Trypanosoma cruzi: multiple nucleoside diphosphate kinase isoforms in a single cell

Nucleoside diphosphate kinases (NDPKs) are multifunctional enzymes involved mainly in the conservation of nucleotides and deoxynucleotides at intracellular levels. Here we report the characterization of two NDPKs from the protozoan parasite Trypanosoma cruzi, the etiological agent of Chagas disease. TcNDPK1 and TcNDPK2 were biochemically characterized presenting different kinetic parameters and regulation mechanisms. NDPK activity was mainly detected in soluble fractions according to the digitonin extraction technique; however 20% of the activity remains insoluble at digitonin concentrations up to 5 mg ml⁻¹. TcNDPK1 is a short enzyme isoform, whereas TcNDPK2 is a long one containing a DM10 motif. In addition, two other putative NDPK genes (TcNPDK3 and TcNDPK4) were detected by data mining at the T. cruzi genome database. The large number and diversity of NDPK isoforms are in agreement with those previously observed for other T. cruzi phosphotransferases, such as adenylate kinases.     

The pea mitochondrial nucleoside diphosphate kinase cleaves DNA and RNA

Here, we present the characterization of a plant NDPK exhibiting nuclease activity. This is the first identification of a nuclease localised in the intermembrane space of plant mitochondria. The recombinant pea NDPK3 protein cleaves not only supercoiled plasmid DNA, but also highly structured RNA molecules such as tRNAs or the 3'UTR of the atp9 mRNA suggesting that the NDPK3 nuclease activity has a structural requirement. ATP inhibits this nuclease activity, while ADP has no effect. Furthermore, studies on NDPK mutant proteins indicate that the nuclease- and the kinase-mechanisms are separate.     

Elimination of double strand nuclease activity from S1 nuclease prepared from crude alpha amylase.

Single strand-specific s1 nuclease prepared as previously described from crude alpha amylase by DEAE-cellulose chromatography also contains nuclease which degrades double strand nucleic acid. The double strand activity can be removed by repeating the DEAE-cellulose chromatography procedure at least two additional times. S1 nuclease prepared by this procedure does not degrade double strand sheared DNA as measured by Sephadex chromatography. Under the same conditions single strand DNA is completely degraded. Thus, S1 nuclease prepared by this procedure is suitable for use in removing single strand regions in DNA/DNA duplexes and DNA/RNA hybrids.     

Sequence and S1 nuclease mapping of the 5'' region of the dihydrofolate reductase-thymidylate synthase gene of Leishmania major.

The 5' structure of mRNA transcribed from the dihydrofolate reductase-thymidylate synthase (DHFR-TS) gene of the protozoan parasite Leishmania major has been characterized. S1 nuclease mapping identifies a heterogenous 5' structure which is not affected by growth phase or developmental stage. The DNA sequence of the 5' region of the DHFR-TS gene does not reveal homology with other trypanosomatid genes, eukaryotic consensus genetic elements, or the mammalian DHFR promoter element. This latter finding is especially significant as we show that the 5' region of the E. coli DHFR gene exhibits homology to the mammalian DHFR promoter element, despite their greater evolutionary distance.     

The active site of the DNA repair endonuclease XPF-ERCC1 forms a highly conserved nuclease motif

XPF-ERCC1 is a structure-specific endonuclease involved in nucleotide excision repair, interstrand crosslink repair and homologous recombination. So far, it has not been shown experimentally which subunit of the heterodimer harbors the nuclease activity and which amino acids contribute to catalysis. We used an affinity cleavage assay and located the active site to amino acids 670-740 of XPF. Point mutations generated in this region were analyzed for their role in nuclease activity, metal coordination and DNA binding. Several acidic and basic residues turned out to be required for nuclease activity, but not DNA binding. The separation of substrate binding and catalysis by XPF-ERCC1 will be invaluable in studying the role of this protein in various DNA repair processes. Alignment of the active site region of XPF with proteins belonging to the Mus81 family and a putative archaeal RNA helicase family reveals that seven of the residues of XPF involved in nuclease activity are absolutely conserved in the three protein families, indicating that they share a common nuclease motif.     

Comparison of Nuclease P1-Malonogalactan Complex with Nuclease P1

Properties of nuclease P₁-malonogalactan complex (P₁-MG) were compared with those of the polysaccharide-free nuclease P₁. Significant difference was not observed between them in phosphomonoester splitting activity, but marked differences were observed in nucleolytic activity as follows: (1) The pH optima of P₁-MG for RNA and heat-denatured DNA were lower than those of nuclease P₁. (2) At lower than 0.001 of ionic strength, RNA and heat- denatured DNA were attacked hardly by P₁-MG, but attacked well by nuclease P₁. (3) The increase in hydrolysis rate of RNA or heat-denatured DNA with an elevation of temperature from 37°C to 70°C was not so marked in P₁-MG as compared with nuclease P₁. (4) P₁-MG hydrolyzed polynucleotides, especially native DNA, much slower than nuclease P₁.

