Atypical MAP kinases - new insights and directions from amoeba.

Mitogen-activated protein kinases (MAPKs) have been the focus of many studies over the past several decades, but the understanding of one subgroup of MAPKs, orthologs of MAPK15, known as atypical MAPKs, has lagged behind others. In most organisms, specific activating signals or downstream responses of atypical MAPK signaling pathways have not yet been identified even though these MAPKs are associated with many eukaryotic processes, including cancer and embryonic development. In this Review, we discuss recent studies that are shedding new light on both the regulation and function of atypical MAPKs in different organisms.

An atypical MAPK regulates translocation of a GATA transcription factor in response to chemoattractant stimulation.

The Dictyostelium atypical mitogen-activated protein kinase (MAPK) Erk2 is required for chemotactic responses to cAMP as amoeba undergo multicellular development. In this study, Erk2 was found to be essential for the cAMP-stimulated translocation of the GATA transcription factor GtaC as indicated by the distribution of a GFP-GtaC reporter. Erk2 was also found to be essential for the translocation of GtaC in response to external folate, a foraging signal that directs the chemotaxis of amoeba to bacteria.

MAPK docking motif in the Dictyostelium Gα2 subunit is required for aggregation and transcription factor translocation.

Some G protein alpha subunits contain a mitogen-activated protein kinase (MAPK) docking motif (D-motif) near the amino terminus that can impact cellular responses to external signals. The Dictyostelium Gα2 G protein subunit is required for chemotaxis to cAMP during the onset of multicellular development and this subunit contains a putative D-motif near the amino terminus. The Gα2 subunit D-motif was altered to examine its potential role in chemotaxis and multicellular development.

Mitogen-activated protein kinase regulation of the phosphodiesterase RegA in early development.

Mitogen-activated protein kinase (MAPK) regulation of cAMP-specific phosphodiesterase function has been demonstrated in mammalian cells and suspected to occur in other eukaryotes. Epistasis analysis in the soil amoeba suggests the atypical MAPK Erk2 downregulates the function of the cAMP-specific phosphodiesterase RegA to regulate progression of the developmental life cycle. A putative MAPK docking motif located near a predicted MAPK phosphorylation site was characterized for contributions to RegA function and binding to Erk2 because a similar docking motif has been previously characterized in the mammalian PDE4D phosphodiesterase.

Multiple phosphorylation sites on the RegA phosphodiesterase regulate Dictyostelium development.

In Dictyostelium, the intracellular cAMP-specific phosphodiesterase RegA is a negative regulator of cAMP-dependent protein kinase (PKA), a key determinant in the timing of developmental morphogenesis and spore formation. To assess the role of protein kinases in the regulation of RegA function, this study identified phosphorylation sites on RegA and characterized the role of these modifications through the analysis of phospho-mimetic and phospho-ablative mutations. Mutations affecting residue T676 of RegA, a presumed target of the atypical MAP kinase Erk2, altered the rate of development and impacted cell distribution in chimeric organisms suggesting that phosphorylation of this residue reduces RegA function and regulates cell localization during multicellular development.

Dictyostelium Erk2 is an atypical MAPK required for chemotaxis.

The Dictyostelium genome encodes only two MAPKs, Erk1 and Erk2, and both are expressed during growth and development. Reduced levels of Erk2 expression have been shown previously to restrict cAMP production during development but still allow for chemotactic movement. In this study the erk2 gene was disrupted to eliminate Erk2 function.

Acanthamoeba and Dictyostelium Use Different Foraging Strategies.

Amoeba often use cell movement as a mechanism to find food, such as bacteria, in their environment. The chemotactic movement of the soil amoeba Dictyostelium to folate or other pterin compounds released by bacteria is a well-documented foraging mechanism. Acanthamoeba can also feed on bacteria but relatively little is known about the mechanism(s) by which this amoeba locates bacteria.

The Dictyostelium MAPK ERK1 is phosphorylated in a secondary response to early developmental signaling.

Previous reports have suggested that the two mitogen-activated protein kinases (MAPKs) in Dictyostelium discoideum, ERK1 and ERK2, can be directly activated in response to external cAMP even though these MAPKs play different roles in the developmental life cycle. To better characterize MAPK regulation, the levels of phosphorylated MAPKs were analyzed in response to external signals. Only ERK2 was rapidly phosphorylated in response to the chemoattractants, cAMP and folate.

Loss of cAMP-specific phosphodiesterase rescues spore development in G protein mutant in dictyostelium.

