Structurally and immunologically distinct poly(A) polymerases in rat liver. Occurrence of a tumor-type enzyme in normal liver

Poly(A) polymerases purified from rat liver nuclei consisted of two distinct species, a predominant enzyme of Mr = 38,000 and a minor one of Mr = 48,000. Prior to extensive purification, the minor enzyme constituted approximately 1% of the total liver poly(A) polymerase. Poly(A) polymerase purified from a rat tumor, Morris hepatoma 3924A, was comprised of a single species of Mr = 48,000 which was identical to the minor liver enzyme with respect to chromatographic and immunological characteristics. Gel filtration on Sephacryl S-200 using 0.3 M NaCl for elution showed that the major liver poly(A) polymerase had a molecular weight of 156,000, which corresponded to a tetramer of the 38-kDa polypeptide, whereas the hepatoma and minor liver 48-kDa species existed as dimers with a molecular weight of 96,000. Fractionation by Sephacryl S-200 resulted in complete loss of both liver poly(A) polymerase activities which could be restored by exogenous N1-type protein kinase. Following CNBr cleavage, the 48-kDa poly(A) polymerase from liver and hepatoma exhibited nearly identical peptide maps which were distinct from that of the major liver enzyme (38 kDa). Antibodies raised against tumor poly(A) polymerase reacted with the 48-kDa polypeptide but not with the 38-kDa liver enzyme. Immune complex formation was observed between seven of the eight CNBr cleavage products derived from the 48-kDa polypeptide of both liver and hepatoma. It is concluded that distinct genes in rat liver code for two structurally and immunologically unique nuclear poly(A) polymerases, one of which is identical to the enzyme from the hepatoma.     

Cell-free synthesis of tumor-type poly(A) polymerase

Previous studies in this laboratory suggested that in adult liver, either the gene for the tumor-type poly(A) polymerase is poorly transcribed or the mRNA for this enzyme is largely not expressed. To test these possibilities, total RNA from rat liver and Morris hepatoma 3924A RNA were isolated by using a guanidine thiocyanate method; poly(A+) RNA and poly(A-) RNA were separated by oligo(dT)-cellulose chromatography and used for translation in a rabbit reticulocyte lysate system. After in vitro translation, the products were immunoprecipitated with either purified anti-tumor poly(A) polymerase antibodies or control immunoglobulins. When the polypeptides translated from poly(A+) or poly(A-) hepatoma RNA were precipitated with immune sera, a unique [35S]methionine-labeled 35-kilodalton (kDa) protein was observed. This band was not apparent when control serum was used for the immunoprecipitation. The radiolabeled 35-kDa polypeptide was not evident when the products were incubated with highly purified tumor nuclear poly(A) polymerase prior to immunoprecipitation. Prior incubation of the translation products with bovine serum albumin instead of poly(A) polymerase had no effect on the immunoprecipitation. This 35-kDa protein was not apparent when liver poly(A+) RNA was used to direct translation. These data demonstrate that (a) the tumor enzyme is not synthesized as a precursor, (b) tumor mRNA, but not normal liver mRNA, contains detectable sequences coding for tumor-type poly(A) polymerase, and (c) poly(A) polymerase mRNA also exists as a poly(A-) population.     

Purification and characterization of a nuclear protein kinase from rat liver and a hepatoma that is capable of activating poly(A) polymerase

The cyclic nucleotide-independent protein kinase which is separated from poly(A) polymerase during its purification from nuclei of rat liver and Morris hepatoma 3924A was purified essentially to homogeneity. Liver nuclear poly(A) polymerase was dissociated from protein kinase by phosphocellulose column chromatography. In contrast, protein kinase copurified with the hepatoma poly(A) polymerase on the phosphocellulose column. Neither liver nor hepatoma kinase was stimulated by spermine or inhibited by heparin. These enzymes did not utilize GTP as phosphoryl donor, or histones or tyrosine-containing [Val5]-angiotensin II as phosphoryl acceptors. The apparent Km with respect to ATP was similar for the liver (4.7 microM) and hepatoma (11 microM) kinases, and the apparent Km with respect to casein was identical (0.6 microgram/microliter) for these enzymes. Both enzymes were capable of phosphorylating poly(A) polymerase and stimulating both tumor and liver poly(A) polymerase activity. However, in addition to their different chromatographic properties, the two kinases differed in molecular weight (liver, 37,000; hepatoma, 56,000), in their response to various divalent metal ions, and in their ability to phosphorylate hepatoma poly(A) polymerase (Km 7.9 and 30 microgram/microliter for liver and hepatoma enzymes, respectively). These latter characteristics distinguished the liver and hepatoma protein kinases from each other as well as from the previously described NI protein kinase.     

