An endonuclease/ligase based mutation scanning method especially suited for analysis of neoplastic tissue

How Can One Metal Power Nucleic Acid Phosphodiester Bond Cleavage by a Nuclease? Multiscale Computational Studies Highlight a Diverse Mechanistic Landscape

Despite the remarkable resistance of the nucleic acid phosphodiester backbone to degradation affording genetic stability, the P-O bond must be broken during DNA repair and RNA metabolism, among many other critical cellular processes. Nucleases are powerful enzymes that can enhance the uncatalyzed rate of phosphodiester bond cleavage by up to ∼1017-fold. Despite the most well accepted hydrolysis mechanism involving two metals (MA2+ to activate a water nucleophile and MB2+ to stabilize the leaving group), experimental evidence suggests that some nucleases can use a single metal to facilitate the chemical step, a controversial concept in the literature. The present perspective uses the case studies of four nucleases (I-PpoI, APE1, and bacterial and human EndoV) to highlight how computational approaches ranging from quantum mechanical (QM) cluster models to molecular dynamics (MD) simulations and combined quantum mechanics-molecular mechanics (QM/MM) calculations can reveal the atomic level details necessary to understand how a nuclease can use a single metal to facilitate this difficult chemistry. The representative nucleases showcase how different amino acid residues (e.g., histidine, aspartate) can fulfill the role of the first metal (MA2+) in the two-metal-mediated mechanisms. Nevertheless, differences in active site architectures afford diversity in the single-metal-mediated mechanism in terms of the metal-substrate coordination, the role of the metal, and the identities of the general acid and base. The greater understanding of the catalytic mechanisms of nucleases obtained from the body of work reviewed can be used to further explore the progression of diseases associated with nuclease (mis)activity and the development of novel nuclease applications such as disease diagnostics, gene engineering, and therapeutics.

Mechanism of Nucleic Acid Phosphodiester Bond Cleavage by Human Endonuclease V: MD and QM/MM Calculations Reveal a Versatile Metal Dependence

Human endonuclease V (EndoV) catalytically removes deaminated nucleobases by cleaving the phosphodiester bond as part of RNA metabolism. Despite being implicated in several diseases (cancers, cardiovascular diseases, and neurological disorders) and potentially being a useful tool in biotechnology, details of the human EndoV catalytic pathway remain unclear due to limited experimental information beyond a crystal structure of the apoenzyme and select mutational data. Since a mechanistic understanding is critical for further deciphering the central roles and expanding applications of human EndoV in medicine and biotechnology, molecular dynamics (MD) simulations and quantum mechanics/molecular mechanics (QM/MM) calculations were used to unveil the atomistic details of the catalytic pathway. Due to controversies surrounding the number of metals required for nuclease activity, enzyme-substrate models with different numbers of active site metals and various metal-substrate binding configurations were built based on structural data for other nucleases. Subsequent MD simulations revealed the structure and stability of the human EndoV-substrate complex for a range of active site metal binding architectures. Four unique pathways were then characterized using QM/MM that vary in metal number (one versus two) and modes of substrate coordination [direct versus indirect (water-mediated)], with several mechanisms being fully consistent with experimental structural, kinetic, and mutational data for related nucleases, including members of the EndoV family. Beyond uncovering key roles for several active site amino acids (D240 and K155), our calculations highlight that while one metal is essential for human EndoV activity, the enzyme can benefit from using two metals due to the presence of two suitable metal binding sites. By directly comparing one- versus two-metal-mediated P-O bond cleavage reactions within the confines of the same active site, our work brings a fresh perspective to the "number of metals" controversy.

Is Metal Stabilization of the Leaving Group Required or Can Lysine Facilitate Phosphodiester Bond Cleavage in Nucleic Acids? A Computational Study of EndoV

