Liquid chromatography mass spectrometry based characterization of epitope configurations.

Here we evaluate a quick and easy tool for determination of epitope configuration using immunocapture and liquid chromatography mass spectrometry (LC-MS) subsequent to pre-treatment of the target protein to disrupt its three-dimensional structure. The approach can be a valuable screening tool to identify antibodies that can be used in peptide capture by anti-protein antibodies. The experimental set-up was established using seven monoclonal antibodies (mAbs) with known linear or conformational epitope recognition. The mAbs were developed to target either of the two biomarkers, progastrin releasing peptide (ProGRP) or human chorionic gonadotropin (hCG). Best coherence with established epitope configuration was seen when using both denaturation, reduction and alkylation as pre-treatment method of the proteins (≥70% reduction in MS signal intensity compared to control) prior to immunocapture and LC-MS determination. The final method was used to determine the epitope configuration of four anti-thyroglobulin mAbs with unknown epitope configuration; all four mAbs showed configurational epitope recognition. These results were also supported by western blots of native, and reduced and alkylated protein using three of the evaluated mAbs, and by analysis native, and reduced and alkylated protein in a routine immunofluorometric assay employing the four evaluated antibodies.

Dysregulation of MITF Leads to Transformation in MC1R-Defective Melanocytes.

The MC1R/cAMP/MITF pathway is a key determinant for growth, differentiation, and survival of melanocytes and melanoma. MITF-M is the melanocyte-specific isoform of Microphthalmia-associated Transcription Factor (MITF) in human melanoma. Here we use two melanocyte cell lines to show that forced expression of hemagglutinin (HA) -tagged MITF-M through lentiviral transduction represents an oncogenic insult leading to consistent cell transformation of the immortalized melanocyte cell line Hermes 4C, being a melanocortin-1 receptor (MC1R) compound heterozygote, while not causing transformation of the MC1R wild type cell line Hermes 3C. The transformed HA-tagged MITF-M transduced Hermes 4C cells form colonies in soft agar and tumors in mice. Further, Hermes 4C cells display increased MITF chromatin binding, and transcriptional reprogramming consistent with an invasive melanoma phenotype. Mechanistically, forced expression of MITF-M drives the upregulation of the AXL tyrosine receptor kinase (AXL), with concomitant downregulation of phosphatase and tensin homolog (PTEN), leading to increased activation of the PI3K/AKT pathway. Treatment with AXL inhibitors reduces growth of the transformed cells by reverting AKT activation. In conclusion, we present a model system of melanoma development, driven by MITF-M in the context of MC1R loss of function, and independent of UV exposure. This model provides a basis for further studies of critical changes in the melanocyte transformation process.

Enhancing nucleic acid delivery by photochemical internalization.

Photochemical internalization (PCI) is a method for releasing macromolecules from endosomal and lysosomal compartments. The PCI approach uses a photosensitizer that localizes to endosomal and lysosomal compartments, and a light source with appropriate light spectra for excitation of the photosensitizer. Upon photosensitizer excitation, endosomal and lysosomal membranes are destroyed, due to the formation of reactive oxygen species, followed by release of the endocytosed material. PCI has been demonstrated to enhance and control (site- and time-specific) delivery of various macromolecules such as viruses, proteins, chemotherapeutics, nucleic acid, and so on. In this Review we present past and current studies of PCI-controlled delivery of natural and artificial nucleic acids, such as peptide nucleic acids, siRNA molecules, mRNA molecules and plasmids. We also discuss critical aspects to further the possibilities for successful gene targeting in space and time.

Light-induced mRNA transfection.

mRNA-based transfection is an attractive strategy for manipulation of gene expression for gain-of-function studies and therapeutic applications. As a potential therapeutic regulator, mRNA transfection has mainly been hampered by poor delivery strategies, combined with lack of specific targeting to the intended tissue(s) or cells. In this chapter, we describe a protocol for light-induced mRNA transfection into human cancer cell lines with the benefit for time- and site-specific mRNA targeting. Light-induced mRNA transfection is achieved by delivering mRNA molecules into endosomal and lysosomal vesicles. Subsequently, a photosensitizer (PS) localized in the membranes of these vesicles is used to induce damage, resulting in release of mRNA molecules into the cytosol. The main benefit of the strategy proposed is the possibility for protein production from the delivered mRNA in a way that is controllable in a time- and site-specific manner.

