Summary. The cellular slime mold, Dictyostelium disoideum, provides an ideal model system to study eukaryotic cell differentiation. In D. discoideum, glycogen degradation provides precursors for the synthesis of developmentally regulated structural products. The enzyme responsible for glycogen degradation, glycogen phosphorylase, exists in active and inactive forms. The active, or‘a’ form, is independent of 5′adenosine monophosphate (5′AMP) while the inactive, or‘b’ form, is 5′AMP‐dependent. The activity of the‘b’ form predominates early in development, while the activity of the‘a’ form peaks in mid‐late development; their combined specific activities remain constant at any point. Polyclonal antibodies raised to the purified forms of this enzyme showed low cross‐reactivity. The anti‐‘a’ serum reacted with a 104‐kDa protein that was associated with phosphorylase‘a’ activity; the anti‐‘b’ serum reacted with a 92‐kDa protein that was associated with phosphorylase‘b’ activity and weakly cross‐reacted with the 104‐kDa protein. Immunoblots of peptide maps of the purified enzyme forms showed that each antibody was specific for the proteolytic fragments of its respective antigen. We also demonstrated in vitro phosphorylation of the‘b’ form by an endogenous protein kinase. Cyclic AMP perturbation of intact cells caused induction of both phosphorylase‐‘a’ activity and the 104‐kDa protein. Immunotitration data suggested that the‘a’ form accumulates due to de novo protein synthesis, although this result must be interpreted with caution.
A key step in the cellular differentiation of Dictyostelium is the degradation of glycogen to provide the precursors for synthesis of the structural end products of development. We have found that the enzyme that initiates this degradative pathway, glycogen phosphorylase (1,4-alpha-D-glucan:orthophosphate alpha-glucosyltransferase; EC 2.4.1.1), is developmentally regulated and exists as two forms. During the time course of development, a previously undescribed activity, the "b" form, decreases, while that of the "a" form increases. The "b" form is inactive unless 5'AMP is included in the reaction mixture. The two forms differ in their elution from DE52 cellulose, affinity constants, thermal stability, affinity for 5'AMP Sepharose, subunit molecular weight, and peptide maps. In crude extracts, anti-a antiserum stains a 104-kD protein that is associated with phosphorylase "a" activity and appears late in development, while anti-b antiserum stains a 92-kD protein that is associated with phosphorylase "b" activity and is present throughout development. We have also demonstrated in vitro phosphorylation of the "b" form by an endogenous protein kinase and a corresponding loss of 5'AMP dependence. If intact cells were exposed to exogenous cAMP, "b" activity decreased and was replaced by "a" activity, as well as the 104-kD protein band on SDS-PAGE. In order to determine if the two forms of the enzyme are different gene products, we screened lambda gt11 expression libraries with antibodies against the purified "a" and "b" forms. Three clones were found to be overlapping by Southern analysis. A yeast glycogen phosphorylase cDNA clone (gpy) and a human muscle glycogen phosphorylase clone (HM-11) cross-hybridized with the Dictyostelium inserts, and gpy shared a few common restriction fragments with the Dictyostelium clones on genomic blots. Northern analysis of Dictyostelium total RNA showed that the Dictyostelium inserts and gpy recognize an mRNA of 3.2 kb, while on poly A-enriched RNA, the yeast clone detects preferentially a 3.6-kb message.
We have recently reported the existence of two forms of glycogen phosphorylase (1,4-alpha-D-glucan: orthophosphate-alpha-glucosyltransferase; EC 2.4.1.1) in Dictyostelium discoideum. During development the activity of the glycogen phosphorylase b form decreased as the activity of the a form increased. The total phosphorylase activity remained constant. The physical and kinetic properties of the Dictyostelium enzyme were similar to those of the mammalian enzyme. In mammals, cAMP regulates the conversion of the two forms by a cAMP dependent protein kinase (cAMPdPK). We report here that if cAMP is added to a single cell suspension, the Dictyostelium phosphorylase activity becomes independent of 5'AMP and a 104 kd peptide appears. We also show the effect of several cAMP analogs on the phosphorylase activity in these single-cell suspensions. The cAMP analogs were selected on the basis of their affinities for the membrane-bound cAMP receptor or the cytoplasmic cAMPdPK. We found that relatively low levels, 100 microM, of cAMP or 2'd-cAMP added to aggregation-competent cells in shaking culture caused a loss of phosphorylase b activity and the appearance of phosphorylase a activity. The analog, 2'd-cAMP, has a high affinity for the cAMP receptor but a low affinity for the cAMPdPK. Two other analogs, Bt2-cAMP and 8-Br-cAMP, which have low affinities for the cAMP receptor but high affinities for the cAMPdPK, required high levels (500 microM) for 'b' to 'a' conversion. cDNAs to three cAMP-regulated genes--PL3, D11, and D3--were used as controls in the above experiments. In order to determine if intracellular levels of cAMP were involved in the regulation of phosphorylase activity, both the phosphorylase and the PL3, D11 and D3 mRNA levels were examined in cells suspended in a glucose/albumin mixture--a medium in which adenylate cyclase is inhibited. Under these conditions, neither gene regulation nor a change in the phosphorylase b to a activity occurred in response to added extra cellular cAMP. The results suggest that an intracellular increase in cAMP is involved in the regulation of the two forms of glycogen phosphorylase in Dictyostelium.
The slime mold Dictyostelium discoideum has two forms of the enzyme glycogen phosphorylase. The inactive phosphorylase 'b' form requires 5' AMP for activity and is present in early development. The active phosphorylase 'a' form is 5' AMP independent and occurs during later development. We here show that the 92 kd 'b' enzyme subunit exists either as a singlet or a doublet upon SDS-PAGE, depending on the method of sample extraction. In the presence of exogenously added Mn2+ and ATP, the phosphorylase 'b' shows apparent conversion into a 5' AMP independent form as measured by enzyme activity. In addition, Mn2+ and ATP also support an in vitro phosphorylation of the 92 kd phosphorylase 'b' subunit. We also demonstrate phosphorylation of the 'b' enzyme subunit in vivo by 32-P incorporation into the enzyme protein. A protein kinase responsible for the observed in vitro phosphorylation of the phosphorylase 'b' subunit is characterized.
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