Nicole M. Moore

Synergistic enhancement of human bone marrow stromal cell proliferation and osteogenic differentiation on BMP-2-derived and RGD peptide concentration gradients

Rational design of bioactive tissue engineered scaffolds for directing bone regeneration in vivo requires a comprehensive understanding of cell interactions with the immobilized bioactive molecules. In the current study, substrates possessing gradient concentrations of immobilized peptides were used to measure the concentration-dependent proliferation and osteogenic differentiation of human bone marrow stromal cells. Two bioactive peptides, one derived from extracellular matrix protein (ECM), GRGDS, and one from bone morphogenic protein-2 (BMP-2), KIPKASSVPTELSAISTLYL, were found to synergistically enhance cell proliferation, up-regulate osteogenic mRNA markers bone sialoprotein (BSP) and Runt-related transcription factor 2, and produce mineralization at densities greater than 130 pmol cm(-2) (65 pmol cm(-2) for each peptide). In addition, COOH-terminated self-assembled monolayers alone led to up-regulated BSP mRNA levels at densities above 200 pmol cm(-2) and increased cell proliferation from day 3 to day 14. Taking further advantage of both the synergistic potentials and the concentration-dependent activities of ECM and growth-factor-derived peptides on proliferative activity and osteogenic differentiation, without the need for additional osteogenic supplements, will enable the successful incorporation of the bioactive species into biorelevant tissue engineering scaffolds.

The use of immobilized osteogenic growth peptide on gradient substrates synthesized via click chemistry to enhance MC3T3-E1 osteoblast proliferation

In this study, we report the use of surface immobilized peptide concentration gradient technology to characterize MC3T3-E1 osteoblast cell response to osteogenic growth peptide (OGP), a small peptide found naturally in human serum at mumol/L concentrations. OGP was coupled to oxidized self assembled monolayer (SAM) gradients by a polyethylene oxide (PEO) linker using click chemistry. After 4h incubation with MC3T3-E1 cells, OGP functionalized surfaces had higher cell attachment at low peptide concentrations compared to control gradients. By day 3, OGP gradient substrates had higher cell densities compared to control gradients at all concentrations. MC3T3-E1 cell doubling time was 35% faster on OGP substrates relative to SAM gradients alone, signifying an appreciable increase in cell proliferation. This increase in cell proliferation, or decrease in doubling time, due to OGP peptide was reduced by day 7. Hence, immobilized OGP increased cell proliferation from 0 days to 3 days at all densities indicating it may be useful as a proliferative peptide that can be used in tissue engineering substrates.

The effect of endosomal escape peptides on in vitro gene delivery of polyethylene glycol-based vehicles.

With recent progress in gene therapy clinical trials, there is an even greater demand to advance the development of nonviral gene delivery vehicles. We have previously developed poly(ethylene glycol) (PEG)‐based vehicles with transfection efficiency similar to polyethyleneimine and low cytotoxicity. It was hypothesized that conjugating endosomal escape peptides (EEPs) to PEG‐based vehicles would further increase their transfection efficiency. The present study aimed to determine how two different EEPs, INF7 and H5WYG, which destabilize the endosomal membrane at different pHs, affect the efficiency of PEG‐based vehicles.

Characterization of a multifunctional PEG-based gene delivery system containing nuclear localization signals and endosomal escape peptides☆

Endosomal escape and nuclear localization are two barriers to gene delivery that need to be addressed in the design of new nonviral gene delivery vehicles. We have previously synthesized low-toxicity polyethylene glycol (PEG)-based vehicles with endosomal escape functionalities, but it was determined that the transfection efficiency of PEG-based vehicles that escaped the endosome was still limited by poor nuclear localization. Two different nuclear localization signal (NLS) peptides, SV40 and TAT, were coupled to PEG-based vehicles with DNA-binding peptides (DBPs) to determine the effect of NLS peptides on the transfection efficiency of PEG-based gene delivery vehicles. Coupling one SV40 peptide, a classical NLS, or two TAT peptides, a nonclassical NLS, to PEG-DBP vehicles increased the transfection efficiency of PEG-DBP/DNA particles 15-fold and resulted in similar efficiency to that of a common cationic polymer vehicle, polyethylenimine (PEI). The transfection efficiency of both types of PEG-DBP-NLS particles was further increased 7-fold in the presence of chloroquine, suggesting that the transfection efficiency of PEG-DBP-NLS particles is limited by their ability to escape the endosome. To develop particles that could escape the endosome and target the nucleus, a mixture of PEG-DBP-NLS vehicles and PEG-based vehicles with DBPs and endosomal escape peptides were complexed with plasmid DNA to form multifunctional particles that had a transfection efficiency 2-3 times higher than that of PEI. Additionally, the PEG-based vehicles were less toxic and more resistant to nonspecific protein adsorption than PEI, making them an attractive alternative for nonviral gene delivery.