Endonuclease V (EndoV) is a single-metal-dependent enzyme that repairs deaminated DNA nucleobases in cells by cleaving the phosphodiester bond, and this enzyme has proven to be a powerful tool in biotechnology and medicine. The catalytic mechanism used by EndoV must be understood to design new disease detection and therapeutic solutions and further exploit the enzyme in interdisciplinary applications. This study has used a mixed molecular dynamics (MD) and quantum mechanics/molecular mechanics (QM/MM) approach to compare eight distinct catalytic pathways and provides the first proposed mechanism for bacterial EndoV. The calculations demonstrate that mechanisms involving either direct or indirect metal coordination to the leaving group of the substrate previously proposed for other nucleases are unlikely for EndoV, regardless of the general base (histidine, aspartate, and substrate phosphate moiety). Instead, distinct catalytic pathways are characterized for EndoV that involve K139 stabilizing the leaving group, a metal-coordinated water stabilizing the transition structure, and either H214 or a substrate phosphate group activating the water nucleophile. In silico K139A and H214A mutational results support the newly proposed roles of these residues. Although this is a previously unseen combination of general base, general acid, and metal-binding architecture for a one-metal-dependent endonuclease, our proposed catalytic mechanisms are fully consistent with experimental kinetic, structural, and mutational data. In addition to substantiating a growing body of literature, suggesting that one metal is enough to catalyze P-O bond cleavage in nucleic acids, this new fundamental understanding of the catalytic function will promote the exploration of new and improved applications of EndoV.

Digital detection of multiple minority mutants and expression levels of multiple colorectal cancer-related genes using digital-PCR coupled with bead-array

To simultaneously analyze mutations and expression levels of multiple genes on one detection platform, we proposed a method termed “multiplex ligation-dependent probe amplification–digital amplification coupled with hydrogel bead-array” (MLPA–DABA) and applied it to diagnose colorectal cancer (CRC). CRC cells and tissues were sampled to extract nucleic acid, perform MLPA with sequence-tagged probes, perform digital emulsion polymerase chain reaction (PCR), and produce a hydrogel bead-array to immobilize beads and form a single bead layer on the array. After hybridization with fluorescent probes, the number of colored beads, which reflects the abundance of expressed genes and the mutation rate, was counted for diagnosis. Only red or green beads occurred on the chips in the mixed samples, indicating the success of single-molecule PCR. When a one-source sample was analyzed using mixed MLPA probes, beads of only one color occurred, suggesting the high specificity of the method in analyzing CRC mutation and gene expression. In gene expression analysis of a CRC tissue from one CRC patient, the mutant percentage was 3.1%, and the expression levels of CRC-related genes were much higher than those of normal tissue. The highly sensitive MLPA–DABA succeeds in the relative quantification of mutations and gene expressions of exfoliated cells in stool samples of CRC patients on the same chip platform. MLPA–DABA coupled with hydrogel bead-array is a promising method in the non-invasive diagnosis of CRC.

Endonuclease V: an unusual enzyme for repair of DNA deamination

Endonuclease V (endo V) was first discovered as the fifth endonuclease in Escherichia coli in 1977 and later rediscovered as a deoxyinosine 3' endonuclease. Decades of biochemical and genetic investigations have accumulated rich information on its role as a DNA repair enzyme for the removal of deaminated bases. Structural and biochemical analyses have offered invaluable insights on its recognition capacity, catalytic mechanism, and multitude of enzymatic activities. The roles of endo V in genome maintenance have been validated in both prokaryotic and eukaryotic organisms. The ubiquitous nature of endo V in the three domains of life: Bacteria, Archaea, and Eukaryotes, indicates its existence in the early evolutionary stage of cellular life. The application of endo V in mutation detection and DNA manipulation underscores its value beyond cellular DNA repair. This review is intended to provide a comprehensive account of the historic aspects, biochemical, structural biological, genetic and biotechnological studies of this unusual DNA repair enzyme.

A simple, universal, efficient PCR-based gene synthesis method: sequential OE-PCR gene synthesis

Herein we present a simple, universal, efficient gene synthesis method based on sequential overlap extension polymerase chain reactions (OE-PCRs). This method involves four key steps: (i) the design of paired complementary 54-mer oligonucleotides with 18 bp overlaps, (ii) the utilisation of sequential OE-PCR to synthesise full-length genes, (iii) the cloning and sequencing of four positive T-clones of the synthesised genes and (iv) the resynthesis of target genes by OE-PCR with correct templates. Mispriming and secondary structure were found to be the principal obstacles preventing successful gene synthesis and were easily identified and solved in this method. Compensating for the disadvantages of being laborious and time-consuming, this method has many attractive advantages, such as the ability to guarantee successful gene synthesis in most cases and good allowance for Taq polymerase, oligonucleotides, PCR conditions and a high error rate. Thus, this method provides an alternative tool for individual gene synthesis without strict needs of the high-specialised experience.

