A spatial gradient of expression of a cAMP-regulated prespore cell-type-specific gene in Dictyostelium

Intercellular signaling. A kinase for cell-fate determination?

GSK-3, a ubiquitous kinase regulated by tyrosine phosphorylation, controls cell-fate decisions in both Drosophila and Dictyostelium; genetic analysis of its interactions with other signaling pathways is now possible.

Protein kinase A is a positive regulator of spore coat gene transcription in Dictyostelium

The cotA, cotB, and cotC genes encode the major spore coat proteins of Dictyostelium. All three cot genes are coordinately expressed as aggregation is nearing completion. Induction and maintenance of their expression is dependent upon the presence of extracellular cAMP. We show that expression of a dominant inhibitor of the cAMP dependent protein kinase (PKA) in prespore cells greatly reduces the transcription rates of the cotB and cotC genes. All three cot genes contain, in their upstream regulatory regions, short sequence elements that have a high content of cytosine and adenosine residues. These CA-rich sequences are essential for optimal cot gene transcription. We show that expression of the dominant PKA inhibitor results in a greatly reduced level of the binding activity that recognizes the CA-rich sequences upstream of the cotB gene. Thus PKA acts, either directly or indirectly, to control expression of the cot genes and it may do so by modulating the activity of a DNA binding protein. However, we find that mutant cells where PKA is constitutively active still require exogenous cAMP for optimal cot gene expression in dissociated cells, suggesting that a separate, PKA-independent, signalling pathway is also involved in the regulation of cot gene expression by extracellular cAMP.

An autonomously propagating luciferase-encoding vector for Dictyostelium discoideum

We have constructed a luc reporter vector for Dictyostelium discoideum using a 626-bp fragment from the nuclear-associated plasmid Ddp2. The ori from Ddp2 is localized within this fragment and was used to provide an autonomous replication sequence for the reporter vector. This reporter vector was stably retained in D. discoideum AX3K cells without alteration. The vector molecule was also found to exist in relatively low copy number compared to other Dictyostelium vectors in the transformed cells. We demonstrated the utility of this vector as a reporter vector with glycogen synthase promoter/luc fusions of varying sizes.

Regulatory role of the G alpha 1 subunit in controlling cellular morphogenesis in Dictyostelium

To determine the function of the Dictyostelium G alpha 1 subunit during aggregation and multicellular development, we analyzed the phenotypes of g alpha 1 null cells and strains overexpressing either wild-type G alpha 1 or two putative constitutively active mutations of G alpha 1. Strains overexpressing the wild-type or mutant G alpha 1 proteins showed very abnormal culmination with an aberrant stalk differentiation. The similarity of the phenotypes between G alpha 1 overexpression and expression of a putative constitutively active G alpha 1 subunit suggests that these phenotypes are due to increased G alpha 1 activity rather than resulting from a non-specific interference of other pathways. In contrast, g alpha 1 null strains showed normal morphogenesis except that the stalks were thinner and longer than those of wild-type culminants. Analysis of cell-type-specific gene expression using lacZ reporter constructs indicated that strains overexpressing G alpha 1 show a loss of ecmB expression in the central core of anterior prestalk AB cells. However, expression of ecmB in anterior-like cells and the expression of prestalk A-specific gene ecmA and the prespore-specific gene SP60/cotC appeared normal. Using a G alpha 1/lacZ reporter construct, we show that G alpha 1 expression is cell-type-specific during the multicellular stages, with a pattern of expression similar to ecmB, being preferentially expressed in the anterior prestalk AB cells and anterior-like cells. The developmental and molecular phenotypes of G alpha 1 overexpression and the cell-type-specific expression of G alpha 1 suggest that G alpha 1-mediated signaling pathways play an essential role in regulating multicellular development by controlling prestalk morphogenesis, possibly by acting as a negative regulator of prestalk AB cell differentiation. During the aggregation phase of development, g alpha 1 null cells display a delayed peak in cAMP-stimulated accumulation of cGMP compared to wild-type cells, while G alpha 1 overexpressors and dominant activating mutants show parallel kinetics of activation but decreased levels of cGMP accumulation compared to that seen in wild-type cells. These data suggest that G alpha 1 plays a role in the regulation of the activation and/or adaptation of the guanylyl cyclase pathway. In contrast, the activation of adenylyl cyclase, another pathway activated by cAMP stimulation, was unaffected in g alpha 1 null cells and cell lines overexpressing wild-type G alpha 1 or the G alpha 1 (Q206L) putative dominant activating mutation.(ABSTRACT TRUNCATED AT 400 WORDS)

Identification and characterization of multiple A/T-rich cis-acting elements that control expression from Dictyostelium actin promoters: the Dictyostelium actin upstream activating sequence confers growth phase expression and has enhancer-like properties

The promoter elements in the Dictyostelium actin 15 and actin 6 genes required for full growth phase expression were identified by assaying promoter/luciferase reporter constructs. We find that these promoters contain common cis-acting elements, an actin upstream activating sequence (UAS) and sequences proximal to the transcription start site that overlap with a poly(dT) region. The actin 15 promoter has two additional cis-acting elements not present in the actin 6 promoter that may account for the higher level of expression from the actin 15 promoter. All of the identified promoter elements are unusual for Dictyostelium in that they are all A/T-rich. Two cis-acting elements, the actin UAS and the poly(dT) domain were studied in greater detail. The actin UAS was tested on a heterologous promoter from the prespore-specific gene SP60 and shown to have the ability to confer growth phase expression. The actin UAS also exhibited the ability to function in a distance- and orientation-independent manner and activate expression synergistically when present in two copies. The poly(dT) domain of the actin 15 promoter was studied in greater detail by using a genetic selection scheme to define parameters that effect the strength of this element. This element is comprised of 45 consecutive dT residues immediately upstream of the putative TATA box. We show that the length of the homopolymer dT region correlates with the expression level of the promoter. The poly(dT) element is also shown to function to promote wild-type levels of expression with small deviations in the sequence, indicating that the element is not required to be homopolymeric to function.

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. G alpha 4 is preferentially expressed in cells randomly distributed within the aggregate that are a component of the anterior-like cell population, and it is not detectably expressed in prespore cells. Our results suggest that an endogenous factor, possibly a pterin, produced during multicellular development is a requisite signal for multicellular development, acting through G alpha 4. We propose that the G alpha 4-expressing cells function as a regulatory cell type controlling prespore cell fate, possibly in response to an endogenous pterin. Our results indicate that G alpha 4 and G alpha 2 have parallel functions in mediating cellular responses to folate (pterins) and cAMP, respectively.

