A.T.M. Shamsul Hoque

Cochlear Gene Delivery through an Intact Round Window Membrane in Mouse

Cochlear gene transfer studies in animal models have utilized mainly two delivery methods: direct injection through the round window membrane (RWM) or intracochlear infusion through a cochleostomy. However, the surgical trauma, inflammation, and hearing loss associated with these methods lead us to investigate a less invasive delivery method. Herein, we studied the feasibility of a vector transgene-soaked gelatin sponge, Gelfoam, for transgene delivery into the mouse cochlea through an intact RWM. The Gelfoam absorbed with liposomes and adenovirus, but not with adeno-associated virus (AAV), was successful in mediating transgene expression across an intact RWM in a variety of cochlear tissues. The Gelfoam technique proved to be an easy, atraumatic, and effective, but vector-dependent, method of delivering transgenes through an intact RWM. Compared with the more invasive gene delivery methods, this technique represents a safer and a more clinically viable route of cochlear gene delivery in humans.

Cationic liposome-mediated gene transfer to rat salivary epithelial cells in vitro and in vivo

Previously we have shown that gene transfer to salivary gland epithelial cells readily occurs via recombinant adenoviruses, although the response is short‐lived and results in a potent host immune response. The aim of the present study was to assess the feasibility of using cationic liposomes to mediate gene transfer to rat salivary cells in vitro and in vivo.

Hydroxychloroquine enhances the endocrine secretion of adenovirus-directed growth hormone from rat submandibular glands in vivo

Use of gene transfer technology for treating single protein deficiency disorders requires delivery of therapeutic levels of the transgene product. We have suggested that salivary glands may provide a potentially valuable target site for certain systemic applications of gene therapeutics (He et al., Gene Ther. 1998;5:537-541). However, the ability of salivary glands to deliver therapeutic proteins to either the upper gastrointestinal tract via saliva or to the bloodstream, as required, must be carefully evaluated. In the anterior pituitary gland, human growth hormone (hGH) is secreted into the bloodstream via the regulated secretory pathway. However, when expressed from an adenoviral vector delivered to salivary glands, most hGH follows the regulated, tissue-specific, exocrine secretory pathway into saliva, where it is not therapeutically useful. We tested the hypothesis that the commonly used, FDA-approved drug hydroxychloroquine (HCQ) can divert adenovirus-directed hGH from this regulated secretory pathway in rat submandibular glands and enhance delivery into the bloodstream. In untreated rats, there was approximately 20-fold more vector-directed hGH in saliva than in serum. Administration of HCQ led to a shift of hGH secretion into the bloodstream. When delivered at doses of 1 or 10 mg/kg body weight, via intraperitoneal injection plus intraductal infusion, the saliva:serum hGH ratio was approximately 2:1. Such HCQ delivery did not significantly alter the total amount of hGH measured, but increased the serum level of hGH 5- to 6-fold. Also, HCQ had no significant effects on serum chemistries or hematological parameters. We conclude that HCQ is able to significantly enhance hGH secretion from salivary glands into the bloodstream and may be useful to facilitate clinical applications of gene therapeutics via salivary glands.

Evaluation of salivary gland acinar and ductal cell-specific promoters in vivo with recombinant adenoviral vectors

Adenoviral vectors efficiently deliver exogenous genes to salivary glands. There are two general epithelial cell types, with very different functions, in salivary glands--acinar and ductal. To determine if gene expression can be restricted in vivo to either general cell type using a relatively cell/tissue-specific promoter in conjunction with adenovirus-mediated gene transfer, we tested the human amylase and kallikrein promoters. For initial studies the sensitive reporter gene luciferase was used in two adenoviral constructs. The adenovirus AdAMY-luc contains the human salivary gland amylase promoter (-1003 to +2)(AMY1C) and AdKALL-luc contains the human tissue kallikein promoter (-315 to -1)(KLK1). The adenovirus AdKALL-hAQP1 was also used to test a therapeutic gene, human aquaporin-1 (hAQP1), potentially of importance in treating surviving ductal cells in irradiation-damaged glands. Luciferase expression after AdAMY-luc delivery in vivo directly to the parotid, submandibular, and sublingual glands, as well as to the lungs, and intravenously via the femoral vein, was restricted to the three salivary glands and the pancreas. AdKALL-luc delivery via the same routes resulted in a more general distribution of luciferase expression, although greatest luciferase activity was seen in salivary glands and lung. Luciferase activity after AdAMY-luc delivery was proportionally greater (approximately 14-fold) in acinar cells, whereas luciferase activity after AdKALL-luc delivery was proportionally greater (approximately 9-fold) in ductal cells. The expression of hAQP1 after AdKALL-hAQP1 gene transfer was mainly observed in ductal cells in vivo. AdKALL-hAQP1 was as useful as AdCMV-hAQP1 in increasing salivary flow rates of irradiated rats. This study demonstrates that adenoviral vectors containing the relatively cell/tissue-specific AMY1C or KLK1 promoters may be useful for targeting therapeutic gene expression in salivary glands.

