Evaluation of buccal cell collection protocols for genetic susceptibility studies

Buccal cells are increasingly used as a source of quality DNA to improve participation rates in molecular studies. Here, three buccal cell collection protocols were compared to determine factors affecting the yield of cells, total DNA per sample, and DNA yield per cell. In addition, kinetic quantitative polymerase chain reaction (PCR) (TaqMan?) was used to quantify human DNA available for PCR. The method of collection used influenced the overall DNA yield per sample. The collection buffer used influenced the number of cells but not the overall DNA yield per sample. Repeated freezing and thawing did not affect overall DNA yield per sample, DNA yield per cell, or the total number of cells collected. Mouthwashes had the highest DNA yield per sample (20.8 μg) compared with cytobrush samples (1.9 μg from three cytobrushes) and tongue depressors (0.8 μg from three tongue depressors). However, mouthwash samples may contain significant non-human DNA and other contaminants that could interfere with some molecular studies. Spectrometry grossly overestimated the total DNA recovered from mouthwash samples compared with fluorometry or quantitative PCR.     

Effects of sample collection and storage conditions on DNA damage in buccal cells from agricultural workers

Buccal cells are becoming a widely used tissue source for monitoring human exposure to occupational and environmental genotoxicants. A variety of methods exist for collecting buccal cells from the oral cavity, including rinsing with saline, mouthwash, or scraping the oral cavity. Buccal cells are also routinely cryopreserved with dimethyl sulfoxide (DMSO), then examined later for DNA damage by the comet assay. The effects of these different sampling procedures on the integrity of buccal cells for measuring DNA damage are unknown. This study examined the influence of the collection and cryopreservation of buccal cells on cell survival and DNA integrity. In individuals who rinsed with Hank's balanced salt solution (HBSS), the viability of leukocytes (90%) was significantly (p<0.01) greater than that of epithelial cells (12%). Similar survival rates were found for leukocytes (88%) and epithelial cells (10%) after rinsing with Listerine(?) mouthwash. However, the viability of leukocytes after cryopreservation varied significantly (p<0.01) with DMSO concentration. Cell survival was greatest at 5% DMSO. Cryopreservation also influenced the integrity of DNA in the comet assay. Although tail length and tail moment were comparable in fresh or cryopreserved samples, the average head intensity for cryopreserved samples was ～6 units lower (95% CI: 0.8-12 units lower) than for fresh samples (t(25)=-2.36, p=0.026). These studies suggest that the collection and storage of buccal samples are critical factors for the assessment of DNA damage. Moreover, leukocytes appear to be a more reliable source of human tissue for assessing DNA damage and possibly other biochemical changes.     

工业化废水处理反应器污泥总DNA提取方法

根据工业化废水处理反应器污泥特性,对常规的溶菌酶-SDS-酚/氯仿环境样品总DNA提取方法进行改进,增强样品预处理,强化细胞裂解,提高杂质去除效率,获得了一种工业化污泥总DNA提取的通用方法,并采用该方法对石家庄若干实际运行的工业化厌氧、好氧反应器的污泥样品进行了总DNA提取研究.结果表明,该方法对所选污泥样品均有效,具有普适性.提取的污泥总DNA杂质含量少,纯度高,A260/A280在1.8左右;提取效率较高.总DNA产率都在0.7 mg/g以上,最大产率可达0.85 mg/g.所提取的污泥总DNA可以直接作为模板进行PCR反应,PCR产物直接进行变性梯度凝胶电泳(DGGE),能够得到较好的DGGE谱图,表明该方法提取的污泥总DNA样品可满足后续分析研究的要求.     

