Intracellular localization of the P21rho proteins.

The three mammalian ras proteins associated specifically with the plasma membrane and this is essential for their biological activity. Two signals encoded within the extreme COOH terminus of the proteins specify this cellular localization; a CAAX box in combination with either a polybasic domain (p21K-rasB) or a palmitoylation site (p21Ha-ras and p21N-ras). All members of the ras-like and rho-like subfamilies of the ras superfamily of small GTP-binding proteins also have CAAX boxes with potential second site sequences resembling either p21K-rasB or P21N-ras/Ha-ras. However it is not at all clear that they are each located at the plasma membrane, and in fact one of the ras-like proteins, rap1, has been localized to the Golgi (Beranger et al., 1991). None of the mammalian rho-like subfamily has yet been localized. Three forms (A, B, and C) of p21rho, the prototype of this family are known; the COOH termini of p21rhoA and p21rhoC resemble p21K-rasB with a polybasic domain, whereas p21rhoB resembles p21N-ras/Ha-ras with two cysteine residues as potential palmitoylation sites. Despite this similarity to the p21ras proteins, rho proteins have been purified from both particulate and cytosolic fractions of a variety of tissues. In order to localize definitively the three rho proteins we have used an epitope tagging approach coupled to microinjection of living cells. We show that a small fraction of all three proteins is localized to the plasma membrane but the majority of p21rhoA and p21rhoC is cytosolic whereas p21rhoB is associated with early endosomes and a pre-lysosomal compartment. Along with the results obtained with chimeric molecules using heterologous proteins attached to rho COOH termini, this suggests that the p21rho proteins cycle on and off the plasma membrane and this may have important implications for their biological function.

Microinjection of recombinant p21rho induces rapid changes in cell morphology.

The rho proteins, p21rho, are ubiquitously expressed guanine nucleotide binding proteins with approximately 30% amino acid homology to p21ras, but their biochemical function is unknown. We show here that microinjection of constitutively activated recombinant rho protein (Val14rho) into subconfluent cells induces dramatic changes in cell morphology: 15-30 min after injection cells adopt a distinct and novel phenotype with a contracted cell body and finger-like processes still adherent to the substratum. Ribosylation of Val14rho with the ADP-ribosyltransferase C3 from clostridium botulinum, before microinjection, renders the protein biologically inactive, but it has no effect on either its intrinsic biochemical properties or on its interaction with the GTPase activating protein, rho GAP. Micro-injection of ribosylated normal rho, on the other hand, has a similar effect of injection of C3 transferase and induces complete rounding up of cells. We also report striking biochemical changes in actin filament organization when contact-inhibited quiescent 3T3 cells are injected with Val14rho protein. The effects induced by activation or inactivation of p21rho described here, suggest that the biological function of this protein is to control some aspect of cytoskeletal organization.

Real time fluorescence imaging of PLC gamma translocation and its interaction with the epidermal growth factor receptor.

The translocation of fluorescently tagged PLC gamma and requirements for this process in cells stimulated with EGF were analyzed using real time fluorescence microscopy applied for the first time to monitor growth factor receptor--effector interactions. The translocation of PLC gamma to the plasma membrane required the functional Src homology 2 domains and was not affected by mutations in the pleckstrin homology domain or inhibition of phosphatidylinositol (PI) 3-kinase. An array of domains specific for PLC gamma isoforms was sufficient for this translocation. The dynamics of translocation to the plasma membrane and redistribution of PLC gamma, relative to localization of the EGF receptor and PI 4,5-biphosphate (PI 4,5-P(2)), were shown. Colocalization with the receptor was observed in the plasma membrane and in membrane ruffles where PI 4,5-P(2) substrate could also be visualized. At later times, internalization of PLC gamma, which could lead to separation from the substrate, was observed. The data support a direct binding of PLC gamma to the receptor as the main site of the plasma membrane recruitment. The presence of PLC gamma in membrane structures and its access to the substrate appear to be transient and are followed by a rapid incorporation into intracellular vesicles, leading to downregulation of the PLC activity.

