Cytochemical localization of alkaline phosphatase in the cell membrane of Dictyostelium discoideum amebae

Distribution of alkaline phosphatase in vegetative dictyostelium cells in relation to the contractile vacuole complex

The structure of the contractile vacuole complex of Dictyostelium discoideum has long been a subject of controversy. A model that originated from the work of John Heuser and colleagues described this osmoregulatory organelle as an interconnected array of tubules and cisternae the membranes of which are densely populated with vacuolar proton pumps. A conflicting model described this same organelle as bipartite, consisting of a pump-rich spongiome and a pump-free bladder, the latter membranes being identified by their alkaline phosphatase activity. In the present study we have employed an antiserum specific for Dictyostelium alkaline phosphatase to examine the distribution of this enzyme in vegetative cells. The antiserum labels puncta, probably vesicles, that lie at or near the plasma membrane and are sometimes, but only rarely, enriched near contractile vacuole membranes. We conclude that alkaline phosphatase is not a suitable marker for contractile vacuole membranes. We discuss these results in relation to the two models of contractile vacuole structure and suggest that all data are consistent with the first model.

Analysis of 5' nucleotidase and alkaline phosphatase by gene disruption in Dictyostelium

In Dictyostelium discoideum a phosphatase with a high pH optimum is known to increase in activity during cell differentiation and become localized to a narrow band of cells at the interface of prespore and prestalk cells. However, it was not clear if this activity is due to a classical "alkaline phosphatase" with broad range substrate specificity or to a "5'nucleotidase" with high substrate preference for 5'AMP. We attempted to disrupt the genes encoding these two phosphatase activities in order to determine if the activity that is localized to the interface region resides in either of these two proteins. During aggregation of 5nt null mutants, multiple tips formed rather than the normal single tip for each aggregate. In situ phosphatase activity assays showed that the wt and the 5nt gene disruption clones had normal phosphatase activity in the area between prestalk and prespore cell types, while the alp null mutants did not have activity in this cellular region. Thus, the phosphatase activity that becomes localized to the interface of the prestalk and prespore cells is alkaline phosphatase.

Purification and renaturation of Dictyostelium recombinant alkaline phosphatase by continuous elution electrophoresis

A 1583 bp fragment of Dictyostelium alp cDNA (94% of the gene) was cloned in pET32a+. The enzyme was expressed in an inactive form in the inclusion body of the expression host BL21-CodonPlus (DE3)-RIL. The recombinant ALP constituted more than 50% of the total protein in the inclusion body and 25-30% of the total protein in the expression host after 3 h induction with IPTG at 37 degrees C. A continuous elution polyacrylamide gel electrophoresis procedure was used to purify the recombinant enzyme. This technique yielded a homogeneous protein that retained enzymatic activity after dialysis without further treatment. A yield of 5mg per liter of culture broth was obtained with a specific activity of approximately 0.7 nmol/min/mg protein (0.7 mU/mg). Immunoinhibition studies using a polyclonal antibody produced against the recombinant protein showed complete inhibition of enzymatic activity when the enzyme was preincubated with the antibody at a 1:1000 dilution. The enzyme exhibited a pH optimum of approximately 9.0. The substrate specificity indicated that the Dictyostelium enzyme is a typical broad range alkaline phosphatase.

Expression pattern of alkaline phosphatase in Dictyostelium

We used two different methods to study the expression pattern of alkaline phosphatase (alp) in Dictyostelium. In situ staining of the endogenous enzyme activity at different stages of development showed that the enzyme was active early in the aggregation stage and localized to the area where the tip of the first finger was initiated. The activity was localized to the anterior region of developing slugs, then became restricted to the region between the prestalk and prespore cells at the culmination stage. In the complete fruiting body, the activity was confined to the lower and upper cup. A second method to study alp expression utilized a beta-galactosidase reporter gene under the control of the alp promoter. A low level of beta-galactosidase activity was observed in vegetative cells, then increased during development. Reporter gene activity was restricted to PstO cells at the slug stage. At the culmination stage, the expression was restricted to prestalk cells at the interface between the prestalk and prespore cells. In the completed fruiting body, the expression was observed in the upper and lower cup.

5'-Nucleotidase in Dictyostelium: protein purification, cloning, and developmental expression

5'-Nucleotidase (5NU) in Dictyostelium discoideum is an enzyme that shows high substrate specificity to 5'-AMP. The enzyme has received considerable attention in the past because of the critical role played by cyclic AMP in cell differentiation in this organism. Degradation of cAMP by cAMP phosphodiesterase (PDE) produces 5'-AMP, the substrate of 5NU. During the time course of development, the enzyme activity of 5NU increases and becomes restricted to a narrow band of cells that form the interface between the prestalk/prespore zones. We have purified a polypeptide associated with 5NU enzyme activity. Protein sequence of this peptide was obtained from mass spectrometry and Edman degradation. Polymerase chain reaction PCR amplification of genomic DNA using degenerate oligonucleotides and a search of sequences of a cDNA project yielded DNA fragments with sequence corresponding to the peptide sequence of 5NU. In addition, a clone was found that corresponded to the classical 'alkaline phosphatase' (AP) as described in several organisms. The sequences of the 5NU and AP cDNAs were not similar, indicating they are the products of separate genes and that both genes exist in Dictyostelium. Analysis of the expression of 5nu during Dictyostelium development by Northern blotting determined that the gene is developmentally regulated. Southern blot analysis showed a single form of the 5nu gene. Targeted gene disruption and knockout mutagenesis using the 5nu sequences suggested that a 5nu mutation may be lethal.

