Faculty Bibliography

Until recently, studies in this field of signal transduction have involved the 'what' and 'when' of signaling. Who talks to whom and for how long? With the advent of genetically encoded fluorescent proteins, it has become possible to monitor signaling events in living cells in real time. This has added the dimension of 'where' to the study of cellular signaling. This lecture, which is a part of 'Cell Signaling Systems: A Course for Graduate Students,' provides a survey of how green fluorescent protein (GFP)-tagged probes for signaling events have been used to elucidate new pathways, to describe the kinetics of signaling events at the single-cell level, and to reveal upon which subcellular compartments these events take place. Some of the findings confirm previous ones using biochemical techniques, and others have been surprising. Examples include those utilizing protein localization, relocalization, fluorescence recovery after photobleaching (FRAP), and fluorescence resonance energy transfer (FRET). The design of FRET probes is described. The detection of small guanosine triphosphatase (GTPase) signaling in living cells is used as an example to explore the creative and diverse ways investigators have developed to look at this system

Members of the Rho family of small GTPases have been shown to be involved in tumorigenesis and metastasis. Currently, most of the available information on the function of Rho proteins in malignant transformation is based on the use of dominant-negative mutants of these GTPases. The specificity of these dominant-negative mutants is limited however. In this study, we used small interfering RNA directed against either Rac1 or Rac3 to reduce their expression specifically. In line with observations using dominant-negative Rac1 in other cell types, we show that RNA interference-mediated depletion of Rac1 strongly inhibits lamellipodia formation, cell migration and invasion in SNB19 glioblastoma cells. Surprisingly however, Rac1 depletion has a much smaller inhibitory effect on SNB19 cell proliferation and survival. Interestingly, whereas depletion of Rac3 strongly inhibits SNB19 cell invasion, it does not affect lamellipodia formation and has only minor effects on cell migration and proliferation. Similar results were obtained in BT549 breast carcinoma cells. Thus, functional analysis of Rac1 and Rac3 using RNA interference reveals a critical role for these GTPases in the invasive behavior of glioma and breast carcinoma cells

Ras GTPases regulate cellular growth and differentiation and are modulated by myriad stimuli including growth factors, cytokines, antigens, and UV irradiation. Ras GTPases are molecular switches that are active when GTP-bound and inactive when GDP-bound. The ability of these GTPases to signal requires that the GTP-bound form engage downstream effectors, interactions that occur only on the cytosolic surface of cellular membranes. Ras family proteins include H-Ras, N-Ras, K-Ras, and Rap1. Insight into the regulation and signaling properties of these molecules has come largely from in vitro studies relying on cellular extracts prepared following cellular stimulation. Since Ras GTPases are expressed on multiple cellular compartments that include the plasma membrane, vesicles derived from the plasma membrane, and other internal membranes such as the ER and Golgi complex, analysis of how their spatial distribution modulates signaling has remained unknown. We have developed fluorescent, GFP-based probes capable of selectively binding GTP-bound Ras or Rap1 in living cells. We have used these reporters to examine sites of cellular activation of Ras and Rap1 during growth factor stimulation. These studies have revealed new insights into the platforms from which these GTPases signal and have led to the hypothesis that GTPase signaling is modulated in a compartmentalized fashion. Here, we describe the design and implementation of fluorescent probes for Ras and Rap1

Ras proteins associate with cellular membranes by virtue of a series of post-translational modifications of their C-terminal CAAX sequences. The discovery that two of the three enzymes that modify CAAX proteins are restricted to the endoplasmic reticulum led to the recognition that all nascent Ras proteins transit endomembranes en route to the PM (plasma membrane) and that at steady-state N-Ras and H-Ras are highly expressed on the Golgi apparatus. To test the hypothesis that Ras proteins on internal membranes can signal, we developed a fluorescent probe that reports when and where in living cells Ras becomes active. We found that growth factors stimulated rapid and transient activation of Ras on the PM followed by delayed and sustained activation on the Golgi. We mapped one pathway responsible for this activity as involving PLCgamma (phospholipase Cgamma)/DAG (diacylglycerol)+Ca2+/RasGRP1. Using mammalian cells and fission yeast, we have shown that differential localization of activated Ras preferentially activates distinct signalling pathways. In very recent work, we have found that (i) the subcellular localization of K-Ras can be acutely modulated by phosphorylation of its C-terminal hypervariable region by PKC, (ii) among the membranes upon which phosphorylated K-Ras accumulates is the outer mitochondrial membrane and (iii) phosphorylated, internalized K-Ras promotes apoptosis. Thus the signalling output of Ras depends on its subcellular localization