Nuclear export of the stress-activated protein kinase p38 mediated by its substrate MAPKAP kinase-2.

BACKGROUND: Mitogen-activated protein (MAP) kinases (or extracellular signal regulated kinases; Erks) and stress-activated protein (SAP) kinases mediate cellular responses to a wide variety of signals. In the Erk MAP kinase pathway, activation of MAP kinases takes place in the cytoplasm and the activated enzyme moves to the nucleus. This translocation to the nucleus is essential to MAP kinase signalling because it enables the kinase to phosphorylate transcription factors. Whether components of the pathway mediated by the SAP kinase p38 change their cellular location on activation is not clear; we have therefore studied the cellular localisation of components of this pathway before and after stimulation. RESULTS: The p38 SAP kinase substrate MAP-kinase-activated protein kinase-2 (MAPKAP kinase-2) contains a putative nuclear localisation signal which we show is functional and required for activation by a variety of stimuli. Following phosphorylation of MAPKAP kinase-2, nuclear p38 was exported to the cytoplasm in a complex with MAPKAP kinase-2. Export of MAPKAP kinase-2 required phosphorylation by p38 but did not appear to require the kinase activity of MAPKAP kinase-2. The p38 activators MKK3 and MKK6 were present in both the nucleus and the cytoplasm, consistent with a role in activating p38 in the nucleus. CONCLUSIONS: In the p38 SAP kinase pathway, MAPKAP kinase-2 serves both as an effector of p38 by phosphorylating substrates and as a determinant of cellular localisation of p38. Nuclear export of p38 and MAPKAP kinase-2 may permit them to phosphorylate substrates in the cytoplasm.

Activation of the Ral and phosphatidylinositol 3' kinase signaling pathways by the ras-related protein TC21.

TC21 is a member of the Ras superfamily of small GTP-binding proteins that, like Ras, has been implicated in the regulation of growth-stimulating pathways. We have previously identified the Raf/mitogen-activated protein kinase pathway as a direct TC21 effector pathway required for TC21-induced transformation (M. Rosário, H. F. Paterson, and C. J. Marshall, EMBO J. 18:1270-1279, 1999). In this study we have identified two further effector pathways for TC21, which contribute to TC21-stimulated transformation: the phosphatidylinositol 3' kinase (PI-3K) and Ral signaling pathways. Expression of constitutively active TC21 leads to the activation of Ral A and the PI-3K-dependent activation of Akt/protein kinase B. Strong activation of the PI-3K/Akt pathway is seen even with very low levels of TC21 expression, suggesting that TC21 may be a key small GTPase-regulator of PI-3K. TC21-induced alterations in cellular morphology in NIH 3T3 and PC12 cells are also PI-3K dependent. On the other hand, activation of the Ral pathway by TC21 is required for TC21-stimulated DNA synthesis but not transformed morphology. We show that inhibition of Ral signaling blocks DNA synthesis in human tumor cell lines containing activating mutations in TC21, demonstrating for the first time that this pathway is required for the proliferation of human tumor cells. Finally, we provide mechanisms for the activation of these pathways, namely, the direct in vivo interaction of TC21 with guanine nucleotide exchange factors for Ral, resulting in their translocation to the plasma membrane, and the direct interaction of TC21 with PI-3K. In both cases, the effector domain region of TC21 is required since point mutations in this region can interfere with activation of downstream signaling.

Activated MEK stimulates expression of AP-1 components independently of phosphatidylinositol 3-kinase (PI3-kinase) but requires a PI3-kinase signal To stimulate DNA synthesis.

