Cell adhesion in transformed D. discoideum cells: expression of gp80 and its biochemical characterization

Ethylene as a potent inducer of sexual development

A novel and critical function of ethylene, a potent plant hormone, has been well documented in Dictyostelium, because it leads cells to the sexual development (macrocyst formation) by inducing zygote formation. Zygote formation (sexual cell fusion) and the subsequent nuclear fusion are the characteristic events occurring during macrocyst formation. A novel gene, zyg1 was found to be predominantly expressed during the sexual development, and its enforced expression actually induces zygote formation. As expected, the zygote inducer, ethylene enhances the expression of zyg1. Thus the function of ethylene has been verified at all of individual (macrocyst formation), cellular (zygote formation), and molecular levels (zyg1 expression). Based on our recent studies concerning the behavior and function of the zyg1 product (ZYG1 protein), the signal transduction pathways involved in zygote formation are proposed in this review.

The carboxyl terminus of Dictyostelium discoideum protein 1I encodes a functional glycosyl-phosphatidylinositol signal sequence

The 1I gene is expressed in the prespore cells of culminating Dictyostelium discoideum. The open reading frame of 1I cDNA encodes a protein of 155 amino acids with hydrophobic segments at both its NH(2)- and COOH-termini that are indicative of a glycosyl-phosphatidylinositol (GPI)-anchored protein. A hexaHis-tagged form of 1I expressed in D. discoideum cells appeared on Western blot analysis as a doublet of 27 and 24 kDa, with a minor polypeptide of 22 kDa. None of the polypeptides were released from the cell surface with bacterial phosphatidylinositol-specific phospholipase C, although all three were released upon nitrous acid treatment, indicating the presence of a phospholipase-resistant GPI anchor. Further evidence for the C-terminal sequence of 1I acting as a GPI attachment signal was obtained by replacing the GPI anchor signal sequence of porcine membrane dipeptidase with that from 1I. Two constructs of dipeptidase with the 1I GPI signal sequence were constructed, one of which included an additional six amino acids in the hydrophilic spacer. Both of the resultant constructs were targeted to the surface of COS cells and were GPI-anchored as shown by digestion with phospholipase C, indicating that the Dictyostelium GPI signal sequence is functional in mammalian cells. Site-specific antibodies recognising epitopes either side of the expected GPI anchor attachment site were used to determine the site of GPI anchor attachment in the constructs. These parallel approaches show that the C-terminal signal sequence of 1I can direct the addition of a GPI anchor.

Starvation promotes Dictyostelium development by relieving PufA inhibition of PKA translation through the YakA kinase pathway

When nutrients are depleted, Dictyostelium cells undergo cell cycle arrest and initiate a developmental program that ensures survival. The YakA protein kinase governs this transition by regulating the cell cycle, repressing growth-phase genes and inducing developmental genes. YakA mutants have a shortened cell cycle and do not initiate development. A suppressor of yakA that reverses most of the developmental defects of yakA- cells, but none of their growth defects was identified. The inactivated gene, pufA, encodes a member of the Puf protein family of translational regulators. Upon starvation, pufA- cells develop precociously and overexpress developmentally important proteins, including the catalytic subunit of cAMP-dependent protein kinase, PKA-C. Gel mobility-shift assays using a 200-base segment of PKA-C's mRNA as a probe reveals a complex with wild-type cell extracts, but not with pufA- cell extracts, suggesting the presence of a potential PufA recognition element in the PKA-C mRNA. PKA-C protein levels are low at the times of development when this complex is detectable, whereas when the complex is undetectable PKA-C levels are high. There is also an inverse relationship between PufA and PKA-C protein levels at all times of development in every mutant tested. Furthermore, expression of the putative PufA recognition elements in wild-type cells causes precocious aggregation and PKA-C overexpression, phenocopying a pufA mutation. Finally, YakA function is required for the decline of PufA protein and mRNA levels in the first 4 hours of development. We propose that PufA is a translational regulator that directly controls PKA-C synthesis and that YakA regulates the initiation of development by inhibiting the expression of PufA. Our work also suggests that Puf protein translational regulation evolved prior to the radiation of metazoan species.

YakA, a protein kinase required for the transition from growth to development in Dictyostelium

When Dictyostelium cells starve they arrest their growth and induce the expression of genes necessary for development. We have identified and characterized a protein kinase, YakA, that is essential for the proper regulation of both events. Amino acid sequence and functional similarities indicate that YakA is a homolog of Yak1p, a growth-regulating protein kinase in S. cerevisiae. Purified YakA expressed in E. coli is able to phosphorylate myelin basic protein. YakA-null cells are smaller and their cell cycle is accelerated relative to wild-type cells. When starved, YakA-null cells fail to decrease the expression of the growth-stage gene cprD, and do not induce the expression of genes required for the earliest stages of development. YakA mRNA levels increase during exponential growth and reach a maximum at the point of starvation, consistent with a role in mediating starvation responses. YakA mRNA also accumulates when cells are grown in medium conditioned by cells grown to high density, suggesting that yakA expression is under the control of an extracellular signal that accumulates during growth. Expression of yakA from a conditional promoter causes cell-cycle arrest in nutrient-rich medium and promotes developmental events, such as the expression of genes required for cAMP signaling. YakA appears to regulate the transition from growth to development in Dictyostelium.

