Comparative Studies on the Detoxification of Aflatoxins by Sodium Hypochlorite and Commercial Bleaches

Cultures of Aspergillus flavus and aflatoxins were destroyed by a commercial bleach (Clorox; active ingredient, NaOCl) or analytical reagent grade NaOCl at 7.0 x 10(-3) M NaOCl in 5 days. Addition of Clorox or NaOCl at 2.8 x 10(-3) M to the fungal growth medium prior to inoculation completely inhibited the fungal growth. Aflatoxin production was inversely proportional to the logarithm of NaOCl concentration and time of treatment. Clorox and NaOCl were equally effective on aflatoxins, but fungal cells were lysed more readily by Clorox than by NaOCl. Mycelia older than 8 days lysed more readily than younger ones. Most conidia survived concentrations below 1.4 x 10(-3) M. The lowest effective concentration for a 2-hr treatment was 8.8 x 10(-3) M which is well below the Clorox concentration recommended for routine laboratory decontamination of aflatoxins. Mice and rats injected with aflatoxins and aflatoxins incompletely destroyed by Clorox died within 72 hr and had typical liver and kidney damage caused by aflatoxins. However, animals injected with NaOCl or Clorox or Clorox-destroyed aflatoxin extracts survived and showed no obvious liver or kidney damage.     

An Efficient Multistrategy DNA Decontamination Procedure of PCR Reagents for Hypersensitive PCR Applications

Background

PCR amplification of minute quantities of degraded DNA for ancient DNA research, forensic analyses, wildlife studies and ultrasensitive diagnostics is often hampered by contamination problems. The extent of these problems is inversely related to DNA concentration and target fragment size and concern (i) sample contamination, (ii) laboratory surface contamination, (iii) carry-over contamination, and (iv) contamination of reagents.

Methodology/Principal Findings

Here we performed a quantitative evaluation of current decontamination methods for these last three sources of contamination, and developed a new procedure to eliminate contaminating DNA contained in PCR reagents. We observed that most current decontamination methods are either not efficient enough to degrade short contaminating DNA molecules, rendered inefficient by the reagents themselves, or interfere with the PCR when used at doses high enough to eliminate these molecules. We also show that efficient reagent decontamination can be achieved by using a combination of treatments adapted to different reagent categories. Our procedure involves γ- and UV-irradiation and treatment with a mutant recombinant heat-labile double-strand specific DNase from the Antarctic shrimp Pandalus borealis. Optimal performance of these treatments is achieved in narrow experimental conditions that have been precisely analyzed and defined herein.

Conclusions/Significance

There is not a single decontamination method valid for all possible contamination sources occurring in PCR reagents and in the molecular biology laboratory and most common decontamination methods are not efficient enough to decontaminate short DNA fragments of low concentration. We developed a versatile multistrategy decontamination procedure for PCR reagents. We demonstrate that this procedure allows efficient reagent decontamination while preserving the efficiency of PCR amplification of minute quantities of DNA.     

Detection of enterotoxigenic Clostridium perfringens in meat samples by using molecular methods

To prevent food-borne bacterial diseases and to trace bacterial contamination events to foods, microbial source tracking (MST) methods provide important epidemiological information. To apply molecular methods to MST, it is necessary not only to amplify bacterial cells to detection limit levels but also to prepare DNA with reduced inhibitory compounds and contamination. Isolates carrying the Clostridium perfringens enterotoxin gene (cpe) on the chromosome or a plasmid rank among the most important food-borne pathogens. Previous surveys indicated that cpe-positive C. perfringens isolates are present in only ～5% of nonoutbreak food samples and then only at low numbers, usually less than 3 cells/g. In this study, four molecular assays for the detection of cpe-positive C. perfringens isolates, i.e., ordinary PCR, nested PCR, real-time PCR, and loop-mediated isothermal amplification (LAMP), were developed and evaluated for their reliability using purified DNA. For use in the artificial contamination of meat samples, DNA templates were prepared by three different commercial DNA preparation kits. The four molecular assays always detected cpe when >103 cells/g of cpe-positive C. perfringens were present, using any kit. Of three tested commercial DNA preparation kits, the InstaGene matrix kit appeared to be most suitable for the testing of a large number of samples. By using the InstaGene matrix kit, the four molecular assays efficiently detected cpe using DNA prepared from enrichment culture specimens of meat samples contaminated with low numbers of cpe-positive C. perfringens vegetative cells or spores. Overall, the current study developed molecular assay protocols for MST to detect the contamination of foods with low numbers of cells, and at a low frequency, of cpe-positive C. perfringens isolates.     