Expression of cAMP-dependent protein kinase in prespore cells is sufficient to induce spore cell differentiation in Dictyostelium

The activity of cAMP-dependent protein kinase (PKA) is required for proper development at several stages during the Dictyostelium life cycle. We present evidence that activation of PKA is rate-limiting for the differentiation of prespore cells to spores and that PKA activation may be the developmental trigger for sporulation. Strains that overexpress the gene encoding the catalytic subunit of PKA (PKAcat) or lack a functional regulatory subunit (rdeC strains) undergo rapid, heterochronic development. We show that overexpression of PKAcat in prespore cell is sufficient to directly induce expression of the spore maturation marker spiA and differentiation to spores, in a cell-autonomous manner. Moreover, overexpression of PKAcat in prespore cells can bypass a mutation that blocks an earlier developmental step to induce spiA expression. Our results suggest that the regulatory pathway in prespore cells between the activation of PKA and spiA induction/spore maturation is quite short and that PKAcat expression in prespore cells may mediate spore differentiation at the level of transcription. This induction of sporulation requires the prior activation of the prespore cell pathway. In addition, we show that beta-galactosidase activity expressed from a PKAcat promoter/lacZ reporter construct is highly enriched in the anterior prestalk A region during the tipped aggregate, slug, and early culminant stages and that this pattern switches abruptly to a prespore pattern at the time of spore maturation, supporting the proposed role of PKA in this process.

Identification and functional analysis of a developmentally regulated extracellular signal-regulated kinase gene in Dictyostelium discoideum

We have cloned a developmentally regulated mitogen-activated protein kinase (extracellular signal-regulated kinase) from Dictyostelium discoideum designated ERK1. Using anti-pTyr antibodies, we show that ERK1 is phosphorylated on tyrosine in vivo and that it will phosphorylate myelin basic protein. The gene expresses two transcripts, one that is preferentially expressed during vegetative growth and early development and one that is induced during the multicellular stages. Developmental Western blots (immunoblots) using anti-ERK1 antibodies indicate that ERK1 is present throughout development. ERK1/lacZ reporter constructs suggest that, in the multicellular stages, the gene is preferentially expressed in a subpopulation of cells scattered throughout the organism, similar to the pattern seen with anterior-like cell markers. Antisense mutagenesis from a derepressible promoter indicates that ERK1 is essential for vegetative growth. Overexpression of ERK1 from either the Actin 15 promoter or the ERK1 promoter results in abnormal morphogenesis starting at the slug stage. Overexpression of ERK1 in null mutants of the phosphotyrosine phosphatase PTP2 results in the production of large aggregation streams and subsequent abnormal morphogenesis that indicate a genetic interaction between ERK1 and PTP2. These cells produce very large aggregation streams that break up into very small mounds that undergo abnormal morphogenesis. The genetic interaction between ERK1 and PTP2 appears to be specific since overexpression of ERK1 in a ptp1- null mutant does not produce the same phenotype. Our results indicate that ERK1 plays an essential role during the growth and differentiation of D. discoideum.

The ‘prespore-like cells’ of Dictyostelium have ceased to express a prespore gene: analysis using short-lived beta-galactosidases as reporters

In transgenic strains of Dictyostelium discoideum that express beta-galactosidase under the control of a prespore-specific promoter, only early slugs show reporter confined to the prespore zone. As slugs migrate beta-galactosidase-positive cells accumulate in the prestalk zone; ultimately, there may be so many that the prestalk-prespore boundary is no longer distinguishable (Harwood, A., Early, A., Jermyn, K. and Williams, J. (1991) Differentiation 46, 7–13). It is not clear whether these ‘anomalous’ reporter-positive cells currently express prespore genes; another possibility is that they are ex-prespore cells that have transformed to prestalk and sorted to the prestalk zone (Sternfeld, J. (1993) Roux Archiv. Dev. Biol. 201, 354–363), while retaining their previously produced reporter. To test the activity of the prespore genes in these cells, we have made prespore reporter constructs whose products decay quickly; these are based on constructs used to investigate protein turnover in yeast (Bachmair, A., Finley, D. and Varshavsky, A. (1986) Science 234, 179–186). In strains bearing such constructs, beta-galactosidase-positive cells do not appear in the prestalk zone. The apparent deterioration of the prestalk/prespore pattern in older slugs is thus an artefact of reporter stability.

Progression of an inductive signal activates sporulation in Dictyostelium discoideum

spiA, a marker for sporulation, is expressed during the culmination stage of Dictyostelium development, when the mass of prespore cells has moved partly up the newly formed stalk. Strains containing a full-length spiA promoter/lacZ fusion were stained for beta-galactosidase activity at intervals during development. The results indicate that expression of spiA initiates in prespore cells at the prestalk/prespore boundary (near the apex) and extends downward into the prespore mass as culmination continues. A spatial gradient of staining expands from the top of the prespore mass and intensifies until the front of activation reaches the bottom, whereupon the entire region stains darkly. The spiA promoter can be deleted to within 301 bp of the transcriptional start site with no effect on the relative strength, timing or spatial localization of expression. Further 5′ deletions from −301 to −175 reduce promoter strength incrementally, although timing and spatial expression are not affected. Deletions to −159 and beyond result in inactive promoters. Treatment of early developmental structures with 8-Br-cAMP in situ activates the intracellular cAMP-dependent protein kinase (PKA) and precociously induces spiA expression and sporulation. The absence of an apparent gradient of staining in these structures suggest that PKA is equivalently activatable throughout the prespore region and that all prespore cells are competent to express spiA. Thus, we postulate that the pattern of expression of spiA reveals the progression of an inductive signal for sporulation and suggest that this signal may originate from the prestalk cells at the apex.

A Dictyostelium anterior-like cell mutant reveals sequential steps in the prespore prestalk differentiation pathway

We have isolated Dictyostelium cell type proportioning mutants in a screen for cAMP signal transduction mutants. All mutants showed reduced numbers of prespore cells as analyzed with prespore-specific antibodies and prespore- and prestalk-specific reporter gene constructs. Formation of prestalk and prespore cells in the mutant HP1 is initially almost normal; however, many prespore cells redifferentiate as anterior-like cells leading to altered cell type proportions. Synergy experiments of HP1 transformant cells with wild-type Ax2 slugs showed the existence of stable subpopulations of cells in the prestalk and prespore regions of the slug. HP1 cells sort exclusively to the back of the prestalk and prespore zone in slugs. These cells will form the upper and lower cup regions of the culminate. Ax2 transformant cells sort to the tip of the anterior prestalk and prespore zone in HP1 slugs and will form the stalk and spores in the culminate. These experiments show that upper and lower cup derive from cells in different differentiation pathways. The lower cup cell derive from prespore cells, which redifferentiate as anterior-like cells in the back of the prespore zone. The upper cup cells derive from cells from the back of the prestalk zone. Synergy experiments showed that the mutation in HP1 results in an altered sensitivity to proportioning signals. The mutation in HP1 may result in a reduced sensitivity to cAMP, which facilitates the redifferentiation of prespore cells via anterior-like to lower cup cells and inhibits the transition from upper cup to stalk cells.

