Modulation of the catalytic activity of the Src family tyrosine kinase Hck by autophosphorylation at a novel site in the unique domain.

Autophosphorylation is a key event in the activation of protein kinases. In this study, we demonstrate that autophosphorylation of the recombinant Src family kinase Hck leads to a 20-fold increase in its specific enzymatic activity. Hck was found to autophosphorylate readily to a stoichiometry of 1.3 mol of phosphate per mol of enzyme, indicating that the kinase autophosphorylated at more than one site. Solid phase sequencing and two-dimensional mapping of the phosphopeptide fragments derived from the autophosphorylated enzyme revealed that the kinase can undergo autophosphorylation at the following two sites: (i) Tyr-388, which is located to the consensus autophosphorylation site commonly found in the activation loop of many protein kinases, and (ii) Tyr-29, which is located in the unique domain of Hck. Hck purified from mouse bone marrow-derived macrophages could also autophosphorylate in vitro at both Tyr-388 and Tyr-29, indicating that naturally occurring Hck can also autophosphorylate at Tyr-29. Furthermore, Hck transiently expressed in human embryonic kidney 293T cells was found to be phosphorylated at Tyr-29 and Tyr-388, proving that Hck can also undergo autophosphorylation at both sites in vivo. The recombinant enzyme carrying the mutation of Tyr-388 to Phe was also able to autophosphorylate at Tyr-29, albeit at a significantly slower rate. A 2-fold increase in the specific enzymatic activity was seen with this mutant despite the stoichiometry of autophosphorylation only approaching 0.2 mol of phosphate per mol of enzyme. This indicates that autophosphorylation of Tyr-29 contributes significantly to the activation of Hck. Regulation of the catalytic activity by phosphorylation of Tyr-29 in the unique domain may represent a new mechanism of regulation of Src family tyrosine kinases.

Identification of insulin-induced sites of ribosomal protein S6 phosphorylation in Drosophila melanogaster.

Insulin treatment of Drosophila melanogaster Kc 167 cells induces the multiple phosphorylation of a Drosophila ribosomal protein, as judged by its decreased electrophoretic mobility on two-dimensional polyacrylamide gels. The extent to which insulin induces this response is potentiated by cycloheximide and blocked by pretreatment with rapamycin. Isolation and mass spectrometric analysis revealed that the multiply phosphorylated protein was the larger of two Drosophila melanogaster orthologues of mammalian 40S ribosomal protein S6, termed here DS6A. Proteolytic cleavage of DS6A derived from stimulated Kc 167 cells with the endoproteinase Lys-C released a number of peptides, one of which contained all the putative phosphorylation sites. Conversion of phosphoserines to dehydroalanines with Ba(OH)(2) showed that the sites of phosphorylation reside at the carboxy terminus of DS6A. The sites of phosphorylation were identified by Edman degradation after conversion of the phosphoserine residues to S-ethylcysteine as Ser(233), Ser(235), Ser(239), Ser(242), and Ser(245). Finally, phosphopeptide mapping of individual phosphoderivatives, isolated from two-dimensional polyacrylamide gels, indicated that DS6A phosphorylation, in analogy to mammalian S6 phosphorylation, appears to proceed in an ordered fashion. The importance of these observations in cell growth and development is discussed.

Dual requirement for a newly identified phosphorylation site in p70s6k.

