Droplet Digital PCR Technology from Bio-Rad Proves Instrumental in Developing a Functional Cure for HIV
Product News: Droplet Digital PCR Technology from Bio-Rad Proves Instrumental in Developing a Functional Cure for HIV
23 Oct 2012
Bio-Rad Laboratories, Inc. has announced that its QX100 Droplet Digital PCR (ddPCR) system has enabled researchers at Sangamo BioSciences, Inc. to generate highly precise and reproducible data that puts the company one step closer to identifying a functional cure for HIV.
“The QX100 system allowed us to easily, accurately, and reproducibly measure low-copy events in genomic DNA,” said Dr. Gary Lee, senior scientist at Sangamo BioSciences. “ddPCR technology gave us confidence in our results, which is critical in advancing any program.”
Sangamo BioSciences utilizes a proprietary zinc-finger DNA-binding protein (ZFP) technology to modify the CCR5 gene, which encodes a major cell-surface co-receptor used by HIV to enter and infect CD4+ cells. The company engineered gene-editing ZFP nucleases (ZFNs) to permanently disrupt CCR5 in the immune cells (CD4+ T-cells) of HIV-positive (HIV+) patients, making these cells resistant to infection and thus potentially able to control the virus upon re-infusion into the patient. This revolutionary treatment employs each patient s own immune cells as an alternative to drug therapy.
Available data from HIV+ subjects in trials to date suggest that integration of HIV DNA into the host cell's genome is a rare event, occurring in only one cell per 1,000 100,000 CD4+ T-cells in peripheral blood. This apparently low level of HIV DNA in the CD4 compartment is known to sustain a low level of viral replication, especially in lymphoid tissues, even when free virus in the periphery has been eliminated by drug therapy. Therefore, one of the major challenges in Sangamo s research was to determine a way to measure the level of HIV DNA in a subject and thereby evaluate the effectiveness of the new therapy. Although real-time quantitative PCR (qPCR) is an effective technology for gene expression analysis, imperfect amplification efficiencies and the necessity of establishing a standard curve prevent qPCR from delivering the precision and sensitivity needed to detect rare target DNA sequences.
Droplet Digital PCR technology provides an absolute measure of target DNA and RNA molecules, offering far greater sensitivity, reproducibility, and precision than qPCR. The QX100 system partitions samples and reagents into 20,000 droplets, with target and background DNA randomly distributed among them. This partitioning reduces background interference, allowing for more reliable and sensitive measurement of single copies of a target sequence (with abundances as low as 0.0001% of background) within a complex sample. Due to the digital nature of the assay and the fact that no standard curve is required, ddPCR can discriminate differences in target DNA concentrations as low as 10%.
According to Dr. Lee, at low copy numbers in two separate assays, real-time PCR results indicated a tenfold difference, making it difficult to determine whether the data reflected experimental variation or biological reality. With ddPCR technology, the difference was shown to be only twofold.
“That’s data we can really trust,” said Lee.
The company is currently conducting two phase 2 clinical trials in HIV+ patients. The QX100 system will be instrumental in allowing Sangamo BioSciences to determine the effectiveness of its therapy in reducing HIV levels. Thus far, the clinical data demonstrate a statistically significant relationship between the number of modified T-cells and a reduction in viral load during an interruption of antiviral treatment.
“We have been able to demonstrate that the QX100 system is the technology of choice when it comes to rare-event detection applications, particularly in clinical studies,” said Dr. Lee.