Association of newly synthesized poly(A) polymerase with four distinct polypeptides

Nuclear poly(A) polymerase was isolated from [35S]methionine-labeled hepatoma McA-RH 7777 cells and subjected to DEAE-Sephadex chromatography. Flow-through and low salt wash fractions containing poly(A) polymerase activity were pooled and subjected to immunoblot analysis using anti-tumor type poly(A) polymerase antibodies and a biotinylated second antibody. The immune complex contained a single 48-kDa polypeptide band corresponding to the tumor-type enzyme. When immunoprecipitations were carried out using the same fraction and antibodies, at least five 35S-methionine-labeled proteins with approximate molecular masses of 74, 48, 35, 30, and 22 kDa were observed. Pulse-chase studies did not indicate a precursor-product relationship between the immunoprecipitated proteins. Preimmune sera did not react with poly(A) polymerase or other components in the protein complex. These data show that poly(A) polymerase exists as part of a complex with at least four other polypeptides and suggest that these polypeptides may be involved in the cleavage and/or polyadenylation reactions.     

Association of poly(A) polymerase with U1 RNA

Previous studies (Stetler, D. A., and Jacob, S. T. (1984) J. Biol. Chem. 259, 7239-7244) have shown that poly(A) polymerase from adult rat liver (liver-type) is structurally and immunologically distinct from the corresponding rat hepatoma (tumor-type) enzyme. When hepatoma 7777 (McA-RH 7777) cells were labeled with [32P]inorganic phosphate, followed by immunoprecipitation with anti-hepatoma poly(A) polymerase antibodies and analysis of the RNAs in the immunoprecipitate, only one labeled small nuclear RNA corresponding to U1 RNA was found. Preimmune sera did not form a complex with U1 RNA. Hepatoma poly(A) polymerase antisera did not immunoprecipitate U1 RNA or any other small nuclear RNA from a cell line (H4-11-EC3) which does not contain the tumor-type poly(A) polymerase. Immunoblot analysis of hepatoma 7777 nuclear extract or purified poly(A) polymerase with anti-ribonucleoprotein antisera did not show any cross-reactivity of the latter sera with poly(A) polymerase. The major RNA immunoprecipitated from the hepatoma nuclear extracts using trimethyl cap (m3G) antisera corresponded to the RNA immunoprecipitated with poly(A) polymerase antisera. These data indicate that U1 RNA is closely associated with poly(A) polymerase and suggest the potential involvement of this RNA in the cleavage/polyadenylation of mRNA precursor.     

Two distinct poly(A) polymerases isolated from the cytoplasm of Ehrlich ascites tumour cells

The poly(A) polymerases from the cytosol and ribosomal fractions of Ehrlich ascites tumour cells are isolated and partially purified by DEAE-cellulose and phosphocellulose column chromatography. Two distinct enzymes are identified: (a) a cytosol Mn2+-dependent poly(A) polymerase (ATP:RNA adenylyltransferase) and (b) a ribosome-associated enzyme defined tentatively as ATP(UTP): RNA nucleotidyltransferase. The cytosol poly(A) polymerase is strictly Mn2+-dependent (optimum at 1 mM Mn2+) and uses only ATP as substrate, poly(A) is a better primer than ribosomal RNA. The purified enzyme is free of poly(A) hydrolase activity, but degradation of [3H]poly(A) takes place in the presence of inorganic pyrophosphate. Most likely this enzyme is of nuclear origin. The ribosomal enzyme is associated with the ribosomes but it is found also in free state in the cytosol. The purified enzyme uses both ATP and UTP as substrates. The substrate specificity varies depending on ionic conditions: the optimal enzyme activity with ATP as substrate is at 1 mM Mn2+, while that with UTP as substrate is at 10--20 mM Mg2+. The enzymes uses both ribosomal RNA and poly(A) [but not poly(U)] as primers. The purified enzyme is free of poly(A) hydrolase activity.     