Biomimetic Tissue–Engineered Systems for Advancing Cancer Research: NCI Strategic Workshop Report

Advanced technologies and biomaterials developed for tissue engineering and regenerative medicine present tractable biomimetic systems with potential applications for cancer research. Recently, the National Cancer Institute convened a Strategic Workshop to explore the use of tissue biomanufacturing for development of dynamic, physiologically relevant in vitro and ex vivo biomimetic systems to study cancer biology and drug efficacy. The workshop provided a forum to identify current progress, research gaps, and necessary steps to advance the field. Opportunities discussed included development of tumor biomimetic systems with an emphasis on reproducibility and validation of new biomimetic tumor models, as described in this report.

Measuring the evolution and output of cross-disciplinary collaborations within the NCI Physical Sciences-Oncology Centers Network.

Development of effective quantitative indicators and methodologies to assess the outcomes of cross-disciplinary collaborative initiatives has the potential to improve scientific program management and scientific output. This article highlights an example of a prospective evaluation that has been developed to monitor and improve progress of the National Cancer Institute Physical Sciences—Oncology Centers (PS-OC) program. Study data, including collaboration information, was captured through progress reports and compiled using the web-based analytic database: Interdisciplinary Team Reporting, Analysis, and Query Resource. Analysis of collaborations was further supported by data from the Thomson Reuters Web of Science database, MEDLINE database, and a web-based survey. Integration of novel and standard data sources was augmented by the development of automated methods to mine investigator pre-award publications, assign investigator disciplines, and distinguish cross-disciplinary publication content. The results highlight increases in cross-disciplinary authorship collaborations from pre- to post-award years among the primary investigators and confirm that a majority of cross-disciplinary collaborations have resulted in publications with cross-disciplinary content that rank in the top third of their field. With these evaluation data, PS-OC Program officials have provided ongoing feedback to participating investigators to improve center productivity and thereby facilitate a more successful initiative. Future analysis will continue to expand these methods and metrics to adapt to new advances in research evaluation and changes in the program.

Analysis of Cell Binding and Internalization of Multivalent PEG-Based Gene Delivery Vehicles

RGD peptides have been incorporated into several gene delivery vehicles to enhance specific interactions of nonviral vehicles with the cell surface. However, there are contradictory results regarding the effect of linear RGD peptides on specific cell surface binding of polyethylene glycol (PEG)-conjugated gene delivery vehicles. This study sought to understand how coupling RGD peptides to PEG vehicles affects cell binding and internalization using a novel four arm PEG backbone. Coupling multiple RGD peptides to the PEG backbone increased the affinity of the vehicle for the cell surface, and that the PEG backbone did not reduce the affinity of RGD peptides for integrin receptors in both kinetic and equilibrium studies. Kinetic studies suggest that cellular internalization of PEG-based vehicles is not regulated by the RGD peptides on the vehicle, but rather by nonspecific interactions with heparan sulfate proteoglycans either alone or in combination with integrins. These results suggest that while increasing the number of RGD peptides per vehicle increases cell binding, but it does not contribute to increased internalization or transfection efficiency.

Physical Biology in Cancer. 1. Cellular physics of cancer metastasis

One of the major challenges in cancer research today is developing new therapeutic strategies to control metastatic disease, the spread of cancer cells from a primary tumor to seed in a distant site. Advances in diagnosis and treatment options have increased the survival rate for most patients with local tumors; however, less progress has been made in treatment of disseminated disease. According to the SEER Cancer Statistics Review, 1975-2010, in the case of breast and prostate cancers, only one in four patients diagnosed with distant metastatic disease will survive more than five years. Current research efforts largely focus on identifying biological targets, such as specific genes and signaling pathways that drive two key steps of metastasis, invasion from the primary tumor and growth in the secondary site. On the other hand, there are phenotypic traits and dynamics in the metastatic process that are not encoded by single genes or signaling pathways but, rather, a larger system of events and biophysical characteristics. Connecting genomic and pathway investigations with quantitative physical phenotypic characteristics of cells, the physical microenvironment, and the physical spatiotemporal interactions of the metastatic process provides a stronger complementary understanding of the disease.