Disulfide bonds are required for Serratia marcescens nuclease activity

Protein engineering enables Serratia marcescens nuclease A to hydrolyze nucleic acids under high-salt conditions

For the purpose of removing nucleotide impurities, Serratia marcescens Nuclease A (SmNucA) is widespread used in biopharmaceutical manufacturing, such as production of adeno-associated viral vector, one of the leading gene delivery platforms that features low immunogenicity. However, such utilization of wild-type SmNucA is limited in saline environment. Depending on downstream process development, the ionic strength can be as high as 500 mM, at which the potency of wild-type SmNucA plunges. We herein design an SmNucA variant with four Lys mutations, namely HighSalt NucA, to improve nucleic acids binding under high-salt conditions. Km determination and molecular dynamics (MD) simulation implies a new catalytical mechanism adopted by HighSalt NucA and another mutant that harbors four Arg substitutions at the same sites. We thereby conclude that basic-residue mutations on the SmNucA surface stabilize the local conformation in close proximity to the substrate-binding cleft at saline concentration of 500 mM. In addition to Lys and Arg mutations, saturation mutagenesis further indicated that certain hydrophobic residues (Ala, Val, Trp, Tyr) and polar residues (Ser, Thr, Asn, Gln) also render SmNucA salt-tolerant, albeit to differing extent. In contrast to activity loss of the wild-type with 400-500 mM NaCl, HighSalt NucA maintains broad substrate specificity even under these extreme conditions, which expands its application prospect in the removal of nucleic acid impurities during process development.

Endonuclease increases efficiency of osteoblast isolation from murine calvariae

Bone is a highly dynamic organ that undergoes remodeling equally regulated by osteoblast-mediated bone formation and osteoclast-mediated bone resorption. To clarify the regulation of osteoblastogenesis, primary murine osteoblasts are required for an in vitro study. Primary osteoblasts are isolated from neonatal calvariae through digestion with collagenase. However, the number of cells collected from one pup is not sufficient for further in vitro experiments, leading to an increase in the use of euthanized pups. We hypothesized that the viscosity of digested calvariae and digestion solution supplemented with collagenase results in cell clumping and reduction of isolated cells from bones. We simply added Benzonase, a genetically engineered endonuclease that shears all forms of DNAs/RNAs, in order to reduce nucleic acid-mediated viscosity. We found that addition of Benzonase increased the number of collected osteoblasts by three fold compared to that without Benzonase through reduction of viscosity. Additionally, Benzonase has no effect on cellular identity and function. The new osteoblast isolation protocol with Benzonase minimizes the number of neonatal pups required for an in vitro study and expands the concept that isolation of other populations of cells including osteocytes that are difficult to be purified could be modified by Benzonase.

High-Level Production of DNA-Specific Endonuclease AsEndI with Synonymous Codon and its Potential Utilization for Removing DNA Contamination

Endonuclease I is a widely distributed periplasmic or extracellular enzyme. A method for the high-level production of recombinant AsEndI (endonuclease I from Aliivibrio salmonicida) in Escherichia coli with secretion expression is investigated. The coding sequence of AsEndI gene was assembled according to the E. coli codon usage bias, and AsEndI was expressed in the periplasm of E. coli TOP10 with a C-terminal 6× His-tagged fusion. The recombinant AsEndI (His-AsEndI) was purified by Ni-NTA resin with a yield of 1.29 × 10⁷ U from 1-L LB medium. His-AsEndI could be classified into Ca²⁺/Mg²⁺-dependent nucleases and showed highest nuclease activity to dsDNA at pH 8.0 and 37 °C. His-AsEndI is highly active in a broad range of salt concentration range up to 1.0 M with optimal NaCl concentration at 0.4 M. His-AsEndI can effectively remove DNA contamination in RNA sample or in PCR reagents to the level that cannot be detected by highly sensitive nested PCR and without adverse effects on the subsequent PCR reaction. His-AsEndI can remove DNA contamination at high salt conditions, especially for the DNA that may be shielded by DNA-binding protein at low salt conditions.