Application of sonication to release DNA from Bacillus cereus for quantitative detection by real-time PCR

A rapid sonication method for lysis of Gram-positive bacteria was evaluated for use in combination with quantitative real-time polymerase chain reaction (PCR) analyses for detection. Other criteria used for evaluation of lysis were microscopic cell count, colony forming units (cfu), optical density at 600 nm and total yield of DNA measured by PicoGreen fluorescence. The aim of this study was complete disruption of cellular structures and release of DNA without the need for lysing reagents and time-consuming sample preparation. The Gram-positive bacterium Bacillus cereus was used as a model organism for Gram-positive bacteria. It was demonstrated by real-time PCR that maximum yield of DNA was obtained after 3 to 5 min of sonication. The yield of DNA was affected by culture age and the cells from a 4-h-old culture in the exponential phase of growth gave a higher yield of DNA after 5 min of sonication than a 24-h-old culture in the stationary phase of growth. The 4-h-old culture was also more sensitive for lysis caused by heating. The maximum yield of DNA, evaluated by real-time PCR, from a culture of the Gram-negative bacterium Escherichia coli, was obtained after 20 s of sonication. However, the yield of target DNA from E. coli rapidly decreased after 50 s of sonication due to degradation of DNA. Plate counting (cfu), microscopic counting and absorbance at 600 nm showed that the number of viable and structurally intact B. cereus cells decreased rapidly with sonication time, whereas the yield of DNA increased as shown by PicoGreen fluorescence and real-time PCR. The present results indicate that 3-5 min of sonication is sufficient for lysis and release of DNA from samples of Gram-positive bacteria.     

DNA amplification to enhance detection of genetically engineered bacteria in environmental samples

The polymerase chain reaction (PCR) was performed to amplify a 1.0-kilobase (kb) probe-specific region of DNA from the herbicide-degrading bacterium Pseudomonas cepacia AC1100 in order to increase the sensitivity of detecting the organism by dot-blot analysis. The 1.0-kb region was an integral portion of a larger 1.3-kb repeat sequence which is present as 15 to 20 copies on the P. cepacia AC1100 genome. PCR was performed by melting the target DNA, annealing 24-base oligonucleotide primers to unique sequences flanking the 1.0-kb region, and performing extension reactions with DNA polymerase. After extension, the DNA was again melted, and the procedure was repeated for a total of 25 to 30 cycles. After amplification the reaction mixture was transferred to nylon filters and hybridized against radiolabeled 1.0-kb fragment probe DNA. Amplified target DNA was detectable in samples initially containing as little as 0.3 pg of target. The addition of 20 micrograms of nonspecific DNA isolated from sediment samples did not hinder amplification or detection of the target DNA. The detection of 0.3 pg of target DNA was at least a 10(3)-fold increase in the sensitivity of detecting gene sequences compared with dot-blot analysis of nonamplified samples. PCR performed after bacterial DNA was isolated from sediment samples permitted the detection of as few as 100 cells of P. cepacia AC1100 per 100 g of sediment sample against a background of 10(11) diverse nontarget organisms; that is, P. cepacia AC1100 was positively detected at a concentration of 1 cell per g of sediment. This represented a 10(3)-fold increase in sensitivity compared with nonamplified samples.     

DNA amplification to enhance detection of genetically engineered bacteria in environmental samples.

The polymerase chain reaction (PCR) was performed to amplify a 1.0-kilobase (kb) probe-specific region of DNA from the herbicide-degrading bacterium Pseudomonas cepacia AC1100 in order to increase the sensitivity of detecting the organism by dot-blot analysis. The 1.0-kb region was an integral portion of a larger 1.3-kb repeat sequence which is present as 15 to 20 copies on the P. cepacia AC1100 genome. PCR was performed by melting the target DNA, annealing 24-base oligonucleotide primers to unique sequences flanking the 1.0-kb region, and performing extension reactions with DNA polymerase. After extension, the DNA was again melted, and the procedure was repeated for a total of 25 to 30 cycles. After amplification the reaction mixture was transferred to nylon filters and hybridized against radiolabeled 1.0-kb fragment probe DNA. Amplified target DNA was detectable in samples initially containing as little as 0.3 pg of target. The addition of 20 micrograms of nonspecific DNA isolated from sediment samples did not hinder amplification or detection of the target DNA. The detection of 0.3 pg of target DNA was at least a 10(3)-fold increase in the sensitivity of detecting gene sequences compared with dot-blot analysis of nonamplified samples. PCR performed after bacterial DNA was isolated from sediment samples permitted the detection of as few as 100 cells of P. cepacia AC1100 per 100 g of sediment sample against a background of 10(11) diverse nontarget organisms; that is, P. cepacia AC1100 was positively detected at a concentration of 1 cell per g of sediment. This represented a 10(3)-fold increase in sensitivity compared with nonamplified samples.     