The prespore vesicles of Dictyostelium discoideum. Purification, characterization, and developmental regulation

The coordinate fusion of the prespore vesicles (PSVs) with the plasma membrane at the terminal stage of spore differentiation in Dictyostelium discoideum is an important example of developmentally regulated protein secretion. However, little is known about the composition of the vesicles, the molecular signals regulating secretion, or the mechanics of the membrane fusion. Taking a biochemical approach, we purified PSVs from different developmental stages. These preparations are highly enriched for their specific cargo of spore coat proteins while devoid of markers for other cellular compartments. Electron microscopic observations show that the PSV preparations are homogenous, with the soluble spore coat protein PsB/SP85 distributed throughout the lumen and the acid mucopolysaccharide localized in the central core. During development the PSVs increase in size and density concomitant with an increase in their protein cargo. The PSVs contain approximately 80 proteins, and we have identified a PSV-specific GTP-binding protein that may be involved in regulating vesicle fusion. The PSVs are not clathrin-coated and do not contain the SpiA spore coat protein. The PSV preparations are ideal for a global proteome analysis to identify proteins involved in signal reception, vesicle movement, docking, and fusion in this developmentally regulated organelle.

A voltage- and K+-dependent K+ channel from a membrane fraction enriched in contractile vacuole of Dictyostelium discoideum

We obtained a membrane fraction enriched in the contractile vacuole by aqueous-polymer two-phase partitioning and its channel activities were analysed by incorporating it into artificial planar lipid bilayers. In asymmetrical KCl solutions (cis, 300 mM/100 mM, trans), we observed single-channel currents of a highly K(+)-selective channel with slope conductance of 102 pS and reversal potential of -20.4 mV, which corresponded to PK+/PCl- = 7. They showed bursts separated by infrequent quiescent periods. At 0 mV the mean open time was 2.0 ms. Among monovalent cations, Na+ and Li+ were impermeable, whereas Rb+ showed permeability equivalent to that of K+, although the unitary conductance was apparently reduced when the current flowed from the Rb+ containing side, suggesting that Rb+ is a permeant blocking ion. The open probability within bursts remained constant at approx.0.6 as long as the holding potential was positive on the cis side with respect to the trans side, but it decreased to 0 at negative potential. This channel was blocked by submillimolar concentrations of quinine and 30 mM TEA+. The open probability-voltage relationship showed a striking dependency on the KCl concentration on either side. This channel may play a role in water transport in this organelle.

Identification of a high-affinity Ca2+ pump associated with endocytotic vesicles in Dictyostelium discoideum

In the cellular slime mold Dictyostelium discoideum, changes in free cytosolic Ca2+ are thought to regulate certain processes during cell aggregation and differentiation. To understand the mechanisms controlling free Ca2+ levels in this organism, we previously isolated and characterized an ATP/Mg2+-dependent, high-affinity Ca2+ pump which appeared to be a component of "inside-out" plasma membrane vesicles [J. L. Milne and M. B. Coukell (1988) Biochem. J. 249. 223-230]. In this report, we demonstrate that a high-affinity Ca2+ pump, with properties virtually identical to the isolated pump, can be detected in filipin- or digitonin-permeabilized cells of Dictyostelium. Moreover, Ca2+-pumping vesicles, which migrate on Percoll/KCl gradients like the vesicles identified earlier, can be isolated from the permeabilized cells. Results of additional experiments suggest that this intracellular Ca2+ transporter is associated with a high-capacity non-IP3-releasable Ca2+ store which is generated by endocytosis. A possible role for this store in maintaining Ca2+ homeostasis in Dictyostelium is discussed.

Isolation and characterization of a plasma membrane calcium pump from Dictyostelium discoideum

During the aggregation and differentiation of amoebae of Dictyostelium discoideum, changes in free cytosolic Ca2+ appear to regulate a number of physiological processes. To understand the mechanisms regulating free intracellular Ca2+ in this organism, we have isolated and characterized an ATP/Mg2+-dependent, high-affinity Ca2+ pump. When homogenates of 2 h starved cells were fractionated on Percoll/KCl gradients, one peak of high-affinity Ca2+-pumping activity was detected. This activity was resolved from enzyme markers of the mitochondrion and the rough endoplasmic reticulum but it cosedimented with the plasma membrane marker, alkaline phosphatase. Further studies suggested that the pump was associated with 'inside-out' plasma membrane vesicles. Like plasma membrane Ca2+-transport ATPases from other systems, this isolated Ca2+ pump: (1) was Mg2+-dependent, (2) displayed a high specificity for ATP as an energy source, (3) exhibited a high affinity for free Ca2+ with a Km of 0.3 microM, and (4) was very sensitive to inhibition by vanadate (IC50 2 microM) but was unaffected by mitochondrial inhibitors, ouabain and Ca2+-channel blockers. Unlike plasma membrane Ca2+ pumps from most other systems, this enzyme appeared not to be regulated by calmodulin. During development, non-mitochondrial, vanadate-sensitive, high-affinity Ca2+-pumping activity in crude lysates remained relatively constant for at least 15 h. These observations suggest that this plasma membrane Ca2+ pump probably functions in Dictyostelium to maintain Ca2+ homeostasis by extruding free cytosolic Ca2+ from the cells.