Characterization of the Dictyostelium discoideum cellulose-binding protein CelB and regulation of gene expression

Similar to other stages of Dictyostelium development, spore germination is a particularly suitable model for studying regulation of gene expression. The transition from spore to amoeba is accompanied by developmentally regulated changes in both protein and mRNA synthesis. A number of spore germination-specific cDNAs have been isolated previously. Among these are two members of the 270 gene family, a group of four genes defined by the presence of a common tetrapeptide repeat of Thr-Glu-Thr-Pro. celA (formerly called 270-6) and celB (formerly 270-11) are expressed solely and coordinately during spore germination, the levels of the respective mRNAs being low in dormant spores, rising during germination to a maximum level at about 2 h, and then rapidly declining as amoebae are released from spores. The mRNAs are not found in growing cells or during multicellular development. The rapidity with which these transcripts accumulate and then disappear during germination implies that the respective products may be important for the process. We reported previously that the CelA protein is a cellulase (endo-1, 4-beta-glucanase (EC 3.2.1.4)). In the present investigation, properties of the CelB protein, a glycosylated protein of 532 amino acids, 36% of which are serine or threonine, were examined, and the upstream sequences involved in the developmental regulation of the expression of the gene have been determined. The CelB protein does not demonstrate cellulase activity, but it has a cellulose-binding domain. Its role, if any, in degradation of the cellulose-containing spore wall is unknown. To identify cis-acting elements in the celB promoter, unidirectional 5' deletions of the celB upstream noncoding region were constructed and used to transform amoebae. Analysis of promoter activity during different stages of development shows that a short, very A/T-rich sequence of approximately 81 base pairs is sufficient for spore-specific celB transcription. Contained in this sequence is the Myb oncogene protein binding site, TAACTG, which was shown previously to be a negative regulator of celA transcription. Dictyostelium and mouse Myb proteins bind to this region of the promoter, suggesting that Myb might regulate celB gene expression negatively as it does in celA.

The cysteine proteinase gene cprG in Dictyostelium discoideum has a serine-rich domain that contains GlcNAc-1-P

A lysosomal cysteine proteinase called proteinase-1 is the major proteolytic enzyme in vegetative cells of Dictyostelium discoideum. This phosphoglycosylated protein contains multiple residues of GlcNAc-1-P linked to peptidyl serines. Here we report the cloning, structure, and expression of its cDNA (cprG). Another cDNA (cprF) closely related to cprG was also cloned and characterized. mRNAs of both genes are present during the vegetative phase and decrease in developing cells. However, the level of cprG mRNA is about 100-fold higher than that of cprF. The predicted protein products of both genes contain a unique serine-rich domain that was previously found only in two Dictyostelium proteinases (CP4 and CP5) that also carry a GlcNAc-1-P-Ser modification. The cprG product, renamed CP7, was tagged with the FLAG-epitope (FLAG-CP7) and shown to bind to cystatin, a highly specific inhibitor of cysteine proteinases. The FLAG-CP7 product also contained both N-linked oligosaccharides and GlcNAc-1-P. Deletion of the serine-rich domain from FLAG-CP7 yields a product that still binds to cystatin, but no longer carries GlcNAc-1-P. This finding supports the idea that the GlcNAc-1-P residues are normally added to the serine-rich domain, found only in vegetative Dictyostelium cysteine proteinases.

Identification of two novel Dictyostelium discoideum cysteine proteinases that carry N-acetylglucosamine-1-P-modification

Dictyostelium discoideum makes multiple developmentally regulated lysosomal cysteine proteinases. One of these, a lysosomal enzyme called proteinase I, contains a cluster of GlcNAc-alpha-1-P-Ser residues. We call this phosphoglycosylation. To study its function, a cDNA library from vegetative cells was screened, and two novel cysteine proteinase clones were characterized (cprD and cprE). Each of them has highly conserved regions expected for cysteine proteinases, but unlike any other, each has a serine-rich domain containing three distinct motifs, poly-S, SGSQ, and SGSG. cprD and cprE cDNAs were overexpressed in Dictyostelium and the active enzymes identified. cprD codes for a protein of approximately 36 kDa (CP4), which is recognized by monoclonal antibodies against GlcNAc-1-P and fucose. cprE corresponds to a 29-kDa protein, which is recognized by antibodies against GlcNAc-1-P. mRNA for both enzymes is present in the vegetative phase and increases during growth on bacteria but decreases throughout development. When the formation of the fruiting body is complete the mRNA for both messages is detected again but in very low levels. Having cloned cDNAs for proteins that carry GlcNAc-1-P should allow us to probe the function of the carbohydrate in these putative lysosomal enzymes.