Validation of the determination of ΔF508 mutations of the cystic fibrosis gene in over 11000 mouthwashes

Mouthwashes can be used as a DNA resource for mutation detection and, because collection and DNA isolation is simple and cheap, they could in particular, be used for large numbers of samples. To determine the failure rate (the proportion of mouth samples in which no PCR product was obtained) and the specificity of buccal epithelial cell mutation detection in large numbers of samples, we collected mouthwashes and blood samples from 11413 blood donors and tested the mouthwashes for the F508 mutation, which has an estimated frequency of 75% among cystic fibrosis chromosomes in The Netherlands. Blood samples were tested for the F508 mutations only if the mutation was identified in the mouthwash or in the case of a failure to obtain PCR products. The sensitivity of the test was determined in mouthwashes of 75 F508 carriers known from earlier family studies. These samples were offered blindly between the mouthwashes of the blood donors. Both specificity and sensitivity of the mouthwash procedure were 100%. The overall failure rate was 5.6%. This large figure was caused mainly by insufficient rinsing of the mouth in one particular blood bank. Exclusion of the results of this blood bank reduced the failure rate to 1.8%. Our results also confirm that for a large number of samples the mouthwash procedure is suitable for mutation detection and, with proper instructions, can be used in community screening.     

Use of activated carbon coated with bentonite for increasing the sensitivity of pcr detection of Escherichia coli O157:H7 in Canadian oyster (Crassostrea gigas) tissue

A novel method for directly increasing the recovery of Escherichia coli O157:H7 and efficiently eliminating PCR inhibitors in oyster tissue without preenrichment was developed with the use of activated carbon coated with bentonite. The recovery of E. coli O157:H7 was significantly affected by the amount of bentonite used to coat the activated charcoal and the pH value of sample preparations. When 4.2 g of activated carbon were coated with 0.4 g of bentonite and seeded oyster samples were adjusted to a pH of 5.0, a high recovery of E. coli O157:H7 (91.6+/-4.4%) was obtained. Activated carbon, coated with bentonite, allowed the PCR detection of 1.5 x 10(2) CFU/g of oyster tissue which was equivalent to 30 genomic targets per PCR reaction. Without the use of activated carbon coated with bentonite, the minimum level of detection was 1.5 x 10(5) CFU/g of oyster tissue, which is equivalent to 3.0 x 10(4) genomic targets per PCR reaction. Three commercial DNA purification systems were used for comparison. The limit of detection with the Wizard DNA Clean-Up System and the Chelex(R)100 Resin was 1.5 x 10(3) CFU/g of oyster tissue which was equivalent to 3.0 x 10(2) CFU/PCR reaction. The QIAamp DNA Mini Kit resulted in a detection limit of 5 x 10(2) CFU/g of oyster tissue which was equivalent to 5 x 10(2) genomic targets per PCR reaction. The use of activated carbon coated with bentonite is an inexpensive method for removal of PCR inhibitors from tissue samples prior to the release of DNA from target cells resulting in relatively low numbers of target cells detected without enrichment.     

