AmpFlSTR Profiler Plus and AmpFlSTR COfiler analysis of tissues stored in GenoFix, a new tissue preservation solution for mass disaster DNA identification.

A preliminary study was conducted to assess the capability of a new alcohol-based tissue fixative, GenoFix, to preserve DNA from biopsy tissues stored at room temperature and/or -20 degrees C in a freezer, for subsequent short tandem repeat (STR) DNA typing analysis. Fresh human smooth muscle samples were stored at room temperature in GenoFix for one month and up to one year and seven months before being processed using the megaplex STR systems, AmpFlSTR Profiler Plus and AmpFlSTR COfiler. Alternatively, muscle tissues in GenoFix were placed at -20 degrees C in a freezer for up to 3 1/2 years following two to three months in the fixative at room temperature. DNA analysis was also carried out on tissues stored in GenoFix for one month at room temperature and subsequently paraffin-embedded and stored at room temperature for four years. The AmpFlSTR Profiler Plus and AmpFlSTR COfiler STR profiles produced, using DNA extracted from all fixed tissue samples, were of very good quality. The fluorescent signals were well balanced across the nine STR loci or six loci comprised in the megaplexes surveyed and profiles showed no differences with those observed for the control blood of the respective donor patients. Continuous exposure to GenoFix at room temperature (up to one year and seven months) did not compromise the STR typing analysis of the fixed tissues. No adverse effects were noted on the STR typeability of tissues fixed with GenoFix and stored at -20 degrees C in a freezer for up to 3 1/2 years. STR profiles generated from the paraffin-embedded tissues fixed in GenoFix were of excellent quality. This preliminary study suggests that GenoFix can be used to store tissue samples at room temperature for up to one year and seven months or at -20 degrees C in a freezer for longer storage (up to 3 1/2 years). This new and odorless tissue fixative promotes tissue and DNA preservation in a very effective manner and as such may prove useful in criminal investigations or mass disaster identifications carried out in remote locations and in which a small or large number of tissue samples are collected for further analyses.

Fingerprint enhancement revisited and the effects of blood enhancement chemicals on subsequent profiler Plus fluorescent short tandem repeat DNA analysis of fresh and aged bloody fingerprints.

This study was aimed at determining the effect of seven blood enhancement reagents on the subsequent Profiler Plus fluorescent STR DNA analysis of fresh or aged bloody fingerprints deposited on various porous and nonporous surfaces. Amido Black, Crowle's Double Stain. 1,8-diazafluoren-9-one (DFO), Hungarian Red, leucomalachite green, luminol and ninhydrin were tested on linoleum, glass, metal, wood (pine, painted white), clothing (85% polyester/15% cotton, 65% polyester/35% cotton, and blue denim) and paper (Scott 2-ply and Xerox-grade). Preliminary experiments were designed to determine the optimal blood dilutions to use to ensure a DNA typing result following chemical enhancement. A 1:200 blood dilution deposited on linoleum and enhanced with Crowle's Double Stain generated enough DNA for one to two rounds of Profiler Plus PCR amplification. A comparative study of the DNA yields before and after treatment indicated that the quantity of DNA recovered from bloody fingerprints following enhancement was reduced by a factor of 2 to 12. Such a reduction in the DNA yields could potentially compromise DNA typing analysis in the case of small stains. The blood enhancement chemicals selected were also evaluated for their capability to reveal bloodmarks on the various porous and nonporous surfaces chosen in this study. Luminol. Amido Black and Crowle's Double Stain showed the highest sensitivity of all seven chemicals tested and revealed highly diluted (1:200) bloody fingerprints. Both luminol and Amido Black produced excellent results on both porous and nonporous surfaces, but Crowle's Double Stain failed to produce any results on porous substrates. Hungarian Red, DFO, leucomalachite green and ninhydrin showed lower sensitivities. Enhancement of bloodmarks using any of the chemicals selected, and short-term exposure to these same chemicals (i.e., less than 54 days), had no adverse effects on the PCR amplification of the nine STR systems surveyed (D3S 1358, HumvWA, HumFGA, D8S1179, D21S11, D18S51, D5S818, D13S317, D7S820) or of the gender determination marker Amelogenin. The intensity of the fluorescent signals was very similar and the allele size measurements remained constant and identical to those of untreated bloody fingerprints. No additional background fluorescence was noted. Continuous exposure (for 54 days) to two of the seven enhancement chemicals selected (i.e., Crowle's Double Stain and Hungarian Red) slightly reduced the amplification efficiency of the longer STR loci in profiles of fresh and 7 to 14-day-old bloodprints. This suggests that long-term exposure to these chemicals possibly affects the integrity of the DNA molecules. This study indicates that significant evidence can be obtained from fresh or aged bloody fingerprints applied to a variety of absorbent and nonabsorbent surfaces which are exposed to different enhancement chemicals for short or long periods of time. It also reaffirms that PCR STR DNA typing procedures are robust and provide excellent results when used in concert with fluorescence-based detection assays after fingerprint identification has taken place.

