Abstract
The domestic chicken is an attractive model system to explore the development and function of brain circuits. Electroporation-mediated and retrovirus (including lentivirus) vector-mediated gene transfer techniques have been widely used to introduce genetic material into chicken cells. However, it is still challenging to efficiently transduce chicken postmitotic neurons without harming the cells. To overcome this problem, we searched for a virus vector suitable for gene transfer into chicken neurons, and report here a novel recombinant virus vector derived from avian adeno-associated virus (A3V). A3V vector efficiently transduces neuronal cells, but not non-neuronal cells in the brain. A single A3V injection into a postembryonic chick brain allows gene expression selectively in neuronal cells within 24 hrs. Such rapid and neuron-specific gene transduction raises the possibility that A3V vector can be utilized for studies of memory formation in filial imprinting, which occurs during the early postnatal days. A3V injection into the neural tube near the ear vesicle at early embryonic stage resulted in persistent and robust gene expression until E20.5 in the auditory brainstem. We further devised an A3V-mediated tetracycline (Tet) dependent gene expression system as a tool for studying the auditory circuit, consisting of the nucleus magnocellularis (NM) and nucleus laminaris (NL), that primarily computes interaural time differences (ITDs). Using this Tet system, we can transduce NM neurons without affecting NL neurons. Thus, the A3V technology complements current gene transfer techniques in chicken studies and will contribute to better understanding of the functional organization of neural circuits.
Highlights
The domestic chicken (Gallus gallus domesticus) has provided an attractive model system to understand the development and function of brain circuits
Each virus vector was applied to chicken neural cells, zebra finch neural cells and 293T cells, at a multiplicity of infection equivalent to 103 genome copies (GC) per cell
Because the only difference between the A3V-RSV-EGFP and AAV2RSV-EGFP vectors is limited to the specific capsid proteins and the inverted terminal repeats (ITRs) flanking the gene expression cassette (RSV-EGFP), transduction efficiency and species-specificity of recombinant associated virus (AAV) vectors should be determined by the distinct structures of these limited components
Summary
The domestic chicken (Gallus gallus domesticus) has provided an attractive model system to understand the development and function of brain circuits. A visually naive chick immediately after hatching can learn the visual characteristics of a moving object, and subsequently form a strong social attachment to it [4,5,6] Such imprinting memory has a great advantage in that the process of memory formation can be analyzed without interference from previous visual experiences [3]. Electroporation-mediated and retrovirus (including lentivirus) vector-mediated gene transfer methods are widely used for chick studies [7,8,9,10] These methods permit genetic manipulation with a relatively high efficiency during the early developmental stage [11,12]. It is still challenging to efficiently and selectively deliver genetic material into chick postmitotic neurons without harming the cells
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