Purification and binding features of a pea fructose-1,6-bisphosphatase domain involved in the interaction with thioredoxin f

We previously demonstrated that a cluster in the available 150 Asn-¹⁷⁰Glu region of pea chloroplast fructose-1,6-bisphosphatase (FBPase) could be involved in its interaction with the physiological modulator thioredoxin (Trx). Using as template a cDNA coding for pea chloroplast FBPase, a DNA insert coding for a 19 amino acid fragment ( 149 Pro-¹⁶⁷Gly) was amplified by PCR. After insertion in the pGEX-4T vector-1, it was expressed in Escherichia coli as a fusion protein (GST-19) with the vector-coded glutathione transferase (GST). This protein appears in the supernatant of cell lysates, and was purified to homogeneity. After thrombin digestion, the 19 amino acid insert was isolated as a polypeptide which displayed a positive reaction against pea chloroplast FBPase antibodies. GST-19 linked to glutathione-Sepharose beads, but not the GST, strongly interacts with pea Trx f , suggesting that this binding depends on the 19 amino acid insert. ELISA and Western blot experiments also demonstrate the existence of a GST-19-Trx f interaction, as well as a negligible quantity of Trx f bound by the vector-coded GST. Putative competitive inhibition assays of FBPase activity carried out in the presence of increasing concentrations of the 19 amino acid insert do not demonstrate any enzyme inhibition. On the contrary, this protein fragment enhances the enzyme activity proportionally to its concentration in the assay mixture. This indicates that the FBPase-Trx f binding promotes some type of structural modification of the Trx molecule, or of the FBPase-Trx docking site, thus facilitating the reductive modulation of FBPase.     

Identification of DNA replication and cell cycle proteins that interact with PCNA.

The identity of DNA replication proteins and cell cycle regulatory proteins which can be found in complexes involving PCNA were investigated by the use of PCNA immobilized on Sepharose 4B. A column containing bovine serum albumin (BSA) bound to Sepharose was used as a control. Fetal calf thymus extracts were chromatographed on PCNA-Sepharose and BSA-Sepharose. The columns were washed and then eluted with 0.5 M KCl. The salt eluates were examined for the presence of both DNA replication proteins (Pol alpha, delta, straightepsilon, PCNA, RFC, RFA, DNA ligase I, NDH II, Topo I and Topo II) and cell cycle proteins (Cyclins A, B1, D1, D2, D3, E, CDK2, CDK4, CDK5 and p21) by western blotting with specific antibodies. The DNA replication proteins which bound to PCNA-Sepharose included DNA polymerase delta and straightepsilon, PCNA, the 37 and 40 kDa subunits of RFC, the 70 kDa subunit of RPA, NDH II and topoisomerase I. No evidence for the binding of DNA polymerase alpha, DNA ligase I or topoisomerase II was obtained. Of the cell cycle proteins investigated, CDK2, CDK4 and CDK5 were bound. This study presents strong evidence that PCNA is a component of protein complexes containing DNA replication, repair and cell cycle regulatory proteins.     

Isolation and characterisation of the cDNA encoding a glycosylated accessory protein of pea chloroplast DNA polymerase.

The cDNA encoding p43, a DNA binding protein from pea chloroplasts (ct) that binds to cognate DNA polymerase and stimulates the polymerase activity, has been cloned and characterised. The characteristic sequence motifs of hydroxyproline-rich glyco-proteins (HRGP) are present in the cDNA corres-ponding to the N-terminal domain of the mature p43. The protein was found to be highly O-arabinosylated. Chemically deglycosylated p43 (i.e. p29) retains its binding to both DNA and pea ct-DNA polymerase but fails to stimulate the DNA polymerase activity. The mature p43 is synthesised as a pre-p43 protein containing a 59 amino acid long transit peptide which undergoes stromal cleavage as evidenced from the post-translational in vitro import of the precursor protein into the isolated intact pea chloroplasts. Surprisingly, p43 is found only in pea chloroplasts. The unique features present in the cloned cDNA indicate that p43 is a novel member of the HRGP family of proteins. Besides p43, no other DNA-polymerase accessory protein with O-glycosylation has been reported yet.     