The activation of p70s6k is associated with multiple phosphorylations at two sets of sites. The first set, S411, S418, T421, and S424, reside within the autoinhibitory domain, and each contains a hydrophobic residue at -2 and a proline at +1. The second set of sites, T229 (in the catalytic domain) and T389 and S404 (in the linker region), are rapamycin sensitive and flanked by bulky aromatic residues. Here we describe the identification and mutational analysis of three new phosphorylation sites, T367, S371, and T447, all of which have a recognition motif similar to that of the first set of sites. A mutation of T367 or T447 to either alanine or glutamic acid had no apparent effect on p70s6k activity, whereas similar mutations of S371 abolished kinase activity. Of these three sites and their surrounding motifs, only S371 is conserved in p70s6k homologs from Drosophila melanogaster, Arabidopsis thaliana, and Saccharomyces cerevisiae, as well as many members of the protein kinase C family. Serum stimulation increased S371 phosphorylation; unlike the situation for specific members of the protein kinase C family, where the homologous site is regulated by autophosphorylation, S371 phosphorylation is regulated by an external mechanism. Phosphopeptide analysis of S371 mutants further revealed that the loss of activity in these variants was paralleled by a block in serum-induced T389 phosphorylation, a phosphorylation site previously shown to be essential for kinase activity. Nevertheless, the substitution of an acidic residue at T389, which mimics phosphorylation at this site, did not rescue mutant p70s6k activity, indicating that S371 phosphorylation plays an independent role in regulating intrinsic kinase activity.

Post-translational processing of rat ribosomal proteins. Ubiquitous methylation of Lys22 within the zinc-finger motif of RL40 (carboxy-terminal extension protein 52) and tissue-specific methylation of Lys4 in RL29.

The complete amino acid sequences of rat and yeast (Saccharomyces cerevisiae) ribosomal proteins derived from precursors containing an N-terminal ubiquitin or ubiquitin-like sequence (C-terminal extension proteins or CEPs) were determined and investigated for any post-translational modifications by reverse-phase HPLC purification, direct amino acid sequence and mass spectrometric analyses. Covalent modifications were detected in the rat liver proteins RS27a (CEP-80), RL29, RL37 and RL40 (CEP-52), while RS30 (CEP), RL36a, RL39 and RL41 were unmodified. Heterogeneity of RS27a was due to C-terminal truncations, with Lys80 missing from about 20% of the liver RS27a population; C-terminal processing was also detected with RL29 and RL37. No other covalent modifications of liver, brain or thymus RS27a were detected. The rat RL40 structure was identical to the cDNA-predicted sequence except for complete stoichiometric N epsilon-trimethylation of Lys22 within its zinc-finger motif; this modification occurred in the ribosomes of all three rat tissues investigated but not in yeast ribosomes. The methylation characteristics of RL40 were distinct from those of ribosomal protein RL29 in the rat, which was differentially monomethylated at Lys4 in the liver, brain and thymus (27%, > 99% and 95% methylation, respectively). In the case of liver, there was no appreciable difference in the RL29 methylation status of free and membrane-bound ribosomes. The possibilities of an essential role for RL40 methylation in the formation of rat ribosomes, and a distinct regulatory role for RL29 methylation in the rat, are discussed.

Isolation and characterization of a structural homologue of human PRK2 from rat liver. Distinguishing substrate and lipid activator specificities.

A homologue of human protein kinase C (PKC)-related kinase-2, PRK2, which had previously escaped identification in normal mammalian tissues, was isolated from rat liver as the protease-activated kinase (PAK) originally named PAK-2. The 130-kDa cytosolic enzyme was purified to homogeneity and shown by tryptic peptide and reverse transcriptase- polymerase chain reaction (RT-PCR)-amplified rat cDNA sequence analyses to be structurally related to the 116-kDa rat hepatic PAK-1/protein kinase N (PKN) and, even more closely (95% sequence identity) to the 130-kDa human PKC-related kinase, PRK2. Rat myeloma RNA was used as the RT-PCR template because of its relative abundance in PAK-2/PRK2 mRNA compared with liver and other rat tissues. The catalytic properties of PAK-2/PRK2 in many respects resembled those of hepatic PAK-1/PKN, but were distinguished by more favorable kinetics with several peptide substrates, and greater sensitivity to PKC pseudosubstrate and polybasic amino acid inhibitors. PAK-2/PRK2 was also activated by lipids, particularly cardiolipin and to a lesser extent by other acidic phospholipids and unsaturated fatty acids. Cardiolipin activation was most evident with autophosphorylation and histone H2B phosphorylation, but only marginally evident with the favored ribosomal S6-(229-239) peptide substrate for the protease-activated kinase activity. It was concluded that PAK-2 is the rat homologue of human PRK2, with biochemical properties distinct from although overlapping those of the PAK-1/PKN/PRK1 isoform.

