Cyclic AMP Receptor Protein from Yeast Mitochondria

We have identified and characterized a cyclic AMP receptor protein in mitochondria of the yeast Saccharomyces cerevisiae. The binding is specific for cyclic nucleotides, particularly for cyclic AMP which is bound with high affinity (Kd of 10(-9) M) at 1 to 5 pmol/mg of mitochondrial protein. The mitochondrial cyclic AMP receptor is synthesized on cytoplasmic ribosomes and has an apparent molecular weight of 45,000 as determined by photoaffinity labeling. It is localized in the inner mitochondrial membrane and faces the intermembrane space. Cross-contamination of mitochondrial inner membranes by plasma membranes or soluble cytoplasmic proteins is excluded

Lipolytic Membrane Release of Two Phosphatidylinositol-Anchored cAMP Receptor Proteins in Yeast Alters Their Ligand-Binding Parameters

Two new cAMP-binding proteins have been discovered recently in Saccharomyces cerevisiae. They are genetically distinct from the regulatory subunit of cytoplasmic cAMP-dependent protein kinase A and are distinguished from the latter, in addition, by their anchorage through phosphatidylinositol-containing lipid and glycolipid structures to mitochondrial and plasma membranes, respectively (Müller and Bandlow, 1989 Biochemistry 28, 9957-9967, 1991, Biochemistry 30, 10181-10190). A nutritional upshift induces the cleavage of the anchor by a phospholipase C (Müller and Bandlow, 1993, J. Cell Biol. 122, 225-236). To test the idea that anchorage by (glycosyl)phosphatidyl-inositol influences cAMP-binding and has a regulatory function, we analyzed ligand binding to the two purified cAMP receptors (46,000 and 54,000 Da) in comparison to the regulatory subunit of the cytoplasmic protein kinase A (52,000 Da). We find that lipolytic cleavage of the two membrane anchors by phosphatidylinositol-specific phospholipases C and D results in significantly higher association and lower dissociation rates of cAMP, thus leading to a dramatic increase in ligand affinity of the two cAMP receptors. Use of cAMP analogues identifies two different cAMP-binding centers in each membrane-embedded protein, one of which is noticeably affected by the cleavage of the anchor. In both phosphatidylinositol-anchored cAMP receptor proteins a single Trp residue in one of the binding centers is photoaffinity-labeled by 8-N3-cAMP, whereas two amino acids, Trp and Tyr, are modified after lipolytic removal of the anchor. The differences in the labeling patterns are interpreted as to result from a conformational rearrangement induced by the cleavage of the anchor. Together with the increased affinity to the ligand these changes document alterations of the properties and folding structure of lipid-anchored proteins following cleavage of the PI-containing anchor by specific phospholipases and provide the first molecular evidence for a regulatory role of the anchorage by a lipid structure. The cytoplasmic regulatory subunit of yeast protein kinase A is not photolabeled to a significant extent under any condition

The CAMP-binding Ectoprotein from Saccharomyces cereuisiae Is Membrane-anchored by Glycosyl-Phosphatidylinositol

Saccharomyces cerevisiae contains an amphiphilic CAMP-binding glycoprotein at the outer face of the plasma membrane (M, = 54,000). It is converted to a hydrophilic form byt reatment withg lycosyl-phosphatidylinositol- specific phospholipases C and D (GPIPLC/ D), suggesting membrane anchorage by a covalently bound glycolipid. Determination of the constituents of the purified anchor by gas-liquid chromatography and amino acid analysis reveals the presence of glycerol, myo-inositol, glucosamine, galactose, mannose, ethanolamine, and asparagine (as the carboxylterminal amino acido f the Pronase-digested proteitno which the anchor is attached). Complementary results are obtained by metabolic labeling, indicating that fatty acids and phosphorus are additional anchor constituents. The phosphoruiss resistant to alkalinep hosphatase, whereas approximately half is lost from the protein after treatment with GPI-PLD or nitroaucisd , and all is removed by aqueous HF indicating the presence of two phosphodiester bonds. Inhibition of Nglycosylation by tunicamycin or removal of proteinbound glycan chains by N-glycanase or Pronase does not abolish radiolabeling of the anchor structure by any of the above compounds. Analysis of the products obtained after sequential enzymic and chemical degradation of the anchor agrees with the arrangemoefn t constitutents in GPIs from higher eucaryotes. Evidence for anchorage of the yeast CAMP-binding protein by a GPI anchoris strengthened additionallyb y the reactivity of the GPI-PLC-cleaved anchor with antibodies directed against the cross-reacting determinoaf nttr ypanosomal variant surface glycoproteins

The intron-containing gene for yeast profilin (PFY) encodes a vital function

The gene coding for profilin (PFY), an actin-binding protein, occurs as a single copy in the haploid genome of Saccharomyces cerevisiae and is required for spore germination and cell viability. Displacement of one gene copy in a diploid cell by a nonfunctional allele is recessively lethal: tetrad analysis yields only two viable spores per ascus. The PFY gene maps on chromosome XV and is linked to the ADE2 marker. The primary transcript of about 1,000 bases contains an intron of 209 bases and is spliced into a messenger of about 750 bases. The intron was identified by comparison with a cDNA clone, which also revealed the 3' end of the transcript. The 5' end of the mRNA was mapped by primer elongation. The gene is transcribed constitutively and has a coding capacity for a protein of 126 amino acids. The deduced molecular weight o

Stimulation of a glycosyl-phosphatidylinositol-specific phospholipase by insulin and the sulfonylurea, glimepiride, in rat adipocytes depends on increased glucose transport

Abstract. Lipoprotein lipase (LPL) and glycolipidanchored cAMP-binding ectoprotein (Gcel) are modified by glycosyl-phosphatidylinositol (GPI) in rat adipocytes, however, the linkage is potentially unstable. Incubation of the cells with either insulin (0.1-30 nM) or the sulfonylurea, glimepiride (0.5-20/zM), in the presence of glucose led to conversion of up to 35 and 20%, respectively, of the total amphiphilic LPL and Gcel to their hydrophilic versions. Inositol-phosphate was retained in the residual protein-linked anchor structure. This suggests cleavage of the GPI anchors by an endogenous GPI-specific insulin- and glimepiride-inducible phospholipase (GPI-PL). Despite cleavage, hydrophilic LPL and Creel remained membrane associated and were released only if a competitor, e.g., inositol-(cyclic)monophosphate, had been added. Other constituents of the GPI anchor (glucosamine and mannose) were less efficient. This suggests reat body of information exists regarding the structural diversity as well as the biosynthesis and posttranslational attachment of glycosyl-phosphatidylinositol (GPI) ~ structures (for recent reviews see Low, 1989; McConville et al., 1993). However, the functional significance of membrane anchorage via GPI structures versus transmembrane polypeptide domains is still a matter of debate. The accessibility of GPI molecules to cleavage by phospholipase [(G)PI-PL] opens the possibility of a regu-Address all correspondence to Dr. (;tinter Miiller, Hoechst AG Frankfurt