cdc42 by G_s-coupled GPCRs, inducing cytoskeletal rearrangements and formation of filopodia-like structures. Furthermore, overexpression of a minimal PDZ-RhoGEF fragment can down-regulate cAMP signaling, suggesting that this effector competes with canonical signaling. This first demonstration that the Gα_s subfamily regulates activity of Rho GTPases extends our understanding of Gα_s activity and establishes RhoGEF coupling as a universal Gα function.

The canonical G protein pathway consists of a cell surface receptor, a heterotrimeric G protein, and an effector protein that controls signaling within the cells. This fundamental paradigm, familiar to every biologist, is rooted in discoveries by the laboratories of Sutherland, Rodbell, and Gilman, which in the 1970s and 1980s dissected biochemical mechanisms of adenylyl cyclase activation by hormones. Their breakthrough came after experiments showing that the G protein G_s is essential to transfer agonist stimulation from the receptor to adenylyl cyclase (1). This G protein consists of the ∼42-kDa α subunit, which binds and hydrolyzes GTP, and the permanently associated dimer of 35-kDa β and ∼10-kDa γ subunits (Gβγ). Their findings helped establish a canonical model in which the agonist-bound receptor causes the G protein to release GDP, and the heterotrimer dissociates into Gα-GTP and free Gβγ; in this state, the G protein can activate its effector (i.e. Gα_s will activate adenylyl cyclase until GTP is hydrolyzed). Although the rod photoreceptor G protein, transducin, was discovered by that time (2), the ubiquitously expressed G_s can be considered the founding member of the G protein family.The subsequent cloning and identification of the other three families (G_i, G_q, and G₁₂) completed the rough map of G protein–mediated transduction. These initial studies suggested that the α subunits were responsible for activation of one type of effector (e.g. Gα_s for adenylyl cyclase and cAMP; Gα_q for phospholipase C, phosphoinositides, and Ca²⁺; and Gα_i for ion channels and inhibition of adenylyl cyclase), whereas the free Gβγ complexes interact with a remarkably large number of binding partners, including some effector enzymes and ion channels (3). Later, Gα₁₂ and Gα₁₃ were found to regulate a distinct type of effectors, the RhoGEFs (4, 5). These multidomain proteins contain pleckstrin homology (PH) domains, which facilitate their membrane localization, and Dbl homology (DH) domains, which catalyze GDP-for-GTP exchange (guanine nucleotide exchange factor; GEF) in the Rho family of small (∼20-kDa) G proteins. At the time, the G₁₂-RhoGEF pathway seemed odd as it contained two G proteins: the receptor-activated “large” G₁₂ class protein and the “small” Rho G protein, which is activated by RhoGEF. However, it was then discovered that Gα_q could activate a RhoGEF called Trio (6), and that Gβγ complexes activate other RhoGEFs, indicating that this pathway, if unusual, is at least popular. Gα_s, however, mostly appeared to be faithful to its originally determined role—to stimulate adenylyl cyclase(s)—possibly contributing to the enduring perception that regulation of a second messenger–generating enzyme is the “real” function of a heterotrimeric G protein.In the current issue of JBC, Castillo-Kauil et al. (7) force a reexamination of the existing canon, presenting data that show Gα_s can also interact with a specific RhoGEF, in this case PDZ-RhoGEF (PRG). The authors made this discovery as part of an examination of the regulation of cell shape by the Rho family. They began by expressing a series of short constructs of three RhoGEF proteins, p115RhoGEF, PRG, and LARG, all of which activated RhoA as expected, promoting cell contraction. However, they noticed that the DH/PH domain of PRG also activated Cdc42 and induced filopodia-like cell protrusions. To investigate which G protein is responsible for activation of this Cdc42-mediated pathway, they overexpressed constitutively active mutants of different Gα subunits. These mutants are stabilized in the active GTP-bound state due to substitution of the glutamine residue crucial for GTP hydrolysis. Surprisingly, the PRG-Cdc42 pathway was stimulated by Gα_sQ227L, the one Gα subtype not known for interaction with RhoGEFs. Furthermore, they showed that binding of PRG to Cdc42 was promoted