To investigate the contribution that ERK/mitogen-activated protein kinase signalling makes to cell cycle progression and gene expression, we have constructed cell lines to express an inducible version of activated MEK1. Using these cells, we show that activation of MEK leads to the expression of Fra-1 and Fra-2 but not c-Fos. Treatment of Ras-transformed cells with the MEK inhibitor PD098059 blocks expression of Fra-1 and Fra-2, showing that in Ras transformation ERK signalling is responsible for Fra-1 and Fra-2 expression. Activation of MEK1 in growth-arrested cells leads to DNA synthesis; however, ERK activation alone is insufficient because the induction of DNA synthesis is blocked by inhibition of phosphatidylinositol 3-kinase (PI3-kinase). Activation of PI3-kinase is indirect, perhaps through autocrine growth factors, and is required for the induction of cyclin D1.

CTCF, a conserved nuclear factor required for optimal transcriptional activity of the chicken c-myc gene, is an 11-Zn-finger protein differentially expressed in multiple forms.

A novel sequence-specific DNA-binding protein, CTCF, which interacts with the chicken c-myc gene promoter, has been identified and partially characterized (V. V. Lobanenkov, R. H. Nicolas, V. V. Adler, H. Paterson, E. M. Klenova, A. V. Polotskaja, and G. H. Goodwin, Oncogene 5:1743-1753, 1990). In order to test directly whether binding of CTCF to one specific DNA region of the c-myc promoter is important for chicken c-myc transcription, we have determined which nucleotides within this GC-rich region are responsible for recognition of overlapping sites by CTCF and Sp1-like proteins. Using missing-contact analysis of all four nucleotides in both DNA strands and homogeneous CTCF protein purified by sequence-specific chromatography, we have identified three sets of nucleotides which contact either CTCF or two Sp1-like proteins binding within the same DNA region. Specific mutations of 3 of 15 purines required for CTCF binding were designed to eliminate binding of CTCF without altering the binding of other proteins. Electrophoretic mobility shift assay of nuclear extracts showed that the mutant DNA sequence did not bind CTCF but did bind two Sp1-like proteins. When introduced into a 3.3-kbp-long 5'-flanking noncoding c-myc sequence fused to a reporter CAT gene, the same mutation of the CTCF binding site resulted in 10- and 3-fold reductions, respectively, of transcription in two different (erythroid and myeloid) stably transfected chicken cell lines. Isolation and analysis of the CTCF cDNA encoding an 82-kDa form of CTCF protein shows that DNA-binding domain of CTCF is composed of 11 Zn fingers: 10 are of C2H2 class, and 1 is of C2HC class. CTCF was found to be abundant and conserved in cells of vertebrate species. We detected six major nuclear forms of CTCF protein differentially expressed in different chicken cell lines and tissues. We conclude that isoforms of 11-Zn-finger factor CTCF which are present in chicken hematopoietic HD3 and BM2 cells can act as a positive regulator of the chicken c-myc gene transcription. Possible functions of other CTCF forms are discussed.

Different structural organization of Ras and Rho effector domains.

Ras regulates proliferation and differentiation signals in cells, and activation of the protein can lead to malignant transformation. Activation of the related protein, Rho, affects cell morphology, and it has been suggested that it may also have some oncogenic potential. We show here that Rho does not induce a malignant phenotype in NIH3T3 cells but instead is a potent activator of actin stress fibre formation. The limited homology between Ras and Rho has enabled us to determine the amino acids specifying their different biological activities and GTPase-activating protein (GAP) protein sensitivities using chimeras. Rho substituted with amino acids 23-46 of Ras induces transformed foci in NIH3T3 monolayers, and we conclude that Ras has a single effector domain required for downstream signalling. Although mutational analysis of Rho has revealed that residues 32-42 are also essential for its biological activity, Ras substituted with amino acids 25-48 of Rho does not induce actin stress fibre formation. On the basis of these experiments, we propose that Rho may have two effector domains: one at amino acids 32-42 and corresponding to the effector region of Ras and the second located elsewhere in the carboxy-terminal two-thirds of the molecule.

p21Ras activation by the guanine nucleotide exchange factor Sos, requires the Sos/Grb2 interaction and a second ligand-dependent signal involving the Sos N-terminus.

