Elizabeth Smiley

DNA delivery from polymer matrices for tissue engineering.

We have proposed engineering tissues by the incorporation and sustained release of plasmids encoding tissue-inductive proteins from polymer matrices. Matrices of poly(lactide-co-glycolide) (PLG) were loaded with plasmid, which was subsequently released over a period ranging from days to a month in vitro. Sustained delivery of plasmid DNA from matrices led to the transfection of large numbers of cells. Furthermore, in vivo delivery of a plasmid encoding platelet-derived growth factor enhanced matrix deposition and blood vessel formation in the developing tissue. This contrasts with direct injection of the plasmid, which did not significantly affect tissue formation. This method of DNA delivery may find utility in tissue engineering and gene therapy applications.

Localized, direct plasmid gene delivery in vivo: prolonged therapy results in reproducible tissue regeneration.

The inability to deliver growth factors locally in a transient but sustained manner is a substantial barrier to tissue regeneration. Systems capable of localized plasmid gene delivery for prolonged times may offer lower toxicity and should be well-suited for growth factor therapeutics. We investigated the potency of plasmid gene delivery from genes physically entrapped in a polymer matrix (gene activated matrix) using bone regeneration as the endpoint in vivo. Implantation of gene activated matrices at sites of bone injury was associated with retention and expression of plasmid DNA for at least 6 weeks, and with the induction of centimeters of normal new bone in a stable, reproducible, dose- and time-dependent manner.

Macrophage migration inhibitory factor acts as a neurotrophin in the developing inner ear

This study is the first to demonstrate that macrophage migration inhibitory factor (MIF), an immune system ‘inflammatory’ cytokine that is released by the developing otocyst, plays a role in regulating early innervation of the mouse and chick inner ear. We demonstrate that MIF is a major bioactive component of the previously uncharacterized otocyst-derived factor, which directs initial neurite outgrowth from the statoacoustic ganglion (SAG) to the developing inner ear. Recombinant MIF acts as a neurotrophin in promoting both SAG directional neurite outgrowth and neuronal survival and is expressed in both the developing and mature inner ear of chick and mouse. A MIF receptor, CD74, is found on both embryonic SAG neurons and adult mouse spiral ganglion neurons. Mif knockout mice are hearing impaired and demonstrate altered innervation to the organ of Corti, as well as fewer sensory hair cells. Furthermore, mouse embryonic stem cells become neuron-like when exposed to picomolar levels of MIF, suggesting the general importance of this cytokine in neural development.

Molecular Characterization of Conditionally Immortalized Cell Lines Derived From Mouse Early Embryonic Inner Ear

Inner ear sensory hair cells (HCs), supporting cells (SCs), and sensory neurons (SNs) are hypothesized to develop from common progenitors in the early embryonic otocyst. Because little is known about the molecular signals that control this lineage specification, we derived a model system of early otic development: conditionally immortalized otocyst (IMO) cell lines from the embryonic day 9.5 Immortomouse. This age is the earliest stage at which the otocyst can easily be separated from surrounding mesenchymal, nervous system, and epithelial cells. At 9.5 days post coitum, there are still pluripotent cells in the otocyst, allowing for the eventual identification of both SN and HC precursors—and possibly an elusive inner ear stem cell. Cell lines derived from primitive precursor cells can also be used as blank canvases for transfections of genes that can affect lineage decisions as the cells differentiate. It is important, therefore, to characterize the “baseline state” of these cell lines in as much detail as possible. We characterized seven representative “precursor‐like” IMO cell populations and the uncloned IMO cells, before cell sorting, at the molecular level by polymerase chain reaction (PCR) and immunocytochemistry (IHC), and one line (IMO‐2B1) in detail by real‐time quantitative PCR and IHC. Many of the phenotypic markers characteristic of differentiated HCs or SCs were detected in IMO‐2B1 proliferating cells, as well as during differentiation for up to 30 days in culture. These IMO cell lines represent a unique model system for studying early stages of inner ear development and determining the consequences of affecting key molecular events in their differentiation. Developmental Dynamics 231:815–827, 2004.

Mouse latent TGF-β binding protein-2: molecular cloning and developmental expression

The molecular cloning and developmental expression of mouse LTBP-2 are presented here. We established the identity of the cDNA by sequence comparison (80% identity with human LTBP-2) and by chromosome localization (mouse chromosome 12, band D, a region of conserved synteny with the human LTBP-2 gene). In contrast to LTBP-1 and LTBP-3, mouse LTBP-2 apparently is a more modular protein, with proline/glycine-rich sequences always alternating with clusters of cysteine-rich structural motifs. We found for the first time that LTBP-2 gene expression in mouse embryos was restricted to cartilage perichondrium and blood vessels, a somewhat surprising result since other LTBP genes are widely expressed in rodent tissues. Therefore, mouse LTBP-2 may play a critical role in the assembly of latent TGF-beta complexes in developing elastic tissues such as cartilage and blood vessel.

8-Cysteine TGF-BP structural motifs are the site of covalent binding between mouse LTBP-3, LTBP-2, and latent TGF-β1

The small latent TGF-beta complex often is associated with the latent TGF-beta binding protein (LTBP). Three LTBPs (LTBP-1, -2, and -3) have been isolated to date. Previous studies have shown that LTBP-1 binds the small latent TGF-beta 1 complex through a disulfide bond between an 8-cysteine structural motif of LTBP-1 (TGF-bp repeat) and the propeptide dimer of latent TGF-beta 1 (TGF-beta 1 latency associated peptide). There is indirect evidence that LTBP-2 and LTBP-3 also bind the latent TGF-beta complex, but the nature and location of the binding interaction are unknown. We have used immunoprecipitation, SDS-PAGE, and autoradiography to characterize the association between mouse LTBP-3 and the small latent TGF-beta 1 complex. We report that the second and third TGF-bp repeats of LTBP-3 covalently bind the latent complex, and we show a similar capability for the homologous TGF-bp repeats of mouse LTBP-2. The second TGF-bp repeat of LTBP-3 is unusual in that it has 9 cysteine residues instead of 8, and our results provide the first evidence that a TGF-bp repeat with an odd number of cysteine residues can covalently bind latent TGF-beta 1. Altogether, these results have important implications for TGF-beta biosynthesis and the regulation of TGF-beta activity.