Validation of highly polymorphic fluorescent multiplex short tandem repeat systems using two generations of DNA sequencers.

Validation studies are a crucial requirement before implementation of new genetic typing systems for clinical diagnostics or forensic identity. Two different fluorescence-based multiplex DNA profiling systems composed of amelogenin, HumD21S11 and HumFGA (referred to as multiplex 1A), and HumD3S1358, HumD21S11 and HumFGA (multiplex 1B) have been evaluated for use in forensic identification using the Applied Biosystems Model 373A and Prism 377 DNA Sequencers, respectively. Experiments were aimed at defining the limit of target DNA required for reliable profiling, the level of degradation that would still permit amplification of the short tandem repeat (STR) loci examined, and the robustness of each locus in the multiplexes after samples were exposed to environmental insults. In addition, the specificity of the multiplexes was demonstrated using nonhuman DNAs. Forensically relevant samples such as cigarette butts, chewing gum, fingernails and envelope flaps were processed using both an organic extraction procedure and a QIAamp protocol. DNAs and resultant multiplex STR profiles were compared. The validation of the triplex STR systems was extended to include over 140 nonprobative casework specimens and was followed with a close monitoring of initial casework (over 300 exhibits). Our results document the robustness of these multiplex STR profiling systems which, when combined with other multiplex systems, could provide a power of discrimination of approximately 0.9999.

Population genetic characteristics of the STR Loci D21S11 and FGA in eight diverse human populations.

A highly polymorphic multiplex short tandem repeat (STR) system composed of D21S11, FGA, and the sex-typing system amelogenin (AMG) has been used to investigate allele frequency distributions in two Canadian Caucasian samples (British Columbia and Alberta), three Canadian aboriginal populations (Coastal Salishans from British Columbia, Ojibwa from northern Ontario, and Cree from Saskatchewan), and three ethnic groups from Singapore (Chinese, Malays, and Asian Indians). Using the automated fluorescence detection approach on an ABD 373A DNA Sequencer, we distinguished 20 D21S11 and 22 FGA alleles with a nearly equal representation of two- and four-base variants. An overlap in allele sizes for both STR loci across populations was observed, but frequency differences were noted. Statistical analysis revealed that (1) both D21S11 and FGA loci conform to Hardy-Weinberg equilibrium in all eight surveyed populations based on five different tests and (2) both STR loci are in linkage equilibrium. Results from the 2 x N contingency table exact tests for population differentiation demonstrated that the Canadian samples from two different provinces were not distinguishable from one another at either STR locus and therefore could be combined to form one Caucasian group. Likewise, Chinese and Malays from Singapore did not show significant differences at either STR locus. In contrast, all other examined populations exhibited differences deemed statistically significant. As a complement to our study, we compared D21S11 allele frequency distributions in 21 worldwide populations and FGA allele frequency distributions in 14 populations. Many alleles never previously reported in worldwide populations were identified in Canadian aboriginal and Asian samples from this study. Twenty-four D21S11 and 29 FGA alleles were distinguished in worldwide groups. Interesting similarities in allele frequency distribution patterns across populations suggest that the STR polymorphism at these loci predates the geographic dispersal of ancestral human populations. This study further demonstrates the utility of highly informative STR loci such as D21S11 and FGA in human population evolutionary history and in forensic medicine.