Development of a Rapid Method for Identifying Carryover Contamination of Positive Control DNA,Using a Chimeric Positive Control and Restriction Enzyme for the Diagnosis of White Spot Syndrome Virus by Nested PCR

Chimeric positive plasmids have been developed to minimize false-positive reactions caused by polymerase chain reaction (PCR) contamination. Here, we developed a rapid method for identifying false-positive results while detecting white spot syndrome virus (WSSV) by nested PCR, using chimeric positive plasmids. The results of PCRs using WSSV diagnostic primer sets showed PCR products of a similar size (WSSV 1st PCR product, 1,447 bp; WSSV 2nd PCR product, 941 bp) using WSSV chimeric plasmids or DNA from shrimp infected with WSSV. The PCR products were digested with DraI for 1 h at 37 °C. The digested chimeric DNA separated into two DNA bands; however, the WSSV-infected shrimp DNA did not separate. Thus, chimeric plasmid DNA may be used as positive control DNA instead of DNA from WSSV-infected shrimp, in order to prevent PCR contamination. Thus, the use of restriction enzyme digestion allowed us to rapidly distinguish between WSSV DNA and WSSV chimeric plasmid DNA.     

Hypersensitive PCR, ancient human mtDNA, and contamination

When highly efficient polymerase was used with high cycle numbers (50-60), strong amplifications were observed, but negative controls were also unexpectedly amplified in a study of ancient human mtDNA from 2000-year-old skeletons. The results of a series of tests revealed that the hypersensitive polymerase chain reaction (PCR) generated by higher cycles and the presence of contaminant DNA (though at extremely low levels) should be responsible for the amplification of negative controls. We suggest that PCR sensitivity be optimized to take advantage of highly efficient polymerase and at the same time prevent "background DNA" from becoming "contaminant DNA" and obscuring the analysis of authentic ancient DNA. We propose the use of multiple positive controls when amplifying ancient human mtDNA samples to indicate the sensitivity of individual PCR amplifications and to monitor the contamination levels of modern human DNA. This study provides some suggestions as to how to amplify and analyze ancient human mtDNA when unavoidable and extremely tiny amounts of modern human DNA exist.     

Sodium hypochlorite denatures the DNA of the amphibian chytrid fungus Batrachochytrium dendrobatidis

Batrachochytrium dendrobatidis, an aquatic amphibian fungus, has been implicated in many amphibian declines and extinctions. A real-time polymerase chain reaction (PCR) TaqMan assay is now used to detect and quantify B. dendrobatidis on amphibians and other substrates via tissue samples, swabbing and filtration. The extreme sensitivity of this diagnostic test makes it necessary to rigorously avoid cross-contamination of samples, which can produce false positives. One technique used to eliminate contamination is to destroy the contaminating DNA by chemical means. We tested 3 concentrations of sodium hypochlorite (NaOCl) (1, 6 and 12%) over 4 time periods (1, 6, 15 and 24 h) to determine if NaOCl denatures B. dendrobatidis DNA sufficiently to prevent its recognition and amplification in PCR tests for the fungus. Soaking in 12% NaOCl denatured 100% of DNA within 1 h. Six percent NaOCl was on average 99.999% effective across all exposure periods, with only very low numbers of zoospores detected following treatment. One percent NaOCl was ineffective across all treatment periods. Under ideal, clean conditions treatment with 6% NaOCl may be sufficient to destroy DNA and prevent cross-contamination of samples; however, we recommend treatment with 12% NaOCl for 1 h to be confident all B. dendrobatidis DNA is destroyed.     