Identification and functional analysis of a developmentally regulated extracellular signal-regulated kinase gene in Dictyostelium discoideum

We have cloned a developmentally regulated mitogen-activated protein kinase (extracellular signal-regulated kinase) from Dictyostelium discoideum designated ERK1. Using anti-pTyr antibodies, we show that ERK1 is phosphorylated on tyrosine in vivo and that it will phosphorylate myelin basic protein. The gene expresses two transcripts, one that is preferentially expressed during vegetative growth and early development and one that is induced during the multicellular stages. Developmental Western blots (immunoblots) using anti-ERK1 antibodies indicate that ERK1 is present throughout development. ERK1/lacZ reporter constructs suggest that, in the multicellular stages, the gene is preferentially expressed in a subpopulation of cells scattered throughout the organism, similar to the pattern seen with anterior-like cell markers. Antisense mutagenesis from a derepressible promoter indicates that ERK1 is essential for vegetative growth. Overexpression of ERK1 from either the Actin 15 promoter or the ERK1 promoter results in abnormal morphogenesis starting at the slug stage. Overexpression of ERK1 in null mutants of the phosphotyrosine phosphatase PTP2 results in the production of large aggregation streams and subsequent abnormal morphogenesis that indicate a genetic interaction between ERK1 and PTP2. These cells produce very large aggregation streams that break up into very small mounds that undergo abnormal morphogenesis. The genetic interaction between ERK1 and PTP2 appears to be specific since overexpression of ERK1 in a ptp1- null mutant does not produce the same phenotype. Our results indicate that ERK1 plays an essential role during the growth and differentiation of D. discoideum.

A GBF-binding site and a novel AT element define the minimal sequences sufficient to direct prespore-specific expression in Dictyostelium discoideum

In order to better understand the molecular mechanisms of cellular differentiation in Dictyostelium discoideum, we have identified the minimum regulatory sequences of the prespore-specific gene SP60/cotC that are sufficient to confer cell-type-specific expression on a heterologous promoter. This region includes at least two essential cis-acting elements: a novel AT-rich element (or elements) and CAE3. The essential function of the AT element is confirmed through point mutations that decrease expression below the level of detection. CAE3 is one of three CA-rich elements (CAEs) required for the induction of SP60/cotC during development or in response to extracellular cyclic AMP. The CAEs have differential affinities for a specific developmentally induced nuclear activity (CAE1 > CAE2 >> CAE3). Here, we identify this activity as G-box-binding factor (GBF) and show that in vitro-transcribed and -translated GBF binds all three SP60/cotC CAEs in a sequence-specific manner. Previous studies have suggested that GBF mediates the induction of some prestalk genes, and these results demonstrate that it also has a specific role in prespore gene activation.

A GBF-binding site and a novel AT element define the minimal sequences sufficient to direct prespore-specific expression in Dictyostelium discoideum

In order to better understand the molecular mechanisms of cellular differentiation in Dictyostelium discoideum, we have identified the minimum regulatory sequences of the prespore-specific gene SP60/cotC that are sufficient to confer cell-type-specific expression on a heterologous promoter. This region includes at least two essential cis-acting elements: a novel AT-rich element (or elements) and CAE3. The essential function of the AT element is confirmed through point mutations that decrease expression below the level of detection. CAE3 is one of three CA-rich elements (CAEs) required for the induction of SP60/cotC during development or in response to extracellular cyclic AMP. The CAEs have differential affinities for a specific developmentally induced nuclear activity (CAE1 > CAE2 >> CAE3). Here, we identify this activity as G-box-binding factor (GBF) and show that in vitro-transcribed and -translated GBF binds all three SP60/cotC CAEs in a sequence-specific manner. Previous studies have suggested that GBF mediates the induction of some prestalk genes, and these results demonstrate that it also has a specific role in prespore gene activation.

Analysis of a novel cyclic Amp inducible prespore gene in Dictyostelium discoideum: evidence for different patterns of cAMP regulation

The D7 cDNA clone hybridizes to a 2.8 kb mRNA which first appears at the mound stage of development in the cellular slime mold Dictyostelium discoideum. This gene which is cyclic AMP (cAMP) inducible and is expressed specifically in the prespore cells contains an open reading frame interrupted by only one intron. The predicted amino acid sequence indicates a novel prespore protein which differs from all of the previously described prespore proteins in that it contains no internal repeats and does not share any homology with any of the other prespore genes. The amino acid sequence predicts a protein of 850 amino acids with a molecular weight of 95,343 daltons and an isoelectric point of 4.25. The protein is very rich in glutamine (13.8%), asparagine (10.6%) and glutamic acid (10.4%) with one potential glycosylation site and 28 possible sites for phosphorylation. The amino terminus is hydrophobic with characteristics of a signal sequence while the entire carboxyl half of the protein is notable for its hydrophilicity. Comparison of cAMP regulation of the D7 gene with the regulation of two other cAMP regulated prespore genes, the PL3(SP87) gene and the Psa(D19), reveals some striking differences. Disaggregation in the presence of cAMP results in transient degradation of mRNA for all three genes. The transcription rate for the D7 and PsA(D19) genes remains relatively unaffected by disaggregation but there is a rapid although transient decline in the transcription rate of the PL3(SP87) gene. Although the accumulation of all three mRNAs is first detectable at mound stage, transcription of the D7 and PsA(D19) genes is detected earlier in development, at rippling aggregate stage several hours prior to the earliest time when transcription of the PL3(SP87) gene is detected. Analysis of the promoter region of the D7 gene reveals three CA like boxes flanked by direct repeats as well as four G rich regions that may serve as regulatory elements.

Developmental decisions in Dictyostelium discoideum

A few hours after the onset of starvation, amoebae of Dictyostelium discoideum start to form multicellular aggregates by chemotaxis to centers that emit periodic cyclic AMP signals. There are two major developmental decisions: first, the aggregates either construct fruiting bodies directly, in a process known as culmination, or they migrate for a period as "slugs." Second, the amoebae differentiate into either prestalk or prespore cells. These are at first randomly distributed within aggregates and then sort out from each other to form polarized structures with the prestalk cells at the apex, before eventually maturing into the stalk cells and spores of fruiting bodies. Developmental gene expression seems to be driven primarily by cyclic AMP signaling between cells, and this review summarizes what is known of the cyclic AMP-based signaling mechanism and of the signal transduction pathways leading from cell surface cyclic AMP receptors to gene expression. Current understanding of the factors controlling the two major developmental choices is emphasized. The weak base ammonia appears to play a key role in preventing culmination by inhibiting activation of cyclic AMP-dependent protein kinase, whereas the prestalk cell-inducing factor DIF-1 is central to the choice of cell differentiation pathway. The mode of action of DIF-1 and of ammonia in the developmental choices is discussed.