DNA polymerase alpha from normal rat liver is different than DNA polymerases alpha from Morris hepatoma strains

To investigate whether DNA replication in rat hepatoma cells is altered compared with that in normal rat liver, the main replicative enzyme, i.e. the DNA polymerase alpha complex, was partially purified from a slow-growing (TC5123) and a fast-growing (MH3924) Morris hepatoma cell strain as well as from normal rat liver. The purified DNA polymerase alpha complexes contained RNA primase. DNA polymerase alpha activities of these complexes were characterized with regard to both their molecular properties and their dNTP and DNA binding sites. The latter were probed with competitive inhibitors of dNTP binding, resulting in Ki values, and with DNA templates, yielding Km values. The sedimentation coefficients of native DNA polymerases alpha from Morris hepatoma cells were found to be lower than that of polymerase alpha from normal rat liver. Consequently, when following the procedure of Siegel and Monty for determination of molecular mass considerably smaller molecular masses were calculated for polymerases of hepatoma strains (TC5123, 127 kDa; MH3924, 138 kDa; rat liver, 168 kDa). Similar differences were found when the dNTP binding site was probed with inhibitors. Ki values obtained with butylphenyl-dGTP were higher for polymerases of the hepatoma strains than for that of normal rat liver. However, Ki values measured with aphidicolin and butylanilino-dATP were lower for DNA polymerase alpha from the fast-growing hepatoma cell strain than for that from normal rat liver, indicating a reduced affinity of the dNTP binding sites for dATP and dCTP. This reduced affinity could be responsible for lowered specificity of nucleotide selection in the base-pairing process which in turn may cause an enhanced error rate in DNA replication in malignant cells. Furthermore, when the DNA binding site was characterized by Michaelis-Menten constants using gapped DNA as a template, Km values were similar for all three DNA polymerases. In contrast, the Km value measured with single-stranded DNA as a template was found to be lower for DNA polymerase alpha from the fast-growing hepatoma MH3924 than for that from normal rat liver. Thus, the DNA-polymerizing complex from MH3924 combines both higher binding strength to single-stranded DNA templates and decreased nucleotide selection, properties which may enhance replication velocity and may lower fidelity.     

Tissue and species distribution of liver type and tumor type nuclear poly(A) polymerases

Previous studies in this laboratory have identified two distinct nuclear poly(A) polymerases, a 48 kDA tumor type enzyme and a 36-38 kDA liver type enzyme. To investigate the tissue and species specificity of these enzymes, nuclear extracts were prepared from various rat tissues, pig brain and two human cell lines. These as well as whole cell extract from yeast were probed for the two enzymes by immunoblot analysis using polyclonal anti-tumor poly(A) polymerase antibodies or autoimmune sera which contain antibodies specific for the liver type enzyme. Results indicate that both tumor and liver type enzymes are conserved across species ranging from rat to human. The yeast enzyme does not appear to be immunologically related to the liver or the tumor type poly(A) polymerase. The liver type enzyme appears to be specific for normal tissues whereas the tumor type enzyme is detected only in tissues in a "tumorigenic" state or cell lines originating from tumor tissues.     

Purification and characterization of dihydropyrimidine dehydrogenase from pig liver

Dihydropyrimidine dehydrogenase was isolated from cytosolic pig liver extracts and purified 3100-fold to apparent homogeneity. Purification made use of ammonium sulfate fractionation, precipitation with acetic acid and chromatography on DEAE-cellulose and 2',5'-ADP-Sepharose with 28% recovery of total activity. The native enzyme has a molecular mass of 206 kDa and is apparently composed of two similar, if not identical, subunits. Proteolytic cleavage reveals two fragments with apparent molecular masses of 92 kDa and 12 kDa. The C-terminal 12-kDa fragment seems to be extremely hydrophobic. The enzyme contains tightly associated compounds including four flavin nucleotide molecules and 32 iron atoms/206-kDa molecule. The iron atoms are probably present in iron-sulfur centers. The flavins released from the enzyme were identified as FAD and FMN in equal amounts. An isoelectric point of 4.65 was determined for the dehydrogenase. Apparent kinetic parameters were obtained for the substrates thymine, uracil, 5-aminouracil, 5-fluorouracil and NADPH.     