Systematic classification of the His-Me finger superfamily

The His-Me finger endonucleases, also known as HNH or ββα-metal endonucleases, form a large and diverse protein superfamily. The His-Me finger domain can be found in proteins that play an essential role in cells, including genome maintenance, intron homing, host defense and target offense. Its overall structural compactness and non-specificity make it a perfectly-tailored pathogenic module that participates on both sides of inter- and intra-organismal competition. An extremely low sequence similarity across the superfamily makes it difficult to identify and classify new His-Me fingers. Using state-of-the-art distant homology detection methods, we provide an updated and systematic classification of His-Me finger proteins. In this work, we identified over 100 000 proteins and clustered them into 38 groups, of which three groups are new and cannot be found in any existing public domain database of protein families. Based on an analysis of sequences, structures, domain architectures, and genomic contexts, we provide a careful functional annotation of the poorly characterized members of this superfamily. Our results may inspire further experimental investigations that should address the predicted activity and clarify the potential substrates, to provide more detailed insights into the fundamental biological roles of these proteins.

Structure-based domain assignment in Leishmania infantum EndoG: characterization of a pH-dependent regulatory switch and a C-terminal extension that largely dictates DNA substrate preferences

Mitochondrial endonuclease G from Leishmania infantum (LiEndoG) participates in the degradation of double-stranded DNA (dsDNA) during parasite cell death and is catalytically inactive at a pH of 8.0 or above. The presence, in the primary sequence, of an acidic amino acid-rich insertion exclusive to trypanosomatids and its spatial position in a homology-built model of LiEndoG led us to postulate that this peptide stretch might act as a pH sensor for self-inhibition. We found that a LiEndoG variant lacking residues 145–180 is indeed far more active than its wild-type counterpart at pH values >7.0. In addition, we discovered that (i) LiEndoG exists as a homodimer, (ii) replacement of Ser211 in the active-site SRGH motif with the canonical aspartate from the DRGH motif of other nucleases leads to a catalytically deficient enzyme, (iii) the activity of the S211D variant can be restored upon the concomitant replacement of Ala247 with Arg and (iv) a C-terminal extension is responsible for the observed preferential cleavage of single-stranded DNA (ssDNA) and ssDNA–dsDNA junctions. Taken together, our results support the view that LiEndoG is a multidomain molecular machine whose nuclease activity can be subtly modulated or even abrogated through architectural changes brought about by environmental conditions and interaction with other binding partners.

The impact of different methods of DNA extraction on microbial community measures of BALF samples based on metagenomic data

PURPOSE

It is a challenge to find a better microorganisms DNA extraction method for samples taken from the lower airways for metagenomic sequencing, as the concentrations of bacteria in the alveoli and small airways are likely considerably less than that of the mouth or lower digestive tract. Background DNA from the host, and extraction biases can significantly interfere with microbiota assessment and increase the cost of sequencing. This study aimed to develop an optimized DNA extraction method, which would enable a higher concentration of microbial DNA to be extracted from the samples.

METHODS

We compared the microbiota profiles of the lower airway communities in twelve individuals with IIP. DNA was extracted using three different extraction methods: QIAamp UCP PurePathogen Blood Kit named kit3 in this study, QIAamp UCP Pathogen Mini Kit named kit2, and QIAamp DNA Microbiome Kit named kit1. DNA libraries were constructed according to the manufacturer's instructions (Illumina). The same workflows from Illumina were used to perform cluster generation, template hybridization, isothermal amplification, linearization, blocking, denaturing, and hybridization of the sequencing primers. Raw data was uploaded to MG-RAST v3 and analyzed.

RESULTS

A great number of bacterium inhabits the lower airways of patients with IIP, though there is no airway infection. More bacterium was found in mouth or upper airway. DNA concentrations of DNA samples isolated with kit1 with Benzonase were significantly lower than those isolated with the other two kits for BALF and mouthwash samples. Moreover, the ratio of human genome in clean reads of samples isolated with kit1 with Benzonase was remarkably smaller than those isolated with kit2 and kit3. The relative abundance of total bacteria, the total number of taxa, and the relative abundance of taxa in BALF samples as opposed to mouthwash samples with kit1 were significantly higher than for those extracted the other kits.

CONCLUSION

A microbial DNA extraction method with pretreatment of depletion of host nucleic acid by Benzonase can enable a higher yield of microbial DNA from samples with a higher fraction of host cells to be obtained. The lower airways of patients with IIP without airway infection were inhabited by a great number of bacterium.