It has been suggested that a key event in growth factor-induced p21Ras activation by the guanine nucleotide exchange factor Sos, is the recruitment of Sos to the plasma membrane by its interaction with the adaptor protein Grb2. However, other evidence argues that the sub cellular localisation of Sos is independent of Grb2, and that the Sos/Grb2 interaction can be dispensed with for p21Ras activation. To clarify the role of the Sos/Grb2 interaction in ligand-stimulated p21Ras activation, we have utilised the observation that overexpression of the Sos C-terminal domain can effectively inhibit p21Ras-dependent signalling in three different mammalian systems. We have shown that concurrent expression of Grb2, but not SH2 or SH3 domain mutants of Grb2, or the alternative adaptor protein Nck, can rescue this inhibitory effect of the C-terminus. This shows that the Grb2/Sos interaction is required to mediate growth factor-dependent activation of p21Ras, and requires the presence of intact SH2 and SH3 domains of Grb2. This approach was also used for a functional analysis of Sos which revealed that growth factor dependent signals are transmitted through both the N-terminal and C-terminal domains.

Reversion of a human tumour cell line containing oncogenic p21ras is associated with a defect in the post-translational processing of the ras protein.

Correct post-translational modifications of the ras proteins are essential for their membrane localisation and functioning. The flat revertant cell lines 1aCB and 8b, derived from the human bladder carcinoma cell line EJ, contain the transforming gene V12Ha-ras and are resistant to retransformation by ras protein or DNA, but still do require the presence of ras for proliferation. Both revertant cell lines demonstrated reduced levels of membrane associated p21ras when compared to their parental EJ cell lines. This reduced level in 1aCB was reflected by an increase in nuclear associated p21ras, as seen by immunofluorescence of endogenous and introduced ras. In addition, 1aCB had a reduced ratio of ras in the detergent to aqueous phases after triton X114 partitioning, suggesting a defect in Step I processing of the p21ras in the cell line. This was not however due to defects in the Step I enzymes farnesyltransferase or carboxymethyltransferase whose activities were not reduced.

Ultrastructural localization of ras-related proteins using epitope-tagged plasmids.

To determine the ultrastructural distribution of H-ras, the rho proteins rho-A, rho-B, rho-C, and the rac1 protein (members of the ras GTP-binding protein family), we used cDNA expression plasmids in which a short sequence coding for the epitope recognized by the anti c-myc monoclonal antibody 9E10 has been inserted at the N-terminus. Each of the expressed proteins has this epitope as a tag, allowing its localization by light and electron microscopy by the same antibody. After nuclear microinjection of these plasmids into MDCK or Rat 2 cells, expression of the protein (6-18 hr later) was confirmed by immunofluorescence labeling with 9E10 imaged by confocal microscopy. For ultrastructural localization of these tagged proteins, a method was devised to process microinjected cells in situ into low-temperature resin. The proteins were localized on the sections using 9E10 detected with colloidal gold conjugates. Ha-ras protein was localized almost exclusively on the cell membranes. Rho-A and rho-C were predominantly associated with the submembraneous actin network, and rho-B was found in association with multivesicular bodies. Rac1 protein induces the formation of large pinocytotic vesicles and was detected on the cytoplasmic face of these vacuoles. These experiments demonstrate the successful use of this approach for detection of de novo synthesized proteins from microinjected plasmids by both light and electron microscopy on a small (< 50 cells) sample size.

In vivo and in vitro studies on the early embryonic lethal oligosyndactylism (Os) in the mouse.

The development of mouse embryos homozygous for oligosyndactylism (Os) is arrested during implantation. Histological investigations confirm a previous report that cells become blocked in mitosis, and air-dried spreads of the mutant embryos reveal that large numbers of cells accumulate in metaphase. Trophoblastic giant cells appear unaffected by the action of the mutant gene both in utero and during culture over the lethal phase. It is proposed that the form of endoreduplication undergone by giant cells renders them refractory to the metaphase block.