Three DNA polymerases of rat ascites hepatoma cells: properties of the enzymes and effect of RNA synthesis on the reactions.

Three different DNA polymerases have been isolated from rat ascites hepatoma cells [1--3]. The molecular weight of a DNA polymerase (polymerase C) purified from the soluble fraction of the cells was estimated to be 142 000 by sedimentation on a sucrose gradient, while the molecular weights of two DNA polymerases (polymerase P-1 and P-2) purified from nuclear membrane-chromatin fraction were estimated to be 117 000 and 44 000, respectively, by the same method. Under certain conditions, the poly (dT) strand of poly[(dA)-(dT)] was copied well by the polymerases, especially by the nuclear polymerases. Poly (dC) was a good template for the high molecular weight DNA polymerases C and P-1, but poly(dT) and poly(dA) were not effective templates. By addition of complementary oligoribonucleotides, the single-stranded deoxypolymers were copied by the high molecular weight polymerases C and P-1. When single-stranded fd phage DNA was used as template, the polymerization reactions by the high molecular weight polymerases were stimulated by the concomitant synthesis of RNA. This indicates that the oligoribonucleotide acts as a primer in these reactions.     

Purification and characterization of rat-liver cytosolic epoxide hydrolase

Rat liver cytosolic epoxide hydrolase has been purified and characterized. The enzyme was purified from tiadenol-induced rat liver 540-fold with respect to trans-stilbene oxide as a substrate. Similar purification was obtained with the substrates trans-beta-ethyl styrene oxide and styrene 7,8-oxide, the specific activities decreasing in the order trans-beta-ethyl styrene oxide greater than styrene 7,8-oxide greater than trans-stilbene oxide. The enzyme exerts highest activity at pH 7.4 Km and Vmax of the pure enzyme for trans-stilbene oxide were 1.7 microM and 205 nmol x min-1 x mg protein-1 respectively. With trans-stilbene oxide as a substrate, the inhibition by organic solvents (2.5% by vol.) increased in the order ethanol less than methanol less than acetone less than isopropanol = N,N-dimethyl formamide less than acetonitrile less than tetrahydrofuran. The native enzyme, with a molecular mass of 120 kDa, consists of two 61-kDa subunits. Digestion of rat liver cytosolic and microsomal epoxide hydrolase by three proteases resulted in markedly different peptide maps. Western-blot analysis with antiserum against rat liver cytosolic epoxide hydrolase revealed a single band with the purified enzyme, and with liver cytosol from control and clofibrate-induced rats. No cross-reactivity was observed with purified rat microsomal epoxide hydrolase or microsomes. A positive reaction at the same molecular mass was obtained with liver cytosol of mouse, guinea pig, Syrian hamster and New Zealand white rabbit but not with that of green monkey.     

Two proteolytic degradation products of calf-thymus poly(ADP-ribose) polymerase are efficient ADP-ribose acceptors. Implications for polymerase architecture and the automodification of the polymerase

Two polypeptides with molecular masses of 76 and 59 kDa were found to copurify with poly(ADP-ribose) polymerase from calf thymus, and to be as efficient acceptors of ADP-ribose as the polymerase itself. Analysis of their CNBr fragments by sodium dodecylsulfate/polyacrylamide gel electrophoresis revealed that the polypeptides were derived from the 112-kDa polymerase. Isolation of poly(ADP-ribose) polymerase in the absence of protease inhibitors resulted in a loss of more than 90% of the polymerase activity and an increased proportion of the 76-kDa and 59-kDa polypeptides in the final polymerase preparation. When the polymerase and the two polypeptides were separated by gel filtration or polyacrylamide gel electrophoresis in 5% acetic acid, no polymerase activity was found associated with the two fragments. Analysis of the CNBr fragments of the three polypeptides after incubation of the enzyme preparation with [32P]NAD showed that most of the fragments were radioactive, indicating multiple ADP-ribosylation sites. Several ADP-ribosylated fragments were found to be common to all three polypeptides, or to two of them.     