Cyclic AMP (cAMP) is an important intracellular signaling molecule for many G protein-mediated signaling pathways but the specificity of cAMP signaling in cells with multiple signaling pathways is not well-understood. In Dictyostelium, at least two different G protein signaling pathways, mediated by the Gα2 and Gα4 subunits, are involved with cAMP accumulation, spore production, and chemotaxis and the stimulation of these pathways results in the activation of ERK2, a mitogen-activated protein kinase that can down regulate the cAMP-specific phosphodiesterase RegA. The regA gene was disrupted in gα2(−) and gα4(−) cells to determine if the absence of this phosphodiesterase rescues the development of these G protein mutants as it does for erk2(−) mutants.

Role of the Vps9-domain protein RgfA in Dictyostelium chemotaxis and development.

Proteins with a Vps9 domain function as guanine nucleotide exchange factors for Rab proteins and can mediate the uptake of cell surface receptors or other molecules through endocytosis. However, genes encoding these proteins have not been previously studied in cells with robust chemotactic capabilities. Several genes encoding Vps9 domains were identified in the genome of Dictyostelium discoideum, and one of the genes, designated as rgfA (DDB_G0272038), was examined for functions in cell growth, development, and chemotaxis.

MAPKs in development: insights from Dictyostelium signaling pathways.

Mitogen activated protein kinases (MAPKs) play important roles in the development of eukaryotic organisms through the regulation of signal transduction pathways stimulated by external signals. MAPK signaling pathways have been associated with the regulation of cell growth, differentiation, and chemotaxis, indicating MAPKs contribute to a diverse set of developmental processes. In most eukaryotes, the diversity of external signals is likely to far exceed the diversity of MAPKs, suggesting that multiple signaling pathways might share MAPKs.

MAP kinases have different functions in Dictyostelium G protein-mediated signaling.

Extracellular signal regulated kinases (ERKs) are a class of MAP kinases that function in many signaling pathways in eukaryotic cells and in some cases, a single stimulus can activate more than one ERK suggesting functional redundancy or divergence from a common pathway. Dictyostelium discoideum encodes only two MAP kinases, ERK1 and ERK2, that both function during the developmental life cycle. To determine if ERK1 and ERK2 have overlapping functions, chemotactic and developmental phenotypes of erk1(-) and erk2(-) mutants were assessed with respect to G protein-mediated signal transduction pathways.

[Foreign bodies--uncommon causes of GIT injuries].

Injuries to various parts of the digestive tract caused by foreign bodies, frequently deliberately swallowed or inserted using various practics, are less common, however serious injuries. The symptomatology may be vague, credibility is often limited or anamnestic data may be intentionaly missing, which makes the diagnostic process tricky. Undefined, vague signs are related to specificities during the GIT perforation, so called hidden perforation.

G{alpha}5 subunit-mediated signalling requires a D-motif and the MAPK ERK1 in Dictyostelium.

The Dictyostelium Galpha5 subunit has been shown to reduce cell viability, inhibit folate chemotaxis and accelerate tip morphogenesis and gene expression during multicellular development. Alteration of the D-motif (mitogen-activated protein kinase docking site) at the amino terminus of the Galpha 5 subunit or the loss of extracellular signal-regulated kinase (ERK)1 diminished the lethality associated with the overexpression or constitutive activation of the Galpha5 subunit. The amino-terminal D-motif of the Galpha5 subunit was also found to be necessary for the reduced cell size, small aggregate formation and precocious developmental gene expression associated with Galpha5 subunit overexpression.

The Galpha4 G protein subunit interacts with the MAP kinase ERK2 using a D-motif that regulates developmental morphogenesis in Dictyostelium.

G protein Galpha subunits contribute to the specificity of different signal transduction pathways in Dictyostelium discoideum but Galpha subunit-effector interactions have not been previously identified. The requirement of the Dictyostelium Galpha4 subunit for MAP kinase (MAPK) activation and the identification of a putative MAPK docking site (D-motif) in this subunit suggested a possible interaction between the Galpha4 subunit and MAPKs. In vivo association of the Galpha4 subunit and ERK2 was demonstrated by pull-down and co-immunoprecipitation assays.

Developmental morphology and chemotactic responses are dependent on G alpha subunit specificity in Dictyostelium.

Dictyostelium discoideum expresses multiple G alpha subunits but only a single G beta and G gamma subunit suggesting that the specific response to an external signal depends largely on G alpha subunit function or G protein-independent signaling from the receptor. To test the contribution of G alpha subunit functional specificity, the chimeric G alpha subunits, G alpha2/4 and G alpha5/4, were created and analyzed along with wild-type subunits for the ability to substitute for the G alpha4 subunit in mediating responses from folate receptors. The G alpha2/4 subunit, but not the G alpha2 or G alpha5/4 subunits, partly rescued chemotaxis and cGMP accumulation in folate-stimulated g alpha4(-) cells.