Mutational and biochemical analysis of the DNA-entry nuclease EndA from Streptococcus pneumoniae

EndA is a membrane-attached surface-exposed DNA-entry nuclease previously known to be required for genetic transformation of Streptococcus pneumoniae. More recent studies have shown that the enzyme also plays an important role during the establishment of invasive infections by degrading extracellular chromatin in the form of neutrophil extracellular traps (NETs), enabling streptococci to overcome the innate immune system in mammals. As a virulence factor, EndA has become an interesting target for future drug design. Here we present the first mutational and biochemical analysis of recombinant forms of EndA produced either in a cell-free expression system or in Escherichia coli. We identify His160 and Asn191 to be essential for catalysis and Asn182 to be required for stability of EndA. The role of His160 as the putative general base in the catalytic mechanism is supported by chemical rescue of the H160A variant of EndA with imidazole added in excess. Our study paves the way for the identification and development of protein or low-molecular-weight inhibitors for EndA in future high-throughput screening assays.

Crystal structure of the EndoG/EndoGI complex: mechanism of EndoG inhibition

EndoG is a ubiquitous nuclease that is translocated into the nucleus during apoptosis to participate in DNA degradation. The enzyme cleaves double- and single-stranded DNA and RNA. Related nucleases are found in eukaryotes and prokaryotes, which have evolved sophisticated mechanisms for genome protection against self-antagonizing nuclease activity. Common mechanisms of inhibition are secretion, sequestration into a separate cellular compartment or by binding to protein inhibitors. Although EndoG is silenced by compartmentalization into the mitochondrial intermembrane space, a nucleus-localized protein inhibitor protects cellular polynucleotides from degradation by stray EndoG under non-apoptotic conditions in Drosophila. Here, we report the first three-dimensional structure of EndoG in complex with its inhibitor EndoGI. Although the mechanism of inhibition is reminiscent of bacterial protein inhibitors, EndoGI has evolved independently from a generic protein-protein interaction module. EndoGI is a two-domain protein that binds the active sites of two monomers of EndoG, with EndoG being sandwiched between EndoGI. Since the amino acid sequences of eukaryotic EndoG homologues are highly conserved, this model is valid for eukaryotic dimeric EndoG in general. The structure indicates that the two active sites of EndoG occupy the most remote spatial position possible at the molecular surface and a concerted substrate processing is unlikely.

The nuclease a-inhibitor complex is characterized by a novel metal ion bridge

Nonspecific, extracellular nucleases have received enhanced attention recently as a consequence of the critical role that these enzymes can play in infectivity by overcoming the host neutrophil defense system. The activity of the cyanobacterial nuclease NucA, a member of the betabetaalpha Me superfamily, is controlled by the specific nuclease inhibitor, NuiA. Here we report the 2.3-A resolution crystal structure of the NucA-NuiA complex, showing that NucA inhibition by NuiA involves an unusual divalent metal ion bridge that connects the nuclease with its inhibitor. The C-terminal Thr-135(NuiA) hydroxyl oxygen is directly coordinated with the catalytic Mg(2+) of the nuclease active site, and Glu-24(NuiA) also extends into the active site, mimicking the charge of a scissile phosphate. NuiA residues Asp-75 and Trp-76 form a second interaction site, contributing to the strength and specificity of the interaction. The crystallographically defined interface is shown to be consistent with results of studies using site-directed NuiA mutants. This mode of inhibition differs dramatically from the exosite mechanism of inhibition seen with the DNase colicins E7/E9 and from other nuclease-inhibitor complexes that have been studied. The structure of this complex provides valuable insights for the development of inhibitors for related nonspecific nucleases that share the DRGH active site motif such as the Streptococcus pneumoniae nuclease EndA, which mediates infectivity of this pathogen, and mitochondrial EndoG, which is involved in recombination and apoptosis.

Structural insights into the mechanism of nuclease A, a betabeta alpha metal nuclease from Anabaena