Regulation by protein-tyrosine phosphatase PTP2 is distinct from that by PTP1 during Dictyostelium growth and development

We have cloned a gene encoding a second Dictyostelium discoideum protein-tyrosine phosphatase (PTP2) whose catalytic domain has approximately 30 to 39% amino acid identity with those of other PTPs and a 41% amino acid identity with D. discoideum PTP1. Like PTP1, PTP2 is a nonreceptor PTP with the catalytic domain located at the C terminus of the protein. PTP2 has a predicted molecular weight of 43,000 and possesses an acidic 58-amino-acid insertion 24 amino acids from the N terminus of the conserved catalytic domain. PTP2 transcripts are expressed at moderate levels in vegetative cells and are induced severalfold at the onset of development. Studies with a PTP2-lacZ reporter gene fusion indicate that PTP2, like PTP1, is preferentially expressed in prestalk and anterior-like cell types during the multicellular stages of development. PTP2 gene disruptants (ptp2 null cells) are not detectably altered in growth and show a temporal pattern of development similar to that of wild-type cells. ptp2 null slugs and fruiting bodies, however, are significantly larger than those of wild-type slugs, suggesting a role for PTP2 in regulating multicellular structures. D. discoideum strains overexpressing PTP2 from the PTP2 promoter exhibit growth rate and developmental abnormalities, the severity of which corresponds to the level of PTP2 overexpression. Strains with high overexpression of the PTP2 gene grow slowly on bacterial lawns and produce small cells in axenic medium. When development is initiated in these strains, cells are able to aggregate but then stop further morphogenesis for 6 to 8 h, after which time a variable fraction of these aggregates continue with normal timing, producing diminutive fruiting bodies. These disruption and overexpression phenotypes for PTP2 are distinct from the corresponding mutant PTP1 phenotypes. Immunoprobing PTP2 mutant strains during growth and development with antiphosphotyrosine antibodies reveals several changes in the tyrosine phosphorylation of proteins in PTP2 mutant strains compared with that in wild-type cells. These changes are different from those identified in the previously characterized corresponding PTP1 disruption and overexpression mutant strains. Thus, although PTP2 and PTP1 are nonreceptor PTPs with similar spatial patterns of expression, our findings suggest that they possess distinct regulatory functions in controlling D. discoideum growth and development.

Regulation by protein-tyrosine phosphatase PTP2 is distinct from that by PTP1 during Dictyostelium growth and development

We have cloned a gene encoding a second Dictyostelium discoideum protein-tyrosine phosphatase (PTP2) whose catalytic domain has approximately 30 to 39% amino acid identity with those of other PTPs and a 41% amino acid identity with D. discoideum PTP1. Like PTP1, PTP2 is a nonreceptor PTP with the catalytic domain located at the C terminus of the protein. PTP2 has a predicted molecular weight of 43,000 and possesses an acidic 58-amino-acid insertion 24 amino acids from the N terminus of the conserved catalytic domain. PTP2 transcripts are expressed at moderate levels in vegetative cells and are induced severalfold at the onset of development. Studies with a PTP2-lacZ reporter gene fusion indicate that PTP2, like PTP1, is preferentially expressed in prestalk and anterior-like cell types during the multicellular stages of development. PTP2 gene disruptants (ptp2 null cells) are not detectably altered in growth and show a temporal pattern of development similar to that of wild-type cells. ptp2 null slugs and fruiting bodies, however, are significantly larger than those of wild-type slugs, suggesting a role for PTP2 in regulating multicellular structures. D. discoideum strains overexpressing PTP2 from the PTP2 promoter exhibit growth rate and developmental abnormalities, the severity of which corresponds to the level of PTP2 overexpression. Strains with high overexpression of the PTP2 gene grow slowly on bacterial lawns and produce small cells in axenic medium. When development is initiated in these strains, cells are able to aggregate but then stop further morphogenesis for 6 to 8 h, after which time a variable fraction of these aggregates continue with normal timing, producing diminutive fruiting bodies. These disruption and overexpression phenotypes for PTP2 are distinct from the corresponding mutant PTP1 phenotypes. Immunoprobing PTP2 mutant strains during growth and development with antiphosphotyrosine antibodies reveals several changes in the tyrosine phosphorylation of proteins in PTP2 mutant strains compared with that in wild-type cells. These changes are different from those identified in the previously characterized corresponding PTP1 disruption and overexpression mutant strains. Thus, although PTP2 and PTP1 are nonreceptor PTPs with similar spatial patterns of expression, our findings suggest that they possess distinct regulatory functions in controlling D. discoideum growth and development.

Characterization of a novel Dictyostelium discoideum prespore-specific gene, PspB, reveals conserved regulatory sequences

While Dictyostelium discoideum has been studied as a developmental system for decades, and many regulatory proteins have been cloned, the molecular mechanisms of cell-type-specific gene expression are poorly understood. In this paper we characterize a novel prespore gene, PspB, and undertake a comparative analysis of the regulatory regions in prespore-specific D. discoideum promoters. Sequence alignment of the PSPB gene product with other prespore-specific proteins identifies a conserved, repeated 12 amino acid cysteine-containing motif that may be involved in spore coat function or assembly. Analysis of the PspB promoter identifies two domains essential for developmentally induced promoter activity. The first region includes two CA-rich elements (CAEs) that we show to be functionally homologous to the cAMP-inducible elements previously identified in the SP60 (cotC) promoter. The PspB CAEs compete with the SP60 (cotC) CAEs for binding in vitro to a developmentally regulated nuclear activity. We identify this activity as G-box Binding Factor, a developmentally induced transcription factor. The PspB CAEs and adjacent nucleotides direct a very low level of prespore-enriched expression, but high levels of cell-type-specific expression requires a second promoter region: a 46-bp AT-rich sequence that does not resemble the CAEs or any other previously described late gene promoter elements. Comparison of the PspB AT element with regulatory regions of the SP60 (cotC), SP70 (cotB), and D19 (pspA) promoters reveals an extensive consensus sequence. We suggest that these AT-rich sequences may represent a common regulatory element (or elements) required for prespore gene activation.

LagC is required for cell-cell interactions that are essential for cell-type differentiation in Dictyostelium

Strain AK127 is a developmental mutant of Dictyostelium discoideum that was isolated by restriction enzyme-mediated integration (REMI). Mutant cells aggregate normally but are unable to proceed past the loose aggregate stage. The cloned gene, lagC (loose aggregate C), encodes a novel protein of 98 kD that contains an amino-terminal signal sequence and a putative carboxy-terminal transmembrane domain. The mutant strain AK127 shows no detectable lagC transcript upon Northern analysis, indicating that the observed phenotype is that of a null allele. Expression of the lagC cDNA in AK127 cells complements the arrest at the loose aggregate stage, indicating that the mutant phenotype results from disruption of the lagC gene. In wild-type cells, lagC mRNA is induced at the loose aggregate stage and is expressed through the remainder of development. lagC- null cells aggregate but then disaggregate and reaggregate to form small granular mounds. Mature spores are produced at an extremely low efficiency (< 0.1% of wild type), appearing only after approximately 72 hr, whereas wild-type strains produce mature spores by 26 hr. lagC- null cells accumulate reduced levels of transcripts for the prestalk-enriched genes rasD and CP2 and do not express the DIF-induced prestalk-specific gene ecmA or the cAMP-induced prespore-specific gene SP60 to significant levels. In chimeric organisms resulting from the coaggregation of lagC- null and wild-type cells, cell-type-specific gene expression is rescued in the lagC- null cells; however, lagC- prespore cells are localized to the posterior of the prespore region and do not form mature spores, suggesting that LagC protein has both no cell-autonomous and cell-autonomous functions. Overexpression of lagC from an actin promoter in both wild-type and lagC- cells causes a delay at the tight aggregate stage, the first stage requiring LagC activity. These results suggest that the LagC protein functions as a nondiffusible cell-cell signaling molecule that is required for multicellular development.