Enrichment of error-free synthetic DNA sequences by CEL I nuclease

As the availability of DNA sequence information has grown, so has the need to replicate DNA sequences synthetically. Synthetically produced DNA sequences allow the researcher to exert greater control over model systems and allow for the combinatorial design and construction of novel metabolic and regulatory pathways, as well as optimized protein-coding sequences for biotechnological applications. This utility has made synthetically produced DNA a hallmark of the molecular biosciences and a mainstay of synthetic biology. However, synthetically produced DNA has a significant shortcoming in that it typically has an error rate that is orders of magnitude higher when compared to DNA sequences derived directly from a biological source. This relatively high error rate adds to the cost and labor necessary to obtain sequence-verified clones from synthetically produced DNA sequences. This unit describes a protocol to enrich error-free sequences from a population of error-rich DNA via treatment with CEL I (Surveyor) endonuclease. This method is a straightforward and quick way of reducing the error content of synthetic DNA pools and reliably reduces the error rates by >6-fold per round of treatment.

Human endonuclease V as a repair enzyme for DNA deamination

The human endonuclease V gene is located in chromosome 17q25.3 and encodes a 282 amino acid protein that shares about 30% sequence identity with bacterial endonuclease V. This study reports biochemical properties of human endonuclease V with respect to repair of deaminated base lesions. Using soluble proteins fused to thioredoxin at the N-terminus, we determined repair activities of human endonuclease V on deoxyinosine (I)-, deoxyxanthosine (X)-, deoxyoxanosine (O)- and deoxyuridine (U)-containing DNA. Human endonuclease V is most active with deoxyinosine-containing DNA but with minor activity on deoxyxanthosine-containing DNA. Endonuclease activities on deoxyuridine and deoxyoxanosine were not detected. The endonuclease activity on deoxyinosine-containing DNA follows the order of single-stranded I>G/I>T/I>A/I>C/I. The preference of the catalytic activity correlates with the binding affinity of these deoxyinosine-containing DNAs. Mg(2+) and to a much less extent, Mn(2+), Ni(2+), Co(2+) can support the endonuclease activity. Introduction of human endonuclease V into Escherichia coli cells deficient in nfi, mug and ung genes caused three-fold reduction in mutation frequency. This is the first report of deaminated base repair activity for human endonuclease V. The relationship between the endonuclease activity and deaminated deoxyadenosine (deoxyinosine) repair is discussed.

A simple, high sensitivity mutation screening using Ampligase mediated T7 endonuclease I and Surveyor nuclease with microfluidic capillary electrophoresis

Mutation and polymorphism detection is of increasing importance for a variety of medical applications, including identification of cancer biomarkers and genotyping for inherited genetic disorders. Among various mutation-screening technologies, enzyme mismatch cleavage (EMC) represents a great potential as an ideal scanning method for its simplicity and high efficiency, where the heteroduplex DNAs are recognized and cleaved into DNA fragments by mismatch-recognizing nucleases. Thereby, the enzymatic cleavage activities of the resolving nucleases play a critical role for the EMC sensitivity. In this study, we utilized the unique features of microfluidic capillary electrophoresis and de novo gene synthesis to explore the enzymatic properties of T7 endonuclease I and Surveyor nuclease for EMC. Homoduplex and HE DNAs with specific mismatches at desired positions were synthesized using PCR (polymerase chain reaction) gene synthesis. The effects of nonspecific cleavage, preference of mismatches, exonuclease activity, incubation time, and DNA loading capability were systematically examined. In addition, the utilization of a thermostable DNA ligase for real-time ligase mediation was investigated. Analysis of the experimental results has led to new insights into the enzymatic cleavage activities of T7 endonuclease I and Surveyor nuclease, and aided in optimizing EMC conditions, which enhance the sensitivity and efficiency in screening of unknown DNA variations.

Gene synthesis: methods and applications

DNA synthesis techniques and technologies are quickly becoming a cornerstone of modern molecular biology and play a pivotal role in the field of synthetic biology. The ability to synthesize whole genes, novel genetic pathways, and even entire genomes is no longer the dream it was 30 years ago. Using little more than a thermocycler, commercially synthesized oligonucleotides, and DNA polymerases, a standard molecular biology laboratory can synthesize several kilobase pairs of synthetic DNA in a week using existing techniques. Herein, we review the techniques used in the generation of synthetic DNA, from the chemical synthesis of oligonucleotides to their assembly into long, custom sequences. Software and websites to facilitate the execution of these approaches are explored, and applications of DNA synthesis techniques to gene expression and synthetic biology are discussed. Finally, an example of automated gene synthesis from our own laboratory is provided.