Influence of ionic strength, pH and temperature on the nucleolytic activity of nuclease P₁-galactan (P₁-G), which was prepared by demalonylating P₁-MG enzymatically, was similar to that of nuclease P₁, except that the activity of P₁-G for native DNA was much lower than nuclease P₁.     

Protein switches identified from diverse insertion libraries created using S1 nuclease digestion of supercoiled-form plasmid DNA

We demonstrate that S1 nuclease converts supercoiled plasmid DNA to unit-length, linear dsDNA through the creation of a single, double-stranded break in a plasmid molecule. These double-stranded breaks occur not only in the origin of replication near inverted repeats but also at a wide variety of locations throughout the plasmid. S1 nuclease exhibits this activity under conditions typically employed for the nuclease's single-stranded nuclease activity. Thus, S1 nuclease digestion of plasmid DNA, unlike analogous digestion with DNaseI, effectively halts after the first double-stranded break. This property makes easier the construction of large domain insertion libraries in which the goal is to insert linear DNA at a variety of locations throughout a plasmid. We used this property to create a library in which a circularly permuted TEM1 β-lactamase gene was inserted throughout a plasmid containing the gene encoding Escherichia coli ribose binding protein. Gene fusions that encode allosteric switch proteins in which ribose modulates β-lactamase catalytic activity were isolated from this library using a combination of a genetic selection and a screen.     

In Vitro Processing of Herpes Simplex Virus Type 1 DNA Replication Intermediates by the Viral Alkaline Nuclease, UL12

Herpes simplex virus type 1 (HSV-1) DNA replication intermediates exist in a complex nonlinear structure that does not migrate into a pulsed-field gel. Genetic evidence suggests that the product of the UL12 gene, termed alkaline nuclease, plays a role in processing replication intermediates (R. Martinez, R. T. Sarisky, P. C. Weber, and S. K. Weller, J. Virol. 70:2075–2085, 1996). In this study we have tested the hypothesis that alkaline nuclease acts as a structure-specific resolvase. Cruciform structures generated with oligonucleotides were treated with purified alkaline nuclease; however, instead of being resolved into linear duplexes as would be expected of a resolvase activity, the artificial cruciforms were degraded. DNA replication intermediates were isolated from the well of a pulsed-field gel (“well DNA”) and treated with purified HSV-1 alkaline nuclease. Although alkaline nuclease can degrade virion DNA to completion, digestion of well DNA results in a smaller-than-unit-length product that migrates as a heterogeneous smear; this product is resistant to further digestion by alkaline nuclease. The smaller-than-unit-length products are representative of the entire HSV genome, indicating that alkaline nuclease is not inhibited at specific sequences. To further probe the structure of replicating DNA, well DNA was treated with various known nucleases; our results indicate that replicating DNA apparently contains no accessible double-stranded ends but does contain nicks and gaps. Our data suggest that UL12 functions at nicks and gaps in replicating DNA to correctly repair or process the replicating genome into a form suitable for encapsidation.     

RELATIONSHIP BETWEEN NUCLEOSIDE DIPHOSPHATE KINASE ACTIVITY AND LIGHT-LIMITED GROWTH RATE IN THE MARINE DIATOM THALASSIOSIRA PSEUDONANA (BACILLARIOPHYCEAE)1

Light-limited cultures of the marine diatom Thalassiosira pseudonana (Hustedt) Hasle and Heimdal (3H clone) were grown over a range of growth rates between 0.06 and 1.64 d^?1. Variations in cell volume, cell quotas of carbon, nitrogen, and protein, and maximal activity of the enzyme nucleoside diphosphate kinase (NDPK) were measured and examined as a function of growth rate. NDPK from T. pseudonana showed K_m values of 0.24 and 0.68 mM for thymidine 5′-diphosphate and adenosine 5′-triphosphate (ATP), respectively, which are similar to those found for NDPK from a variety of organisms, from bacteria to mammals. An apparent activation enthalpy of 3.52 kCal·mol^?1 was determined from Arrhenius plots. No thermodynamic transition points were noted over a temperature range from 10° to 25°C. NDPK activity was significantly correlated with growth rate but not with cell volume, carbon, nitrogen, or protein; for interspecific comparisons, normalization of enzyme activity to cell number may be most meaningful. NDPK activity per cell versus growth rate followed a U-shaped relationship, being relatively constant between 0.5 and 1.0 d^?1 and rising at higher and lower growth rates. Over this range, enzyme activity may be regulated by substrate concentration (ATP or other nucleoside triphosphates) or by adenylate energy charge. At higher growth rates where energy charge and substrate concentrations are probably high, changes in enzyme concentration appear to be required. The reasons for a rise in enzyme activity at low growth rate is unclear. Simultaneous measurement of nucleoside di- and triphosphate levels alongside NDPK measurements may help clarify the relationship, but these preliminary experiments indicate that NDPK is of limited usefulness as an index of in situ growth rate.     