Nuclease A (NucA) is a nonspecific endonuclease from Anabaena sp. capable of degrading single- and double-stranded DNA and RNA in the presence of divalent metal ions. We have determined the structure of the delta(2-24),D121A mutant of NucA in the presence of Zn2+ and Mn2+ (PDB code 1ZM8). The mutations were introduced to remove the N-terminal signal peptide and to reduce the activity of the nonspecific nuclease, thereby reducing its toxicity to the Escherichia coli expression system. NucA contains a betabeta alpha metal finger motif and a hydrated Mn2+ ion at the active site. Unexpectedly, NucA was found to contain additional metal binding sites approximately 26 A apart from the catalytic metal binding site. A structural comparison between NucA and the closest analog for which structural data exist, the Serratia nuclease, indicates several interesting differences. First, NucA is a monomer rather than a dimer. Second, there is an unexpected structural homology between the N-terminal segments despite a poorly conserved sequence, which in Serratia includes a cysteine bridge thought to play a regulatory role. In addition, although a sequence alignment had suggested that NucA lacks a proposed catalytic residue corresponding to Arg57 in Serratia, the structure determined here indicates that Arg93 in NucA is positioned to fulfill this role. Based on comparison with DNA-bound nuclease structures of the betabeta alpha metal finger nuclease family and available mutational data on NucA, we propose that His124 acts as a catalytic base, and Arg93 participates in the catalysis possibly through stabilization of the transition state.

Sugar non-specific endonucleases

Sugar non-specific endonucleases are multifunctional enzymes and are widespread in distribution. Apart from nutrition, they have also been implicated in cellular functions like replication, recombination and repair. Their ability to recognize different DNA structures has also been exploited for the determination of nucleic acid structure. Although more than 30 non-specific endonucleases have been isolated to date, very little information is available regarding their structure-function correlations except that of staphylococcal and Serratia nucleases. However, during the past few years, the primary structure, nature of the active site based on sequence homology, and the probable mechanism of action have been postulated for some of the enzymes. This review describes the purification, characteristics, biological role and applications of sugar non-specific endonucleases.

Identification and phylogeny of a non-specific endonuclease gene of white spot syndrome virus of shrimp

White spot syndrome virus (WSSV) is a taxonomically unclassified virus which causes a disease in shrimps worldwide. A 936 bp long open reading frame (ORF) was found on a 7.2 kb HindIII fragment of the DNA genome of WSSV located adjacent to the ribonucleotide reductase small subunit gene. This putative ORF showed homology to prokaryotic and eukaryotic endonucleases, which contain a non-specific endonuclease motif. Alignment with viral and eukaryotic endonuclease ORFs revealed that most catalytically and structurally important amino acid residues were present in the putative WSSV non-specific endonuclease gene. An unrooted parsimonous phylogenetic tree of non-specific endonucleases indicated that the WSSV ORF was located in a well bootstrap supported clade containing only arthopods, including one of WSSV's natural hosts, Penaeus japonicus. A similar conjunction was found for the only other viral homologue, present in Fowlpox virus, which was also found in a well bootstrap-supported clade with its natural host, Gallus gallus. This clustering of virus and host suggests that both WSSV and Fowlpox virus may have acquired their nuclease genes from their respective natural hosts. Because the motif for non-specific nucleases is found in only two viruses, this gene cannot be used to clarify the taxonomic position of WSSV. However, the presence of this type of nuclease rarely found in viruses adds a novel feature to WSSV.

Properties of the major non-specific endonuclease from the strict anaerobe Fibrobacter succinogenes and evidence for disulfide bond formation in vivo

DNase A is a non-specific endonuclease of Fibrobacter succinogenes. The enzyme was purified to homogeneity and its properties studied both in vitro and in vivo. Magnesium but not calcium was essential for nucleolytic activity. Manganese ions substituted for magnesium but were less stimulatory. DNase A activity was markedly inhibited by either NaCl or KCl at concentrations greater than 75 mM. The enzyme had a temperature optimum of 25 degrees C and a pH optimum of about 7.0. Values for K:(m) and K:(cat) were determined to be 61 microM and 330 s(-1) respectively, with a catalytic efficiency approximately threefold greater than bovine pancreatic DNase I, but 10-fold less than the Serratia marcescens NucA. DNase A was localized to the periplasm and probably exists as a monomeric species. The enzyme possessed one or more disulfide bonds. In the reduced form it had an apparent mass of 33 kDa, while in the oxidized form it was 29 kDa as estimated by SDS-PAGE. Reduction of the disulfide bonds by dithiothreitol with or without subsequent alkylation by iodoacetamide strongly inactivated the enzyme. DNase A accumulated in vivo had an apparent mass of 29 kDa, indicating that it was in an oxidized form. This is the first indication in a strict anaerobe of a functional periplasmic disulfide bond forming system, phenotypically similar to Dsb systems in facultative and aerobic bacteria.