Risk assessment of false-positive quantitative real-time PCR results in food, due to detection of DNA originating from dead cells

Real-time PCR technology is increasingly used for detection and quantification of pathogens in food samples. A main disadvantage of nucleic acid detection is the inability to distinguish between signals originating from viable cells and DNA released from dead cells. In order to gain knowledge concerning risks of false-positive results due to detection of DNA originating from dead cells, quantitative PCR (qPCR) was used to investigate the degradation kinetics of free DNA in four types of meat samples. Results showed that the fastest degradation rate was observed (1 log unit per 0.5 h) in chicken homogenate, whereas the slowest rate was observed in pork rinse (1 log unit per 120.5 h). Overall results indicated that degradation occurred faster in chicken samples than in pork samples and faster at higher temperatures. Based on these results, it was concluded that, especially in pork samples, there is a risk of false-positive PCR results. This was confirmed in a quantitative study on cell death and signal persistence over a period of 28 days, employing three different methods, i.e. viable counts, direct qPCR, and finally floatation, a recently developed discontinuous density centrifugation method, followed by qPCR. Results showed that direct qPCR resulted in an overestimation of up to 10 times of the amount of cells in the samples compared to viable counts, due to detection of DNA from dead cells. However, after using floatation prior to qPCR, results resembled the viable count data. This indicates that by using of floatation as a sample treatment step prior to qPCR, the risk of false-positive PCR results due to detection of dead cells, can be minimized.     

Polymerase chain reaction for detection of Clostridium botulinum types A, B and E in food, soil and infant faeces

The application of the polymerase chain reaction (PCR) for detection of Clostridium botulinum types A, B and E in foods, environmental and clinical samples was evaluated and compared to the mouse bioassay. Samples inoculated with 10, 100 and 1000 spores of Cl. botulinum types A and B included pasteurized milk, UHT milk, infant formula, infant faeces, meat juice, canned tuna, mushrooms, blood sausage and soil. Clostridium botulinum type E spores were inoculated into fish eggs, canned tuna, picked herring, raw fish and soil at similar levels. Spores were added to 2.5 g of each sample with the exception of soil which was inoculated in 10 g samples. The presence of Cl. botulinum in sample enrichments was determined by both PCR and the bioassay. An overall correlation of 95.6% was observed between PCR results and the mouse bioassay. Of the total of 114 samples tested there was disparity between the mouse bioassay and the PCR in three samples of soil inoculated with 100 type A or E spores and 10 type B spores per 10 g, respectively, and two samples of infant faeces inoculated with 10 type A or B spores per 2.5 g. All of these samples gave negative animal results and positive PCR results.     

Quantitation of DNA in buccal cell samples collected in epidemiological studies

Abstract

Buccal cell samples are increasingly used in epidemiological studies as a source of genomic DNA. The accurate and precise quantitation of human DNA is critical for the optimal use of these samples. However, it is complicated by the presence of bacterial DNA and wide inter-individual variation in DNA concentration from buccal cell collections. The paper evaluated the use of ultraviolet light (UV) spectroscopy, Höechst (H33258) and PicoGreen? as measures of total DNA, and real-time quantitative polymerase chain reaction (PCR) as a measure of human amplifiable DNA in buccal samples. Using serially diluted white blood cell DNA samples (at a concentration range of 300 to 0.5?ng µl^?1), UV spectroscopy showed the largest bias, followed by Höechst, especially for low concentrations. PicoGreen and real-time PCR provided the most accurate and precise estimates across the range of concentrations evaluated, although an increase in bias with decreasing concentrations was observed. The ratio of real-time PCR to PicoGreen provided a reasonable estimate of the percentage of human DNA in samples containing known mixtures of human and bacterial DNA. Quantification of buccal DNA from samples collected in a breast cancer case-control study by PicoGreen and real-time PCR indicated that cytobrush and mouthwash DNA samples contain similar percentages of human amplifiable DNA. Real-time PCR is recommended for the quantification of buccal cell DNA in epidemiological studies since it provides precise estimates of human amplifiable DNA across the wide range of DNA concentrations commonly observed in buccal cell DNA samples.     