Cloning,expression and characterization of a gene which encodes a topoisomerase I with positive supercoiling activity in pea

We have isolated and sequenced the full length cDNA for topoisomerase I. Using degenerate primers, based on the conserved amino acid sequences of five eukaryotic topoisomerase I, a 386 bp fragment was PCR amplified using pea cDNA as template. This fragment was used as a probe to screen a pea cDNA library. Two partial cDNA clones were isolated which were truncated at the 5 end. RACE-PCR was employed to isolate the remaining portion of the gene. The total size of the gene was 3055 bp with an open reading frame of 2676 bp. The deduced structure of pea topoisomerase I contain 892 amino acids with a calculated molecular weight of 100 kDa and an estimated pI of 9.3. A comparison of the deduced amino acid sequences of the pea topo I with the other eukaryotic topoisomerases clearly suggested that they are all related. Pea topoisomerase I has been overexpressed in E. coli system and the recombinant topoisomerase purified to homogeneity. The purified protein relaxes both positive and negative supercoiled DNA in the absence of divalent cation Mg²⁺. In the presence of Mg²⁺ ions the purified enzyme introduces positive supercoils a unique property not reported in any other organism except in archaebacterial topoisomerase I. Polyclonal antibodies were raised against recombinant topoisomerase I and western blotting with sub-cellular fractions indicated the localization of this topoisomerase in pea nuclei.     

HMG protein binding to an A/T-rich positive regulatory region of the pea plastocyanin gene promoter

Gel retardation assays using pea nuclear extracts have detected specific binding to regions of the promoter of the pea plastocyanin gene (petE). Several complexes which differ in sensitivity to competition with unlabelled promoter fragments and various DNA alternating copolymers, to heat treatment and to digestion with proteinase K have been detected. A protein factor, PCF1, forming one of these complexes was heat-stable and most sensitive to competition with poly(dAdT).poly(dAdT) compared to other alternating copolymers. DNase I footprinting assays showed that tracts of A/T-rich sequence within the -444 to -177 positive regulatory region of the petE promoter were protected in the presence of the pea nuclear extract. The factor PCF1 copurified with a high-mobility-group (HMG) protein preparation from pea chromatin. DNase I footprinting with the HMG protein preparation demonstrated that similar tracts of A/T-rich sequences within the promoter were protected. Southwestern-blot analysis of pea HMG proteins purified by gel filtration through Superose 12 detected a single DNA-binding species of 21 kDa. The properties of the factor PCF1 suggest that it is likely to be an HMG I protein.     

Isolation and characterization of a cDNA clone encoding the major hsp70 of the pea chloroplastic stroma

The 70-kD heat shock proteins (hsp70s) are a group of ubiquitous, highly conserved molecular chaperones that have been implicated in a variety of processes, ranging from DNA replication to protein folding and transport. To learn more about the evolution and possible functions of higher plant chloroplastic hsp70s, we isolated a cDNA clone encoding the major stromal hsp70 of pea chloroplasts, which we term CSS1 (Chloroplastic Stress Seventy). This cDNA clone encodes a 75,490-D protein that is very closely related to an hsp70 from the cyanobacterium, Synechocystis. CSS1 is nuclear encoded and synthesized as a higher molecular mass precursor with a chloroplastic transit peptide approximately 65 amino acids long. CSS1 mRNA was detected in RNA samples from leaves and roots of pea (Pisum sativum) plants grown at 18°C but increased 9- and 6-fold, respectively, after brief exposure of the plants to elevated temperature. We discuss the possible role(s) of CSS1 in chloroplastic protein transport and other processes.     

Molecular genetic and biochemical analysis of Brassica napus proliferating cell nuclear antigen function

A cDNA encoding the proliferating cell nuclear antigen (PCNA) from Brassica napus (oilseed rape) was shown to complement the lethal deletion mutation in the PCNA gene (POL30) of Saccharomyces cerevisiae. We provide unequivocal evidence that the B. napus PCNA can perform all the essential functions of the yeast PCNA in DNA replication, although some species-specific differences may exist. In addition, the B. napus PCNA expressed as a fusion polypeptide with glutathione S-transferase (GST) was shown to stimulate the activity and processivity of two -like DNA polymerases from wheat in vitro. These experiments provide direct biochemical evidence that the B. napus PCNA may function as an auxiliary factor in plant cell DNA replication.     