Extensive human DNA contamination in extracts from ancient dog bones and teeth

Ancient DNA (aDNA) sequences, especially those of human origin, are notoriously difficult to analyze due to molecular damage and exogenous DNA contamination. Relatively few systematic studies have focused on this problem. Here we investigate the extent and origin of human DNA contamination in the most frequently used sources for aDNA studies, that is, bones and teeth from museum collections. To distinguish contaminant DNA from authentic DNA we extracted DNA from dog (Canis familiaris) specimens. We monitored the presence of a 148-bp human-specific and a 152-bp dog-specific mitochondrial DNA (mtDNA) fragment in DNA extracts as well as in negative controls. The total number of human and dog template molecules were quantified using real-time polymerase chain reaction (PCR), and the sequences were characterized by amplicon cloning and sequencing. Although standard precautions to avoid contamination were taken, we found that all samples from the 29 dog specimens contained human DNA, often at levels exceeding the amount of authentic ancient dog DNA. The level of contaminating human DNA was also significantly higher in the dog extracts than in the negative controls, and an experimental setup indicated that this was not caused by the carrier effect. This suggests that the contaminating human DNA mainly originated from the dog bones rather than from laboratory procedures. When cloned, fragments within a contaminated PCR product generally displayed several different sequences, although one haplotype was often found in majority. This leads us to believe that recognized criteria for authenticating aDNA cannot separate contamination from ancient human DNA the way they are presently used.     

An Assessment of Air As a Source of DNA Contamination Encountered When Performing PCR

Sensitive molecular methods, such as the PCR, can detect low-level contamination, and careful technique is required to reduce the impact of contaminants. Yet, some assays that are designed to detect high copy-number target sequences appear to be impossible to perform without contamination, and frequently, personnel or laboratory environment are held responsible as the source. This complicates diagnostic and research analysis when using molecular methods. To investigate the air specifically as a source of contamination, which might occur during PCR setup, we exposed tubes of water to the air of a laboratory and clean hood for up to 24 h. To increase the chances of contamination, we also investigated a busy open-plan office in the same way. All of the experiments showed the presence of human and rodent DNA contamination. However, there was no accumulation of the contamination in any of the environments investigated, suggesting that the air was not the source of contamination. Even the air from a busy open-plan office was a poor source of contamination for all of the DNA sequences investigated (human, bacterial, fungal, and rodent). This demonstrates that the personnel and immediate laboratory environment are not necessarily to blame for the observed contamination.     

Use of PCR analysis for detecting low levels of bacteria and mold contamination in pharmaceutical samples

PCR assays were developed and compared to standard methods for quality evaluation of pharmaceutical raw materials and finished products with low levels of microbial contamination. Samples were artificially contaminated with less than 10 CFU of Escherichia coli, Staphylococcus aureus, Pseudomonas aeruginosa, and Aspergillus niger. Bacterial DNA was extracted from each enrichment broth by mild lysis in Tris-EDTA-Tween 20 buffer containing proteinase K while mold DNA was extracted by boiling samples in Tris-EDTA-SDS buffer for 1 h. A 10-microl aliquot of extracted DNA was added to Ready-To-Go PCR beads and specific primers for E. coli, S. aureus, and P. aeruginosa. However, 50-microl aliquots of extracted mold DNA were used for amplification of specific A. niger DNA sequences. Standard methods required 6-8 days while PCR detection of all microorganisms was completed within 27 h. Low levels of microbial contamination were detected in all raw materials and products using PCR assays. Rapid quality evaluation of pharmaceutical samples resulted in optimization of product manufacturing, quality control, and release of finished products.     

A multiple-tubes approach for accurate genotyping of very small DNA samples by using PCR: statistical considerations.

A multiple-tubes procedure is described for using PCR to determine the genotype of a very small DNA sample. The procedure involves dividing the sample among several tubes, then amplifying and typing the contents of each tube separately. The results are analyzed by a statistical procedure which determines whether a genotype can be conclusively assigned to the DNA sample. Simulation studies show that this procedure usually gives correct results even when the number of double-stranded fragments in the sample is as small as 30. The procedure remains effective even in the presence of small amounts of laboratory contamination. We find that the multiple-tubes procedure is superior to the standard one-tube procedure, either when the sample is small or when laboratory contamination is a potential problem; and we recommend its use in these situations. Because the procedure is statistical, it allows the degree of certainty in the result to be quantified and may be useful in other PCR applications as well.     

Use of molecular beacon for the detection of fertile male plants in batches of sterile male rapeseed

A assay was developed to detect the level of contaminating male fertile rapeseeds within a population of male sterile Ogu-INRA seeds, based on PCR amplification of DNA and fluorescence technology. A molecular beacon was constructed to recognize a specific sequence of the male fertile plant. However, this sequence was also present in the male sterile plant at a very low concentration because of the recombinant structure of the Ogu-INRA mitochondrial genome. Conditions for quantitative PCR were found to take into account this biological data in order to develop an effective test. A 1% contamination can be detected with the naked eye with an ultraviolet light table or by use of a spectrofluorometer. The sensitivity of this method is dependent upon the molecular beacon concentration.     