Toxoplasma gondii: detection by mouse bioassay, histopathology, and polymerase chain reaction in tissues from experimentally infected pigs

In the present study, we evaluated three techniques, mouse bioassay, histopathology, and polymerase chain reaction (PCR) to detect Toxoplasma gondii infection in tissues from experimentally infected pigs. Twelve mixed breed pigs, seronegative for T. gondii using an indirect immunofluorescent antibody test (IFAT), were used. Ten pigs were infected with 4 x 10(4) VEG strain oocysts, and two were maintained as uninfected controls. Animals were killed 60 days pos infection. Muscle (heart, tongue, diaphragm, and masseter) and brain samples were collected to investigate the presence of T. gondii tissue cysts by the different assay methods. For the bioassay, samples of brain (50 g) and pool of muscle samples (12.5 g of tongue, masseter, diaphragm, and heart) were used. PCR was performed using Tox4 and Tox5 primers which amplified a 529 bp fragment. The DNA extraction and PCR were performed three times, and all tissue samples were tested individually (brain, tongue, masseter, diaphragm, and heart). For histopathology, fragments of tissues were fixed in 10% of buffered formal saline and stained with HE. Histopathological results were all negative. PCR showed 25/150 (16.6%) positive samples, being 17/120 (14.1%) and 8/30 (26.6%) from muscle, and brain tissues, respectively. Tissue cysts of T. gondii were identified by mouse bioassay in 54/98 (55.1%) samples, being 31/48 (64.6%) from muscle samples, and 23/50 (46.0%) from brain samples. Toxoplasma gondii isolation in muscle samples by mouse bioassay was higher than in PCR (P<0.01). Results indicate that DNA from pig tissues interfered with 529-bp-PCR sensitivity, and mouse bioassay was better than PCR in detecting T. gondii in tissues from pigs.     

Rapid method for separation of bacterial DNA from humic substances in sediments for polymerase chain reaction.

The polymerase chain reaction (PCR) was used to amplify an Escherichia coli 16S ribosomal gene fragment from sediments with high contents of humic substances. Total DNA was extracted from 1 g of E. coli seeded or unseeded samples by a rapid freeze-and-thaw method. Several approaches (use of Bio-Gel P-6 and P-30 and Sephadex G-50 and G-200 columns, as well as use of the Stoffel fragment) were used to reduce interference with the PCR. The best results were obtained when crude DNA extracts containing humic substances were purified by using Sephadex G-200 spun columns saturated with Tris-EDTA buffer (pH 8.0). Eluted fractions were collected for PCR analyses. The amplified DNA fragment was obtained from seeded sediments containing fewer than 70 E. coli cells per g. Because only 1/100 of the eluted fractions containing DNA extracts from 70 cells per g was used for the PCR, the sensitivity of detection was determined to be less than 1 E. coli cell. Thus, DNA direct extraction coupled with this technique to remove interference by humic substances and followed by the PCR can be a powerful tool to detect low numbers of bacterial cells in environmental samples containing humic substances.     

Rapid method for separation of bacterial DNA from humic substances in sediments for polymerase chain reaction.

The polymerase chain reaction (PCR) was used to amplify an Escherichia coli 16S ribosomal gene fragment from sediments with high contents of humic substances. Total DNA was extracted from 1 g of E. coli seeded or unseeded samples by a rapid freeze-and-thaw method. Several approaches (use of Bio-Gel P-6 and P-30 and Sephadex G-50 and G-200 columns, as well as use of the Stoffel fragment) were used to reduce interference with the PCR. The best results were obtained when crude DNA extracts containing humic substances were purified by using Sephadex G-200 spun columns saturated with Tris-EDTA buffer (pH 8.0). Eluted fractions were collected for PCR analyses. The amplified DNA fragment was obtained from seeded sediments containing fewer than 70 E. coli cells per g. Because only 1/100 of the eluted fractions containing DNA extracts from 70 cells per g was used for the PCR, the sensitivity of detection was determined to be less than 1 E. coli cell. Thus, DNA direct extraction coupled with this technique to remove interference by humic substances and followed by the PCR can be a powerful tool to detect low numbers of bacterial cells in environmental samples containing humic substances.     

Detection of enterotoxigenic Clostridium perfringens in food and fecal samples with a duplex PCR and the slide latex agglutination test.

