S. A. M. Martins

Gene delivery to human bone marrow mesenchymal stem cells by microporation

Electroporation has been considered one of the most efficient non-viral based methods to deliver genes regardless of frequently observed high cell mortality. In this study we used a microporation technique to optimise the delivery of plasmid DNA encoding green fluorescence protein (GFP) to human bone marrow mesenchymal stem cells (BM-MSC). Using resuspension buffer (RB) and as low as 1.5 x 10⁵ cells and 1 μg of DNA, we achieved 40% of cells expressing the transgene, with cell recovery and cell viabilities of 85% and 90%, respectively. An increase in DNA amount did not significantly increase the number of transfected cells but clearly reduced cell recovery. A face-centered composite design was used to unveil the conditions giving rise to optimal plasmid delivery efficiencies when using a sucrose based microporation buffer (SBB). The BM-MSC proliferation kinetics were mainly affected by the presence of plasmid and not due to the microporation process itself although no effect was observed on their immunophenotypic characteristics and differentiative potential. Based on the data shown herein microporation demonstrated to be a reliable and efficient method to genetically modify hard-to-transfect cells giving rise to the highest levels of cell survival reported so far along with superior gene delivery efficiencies.

Application of central composite design for DNA hybridization onto magnetic microparticles

Central composite face-centered (CCF) design and response surface methodologies were used to investigate the effect of probe and target concentration and particle number in immobilization and hybridization on a microparticle-based DNA/DNA hybridization assay. The factors under study were combined according to the CCF design matrix, and the intensity of the hybridization signal was quantified by flow cytometry. A second-order polynomial was fitted to data and validated by analysis of variance. The results showed a complex relationship between variables and response given that all factors as well as some interactions were significant, yet it could explain 95% of the data. Probe and target concentration had the strongest impact on hybridization signal intensity. Increments in initial probe concentration in solution positively affected the hybridization signal until a negative influence of a compact probe layer emerged. This trend was attributed to probe-probe interactions. By manipulating particle number on both immobilization and hybridization, enhancements on the assay sensitivity could be obtained. Under optimized conditions, the limit of detection (LOD) at the 95% confidence level was determined to be 2.3 nM of target solution concentration.

Implementing a strategy for on-chip detection of cell-free DNA fragments using GMR sensors: A translational application in cancer diagnostics using ALU elements

Cell-free DNA (cfDNA) is foreseen as a promising source for liquid biopsies in cancer diagnostics. Despite its promise, methods available for its evaluation lack in robustness or, in the case of next-generation sequencing (NGS), are extremely sensitive but overly complex for routine operation. In contrast to NGS, integrated lab-on-chip devices offer advantages particularly in terms of automation, cost and speed. These devices, however, have rarely demonstrated the detection of biologically relevant DNA fragments originating from blood. To this end, we present a strategy for the magnetic labeling and detection of cfDNA fragments, using an array of 30 magnetoresistive (MR) sensors integrated in a portable biochip platform. As a proof-of-concept, we selected the fragments ALU115 and ALU247, recently identified as promising cancer targets in cfDNA integrity assessment. This work reveals a rational optimization of the DNA probes design and density at the surface which allowed achieving specific target detection and increased inhibition of unspecific interactions, without the need for blocking agents. The developed strategy is adaptable for the detection of mutations, homologous or truncated sequences such as the case of ALU115 and ALU247, sequences that share great similarity. Upon optimization, the MR sensors detected a concentration of the ALU elements within the picomolar range, showing potential for cfDNA analysis in cancer diagnostics.

The role of probe-probe interactions on the hybridization of double-stranded DNA targets onto DNA-modified magnetic microparticles.

AbstractIn this work, we have studied the effect of different probe lengths and surface densities on the hybridization of a 181-bp polymerase chain reaction product to probes tethered onto magnetic microparticles. Hybridization was shown to be favored by longer probes but only at probe surface densities where probe-to-probe interactions are absent. From these results, a simple rule was inferred for determining maximum surface densities above which hybridization signals decreased. According to this rule, if the average surface area occupied by an immobilized probe (Σ) is larger than the projected surface area of each tethered probe molecule (Sss), hybridization efficiency increases with surface density, whereas the reverse occurs when Σ −  Sss < 0.

Optimization of DNA Hybridization on Aminopropyl-Controlled Pore-Glass Particles: Detection of Non-Labeled Targets by PicoGreen Staining

A rapid and cost effective strategy was developed to detect the hybridization of DNA sequences, covalently attached to aminopropyl-controlled pore glass particles (ACPG) with non-labeled targets. The optimization of parameters, such as immobilization chemistry, hybridization time, and washing conditions, was first accomplished using a direct method based on the detection of fluorescein-labeled complementary targets. Under the optimized conditions, a methodology based on the post PicoGreen staining of the duplex molecules formed upon hybridization was demonstrated. This approach eliminates the requirements for pre-target labeling, while providing a rapid detection (less than 20 minutes) of specific complementary targets present in the solution.