Mycoplasma fermentans Inhibits the Activity of Cellular DNA Topoisomerase I by Activation of PARP1 and Alters the Efficacy of Its Anti-Cancer Inhibitor

To understand the effects of the interaction between Mycoplasma and cells on the host cellular function, it is important to elucidate the influences of infection of cells with Mycoplasma on nuclear enzymes such as DNA Topoisomerase type I (Topo I). Human Topo I participates in DNA transaction processes and is the target of anti-cancer drugs, the camptothecins (CPTs). Here we investigated the mechanism by which infection of human tumor cells with Mycoplasma fermentans affects the activity and expression of cellular Topo I, and the anti-cancer efficacy of CPT. Human cancer cells were infected or treated with live or sonicated M. fermentans and the activity and expression of Topo I was determined. M. fermentans significantly reduced (by 80%) Topo I activity in the infected/treated tumor cells without affecting the level of Topo I protein. We demonstrate that this reduction in enzyme activity resulted from ADP-ribosylation of the Topo I protein by Poly-ADP-ribose polymerase (PARP-1). In addition, pERK was activated as a result of the induction of the MAPK signal transduction pathway by M. fermentans. Since PARP-1 was shown to be activated by pERK, we concluded that M. fermentans modified the cellular Topo I activity by activation of PARP-I via the induction of the MAPK signal transduction pathway. Moreover, the infection of tumor cells with M. fermentans diminished the inhibitory effect of CPT. The results of this study suggest that modification of Topo I activity by M. fermentans may alter cellular gene expression and the response of tumor cells to Topo I inhibitors, influencing the anti-cancer capacity of Topo I antagonists.     

Molecular cloning of cDNA coding for rat proliferating cell nuclear antigen (PCNA)/cyclin.

The 'proliferating cell nuclear antigen' (PCNA), also known as cyclin, appears at the G1/S boundary in the cell cycle. Because of its possible relationship with cell proliferation, PCNA/cyclin has been receiving attention. PCNA/cyclin is a non-histone acidic nuclear protein with an apparent mol. wt of 33000-36000. The amino acid composition and the sequence of the first 25 amino acids of rabbit PCNA/cyclin are known. Using an oligonucleotide probe corresponding to the sequence of the first five amino acids, a cDNA clone for PCNA/cyclin was isolated from rat thymocyte cDNA library. The cDNA (1195 bases) contains an open reading frame of 813 nucleotides coding for 261 amino acids. The 3'-non-coding region is 312 nucleotides long and contains three putative polyadenylation signals. The mol. wt of rat PCNA/cyclin was calculated to be 28 748. The deduced amino acid sequence and composition of rat PCNA/cyclin are in excellent agreement with the published data. Using the cDNA probe, two species of mRNA (1.1 and 0.98 kb) were detected in rat thymocyte RNA. Southern blot analysis of total human genomic DNA suggests that there is a single gene coding for PCNA/cyclin. The deduced amino acid sequence of rat PCNA/cyclin has a similarity with that of herpes simplex virus type-1 DNA binding protein.     

Structure and expression of chloroplast-localized porphobilinogen deaminase from pea (Pisum sativum L.) isolated by redundant polymerase chain reaction.

Porphobilinogen (PBG) deaminase catalyzes the polymerization of four PBG monopyrrole units into the linear tetrapyrrole hydroxymethylbilane necessary for the formation of chlorophyll and heme in plant cells. Degenerate oligonucleotide primers were designed based on amino acid sequence data (generated by mass spectrometry) for purified PBG deaminase from pea (Pisum sativum L.) chloroplasts. These primers were used in TaqI polymerase-catalyzed polymerase chain reaction (PCR) amplification to produce partial cDNA and nuclear genomic fragments encoding the enzyme. Subsequently, a 1.6-kb cDNA was isolated by screening a cDNA library constructed in lambda gt11 from leaf poly(A)+ RNA with the PCR products. The cDNA encodes an approximately 40-kD polypeptide containing a 46-amino acid NH2-terminal transit peptide and a mature protein of 323 amino acids. The deduced amino acid sequence of the mature pea enzyme is similar to PBG deaminases from other species and contains the conserved arginine and cysteine residues previously implicated in catalysis. Northern blot analysis indicates that the pea gene encoding PBG deaminase is expressed to varying levels in chlorophyll-containing tissues and is subject to light induction.     