Phosphorylation events associated with different states of activation of a hepatic cardiolipin/protease-activated protein kinase. Structural identity to the protein kinase N-type protein kinases.

Cardiolipin- or protease-activated protein kinase, isolated from rat liver cytosol and originally named liver PAK-1, was found to be the natural form of protein kinase N (PKN) by comparing the sequences of 43 tryptic peptides of the purified liver enzyme and determining the corresponding liver cDNA sequence. These analyses also identified (i) Arg-546 as the major site of proteolytic activation, (ii) the protease resistance of the C-terminal extension beyond the catalytic domain, and (iii) in vivo stoichiometric phosphorylation of Thr-778 in the mature enzyme. Homology modeling of the catalytic domain indicated that phosphothreonine 778 functions as an anchoring site similar to Thr-197 in cAMP-dependent protein kinase, which stabilizes an active site compatible with preferred substrate sequences of PAK-1/PKN. Sigmoidal autophosphorylation kinetics and increased S6-(229-239) peptide kinase activity following preincubation with ATP suggested phosphorylation-dependent activation of PAK-1/PKN. The onset of activation corresponded with phosphorylation of the regulatory domain site Ser-377 (located within a spectrin homology region), followed by Thr-504 (within a limited protein kinase C homology region), and, to a lesser extent, Thr-64 (in the RhoA-binding region). Several additional sites in the hinge region adjacent to a PEST protein degradation signal were selectively autophosphorylated following cardiolipin activation. Overall, these observations suggest that the regulation of this class of protein kinase involves complex interactions among phosphorylation-, lipid-, and other ligand-dependent activation events.

Evolution of transthyretin gene expression in the liver of Didelphis virginiana and other American marsupials.

The occurrence of the thyroid hormone-binding plasma protein transthyretin in the bloodstream was investigated for four American marsupial species. Serum samples were analyzed by incubation with radioactive T4, followed by electrophoresis, then autoradiography, and Western blotting. Transthyretin was found in serum from Monodelphis domestica, Didelphis virginiana, Caluromys lanatus, and Dromiciops australis. For unambiguous identification, transthyretin from D, virginiana was purified from serum and its N-terminal amino acid sequence was determined. The obtained results suggest that the initiation of transthyretin gene expression in the liver of marsupials occurred independently in several lineages of American marsupials, all of which are at the ends of phylogenetic branches. The expression of the transthyretin gene in the liver of the American polyprotodont marsupials contrasts with the lack of transthyretin gene expression in the liver of all 22 previously investigated Australian Polyprotodonta.

Characterization of the chemical and antimicrobial properties of piscicolin 126, a bacteriocin produced by Carnobacterium piscicola JG126.

A novel peptide bacteriocin produced by the lactic acid bacterium Carnobacterium piscicola JG126 isolated from spoiled ham was purified and characterized. This bacteriocin, designated piscicolin 126, inhibited the growth of several gram-positive bacteria, especially the food-borne pathogen Listeria monocytogenes, but had no effect on the growth of a number of yeasts and gram-negative bacteria. Bactericidal activity was not destroyed by exposure to elevated temperatures at low pH values; however, bactericidal activity was lost at high pH values, especially when high pH values were combined with an elevated temperature. Piscicolin 126 activity was not affected by catalase, lipase, or lysozyme but was destroyed by exposure to a range of proteolytic enzymes. Piscicolin 126 was purified to homogeneity and was found to be a peptide having a molecular weight of 4,416.6 +/- 1.9. A sequence analysis revealed that this compound is a cystibiotic (class IIa) bacteriocin containing 44 amino acid residues and one intrapeptide disulfide ring. Piscicolin 126 has regions of homology with some other bacteriocins obtained from lactic acid bacteria and is most closely related to sakacin P and pediocin PA-1 (levels of identity, 75 and 55%, respectively). Addition of piscicolin 126 to a devilled ham paste test food system inhibited the growth of L. monocytogenes for at least 14 days. Piscicolin 126 was more effective than two commercially available bacteriocin preparations tested in the same system.

