Extracellular Phosphodiesterase Research Articles

Adenylate cyclase A amplification and functional diversification during Polyspondylium pallidum development

BackgroundIn Dictyostelium discoideum (Ddis), adenylate cyclase A (ACA) critically generates the cAMP oscillations that coordinate aggregation and morphogenesis. Unlike group 4 species like Ddis, other groups do not use extracellular cAMP to aggregate. However, deletion of cAMP receptors (cARs) or extracellular phosphodiesterase (PdsA) in Polyspondylium pallidum (Ppal, group 2) blocks fruiting body formation, suggesting that cAMP oscillations ancestrally control post-aggregative morphogenesis. In group 2, the acaA gene underwent several duplications. We deleted the three Ppal aca genes to identify roles for either gene and tested whether Ppal shows transient cAMP-induced cAMP accumulation, which underpins oscillatory cAMP signalling.ResultsIn contrast to Ddis, pre-aggregative Ppal cells did not produce a pulse of cAMP upon stimulation with the cAR agonist 2′H-cAMP, but acquired this ability after aggregation. Deletion of Ppal aca1, aca2 and aca3 yielded different phenotypes. aca1ˉ cells showed relatively thin stalks, aca2ˉ showed delayed secondary sorogen formation and aca3ˉ formed less aggregation centers. The aca1ˉaca2ˉ and aca1ˉaca3ˉ mutants combined individual defects, while aca2ˉaca3ˉ and aca1ˉaca3ˉaca2ˉ additionally showed > 24 h delay in aggregation, with only few aggregates with fragmenting streams being formed. The fragments developed into small fruiting bodies with stalk and spore cells. Aggregation was restored in aca2ˉaca3ˉ and aca1ˉaca3ˉaca2ˉ by 2.5 mM 8Br-cAMP, a membrane-permeant activator of cAMP-dependent protein kinase (PKA). Like Ddis, Ppal sorogens also express the adenylate cyclases ACR and ACG. We found that prior to aggregation, Ddis acaˉ/ACG cells produced a pulse of cAMP upon stimulation with 2′H-cAMP, indicating that cAMP oscillations may not be dependent on ACA alone.ConclusionsThe three Ppal replicates of acaA perform different roles in stalk morphogenesis, secondary branch formation and aggregation, but act together to enable development by activating PKA. While even an aca1ˉaca3ˉaca2ˉ mutant still forms (some) fruiting bodies, suggesting little need for ACA-induced cAMP oscillations in this process, we found that ACG also mediated transient cAMP-induced cAMP accumulation. It, therefore, remains likely that post-aggregative Ppal morphogenesis is organized by cAMP oscillations, favouring a previously proposed model, where cAR-regulated cAMP hydrolysis rather than its synthesis dominates oscillatory behaviour.

Robustness of Self-Organizing Chemoattractant Field Arising from Precise Pulse Induction of Its Breakdown Enzyme: A Single-Cell Level Analysis of PDE Expression in Dictyostelium

The oscillation of chemoattractant cyclic AMP (cAMP) in Dictyostelium discoideum is a collective phenomenon that occurs when the basal level of extracellular cAMP exceeds a threshold and invokes cooperative mutual excitation of cAMP synthesis and secretion. For pulses to be relayed from cell to cell repetitively, secreted cAMP must be cleared and brought down to the subthreshold level. One of the main determinants of the oscillatory behavior is thus how much extracellular cAMP is degraded by extracellular phosphodiesterase (PDE). To date, the exact nature of PDE gene regulation remains elusive. Here, we performed live imaging analysis of mRNA transcripts for pdsA—the gene encoding extracellular PDE. Our analysis revealed that pdsA is upregulated during the rising phase of cAMP oscillations. Furthermore, by analyzing isolated cells, we show that expression of pdsA is strictly dependent on the presence of extracellular cAMP. pdsA is induced only at ∼1 nM extracellular cAMP, which is almost identical to the threshold concentration for the cAMP relay response. The observed precise regulation of PDE expression together with degradation of extracellular cAMP by PDE form a dual positive and negative feedback circuit, and model analysis shows that this sets the cAMP level near the threshold concentration for the cAMP relay response for a wide range of adenylyl cyclase activity. The overlap of the thresholds could allow oscillations of chemoattractant cAMP to self-organize at various starving conditions, making its development robust to fluctuations in its environment.