A duplex PCR procedure was evaluated for the detection of Clostridium perfringens in food and biological samples and for the identification of enterotoxigenic strains. This method uses two sets of primers which amplify in the same reaction two different DNA fragments simultaneously: the 283-bp C. perfringens phospholipase C gene fragment and the 426-bp enterotoxin gene fragment. Internal primers within the two primer sets confirmed the specificity of the method by DNA-DNA hybridization with the PCR products. No cross-reaction was observed with other Clostridium species or with other bacteria routinely found in food. The detection level was approximately 10(5) C. perfringens cells per g of stool or food sample. When overnight enrichment culture was used, 10 C. perfringens cells per g was detected in 57 artificially contaminated food samples. The duplex PCR is a rapid, sensitive, and reliable method for the detection and identification of enterotoxigenic C. perfringens strains in food samples. A slide latex agglutination test was also evaluated as a rapid, simple technique for the detection of C. perfringens enterotoxin in stool samples.     

Detection of Pseudomonas aeruginosa from clinical and environmental samples by amplification of the exotoxin A gene using PCR.

PCR was used to detect Pseudomonas aeruginosa from water samples by amplifying a 396-bp region of the exotoxin A (ETA) structural gene sequence. The identify of the amplified 396-bp fragment was confirmed by digesting it with PvuI restriction endonuclease, which produced the predicted 246- and 150-bp fragments. Specific primers amplified ETA-positive P. aeruginosa DNA, whereas other species of Pseudomonas and GC-rich bacteria did not yield any 396-bp fragment. The specificity and sensitivity of the assay were 100 and 96%, respectively, which confirms the assay's reliability for diagnostic and epidemiological studies. The assay can detect as few as 5 to 10 cells in a 10-ml water sample or 0.1 pg of P. aeruginosa DNA per reaction mixture (5 microliters) by ethidium bromide staining of an agarose gel. Ten-times-lower concentrations were detected by hybridization with a digoxigenin-labeled oligonucleotide probe internal to the PCR product. With this PCR method, ETA-positive P. aeruginosa was detected in animal cage water samples at a level of 40 cells per ml. This method is rapid and less cumbersome than other diagnostic methods for the identification of P. aeruginosa strains. The method described can be used to detect a low level of P. aeruginosa from environmental and clinical samples without the use of selective media or additional biochemical tests.     

Effective PCR detection of vegetative and dormant bacterial cells due to a unified method for preparation of template DNA encased within cell envelopes

The unified method of template preparation for PCR in the form of DNA covered by permeabilized cell envelopes was used for the cells of different physiological status (vegetative, dormant forms of different types, and nonviable micromummies). The procedure for the preparation of template DNA included one-stage (boiling in a buffer with chaotropic salts) or two-stage (boiling in a buffer with chaotropic salts followed by treatment with proteinase K) sample preparation. The proposed method proved effective for detection of not only vegetative cells but also of the bacillary spores and the cystlike dormant cells (CLC) of non-spore-forming bacteria. For example, the two-stage sample preparation of Bacillus cereus spores resulted in the PCR sensitivity increase up to the detection level of 3–30 spores per sample; the one-stage sample preparation was three orders of magnitude less efficient (10₄ spores per sample). An increase in the sensitivity of PCR detection (4–10-fold) owing to the use of the two-stage sample preparation was shown for bacillary, staphylococcal, and mycobacterial CLC. The possibility of PCR detection of staphylococcal micromummies with irreversibly lost viability, which were therefore undetectable by plating techniques, was also demonstrated. The application of the unified sample preparation method ensuring efficacious PCR detection of bacterial cells, irrespective of their physiological state, may be a promising approach to more complete detection of microbial diversity and the overall insemination of natural substrates.     