Interlaboratory comparison of autoradiographic DNA profiling measurements: precision and concordance.

Knowledge of the expected uncertainty in restriction fragment length polymorphism (RFLP) measurements is required for confident exchange of such data among different laboratories. The total measurement uncertainty among all Technical Working Group for DNA Analysis Methods laboratories has previously been characterized and found to be acceptably small. Casework cell line control measurements provided by six Royal Canadian Mounted Police (RCMP) and 30 U.S. commercial, local, state, and Federal forensic laboratories enable quantitative determination of the within-laboratory precision and among-laboratory concordance components of measurement uncertainty typical of both sets of laboratories. Measurement precision is the same in the two countries for DNA fragments of size 1000 base pairs (bp) to 10,000 bp. However, the measurement concordance among the RCMP laboratories is clearly superior to that within the U.S. forensic community. This result is attributable to the use of a single analytical protocol in all RCMP laboratories. Concordance among U.S. laboratories cannot be improved through simple mathematical adjustments. Community-wide efforts focused on improved concordance may be the most efficient mechanism for further reduction of among-laboratory RFLP measurement uncertainty, should the resources required to fully evaluate potential cross-jurisdictional matches become burdensome as the number of RFLP profiles on record increases.

Characterization of human lymphoid cell lines GM9947 and GM9948 as intra- and interlaboratory reference standards for DNA typing.

The incorporation of reference DNA is crucial to the validation of any DNA typing protocol. Currently, reference DNA standards are restricted to molecular size DNA ladders and/or tumor cell line DNA. Either of these, however, presents some limitations. We have rigorously characterized two Epstein-Barr virus (EBV)-immortalized human lymphoid cell lines--GM9947 (female) and GM9948 (male)--to determine their suitability as alternative in-line standards for three widely employed allele profiling strategies. Twenty-one highly polymorphic VNTR-based allelic systems (7 RFLPs, 2 AmpFLPs, and 12 STRs) distributed over 12 chromosomes were scrutinized along with 3 gender-based discriminatory systems. The genetic stability of each locus was confirmed over a period of 225 in vitro population doublings. Allele size estimates and degree of informativeness for each of the 21 VNTR systems were compiled. The reproducibility of allele scoring by traditional RFLP analyses, using both cell lines as reference standards, was also verified by an interlaboratory validation study involving 13 analysts from two geographically distinct forensic laboratories. Taken together, our data indicate that GM9947 and GM9948 genomic DNAs could be adopted as reliable reference standards for DNA typing.

DNA typing for bone marrow engraftment follow-up after allogeneic transplant: a comparative study of current technologies.

DNA typing is widely used to document engraftment after allogeneic bone marrow transplantation (BMT). Most DNA typing procedures discriminate allogeneic engraftment on the basis of DNA length polymorphisms or sequence variations found in variable number of tandem repeat (VNTR) loci, or the presence of Y chromosome-specific DNA We have compared 3 types of VNTR analysis, their respective mode of allele detection and Y chromosome DNA detection in order to assess the strengths and limitations of each approach. Chimerism was assessed in 8 recipients after allogeneic BMT. Samples were subjected to 6 restriction fragment length polymorphism (RFLP) loci-analysis using radioactivity, 2 amplified fragment length polymorphism (AmpFLP) loci-analysis using a silver-stain mode of detection, 12 short tandem repeat (STR) loci-analysis using fluorescence detection and Y chromosome analysis. We evaluated each procedure for its ability to (1) discriminate sibling donor-recipient pairs in our samples; (2) generate a concordant chimerism diagnosis; and (3) detect and assess the contribution of minority components in mixed-chimera situations. In sex-mismatched BMTs with a female graft donor, Y chromosome probing has proven most efficient. In all other cases, AmpFLPs proved to be a rapid and efficient procedure with sufficient discriminating capability and sensitivity to warrant their use in clinical settings. STRs are rapid as well but require a larger loci complement to discriminate efficiently and they do not currently detect, under our conditions, all mixed chimeras. RFLPs are clearly superior at discriminating siblings but are time-consuming and serve best in cases where AmpFLP and STR analyses fail.

DNA typing with fluorescently tagged short tandem repeats: a sensitive and accurate approach to human identification.