Involvement of cyclic adenosine monophosphate in the control of motile behavior of Physarum polycephalum plasmodium

Possible involvement of autocrine factors into the control of motile behavior via a receptor-mediated mechanism was investigated in Physarum polycephalum plasmodium, a multinuclear amoeboid cell with the auto-oscillatory mode of motility. Cyclic adenosine monophosphate (cAMP) and extracellular cAMP-specific phosphodiesterase, its involvement into the control of plasmodium motile behavior was proved by action of its strong inhibitor, were regarded as putative autocrine factors. It was shown that the plasmodium secreted cAMP. When it was introduced into agar support, 0,1-1 mM cAMP induced a delay of the plasmodium spreading and its transition to migration. When locally applied, cAMP at the same concentrations induced typical for attractant action the increase in oscillation frequency and the decrease of ectoplasm elasticity. The ability to exhibit positive chemotaxis in cAMP gradient and the dependence of its realization were shown to depend on the plasmodium state. Chemotaxis test specimens obtained from the migrating plasmodium, unlike those obtained from growing culture, generate alternative fronts which compete effectively with fronts oriented towards the attractant increment. The results obtained support our supposition stated earlier that advance of the Physarum polycephalum plasmodium leading edge is determined by local extracellular cAMP gradients arising from a time delay between secretion and hydrolysis of the nucleotide.

The effects of inhibitors and magnesium ions on the activity of the thermostable extracellular cAMP-Specific phosphodiesterase of Physarum polycephalum plasmodium

Plasmodium of myxomycete Physarum polycephalum produces cyclic nucleotide phosphodiesterase (PDE). The extracellular PDE is cAMP-specific and highly thermostable. This study demonstrates that the extracellular PDE of Ph. polycephalum is weakly inhibited by caffeine, isobutylmethylxantine and theophiline (type I mammalian PDE nonspecific inhibitors), dipyridamole (mammalian PDE5, PDE6, PDE8 and PDE10 inhibitors), and erythro-9-[3-(2-hydroxynonyl)]-adenine (mammalian PDE2 inhibitor). The enzyme does not require Mg2+ for the activity. The results show that the Ph. polycephalum extracellular PDE differs from class I PDEs, represented by mammalian PDE1-PDE11, and, most likely, belongs to a poorly investigated class II PDEs.

Current standard assays using artificial substrates overestimate phosphodiesterase activity

Phosphodiesterases (PDE) are important enzymes in environments with significant proportion of phosphodiesters. The breakdown of phosphodiesters is a two step process, initiated by PDE hydrolyzing an ester-P bond on the diester molecule, breaking it into an organic moiety and a phosphomonoester. In the second step, the phosphomonoester is further hydrolyzed by phosphomonoesterase (PME) into the second organic moiety and free phosphate, Pi. The methods to assess extracellular PDE activities commonly use the substrate analogues bis-(p-nitrophenyl) phosphate (bis-pNPP) or bis-(4-methylumbelliferyl) phosphate (bis-MUFP), measure the resulting concentration of p-nitrophenol (pNP) or 4-methylumbelliferon (MUF), and assume the contribution from phosphomonoester hydrolysis by PME to be insignificant. To verify this, we measured concentrations of MUF and Pi at the end of the 30- and 60-min incubation of wetland plant root segments with a phosphodiester substrate. We found that the hydrolysis was complete (MUF:Pi ratio ∼ 2) confirming the importance of step 2. We suggest that a correction for additional hydrolysis by PME should be employed in samples where this is possible, such as plant roots or microbial cultures. Here, the MUF:Pi should be verified for each new sample type tested for its PDE activity, and values obtained from the PDE assay should be lowered accordingly. We do not recommend using the standard artificial substrates for PDE activity measurements in more heterogeneous samples, for example soils, where these assays have low reliability and can produce erroneous results.

Involvement of extracellular cAMP-specific phosphodiesterase in the control of motile activity of Physarum polycephalum plasmodium

Possible involvement of extracellular cAMP-specific phosphodiesterase in the control of cell motile behavior has been investigated in Physarum polycephalum plasmodium, a multinuclear amoeboid cell with the autooscillatory mode of motility. It was found that the rate of the hydrolysis of 10 mM cAMP by a partially purified preparation of cAMP-specific phosphodiesterase secreted by the plasmodium in the course of migration decreases 20-30 times under the action of 1 mM dithiothreitol. In the presence of 1-5 mM of this strong reducing agent, the onset of the plasmodium spreading and the transition to the stage of migration were delayed in a concentration-dependent manner. In accordance with the morphological pattern of motile behavior, the duration of the maintenance of high frequency autooscillations, which normally precede the increase in the rate of the spreading and appear also in response to the application of attractants at spatially uniform concentrations, strongly increased by the action of dithiothreitol. The results obtained suggest that the autocrine production of cAMP and extracellular cAMP-specific phosphodiesterase is an important constituent of the mechanism controlling the motile behavior of the Physarum polycephalum plasmodium.