Evaluation of biodegradable peptide carriers for light-directed targeting.

A promising strategy for increased intracellular delivery of nucleic acids with the benefit for targeting is photochemical internalization (PCI). PCI relies on the use of a photosensitizing compound that photochemically destroys membranes in the endocytic pathway after illumination, resulting in cytosolic transfer of endosomal content. PCI technology combined with biodegradable polyamino acid carriers and nucleic acids delivers effective targeting and improved biosafety. In an in vitro model system, we have evaluated various poly-l-lysine (PLL), poly-l-histidine (PLH), and poly-l-arginine (PLA) formulations for light-directed small interference RNA (siRNA) gene silencing and messenger RNA (mRNA) delivery. We find that PLA formulations are suitable as siRNA and mRNA carriers in a strictly light-directed manner.

Light-controlled modulation of gene expression using polyamidoamine formulations.

A promising method that offers both time- and site-specific delivery of macromolecules is photochemical internalization technology (PCI). Here, we have characterized various polyamidoamine (PAMAM) carriers [generation (G) 0-7], for light-directed delivery of nucleic acids in vitro by the use of PCI technology. A number of parameters for optimal delivery of nucleic acids into human cancer cells, that is, various light-doses, carrier-doses, and small interfering RNA (siRNA)/messenger RNA (mRNA) doses were investigated for either up- or down-regulation of enhanced green fluorescent protein (EGFP) gene expression. In summary, our results showed in an osteosarcoma cell line (OHS) [EGFP] model system the possibility for efficient light-directed siRNA silencing (>80% silencing) when using PAMAM G3 to G7 as carriers. Surprisingly, no EGFP mRNA up-regulation was detected either with or without PCI after EGFP mRNA/PAMAM (G0-G7) transfection in standard OHS cells. We have here identified properties for PAMAM formulations enabling light-directed siRNA delivery with the aim of developing a site-specific strategy for delivery of nucleic acids in vivo.

Potent gene silencing in vitro at physiological pH using chitosan polymers.

Among non-viral cationic polymers, biodegradable chitosan has during the last decade become an attractive carrier for small interference RNA (siRNA) delivery. Currently, degradation of macromolecules in the lysosomes is assumed to be a major barrier for effective siRNA transfection. Hence, transfection protocols are focused toward endosomal release mechanisms. In this work, we have tested 3 novel chitosan polymers and their siRNA delivery properties in vitro. To obtain efficient gene silencing of our model gene, S100A4, various transfection parameters were investigated, such as pH, nitrogen/phosphate ratio, photochemical internalization (PCI), media for complex formation, and cell lines. Our results showed that 2 linear chitosan polymers demonstrated excellent siRNA gene silencing, better than Lipofectamine 2000. The silencing effect was achieved without PCI treatment, under physiological pH, and with no observable reduction in cell viability.

Cyclodextrin-containing polymer delivery system for light-directed siRNA gene silencing.

In this study, we have investigated the possibility of combining a cyclodextrin-containing polymer (CDP) with siRNA molecules to modulate gene expression in a light-directed manner through photochemical internalization (PCI) technology. We utilized S100A4 as a model gene to evaluate the efficacy of gene silencing. After optimization of carrier/cargo ratio and illumination dose, real-time reverse transcriptase-polymerase chain reaction data showed between 80% and 90% silencing in the siRNA samples treated with PCI compared with untreated control. In contrast, only a 0%-10% silencing effect was detected in the siRNA samples without PCI treatment, demonstrating the potency of light-specific delivery of siRNA molecules. Light-directed siRNA delivery was shown in 2 different cell lines with corresponding potency. Further, time-lapse results demonstrated maximum gene silencing only at 5 hours after endosomal release, implying, for example, rapid carrier decondensation when using the CDP. This work represents a first success in using a CDP delivery agent, without endosomolytic properties for siRNA gene silencing in a light-directed manner, opening the opportunity to use CDPs for light-directed siRNA gene silencing in vivo.