only by G_s-coupled receptors, and not by G_q- or G_i-coupled GPCRs. The authors then investigated the PRG site responsible for the interaction with Gα_s, narrowing it down to the isolated PRG DH and PH domains and their linker region. A construct encompassing these domains was able to inhibit (i) GPCR-mediated activation of Cdc42, (ii) the Gα_sQ227L-promoted interaction of PRG with Cdc42, and (iii) some protein phosphorylation events downstream of the canonical cAMP pathway. Taken together, their work identifies PRG as a novel effector for G_s; the Gα_s-PRG interaction mediates activation of Rho family protein Cdc42, leading to cytoskeletal remodeling.The unexpected results of Castillo-Kauil et al. open up new opportunities to explore this mechanism at different levels of biology. The experiments described in the paper were performed in vitro using cultured cells, imaging, and pulldown of protein complexes containing the overexpressed Gα_s Q227L mutant. Considering the multitude of G_s-coupled receptors and RhoGEFs in the body (8, 9), it will be important to understand the physiological context where the new G_s-mediated pathway plays a significant role. This will require experimentation in vivo and possibly reevaluation of the phenotypes associated with known pathogenic mutations in Gα_s (GNAS) and other relevant genes. At the molecular level, it would be important to delineate the biochemical mechanisms of Gα_s interaction with PRG. For example, at what stage of the GTP/GDP cycle does Gα_s bind to PRG: in the GTP-bound state, which also activates adenylate cyclase, or in the transition state (i.e. just before the terminal phosphate of GTP is removed)? Indeed, there is precedent for proteins that bind preferentially with the transition state—specifically RGS proteins, which accelerate the GTPase reaction. Another possibility is that, by analogy with p115RhoGEF, which stimulates GTPase activity of Gα₁₂ and Gα₁₃, PRG (and other RhoGEFs with similar DH-PH sequences) can influence interaction of Gα_s with nucleotides, Gβγ, and other partners.Since defining the receptor, G protein, and effector as the three essential members of the G protein pathway, researchers have discovered many additional proteins that regulate the amplitude and duration of the stimulus and/or participate in cross-talk with other signaling circuits. These “new” proteins include arrestins, receptor kinases, nonreceptor exchange factors, GTPase-activating proteins, special chaperones, etc. Thus, in a way, discovering a novel binding partner for a signaling molecule is not as surprising as it would have been 20 years ago. However, the new partner identified by Castillo-Kauil et al. makes the result of extra significance; until now, we knew that three of four G protein subfamilies could regulate Rho GTPases by activating RhoGEFs: G₁₂ and G_q via their α subunits and G_i via the Gβγ subunits (10). The demonstration that the G_s subfamily is no exception shows that activation of RhoGEFs by heterotrimeric G proteins may be a truly universal mechanism (Fig. 1). The significance of this insight is that the multitude of biological processes regulated by Rho-GTPase networks can potentially respond to the entire repertoire of GPCR-mediated stimuli.Open in a separate windowFigure 1.Activation of the Rho family by heterotrimeric G proteins. The Rho family of small GTPases is activated by RhoGEF proteins, some of which can be stimulated by heterotrimeric G proteins. Of four families of heterotrimeric G proteins, three (G₁₂, G_q, and G_i, shown in shades of gray) were known to activate certain RhoGEFs. The new results (highlighted in orange) (7) show that G_s, the G protein known to stimulate production of cAMP, can also stimulate a particular RhoGEF; this suggests that the Rho GTPases can potentially be stimulated by the multitude of signals from the entire class of GPCRs, including those coupled to G_s. IP₃, inositol 1,4,5-trisphosphate.

Funding and additional information—This work was supported in part by National Institutes of Health Grant R56DK119262 (to V. Z. S.). The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article.

Abbreviations—The abbreviations used are:

PH

pleckstrin homology

DH

Dbl homology

GEF

guanine nucleotide exchange factor

PRG

PDZ-RhoGEF

GPCR

G protein–coupled receptor.