[Advances in early diagnosis of colorectal cancer based on detection of RNAs in stool.]

Colorectal cancer (CRC) is one of the most malignant cancers in gastrointestinal tract. In China, there are increasing rates of morbidity and mortality for CRC. As the mortality is closely related to the stage of disease at time of diagnosis, early diagnosis of CRC is important. However, current techniques used for clinical diagnosis have limitations which made them difficult to achieve the early diagnosis. The detection of RNAs in stool is a newly developed noninvasive technique for early diagnosis of CRC at molecular levels. Compared with the techniques including colonoscopy, fecal occult-blood test and stool DNA-based mutation detection, diagnosis based on the detection of RNAs in stool has the advantages of low-cost and high sensitivity. Moreover, stool RNA-based techniques are able to analyze multiplexed gene expression simultaneously and monitor cancer progression dynamically. This paper introduced the feasibility of stool RNA analysis, and systematically reviewed the genes associated with stool RNA analysis, methods of RNA isolation from stool sample, and techniques for gene expression analysis in stool RNA. Finally, further applications of stool RNA-based techniques for early diagnosis of CRC were briefly discussed.

A randomized phase 2 study of erlotinib alone and in combination with bortezomib in previously treated advanced non-small cell lung cancer

INTRODUCTION

This phase 2 study was conducted to determine the efficacy and safety of erlotinib alone and with bortezomib in patients with non-small cell lung cancer (NSCLC).

METHODS

Patients with histologically or cytologically confirmed relapsed or refractory stage IIIb/IV NSCLC were randomized (1:1; stratified by baseline histology, smoking history, sex) to receive erlotinib 150 mg/d alone (arm A; n = 25) or in combination with bortezomib 1.6 mg/m2, days 1 and 8 (arm B; n = 25) in 21-day cycles. Responses were assessed using Response Evaluation Criteria in Solid Tumors. Tumor samples were evaluated for mutations predicting response. Six additional patients received the combination in a prior dose deescalation stage and were included in safety analyses.

RESULTS

Response rates were 16% in arm A and 9% in arm B; disease control rates were 52 and 45%, respectively. The study was halted at the planned interim analysis due to insufficient clinical activity in arm B. Median progression-free survival and overall survival were 2.7 and 7.3 months in arm A, and 1.3 and 8.5 months in arm B. Six-month survival rates were 56.0% in both arms; 12-month rates were 40 and 30% in arms A and B, respectively. Response rate to erlotinib+/-bortezomib was significantly higher in patients with epidermal growth factor receptor mutations (50 versus 9% for wild type). The most common treatment-related grade > or =3 adverse event was skin rash (three patients in each treatment group).

CONCLUSION

Insufficient activity was seen with erlotinib plus bortezomib in patients with relapsed/refractory advanced NSCLC to warrant a phase 3 study of the combination.

Highly sensitive mutation detection based on digital amplification coupled with hydrogel bead-array

In order to detect small amounts of mutants for early cancer diagnosis, we have developed the novel method of using amplicon-coated microbeads and single-molecule-PCR in water-in-oil emulsions, which we coupled with a new detection platform, the hydrogel bead-array, a 3-D polyacrylamide gel network used as a carrier to immobilize the beads.

Analysis of genes, transcripts, and proteins via DNA ligation

Analytical reactions in which short DNA strands are used in combination with DNA ligases have proven useful for measuring, decoding, and locating most classes of macromolecules. Given the need to accumulate large amounts of precise molecular information from biological systems in research and in diagnostics, ligation reactions will continue to offer valuable strategies for advanced analytical reactions. Here, we provide a basis for further development of methods by reviewing the history of analytical ligation reactions, discussing the properties of ligation reactions that render them suitable for engineering novel assays, describing a wide range of successful ligase-based assays, and briefly considering future directions.