The Group Migration of Dictyostelium Cells Is Regulated by Extracellular Chemoattractant Degradation

Starvation of Dictyostelium induces a developmental program in which cells form an aggregate that eventually differentiates into a multicellular structure. The aggregate formation is mediated by directional migration of individual cells that quickly transition to group migration in which cells align in a head-to-tail manner to form streams. Cyclic AMP acts as a chemoattractant and its production, secretion, and degradation are highly regulated. A key protein is the extracellular phosphodiesterase PdsA. In this study we examine the role and localization of PdsA during chemotaxis and streaming. We find that pdsA(-) cells respond chemotactically to a narrower range of chemoattractant concentrations compared with wild-type (WT) cells. Moreover, unlike WT cells, pdsA(-) cells do not form streams at low cell densities and form unusual thick and transient streams at high cell densities. We find that the intracellular pool of PdsA is localized to the endoplasmic reticulum, which may provide a compartment for storage and secretion of PdsA. Because we find that cAMP synthesis is normal in cells lacking PdsA, we conclude that signal degradation regulates the external cAMP gradient field generation and that the group migration behavior of these cells is compromised even though their signaling machinery is intact.

Generating Biological Oscillations

Biochemical oscillations exist in nature; however, relatively little is known about the molecular circuits underlying these oscillations. An example of such an oscillation is found in the periodic pulses of cyclic adenosine monophosphate (cAMP) in Dictyostelium during development. Components of this oscillation include the cAMP receptor, adenylyl cyclase, extracellular phosphodiesterase, intracellular phosphodiesterase, cAMP-dependent protein kinase, and mitogen-activated protein (MAP) kinase 4. Maeda et al. provide experimental data to further elucidate the circuitry and show that phosphodiesterase RegA is directly regulated by the phosphorylating activity of the MAP kinase ERK2. Simulations show that the circuit would be effective in producing oscillations over a sustained period. M. Maeda, S. Lu, G. Shaulsky, Y. Miyazaki, H. Kuwayama, Y. Tanaka, A. Kuspa, W. F. Loomis, Periodic signaling controlled by an oscillatory circuit that includes protein kinases ERK2 and PKA. Science 304 , 875-878 (2004). [Abstract] [Full Text]

Glycerophosphocholine metabolism in higher plant cells. Evidence of a new glyceryl-phosphodiester phosphodiesterase.

Glycerophosphocholine (GroPCho) is a diester that accumulates in different physiological processes leading to phospholipid remodeling. However, very little is known about its metabolism in higher plant cells. (31)P-Nuclear magnetic resonance spectroscopy and biochemical analyses performed on carrot (Daucus carota) cells fed with GroPCho revealed the existence of an extracellular GroPCho phosphodiesterase. This enzymatic activity splits GroPCho into sn-glycerol-3-phosphate and free choline. In vivo, sn-glycerol-3-phosphate is further hydrolyzed into glycerol and inorganic phosphate by acid phosphatase. We visualized the incorporation and the compartmentation of choline and observed that the major choline pool was phosphorylated and accumulated in the cytosol, whereas a minor fraction was incorporated in the vacuole as free choline. Isolation of plasma membranes, culture medium, and cell wall proteins enabled us to localize this phosphodiesterase activity on the cell wall. We also report the existence of an intracellular glycerophosphodiesterase. This second activity is localized in the vacuole and hydrolyzes GroPCho in a similar fashion to the cell wall phosphodiesterase. Both extra- and intracellular phosphodiesterases are widespread among different plant species and are often enhanced during phosphate deprivation. Finally, competition experiments on the extracellular phosphodiesterase suggested a specificity for glycerophosphodiesters (apparent K(m) of 50 microM), which distinguishes it from other phosphodiesterases previously described in the literature.

Induction of an extracellular cyclic nucleotide phosphodiesterase as an accessory ribonucleolytic activity during phosphate starvation of cultured tomato cells.