Lack of glycosyl-phosphatidylinositol anchoring leads to precursor retention by a unique mechanism in Dictyostelium discoideum

Gp80, a cell-adhesion molecule in Dictyostelium discoideum, is modified by N- and O-linked oligosaccharides, and a glycosylphosphatidylinositol (GPI) anchor. To identify sequences important for the addition of these modifications to gp80, we created a hybrid protein in which the C-terminal 136 amino acids of yeast invertase were replaced by the C-terminal 110 amino acids of gp80. When expressed in D. discoideum, this protein (Inv-gp80) was not GPI-anchored and was retained in a pre-Golgi compartment. Inv-gp80 did, however, display characteristics of a transmembrane protein, suggesting a novel mechanism for its retention. We also expressed a truncated version of the hybrid protein in which the C-terminal 22 amino acids of the Inv-gp80 were deleted. The truncated protein (Inv-gp80stop) was O-glycosylated and secreted. These observations indicate that the hybrid protein is not abnormally folded and demonstrate the importance of the C-terminal 22 amino acids in the retention of Inv-gp80. Together, the data suggest that oligomerization of the protein blocks its GPI anchoring.

Involvement of cell-cell adhesion in the expression of the cell cohesion molecule gp80 in Dictyostelium discoideum

Soon after the initiation of the developmental cycle of Dictyostelium discoideum, cells acquire EDTA-sensitive cell-cell binding sites mediated by the glycoprotein gp24. Cells at the aggregation stage display a second type of cell adhesion site, the EDTA-resistant cell-cell binding sites, mediated by the glycoprotein gp80. The gene encoding gp80 is first turned on to a low basal level of expression in the preaggregation stage. At the onset of the aggregation stage, cells produce pulses of low levels of cAMP, which greatly augment the expression of gp80. To investigate the role of cell-cell adhesion in the regulation of gp80 expression, cells were developed in the presence of EDTA or carnitine to block the EDTA-sensitive cell binding sites. Alternatively, cell cohesion was disrupted by shaking low-density cultures at high shearing forces. In all three instances, gp80 was expressed at a substantially reduced level. In addition, exogenous cAMP pulses, which normally were capable of stimulating a precocious and enhanced expression of gp80, failed to restore the high level of gp80 expression. However, if the formation of cell-cell contact was permitted, exogenous cAMP pulses were able to rescue the expression of gp80 even when the cAMP signal relay was blocked. These results indicate that previous cell-cell contact, provided by the EDTA-sensitive binding sites, is required for the activation of the cAMP-mediated signal transduction pathway producing high levels of gp80 expression.

Two distinct adhesion systems are responsible for EDTA-sensitive adhesion in Dictyostelium discoideum

Early in their developmental program, Dictyostelium discoideum exhibit EDTA-sensitive and EDTA-resistant adhesion. The molecules which mediate the adhesions have been called contact sites, with contact sites A mediating EDTA-resistant adhesion and contact sites B mediating EDTA-sensitive adhesion. The studies described here have revealed that prior to aggregation, a second EDTA-sensitive adhesion system emerges. In keeping with previously established nomenclature, the molecules mediating the newly discovered adhesion system have been called contact sites C. Unlike contact sites B, contact sites C are unaffected by a contact sites B-blocking peptide. Contact sites C-mediated adhesion is also distinct from contact sites B-mediated adhesion in that contact sites C-mediated adhesion is EGTA-resistant and in the presence of EDTA it can be rescued by the addition of Mg2+. Thus Mg2+ may be the cation present under physiological conditions that is essential for contact sites C activity. Unlike contact sites B-mediated adhesion, contact sites C-mediated adhesion is not observed in growing amoebae. Contact sites C-mediated adhesion first becomes apparent within hours after the initiation of development and its strength appears to increase throughout the first 10 h of the developmental program. A mutant lacking the EDTA-resistant contact sites A exhibits normal contact sites B- and C-mediated adhesion, demonstrating that both EDTA-sensitive adhesion systems are independent of contact sites A. Thus aggregating D. discoideum amoebae possess three distinct adhesion systems, one of them is EDTA-resistant and the other two are EDTA-sensitive.

The Dictyostelium discoideum spore germination-specific cellulase is organized into functional domains

During Dictyostelium discoideum spore germination, degradation of the cellulose-containing spore wall is required to allow the amoeba to emerge. The CelA gene, which is transcribed and expressed exclusively during spore germination, codes for a 705-amino-acid protein that has cellulase activity [endo-(1,4)-beta-D-glucanase]. Amoebae transformed by a vector containing the CelA coding sequence or portions of it transcribed from a heterologous promoter expressed and secreted full-length or suitably truncated proteins during vegetative growth when, under normal conditions, these proteins are not made. The gene constructs divided the CelA protein into three domains: a 461-amino-acid N-terminal region that has significant similarity to those of other cellulases and that has been shown to be the catalytic domain; a contiguous 91-residue repeat containing the motif threonine-glutamic acid-threonine-proline, which is glycosylated; and, joined to the repeat, a C-terminal 153-amino-acid sequence that most probably defines a cellulose-binding domain.