Endonucleolytic mutation analysis by internal labeling (EMAIL)

Mismatch-specific endonucleases are efficient tools for the targeted scanning of populations for subtle DNA variations. Conventional protocols involve 5'-labeled amplicon substrates and the detection of digestion products by LIF electrophoresis. A shortcoming of such protocols, however, is the limited 5'-signal strength. Normally the sensitivity of fluorescent DNA analyzers is superior to that of intercalating dye/agarose systems, however, pooling capacities of the former and latter approaches to mismatch scanning are somewhat similar. Detection is further limited by significant background. We investigated the activity of CEL nucleases using amplicon substrates labeled both internally and at each 5'-terminus. The amplicons were generated from exon 8 of the rice starch synthase IIa encoding gene. Signal of both 5'-labels was significantly reduced by enzyme activity, while that of the internal label was largely unaffected. In addition, background resulting from internal labeling was a significant improvement on that associated with 5'-labeling. Sizing of the multilabeled substrates suggests that 5'-modification enhances exonucleolytic activity, resulting in the removal of the dye-labeled terminal nucleotides. We have developed an alternative approach to mismatch detection, in which amplicon labeling is achieved via the incorporation of fluorescently labeled deoxynucleotides, which we have named Endonucleolytic Mutation Analysis by Internal Labeling (EMAIL). The strength of the EMAIL assay was demonstrated by the reclassification of a rice line as being heterozygous for the starch gene. This cultivar was assigned as being homozygous by a previous resequencing study. EMAIL shows potential for the clear identification of multiple mutations amongst allelic pools.

Switching base preferences of mismatch cleavage in endonuclease V: an improved method for scanning point mutations

Endonuclease V (endo V) recognizes a broad range of aberrations in DNA such as deaminated bases or mismatches. It nicks DNA at the second phosphodiester bond 3′ to a deaminated base or a mismatch. Endonuclease V obtained from Thermotoga maritima preferentially cleaves purine mismatches in certain sequence context. Endonuclease V has been combined with a high-fidelity DNA ligase to develop an enzymatic method for mutation scanning. A biochemical screening of site-directed mutants identified mutants in motifs III and IV that altered the base preferences in mismatch cleavage. Most profoundly, a single alanine substitution at Y80 position switched the enzyme to essentially a C-specific mismatch endonuclease, which recognized and cleaved A/C, C/A, T/C, C/T and even the previously refractory C/C mismatches. Y80A can also detect the G13D mutation in K-ras oncogene, an A/C mismatch embedded in a G/C rich sequence context that was previously inaccessible using the wild-type endo V. This investigation offers insights on base recognition and active site organization. Protein engineering in endo V may translate into better tools in mutation recognition and cancer mutation scanning.

Two-dimensional strandness-dependent electrophoresis: A method to characterize single-stranded DNA, double-stranded DNA, and RNA–DNA hybrids in complex samples

We describe two-dimensional strandness-dependent electrophoresis (2D-SDE) for quantification and length distribution analysis of single-stranded (ss) DNA fragments, double-stranded (ds) DNA fragments, RNA-DNA hybrids, and nicked DNA fragments in complex samples. In the first dimension nucleic acid molecules are separated based on strandness and length in the presence of 7 M urea. After the first-dimension electrophoresis all nucleic acid fragments are heat denatured in the gel. During the second-dimension electrophoresis all nucleic acid fragments are single-stranded and migrate according to length. 2D-SDE takes about 90 min and requires only basic skills and equipment. We show that 2D-SDE has many applications in analyzing complex nucleic acid samples including (1) estimation of renaturation efficiency and kinetics, (2) monitoring cDNA synthesis, (3) detection of nicked DNA fragments, and (4) estimation of quality and in vitro damage of nucleic acid samples. Results from 2D-SDE should be useful to validate techniques such as complex polymerase chain reaction, subtractive hybridization, cDNA synthesis, cDNA normalization, and microarray analysis. 2D-SDE could also be used, e.g., to characterize biological nucleic acid samples. Information obtained with 2D-SDE cannot be readily obtained with other methods. 2D-SDE can be used for preparative isolation of ssDNA fragments, dsDNA fragments, and RNA-DNA hybrids.