Human identification through DNA analysis has faced tremendous changes in the past seven years. The advent of the polymerase chain reaction (PCR) technology coupled with the discovery of amplifiable minisatellites and microsatellites known as amplified fragment length polymorphisms and short tandem repeats (STRs), respectively, allow allelic profiles to be obtained with minute amounts of target DNA even in a degraded state. Very recently, a new dimension in DNA typing analysis was opened with the development of instruments for automated real-time analysis of fluorescent amplification products. In order to derive an automated approach to DNA typing, STR systems were evaluated for sensitivity and accuracy using the Gene Scanner and compared to other DNA typing methods currently in use. Eight different STR systems (encompassing tri-, tetra- and pentanucleotide repeats) were investigated, and conditions for their amplification with fluorescence-tagged primers, resolution on polyacrylamide gels and analysis on a fluorescent DNA fragment analyzer were optimized. Using these conditions, discrete allelic profiles were obtained following amplification of DNA extracted from various cell lines, liquid blood, dry bloodstains and hair samples. Amplification from serial dilutions of template DNA indicated that the minimal amount of target DNA required to detect a fluorescent signal on the Gene Scanner for any of the eight STR systems examined is approximately 100 picograms. The level of precision obtained for real-time allele size determination was observed to be +/- 0.2 to 0.5 base pair (intragel) and +/- 0.5 to 1.5 base pairs (intergel). Consequently, PCR-based DNA typing with fluorescent STR primers and automated analysis provides the enhanced level of precision, accuracy and sensitivity required for forensic casework analysis. Moreover, this approach offers significant advantages for the routine processing of large numbers of DNA samples, greatly facilitates and expedites the generation of allelic profile databases and enables investigators to perform the simultaneous survey of several different loci from single individuals and/or forensic samples.

Sensitive and specific quantification of human genomic deoxyribonucleic acid (DNA) in forensic science specimens: casework examples.

We describe the forensic science application of a method for quantification of human genomic deoxyribonucleic acid (DNA). The two cases cited in this report involve DNA samples extracted from skin tissue and bloodstained clothing recovered from different crime scenes. High-molecular-weight DNA was recovered from both specimens, and the concentrations of these DNAs were estimated to be approximately 0.5 microgram/microL by ethidium bromide/agarose gel electrophoresis. Using the human-specific DNA probe p17H8 (locus D17Z1) to quantify the amount of human genomic DNA in these samples, it is shown that less than 1% of the DNA isolated from the skin tissue is of human origin and that the DNA isolated from the bloodstained clothing is effectively devoid of human DNA sequences. These case examples illustrate the need to quantify not only the total amount of DNA recovered from forensic casework material, but also the proportion of the DNA that is of human origin.

Fixed-bin analysis for statistical evaluation of continuous distributions of allelic data from VNTR loci, for use in forensic comparisons.

The detection of DNA polymorphisms by RFLP analysis is having a major impact on identity testing in forensic science. At present, this approach is the best effort a forensic scientist can make to exclude an individual who has been falsely associated with an evidentiary sample found at a crime scene. When an analysis fails to exclude a suspect as a potential contributor of an evidentiary sample, a means should be provided to assess suitable weight to the putative match. Most important, the statistical analysis should not place undue weight on a genetic profile derived from an unknown sample that is attributed to an accused individual. The method must allow for limitations in conventional agarose-submarine-gel electrophoresis and Southern blotting procedure, limited sample population data, possible subpopulation differences, and potential sampling error. A conservative statistical method was developed based on arbitrarily defined fixed bins. This approach permits classification of continuous allelic data, provides for a simple and portable data-base system, and is unlikely to underestimate the frequency of occurrence of a set of alleles. This will help ensure that undue weight is not placed on a sample attributed to an accused individual.

Determination of foreign gene copy number in stably transfected cell lines by southern transfer analysis.