Mechanism of DNA cleavage by the DNA/RNA-non-specific Anabaena sp. PCC 7120 endonuclease NucA and its inhibition by NuiA

A structural model of the DNA/RNA non-specific endonuclease NucA from Anabaena sp. PCC7120 that has been obtained on the basis of the three-dimensional structure of the related Serratia nuclease, suggests that the overall architecture of the active site including amino acid residues H124, N155 and E163 (corresponding to H89, N119 and E127 in Serratia nuclease) is similar in both nucleases. Substitution of these residues by alanine leads to a large reduction in activity (<0.1 %), similarly as observed for Serratia nuclease demonstrating that both enzymes share a similar mechanism of catalysis with differences only in detail. NucA is inhibited by its specific polypeptide inhibitor with a K(i) value in the subpicomolar range, while the related Serratia nuclease at nanomolar concentrations is only inhibited at an approximately 1000-fold molar excess of NuiA. The artificial chromophoric substrate deoxythymidine 3',5'-bis-(p-nitrophenyl phosphate) is cleaved by NucA as well as by Serratia nuclease. Cleavage of this analogue by NucA, however, is not inhibited by NuiA, suggesting that small molecules gain access to the active site of NucA in the enzyme-inhibitor complex under conditions where cleavage of DNA substrates is completely inhibited. The active site residue E163 seems to be the main target amino acid for inhibition of NucA by NuiA, but R93, R122 and R167 (corresponding to K55, R87, R131 in Serratia nuclease) are also involved in the NucA/NuiA interaction. NuiA deletion mutants show that the structural integrity of the N and C-terminal region of the inhibitor is important for complex formation with NucA and inhibition of nuclease activity. Based on these results a mechanism of DNA cleavage by NucA and its inhibition by NuiA is proposed.

The DNA/RNA non-specific Serratia nuclease prefers double-stranded A-form nucleic acids as substrates

A steady-state kinetic analysis of the cleavage of the oligonucleotides d(CGCTTTTTTGC) (d(y)), d(GCAAAAAAGCG) (d(r)), r(CGCUUUUUUGC) (r(y)) and r(GCAAAAAAGCG) (r(r)) in single and double-stranded form by the extracellular Serratia marcescens endonuclease, in conjunction with structural data from a circular dichroism spectroscopic analysis of these substrates, suggests that oligonucleotides adopting the A-conformation are preferred over those adopting the B-conformation as substrates. Relative catalytic efficiencies (kcat/KM) for the cleavage of the homo- and heteroduplexes follow the order r(r).r(y) (1.0)>r(r).d(y) (0.9)>d(r). r(y) (0.7)>d(r).d(y) (0.3). The purine-rich single-stranded oligonucleotides r(r) and d(r), are cleaved more efficiently than the pyrimidine-rich oligonucleotides, r(y) and d(y), presumably because they adopt helical structures with pronounced base stacking. Except for the double-stranded oligodeoxynucleotide substrate, the individual strands are cleaved more efficiently when incorporated into a duplex, than in a single-stranded form. Cleavage experiments with various polynucleotides, including a viroid RNA and a specifically designed 167 bp DNA, confirm that double-stranded A-form nucleic acids are preferentially attacked by Serratia nuclease. In an attempt to analyze the basis of these preferences, we have mutated the amino acid residues Tyr76 and Trp123 of Serratia nuclease. These residues are located close to the active site and are conserved in all members of the Serratia nuclease family, suggesting that they could be involved in substrate binding, e.g. by stacking interactions with the bases, which could lead to the cleavage preferences observed. However, only effects on the activity, but no change of the sequence or substrate preferences, were detected upon substitution of these amino acid residues, ruling out any involvement of these residues in the A-form preference of Serratia nuclease.

