Lysosomal enzyme inactivation associated with defects in post-translational modification during development in Dictyostelium discoideum

The developmental accumulation of lysosomal alpha-mannosidase-1 activity in Dictyostelium discoideum is controlled at the level of de novo enzyme precursor biosynthesis. Aggregation-deficient mutants are defective with regard to the accumulation of alpha-mannosidase-1 activity beyond 8-16 h of development. We used enzyme-specific monoclonal antibodies to show that the activity defect in aggregation-deficient strains is not due to a lack of alpha-mannosidase-1-precursor synthesis or processing, or to preferential degradation of the mature enzyme protein. Instead, the defect is a result of enzyme inactivation: cells of aggregation-deficient strains contain significant amounts of inactive alpha-mannosidase-1 protein late in development. The alpha-mannosidase-1 inactivation phenotype is associated with a more general defect in lysosomal enzyme modification. A change in the post-translational modification system occurs during normal slime-mold development, as shown by differences in enzyme isoelectric point, antigenicity, and thermolability. We found that this change in modification does not occur in mutant strains blocked early in development. We propose a model in which pleiotropic mutations in early aggregation-essential genes can indirectly affect the accumulation of alpha-mannosidase-1 activity by preventing the expression of a developmentally controlled change in the post-translational modification system, a change which is required for the stability of several lysosomal enzymes late in development.     

Regulation of lysosomal alpha-mannosidase-1 synthesis during development in Dictyostelium discoideum

The cellular specific activity of lysosomal alpha-mannosidase-1 increases dramatically during development in Dictyostelium discoideum. alpha-Mannosidase-1 is composed of two subunits (Mr = 58,000 and 60,000) which are derived from a common precursor polypeptide (Mr = 140,000). Using enzyme-specific monoclonal antibodies we have determined that throughout development (a) the relative rate of precursor biosynthesis closely parallels the rate of accumulation of cellular enzyme activity and (b) the newly synthesized precursor is efficiently processed to mature enzyme (t1/2 less than 10 min). This indicates that the developmental accumulation of alpha-mannosidase-1 activity is primarily controlled by de novo enzyme synthesis. Furthermore, the change in the relative rate of enzyme precursor synthesis can be accounted for by an increase in the cellular level of functional alpha-mannosidase-1 mRNA during development.     

A late developmental change in lysosomal enzyme sulfation specific to newly synthesized proteins in Dictyostelium discoideum

During development in Dictyostelium discoideum, several lysosomal glycosidases undergo changes in post-translational modification that are thought to involve differences in the extent of sulfation or phosphorylation, and appear to be required for the maintenance of cellular enzyme activity late in development. We have used monoclonal antibodies specific to the lysosomal enzyme alpha-mannosidase-1 to study the major late (12 hr) developmental change in the modification system. Pulse-chase experiments performed both early and late in development reveal that the substrate for the late form of modification is restricted to newly synthesized alpha-mannosidase-1 precursor protein. We have identified one modification difference between the two developmentally distinct isozymes of alpha-mannosidase-1: 35SO4 pulse-chase data show that the newly synthesized "late" enzyme precursor is significantly undersulfated in comparison with the enzyme synthesized early in development. This apparent lack of sulfation is associated with the lack of acquisition of endoglycosidase H resistance. By contrast, an aggregation-deficient mutant, which is defective with regard to the accumulation of alpha-mannosidase-1 activity late in development, synthesizes the "early" sulfated form of the enzyme throughout development. We conclude that the late developmental change in post-translational modification specifically involves one of the biochemical steps in which the N-linked oligosaccharide side chains of the newly synthesized alpha-mannosidase-1 precursor are modified by sulfation.     