The quantitative appraisal of the number of foreign gene copies integrated within the genomes of stably transfected cells is most conveniently performed using the strategy known as Southern blotting (1,2). First introduced by E. M. Southern in 1975 (2) the basic protocol involves the following steps: Size-fractionated DNA is first transferred from a gel matrix to a solid support under conditions that prevent self-annealing. The DNA molecules are then immobilized (covalently linked to the support) and processed for hybridization to a radiolabeled probe that has a nucleotide sequence complementing that of the target sequence to be detected. The blot is then washed extensively to remove unreacted probe molecules, and the hybrids formed between the probe and target sequences are revealed by autoradiography. The relative intensity of each autoradiographic signal will reflect the amount of hybridized material present. Quantification may be performed visually, by scanning laser densitometry, or, if the hybrids are sufficiently radioactive, by liquid scintillation counting.

Elevated c-myc messenger RNA in multiple myeloma cell lines.

Oncogene analyses of four human myeloma cell lines provided no indication of gene amplification or rearrangement using DNA probes for the met, raf, abl, mos, erb B, Her-2-neu, fos, myb-7, fms, L-myc, sis, and myb-1 genes. However, a consistent elevation of up to 23-fold in the level of c-myc mRNA was observed in all of the cell lines studied. No restriction fragment length polymorphism (in exons one, two, or three) or c-myc gene amplification has as yet been demonstrated to account for the c-myc mRNA elevation. The c-myc mRNA has a half-life of 25 min which is comparable to that observed in other systems. The elevation in c-myc mRNA is further evidence for the role of the c-myc proto-oncogene in the pathogenesis of myeloma.

Identification of complex DNA polymorphisms based on variable number of tandem repeats (VNTR) and restriction site polymorphism.

Restriction fragment length polymorphisms (RFLPs) of genomic DNA are generally attributable to base changes that create or abolish restriction endonuclease sites or to nucleotide sequence insertions or deletions that alter the distance separating two restriction sites. Minisatellite or variable number of tandem repeats (VNTR) markers are prominent examples of the latter type of polymorphism. In this report, we describe complex DNA polymorphisms that are due both to the presence of VNTRs as well as to altered restriction endonuclease sites. A strategy for identifying such polymorphisms and resolving their component allelic fragments is demonstrated.

Agarose gel electrophoresis of linear genomic DNA in the presence of ethidium bromide: band shifting and implications for forensic identity testing.

We demonstrate that agarose gel electrophoresis of linear duplex DNA in the presence of ethidium bromide has a marked effect on the mobility of genomic DNA fragments detected by Southern hybridization. Mobility shifts of greater than 6% of the actual molecular weight were detected when different amounts of the same DNA sample were analyzed in 1.0% agarose gels containing 0.5 micrograms ml-1 ethidium bromide. For forensic applications, shifts of this magnitude could complicate the task of comparing restriction fragment length polymorphism profiles and introduce a degree of uncertainty to allele frequency population databases.

A simple and sensitive method for quantifying human genomic DNA in forensic specimen extracts.

The analysis of DNA restriction fragment length polymorphisms by Southern blot hybridization requires that sufficient quantities of high molecular weight genomic DNA be extracted from biological specimens. Prior to analysis, it is necessary to determine the quantity and quality of the extracted DNA. For many applications, it is also desirable to determine the amount of DNA which is of human origin. In this report, we describe a simple and highly sensitive procedure for the specific quantification of human genomic DNA in forensic extracts or any biological sample. A small fraction of the extract is immobilized onto a nylon membrane and subsequently hybridized to p17H8 (D17Z1), a cloned probe which detects highly repetitive, primate-specific alpha satellite DNA. The procedure requires less than four hours to complete and can be used to quantify subnanogram amounts of hybridizable human genomic DNA.

Rapid DNA extraction and sensitive alkaline blotting protocol: application for detection of gene rearrangement and amplification for clinical molecular diagnosis.

A simple and sensitive DNA extraction/Southern blotting method is described for the routine detection of gene rearrangement and amplification in DNA samples. Significant features of the procedure are: (1) sequential digestion of RNA and protein in the same DNA buffer; and (2) use of a modified alkaline transfer protocol which increases sensitivity and decreases the autoradiographic exposure period. The method lends itself to handling multiple samples containing minimal amounts of starting material, requires equipment commonly found in a clinical laboratory, and yields results within 36 h of specimen receipt. Accordingly, these procedures may find utility in the establishment of molecular diagnostics in a conventional clinical setting.