Degradation of DNA topoisomerase I by a novel trypsin-like serine protease in proliferating human T lymphocytes

DNA topoisomerase I (Topo I) contributes to various important biological functions, and its activity is therefore likely regulated in response to different physiological conditions. Increases in both the synthesis and degradation of Topo I were previously shown to accompany phytohemagglutinin stimulation of proliferation in human peripheral T lymphocytes. The mechanism of this degradation of Topo I has now been investigated with both in vivo and in vitro assays. The activity of a nuclear protease that specifically degrades Topo I was induced in proliferating T lymphocytes. The full-length Topo I protein (100 kDa) was sequentially degraded to 97- and 82-kDa fragments both in vivo and in vitro. The initial site of proteolytic cleavage was mapped to the NH(2)-terminal region of the enzyme. The degradation of Topo I in vitro was inhibited by aprotinin or soybean trypsin inhibitor, suggesting that the enzyme responsible is a trypsin-like serine protease. Furthermore, Topo I degradation by this protease was Mg(2+)-dependent. The Topo I-specific protease activity induced during T lymphocytes proliferation was not detected in Jurkat (human T cell leukemia) cells and various other tested human cancer cell lines, possibly explaining why the abundance of Topo I is increased in tumor cells.     

A 39 amino acid fragment of the cell cycle regulator p21 is sufficient to bind PCNA and partially inhibit DNA replication in vivo.

The cell cycle regulator p21 interacts with and inhibits the DNA replication and repair factor proliferating cell nuclear antigen (PCNA). We have defined a 39 amino acid fragment of p21 which is sufficient to bind PCNA with high affinity (Kd 10-20 nM). This peptide can inhibit DNA replication in vitro and microinjection of a GST fusion protein containing this domain inhibited S phase in vivo. Despite its high affinity for PCNA, the free 39 amino acid peptide does not have a well-defined structure, as judged from circular dichroism and nuclear magnetic resonance measurements, suggesting an induced fit mechanism for the PCNA-p21 interaction. The association of the small peptide with PCNA was thermolabile, suggesting that portions of p21 adjoining the minimal region of contact stabilize the interaction. In addition, a domain containing 67 amino acids from the N-terminus of PCNA was defined as both necessary and sufficient for binding to p21.     

Structure of the human gene for the proliferating cell nuclear antigen

The proliferating cell nuclear antigen (PCNA, cyclin) was originally defined as a nuclear protein whose appearance correlated with the proliferative state of the cell. It is now known to be a co-factor of DNA polymerase delta and to be necessary for DNA synthesis and cell cycle progression. cDNA clones of human PCNA have been isolated and, using one of these cDNA, we have now obtained from a lambda phage library a clone containing the entire human PCNA gene and flanking sequences. The human PCNA gene is a unique copy gene and has 6 exons. It spans, from the cap site to the poly(A) signal 4961 base pairs. We have identified, in the 5'-flanking sequence, a region with promoter activity, a well as other structural elements common to other promoters. An interesting feature of the PCNA gene is the presence of extensive sequence similarities among introns and between introns and exons.     

Isolation and characterization of a pea pod cDNA encoding a putative blue copper protein correlated with lignin deposition

Nearly isogenic pea lines were selected to investigate the geneticbasis for lignification of the pea (Pisum sativum) pod endocarp.The development of the pod endocarp in the normal and mutantpea pod pheno-types was examined by light microscopy. A peapod cDNA library representing poly (A)+ RNA purified from L59pea pods (genotype, PV; phenotype, lignified endocarp) was differentiallyscreened with total cDNA probes prepared from total pod RNAfrom L59 and L1390 (genotype, pv; phenotype, no lignificationof endocarp) pods 4-6 d after flowering (DAF). A clone, designatedpLP18, was selected for further characterization on the basisof hybridization to the L59 cDNA probe, but not the L1390 cDNAprobe. Northern blotting was used to show that pLP18 representeda mRNA of 0.95 kb. The predicted polypeptide from the LP18 cDNAencoded a putative blue type 1 copper protein. The expressionpattern of LP18 mRNA in pods of the experimental pea lines wasdetermined using RT-PCR quantitation. Hybridization of the cDNAto pea genomic DNA showed that this protein is probably encodedby a single gene. Key words: Pisum sativum, pod endocarp, lignification, blue copper protein     