α-Mannosidase-1 mutants of Dictyostelium dkoideum: Early aggregation-essential genes regulate enzyme precursor synthesis, modification, and processing

The lysosomal enzyme alpha-mannosidase-1 is one of the earliest developmentally controlled gene products in Dictyostelium discoideum. Although this enzyme is synthesized throughout the first 20 h of development, it is not required for complete morphogenesis, since structural gene (manA) mutants lacking activity develop normally. We isolated six strains deficient in alpha-mannosidase-1 activity which, unlike structural gene mutants, fail to aggregate. Fruiting revertants of these strains accumulate wild-type levels of alpha-mannosidase-1 activity, suggesting that both the enzymatic and morphological defects are caused by single mutations in nonstructural genes essential for early development. Direct genetic evidence for mutations outside of the structural gene was obtained by complementation analysis. We used alpha-mannosidase-1-specific monoclonal antibodies to analyze the biochemical defects in these mad (alpha-mannosidase-1-deficient) mutants. All mad mutants show a significantly reduced relative rate of enzyme precursor biosynthesis. The mad-404 mutation results in a complete lack of precursor biosynthesis, as well as a lack of functional alpha-mannosidase-1 mRNA. In some cases, however, the enzymatic defect results from improper post-translational modification which affects precursor processing. We conclude that a small number of aggregation-essential genes are involved in regulating the synthesis, modification, and processing of alpha-mannosidase-1 during development.     

Effects of a post-translational modification mutation on different developmentally regulated glycosidases in Dictyostelium discoideum.

We have studied the effect of a post-translational modification mutation upon four developmentally regulated glycosidases of Dictyostelium discoideum. The presence of the modA mutation affects the intracellular level of these multimeric enzymes differently. The level of alpha-glucosidase is unaffected in the modA mutant. The mutant cell contains only a very small fraction of the wild type beta-glucosidase-1 activity. The alteration in modification renders beta-glucosidase-1 holoenzyme thermolabile and susceptible to degradation in vivo. alpha-Mannosidase-1 and N-acetylglucosaminidase are found at approximately 1/3 of the wild type level in the modA mutant. Degradation of holoenzyme does not appear to be responsible for the low level of these activities. We propose that alpha-mannosidase-1 and N-acetylglucosaminidase subunits are being degraded prior to subunit assembly. We conclude the modification bestows different properties upon the various glycosidases.     

Isozymes of β-Glucosidase in Dictyostelium discoideum

The activity of beta-glucosidase (EC 3.2.1.21) in extracts of Dictyostelium discoideum was investigated. The specific activity increased early in development, declined during pseudoplasmodium formation, and increased again during sorocarp formation. The beta-glucosidase which was present in growing amoebae and during the first stages of multicellular development was electrophoretically distinct from the enzyme which accumulated during the final stages of morphogenesis. Ribonucleic acid synthesis and protein synthesis during development were required for the accumulation of the later isozyme. Analysis of beta-glucosidase activity in a number of morphological mutants suggests that the enzyme which accumulates late in morphogenesis is developmentally controlled.     

Characterization and genetic mapping of modA. A mutation in the post-translational modification of the glycosidases of Dictyostelium discoideum.

We have isolated a mutant of Dictyostelium discoideum, M31, which produces a reduced number of alpha-mannosidase-1 molecules per cell during the developmental program of the organism. We find that several of the glycosidases, a group of lysosomal proteins produced by D. discoideum, are altered in strain M31 and that this strain produces a reduced level of at least three of these activities. These enzymes do not share a common protein subunit but are known to share a common antigenic determinant which is, in part, carbohydrate in nature. In the wild type parent of M31, alpha-mannosidase-1 is modified by the addition of mannose and glucosamine (probably as N-acetylglucosamine) in the molar ratio of 5:2. alpha-Mannosidase-1 was also found to contain phosphoserine/phosphothreonine residues. alpha-Mannosidase-1 and other glycosidases are electrophoretically less negative when isolated from strain M31 than when isolated from wild type cells. The mutation present in M31, modA, appears to affect posttranslational modification, modA is a recessive mutation which we map onto linkage group I.     