Expression of the aquaporin 8 water channel in a rat salivary epithelial cell line

Aquaporins are a family of water channels considered to play an important role in fluid transport across plasma membranes. Among the reported isoforms, relatively little is known about the functional role of aquaporin 8 (AQP8), and there are no cell lines known to express the AQP8 protein. We report here that the rat submandibular epithelial cell line, SMIE, expresses AQP8. Using RT‐PCR, the presence of mRNA for AQP8 was demonstrated in these cells. Confocal immunofluorescence experiments revealed that the AQP8 protein is primarily present in the apical membranes of SMIE cells. When grown as a polarized monolayer on collagen coated polycarbonate filters, and exposed on their apical surface to different hyperosmotic (440, 540, or 640 mOsm) solutions, net fluid movement across SMIE cells was 8–25‐fold that seen under isosmotic conditions. Similarly, when grown on coverslips and then exposed to a hypertonic solution, SMIE cells shrunk as a function of time. Together, these results suggest that SMIE cells endogenously express functional AQP8 water channels. Published 2002 Wiley‐Liss, Inc.

Salivary glands as a model for craniofacial applications of gene transfer.

The potential applications of gene transfer technology to all branches of medicine are increasing. It is quite likely that within the next 10-20 years surgical practice routinely will utilize gene transfer, at least adjunctively. The purpose of this review is to familiarize the oral and maxillofacial surgeon with this technology. Studies performed with salivary glands in animal models are presented as examples of proof of concept.

Using Salivary Glands as a Tissue Target for Gene Therapeutics

Gene transfer offers a potential way to correct local and systemic protein deficiency disorders by using genes as drugs, so called gene therapeutics. Salivary glands present an interesting target site for gene therapeutic applications. Herein, we review proofs of concept achieved for salivary glands with in vivo animal models. In that context we discuss problems (general and salivary tissue-specific) that limit immediate clinical use for this application of gene transfer. Ongoing efforts, however, suggest that salivary glands may be suitable as gene therapeutic target sites for drug delivery in the near future.

Use of Polyethylenimine-Adenovirus Complexes to Examine Triplex Formation in Intact Cells

Triplex-forming oligonucleotides (TFOs) show potential for sequence-specific DNA binding and inhibition of gene expression. We have applied this antigene strategy using a TFO incorporating an Auger-emitting radionucleotide, 125I, to study the production of double-strand breaks (dsb) in the rat aquaporin 5 (rAQP5) cDNA. 125I-TFO bound to the pCMVrAQP5 plasmid in vitro in a dose-dependent manner and formed stable triplexes up to 65 degrees C and in the presence of 140 mM KCl. Further, 125I-TFO resulted in a predictable dsb when analyzed by Southern hybridization. To deliver TFOs to epithelial cells, we employed 125I-TFO-polyethyleneimine-adenovirus (125I-TFO-PEI-Ad) complexes. We hypothesized that these complexes would take advantage of adenoviral characteristics to transfer 125I-TFO to the cell nucleus. Adenovirus-containing complexes brought about greater uptake and nuclear localization of TFOs compared with delivery with 125I-TFO-PEI complexes alone. No significant degradation of 125I-TFO was found after delivery into cells using PEI-Ad complexes and freezing and thawing. We next used PEI-Ad complexes to deliver 125I-TFO and pCMVrAQP5 separately to epithelial cells to determine if triplexes can form de novo within cells, resulting in the specific dsb in the rAQP5 cDNA. After delivery, cell pellets were stored at -80 degrees C for more than 60 days. Thereafter, plasmid DNA was isolated from cells and analyzed for dsb by Southern hybridization. However, none were detected. We conclude that under the experimental conditions employed, effective triplexes, with 125I-TFO and pCMVrAQP5, do not form de novo inside cells.