Enzymatic mutation detection technologies

Mutation is as necessary for life as fidelity is in DNA replication. The study of mutations reveals the normal functions of genes, messages, proteins, the causes of many diseases, and the variability of responses among individuals. Indeed, recent mutations that have not yet become polymorphisms are often deleterious and pertinent to the disease history of afflicted individuals. This review discusses the principles behind a variety of methods for the detection of mutations and factors that should be considered in future methods design. One enzymatic approach in particular using orthologs of the CEL I nuclease that show high specificity for all mismatches, appears to be easy and robust. Further developments of this and other methods will allow mutation detection to become an integral component of individualized medicine.

High sensitivity EndoV mutation scanning through real-time ligase proofreading

The ability to associate mutations in cancer genes with the disease and its subtypes is critical for understanding oncogenesis and identifying biomarkers for clinical diagnosis. A two-step mutation scanning method that sequentially used endonuclease V (EndoV) to nick at mismatches and DNA ligase to reseal incorrectly or nonspecifically nicked sites was previously developed in our laboratory. Herein we report an optimized single-step assay that enables ligase to proofread EndoV cleavage in real-time under a compromise between buffer conditions. Real-time proofreading results in a dramatic reduction of background cleavage. A universal PCR strategy that employs both unlabeled gene-specific primers and labeled universal primers, allows for multiplexed gene amplification and precludes amplification of primer dimers. Internally labeled PCR primers eliminate EndoV cleavage at the 5' terminus, enabling high-throughput capillary electrophoresis readout. Furthermore, signal intensity is increased and artifacts are reduced by generating heteroduplexes containing only one of the two possible mismatches (e.g. either A/C or G/T). The single-step assay improves sensitivity to 1:50 and 1:100 (mutant:wild type) for unknown mutations in the p53 and K-ras genes, respectively, opening prospects as an early detection tool.

Improving specificity of DNA hybridization-based methods

Methods based on DNA reassociation in solution with the subsequent PCR amplification of certain hybrid molecules, such as coincidence cloning and subtractive hybridization, all suffer from a common imperfection: cross-hybridization between various types of paralogous repetitive DNA fragments. Although the situation can be slightly improved by the addition of repeat-specific competitor DNA into the hybridization mixture, the cross-hybridization outcome is a significant number of background chimeric clones in resulting DNA libraries. In order to overcome this challenge, we developed a technique called mispaired DNA rejection (MDR), which utilizes a treatment of resulting reassociated DNA with mismatch-specific nucleases. We examined the MDR efficiency using cross-hybridization of complex, whole genomic mixtures derived from human and chimpanzee genomes, digested with frequent-cutter restriction enzyme. We show here that both single-stranded DNA-specific and mismatched double-stranded DNA-specific nucleases can be used for MDR separately or in combination, reducing the background level from 60 to 4% or lower. The technique presented here is of universal usefulness and can be applied to both cDNA and genomic DNA subtractions of very complex DNA mixtures. MDR is also useful for the genome-wide recovery of highly conserved DNA sequences, as we demonstrate by comparing human and pygmy marmoset genomes.

Cleavage of deoxyoxanosine-containing oligodeoxyribonucleotides by bacterial endonuclease V

Oxanine (O) is a deamination product derived from guanine with the nitrogen at the N1 position substituted by oxygen. Cytosine, thymine, adenine, guanine as well as oxanine itself can be incorporated by Klenow Fragment to pair with oxanine in a DNA template with similar efficiency, indicating that oxanine in DNA may cause various mutations. As a nucleotide, deoxyoxanosine may substitute for deoxyguanosine to complete a primer extension reaction. Endonuclease V, an enzyme known for its enzymatic activity on uridine-, inosine- and xanthosine-containing DNA, can cleave oxanosine-containing DNA at the second phosphodiester bond 3' to the lesion. Mg2+ or Mn2+, and to a small extent Co2+ or Ni2+, support the oxanosine-containing DNA cleavage activity. All four oxanosine-containing base pairs (A/O, T/O, C/O and G/O) were cleaved with similar efficiency. The cleavage of double-stranded oxanosine-containing DNA was approximately 6-fold less efficient than that of double-stranded inosine-containing DNA. Single-stranded oxanosine-containing DNA was cleaved with a lower efficiency as compared with double-stranded oxanosine-containing DNA. A metal ion enhances the binding of endonuclease V to double-stranded and single-stranded oxanosine-containing DNA 6- and 4-fold, respectively. Hypothetic models of oxanine-containing base pairs and deaminated base recognition mechanism are presented.