The C. elegans apoptotic nuclease NUC-1 is related in sequence and activity to mammalian DNase II

The Caenorhabditis elegans nuc-1 gene has previously been implicated in programmed cell death due to the presence of persistent undegraded apoptotic DNA in nuc-1 mutant animals. In this report, we describe the cloning and characterization of nuc-1, which encodes an acidic nuclease with significant sequence similarity to mammalian DNase II. Database searches performed with human DNase II protein sequence revealed a significant similarity with the predicted C. elegans C07B5.5 ORF. Subsequent analysis of crude C. elegans protein extracts revealed that wild-type animals contained a potent endonuclease activity with a cleavage preference similar to DNase II, while nuc-1 mutant worms demonstrated a marked reduction in this nuclease activity. Sequence analysis of C07B5.5 DNA and mRNA also revealed that nuc-1(e1392), but not wild-type animals contained a nonsense mutation within the CO7B5.5 coding region. Furthermore, nuc-1 transgenic lines carrying the wild-type C07B5.5 locus demonstrated a complete complementation of the nuc-1 mutant phenotype. Our results therefore provide compelling evidence that the C07B5.5 gene encodes the NUC-1 apoptotic nuclease and that this nuclease is related in sequence and activity to DNase II.     

Random cleavage of superhelical SV 40 DNA S1 nuclease.

SV40 DNA FO I is randomly cleaved by S1 nuclease both at moderate (50 mM) and higher salt concentrations (250 mM NaC1). Full length linear S1 cleavage products of SV40 DNA when digested with various restriction endonucleases revealed fragments that were electrophoretically indistinguishable from the products found after digestion of superhelical SV40 DNA FO I with the corresponding enzyme. Concordingly, when the linear S1 generated duplexes were melted and renatured, circular duplexes were formed in addition to complex larger structures. This indicated that cleavage must have occurred at different sites. The double-strand-cleaving activity present in S1 nuclease preparations requires circular DNA as a substrate, as linear SV40 DNA is not cleaved. With regard to these properties S1 nuclease resembles some of the complex type I restriction nucleases from Escherichia coli which also cleave SV40 DNA only once, and, completely at random.     

Heat shock modulates phosphorylation status and activity of nucleoside diphosphate kinase in cultured sugarcane cells

Nucleoside diphosphate kinase (NDPK) is involved in the regeneration of nucleoside triphosphates (NTPs) through its phosphotransferase activity via an autophosphorylating histidine residue. Additionally, autophosphorylation of serine and/or threonine residues is documented for NDPKs from various organisms. However, the metabolic significance of serine/threonine phosphorylation has not been well characterized. In this study we report the cloning and characterization of NDPKI from cultured sugarcane (Saccharum officinarum L. line H50-7209) cells, and modulation of serine autophosphorylation of NDPK1 in response to heat-shock (HS). Heat-shock treatment at 40°C for 2 h resulted in a 40% reduction in labeled phosphoserine in NDPK1. This dephosphorylation was accompanied by an increase in NDPK enzyme activity. In contrast, NDPK1 in cultured tobacco (cv. W-38) cells did not show changes in autophosphorylation or increased enzyme activity in response to HS. The mRNA or protein level of NDPK1 did not increase in response to HS. Sugarcane cells sustain the constitutive protein synthesis in addition to heat-shock protein synthesis during HS, while constitutive protein synthesis is significantly reduced in tobacco cells during HS. Thus, HS modulation of NDPK1 activity and serine dephosphorylation in sugarcane cells may represent an important physiological role in maintaining cellular metabolic functions during heat stress.     