On the advantage of being a dimer, a case study using the dimeric Serratia nuclease and the monomeric nuclease from Anabaena sp. strain PCC 7120

The extracellular endonucleases from Serratia marcescens and Anabaena sp. are members of a family of nonspecific endonucleases. In contrast to the monomeric Anabaena nuclease, the Serratia nuclease is a dimer of two identical subunits. To find out whether the two active sites of the Serratia nuclease function independently of each other and what the advantage of being a dimer for this enzyme might be, we produced (i) dimers in which the two subunits were cross-linked, (ii) heterodimers consisting of a wild type and an inactive mutant subunit which were also cross-linked, and (iii) monomeric variants which are unable to dimerize. The monomeric H184R variant and the cross-linked S140C variant exhibit the same activity as the wild type enzyme, while the cross-linked heterodimer with one inactive subunit shows only half of the activity of the wild type enzyme, demonstrating functional independence of the two subunits of the Serratia nuclease. On the other hand at low enzyme and substrate concentrations dimeric forms of the Serratia nuclease are relatively more active than monomeric forms or the monomeric Anabaena nuclease in cleaving polynucleotides, not, however, oligonucleotides, which is correlated with the ability of dimeric forms of the Serratia nuclease to form large enzyme-substrate networks with high molecular weight DNA and to cleave polynucleotides in a processive manner. We conclude that in the natural habitat of Serratia marcescens where the supply of nutrients may become growth limiting the dimeric nuclease can fulfil its nutritive function more efficiently than a monomeric enzyme.

Synthesis and biochemical characterization of obligatory dimers of the sugar non-specific nuclease from Serratia marcescens using specifically designed bismaleimidoalkanes as SH-specific crosslinking reagents

The genetically engineered S140C variant of the homodimeric nuclease from Serratia marcescens was crosslinked across the dimer interface at the Cys 140 residues using bifunctional SH-specific 1,1'-alkanediyl-bis-pyrrole-2,5-diones of different lengths. These bismaleimidoalkanes were synthesized by the condensation of n-alkyldiamines with maleic anhydride and subsequent cyclization with acetic anhydride and sodium acetate. Bismaleimidohexane (BMH) which gave the best crosslinking yield was used to produce in preparative amounts crosslinked Serratia nuclease. The crosslinked protein has the same secondary structure and exhibits the same guanidinium chloride unfolding behavior as the wild type enzyme or the non-covalently linked S 140C variant. In contrast, in thermal unfolding experiments the crosslinked dimer behaves differently from the wild type enzyme or the non-covalently linked S140C variant. CD-spectra recorded during temperature rise showed only minor changes of the secondary structure composition for the wild type enzyme and the non-covalently linked S140C variant, whereas in the case of the crosslinked S140C dimer a distinct increase of the CD effect was observed corresponding to an increase in alpha-helix. Our results demonstrate that bismaleimidoalkanes are very well suited to covalently link subunits of proteins, provided suitably located cysteine residues are present.

Serratia marcescens and its extracellular nuclease

Serratia marcescens produces an endonuclease with extraordinarily high specific activity that is released into the surrounding medium. This enzyme has been the focus of studies on gene regulation, protein secretion, endonuclease action, and protein structure; it has also been found to have many applications in biotechnology. Here we briefly review these different facets of research regarding the Serratia nuclease and summarize the current state of knowledge about this enzyme.

Secretion of nuclease across the outer membrane of Serratia marcescens and its energy requirements

Extracellular secretion of Serratia marcescens nuclease occurs as a two-step process via a periplasmic intermediate. Unlike other extracellular proteins secreted by gram-negative bacteria by the general secretory pathway, nuclease accumulates in the periplasm in its active form for an unusually long time before its export into the growth medium. The energy requirements for extracellular secretion of nuclease from the periplasm were investigated. Our results suggest that the second step of secretion across the outer membrane is dependent upon the external pH; acidic pH effectively but reversibly blocks extracellular secretion. However, electrochemical proton gradient, and possibly ATP hydrolysis, are not required for this step. We suggest that nuclease uses a novel mechanism for the second step of secretion in S. marcescens.

Kinetic analysis of the cleavage of natural and synthetic substrates by the Serratia nuclease