Cloning and characterization of the G-box binding factor, an essential component of the developmental switch between early and late development in Dictyostelium

During Dictyostelium development, the cAMP-regulated induction of cell-type-specific late genes marks a developmental switch from the initial formation of the multicellular organism to the differentiation of the various cell types that mediate morphogenesis and eventually give rise to the mature fruting body. The G-box binding factor (GBF) is a developmentally regulated Dictyostelium transcription factor whose affinity for a DNA sequence correlates with the ability of that sequence to confer inducibility to late gene promoters in response to high, continuous levels of extracellular cAMP. We report the purification of GBF and cloning of the gene that encodes it, as confirmed by in vitro production of GBF activity. The predicted protein is highly basic and contains two putative zinc fingers. Disruption of the GBF gene by homologous recombination results in the loss of all GBF DNA-binding activity, developmental arrest at the loose aggregate stage, and the loss of late gene induction during development or in response to extracellular cAMP. Constitutive expression of GBF complements the null phenotype and allows for the rapid activation of a class of late genes in response to cAMP. Our results indicate that GBF acts as an extracellular cAMP-responsive transcriptional activator regulating late gene expression and is an essential component of a developmental switch between aggregation and cellular morphogenesis.

Spatial and temporal expression of the Dictyostelium discoideum G alpha protein subunit G alpha 2: expression of a dominant negative protein inhibits proper prestalk to stalk differentiation

Previous results have shown that the G alpha protein subunit G alpha 2 is required for aggregation in Dictyostelium discoideum and is essential for coupling cell-surface cAMP receptors to downstream effectors in vivo during this stage of development. G alpha 2 expresses at least four distinct transcripts that are differentially regulated during development; two of the transcripts are expressed exclusively in the multicellular stages and their expression is restricted to prestalk cells. We partially dissected the G alpha 2 promoter and identified a component that is expressed exclusively during the multicellular stages using luciferase gene fusions. When this promoter region is coupled to lacZ, beta-gal expression is restricted to the multicellular stages and localized in prestalk cells with a pattern similar to that of the ecmA prestalk-specific promoter. We show that expression in wild-type cells of the G alpha 2 mutant protein [G alpha 2(G206T)] during the early stages of development blocks aggregation and cAMP-mediated activation of adenylyl cyclase and guanylyl cyclase, suggesting it functions as a dominant negatively active G alpha subunit. When this mutant G alpha protein is expressed from the ecmA prestalk-specific promoter, abnormal stalk differentiation during culmination is observed. Expression of the mutant G alpha 2 from the SP60 prespore promoter or wild-type G alpha 2 from either the ecmA or the SP60 promoter results in no detectable phenotype. The results suggest that G alpha 2 plays an essential role during the culmination stage in prestalk cells and may mediate cAMP receptor activation of these processes during multicellular development.

Cooperation of positively and negatively acting promoter elements determines prespore-specific transcription of Dp87 gene in Dictyostelium

Dp87 gene in Dictyostelium is a novel prespore-specific gene, whose expression is first observed when the aggregation stream is formed, the earliest among prespore-specific genes so far isolated. By 5'-sequential deletion analyses, we had previously indicated that the region between -447 and -356 is important for transcription. Here we show by detailed analyses that the regulatory mechanism of the gene is more complex in that multiple positive and negative regulatory regions including the previously identified region act cooperatively. In addition, we show that the region including the putative TATA box and the transcriptional start site is required for proper negative regulation of the gene.

cAMP-dependent protein kinase differentially regulates prestalk and prespore differentiation during Dictyostelium development

We and others have previously shown that cAMP-dependent protein kinase (PKA) activity is essential for aggregation, induction of prespore gene expression and multicellular development in Dictyostelium. In this manuscript, we further examine this regulatory role. We have overexpressed the Dictyostelium PKA catalytic subunit (PKAcat) in specific cell types during the multicellular stages, using prestalk and prespore cell-type-specific promoters to make PKA activity constitutive in these cells (independent of cAMP concentration). To examine the effects on cell-type differentiation, we cotransformed the PKAcat-expressing vectors with reporter constructs expressing lacZ from four cell-type-specific promoters: ecmA (specific for prestalk A cells); ecmB (specific for prestalk B and anterior-like cells in the slug); ecmB delta 89 (specific for stalk cells); and SP60 (prespore-cell-specific). By staining for beta-galactosidase expression histologically at various stages of development in individual strains, we were able to dissect the morphological changes in these strains, examine the spatial localization of the individual cell types, and understand the possible roles of PKA during multicellular development. Expression of PKAcat from either the ecmA or ecmB prestalk promoters resulted in abnormal development that arrested shortly after the mound stage, producing a mound with a round apical protrusion at the time of tip formation. Prestalk A and prestalk B cells were localized in the central region and the apical mound in the terminal differentiated aggregate, while prespore cells showed an aberrant spatial localization. Consistent with a developmental arrest, these mounds did not form either mature spores or stalk cells and very few cells expressed a stalk-cell-specific marker. Expression of PKAcat from the prespore promoter resulted in abnormal morphogenesis and accelerated spore cell differentiation. When cells were plated on agar, a fruiting body was formed with a very large basal region, containing predominantly spores, and a small, abnormal sorocarp. Mature spore cells were first detected by 14 hours, with maximal levels reached by 18–20 hours, in contrast to 24–26 hours in wild-type strains. When cells were plated on filters, they produced an elongated tip from a large basal region, which continued to elongate as a tubular structure and produce a ‘slug-like’ structure at the end. The slug was composed predominantly of prestalk cells with a few prespore cells restricted to the junction between the ‘slug’ and tube. As the slug migrated, these prespore cells were found in the tube, while new prespore cells appeared at the slug/tube junction, suggesting a continual differentiation of new prespore cells at the slug's posterior.(ABSTRACT TRUNCATED AT 400 WORDS)

Two distinct populations of prestalk cells within the tip of the migratory Dictyostelium slug with differing fates at culmination

The ecmA gene of Dictyostelium encodes an extracellular matrix protein and is selectively expressed in prestalk cells. We show that its promoter contains discrete elements that direct expression in different subpopulations of prestalk cells. Prestalk(pst)A cells occupy the front half of the prestalk region. Expression in pstA cells requires DNA sequences close to the cap site of the gene and a separate, upstream region that acts in combination with the gene proximal sequences. PstO cells are situated in the rear half of the prestalk region and at least two separate and redundant promoter regions direct expression within them. All constructs that are expressed in pstO cells are also expressed in anterior-like cells (ALCs); cells that resemble prestalk cells but which are scattered throughout the prespore region. This observation suggests that pstO cells and ALCs may be very similar in their properties. If development occurs under conditions in which a migratory slug is not formed, there is an ordered movement of cells into the stalk tube. PstA cells enter the stalk tube first, followed by a proportion of the pstO cells. The remainder of the pstO cells contribute to the upper cup, an ALC-derived subpopulation of prestalk cells which is located at the apex of the spore head. After prolonged slug migration, a discrete pstO zone appears not to be maintained and, at culmination, pstO cells are found scattered throughout the stalk.