The yeast homolog of mammalian ribosomal protein S30 is expressed from a duplicated gene without a ubiquitin-like protein fusion sequence. Evolutionary implications.

In mammals, the 59-residue ribosomal protein S30 (rpS30) is synthesized as a fusion to a 74-residue ubiquitin-like protein, which is cleaved to yield mature rpS30. An artificial fusion of this ubiquitin-like protein to E. coli beta-galactosidase was not cleaved when expressed in yeast (Saccharomyces cerevisiae), indicating that yeast lack this cleaving activity. The yeast rpS30 homolog (yrpS30) was purified and sequenced to reveal a 63-residue protein with 61% sequence identity to mammalian rpS30. Degenerate oligonucleotides based on the yrpS30 sequence were used to isolate full-length yrpS30 cDNAs. Sequence analysis of five cDNA clones revealed that yrpS30 is not synthesized as a fusion to a ubiquitin-like protein but is extended at its N terminus by a single methionine residue. The corresponding gene was identified in the GenBankTM data base by sequence alignment and termed RPS30A. The gene consists of two exons separated by a 430-base pair intron, which contains consensus splicing elements. Exon 1 encodes the initiator methionine residue and is preceded by canonical yeast ribosomal protein gene promoter elements. Exon 2 encodes the 62-residue mature yrpS30. Genomic hybridization reveals that the RPS30A gene is duplicated. Disruption of the RPS30A gene is not lethal but confers a slow growth phenotype. Ribosomes in the mutant strains contain an authentic yrpS30 protein, indicating that a functional yrpS30 is expressed from the duplicated gene but that the reduced capacity for yrpS30 synthesis restricted the growth rate. Analysis of available DNA sequence data bases reveals that rpS30 is synthesized as a fusion to a ubiquitin-like protein in nematodes and mammals but unfused in yeast, plants, and protazoa.

The principal target of rapamycin-induced p70s6k inactivation is a novel phosphorylation site within a conserved hydrophobic domain.

The immunosuppressive agent rapamycin induces inactivation of p70s6k with no effect on other mitogen-activated kinases. Here we have employed a combination of techniques, including mass spectrometry, to demonstrate that this effect is associated with selective dephosphorylation of three previously unidentified p70s6k phosphorylation sites: T229, T389 and S404. T229 resides at a conserved position in the catalytic domain, whose phosphorylation is essential for the activation of other mitogen-induced kinases. However, the principal target of rapamycin-induced p70s6k inactivation is T389, which is located in an unusual hydrophobic sequence outside the catalytic domain. Mutation of T389 to alanine ablates kinase activity, whereas mutation to glutamic acid confers constitutive kinase activity and rapamycin resistance. The importance of this site and its surrounding motif to kinase function is emphasized by its presence in a large number of protein kinases of the second messenger family and its conservation in putative p70s6k homologues from as distantly related organisms as yeast and plants.

Induction of amphipathic helical peptide structures in RP-HPLC.

