Detection of intra-articular gene therapy in horses using quantitative real time PCR in synovial fluid and plasma.

Gene therapy promotes the expression of missing or defective genes and can be curative following administration of a single dose. Gene therapy is prohibited in equine athletes by regulatory bodies due to the high potential for abuse and novel analytical methods are needed for detection. The goal of this study was to detect the administration of an experimental gene therapy: a recombinant adeno-associated viral vector (rAAV) carrying a transgene for the anti-inflammatory cytokine IL-10 (rAAV-IL10). Twelve horses were randomly assigned to receive an intra-articular injection of rAAV-IL10 or phosphate buffered saline (vehicle) into a middle carpal joint. Plasma and synovial fluid were collected on days 0, 1, 2, 4, 7, 14, 28, 56, and 84. Primer pairs were designed to detect two unique regions of rAAV. Using quantitative real time PCR, both sets of primers detected rAAV for 14-28 days in joints and up to 4 days in plasma, in all six treated horses. In synovial fluid, rAAV was detected on day 56 in 4/6 horses by both primer sets, and on day 84 in 1/6 horses by one primer set. In plasma, rAAV was detected for 7 days in 5/6 horses, 14 days in 2/6 horses, and 28 days in 1/6 horses by one primer set, and was detected for up to 14 days in 1/6 horses by the other primer set. This study is the first to validate that quantitative real time PCR can be used to systemically detect the local administration of a gene therapy product to horses.

[The usefulness of SNP markers for analyses of highly degraded biological materials]. / Przydatnosc markerów SNP do analiz materialu biologicznego o wysokim stopniu degradacji.

The most common cause of problems associated with analyzing DNA extracted from forensic samples is their high level of degradation. Such difficulties are caused by the fact that STR markers have too large amplicon sizes to be amplified in degraded DNA samples. Thus, it is necessary to employ more efficient markers for analyzing evidential samples. SNPs are ideal tools for such purposes, for the SNP genotyping method does not require large amplicon size, and thus increases the possibility of amplifying degraded DNA samples. Although single SNP is not polymorphic enough, we can obtain sufficient results by examining several SNPs. The aim of this study was to examine the usefulness of the SNP-pentaplex (rs2294067, rs2282160, rs2070764, rs2277216, rs1063739) for forensic applications by analysing several forensic cases, which were impossible to solve in a range of STR markers because of highly degraded DNA. DNA fragments were amplified in one multiplex PCR reaction, which contained 5 primer pairs. SNPs were subsequently identified in a minisequencing reaction and gel electrophoresis in an ABI Prism 377 Sequencer. The research confirmed the usefulness of SNP-pentaplex for forensic applications. Despite employing mainly degraded and low copy number DNA, full genetic profiles were obtained in almost every sample. Although the discrimination power of SNP-pentaplex is not sufficient for obtaining adequate evidential value, it seems to be an ideal screening method for forensic applications.

Genotyping patients with recent blood transfusions.

BACKGROUND: Many studies have used polymerase chain reaction amplification (PCR) to genotype for common polymorphisms in intensive-care units (ICUs) where blood transfusions are common. Evidence that donor leukocytes in transfused blood can be detected by PCR of the recipient blood suggests that this minor population of donor white cells (microchimerism) can interfere with genotyping of allelic polymorphisms in critically ill transfused patients. To investigate this possibility, we assayed DNA extracted from the blood and buccal cells of ICU patients for 2 common polymorphisms in the TNF-beta gene and the surfactant protein-B (SP-B) gene. METHODS: Study subjects were ICU patients from the Massachusetts General Hospital (Boston, MA) enrolled into a study on the molecular epidemiology of acute respiratory distress syndrome between January 1999 and October 2000. Blood and buccal cells were collected and DNA was extracted from 145 patients. Genotyping was performed by enzyme digestion and pyrosequencing. RESULTS: The Kappa statistics comparing the genotype results from blood and buccal cells were 0.98 (95% confidence interval [CI] = 0.94-1.01) for TNFB and 0.95 (CI = 0.87-1.02) for SP-B. When the analysis was restricted only to the 107 patients who were transfused, the Kappa statistic remained high at 0.97 (CI = 0.93-1.01) for TNFB and 0.93 (CI = 0.84-1.03) for SP-B. CONCLUSION: We conclude that microchimerism from allogeneic blood transfusion is unlikely to have major effects on the genotype results of common polymorphisms in large molecular epidemiology studies conducted in the critical care setting if DNA is collected within a day after transfusions.

Simultaneous genotyping of human platelet antigens (HPA) 1 through 6 using new sequence-specific primers for HPA-5.

BACKGROUND: Polymerase chain reaction using sequence-specific primers is widely used for genotyping human platelet antigens (HPA). However, the results of HPA-5 genotyping are still problematic. STUDY DESIGN AND METHODS: New sequence-specific primers were designed for HPA-5 that, together with already published primers, allow simultaneous genotyping of HPA-1, -2, -3, -4, -5, and -6. The reliability of the described protocol was determined by using reference DNA samples as well as samples from healthy blood donors. RESULTS: All primers produced specific amplification products. The genotype and the previously ascertained phenotype of the tested specimens were in concordance in all cases. CONCLUSION: The described polymerase chain reaction protocol allows rapid, reliable, simultaneous genotyping of HPA-1, -2, -3, -4, -5, and -6.

Identification of a 6 base pair insertion in West Highland White Terriers with erythrocyte pyruvate kinase deficiency.

OBJECTIVE: To define the disease-causing mutation in West Highland White Terriers (WHWT) with erythrocyte pyruvate kinase (R-PK) deficiency and to design a genetic test capable of recognizing affected (homozygous) and carrier (heterozygous) dogs. ANIMALS: 3 anemic WHWT littermates and 1 unaffected littermate; 16 dogs from the same kennel, including 4 unrelated, phenotypically normal dogs (control dogs), and 12 for which PK activity was not known; 2 PK-deficient Basenjis; 2 PK-deficient Beagles; 4 unaffected English Springer Spaniels; and 1 mixed-breed dog. PROCEDURES: cDNA was cloned and sequenced, and cDNA sequences were compared with the published sequence for canine R-PK cDNA to identify the putative disease-causing mutation. Genomic DNA spanning the affected region was cloned and sequenced to verify the mutation. Subsequently, polymerase chain reaction primers were designed to amplify the section of the gene containing the mutation from DNA in blood or buccal swab samples. Gel electrophoresis allowed assignment of genotypes on the basis of allele separation. RESULTS: 4 single base polymorphisms attributable to sequencing errors in the published sequence were identified, along with a 6 base pair (bp) insertion in exon 10 that was recognized as a putative disease-causing mutation. An identical insertion was found in genomic DNA. Amplification of genomic DNA yielded a 117 bp product for genotypically normal dogs and a 123 bp product for WHWT homozygous for PK deficiency. Carriers had 1 copy of each allele and variable heteroduplex structures. CONCLUSIONS AND CLINICAL RELEVANCE: A 6 bp insertion in the C domain of R-PK was identified in WHWT with PK deficiency. Affected and carrier dogs could be distinguished with a genetic test.