During growth under conditions of phosphate limitation, suspension-cultured cells of tomato (Lycopersicon esculentum Mill.) secrete phosphodiesterase activity in a similar fashion to phosphate starvation-inducible ribonuclease (RNase LE), a cyclizing endoribonuclease that generates 2':3'-cyclic nucleoside monophosphates (NMP) as its major monomeric products (T. Nürnberger, S. Abel, W. Jost, K. Glund [1990] Plant Physiol 92: 970-976). Tomato extracellular phosphodiesterase was purified to homogeneity from the spent culture medium of phosphate-starved cells and was characterized as a cyclic nucleotide phosphodiesterase. The purified enzyme has a molecular mass of 70 kD, a pH optimum of 6.2, and an isoelectric point of 8.1. The phosphodiesterase preparation is free of any detectable deoxyribonuclease, ribonuclease, and nucleotidase activity. Tomato extracellular phosphodiesterase is insensitive to EDTA and hydrolyzes with no apparent base specificity 2':3'-cyclic NMP to 3'-NMP and the 3':5'-cyclic isomers to a mixture of 3'-NMP and 5'-NMP. Specific activities of the enzyme are 2-fold higher for 2':3'-cyclic NMP than for 3':5'-cyclic isomers. Analysis of monomeric products of sequential RNA hydrolysis with purified RNase LE, purified extracellular phosphodiesterase, and cleared -Pi culture medium as a source of 3'-nucleotidase activity indicates that cyclic nucleotide phosphodiesterase functions as an accessory ribonucleolytic activity that effectively hydrolyzes primary products of RNase LE to substrates for phosphate-starvation-inducible phosphomonoesterases. Biosynthetical labeling of cyclic nucleotide phopshodiesterase upon phosphate starvation suggests de novo synthesis and secretion of a set of nucleolytic enzymes for scavenging phosphate from extracellular RNA substrates.

Evidence that the RdeA protein is a component of a multistep phosphorelay modulating rate of development in Dictyostelium.

We have isolated an insertional mutant of Dictyostelium discoideum that aggregated rapidly and formed spores and stalk cells within 14 h of development instead of the normal 24 h. We have shown by parasexual genetics that the insertion is in the rdeA locus and have cloned the gene. It encodes a predicted 28 kDa protein (RdeA) that is enriched in charged residues and is very hydrophilic. Constructs with the DNA for the c-Myc epitope or for the green fluorescent protein indicate that RdeA is not compartmentalized. RdeA displays homology around a histidine residue at amino acid 65 with members of the H2 module family of phosphotransferases that participate in multistep phosphoryl relays. Replacement of this histidine rendered the protein inactive. The mutant is complemented by transformation with the Ypd1 gene of Saccharomyces cerevisiae, itself an H2 module protein. We propose that RdeA is part of a multistep phosphorelay system that modulates the rate of development.

Inhibition of Insulin Receptor Phosphorylation by PC-1 Is Not Mediated by the Hydrolysis of Adenosine Triphosphate or the Generation of Adenosine

Individuals with insulin resistance show increased levels of PC-1 expression in skeletal muscle and fibroblasts, and in transfected cell lines that overexpress PC-1 there is a reduction in the insulin-stimulated insulin receptor tyrosine phosphorylation. As PC-1 is a type II transmembrane protein with extracellular phosphodiesterase and pyrophosphatase activity, increased expression of PC-1 at the cell surface will decrease extracellular adenosine triphosphate levels and increase extracellular adenosine levels. Consequently it is possible that PC-1-mediated insulin resistance could be caused either by a decrease in adenosine triphosphate or an indirect increase in adenosine levels. We have tested this hypothesis and find that the PC-1-mediated inhibition of insulin-stimulated insulin receptor autophosphorylation is not altered by agents that alter the level or action of adenosine. Further, a mutated PC-1 with a single amino acid change that abolishes the phosphodiesterase and pyrophosphatase activities is still able to inhibit insulin-stimulated insulin receptor phosphorylation. The results of these experiments indicate that the phosphodiesterase activity of PC-1 is not involved in the inhibition of insulin receptor autophosphorylation.

The binding of dinucleoside phosphonates in the active site of the metallo-enzyme, Staphylococcal nuclease: synthetic, solution and preliminary crystallographic studies

Staphylococcal nuclease is a Ca 2+-activated, extracellular phosphodiesterase which degrades DNA or RNA ot 3′-nucleotides. The enzyme is strongly inhibited by deoxythymidine 3′,5′-diphosphate (pdTp). The high resolution crystal structure of the nuclease-pdTp-Ca 2+ complex has facilitated a proposed mechanism of action. However, attempts to test this mechanism in solution have been frustrated by the lack of non-hydrolyzable dinucleotide analogues. Here we report a novel synthesis route for several isoteric phosphonate analogues of pdTpdT. Binding and kinetic experiments show that the phosphonate derivatives competitively inhibit enzymatic activity while stabilizing the protein's tertiary conformation. A description of the active site as seen in the nuclease-dinucleoside phosphate (pcdTpcdT)-Ca 2+ complex at 2.0 Å resolution is presented.