The retention behavior of a series of amphipathic peptide multimers based on the amino acid sequence [KSEEQLA]n has been investigated using reversed-phase high performance liquid chromatography (RP-HPLC). Structure-retention parameters which are related to the hydrophobic contact area and affinity of these peptides for the immobilized hydrocarbonaceous ligands were determined over a range of operating temperatures between 5 degrees and 85 degrees C. The influence of ligand hydrophobicity was assessed by comparison of peptide retention behavior using an n-octadecyl (C18)- and an n-butyl (C4)-silica of similar ligand density. The results demonstrated that ligand-mediated conformational effects can stabilize peptide structure depending on the chromatographic residence time and peptide length. In particular, more highly stabilized secondary structures were evident for the longer peptides. In addition, the amphipathic secondary structure of the peptides were more effectively stabilized by the more hydrophobic C18 ligands relative to the shorter C4 ligands. Additional information on the interactive dynamics of these peptide multimers was obtained from analysis of bandwidth dependencies under the different chromatographic conditions. These studies provide further insight into the role which hydrophobic forces can play in the stabilization of peptide structures.

Evolution of transthyretin in marsupials.

The evolution of the expression and the structure of the gene for transthyretin, a thyroxine-binding plasma protein formerly called prealbumin, was studied in three marsupial species: the South American polyprotodont Monodelphis domestica, the Australian polyprotodont Sminthopsis macroura and the Australian diprotodont Petaurus breviceps. The transthyretin gene was found to be expressed in the choroid plexus of all three species. In liver it was expressed in P. breviceps and in M. domestica, but not in S. macroura. This, together with previous studies [Richardson, S. J., Bradley, A. J., Duan, W., Wettenhall, R. E. H., Harms, P. J., Babon, J. J., Southwell, B. R., Nicol, S., Donnellan, S. C. & Schreiber, G. (1994) Am. J. Physiol. 266, R1359-R1370], suggests the independent evolution of transthyretin synthesis in the liver of the American Polyprotodonta and the Australian Diprotodonta. The results obtained from cloning and sequencing of the cDNA for transthyretin from the three species suggested that, in the evolution of the structure of transthyretin in vertebrates, marsupial transthyretin structures are intermediate between bird/reptile and eutherian transthyretin structures. In marsupials, as in birds and reptiles, a hydrophobic tripeptide beginning with valine and ending with histidine was found in transthyretin at a position which has been identified in eutherians as the border between exon 1 and intron 1. In humans, rats and mice, the nine nucleotides, coding for this tripeptide in marsupials/reptiles/birds, are found at the 5' end of intron 1. They are no longer present in mature transthyretin mRNA. This results in a change in character of the N-termini of the subunits of transthyretin from hydrophobic to hydrophilic. This change might affect the accessibility of the thyroxine-binding site in the central channel of transthyretin, since, at least in humans, the N-termini of the subunits of transthyretin are located in the vicinity of the channel entrance [Hamilton, J. A., Steinrauf, L. K., Braden, B. C., Liepnieks, J., Benson, M. D., Holmgren, G., Sandgren, O. & Steen, L. (1993) J. Biol. Chem. 268, 2416-2424].

Differential effects of fatty acid and phospholipid activators on the catalytic activities of a structurally novel protein kinase from rat liver.

The lipid responsiveness of the structurally unique protein kinase, referred to as PAK-1, recently isolated from rat liver [(1994) J. Biol. Chem. 269, in press], is characterised by the high sensitivity (low micromolar) of its ribosomal S6(229-239) peptide kinase activity to both cardiolipin and the cis-unsaturated fatty acids and insensitivity to phosphatidylserine. Autophosphorylation of PAK-1 exhibited even greater sensitivity (submicromolar) to cardiolipin, but was relatively less affected by phosphatidylserine. Oleate, the most potent activator of PAK-1's peptide kinase activity was relatively ineffectual with autophosphorylation. These and other unusual characteristics, including high levels of basal catalytic activities, suggest a novel mechanism of regulation distinct from that of the protein kinase Cs.

A cardiolipin-activated protein kinase from rat liver structurally distinct from the protein kinases C.