Palmitoylation is postulated to regulate Ras signaling by modulating its intracellular trafficking and membrane microenvironment. The mechanisms by which palmitoylation contributes to these events are poorly understood. Here, we show that dynamic turnover of palmitate regulates the intracellular trafficking of HRas and NRas to and from the Golgi complex by shifting the protein between vesicular and nonvesicular modes of transport. A combination of time-lapse microscopy and photobleaching techniques reveal that in the absence of palmitoylation, GFP-tagged HRas and NRas undergo rapid exchange between the cytosol and ER/Golgi membranes, and that wild-type GFP-HRas and GFP-NRas are recycled to the Golgi complex by a nonvesicular mechanism. Our findings support a model where palmitoylation kinetically traps Ras on membranes, enabling the protein to undergo vesicular transport. We propose that a cycle of depalmitoylation and repalmitoylation regulates the time course and sites of Ras signaling by allowing the protein to be released from the cell surface and rapidly redistributed to intracellular membranes

The CAAX motif at the C terminus of most monomeric GTPases is required for membrane targeting because it signals for a series of three posttranslational modifications that include isoprenylation, endoproteolytic release of the C-terminal- AAX amino acids, and carboxyl methylation of the newly exposed isoprenylcysteine. The individual contributions of these modifications to protein trafficking and function are unknown. To address this issue, we performed a series of experiments with mouse embryonic fibroblasts (MEFs) lacking Rce1 (responsible for removal of the -AAX sequence) or Icmt (responsible for carboxyl methylation of the isoprenylcysteine). In MEFs lacking Rce1 or Icmt, farnesylated Ras proteins were mislocalized. In contrast, the intracellular localizations of geranylgeranylated Rho GTPases were not perturbed. Consistent with the latter finding, RhoGDI binding and actin remodeling were normal in Rce1- and Icmt-deficient cells. Swapping geranylgeranylation for farnesylation on Ras proteins or vice versa on Rho proteins reversed the differential sensitivities to Rce1 and Icmt deficiency. These results suggest that postprenylation CAAX processing is required for proper localization of farnesylated Ras but not geranygeranylated Rho proteins

The G(alpha)o/i-coupled CB1 cannabionoid receptor induces neurite outgrowth in Neuro-2A cells. The mechanisms of signaling through G(alpha)o/i to induce neurite outgrowth were studied. The expression of G(alpha)o/i reduces the stability of its direct interactor protein, Rap1GAPII, by targeting it for ubiquitination and proteasomal degradation. This results in the activation of Rap1. G(alpha)o/i-induced activation of endogenous Rap1 in Neuro-2A cells is blocked by the proteasomal inhibitor lactacystin. G(alpha)o/i stimulates neurite outgrowth that is blocked by the expression of dominant negative Rap1. Expression of Rap1GAPII also blocks the G(alpha)o/i-induced neurite outgrowth and treatment with proteasomal inhibitors potentiates this inhibition. The endogenous G(alpha)o/i-coupled cannabinoid (CB1) receptor in Neuro-2A cells stimulates the degradation of Rap1GAPII; activation of Rap1 and treatment with pertussis toxin or lactacystin blocks these effects. The CB1 receptor-stimulated neurite outgrowth is blocked by treatment with pertussis toxin, small interfering RNA for Rap, lactacystin, and expression of Rap1GAPII. Thus, the G(alpha)o/i-coupled cannabinoid receptor, by regulating the proteasomal degradation of Rap1GAPII, activates Rap1 to induce neurite outgrowth

Peptide deformylase activity was thought to be limited to ribosomal protein synthesis in prokaryotes, where new peptides are initiated with an N-formylated methionine. We describe here a new human peptide deformylase (Homo sapiens PDF, or HsPDF) that is localized to the mitochondria. HsPDF is capable of removing formyl groups from N-terminal methionines of newly synthesized mitochondrial proteins, an activity previously not thought to be necessary in mammalian cells. We show that actinonin, a peptidomimetic antibiotic that inhibits HsPDF, also inhibits the proliferation of 16 human cancer cell lines. We designed and synthesized 33 chemical analogs of actinonin; all of the molecules with potent activity against HsPDF also inhibited tumor cell growth, and vice versa, confirming target specificity. Small interfering RNA inhibition of HsPDF protein expression was also antiproliferative. Actinonin treatment of cells led to a tumor-specific mitochondrial membrane depolarization and ATP depletion in a time- and dose-dependent manner; removal of actinonin led to a recovery of the membrane potential consistent with indirect effects on the electron transport chain. In animal models, oral or parenteral actinonin was well tolerated and inhibited human prostate cancer and lung cancer growth. We conclude that HsPDF is a new human mitochondrial enzyme that may provide a novel selective target for anticancer therapy by use of actinonin-based antibiotics

Subcellular compartmentalization is an emerging paradigm in signaling pathways including the Ras/MAPK pathway. In a recent issue of Developmental Cell, Torii et al. (2004) characterize a new MAPK scaffold, Sef, that resides on the Golgi apparatus, binds active MEK/ERK complexes, and permits signaling to cytosolic substrates but not nuclear targets