Akonni TruTip? and Qiagen? Methods for Extraction of Fetal Circulating DNA - Evaluation by Real-Time and Digital PCR

Due to the low percentage of fetal DNA present in maternal plasma (< 10%) during early gestation, efficient extraction processes are required for successful downstream detection applications in non-invasive prenatal diagnostic testing. In this study, two extraction methods using similar chemistries but different workflows were compared for isolation efficiency and percent fetal DNA recovery. The Akonni Biosystems TruTip technology uses a binding matrix embedded in a pipette tip; the Circulating Nucleic Acids Kit from Qiagen employs a spin column approach. The TruTip method adds an extra step to decrease the recovery of DNA fragments larger than 600 bp from the sample to yield an overall higher percentage of smaller molecular weight DNA, effectively enriching for fetal DNA. In this evaluation, three separate extraction comparison studies were performed - a dilution series of fragmented DNA in plasma, a set of clinical maternal samples, and a blood collection tube time point study of maternal samples. Both extraction methods were found to efficiently extract small fragment DNA from large volumes of plasma. In the amended samples, the TruTip extraction method was ~15% less efficient with overall DNA recovery, but yielded an 87% increase in % fetal DNA relative to the Qiagen method. The average percent increase of fetal DNA of TruTip extracted samples compared to the Qiagen method was 55% for all sets of blinded clinical samples. A study comparing extraction efficiencies from whole blood samples incubated up to 48 hours prior to processing into plasma resulted in more consistent % fetal DNA recoveries using TruTip. The extracted products were tested on two detection platforms, quantitative real-time PCR and droplet digital PCR, and yielded similar results for both extraction methods.     

The contribution of bacteria to the total adenosine triphosphate extracted from the microbiota in the water of a salt-marsh creek

The contribution of bacteria to the total adenosine 5-triphosphate (ATP) measured in estuarine samples was investigated. A portion of the bacterial population present in samples was separated from other biological materials by filtration through a 1.0-μm filter (Nucleopore). The quantification of ATP and the enumeration of bacteria (by epifluorescence microscopy) was performed on filtered and unfiltered portions of each sample as well as on cultured organisms. The values of ATP per cell averaged 1.48 × 10⁻¹⁵ g/cell from laboratory cultures and generally two orders-of-magnitude lower in bacteria from the natural system with values ranging from 0.24 to 28.8 × 10⁻¹⁷ g/cell. In bacteria collected from the marsh waters, the higher values of ATP per cell were observed in samples collected during the warmer months. When samples were obtained from areas of the marsh influenced by oceanic waters, the highest values of ATP per cell were observed at low tide. The nucleotide levels in bacterial cells in the high marsh were not markedly influenced by the tides. Bacterial ATP contributed from < 1–83% of the ATP measured in the total microbiota; the average content was 25% of the total. Generally, waters from the high marsh i.e., water influenced strongly by sediment microbes, contained a greater percentage of bacterial ATP.     

An improved procedure for quantitating mitochondrial DNA in cultured mammalian cells

A new improved method that reproducibly measures small perturbations of mitochondrial DNA in populations of cells has been developed. It is based on first obtaining a cell count and then analyzing three aliquots of cells: one for total DNA per cell by fluorometry, one for total protein per cell and one for the amount of mitochondrial DNA per microgram of total cell DNA. To quantitate mitochondrial DNA, 0, 1, 2, and 3 nanograms of mouse mtDNA purified from a plasmid are added as internal standard DNA to four 1.0-microgram samples of purified total cell DNA containing an unknown amount of mitochondrial DNA (a sample set). Three sample sets are electrophoresed in an agarose gel devoid of ethidium bromide. Following Southern transfer to nitrocellulose and hybridization to purified 32P-labeled mouse mitochondrial DNA, an autoradiogram is prepared for use as a template to locate the mitochondrial DNA bands. These bands are cut out of the nitrocellulose filters, and their 32P-content is determined using a liquid scintillation counter. For each sample set, the counts per minute is plotted against the amount of mitochondrial DNA added. The plot is linear and the negative average of the values for the three intercepts on the x-axis yields the amount of nanograms of mitochondrial DNA per microgram of total cell DNA. The method is highly reproducible with a standard deviation of approximately 9 percent. The advantages of using this method over others that have been reported are discussed.