This article presents a unique approach for the delivery of gene therapy vectors into the cochlea of the laboratory rat. Mice and guinea pigs are established in vivo models for cochlear gene therapy each of which has distinct advantages and disadvantages. The rat has some of the molecular advantages of a mouse model combined with size advantages for surgical approaches. Vector delivery via cochleostomy or injection through the round window causes concomitant sensorineural hearing loss and is therefore not suitable for studies where the change in hearing is being followed. Compared to the mouse, the rat does not demonstrate easily recognizable landmarks that allow for use of the semicircular canal as an approach to the inner ear. We analyzed sagittal and coronal temporal bone sections of Long Evans rats and identified the bony entrance of the facial nerve as a crucial landmark for canalostomy. Auditory brainstem response and distortion product otoacustic emission measurements revealed minimal differences in the hearing threshold after adenovirus vector application when large volumes of vector were infused to the inner ear. Canalostomy and infusion of adenoviral vectors also resulted in temporary balance disturbance in the rat. Immunohistochemical assessment after delivery of a green fluorescent protein expressing vector showed significant GFP expression in the cochlea.
We have previously shown that activation of PKC (protein kinase C) results in internalization of hCAT-1 [human CAT-1 (cationic amino acid transporter 1)] and a decrease in arginine transport [Rotmann, Strand, Martiné and Closs (2004) J. Biol. Chem. 279, 54185-54192]. However, others found increased transport rates for arginine in response to PKC activation, suggesting a differential effect of PKC on different CAT isoforms. Therefore we investigated the effect of PKC on hCAT-3, an isoform expressed in thymus, brain, ovary, uterus and mammary gland. In Xenopus laevis oocytes and human U373MG glioblastoma cells, hCAT-3-mediated L-arginine transport was significantly reduced upon treatment with compounds that activate classical PKC. In contrast, inactive phorbol esters and an activator of novel PKC isoforms had no effect. PKC inhibitors (including the PKCalpha-preferring Ro 31-8280) reduced the inhibitory effect of the PKC-activating compounds. Microscopic analyses revealed a PMA-induced reduction in the cell-surface expression of fusion proteins between hCAT-3 and enhanced green fluorescent protein expressed in X. laevis oocytes and glioblastoma cells. Western-blot analysis of biotinylated surface proteins demonstrated a PMA-induced decrease in hCAT-3 in the plasma membrane, but not in total protein lysates. Pretreatment with a PKC inhibitor also reduced this PMA effect. It is concluded that similar to hCAT-1, hCAT-3 activity is decreased by PKC via reduction of transporter molecules in the plasma membrane. Classical PKC isoforms seem to be responsible for this effect.
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