Detection of rendered meat and bone meals by PCR is dependent on animal species of origin and DNA extraction method.

The capability of eight commercially available DNA extraction kits to extract bovine DNA originating in meat and bone meal from fortified feed was evaluated. Four different batches of bovine meat and bone meal (BMBM) were used for DNA extraction with the eight commercial DNA extraction kits. Within each kit, there were minimal differences in the batch-to-batch amounts of extracted DNA. There were differences between the kits in the amounts of DNA that could be extracted from the same amount of starting BMBM. These differences did not translate into differences in the amount of amplifiable DNA from BMBM-fortified dairy feed. Using a validated real-time PCR method, the kit yielding the highest amount extractable DNA was completely unable to yield a positive PCR result; one other kit was also unable to produce a positive PCR result from DNA extracted from BMBM-fortified feed. There was a complete lack of a correlation between the amount of bovine DNA isolated from BMBM by a given extraction kit compared with the relative amounts of DNA isolated from fortified animal feed as evidenced by the cycle threshold values generated using the real-time PCR method. These results demonstrate that extraction of DNA from processed animal protein is different for pure ingredients and fortified animal feeds. These results indicate that a method specifically developed using just animal-derived meat and bone meal may not yield a functional assay when used to detect animal tissues in complete animal feed.

Development, evaluation, and peer verification of a rapid real-time PCR method for the detection of animal material.

Four real-time PCR assays that can be used with U.S.- and European Union-rendered materials to detect three ruminant species (bovine, caprine, and ovine) and a select set of avians (chicken, goose, and turkey) were developed. This method was evaluated against stringent acceptance criteria previously developed by the U.S. Food and Drug Administration, Center for Veterinary Medicine's Office of Research. Acceptance criteria for determining success used a statistical approach requiring a 90% probability of achieving the correct response, within a 95% confidence interval. A minimum detection level of 0.1% meat and bone meal (MBM) was required, consistent with the sensitivity of the validated PCR-based method currently used by the U.S. Food and Drug Administration as an aid in enforcement of the Agency's feed ban. PCR primer specificity was determined by using a panel of DNA samples derived from 16 different animal species. The method is able to detect 0.1% rendered material in complete feed in less than 1.5 h of total assay time, a significant improvement over the current method, which requires 7 to 8 h for completion. The real-time assay for the detection of animal material passed stringent acceptance criteria for sensitivity, selectivity, and specificity. The method also passed ruggedness, real-time platform, and second analyst trials. Two external laboratories participating in a peer-verification trial demonstrated 100% specificity in identifying bovine MBM, ovine MBM, or caprine meat meal, while exhibiting a 0.6% rate of false positives. These results demonstrated that this method was capable of being used by other laboratories.

Comprehensive DNA signature discovery and validation.

DNA signatures are nucleotide sequences that can be used to detect the presence of an organism and to distinguish that organism from all other species. Here we describe Insignia, a new, comprehensive system for the rapid identification of signatures in the genomes of bacteria and viruses. With the availability of hundreds of complete bacterial and viral genome sequences, it is now possible to use computational methods to identify signature sequences in all of these species, and to use these signatures as the basis for diagnostic assays to detect and genotype microbes in both environmental and clinical samples. The success of such assays critically depends on the methods used to identify signatures that properly differentiate between the target genomes and the sample background. We have used Insignia to compute accurate signatures for most bacterial genomes and made them available through our Web site. A sample of these signatures has been successfully tested on a set of 46 Vibrio cholerae strains, and the results indicate that the signatures are highly sensitive for detection as well as specific for discrimination between these strains and their near relatives. Our approach, whereby the entire genomic complement of organisms are compared to identify probe targets, is a promising method for diagnostic assay development, and it provides assay designers with the flexibility to choose probes from the most relevant genes or genomic regions. The Insignia system is freely accessible via a Web interface and has been released as open source software at: http://insignia.cbcb.umd.edu.

Potential use of DNA barcodes in regulatory science: applications of the Regulatory Fish Encyclopedia.

The use of a DNA-based identification system (DNA barcoding) founded on the mitochondrial gene cytochrome c oxidase subunit I (COI) was investigated for updating the U.S. Food and Drug Administration Regulatory Fish Encyclopedia (RFE; http://www.cfsan.fda.gov/-frf/rfe0.html). The RFE is a compilation of data used to identify fish species. It was compiled to help regulators identify species substitution that could result in potential adverse health consequences or could be a source of economic fraud. For each of many aquatic species commonly sold in the United States, the RFE includes high-resolution photographs of whole fish and their marketed product forms and species-specific biochemical patterns for authenticated fish species. These patterns currently include data from isoelectric focusing studies. In this article, we describe the generation of DNA barcodes for 172 individual authenticated fish representing 72 species from 27 families contained in the RFE. These barcode sequences can be used as an additional identification resource. In a blind study, 60 unknown fish muscle samples were barcoded, and the results were compared with the RFE barcode reference library. All 60 samples were correctly identified to species based on the barcoding data. Our study indicates that DNA barcoding can be a powerful tool for species identification and has broad potential applications.

Metastatic progression and gene expression between breast cancer cell lines from African American and Caucasian women.

African American (AA) women have a lower overall incidence of breast cancer than do Caucasian (CAU) women, but a higher overall mortality. Little is known as to why the incidence of breast cancer is lower yet mortality is higher in AA women. Many studies speculate that this is only a socio-economical problem. This investigation suggests the possibility that molecular mechanisms contribute to the increased mortality of AA women with breast cancer. This study investigates the expression of 14 genes which have been shown to play a role in cancer metastasis. Cell lines derived from AA and CAU patients were analyzed to demonstrate alterations in the transcription of genes known to be involved in cancer and the metastatic process. Total RNA was isolated from cell lines and analyzed by RT-PCR analysis. Differential expression of the 14 targeted genes between a spectrum model (6 breast cancer cell lines and 2 non-cancer breast cell lines) and a metastasis model (12 metastatic breast cancer cell lines) were demonstrated. Additionally, an in vitro comparison of the expression established differences in 5 of the 14 biomarker genes between African American and Caucasian breast cell lines. Results from this study indicates that altered expression of the genes Atp1b1, CARD 10, KLF4, Spint2, and Acly may play a role in the aggressive phenotype seen in breast cancer in African American women.

Comparative study of matrix metalloproteinase expression between African American and Caucasian Women.

To date there are 26 human matrix metalloproteinases (MMPs) which are classified according to their substrate specificity and structural similarities. The four major subgroups of MMPs are gelatinases, interstitial collagenases, stromelysins, and membrane-type matrix metalloproteinases (MT-MMPs). This study investigates the expression of 26 MMPs, which have been shown to play a role in cancer metastasis. Breast tissues and cell lines derived from African American patients and Caucasian patients were assayed to demonstrate alterations in the transcription of genes primarily responsible for degrading the extracellular matrix (ECM). The expression levels of the extracellular matrix and adhesion molecules were analyzed using the gene array technology. Steady state levels of mRNAs were validated by RT-PCR analysis. Total RNA was isolated from tissue and cell lines and used in the RT-PCR assays. From this data, differential expression of MMPs between 6 breast cancer cell lines and 2 non-cancer breast cell lines was demonstrated. We have performed an in vitro comparison of MMP expression and established differences in 12 MMPs (3, 7, 8, 9, 11-15, 23B, 26, and 28) expression between African American and Caucasian breast cell lines. Thus, evidence indicates that altered expression of MMPs may play a role in the aggressive phenotype seen in African American women.