A locus regulating N-acetylglucosaminidase synthesis during development in dictyostelium

The cellular specific activity of N-acetylglucosaminidase increases during development in Dictyostelium discoideum. A monoclonal antibody which specifically recognizes Mr 68,000 and 67,000 forms of N-acetylglucosaminidase was used to show that changes in the relative rate of enzyme synthesis during development parallel the pattern of enzyme accumulation. Developmental and regulatory mutants were isolated to study the relationship between development and enzyme accumulation. No evidence was obtained for any dependence of enzyme accumulation on those genes that are required for aggregation. However, a separate regulatory locus was identified which is involved in enzyme accumulation. Mutations in this gene, nagC, prevent enzyme accumulation during development by preventing an increase in the relative synthetic rate of N-acetylglucosaminidase. The accumulation of other enzymes is unaffected and the mutation causes no developmental defects other than those caused by the loss of N-acetylglucosaminidase activity. The nagC mutation, which is recessive, maps to linkage group VI and is therefore unlinked to the structural gene for N-acetylglucosaminidase.     

Dictyostelium macroautophagy mutants vary in the severity of their developmental defects

Macroautophagy is the major mechanism that eukaryotes use to recycle cellular components during stressful conditions. We have shown previously that the Atg12-Atg5 conjugation system, required for autophagosome formation in yeast, is necessary for Dictyostelium development. A second conjugation reaction, Aut7/Atg8 lipidation with phosphatidylethanolamine, as well as a protein kinase complex and a phosphatidylinositol 3-kinase complex are also required for macroautophagy in yeast. In this study, we characterize mutations in the putative Dictyostelium discoideum orthologues of budding yeast genes that are involved in one of each of these functions, ATG1, ATG6, and ATG8. All three genes are required for macroautophagy in Dictyostelium. Mutant amoebae display reduced survival during nitrogen starvation and reduced protein degradation during development. Mutations in the three genes produce aberrant development with defects of varying severity. As with other Dictyostelium macroautophagy mutants, development of atg1-1, atg6(-), and atg8(-) is more aberrant in plaques on bacterial lawns than on nitrocellulose filters. The most severe defect is observed in the atg1-1 mutant, which does not aggregate on bacterial lawns and arrests as loose mounds on nitrocellulose filters. The atg6(-) and atg8(-) mutants display almost normal development on nitrocellulose filters, producing multi-tipped aggregates that mature into small fruiting bodies. The distribution of a green fluorescent protein fusion of the autophagosome marker, Atg8, is aberrant in both atg1-1 and atg6(-) mutants.     

Different molecular mechanisms for cAMP regulation of gene expression during Dictyostelium development

Alterations in cAMP concentrations have been implicated in developmentally regulated gene expression in Dictyostelium. Using a variety of culture conditions to control the metabolism of cAMP during cytodifferentiation, I have examined the role of the cyclic nucleotide in development. Conditions which allow intracellular synthesis of cAMP promote the normal developmental repression of gene M4-1 by a mechanism which is completely independent of the formation of multicellular aggregates. If, however, cells are inhibited in their ability to activate adenylate cyclase and, thus, intracellular cAMP signaling, they prove unable to repress M4-1, even in the presence of exogenous cAMP. In contrast, expression of genes which exhibit maximal activity after aggregate formation depends upon accumulation of extracellular cAMP. Inhibition of intracellular cAMP signaling does not prevent the expression of these genes if cultures are simultaneously exposed to high levels of exogenously added extracellular cAMP. These results indicate that there are at least two independent mechanisms involved in the developmental regulation of gene expression by cAMP in Dictyostelium. I discuss plausible molecular mechanisms through which cAMP might alter gene expression.     

