Synthesis of poly(methyl methacrylate) and block copolymers by semi-batch nitroxide mediated polymerization

The limits of control of the molecular weight and polymer structure in the semi-batch solution polymerization of methyl methacrylate by NMP are explored.

The protein kinase YakA regulates g-protein-linked signaling responses during growth and development of Dictyostelium

A genetic screen for Dictyostelium mutants that phenotypically resemble cells lacking the G-protein beta-subunit yielded the protein kinase YakA. Like gbeta-null cells, yakA-null cells fail to enter development and display slow growth on bacterial lawns. We created a temperature-sensitive yakA mutant and showed that YakA activity is required not only at the onset but also during development. The yakA-null cells have strong defects in folic acid-induced responses, such as actin polymerization and cGMP accumulation, indicating that they play a role in G-protein-mediated signaling responses. We propose that YakA acts downstream of G-proteins, because cAMP receptors still couple to G-proteins in the yakA mutant. In addition, the previously observed growth arrest induced by overexpression of YakA also occurs in gbeta mutants. We localized YakA-GFP to the cytosol suggesting that YakA may be a functional homolog of its mammalian counterparts Dyrk2 and Dyrk3, a subclass of dual-specificity Yak-related kinases (Dyrk) with unknown function.

Differential developmental expression and cell type specificity of Dictyostelium catalases and their response to oxidative stress and UV-light

Cells of Dictyostelium discoideum are highly resistant to DNA damaging agents such as UV-light, gamma-radiation and chemicals. The genes encoding nucleotide excision repair (NER) and base excision repair (BER) enzymes are rapidly upregulated in response to UV-irradiation and DNA-damaging chemicals, suggesting that this is at least partially responsible for the resistance of this organism to these agents. Although Dictyostelium is also unusually resistant to high concentrations of H(2)O(2), little is known about the response of this organism to oxidative stress. To determine if transcriptional upregulation is a common mechanism for responding to DNA-damaging agents, we have studied the Dictyostelium catalase and Cu/Zn superoxide dismutase antioxidant enzymes. We show that there are two catalase genes and that each is differentially regulated both temporally and spatially during multicellular development. The catA gene is expressed throughout growth and development and its corresponding enzyme is maintained at a steady level. In contrast, the catB gene encodes a larger protein and is only expressed during the final stages of morphogenesis. Cell type fractionation showed that the CatB enzyme is exclusively localized to the prespore cells and the CatA enzyme is found exclusively in the prestalk cells. Each enzyme has a different subcellular localization. The unique developmental timing and cell type distribution suggest that the role for catB in cell differentiation is to protect the dormant spores from oxidative damage. We found that exposure to H(2)O(2) does not result in the induction of the catalase, superoxide dismutase, NER or BER mRNAs. A mutant with greatly reduced levels of catA mRNA and enzyme has greatly increased sensitivity to H(2)O(2) but normal sensitivity to UV. These results indicate that the natural resistance to oxidative stress is not due to an ability to rapidly raise the level of antioxidant or DNA repair enzymes and that the response to UV-light is independent from the response to reactive oxygen compounds.

Molecular basis of localized responses during chemotaxis in amoebae and leukocytes

Free-living amoebae as well as mammalian leukocytes sense chemoattractants with seven helix receptors linked to G-proteins. The cells respond by extending pseudopods and moving in the direction of the highest concentration. Recent studies using GFP-tagged proteins in Dictyostelium have shown that the directional response becomes sharply localized downstream of the receptors and G-proteins but upstream of the actin cytoskeleton. These studies together with the isolation novel genes by insertional mutagenesis in Dictyostelium are leading to a new understanding of chemotaxis in eucaryotic cells.

Two ras genes in Dictyostelium minutum show high sequence homology, but different developmental regulation from Dictyostelium discoideum rasD and rasG genes

The social amoeba Dictyostelium discoideum expresses five ras genes at different stages of development. One of them, DdrasD is expressed during postaggregative development and transcription is induced by extracellular cAMP. A homologue of DdrasD, the DdrasG gene, is expressed exclusively during vegetative growth. We cloned two ras homologues Dmras1 and Dmras2 from the primitive species D. minutum, which show high homology to DdrasD and DdrasG and less homology to the other Ddras genes. In contrast to the DdrasD and DdrasG genes, both the Dmras1 and Dmras2 genes are expressed during the entire course of development. The expression levels are low during growth, increase at the onset of starvation and do not decrease until fruiting bodies have formed. Expression of neither Dmras1 or Dmras2 is regulated by cAMP. So even though the high degree of homology between the ras genes of different species suggests conservation of function, this function is apparently not associated with a specific developmental stage.