Micropropagation protocol for Antigonon leptopus an important ornamental and medicinal plant

The effect of some factors on in vitro consecutive micropropagation behavior of Antigonon leptopus was examined including those of culture establishment, shootlets multiplication, rooting and acclimatization stages. The highest percent of aseptic cultures and survival of explants (100%) were obtained as a result of using Clorox 10% for 3?min followed by MC 0.1% for 2?min while, using each of them individually (Clorox 20% or MC 0.1%) for 5?min caused the highest percent of shoot formation. During the multiplication stage, the highest percent of shoot formation was reached to 100% with repeating culture of explants (two times) on MS medium supplemented with 2ip at 1.0 and IBA at 0.2?mg/l. The highest numbers of shootlets/explant were obtained when 2.0?mg/l of BAP or 0.5?mg/l BA?+?0.2?mg/l of IBA were added to MS culture medium. Culturing the explants on MS medium supplemented with 2ip at 0.5 or 1.0?mg/l each combined with 0.2?mg/l of IBA showed the longest shootlets. Reducing the strength of culture media to ½ or ¾ had promotion effect on rooting formation of shootlets. The best results of plant acclimatization (survival percent, plant height and root length) were obtained by using sand or peat moss soil. The amplified DNA fragments using B7, B9 and C19 primers for mother and micropropagated plants showed that the produced pattern by primer B7 had a maximum number of 10 bands of DNA fragments with molecular size ranging between 1025.57 and 176.36?bp, micropropagated plants showed 95.2% similarity in relation to mother plant.     

Examination of Poliovirus Vaccine Preparations for SV40 Sequences

Oral poliovaccines derived from the strains developed by Sabin have been the basis of vaccination against poliomyelitis in the U.K. since 1962. Contamination of earlier materials with the monkey virus SV40, particularly inactivated Salk type poliovaccines, is well documented. Precautions have been in place for more than 30 years to prevent SV40 contamination of oral poliovaccines based on screening of donor animals and tests for SV40 infectivity. PCR was applied to examine all archived samples of oral poliovaccines available to us dating from 1966 to the present, including all vaccines used in the U.K. since 1980, for the presence of SV40 sequences. Of 132 materials examined, 118 were negative on initial testing and fourteen gave reactions which on further examination were attributed either to cross contamination during handling in the laboratory at National Institute for Biological Standards and Control (NIBSC) or to non-specific amplification. It was concluded that none of the samples contained SV40 sequences. The materials included 69 separate monovalent bulks of poliovirus type 1, 2 or 3 grown on monkey kidney cells from four different manufacturers and 74 bulks grown on human diploid cells from two manufacturers.One additional seed material from 1962 contained low levels of unique and characteristic SV40 sequences. The seed had been treated by the manufacturer to inactivate DNA viruses and tests by the manufacturer and at NIBSC failed to demonstrate the presence of infectious SV40 virus. Monovalent bulks prepared by the manufacturer from this seed were negative for SV40 sequences by PCR.The PCR studies provide no evidence of contamination of oral poliovaccines used in the UK with infectious SV40 and suggest that the steps taken to ensure the absence of infectious SV40 are satisfactory.     

Comparison of different decontamination methods for reagents to detect low concentrations of bacterial 16S DNA by real-time-PCR

Contamination of polymerase chain reaction (PCR) reagents continues to be a major problem when consensus primers are used for detection of low concentrations of bacterial DNA. We designed a real-time polymerase chain reaction (PCR) for quantification of bacterial DNA by using consensus primers that bind specifically to the 16S region of bacterial DNA. We have tested four different methods of decontamination of PCR reagents in a project aimed at detecting bacterial DNA at low concentrations: deoxyribonuclease (DNAse) treatment, restriction endonuclease digestion, UV irradiation, and 8-methoxypsoralen in combination with long-wave UV light to intercalate contaminating DNA into double-stranded DNA. All four methods result in inhibition of the PCR reaction, and most of the decontamination procedures failed to eliminate the contaminating bacterial DNA. Only the DNAse decontamination proved to be efficient in eliminating contaminating DNA while conserving PCR efficiency. All four decontamination methods are time consuming and have the possibility of carrying new contamination into the reaction mixture. However, decontamination with DNAse may help, together with the use of highly purified PCR reagents, in detecting small amounts of bacterial DNA in clinical specimens.     

A tale of two fluids: does storing specimens together in liquid preservative cause DNA cross‐contamination in molecular gut‐content studies?