Use of a transactive regulatory mutant of Dictyostelium discoideum in a eucaryotic expression system

The discoidin proteins of Dictyostelium discoideum are highly expressed during development. The Disc I gamma promoter allows the regulation of heterologous protein expression by experimental conditions. We report conditions under which the promoter activity is efficiently repressed during growth in the wildtype strain AX2. In addition we show that a mutant which overexpresses the discoidins also overexpresses the reporter genes beta-galactosidase, luciferase and CAT 10- to 100-fold when these are placed under the control of a Disc I gamma promoter. This system may be generally useful for the overexpression of genes in Dictyostelium, both for functional studies in vivo and for the production of heterologous proteins for purification.

A localized differentiation-inducing-factor sink in the front of the Dictyostelium slug

Differentiation-inducing factor 1 [DIF-1; 1-(3,5-dichloro-2,6-dihydroxy-4-methoxyphenyl)-hexan-1-one] induces stalk cell differentiation during Dictyostelium development. It is present as a gradient in the multicellular slug, its lowest concentration being in the anterior. Here we demonstrate the existence of a localized sink for DIF-1, also in the anterior of the slug, which could be responsible for generating the DIF-1 gradient. DIF-1 is metabolized extensively by developing cells, initially by a mono-dechlorination. We used an enzyme assay for DIF-1 dechlorinase to examine its distribution in the slug. DIF-1 dechlorinase activity is 30-fold higher in prestalk cells (largely anterior) compared with prespore cells (posterior) when these are separated from each other on Percoll density gradients. Dissection experiments showed that DIF-1 dechlorinase is 25-fold enriched in the anterior 13% of the slug compared with the rest. These experiments also showed that DIF-1 dechlorinase is more anterior-enriched than the standard prestalk markers, the ecmA and ecmB mRNAs. When cut from a slug, both prestalk and prespore fragments regulate to restore the missing cell type. Prespore fragments rapidly regain (by 30 min) a DIF-1 sink in their anteriors, and prestalk fragments restore a posterior zone with low DIF-1 dechlorinase by 4 hr after cutting. The reappearance of the DIF-1 sink in the anterior of prespore fragments is accomplished without detectable cell sorting and may, therefore, be in response to positional signals. Finally, a localized sink may provide a general way of producing a gradient of a signal substance in a developing embryo.

Regulation of the Dictyostelium glycogen phosphorylase 2 gene by cyclic AMP

A crucial developmental event in the cellular slime mold, Dictyostelium discoideum, is glycogen degradation. The enzyme that catalyzes this degradation, glycogen phosphorylase 2 (gp-2), is developmentally regulated and cAMP appears to be involved in this regulation. We have examined several aspects of the cAMP regulation of gp-2. We show that addition of exogenous cAMP to aggregation competent amoebae induced the appearance of gp-2 mRNA. The induction of gp-2 mRNA occurred within 1 and 1.5 h after the initial exposure to cAMP. Exposure to exogenous cAMP concentrations as low as 1.0 microM could induce gp-2 mRNA. We also examined the molecular mechanism through which cAMP induction of gp-2 occurs. Induction of gp-2 appears to result from a mechanism that does not require intracellular cAMP signaling, and may occur directly through a cAMP binding protein without the requirement of any intracellular signalling. We also examined the promoter region of the gp-2 gene for cis-acting elements that are involved in the cAMP regulation of gp-2. A series of deletions of the promoter were fused to a luciferase reporter gene and then analyzed for cAMP responsiveness. The results indicated that a region from -258 nucleotides to the transcriptional start site is sufficient for essentially full activity and appears to carry all necessary cis-acting sites for cAMP induction. Further deletion of 58 nucleotides from the 5' end, results in fivefold less activity in the presence of cAMP. Deletion of the next 104 nucleotides eliminates the cAMP response entirely.

DdPK3, which plays essential roles during Dictyostelium development, encodes the catalytic subunit of cAMP-dependent protein kinase

We have previously reported the analysis of DdPK3, a developmentally regulated putative serine/threonine kinase that shares approximately 50% amino acid sequence identity with metazoan cAMP-dependent protein kinase A (PKA) and protein kinase C, within their catalytic domains. Cells in which the DdPK3 gene has been disrupted do not aggregate but they are able to induce aggregation-stage genes in response to cAMP pulses and the prestalk-specific ras gene DdrasD in response to high continuous levels of cAMP but will not induce prespore gene expression. In this report, we present conclusive evidence that DdPK3 encodes the catalytic subunit of the Dictyostelium PKA. DdPK3 null cells lack kinase activity that phosphorylates a PKA-specific substrate and is specifically inhibitable by recombinant cAMP-dependent protein kinase inhibitor. DdPK3 expressed in Escherichia coli has PKA activity that is inhibitable by protein kinase inhibitor. When Ddpk3 null cells are complemented with DdPK3 expressed from an actin promoter on an extrachromosomal vector (low copy number), PKA activity is restored and the cells proceed to the slug stage but will not culminate, suggesting that properly regulated PKA activity is essential for culmination. Moreover, overexpressing DdPK3 in wild-type cells on integrating vectors (high copy number) from either an actin or prespore-specific promoter results in accelerated development and the ability to form mature spores in monolayer culture in the presence of high cAMP, a developmental potential lacking in wild-type cells.

Analysis of a spatially regulated phosphotyrosine phosphatase identifies tyrosine phosphorylation as a key regulatory pathway in Dictyostelium

We have cloned a Dictyostelium phosphotyrosine phosphatase (PTP1) with a catalytic domain showing approximately 38%-50% amino acid identity to those of other PTPs. PTP1 contains an approximately 99 amino acid insert and bacterially produced PTP1 possesses PTP activity. PTP1 is expressed at a very low level in vegetative cells, induced by 4 hr, and maximally expressed at the tight aggregate stage. PTP1-lacZ studies indicate that PTP1 is spatially localized to prestalk and anterior-like cell types. PTP1 gene disruptants show accelerated development, whereas strains overexpressing PTP1 to a high level fail to aggregate. Strains overexpressing moderate levels exhibit severe morphological defects following aggregation, including multiply tipped aggregates and morphologically aberrant fruiting bodies. Western blot analysis using anti-phosphotyrosine antibodies shows specific changes in the mutant strains when compared with wild-type cells. The results indicate that reversible protein-tyrosine phosphorylation and PTP1 play important regulatory roles during Dictyostelium development.