Expression of the pea gene PSMTA in E. coli. Metal-binding properties of the expressed protein

The pea (Pisum sativum L.) gene PSMTA has an ORF encoding a predicted protein with sequence similarity to class I metallothioneins (MTS). To examine the metal-binding properties of the PSMTA protein it has been expressed in E. coli as a carboxyterminal extension of glutathione-S-transferase (GST). Metal ions were associated with the expressed protein when purified from lysates of E. coli grown in metal supplemented media. The pH of half-dissociation of Zn, Cd and Cu ions from the recombinant fusion protein was determined to be 5.35, 3.95 and 1.45 respectively, compared with equivalent estimates of 4.50, 3.00 and 1.80 for equine renal MT.     

Glutamine synthetase genes of pea encode distinct polypeptides which are differentially expressed in leaves, roots and nodules.

We have characterized the distinct polypeptides, primary translation products and mRNAs encoding glutamine synthetase (GS) in the various organs of pea. Western blot analysis of soluble protein has identified five distinct GS polypeptides which are expressed at different relative levels in leaves, roots and nodules of pea. Of the two GS polypeptides in leaves (44 and 38 kd), the 44-kd GS polypeptide is predominant and is localized to the chloroplast stroma. In roots, the predominant GS polypeptide is 38 kd. Upon Rhizobium infection of roots, three 37-kd GS polypeptides increase in abundance in the nodules relative to uninfected roots. cDNA clones encoding three different GS mRNAs have been characterized. Hybrid-select translation has identified three different GS primary translation products (49, 38 and 37 kd). Two cDNA clones (pGS134 and pGS341) are homologous to GS mRNAs most abundant in nodules which encode the 38- and 37-kd GS primary translation products. A third cDNA (pGS197) corresponds to a larger GS mRNA species specific to leaf poly(A) RNA, which encodes a 49-kd putative precursor to the mature chloroplast GS polypeptide. cDNA sequence analysis and Southern blot analysis of pea nuclear DNA identifies at least three genes encoding GS in pea which are related but distinct in structure and in vivo pattern of expression.     

PCNA interacts with Indian mung bean yellow mosaic virus rep and downregulates Rep activity

Proliferative cell nuclear antigen (PCNA), a conserved plant protein as well as an important replication factor, is induced in response to geminivirus infection in the resting cells of the phloem tissues. The biochemical role of PCNA in rolling circle replication (RCR) of geminivirus DNA has not been explored in detail. The initiation of RCR of the bipartite genome of a geminivirus, Indian mung bean yellow mosaic virus (IMYMV), is mainly controlled by viral protein Rep (or AL1 or AC1). The role of host PCNA in RCR of IMYMV was revealed by studying the physical and functional interactions between recombinant PCNA and recombinant IMYMV Rep. Pea nuclear PCNA as well as recombinant pea PCNA showed binding to recombinant Rep in experiments involving both affinity chromatography and yeast two-hybrid approaches. The contacting amino acid residues of PCNA seemed to be present throughout a wide region of the trimeric protein, while those of Rep appeared to be localized only in the middle part of the protein. The site-specific nicking-closing activity and the ATPase function of IMYMV Rep were impaired by PCNA. These observations lead to interesting speculations about the control of viral RCR and dynamic profiles of protein-protein interactions at the RCR origin of the geminiviruses.     

Studies on gene structure, enzymatic activity and regulatory mechanism of acetohydroxy acid isomeroreductase from G2 pea

Using cDNA representational difference analysis (cDNA RDA), a cDNA whose expression was induced by gibberellins was cloned in our lab from G2 pea[1]. Sequence analysis showed that it shares high homology with acetohydroxy acid isomeroreductase (also known as ketol-acid reductoisomerase, EC1.1.1.86) in branched-chain amino acids biosynthetic pathway. Previous experiments confirmed that when expressed in E. coli cells, it was able to catalyze the reduction of AHB (2-aceto-2-hydroxybutyrat…