Adenylyl cyclase G, an osmosensor controlling germination of Dictyostelium spores

Dictyostelium cells express a G-protein-coupled adenylyl cyclase, ACA, during aggregation and an atypical adenylyl cyclase, ACG, in mature spores. The ACG gene was disrupted by homologous recombination. acg- cells developed into normal fruiting bodies with viable spores, but spore germination was no longer inhibited by high osmolarity, a fairly universal constraint for spore and seed germination. ACG activity, measured in aca-/ACG cells, was strongly stimulated by high osmolarity with optimal stimulation occurring at 200 milliosmolar. RdeC mutants, which display unrestrained protein kinase A (PKA) activity and a cell line, which overexpresses PKA under a prespore specific promoter, germinate very poorly, both at high and low osmolarity. These data indicate that ACG is an osmosensor controlling spore germination through activation of protein kinase A.

Regulation of Dictyostelium adenylylcyclases by morphogen-induced modulation of cytosolic pH or Ca2+ levels

Inhibition of cAMP production and consequent inactivation of protein kinase A (PKA) by the putative morphogen ammonia has been suggested to block culmination and stalk cell differentiation in Dictyostelium. Since other weak bases mimic and weak acids act oppositely to ammonia, its effects were attributed to cytosolic or vesicular alkalinization; the latter resulting in impaired Ca2+ sequestration. We investigated whether weak bases and acids modulate the activity of the two Dictyostelium adenylylcyclases ACA and ACG in a manner consistent with their effects on development. It appeared that ammonia inhibits both ACG activity and ACA activation only transiently and does not significantly affect cAMP levels in slugs. Surprisingly, weak acids inhibit both ACA and ACG permanently, but do not affect secretion of cAMP as was suggested earlier. The effects of weak acids, which reduce cytosolic pH, are consistent with the pH dependence of ACA and ACG. In lysates, basal and GTP gamma S-stimulated ACA activity as well as ACG activity are optimal at pH 8 and are virtually absent below pH 7. ACG activity in cell lysates is completely insensitive to Ca2+, while GTP gamma S-stimulated ACA activity is maximally 50% reduced by supraphysiological Ca2+ concentrations. The observation that weak acids strongly inhibit ACA and ACG while promoting a PKA-dependent process such as stalk cell differentiation suggests that in Dictyostelium PKA can be activated in the absence of cAMP production.

Metabolic pathways for differentiation-inducing factor-1 and their regulation are conserved between closely related Dictyostelium species, but not between distant members of the family

There is suggestive evidence that a conserved signalling system involving differentiation inducing factor-1 (DIF-1) controls stalk cell differentiation in a variety of slime mould species. In the standard laboratory species, Dictyostelium discoideum, DIF-1 is first inactivated by dechlorination catalysed by DIF-1 dechlorinase, then by several hydroxylation events, so that eventually about 12 metabolites are produced. If DIF-1 is used as a signal molecule in other species, they too must be able to metabolize it. We report here that the essentials of DIF-1 metabolism are conserved in D. mucoroides, the closest relative of D. discoideum. Both the dechlorinase and hydroxylase enzymes were present in D. mucoroides, and living cells of both species produced a similar spectrum of metabolites from [3H]DIF-1. Furthermore, DIF-1 dechlorinase was induced by DIF-1, as in D. discoideum, and this induction was repressed by ammonia and cAMP. DIF-1 dechlorinase could not be detected in cell extracts from D. minutum or Polysphondylium violaceum. However, living cells of both species are able to metabolize DIF-1; P. violaceum seems to produce a small amount of the monodechlorinated compound, DIF-3, but all other metabolites from both species appear to be unique. Thus all investigated species can metabolize DIF-1, but the exact route of metabolism is not highly conserved.

Universal signals control slime mold stalk formation

The primitive slime mold Dictyostelium minutum does not display oscillations during aggregation, cannot form migrating slugs, and does not form a prestalk/prespore pattern, all of which are characteristic for development of its advanced relative Dictyostelium discoideum. We used D. minutum to investigate whether slime molds share common mechanisms controlling development. In D. discoideum, the morphogen differentiation inducing factor (DIF) can induce stalk-cell differentiation in vitro. However, stalk formation in vivo is supposedly triggered by local depletion of DIF antagonists such as ammonia or cAMP. A homologue of the D. discoideum stalk gene ecmB was cloned in D. minutum that encodes a 3.4-kb mRNA, and its deduced amino acid sequence shows repeats of 24 amino acids that are characteristic for the D. discoideum ecmB gene. Remarkably, DIF effectively induces expression of the D. minutum ecmB gene and ammonia inhibits its expression. D. discoideum cells were transformed with a construct of the D. minutum ecmB promoter fused to the lacZ reporter gene and showed expression in the stalk, but not in the upper and lower cup of the fruiting body, which also express the D. discoideum ecmB gene. In D. discoideum, the D. minutum ecmB and the ecmB promoter are similarly activated by DIF and repressed by both cAMP and ammonia, suggesting that additional signaling is required for ecmB expression in upper and lower cup cells. Our data indicate that the extracellular signals controlling stalk formation and their intracellular signaling cascades including gene regulatory proteins remained highly conserved during slime mold evolution.