Amino acid substitutions in the Dictyostelium G alpha subunit G alpha 2 produce dominant negative phenotypes and inhibit the activation of adenylyl cyclase, guanylyl cyclase, and phospholipase C

Previous studies have demonstrated that the Dictyostelium G alpha subunit G alpha 2 is essential for the cAMP-activation of adenylyl cyclase and guanylyl cyclase and that g alpha 2 null mutants do not aggregate. In this manuscript, we extend the analysis of the function of G alpha 2 in regulating downstream effectors by examining the in vivo developmental and physiological phenotypes of both wild-type and g alpha 2 null cells carrying a series of mutant G alpha 2 subunits expressed from the cloned G alpha 2 promoter. Our results show that wild-type cells expressing G alpha 2 subunits carrying mutations G40V and Q208L in the highly conserved GAGESG (residues 38-43) and GGQRS (residues 206-210) domains, which are expected to reduce the intrinsic GTPase activity, are blocked in multicellular development. Analysis of down-stream effector pathways essential for mediating aggregation indicates that cAMP-mediated activation of guanylyl cyclase and phosphatidylinositol-phospholipase C (PI-PLC) is almost completely inhibited and that there is a substantial reduction of cAMP-mediated activation of adenylyl cyclase. Moreover, neither mutant G alpha 2 subunit can complement g alpha 2 null mutants. Expression of G alpha 2(G43V) and G alpha 2(G207V) have little or no effect on the effector pathways and can partially complement g alpha 2 null cells. Our results suggest a model in which the dominant negative phenotypes resulting from the expression of G alpha 2(G40V) and G alpha 2(Q208L) are due to a constitutive adaptation of the effectors through a G alpha 2-mediated pathway. Analysis of PI-PLC in g alpha 2 null mutants and in cell lines expressing mutant G alpha 2 proteins also strongly suggests that G alpha 2 is the G alpha subunit that directly activates PI-PLC during aggregation. Moreover, overexpression of wild-type G alpha 2 results in the ability to precociously activate guanylyl cyclase by cAMP in vegetative cells, suggesting that G alpha 2 may be rate limiting in the developmental regulation of guanylyl cyclase activation. In agreement with previous results, the activation of adenylyl cyclase, while requiring G alpha 2 function in vivo, does not appear to be directly carried out by the G alpha 2 subunit. Our data are consistent with adenylyl cyclase being directly activated by either another G alpha subunit or by beta gamma subunits released on activation of the G protein containing G alpha 2.

Chemotactic sorting to cAMP in the multicellular stages of Dictyostelium development

Dictyostelium transformants that overproduce the extracellular form of cyclic nucleotide phosphodiesterase and so accumulate a reduced amount of cAMP are blocked in development after aggregation in the form of a tight mound, prior to formation of the apical tip. In such mounds, prespore cell differentiation is repressed, and the apical accumulation of prestalk cells is greatly retarded. When a source of cAMP is placed below the arrested mounds, prestalk cells that would normally migrate in an apical direction instead sort downwards to the substratum. Thus, by acting as the chemoattractant that draws prestalk cells to the apex, cAMP signaling directs the formation of a patterned structure.

A G-rich sequence element common to Dictyostelium genes which differ radically in their patterns of expression

Removal of a G-rich element from the DIF-inducible, prestalk-, and stalk-specific ecmB gene reduces expression but cell-type specificity is retained. The ecmB element will functionally substitute for a homologous sequence upstream of CP2, a cAMP-inducible gene and is bound by GBF, the factor which interacts with the CP2 G box. These results suggest that the G box may play a similar stimulatory role in these two independently regulated genes where it presumably interacts with different ancillary promoter elements.

Characterization of phospholipase activity in Dictyostelium discoideum. Identification of a Ca(2+)-dependent polyphosphoinositide-specific phospholipase C

We have identified a Ca(2+)-dependent polyphosphoinositide-specific phospholipase C activity in Dictyostelium discoideum. Addition of Ca2+ (20 microM) results in the rapid formation of Ins(1,4,5)P3 within 5 s and leads to sustained inositol phosphate production for up to 40 min in membranes prepared from [3H]inositol-labelled cells. The phospholipase C activity is primarily membrane-bound under the conditions used to lyse the cells. In addition to this activity we also identified a family of Ca(2+)-regulated phospholipase activities active on a range of phospholipid substrates, using [3H]palmitate labelling. Inositol-specific phospholipase C activity is highest in vegetatively growing cells and in starved cells during the first 6 h in development, during which time Ca2+ elicited a 5-fold stimulation of inositol phosphate formation. After this time, total activity decreased progressively until 15 h, after which the activity remained constant up until 24 h. During this period, Ca2+ was able to stimulate a 2-fold increase in inositol phosphates.

Regulation of the Dictyostelium cAMP-induced, prestalk-specific DdrasD gene: identification of cis-acting elements

We have shown previously that expression of the Dictyostelium ras gene DdrasD (previously denoted Ddras) is induced during multicellular development and in single-cell shaking culture in response to cAMP (1). Analysis of transformants carrying DdrasD/lacZ reporter constructs showed DdrasD expression to be prestalk-specific (2). The gene is transcribed from three start sites with transcription from the distal site producing an approximately 1.2 kb transcript, which is expressed at low levels in growing cells and is subsequently induced late in aggregation. This promoter is also induced to high levels by cAMP. Transcription from the two more proximal sites is coregulated and is induced during development, resulting in approximately 1.0 kb transcripts. In this study, we examine cis-acting regions required for proper regulation of DdrasD expression using a DdrasD/beta-glucuronidase reporter gene construct. We have identified distinct sequence elements required for developmental and vegetative expression of DdrasD. A domain containing a CA repeat, similar to ones found in other late, cAMP-induced Dictyostelium genes, is required for cAMP-induced and developmental expression.