The extracellular nuclease from Serratia marcescens is a non-specific endonuclease that hydrolyzes double-stranded and single-stranded DNA and RNA with high specific activity. Steady-state and presteady-state kinetic cleavage experiments were performed with natural and synthetic DNA and RNA substrates to understand the mechanism of action of the Serratia nuclease. Most of the natural substrates are cleaved with similar Kcat and K(m) values, the Kcat/K(m) ratios being comparable to that of staphylococcal nuclease. Substrates with extreme structural features, like poly(dA).poly(dT) or poly(dG).poly(dC), are cleaved by the Serratia nuclease with a 50 times higher or 10 times lower K(m), respectively, as salmon testis DNA. Neither with natural DNA or RNA nor synthetic oligodeoxynucleotide substrates did we observe substrate inhibition for the Serratia nuclease as reported recently. Experiments with short oligodeoxynucleotides confirmed previous results that for moderately good cleavage activity the substrate should contain at least five phosphate residues. Shorter substrates are still cleaved by the Serratia nuclease, albeit at a rate reduced by a factor of more than 100. Cleavage experiments with oligodeoxynucleotides substituted by a single phosphorothioate group showed that the negative charge of the pro-Rp-oxygen of the phosphate group 3' adjacent to the scissile phosphodiester bond is essential for cleavage, as only the Rp-phosphorothioate supports cleavage at the 5' adjacent phosphodiester bond. Furthermore, the modified bond itself is only cleaved in the Rp-diastereomer, albeit 1000 times more slowly than the corresponding unmodified phosphodiester bond, which offers the possibility to determine the stereochemical outcome of cleavage. Pre-steady-state cleavage experiments demonstrate that it is not dissociation of products but association of enzyme and substrate or the cleavage of the phosphodiester bond that is the rate-limiting step of the reaction. Finally, it is shown that Serratia nuclease accepts thymidine 3',5'-bis(p-nitrophenyl)phosphate as a substrate and cleaves it at its 5'-end to produce nitrophenol and thymidine 3'-(p-nitrophenylphosphate) 5-phosphate. The rate of cleavage of this artificial substrate, however, is 6-7 orders of magnitude smaller than the rate of cleavage of macromolecular DNA or RNA.

Two-step secretion of the Serratia marcescens extracellular nuclease

The extracellular nuclease of Serratia marcescens is one of a wide variety of enzymes secreted into the growth medium. Its appearance occurs late in the growth of a culture, and its gene, nucA, is transcriptionally regulated in a complex fashion by growth phase and other factors. Pulse-labeling studies reveal that extracellular secretion of nuclease occurs as a two-step process. In the first step, nuclease is rapidly translocated across the cytoplasmic membrane into the periplasm, where it accumulates as a mature active nuclease. A precursor protein, nuclease still carrying its signal sequence, was detected in the presence of carbonyl cyanide m-chlorophenylhydrazone or sodium azide, suggesting that this initial translocation and signal processing step involves an energy-dependent and Sec-dependent pathway in S. marcescens. The second step of secretion across the outer membrane is a slow process requiring between 30 to 120 min, depending on growth conditions.

Differential secretion of isoforms of Serratia marcescens extracellular nuclease

Extracellular secretion of the Serratia marcescens nuclease occurs in a two-step process: (i) rapidly to the periplasm via a signal sequence-dependent pathway and then (ii) slowly to the extracellular growth medium without cell lysis. There are two major isoforms of the nuclease in the culture supernatant of S. marcescens. We have isolated, purified, and determined the sequences of both isoforms. The first isoform, the mature nuclease (Sm2), is the result of signal sequence processing. The second isoform (Sm1) has three additional amino acids missing from the N terminus of the mature nuclease. Sm1 starts to appear extracellularly only during prolonged growth of a culture (16 to 48 h), probably because of cell lysis. However, pulse-chase experiments show that it is made early with Sm2 but is not secreted efficiently.

Purification and characterization of the nuclease NucM of Erwinia chrysanthemi

The major periplasmic nuclease of Erwinia chrysanthemi strain 3937, NucM, has been purified near to homogeneity by a one step purification procedure, using chromatography on a sulfopropyl column. NucM cleaves randomly single and double-stranded DNA and RNA. It does not need divalent cations for its action, and is more active in low salt buffers. A serine and a histidine residue could be present in the catalytic site. Formation of disulfide bonds is necessary for NucM activity. NucM is probably synthesized as a reduced inactive polypeptide and becomes active in the periplasm once disulfide bonds are formed.

A conditional suicide system in Escherichia coli based on the intracellular degradation of DNA

The potential risks associated with the intentional or unintentional release of genetically engineered microorganisms led to the construction of biological containment systems by which bacteria are killed in a controlled suicide process. In previously published suicide systems, cell killing was caused by proteins destroying the cell membrane or cell wall. Here a conditional cell killing system based on the intracellular degradation of cellular DNA is presented. The nuclease gene used was that of the extracellular nuclease of Serratia marcescens. The nuclease gene was deleted for the leader-coding sequence, and the truncated gene was put under the control of the lambda pL promoter. Following thermoinduction of the nuclease gene cassette in Escherichia coli, cell survival dropped to 2 x 10(-5), and more than 80% of the radioactively labeled DNA was converted to acid-soluble material within 2.5 h in the absence of cell lysis. The majority (84%) of clones which survived thermoinduced killing turned out to be as sensitive to a second thermoinduction as the original strain. The other clones showed somewhat slower killing kinetics or slightly higher final levels of survivors. The suicide system described combines the regulated killing of cells with the destruction of intracellular DNA otherwise potentially available for horizontal gene transfer processes.