The Structural Gene for α-Mannosidase-1 in DICTYOSTELIUM DISCOIDEUM

We have isolated 4 independent mutations affecting alpha-mannosidase-1, a developmentally regulated activity in Dictyrostelium discoideum. Three of these result in a thermolabile alpha-mannosidase-1 activity. One mutation also affects the substrate affinity (Km) of the activity. In diploids these mutations show a gene dosage effect and are all alleles. The structural gene for alpha-mannosidase-1, as defined by these mutations, defines a new linkage group, linkage group VI. alpha-mammosidase 1 is probably a homopolymer with subunits of 54,000 daltons. We have also mapped two temperature-sensitive-for-growth mutations onto two previously defined linkage groups.     

Effects of differentiated membranes on the developmental program of the cellular slime mold.

In the preceding paper isolated aggregation phase membranes (prepared from Dictyostelium discoideum cells which had proceeded through 12–14 hr of the developmental cycle) were found to be capable of preventing the aggregation and subsequent morphological development of vegetative cells when mixed with these and plated under normal conditions for slime mold development. In this paper we have extended the investigations on the nature of this interaction by monitoring the display of several developmentally controlled enzymes. It appears that exogenously applied aggregation phase membrane preparations are capable of influencing biochemical events inside D. discoideum cells through their interaction with the cell surface. This interaction leads to the induction or accumulation of some developmentally controlled enzymes, as well as the repression or excretion of others. The results suggest that the formation and maintenance of correct cell-cell contacts during normal development may be of crucial importance. They also show that changes in the specific activity of some developmentally controlled enzymes may in certain conditions be wholly divorced from both morphogenesis and the normal sequence of induction.     

Acetylglucosaminidase, an Early Enzyme in the Development of Dictyostelium discoideum

The specific activity of acetylglucosaminidase has been found to increase more than 10-fold during the first 10 hr of development in the cellular slime mold Dictyostelium discoideum. The specific activity then remained essentially constant until after germination. The activity was purified 36-fold and found to behave as a single protein species. The increase in specific activity required concomitant protein synthesis. If ribonucleic acid synthesis was preferentially inhibited during the period of synthesis of acetylglucosaminidase, further increase in enzymatic activity stopped after 2 hr. The increase in activity did not occur in a mutant strain which did not undergo the first step in morphogenesis. Mutant strains, blocked slightly later in morphogenesis, synthesized the enzyme at the normal rate but for an extended period. It was concluded that the initiation and termination of synthesis of acetylglucosaminidase are controlled by the developmental program.     

Macroautophagy is required for multicellular development of the social amoeba Dictyostelium discoideum

Macroautophagy is a mechanism employed by eukaryotic cells to recycle non-essential cellular components during starvation, differentiation, and development. Two conjugation reactions related to ubiquitination are essential for autophagy: Apg12p conjugation to Apg5p, and Apg8p conjugation to the lipid phosphatidylethanolamine. These reactions require the action of the E1-like enzyme, Apg7p, and the E2-like enzymes, Apg3p and Apg10p. In Dictyostelium, development is induced by starvation, conditions under which autophagy is required for survival in yeast and plants. We have identified Dictyostelium homologues of 10 budding yeast autophagy genes. We have generated mutations in apg5 and apg7 that produce defects typically associated with an abrogation of autophagy. Mutants are not grossly affected in growth, but survival during nitrogen starvation is severely reduced. Starved mutant cells show little turnover of cellular constituents by electron microscopy, whereas wild-type cells show significant cytoplasmic degradation and reduced organelle number. Bulk protein degradation during starvation-induced development is reduced in the autophagy mutants. Development is aberrant; the autophagy mutants do not aggregate in plaques on bacterial lawns, but they do proceed further in development on nitrocellulose filters, forming defective fruiting bodies. The autophagy mutations are cell autonomous, because wild-type cells in a chimaera do not rescue development of the autophagy mutants. We have complemented the mutant phenotypes by expression of the cognate gene fused to green fluorescent protein. A green fluorescent protein fusion of the autophagosome marker Apg8 mislocalizes in the two autophagy mutants. We show that the Apg5-Apg12 conjugation system is conserved in Dictyostelium.     