The study of food webs and trophic interactions increasingly relies on PCR‐based molecular gut‐content analysis. However, this technique may be prone to error from contamination of minute quantities of DNA; i.e., simply storing specimens together in a liquid medium may lead to cross‐contamination. In this study, we used PCR to determine the contamination rate when (1) specimens were stored together in 95% ethanol for various time periods, and (2) predators fall into ethylene glycol‐filled pitfall traps where the dying predator may inadvertently consume prey DNA‐contaminated liquid. We designed experiments and PCR primers to quantify the risk of contamination for both situations and found no contamination by storing specimens together in 95% ethanol. Furthermore, zero predators contained prey DNA in their gut contents from imbibing prey DNA‐contaminated ethylene glycol. These results support the use of mass sampling techniques, like wet pitfall traps, for molecular gut‐content analysis.     

Assessment of bacterial community structure in the deep sub-seafloor biosphere by 16S rDNA-based techniques: a cautionary tale

Investigations into the deep marine environment have demonstrated the presence of a significant microbial biomass buried deep within sediments on a global scale. It is now believed that this deep biosphere plays a major role in the global cycling of elements and contains a large reservoir of organic carbon. This paper reports the development of a DNA extraction protocol that addresses the particular problems faced in applying molecular ecological techniques to samples containing very low biomass. Sediment samples were collected from different geographical locations within the Pacific Ocean and include the Ocean Drilling Program (ODP) Leg 190, Nankai Trough Accretionary Prism. Seven DNA extraction protocols were tested and a commercially available DNA extraction kit with modifications was shown to produce higher yields of polymerase chain reaction (PCR)-amplifiable DNA than standard laboratory methods. Denaturing gradient gel electrophoresis (DGGE) analysis of 16S rRNA gene diversity revealed that template DNA from these extremely low biomass sediment samples was susceptible to PCR bias and random amplification. We propose that it is essential to screen 16S rRNA gene products for bacterial diversity by DGGE or other rapid fingerprinting methods, prior to their use in establishing a representative clone library of deep sub-seafloor bacteria. This represents a cautionary approach to analysis of microbial diversity in such sub-seafloor ecosystems.     

Novel method for preparation of the template DNA and selection of primers to differentiate the material rice cultivars of rice wine by PCR

As many rice wine brewers label the name of the cultivar of the material rice, authentication technology is necessary. The problems are (1) decomposition of DNAs during the fermentation, (2) contamination of DNAs from microorganisms, (3) co-existence of PCR inhibitors, such as polyphenols. The present authors improved the PCR method by (1) lyophilizing and pulverizing the rice wine to concentrate DNAs, (2) decomposition of starches and proteins so as not to inhibit DNA extraction by the use of heat-resistant amylase and proteinase K, (3) purification of the template DNA by the combination of CTAB method and fractional precipitation by 70% EtOH. To prevent the amplification of microorganism's DNAs during PCR, the present authors selected the suitable plant-specific primers. It became possible to prepare the template DNAs for PCR from the rice wine. The sequences of the amplified DNAs by PCR were ascertained to be same with those of material rice. Mislabeling of material rice cultivar was detected by PCR using the commercial rice wine. It became possible to extract and purify the template DNAs for PCR from the rice wine and to differentiate the material rice cultivars by the PCR using the rice wine as a sample.     

Minimizing DNA contamination by using UNG-coupled quantitative real-time PCR on degraded DNA samples: application to ancient DNA studies

PCR analyses of ancient and degraded DNA suffer from their extreme sensitivity to contamination by modern DNA originating, in particular, from carryover contamination with previously amplified or cloned material. Any strategy for limiting carryover contamination would also have to be compatible with the particular requirements of ancient DNA analyses. These include the need (i) to amplify short PCR products due to template fragmentation; (ii) to clone PCR products in order to track possible base misincorporation resulting from damaged templates; and (iii) to avoid incomplete decontamination causing artifactual sequence transformation. Here we show that the enzymatic decontamination procedures based upon dUTP- and uracil-N-glycosylase (UNG) can be adapted to meet the specific requirements of ancient DNA research. Thus, efficiency can be improved to vastly reduce the amplification of fragments < or = 100 bp. Secondly, the use of an Escherichia coli strain deficient in both UNG and dUTPase allows for the cloning of uracil-containing PCR products and offers protection from plasmid DNA contamination, and, lastly, PCR products amplified from UNG-degraded material are free of misleading sequence modifications.