Identification of catalytically relevant amino acids of the extracellular Serratia marcescens endonuclease by alignment-guided mutagenesis

By sequence alignment of the extracellular Serratia marcescens nuclease with three related nucleases we have identified seven charged amino acid residues which are conserved in all four sequences. Six of these residues together with four other partially conserved His or Asp residues were changed to alanine by site-directed PCR-mediated mutagenesis using a variant of the nuclease gene in which the coding sequence of the signal peptide was replaced by the coding sequence for an N-terminal affinity tag [Met(His)6GlySer]. Four of the mutant proteins showed almost no reduction in nuclease activity but five displayed a 10- to 1000-fold reduction in activity and one (His110Ala) was inactive. Based upon these results it is suggested that the S.marcescens nuclease employs a mechanism in which His110 acts in concert with a Mg2+ ion and three carboxylates (Asp107, Glu148 and Glu232) as well as one or two basic amino acid residues (Arg108, Arg152).

The extracellular nuclease of Serratia marcescens: studies on the activity in vitro and effect on transforming DNA in a groundwater aquifer microcosm

A quantitative endonuclease assay, which relies on the introduction of single and double strand breaks into supercoiled plasmid DNA, was used to study the activity of the extracellular nuclease of Serratia marcescens SM6 in buffer and in groundwater. The parallel enzyme concentration-dependent production of relaxed and linear plasmid molecules suggests that the nuclease produces single and double strand breaks in duplex DNA. Bovine serum albumin stimulated the nuclease activity towards DNA and RNA and increased the stability of the enzyme against thermal inactivation. The DNase activity at 4 degrees C and 50 degrees C was almost half of that at the optimum temperature (37 degrees C). The nuclease was active in groundwater, although the specific activity was lower than in buffer. In a groundwater aquifer microcosm, mineral-adsorbed transforming DNA was substantially less accessible to the nuclease than was dissolved DNA. The data suggest that the extracellular nuclease of Serratia marcescens may contribute to DNA turnover in the environment and that adsorption of DNA to minerals provides protection against the nuclease.

The cell proliferation-associated antigen of antibody Ki-67: a very large, ubiquitous nuclear protein with numerous repeated elements, representing a new kind of cell cycle-maintaining proteins

The antigen defined by mAb Ki-67 is a human nuclear protein the expression of which is strictly associated with cell proliferation and which is widely used in routine pathology as a "proliferation marker" to measure the growth fraction of cells in human tumors. Ki-67 detects a double band with apparent molecular weights of 395 and 345 kD in immunoblots of proteins from proliferating cells. We cloned and sequenced the full length cDNA, identified two differentially spliced isoforms of mRNA with open reading frames of 9,768 and 8,688 bp encoding for this cell proliferation-associated protein with calculated molecular weights of 358,761 D and 319,508 D, respectively. New mAbs against a bacterially expressed part and a synthetic polypeptide deduced from the isolated cDNA react with the native Ki-67 antigen, thus providing a circle of evidence that we have cloned the authentic Ki-67 antigen cDNA. The central part of the Ki-67 antigen cDNA contains a large 6,845-bp exon with 16 tandemly repeated 366-bp elements, the "Ki-67 repeats", each including a highly conserved new motif of 66 bp, the "Ki-67 motif", which encodes for the epitope detected by Ki-67. Computer analysis of the nucleic acid and the deduced amino acid sequence of the Ki-67 antigen confirmed that the cDNA encodes for a nuclear and short-lived protein without any significant homology to known sequences. Ki-67 antigen-specific antisense oligonucleotides inhibit the proliferation of IM-9 cell line cells, indicating that the Ki-67 antigen may be an absolute requirement for maintaining cell proliferation. We conclude that the Ki-67 antigen defines a new category of cell cycle-associated nuclear nonhistone proteins.