Incorporation of protein into spore coats is not cell autonomous in Dictyostelium

At maturity, the spores of Dictyostelium are suspended in a viscous fluid droplet, with each spore being surrounded by its own spore coat. Certain glycoproteins characteristic of the spore coat are also dissolved in this fluid matrix after the spore coat is formed. To determine whether any proteins of the coat reside in this fluid phase earlier during the process of spore coat assembly, pairs of strains which differed in a spore coat protein carbohydrate marker were mixed and allowed to form spore coats in each other's presence. We reasoned that proteins belonging to an early, soluble, extracellular pool would be incorporated into the spore coats of both strains. To detect trans-incorporation, spores were labeled with a fluorescent antibody against the carbohydrate marker and each spore's fluorescence was analyzed by flow cytometry. Several proteins of both the outer and inner protein layers of the coat appeared to be faithfully and reciprocally trans-incorporated and hence judged to belong to a soluble, assembly-phase pool. Western blot analysis of sorted spores, and EM localization, confirmed this conclusion. In contrast, one outer-layer protein was not trans-incorporated, and was concluded to be insoluble at the time of secretion. Three classes of spore coat proteins can be described: (a) Insoluble from the time of secretion; (b) present in the early, soluble pool but not the late pool after spore coat formation; and (c) present in the soluble pool throughout spore coat assembly. These classes may, respectively: (a) Nucleate spore coat assembly; (b) comprise a scaffold defining the dimensions of the nascent spore coat; and (c) complete the assembly process by intercalation into the scaffold.

Protein binding and DNase-I-hypersensitive sites in the cis-acting regulatory region of the spore-coat SP96 gene of Dictyostelium

The spore-coat protein gene (SP96) of Dictyostelium discoideum is transcribed only in prespore cells. To identify the cis-acting region of this gene, mutant mini-genes which contained different lengths of 5' upstream region, the partially deleted SP96 coding region and ca. 600 bp of 3' flanking sequence were transformed into D. discoideum cells. Expression of the mini-genes was analysed by Northern hybridization. Our results indicate that the 5' upstream region from -686 to -494 contains an important cis-acting element for the temporal and cell type-specific transcription. A nuclear factor which specifically bound the cis-acting region was identified by gel retardation assay. DNase-I-hypersensitivity of the 5' upstream region was examined and it was shown that the appearance of two new hypersensitive sites correlates with transcriptional activation of the gene. One of the two sites maps to the TATA region and the other was located in the cis-acting region identified by deletion analysis. Our results suggest that gene activation occurs by conformational changes in the chromatin structure of the cis-acting region followed by subsequent binding of regulatory factors and the TATA-binding protein.

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. Cells that overexpress the G alpha 4 gene (G alpha 4HC) also show reduced spore production but display an aberrant morphological phenotype distinct from that of g alpha 4 cells. The g alpha 4 phenotype can be partially rescued by the presence of wild-type or G alpha 4HC cells in chimeric organisms, suggesting that G alpha 4-expressing cells produce an intercellular signal that is essential for multicellular development.

Regulation of cellular differentiation during Dictyostelium morphogenesis

In Dictyostelium there are multiple prestalk cell types that have a complex pattern of directed cell movement during slug formation and culmination. Three extracellular signals, cyclic AMP, DIF and ammonia, control cell type differentiation. Recently there has been considerable progress in understanding their modes of action and interaction.

cAMP signal transduction pathways regulating development of Dictyostelium discoideum

Dictyostelium discoideum development is regulated through receptor/G protein signal transduction using cAMP as a primary extracellular signal. Signaling pathways will be discussed as well as the regulation and function of individual cAMP receptors and G alpha subunits. Finally potential downstream targets including protein kinases and nuclear events will be explored.

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. Transcripts from both of these genes are primarily expressed during the multicellular stages of development, suggesting possible roles in cell differentiation or morphogenesis. The entire G alpha 4 gene was sequenced and found to encode a protein consisting of 345 amino acids. The G alpha 4 subunit is homologous to other previously identified G alpha subunits, including the Dictyostelium G alpha 1 (43% identity) and G alpha 2 (41% identity) subunits. However, the G alpha 4 subunit contains some unusual sequence divergences in residues highly conserved among most eukaryotic G alpha subunits, suggesting that G alpha 4 may be a member of another class of G alpha subunits.

A developmentally regulated, putative serine/threonine protein kinase is essential for development in Dictyostelium

Using PCR technology, we have cloned parts of three developmentally regulated putative serine/threonine kinases from Dictyostelium. All show significant homology to members of the cAMP-dependent protein kinase A/protein kinase C subfamilies. A genomic clone encoding one of these, DdPK3, has been isolated and sequenced. The open reading frame encodes a protein of 648 amino acids with the conserved kinase domain in the C-terminal half. The protein encoded by this gene is unusual in that it contains long homopolymer runs in the N-terminal half of the protein, including a long run of 88 amino acids in which 73 are glutamine residues. To examine the function of DdPK3, a gene disruption was created via homologous recombination. Ddpk3- cells do not aggregate by themselves but will co-aggregate with wild-type cells. However, after aggregation these cells are 'sloughed off' and do not proceed further through development, but are found as a discrete mass alongside the fruiting body formed by the wild-type cells. Analysis of signal transduction pathways indicates that cAMP pulse-induced expression of aggregation stage-specific genes is normal in Ddpk3- cells, as is induction of the prestalk gene Ddras in single cell assays. However, cAMP induction of the late promoters of cAMP receptor cAR1 and of two prespore-specific genes is absent under similar conditions. These cells show normal activation of adenylate cyclase and normal phosphorylation of the G alpha protein G alpha 2 in response to cAMP. The possible role of DdPK3 in Dictyostelium development is discussed.

Effects of protein synthesis inhibition on the transcription and transcript stability of Dictyostelium prespore genes

The in vivo accumulation of several prespore transcripts of Dictyostelium discoideum has previously been shown to depend upon concomitant protein synthesis (Ratner, D.I., Pentz, W.H. and Pelletier, D.A. (1989) Biochim. Biophys. Acta 1008, 71-78). Measurements of in vivo mRNA decay and nuclear run-on transcription assays have now been used to learn whether protein synthesis is required primarily for mRNA synthesis or transcript stability. The translational inhibitors cycloheximide and pactamycin stabilized existing prespore transcripts, despite their effect upon mRNA accumulation. Transcriptional assays, performed at intervals throughout the developmental cycle, demonstrated that temporal changes in the abundance of several cell-specific transcripts correlated closely with changes in their rates of synthesis. Finally, blocking protein synthesis strongly inhibited the transcription of the prespore genes examined. These results imply that one or more developmentally regulated, labile proteins are needed for the activation of prespore gene transcription.

Unexpected localisation of cells expressing a prespore marker of Dictyostelium discoideum

We show that the anterior, prestalk region of the Dictyostelium slug contains cells which express, or have expressed, a prespore-specific marker. We term these cells "prespore-like cells" (PLC). In newly formed slugs there is a sharp prespore/prestalk boundary, with very few PLC, but after several days of migration the clear demarcation between prespore and prestalk zones breaks down because the number of PLC increases dramatically. This is consistent with previous observations showing there to be rapid interchange of cells between the prestalk and prespore regions. This is not, however, their only source, as a scattering of PLC appear when separate prestalk and prespore regions first become apparent at the time of tip formation. Also, at culmination, there is respecification of "prespore" cells at the prestalk/prespore boundary to form part of the mature stalk. The existence of these cells, and of PLC, may explain why we find prespore-specific mRNAs in mature stalk cells.