S1 nuclease does not cleave DNA at single-base mis-matches

Three assays have been designed to detect the cleavage of duplex phi X174 DNA at single-base mis-matches. Studies with S1 nuclease failed to detect cleavage at mis-matches. S1 nuclease digestion at 37 and 55 degrees C failed to produce a preferential degradation of a multiply mis-matched heteroduplex when compared to a mis-match-free homo-duplex as analyzed by sedimentation on sucrose gradients. Other heteroduplex templates were not cleaved by S1 nuclease at a defined single-base mis-match when assayed by gel electrophoresis or by marker rescue. In all cases, the amount of S1 nuclease employed was at least 10-times more than that required to render a single-stranded phi X174 DNA molecule completely acid soluble. The rate of hydrolysis of single-base mis-matches by S1 nuclease was estimated to be less than 0.016% of the rate at a base in single-strand phi X174 DNA. In no instance did we detect activity by S1 nuclease directed at mis-matched sites in our template molecules. Similarly, the single-strand specific endonuclease from Neurospora crassa does not cleave heteroduplex templates at a defined single-base mis-match when assayed by marker rescue.     

Molecular interactions of human Exo1 with DNA

Human Exo1 is a member of the RAD2 nuclease family with roles in replication, repair and recombination. Despite sharing significant amino acid sequence homology, the RAD2 proteins exhibit disparate nuclease properties and biological functions. In order to identify elements that dictate substrate selectivity within the RAD2 family, we sought to identify residues key to Exo1 nuclease activity and to characterize the molecular details of the human Exo1–DNA interaction. Site-specific mutagenesis studies demonstrate that amino acids D78, D173 and D225 are critical for Exo1 nuclease function. In addition, we show that the chemical nature of the 5′-terminus has a major impact on Exo1 nuclease efficiency, with a 5′-phosphate group stimulating degradation 10-fold and a 5′-biotin inhibiting degradation 10-fold (relative to a 5′-hydroxyl moiety). An abasic lesion located within a substrate DNA strand impedes Exo1 nucleolytic degradation, and a 5′-terminal abasic residue reduces nuclease efficiency 2-fold. Hydroxyl radical footprinting indicates that Exo1 binds predominantly along the minor groove of flap DNA, downstream of the junction. As will be discussed, our results favor the notion that the single-stranded DNA structure is pinched by the helical arch of the protein and not threaded through this key recognition loop. Furthermore, our studies indicate that significant, presumably biologically relevant, differences exist between the active site dynamics of Exo1 and Fen1.     

Strand exchange protein 1 from Saccharomyces cerevisiae. A novel multifunctional protein that contains DNA strand exchange and exonuclease activities

Strand exchange protein 1 (Sep1) from Saccharomyces cerevisiae catalyzes the formation of heteroduplex DNA molecules from single-stranded circles and homologous linear duplex DNA in vitro. Previously, Sep1 was purified as a 132,000-Da species; however, DNA sequence analysis indicates that the SEP1 gene is capable of encoding a 175,000-Da protein (Tishkoff, D.X., Johnson, A.W., and Kolodner, R.D. (1991) Mol. Cell. Biol. 11, 2593-2608). The SEP1 gene was cloned into a GAL10 expression vector and expressed in a protease-deficient yeast strain. Intact Sep1, which migrated as a Mr-160,000 polypeptide during sodium dodecyl sulfate-polyacrylamide gel electrophoresis, was purified to apparent homogeneity and shown to have activities similar to those of the originally purified Mr = 132,000 fragment. We report here that, in addition to strand exchange activity, Sep1 contains an intrinsic exonuclease that is active on single- and double-stranded DNA with a severalfold preference for single-stranded DNA. The nuclease was induced in crude extracts upon induction with galactose, it co-purified with the strand exchange activity of Sep1, and the nuclease and strand exchange activities of Sep1 showed the same kinetics of heat inactivation. Sep1 nuclease, which requires Mg2+, can be functionally separated from the strand exchange activity by the substitution of Ca2+ for Mg2+. Under these conditions, the nuclease is inactive, and strand exchange activity is dependent on prior resection of the DNA ends by an exogenous exonuclease. Thus, the nuclease is necessary for synapsis but not strand exchange. Electron microscopic analysis revealed that true strand exchange products, alpha molecules and nicked double-stranded circular molecules, were formed. In addition, strand transfer proceeded to similar extents on 5'-resected and 3'-resected DNA. This result suggests that the polarity of strand transfer by Sep1 is determined by the polarity of its intrinsic nuclease.     