In vivo and in vitro studies on the early embryonic lethal tail-short (Ts) in the mouse.

An histological study reveals that embryos homozygous for the mutation tail-short (Ts) become abnormal as morulae, although a small amount of cell division may continue to take place during the following day. Homozygotes can be identified at 3 1/2 days post coitum (p.c.) by several criteria including low cell number, absence of cavitation, and weak cytoplasmic staining with haematoxylin. A similar pattern of developmental arrest is exhibited during culture, although an initial degree of cavitation occurs more frequently.

Requirement for Ras in Raf activation is overcome by targeting Raf to the plasma membrane.

A conserved tyrosine kinase-activated signal transduction pathway has recently been identified that comprises the plasma membrane-bound small guanine-nucleotide-binding protein Ras and the protein kinases Raf, MAP-kinase kinase and MAP kinase. GTP-bound Ras interacts directly with the amino-terminal regulatory domain of Raf, but although Ras and Raf can be coimmunoprecipitated from ligand-stimulated cells, Ras-GTP does not stimulate the kinase activity of Raf in vitro. Furthermore, we have failed to detect Ras in preparations of active detergent-solubilized Raf, demonstrating that once it is activated, Raf does not require Ras. Whereas Raf is normally cytosolic, in cells expressing active Ras, Raf is associated with the plasma membrane. This led us to investigate whether Ras is required to localize Raf to the plasma membrane in order for Raf to become activated. We fused the membrane localization signal of K-Ras(4B) to the carboxy terminus of Raf. This protein is constitutively active and can be further activated by epidermal growth factor, independently of Ras. Our results indicate that Ras functions as a regulated, membrane-bound anchor for Raf, and that other signal(s) also contribute to Raf activation.

Signals from Ras and Rho GTPases interact to regulate expression of p21Waf1/Cip1.

Small GTPases act as molecular switches in intracellular signal-transduction pathways. In the case of the Ras family of GTPases, one of their most important roles is as regulators of cell proliferation, and the mitogenic response to a variety of growth factors and oncogenes can be blocked by inhibiting Ras function. But in certain situations, activation of Ras signalling pathways arrests the cell cycle rather than causing cell proliferation. Extracellular signals may trigger different cellular responses by activating Ras-dependent signalling pathways to varying degrees. Other signalling pathways could also influence the consequences of Ras signalling. Here we show that when signalling through the Ras-related GTPase Rho is inhibited, constitutively active Ras induces the cyclin-dependent-kinase inhibitor p21Waf1/Cip1 and entry into the DNA-synthesis phase of the cell cycle is blocked. When Rho is active, induction of p21Waf1/Cip1 by Ras is suppressed and Ras induces DNA synthesis. Cells that lack p21Waf1/Cip1 do not require Rho signalling for the induction of DNA synthesis by activated Ras, indicating that, once Ras has become activated, the primary requirement for Rho signalling is the suppression of p21Waf1/Cip1 induction.

Activation of the Raf/MAP kinase cascade by the Ras-related protein TC21 is required for the TC21-mediated transformation of NIH 3T3 cells.

TC21 is a member of the Ras superfamily of small GTP-binding proteins and, like Ras, has been implicated in the regulation of growth-stimulating pathways. Point mutations introduced into TC21 based on equivalent H-Ras oncogenic mutations are transforming in cultured cells, and oncogenic mutations in TC21 have been isolated from several human tumours. The mechanism of TC21 signalling in transformation is poorly understood. While activation of the serine/threonine kinases Raf-1 and B-Raf has been implicated in signalling pathways leading to transformation by H-Ras, it has been argued that TC21 does not activate Raf-1 or B-Raf. Since the Raf-signalling pathway is important in transformation by other Ras proteins, we assessed whether the Raf pathway is important to transformation by TC21. Raf-1 and B-Raf are constitutively active in TC21-transformed cells and the ERK/MAPK cascade is required for the maintenance of the transformed state. We demonstrate that oncogenic V23 TC21, like Ras, interacts with Raf-1 and B-Raf (but not with A-Raf), resulting in the translocation of the Raf proteins to the plasma membrane and in their activation. Furthermore, using point mutations in the effector loop of TC21, we show that the interaction of TC21 with Raf-1 is crucial for transformation.