Harmonized microarray/mutation scanning analysis of TP53 mutations in undissected colorectal tumors

Both the mutational status and the specific mutation of TP53 (p53) have been shown to impact both tumor prognosis and response to therapies. Molecular profiling of solid tumors is confounded by infiltrating wild-type cells, since normal DNA can interfere with detection of mutant sequences. Our objective was to identify TP53 mutations in 138 stage I-IV colorectal adenocarcinomas and liver metastases without first enriching for tumor cells by microdissection. To achieve this, we developed a harmonized protocol involving multiplex polymerase chain reaction/ligase detection reaction (PCR/LDR) with Universal DNA microarray analysis and endonuclease V/ligase mutation scanning. Sequences were verified using dideoxy sequencing. The harmonized protocol detected all 66 mutations. Dideoxy sequencing detected 41 out of 66 mutations (62%) using automated reading, and 59 out of 66 mutations (89%) with manual reading. Data analysis comparing colon cancer entries in the TP53 database (http://p53.curie.fr) with the results reported in this study showed that distribution of mutations and the mutational events were comparable.

Towards fast and inexpensive molecular diagnostic: the case of TP53

BACKGROUND

Much research suggests that TP53 mutations have prognostic importance and sometimes are a significant factor in clinical oncology. A considerable effort has been made to develop fast and inexpensive methods for TP53 mutations detection.

METHODS

On the basis of describing the role of TP53 as tumor suppressor gene and TP53 mutation spectrum, the authors discuss conventional methods and new technologies for TP53 mutations detection. This discussion is supported by more recent publications in the field of both molecular genetics and analysis technologies.

RESULTS

Biosensors and gene chips are of considerable recent interest, due to their tremendous promise for obtaining sequence-specific information in a faster, simpler and cheaper manner compared to traditional methods.

CONCLUSIONS

New methods such as biosensors and gene chips appear promising as analytical methods of detecting mutations.

Incision at hypoxanthine residues in DNA by a mammalian homologue of the Escherichia coli antimutator enzyme endonuclease V

Deamination of DNA bases can occur spontaneously, generating highly mutagenic lesions such as uracil and hypoxanthine. In Escherichia coli two enzymes initiate repair at hypoxanthine residues in DNA. The alkylbase DNA glycosylase, AlkA, initiates repair by removal of the damaged base, whereas endonuclease V, Endo V, hydrolyses the second phosphodiester bond 3' to the lesion. We have identified and characterised a mouse cDNA with striking homology to the E.coli nfi gene, which also has significant similarities to motifs required for catalytic activity of the UvrC endonuclease. The 37-kDa mouse enzyme (mEndo V) incises the DNA strand at the second phosphodiester bond 3' to hypoxanthine- and uracil-containing nucleotides. The activity of mEndo V is elevated on single-stranded DNA substrate in vitro. Expression of the mouse protein in a DNA repair-deficient E.coli alkA nfi strain suppresses its spontaneous mutator phenotype. We suggest that mEndo V initiates an alternative excision repair pathway for hypoxanthine removal. It thus appears that mEndo V has properties overlapping the function of alkylbase DNA glycosylase (Aag) in repair of deaminated adenine, which to some extent could explain the absence of phenotypic abnormalities associated with Aag knockout in mice.

Methods for screening tumors for p53 status and therapeutic exploitation

Mutations in the p53 oncosuppressor gene occur in most human cancers and regulation of the protein is defective in a variety of others. Novel strategies are emerging for the treatment of tumors that have p53 mutations. In this context, the analysis of p53 status is useful in diagnosis and prognosis, and could serve to evaluate the effectiveness of a cancer treatment. In this review, we report an overview of major methods for screening tumors for p53 status and the major strategies suggested for restoring p53 function.

Single nucleotide polymorphism seeking long term association with complex disease

Successful investigation of common diseases requires advances in our understanding of the organization of the genome. Linkage disequilibrium provides a theoretical basis for performing candidate gene or whole-genome association studies to analyze complex disease. However, to constructively interrogate SNPs for these studies, technologies with sufficient throughput and sensitivity are required. A plethora of suitable and reliable methods have been developed, each of which has its own unique advantage. The characteristics of the most promising genotyping and polymorphism scanning technologies are presented. These technologies are examined both in the context of complex disease investigation and in their capacity to face the unique physical and molecular challenges (allele amplification, loss of heterozygosity and stromal contamination) of solid tumor research.