A cAMP receptor-like G protein-coupled receptor with roles in growth regulation and development.

Dictyostelium discoideum uses G protein-mediated signal transduction for many vegetative and developmental functions, suggesting the existence of G protein-coupled receptors (GPCRs) other than the four known cyclic adenosine monophosphate (cAMP) receptors (cAR1-4). Sequences of the cAMP receptors were used to identify Dictyostelium genes encoding cAMP receptor-like proteins, CrlA-C. Limited sequence identity between these putative GPCRs and the cAMP receptors suggests the Crl receptors are unlikely to be receptors for cAMP.

Related Galpha subunits play opposing roles during Dictyostelium development.

Of the several known Dictyostelium G protein subunits, the Galpha4 and Galpha5 subunits are the most closely related pair based on phylogenetic analysis and expression patterns, but these subunits perform different roles during development. To investigate potential relationships between these subunits with respect to cell differentiation, chimeric organisms composed of strains lacking or overexpressing either subunit were created and examined for developmental morphogenesis and spore production. Chimeras of galpha4 null and galpha5 null strains or Galpha4 and Galpha5 overexpression strains displayed compensatory morphogenesis, implying that the subunits promote complementary developmental processes.

Activated Galpha subunits can inhibit multiple signal transduction pathways during Dictyostelium development.

Mutations impairing the GTPase activity of G protein Galpha subunits can result in activated Galpha subunits that affect signal transduction and cellular responses and, in some cases, promote tumor formation. An analogous mutation in the Dictyostelium Galpha4 subunit gene (Q200L substitution) was constructed and found to inhibit Galpha4-mediated responses to folic acid, including the accumulation of cyclic nucleotides and chemotactic cell movement. The Galpha4-Q200L subunit also severely inhibited responses to cAMP, including cyclic nucleotide accumulation, cAMP chemotaxis, and cellular aggregation.

Folic acid stimulation of the Galpha4 G protein-mediated signal transduction pathway inhibits anterior prestalk cell development in Dictyostelium.

In Dictyostelium discoideum, several G proteins are known to mediate the transduction of signals that direct chemotactic movement and regulate developmental morphogenesis. The G protein alpha subunit encoded by the Galpha4 gene has been previously shown to be required for chemotactic responses to folic acid, proper developmental morphogenesis, and spore production. In this study, cells overexpressing the wild type Galpha4 gene, due to high copy gene dosage (Galpha4HC), were found to be defective in the ability to form the anterior prestalk cell region, express prespore- and prestalk-cell specific genes, and undergo spore formation.

Mutations in the Dictyostelium heterotrimeric G protein alpha subunit G alpha5 alter the kinetics of tip morphogenesis.

Tip morphogenesis during the Dictyostelium developmental life cycle is a process by which prestalk cells sort to form the anterior region of the multicellular organism. We show that the temporal regulation of this morphological process is dependent on the copy number of the Dictyostelium G alpha5 gene. Tip formation is delayed in aggregates of g alpha5 null mutant cells and accelerated in aggregates overexpressing the G alpha5 gene compared to tip formation in wild-type cells.

The G alpha subunit G alpha 4 couples to pterin receptors and identifies a signaling pathway that is essential for multicellular development in Dictyostelium.

In this paper, we show that the G alpha subunit G alpha 4 couples to pterin receptors and identifies a signalling pathway that is essential for multicellular development in Dictyostelium. G alpha 4 is developmentally regulated, is essential for proper morphogenesis and spore production, and functions cell nonautonomously. We show that G alpha 4 is coupled to receptors (alpha FAR) that activate chemotaxis and adenylyl and guanylyl cyclases in response to folate during the early stages of development and to a late class of folate receptors (beta FAR) that have different specificities for pterins.

Analysis of G alpha 4, a G-protein subunit required for multicellular development in Dictyostelium.

The Dictyostelium G alpha 4 gene encodes a G-protein alpha subunit that is primarily expressed during the multicellular stages of development. g alpha 4 null mutants, created by gene disruption, show aberrant morphological differentiation, reduced levels of prespore gene expression, and a loss of the ability to produce spores. These developmental phenotypes can be rescued by complementation with the wild-type gene.

Identification of Dictyostelium G alpha genes expressed during multicellular development.

Guanine nucleotide-binding protein (G protein)-mediated signal transduction constitutes a common mechanism by which cells receive and respond to a diverse set of environmental signals. Many of the signals involved in the developmental life cycle of the slime mold Dictyostelium have been postulated to be transduced by such pathways and, in some cases, these pathways have been demonstrated to be dependent on specific G proteins. Using the polymerase chain reaction, we have identified two additional Dictyostelium G alpha genes, G alpha 4 and G alpha 5, that are developmentally regulated.