DNA polymerases of rat liver. Partial characterization and effect of various inhibitors.

Three distinct DNA-dependent DNA polymerase activities have been partially purified from normal rat liver. Soluble activities are separable into two distinct fractions (P1 and P2) by phosphocellulose chromatography. A low-molecular-weight DNA polymerase was isolated from purified nuclei. The enzymes were characterized according to chromatographic and sedimentation behavior, enzymological properties, and response to various inhibitors. The results indicate that fraction P1 corresponds to the high-molecular-weight enzyme and suggest that polymerase P2 may be derived from partial dissociation of the high-molecular-weight enzyme. The molecular weight of polymerase P1 was estimated to be about 250 000 by Sephadex column chromatography. Both fraction P2 and nuclear DNA polymerase appeared to be low-molecular-weight enzymes. However, the molecular size of these activities was apparently different. The estimated molecular weights of nuclear and P2 enzyme are about 40 000 and 25 000, respectively. As with the nuclear enzyme, polymerase P2 (but not P1) appeared to be free of detectable exonuclease activity. All of these polymerases showed a marked preference for initiated polydeoxyribonucleotide templates. The rat liver polymerases differed in their ability to use poly[d(A-T)-A1 primer-template, as is shown by the ratios of their activity with this synthetic polymer to that with activated DNA: 0.5, 2.75, and 1.34 for P1, P2, and nuclear polymerase, respectively. Denatured DNA was a poor template for both enzymes P1 and P2, but it was inert as template for the nuclear enzyme. Although each of these polymerases required all four deoxynucleoside triphosphates for maximal activity, they catalyzed a high rate of synthesis in the absence of one or more deoxynucleoside triphosphates. Such a 'limited' synthesis was much more extensive for polymerase P2 and nuclear enzyme than for P1 was the most sensitive of the three to sulphydryl reagents, ehtidium bromide, heparin, and single-stranded DNA. The responses of P2 and nuclear enzymes to various inhibitors were very similar. However, these two enzymes respond differently to heat and high ionic strength.     

A simple procedure for isolation of eukaryotic mRNA polyadenylation factors.

We have devised a simple chromatographic procedure which isolates five polyadenylation factors that are required for polyadenylation of eukaryotic mRNA. The factors were separated from each other by fractionation of HeLa cell nuclear extract in two consecutive chromatographic steps. RNA cleavage at the L3 polyadenylation site of human adenovirus 2 required at least four factors. Addition of adenosine residues required only two of these factors. The fractionation procedure separates two components that are both likely to be poly(A) polymerases. The candidate poly(A) polymerases were interchangeable and participated during both RNA cleavage and adenosine addition. They were discriminated from each other by chromatographic properties, heat sensitivity and divalent cation requirement. We have compared our data with published information and have been able to correlate the activities that we have isolated to previously identified polyadenylation factors. However, we have not been able to assign one of the candidate poly(A) polymerases to a previously identified poly(A) polymerase. This simple fractionation procedure can be used for generating an in vitro reconstituted system for polyadenylation within a short period of time.     

Nuclear and chloroplast poly(A) polymerases from plants share a novel biochemical property

Poly(A) polymerases are centrally involved in the process of mRNA 3' end formation in eukaryotes. In animals and yeast, this enzyme works as part of a large multimeric complex to add polyadenylate tracts to the 3' ends of precursor RNAs in the nucleus. Plant nuclear enzymes remain largely uncharacterized. In this report, we describe an initial analysis of plant nuclear poly(A) polymerases (nPAPs). An enzyme purified from pea nuclear extracts possesses many features that are seen with the enzymes from yeast and mammals. However, the pea enzyme possesses the ability to polyadenylate RNAs that are associated with polynucleotide phosphorylase (PNP), a chloroplast-localized enzyme involved in RNA turnover. Similar behavior is not seen with the yeast poly(A) polymerase (PAP). A fusion protein consisting of glutathione-S-transferase and the active domain of an Arabidopsis-encoded nuclear poly(A) polymerase was also able to utilize PNP, indicating that the activity of the pea enzyme was due to an interaction between the pea nPAP and PNP, and not to other factors that might copurify with the pea enzyme. These results suggest the existence, in plant nuclei, of factors related to PNP, and an interaction between such factors and poly(A) polymerases.     