Determinants of RasC specificity during Dictyostelium aggregation

RasC is required for optimum activation of adenylyl cyclase A and for aggregate stream formation during the early differentiation of Dictyostelium discoideum. RasG is unable to substitute for this requirement despite its sequence similarity to RasC. A critical question is which amino acids in RasC are required for its specific function. Each of the amino acids within the switch 1 and 2 domains in the N-terminal portion of RasG was changed to the corresponding amino acid from RasC, and the ability of the mutated RasG protein to reverse the phenotype of rasC(-) cells was determined. Only the change from aspartate at position 30 of RasG to alanine (the equivalent position 31 in RasC) resulted in a significant increase in adenylyl cyclase A activation and a partial reversal of the aggregation-deficient phenotype of rasC(-) cells. All other single amino acid changes were without effect. Expression of a chimeric protein, RasG(1-77)-RasC(79-189), also resulted in a partial reversal of the rasC(-) cell phenotype, indicating the importance of the C-terminal portion of RasC. Furthermore, expression of the chimeric protein, with alanine changed to aspartate (RasG(1-77(D30A))-RasC(79-189)), resulted in a full rescue the rasC(-) aggregation-deficient phenotype. Finally, the expression of either a mutated RasC, with the aspartate 31 replaced by alanine, or the chimeric protein, RasC(1-78)-RasG(78-189), only generated a partial rescue. These results emphasize the importance of both the single amino acid at position 31 and the C-terminal sequence for the specific function of RasC during Dictyostelium aggregation.     

Regulation of lysosomal α-mannosidase-1 synthesis during development in Dictyostelium discoideum

The cellular specific activity of lysosomal α-mannosidase-1 increases dramatically during development in Dictyostelium discoideum. α-Mannosidase-1 is composed of two subunits (M_r = 58,000 and 60,000) which are derived from a common precursor polypeptide (M_r = 140,000). Using enzyme-specific monoclonal antibodies we have determined that throughout development (a) the relative rate of precursor biosynthesis closely parallels the rate of accumulation of cellular enzyme activity and (b) the newly synthesized precursor is efficiently processed to mature enzyme (t_1/2 < 10 min). This indicates that the developmental accumulation of α-mannosidase-1 activity is primarily controlled by de novo enzyme synthesis. Furthermore, the change in the relative rate of enzyme precursor synthesis can be accounted for by an increase in the cellular level of functional α-mannosidase-1 mRNA during development.     

Multiple regulatory genes control expression of a gene family during development of Dictyostelium discoideum.

Mutant strains of Dictyostelium discoideum carrying dis mutations fail to transcribe specifically the family of developmentally regulated discoidin lectin genes during morphogenesis. The phenotypes of these mutants strongly suggested that the mutations reside in regulatory genes. Using these mutant strains, we showed that multiple regulatory genes are required for the expression of the lectin structural genes and that these regulatory genes (the dis+ alleles) act in trans to regulate this gene family. These regulatory genes fall into two complementation groups (disA and disB) and map to linkage groups II and III, respectively. A further regulatory locus was defined by the identification of an unlinked supressor gene, drsA (discoidin restoring), which is epistatic to disB, but not disA, and results in the restoration of lectin expression in cells carrying the disB mutation. Mutant cells carrying the drsA allele express the discoidin lectin gene family during growth and development, in contrast to wild-type cells which express it only during development. Therefore, the suppressor activity of the drsA allele appears to function by making the expression of the discoidin lectins constitutive and no longer strictly developmentally regulated. The data indicate that normal expression of the discoidin lectins is dependent on the sequential action of the disB+, drsA+, and disA+ gene products. Thus, we described an interacting network of regulatory genes which in turn controls the developmental expression of a family of genes during the morphogenesis of D. discoideum.