Dilute-'N'-Go dideoxy sequencing of all DNA strands generated in multiplex LATE-PCR assays.

We have recently described a Dilute-'N'-Go protocol that greatly simplifies preparation and sequencing of both strands of an amplicon generated using linear-after-the-exponential (LATE)-PCR, an advanced form of asymmetric PCR . The same protocol can also be used to sequence all limiting primer strands in a multiplex LATE-PCR, by adding back each of the depleted limiting primers to a separate aliquot of the multiplex reaction. But, Dilute-'N'-Go sequencing cannot be used directly to sequence each of the excess primer strands in the same multiplex reaction, because all of the excess primers are still present at high concentration. This report demonstrates for the first time that it is possible to sequence each of the excess primer strands using a modified Dilute-'N'-Go protocol in which blockers are added to prevent all but one of the excess primers serving as the sequencing primer in separate aliquots. The optimal melting temperatures, positions and concentrations of blockers relative to their corresponding excess primers are defined in detail. We are using these technologies to measure DNA sequence changes in mitochondrial genomes that accompany aging and exposure to certain drugs.

Advancing a rapid, high throughput screening platform for optimization of lentivirus production.

BACKGROUND: Lentiviral vectors (LVVs) hold great promise as delivery tools for gene therapy and chimeric antigen receptor T cell (CAR-T) therapy. Their ability to target difficult to transfect cells and deliver genetic payloads that integrate into the host genome makes them ideal delivery candidates. However, several challenges remain to be addressed before LVVs are more widely used as therapeutics including low viral vector concentrations and the absence of suitable scale-up methods for large-scale production. To address these challenges, we have developed a high throughput microscale HEK293 suspension culture platform that enables rapid screening of conditions for improving LVV productivity. KEY RESULTS: High density culture (40 million cells mL-1 ) of HEK293 suspension cells in commercially available media was achieved in microscale 96-deep well plate platform at liquid volumes of 200 µL. Comparable transfection and LVV production efficiencies were observed at the microscale, in conventional shake flasks and a 1-L bioreactor, indicating that significant scale-down does not affect LVV concentrations and predictivity of scale-up. Optimization of production step allowed for final yields of LVVs to reach 1.5 × 107  TU mL-1 . CONCLUSIONS: The ability to test a large number of conditions simultaneously with minimal reagent use allows for the rapid optimization of LVV production in HEK293 suspension cells. Therefore, such a system may serve as a valuable tool in early stage process development and can be used as a screening tool to improve LVV concentrations for both batch and perfusion based systems.

Farm Management Effects on Rhizosphere Colonization by Native Populations of 2,4-Diacetylphloroglucinol-Producing Pseudomonas spp. and Their Contributions to Crop Health.

ABSTRACT Analyses of multiple field experiments indicated that the incidence and relative abundance of root-colonizing phlD+ Pseudomonas spp. were influenced by crop rotation, tillage, organic amendments, and chemical seed treatments in subtle but reproducible ways. In no-till corn plots, 2-year rotations with soybean resulted in plants with approximately twofold fewer phlD+ pseudomonads per gram of root, but 3-year rotations with oat and hay led to population increases of the same magnitude. Interestingly, tillage inverted these observed effects of cropping sequence in two consecutive growing seasons, indicating a complex but reproducible interaction between rotation and tillage on the rhizosphere abundance of 2,4-diacetlyphloroglucinol (DAPG) producers. Amending conventionally managed sweet corn plots with dairy manure compost improved plant health and also increased the incidence of root colonization when compared with nonamended plots. Soil pH was negatively correlated to rhizosphere abundance of phlD+ pseudomonads in no-till and nonamended soils, with the exception of the continuous corn treatments. Chemical seed treatments intended to control fungal pathogens and insect pests on corn also led to more abundant populations of phlD in different tilled soils. However, increased root disease severity generally was associated with elevated levels of root colonization by phlD+ pseudomonads in no-till plots. Interestingly, within a cropping sequence treatment, correlations between the relative abundance of phlD and crop stand or yield were generally positive on corn, and the strength of those correlations was greater in plots experiencing more root disease pressure. In contrast, such correlations were generally negative in soybean, a difference that may be partially explained by difference in application of N fertilizers and soil pH. Our findings indicate that farming practices can alter the relative abundance and incidence of phlD+ pseudomonads in the rhizosphere and that practices that reduce root disease severity (i.e., rotation, tillage, and chemical seed treatment) are not universally linked to increased root colonization by DAPG-producers.

Single-molecule LATE-PCR analysis of human mitochondrial genomic sequence variations.

It is thought that changes in mitochondrial DNA are associated with many degenerative diseases, including Alzheimer's and diabetes. Much of the evidence, however, depends on correlating disease states with changing levels of heteroplasmy within populations of mitochondrial genomes, rather than individual mitochondrial genomes. Thus these measurements are likely to either overestimate the extent of heteroplasmy due to technical artifacts, or underestimate the actual level of heteroplasmy because only the most abundant changes are observable. In contrast, Single Molecule (SM) LATE-PCR analysis achieves efficient amplification of single-stranded amplicons from single target molecules. The product molecules, in turn, can be accurately sequenced using a convenient Dilute-'N'-Go protocol, as shown here. Using these novel technologies we have rigorously analyzed levels of mitochondrial genome heteroplasmy found in single hair shafts of healthy adult individuals. Two of the single molecule sequences (7% of the samples) were found to contain mutations. Most of the mtDNA sequence changes, however, were due to the presence of laboratory contaminants. Amplification and sequencing errors did not result in mis-identification of mutations. We conclude that SM-LATE-PCR in combination with Dilute-'N'-Go Sequencing are convenient technologies for detecting infrequent mutations in mitochondrial genomes, provided great care is taken to control and document contamination. We plan to use these technologies in the future to look for age, drug, and disease related mitochondrial genome changes in model systems and clinical samples.

Monoplex/multiplex linear-after-the-exponential-PCR assays combined with PrimeSafe and Dilute-'N'-Go sequencing.

This protocol describes the design and execution of monoplex and multiplex linear-after-the-exponential (LATE)-PCR assays using a novel reagent, PrimeSafe, that suppresses all forms of mispriming. LATE-PCR is an advanced form of asymmetric amplification that uses a limiting primer and an excess primer for efficient exponential amplification of double-stranded DNA, followed by linear amplification of one strand. Each single-stranded amplicon can be quantitatively detected in real time or at end point. By separating primer annealing from product detection, LATE-PCR enables product analysis at low temperatures. Alternatively, each single strand can be sequenced by a convenient Dilute-'N'-Go procedure. Amplified samples are diluted with individual sequencing primers without the use of columns or spins. We have amplified and then sequenced 15 different single-stranded products generated in a single multiplexed LATE-PCR comprised of 15 pairs of unrelated primers. Dilute-'N'-Go dideoxy sequencing is more convenient, faster and less expensive than sequencing double-stranded amplicons generated via conventional symmetric PCR. The preparation of LATE-PCR products for Dilute-'N'-Go sequencing takes only 30 seconds.