A DNA polymerase with unusual properties from the slime mold Physarum polycephalum

Two forms of a DNA polymerase have been purified from microplasmodia of Physarum polycephalum by poly(ethyleneimine) precipitation and chromatography on DEAE-Sephacel, phosphocellulose, heparin Sepharose, hydroxyapatite, DNA-agarose, blue-Sepharose. They were separated from DNA polymerase alpha on phosphocellulose and from each other on heparin-Sepharose. Form HS1 enzyme was 30-40% pure and form HS2 enzyme 60% with regard to protein contents of the preparations. Form HS2 enzyme was generated from form HS1 enzyme on prolonged standing of enzyme preparations. The DNA polymerases were obtained as complexes of a 60-kDa protein associated with either a 135-kDa (HS1) or a 110-kDa (HS2) DNA-polymerizing polypeptide in a 1:1 molar stoichiometry. The biochemical function of the 60-kDa protein remained unknown. The complexes tended to dissociate during gradient centrifugation and during partition chromatography as well as during polyacrylamide gradient gel electrophoresis under nondenaturing conditions at high dilutions of samples. Both forms existed in plasmodia extracts, their proportions depending on several factors including those which promoted proteolysis. The DNA polymerases resembled eucaryotic DNA polymerase beta by several criteria and were functionally indistinguishable from each other. It is suggested that lower eucaryotes contain repair DNA polymerases, which are similar to those of eubacteria on a molecular mass basis.     

Two forms of DNA polymerase delta from mouse cells. Purification and properties

A procedure is described for the purification from cultured mouse cells of two DNA polymerase "delta-like" enzymes, as defined by intrinsic 3'-exonuclease activity, inhibition by aphidicolin, and relative insensitivity to N2-(p-n-butylphenyl)-dGTP. One of the two enzymes has been purified to near homogeneity and, similar to the DNA polymerase delta from calf thymus described by Lee et al. (Lee, M. Y. W. T., Tan, C. K., Downey, K. M., and So, A. G. (1984) Biochemistry 23, 1906-1913), it has a total molecular mass of 178 kDa (from sedimentation velocity of 8.0 S and Stokes radius of 54 A) and is composed of one each of 125- and 50-kDa polypeptides. It also resembles the DNA polymerase delta of Lee et al. in being stimulated by proliferating cell nuclear antigen (PCNA). It is the first clear structural and functional counterpart of the calf thymus enzyme. The major difference between the mouse DNA polymerase delta and the calf thymus enzyme of Lee et al. is that, under specific conditions, the mouse enzyme is active with poly(dA).oligo(dT) in the absence of PCNA, whereas the activity of the calf thymus enzyme with this template is reported to be completely dependent on PCNA. The reason for this difference is not known at this time. The second mouse cell enzyme has a molecular mass of 112 kDa (from sedimentation velocity of 6.3 S and Stokes radius of 43.0 A) and consists of a single polypeptide of 123-125 kDa in denaturing gels (p125). On the basis of its apparent formation by dissociation of DNA polymerase delta, and multiple similarities with DNA polymerase delta in enzymatic properties, the p125 is provisionally identified as the 125-kDa polypeptide of DNA polymerase delta. The p125 does not respond to PCNA, suggesting that the 50-kDa polypeptide is required for the stimulation of DNA polymerase delta by PCNA. The presence of the p125 in cell extracts would explain reports that DNA polymerase delta consists of a single polypeptide of approximately 125 kDa and/or thast it has a smaller molecular mass than DNA polymerase delta of Lee et al. and is not affected by PCNA (this does not apply to PCNA-independent DNA polymerase delta-like enzymes with higher molecular mass than the polymerase delta of Lee et al., which have recently been named DNA polymerases epsilon).     