Phosphodiesterase and phosphotriesterase in Rhizobium and Bradyrhizobium strains and their roles in the degradation of organophosphorus pesticides

Of 13 Rhizobium and Bradyrhizobium strains investigated for the production of cellular and extracellular phosphodiesterase and phosphotriesterase, all were found to produce both enzymes. Phosphodiesterase was produced at a much higher level than phosphotriesterase. Rhizobium meliloti TAL 1373 was the most productive. The extracellular enzymes were activated by inclusion in the assay mixture of Ca2+ or Mg2+. The enzymes were inhibited by Zn2+ but not significantly affected by Cu2+, Co2+ and Mn2+. Both hydrolases were inhibited by dithiothreitol but not by thiol-directed inhibitors, suggesting that sulphydryl groups are not directly involved in catalysis. The enzymes have the ability to hydrolyse some organophosphorus compounds, suggesting that Rhizobium and Bradyrhizobium strains play an important role in the degradation of organophosphorus pesticides.

Extracellular cAMP accumulation and degradation in rat cerebral cortex in dissociated cell culture

Norepinephrine (NE) stimulated the accumulation of cAMP in embryonic rat cerebral cortex in dissociated cell culture. After exposure to NE for 10 min, the intracellular cAMP content of these cultures went from 22 +/- 12 to 202 +/- 75 pmol/mg protein. Using selective culturing techniques, evidence was obtained supporting the hypothesis that NE-stimulated production of cAMP is a property associated with the glial rather than the neuronal component of these cultures. Beta adrenergic agonist stimulation of cortical cultures also resulted in the efflux of cAMP into the medium. At the peak of extracellular accumulation of cAMP (following a 40-min exposure to isoproterenol), 180 pmol cAMP/mg protein had been transported into the extracellular medium. The fate of extracellular cAMP was investigated using thin-layer chromatography. Extracellular cAMP was degraded to AMP and adenosine; this degradation did not seem to be due to the presence of serum or serum components, suggesting the existence of an extracellular phosphodiesterase. In response to NE stimulation of glia, in particular astrocytes, cAMP or its metabolites may accumulate at high enough concentrations in the extracellular space in cerebral cortex to affect neuronal function, possibly via adenosine receptors.

The Cyclic Nucleotide Specificity of Eight cAMP-binding Proteins in Dictyostelium discoideum Is Correlated Into Three Groups

cAMP is a mediator of inter- and intracellular events in Dictyostelium discoideum and is thought to act through specific receptors. Eight forms of cAMP-binding proteins have been described in this organism: four forms of a cell surface receptor, a cell surface and extracellular phosphodiesterase, an intracellular cAMP-dependent protein kinase (CAK), and a recently identified cAMP-binding protein (CABP1) that is present on the cell surface, in the cytoplasm, and in the nucleus. In this study we have analyzed the cyclic nucleotide specificity of these cAMP-binding proteins using 13 derivatives of cAMP with modifications in the adenine, ribose, and phosphate moiety. The results suggest that the cAMP-binding proteins belong to three groups: (i) four forms of the cell surface receptor, (ii) two forms of an intracellular receptor (CABP1 and CAK), and (iii) cell surface and extracellular phosphodiesterase. cAMP is probably bound to the surface receptors in the anti conformation in a hydrophobic cleft of the receptor with essential interactions at N6H2' and O3'. In contrast, cAMP is probably bound to CAK and CABP1 in the syn conformation with essential interactions at O2', O3', O5', and exocyclic oxygen. Finally, binding of cAMP to phosphodiesterase involves only O3' and exocyclic oxygen. The cyclic nucleotide specificity of cAMP-induced processes in D. discoideum indicates that the cell surface receptors participate in the transduction of the cAMP signal during chemotaxis and cell differentiation. Functions for CABP1 and CAK in these processes are presently elusive.

Isolation of an aggregation-less mutant of Dictyostelium discoideum with the expression of contact site A glycoprotein.