The nuclease domain of the SPP1 packaging motor coordinates DNA cleavage and encapsidation

The large terminase subunit is a central component of the genome packaging motor from tailed bacteriophages and herpes viruses. This two-domain enzyme has an N-terminal ATPase activity that fuels DNA translocation during packaging and a C-terminal nuclease activity required for initiation and termination of the packaging cycle. Here, we report that bacteriophage SPP1 large terminase (gp2) is a metal-dependent nuclease whose stability and activity are strongly and preferentially enhanced by Mn²⁺ ions. Mutation of conserved residues that coordinate Mn²⁺ ions in the nuclease catalytic site affect the metal-induced gp2 stabilization and impair both gp2-specific cleavage at the packaging initiation site pac and unspecific nuclease activity. Several of these mutations block also DNA encapsidation without affecting ATP hydrolysis or gp2 C-terminus binding to the procapsid portal vertex. The data are consistent with a mechanism in which the nuclease domain bound to the portal switches between nuclease activity and a coordinated action with the ATPase domain for DNA translocation. This switch of activities of the nuclease domain is critical to achieve the viral chromosome packaging cycle.     

Activity of single-stranded DNA endonucleases in mung bean is associated with cell division

A single-strand-specific endonuclease from mung bean sprouts is widely usedin molecular biology. However, the biological role of this enzyme is unknown. We studied the spatial and temporal activity of single-stranded DNA endonucleases in mung bean seedling by following enzyme activity that linearizes supercoiled plasmid DNA, a characteristic of this type of enzyme. The formation of a linear molecule from supercoiled DNA was found to occur in two distinguishable steps. The first, which involves introducing a nick into the supercoiled DNA and relaxing it, is very rapid and complete within a few seconds. The second step of cleaving the opposite strand to generate a unit-length linear duplex DNA is a relatively slow process. Analysis of the DNA cleavage sites showed the nuclease preferentially cuts supercoiled DNA at an AT-rich region. Varying levels of nuclease activity could be detected in different tissues of the mung bean seedling. The highest activity was in the root tip and was correlated with histone H1 kinase activity. This implies a link between nuclease activity and cell division. Induction of cell division in mung bean hypocotyls with auxin promoted formation of root primordia and considerably increased the activity of single-stranded DNA endonucleases. The nuclease activity and histone H1 kinase activity were reduced in mung bean cuttings treated with hydroxyurea, but not in cuttings treated with oryzalin. The potential function of single-stranded DNA endonucleases is discussed.     

Characterization of a periplasmic S1-like nuclease coded by the Mesorhizobium loti symbiosis island

DNA sequences encoding hypothetical proteins homologous to S1 nuclease from Aspergillus oryzae are found in many organisms including fungi, plants, pathogenic bacteria, and eukaryotic parasites. One of these is the M1 nuclease of Mesorhizobium loti which we demonstrate herein to be an enzymatically active, soluble, and stable S1 homolog that lacks the extensive mannosyl-glycosylation found in eukaryotic S1 nuclease homologs. We have expressed the cloned M1 protein in M. loti and purified recombinant native M1 to near homogeneity and have also isolated a homogeneous M1 carboxy-terminal hexahistidine tag fusion protein. Mass spectrometry and N-terminal Edman degradation sequencing confirmed the protein identity. The enzymatic properties of the purified M1 nuclease are similar to those of S1. At acidic pH M1 is 25 times more active on single-stranded DNA than on double-stranded DNA and 3 times more active on single-stranded DNA than on single-stranded RNA. At neutral pH the RNase activity of M1 exceeds the DNase activity. M1 nicks supercoiled RF-I plasmid DNA and rapidly cuts the phosphodiester bond across from the nick in the resultant relaxed RF-II plasmid DNA. Therefore, M1 represents an active bacterial S1 homolog in spite of great sequence divergence. The biochemical characterization of M1 nuclease supports our sequence alignment that reveals the minimal 21 amino acid residues that are necessarily conserved for the structure and functions of this enzyme family. The ability of M1 to degrade RNA at neutral pH implies previously unappreciated roles of these nucleases in biological systems.     

Yeast DNA polymerases: antigenic relationship, use of RNA primer and associated exonuclease activity.

Highly purified preparation of DNA polymerases A and B from yeast were compared with respect to antigenic relationship, ability to use ribonucleotide primers and associated nuclease activity. The following results were obtained. 1. Antiserum directed against DNA polymerase A inhibits this enzyme but does not interfere with activity of DNA polymerase B or of mitochondrial DNA polymerase, nor does it precipitate the latter two enzymes. 2. DNA polymerase A is capable of using oligo(ribouridylic acid) as a primer for the polymerization of dTMP. This reaction is not catalyzed by polymerase B to any significant extent. 3. Whereas DNA polymerase A is devoid of nuclease activity, DNA polymerase B catalyses an exonucleolytic release of mononucleotide units from the 3' end of polynucleotides. The results of several experiments suggest that this nuclease activity is associated with the DNA polymerase B molecule.