A neutral magnesium-dependent sphingomyelinase isoform associated with intracellular membranes and reversibly inhibited by reactive oxygen species.

Activation of neutral sphingomyelinase(s) and subsequent generation of ceramide has been implicated in a wide variety of cellular responses. Although this enzyme(s) has not been purified and cloned from higher organisms, one mammalian cDNA has been previously isolated based on its similarity to the bacterial enzyme. To further elucidate the function of this neutral sphingomyelinase, we studied its relationship with enzymes present in mammalian cells and tissues, its subcellular localization, and properties that could be important for the regulation of its activity. Using specific antibodies, it is suggested that the enzyme could represent one of several forms of neutral sphingomyelinases present in the extract from brain particulate fraction. In PC12 cells, the enzyme is localized in the endoplasmic reticulum and is not present in the plasma membrane. The same result has been obtained in several cell lines transfected or microinjected with plasmids encoding this enzyme. The molecular and enzymatic properties of the cloned neutral magnesium-dependent sphingomyelinase, produced using baculovirus or bacterial expression systems, have been analyzed, demonstrating the expected ion dependence and substrate specificity. The enzyme activity also has a strong requirement for reducing agents and is reversibly inhibited by reactive oxygen species and oxidized glutathione. The studies demonstrate that the cellular localization and some properties of this enzyme are distinct from properties previously associated with neutral magnesium-dependent sphingomyelinases in crude or partially purified preparations.

p21H-ras-induced morphological transformation and increases in c-myc expression are independent of functional protein kinase C.

It has previously been demonstrated that efficient DNA synthesis by oncogenic p21H-ras only occurs in the presence of insulin and is absolutely dependent on functional protein kinase C. Here we show that morphological transformation induced by oncogenic p21H-ras does not require functional protein kinase C. The early phases of protein kinase C-independent morphological transformation do not require de novo protein synthesis. We have also demonstrated that the introduction of p21H-ras into quiescent Swiss 3T3 cells by scrape-loading leads to increased levels of c-myc mRNA similar to those seen following serum stimulation. The increases in c-myc mRNA levels induced by p21H-ras are also independent of functional protein kinase C. Both morphological transformation and the elevation of c-myc mRNA levels do not require insulin. These results demonstrate that p21H-ras is generating protein kinase C-dependent and -independent signals.

Differential regulation of Raf-1, A-Raf, and B-Raf by oncogenic ras and tyrosine kinases.

It has previously been shown that maximal activation of Raf-1 is produced by synergistic signals from oncogenic Ras and activated tyrosine kinases. This synergy arises because Ras-GTP translocates Raf-1 to the plasma membrane where it becomes phosphorylated on tyrosine residues 340 and 341 by membrane-bound tyrosine kinases (Marais, R., Light, Y., Paterson, H. F., and Marshall, C. J. (1995) EMBO J. 14, 3136-3145). We have examined whether the other two members of the Raf family, A-Raf and B-Raf, are regulated in a similar way to Raf-1. A-Raf behaves like Raf-1, being weakly activated by oncogenic Ras more strongly activated by oncogenic Src, and these signals synergize to give maximal activation. B-Raf by contrast is strongly activated by oncogenic Ras alone and is not activated by oncogenic Src. These results show that maximal activation of B-Raf merely requires signals that generate Ras-GTP, whereas activation of Raf-1 and A-Raf requires Ras-GTP together with signals that lead to their tyrosine phosphorylation. B-Raf may therefore be the primary target of oncogenic Ras.