Purification of a mitochondrial DNA polymerase from Crithidia fasciculata.

The mitochondrial DNA polymerase from Crithidia fasciculata has been purified to near homogeneity. SDS-PAGE analysis of the purified enzyme reveals a single polypeptide with a molecular weight of approximately 43,000. The protein is basic, with an isoelectric point between 7.6-8.0. Its Stokes radius of 22 A and its sedimentation coefficient of 4.1 S suggest a native molecular weight of 38,000, indicating that the protein is a monomer under our experimental conditions. Western blots and immunoprecipitations of crude extracts reveal a cross-reacting protein of 48 kDa, suggesting that the purified enzyme may be an enzymatically active proteolytic product. The mitochondrial origin of the polymerase was confirmed by cell fractionation. Our results indicate that the C. fasciculata enzyme may be among the smallest known mitochondrial polymerases.     

Molecular and immunological characterization of plastid and cytosolic pyruvate kinase isozymes from castor-oil-plant endosperm and leaf

1. Monospecific antiserum was raised in rabbits to homogeneous cytosolic pyruvate kinase isolated from 5-day-old germinating endosperm of the castor oil plant, Ricinus communis. An earlier study demonstrated that the purified enzyme is putatively heterotetrameric, composed of two subunits which migrate as 57-kDa and 56-kDa proteins upon sodium dodecyl sulfate/polyacrylamide gel electrophoresis [Plaxton, W. C. (1988) Plant Physiol. (Bethesda) 86, 1065-1069]. Both proteins were detected on Western blots of extracts prepared under denaturing conditions from 4-8-day-old, but not 0-3-day-old, germinating-endosperm tissue. This suggests that both subunits exist in vivo, and that the large increase in pyruvate kinase activity which occurs around the fourth day of germination is due to an increase in pyruvate kinase concentration. 2. The cytosolic and plastidic pyruvate kinase isozymes (termed PKc and PKp, respectively) from castor-oil-plant developing endosperm and expanding leaf tissue were separated by anion-exchange chromatography on Q-Sepharose. The antigenic reaction of the partially purified enzyme preparations to rabbit polyclonal antibodies raised against homogeneous germinating-castor-bean PKc was tested by immunoprecipitation and Western blotting. Although developing-endosperm and leaf PKc appeared to be antigenically very similar to germinating-endosperm PKc, they differed from the heterotetrameric germinating-endosperm enzyme by being composed of a single type of subunit with a molecular mass of about 56 kDa. No cross-reactivity of the PKc antibodies was observed with either developing-endosperm or leaf PKp, nor with rabbit muscle or Bacillus stearothermophilus pyruvate kinase. Conversely, none of the castor-oil-plant pyruvate kinase preparations showed significant cross-reactivity with antibodies raised against purified yeast or rabbit muscle pyruvate kinases. 3. To investigate the structural relationship between the two germinating-endosperm-PKc subunits, each polypeptide was characterized by amino acid composition analysis and peptide mapping by CNBr fragmentation. The amino acid compositions and CNBr cleavage patterns of the two subunits were similar, but not identical, suggesting that these polypeptides are related, but distinct, proteins. Mild tryptic attack of native enzyme led to an approximate 6-kDa reduction in the apparent molecular mass of both subunits, further indicating sequence similarity between the two polypeptides. 4. Native molecular masses of the various castor-oil-plant pyruvate kinases were estimated by Superose-6 gel-filtration chromatography.(ABSTRACT TRUNCATED AT 400 WORDS)     

Immunological properties and peptide mapping of two type I casein kinases from yeast

Two protein kinases of Mr 43,000 and 23,000 from yeast, belonging to type-1 casein kinases, were purified to apparent homogeneity and used for investigation of their immunological affinity and for comparison of their peptide map patterns. The results obtained showed that antibodies against the 43 kDa kinase did not react with the 23 kDa enzyme. Moreover, the peptide maps of the radioiodinated kinases obtained either by chemical cleavage of peptide bonds in the presence of CNBr or by a limited digestion with V8 protease were completely different. All these observations point to the lack of relatedness between the two investigated enzymes.