A cardiolipin- and protease-activated protein kinase (PAK) has been isolated from cytoplasmic extracts of rat liver. The enzyme (PAK-1) phosphorylates the ribosomal protein S6-(229-239) peptide analogue and can be activated by limited proteolysis. Partial amino acid sequences of tryptic peptides derived from both the purified 116-kDa PAK-1 holoenzyme and its active catalytic fragment reveal that the catalytic domain is most related (50-58% identity) to the protein kinase C family. PAK-1 has protein and peptide substrate specificities distinct from those of known protein kinase C isoforms and is insensitive to inhibition by the protein kinase C-alpha-(19-31) pseudosubstrate peptide. Phosphatidylserine, diacylglycerol, and phorbol ester do not activate PAK-1 toward the S6 peptide substrate. However, other acidic phospholipids, the most effective being cardiolipin, activate PAK-1 to a similar extent as trypsin. The PAK-1 catalytic activities generated through activation by cardiolipin or limited proteolysis were kinetically similar, with Km values of 3.6 and 3.4 microM, respectively, for the S6-(229-239) peptide substrate. However, differences were observed in the catalytic activities with protamine sulfate and the glycogen synthase-(1-12) peptide analogue as substrates. It was concluded that PAK-1 is a phospholipid-regulated protein kinase with a primary structure, substrate specificity, and mechanism of regulation in vitro distinct from those of any known member of the protein kinase C superfamily.

Evolution of marsupial and other vertebrate thyroxine-binding plasma proteins.

Binding of radioactive thyroxine to proteins in the plasma of vertebrates was studied by electrophoresis followed by autoradiography. Albumin was found to be a thyroxine carrier in the blood of all studied fish, amphibians, reptiles, monotremes, marsupials, eutherians (placental mammals), and birds. Thyroxine binding to transthyretin was detected in the blood of eutherians, diprotodont marsupials, and birds, but not in blood from fish, toads, reptiles, monotremes, and Australian polyprotodont marsupials. Globulins binding thyroxine were only observed in the plasma of some mammals. Apparently, albumin is the phylogenetically oldest thyroxine carrier in vertebrate blood. Transthyretin gene expression in the liver developed in parallel, and independently, in the evolutionary lineages leading to eutherians, to diprotodont marsupials, and to birds. In contrast, high transthyretin mRNA levels, strong synthesis, and secretion of transthyretin in choroid plexus from reptiles and birds indicate that transthyretin gene expression in the choroid plexus evolved much earlier than in the liver, probably at the stage of the stem reptiles. NH2-terminal sequence analysis suggests a change of transthyretin pre-mRNA splicing during evolution.

Transthyretin gene expression in choroid plexus first evolved in reptiles.

The presence of transthyretin in mammals and birds, but not amphibia, suggested that transthyretin expression first appeared in stem reptiles. Therefore, transthyretin synthesis was studied in a lizard. Transthyretin synthesis in choroid plexus pieces from Tiliqua rugosa was demonstrated by incorporation of radiactive amino acids. Oligonucleotides corresponding to conserved regions of transthyretin were used as primers in polymerase chain reaction with lizard choroid plexus cDNA. Amplified DNA was used to screen a lizard choroid plexus cDNA library. A full-length transthyretin cDNA clone was isolated and sequenced. A three-dimensional model of lizard transthyretin was obtained by homology modeling. The central channel of transthyretin, containing the thyroxine-binding site, was found to be completely conserved between reptiles and mammals. Transthyretin expression was not detected in lizard liver. These data suggest that transthyretin first evolved in the choroid plexus of the brain. Due to a change in tissue distribution of gene expression, occurring much later during evolution, transthyretin also became a plasma protein, synthesized in the liver.

Chicken smooth muscle myosin light chain kinase is acetylated on its NH2-terminal methionine.