We isolated mutants defective in aggregation (aggregation-less) by mutagenizing the "double-bypass" mutant HG592 of Dictyostelium discoideum as the parental strain. One of the mutants expressed the contact site A glycoprotein with an apparent molecular weight of 80 X 10(3) on the cell surface in the normal developmental stage and retained EDTA-stable cell contact as well as EDTA-sensitive cell contact. However, the mutant failed to aggregate on agar plates with bacteria. This mutant was designated HG700. We could not identify any differences between this mutant and the parental strain in levels of adenylate cyclase or extracellular phosphodiesterase activity, or in its chemotaxis toward cAMP. The mutant had greatly decreased the incorporation of [35S] sulfate into the particulate fractions of the cells starved for 6 h. This suggests that the modification by sulfation may crucially affect the mechanism of cell aggregation.

Disruption of Dictyostelium discoideum morphogenesis by overproduction of cAMP phosphodiesterase.

The development and cellular differentiation of Dictyostelium discoideum are disrupted in transformants secreting high levels of the cyclic nucleotide phosphodiesterase. The aggregation of these cells in the early stage of development proceeds rapidly and without the formation of organized streams. The later stages of development, in which differentiation into stalk and spore cells normally takes place, are completely blocked so that the transformants remain in spherical clusters of undifferentiated cells that do not elaborate the tip structure that regulates morphogenesis. These effects are due to overproduction of extracellular phosphodiesterase and demonstrate the role of cAMP during the aggregation phase of development as well as in the control of differentiation and pattern formation.

Induction by folate and folate analogs of extracellular and membrane-bound phosphodiesterase from Dictyostelium discoideum.

Folate stimulation is known to enhance Dictyostelium discoideum differentiation. During early differentiation, D. discoideum cells possess two classes of folate receptors which can be distinguished by their difference in specificity (R. J. W. de Wit, FEBS Lett. 150, 445-448, 1982). We investigated the type of receptor by which folate affects cell differentiation. Two independently regulated developmental markers were used: the extracellular phosphodiesterase-inhibitor system and cell-surface phosphodiesterase activity. Our results indicate that the major effect of folate on development is mediated by the folate-specific receptor. The nonspecific folate receptor was only involved in a minor, transient enhancement of the extracellular phosphodiesterase activity very early in development.

Incomplete contact site A glycoprotein in HL220, a modB mutant of Dictyostelium discoideum.

HL220, a modB mutant that lacks a modification of certain membrane proteins of Dictyostelium discoideum, has been shown to aggregate and to form EDTA-stable intercellular contacts typical of aggregating wild-type cells. A developmentally regulated glycoprotein of 80 X 10(3) apparent molecular weight has been identified as a target site of adhesion-blocking Fab and thought to be involved in EDTA-stable cell contact formation (Müller & Gerisch, 1978). In the HL220 mutant this glycoprotein is no longer recognized by a modB-specific antibody. Therefore, it has been suggested that the 80 X 10(3) Mr glycoprotein, or a modification on it, is not required for the EDTA-stable cell contact of aggregating cells. We show that HL220 synthesizes an equivalent of the 80 X 10(3) Mr glycoprotein with an apparent molecular weight of 68 X 10(3). The mutant product reacted with certain monoclonal antibodies highly specific for the 80 X 10(3) Mr glycoprotein in the wild type, and was developmentally regulated like the 80 X 10(3) Mr glycoprotein. These results indicate that the 68 X 10(3) Mr protein of the mutant lacks a modification, most likely an oligosaccharide residue, the absence of which causes the substantial shift of the apparent molecular weight from 80 X 10(3) to 68 X 10(3). Monoclonal antibodies that did not react with proteins of the mutant could be classified according to their reactions with different sub-sets of wild-type proteins. These results indicate that the proteins that reacted with either one or the other antibody were not modified by a uniform structure. The modification rather varies from one sub-set of cross-reacting proteins to another, suggesting differences between the glycosyl residues of the partially cross-reacting proteins. HL220 cells showed strongly reduced EDTA-stable contact formation under our conditions. EDTA-sensitive intercellular adhesion was undetectable in the mutant, whereas adhesion of the cells to the substratum appeared to be strengthened. The rear ends of the cells, in particular, were tightly attached to glass or Teflon surfaces. The mutant cells were capable of responding chemotactically. Propagated excitation waves like those known to be based on periodic cyclic AMP production and relay were clearly seen. Extracellular phosphodiesterase induction by cyclic AMP and phosphodiesterase inhibitor production were normal. These results indicate that the generation of chemotactic signals and the cellular responses to cyclic AMP are not severely affected by the mutation.