The reported cDNA structure of chicken smooth muscle myosin light chain kinase (smMLCK) encodes a protein of 972 residues (Olson et al. Proc. Natl. Acad. Sci USA, 87:2284-2288, 1990). The calculated M(r) is 107,534 whereas the estimate by SDS-PAGE is approximately 130,000. Gibson and Higgins (DNA Sequence (in press)) have recently reported the possibility of errors in the cDNA sequence for non-muscle MLCK and that the NH2-terminus of both it and smMLCK may extend beyond the reported coding region. The native smMLCK is NH2-terminally blocked. A CNBr peptide derived from smMLCK contains the NH2-terminal sequence Asp-Phe-Arg-Ala corresponding to residues 2 to 4 in the smMLCK sequence indicating that Met-1 is present. Using a limited thermolysin digest we isolated an NH2-terminally blocked peptide by reversed-phase HPLC. This thermolytic peptide had a mass of approximately 797 by time of flight mass spectrometry. Amino acid analysis and Edman sequencing of a CNBr-subfragment of the thermolytic peptide indicated that it had the composition and sequence, (Met)-Asp-Phe-Arg-Ala-Asn, with a calculated mass of 753. The difference in mass corresponds to the NH2-terminal Met being blocked by acetylation. The results demonstrate that the NH2-terminal sequence of smMLCK inferred from the reported cDNA sequence is correct and that the proposed initiating Met is not removed, but modified by alpha-NH2 acetylation of the translation product.

Transthyretin expression evolved more recently in liver than in brain.

1. Transthyretin was found to be synthesized and secreted by choroid plexus from rats, echidnas, and lizards, but not toads. 2. Transthyretin was observed in blood from placental mammals, birds, and marsupials, but not reptiles and monotremes. 3. The obtained data suggest that transthyretin synthesis by the liver evolved independently in the lineage leading to the placental mammals and marsupials and in that leading to the birds. 4. It is proposed that transthyretin gene expression in mammalian liver appeared about 200 million years later than its first occurrence in the choroid plexus of the stem reptiles.

Protein synthesis at the blood-brain barrier. The major protein secreted by amphibian choroid plexus is a lipocalin.

Among the proteins secreted by choroid plexus of vertebrates, one protein is much more abundant than all others. In mammals, birds, and reptiles this protein is transthyretin, a tetramer of identical 15-kDa subunits. In this study choroid plexus from frogs, tadpoles, and toads incubated in vitro were found to synthesize and secrete one predominant protein. However, this consisted of one single 20-kDa polypeptide chain. It was expressed throughout amphibian metamorphosis. Part of its amino acid sequence was determined and used for construction of oligonucleotides for polymerase chain reaction. The amplified DNA was used to screen a toad choroid plexus cDNA library. Full-length cDNA clones were isolated and sequenced. The derived amino acid sequence for the encoded protein was 183 amino acids long, including a 20-amino acid presegment. The calculated molecular weight of the mature protein was 18,500. Sequence comparison with other proteins showed that the protein belonged to the lipocalin superfamily. Its expression was highest in choroid plexus, much lower in other brain areas, and absent from liver. Since no transthyretin was detected in proteins secreted from amphibian choroid plexus, abundant synthesis and secretion of transthyretin in choroid plexus must have evolved only after the stage of the amphibians.

Rapid purification and N-terminal sequencing of a potato tuber cyclic nucleotide binding phosphatase.

A high affinity cyclic nucleotide binding phosphatase was purified to homogeneity from potato tubers by a rapid procedure involving batchwise elution from carboxymethylcellulose and gel filtration. The phosphatase has a molecular weight of 28,000 as estimated from both SDS-PAGE and gel filtration. The phosphatase binds to Con A-agarose and is eluted by 0.5 M alpha-methylglucoside. The phosphatase catalyses the hydrolysis of nucleoside monophosphates, p-nitrophenylphosphate and O-phospho-L-tyrosine, but not of O-phospho-L-serine or O-phospho-L-threonine. N-terminal sequencing of the phosphatase has revealed significant homology with two similar-size soybean leaf and stem storage glycoproteins.