The use of protein coding nucleic acids (usually cDNAs, i.e., the double-stranded DNA copies derived from the gene mRNAs) is aimed at providing the relevant cells with a protein that either permits to rescue a missing function or supplies a new function able to counteract or alleviate the disease. Candidate therapeutic genes are obvious in the case of recessively inherited neurodegenerative diseases due to loss-of-function mutations, such as, for example, lysosomal storage diseases or recessively inherited forms of Parkinson’s disease. For these disorders, the strategy relies on the delivery of the wild-type copy of the disease gene in order to supply the missing or defective protein. On the other hand, the choice of candidate therapeutic genes for non-inherited as well as dominantly inherited monogenic neurodegenerative diseases relies on the available knowledge about pathogenetic mechanisms.

A strategy that widely applies to the treatment of neurodegenerative diseases is the delivery of genes coding for neurotrophic factors (NTFs) as neuroprotective/neurorestorative agents. NTFs are secreted proteins expressed in both developing and adult nervous system. They regulate the development, maintenance, function and plasticity of the nervous system, and exert their actions through binding and activating specific cell surface receptors. A single neuronal group can respond to several NTFs and a given NTF affects many neuronal types. Neurons can derive trophic support not only from innervated cells (retrograde transport), but also from afferent neurons (anterograde transport), or even themselves (autocrine mechanism). Therefore, the trophic requirement of a neuronal population is due to a complex interaction between different NTFs that contribute to the highly specific connectivity of the nervous system. Importantly, NTFs not only promote neuron survival (survival effect), but can also protect specific neuronal populations against different types of brain insults (neuroprotective effect), and repair already damaged neurons (neurorestorative effect). In consideration of these properties, NTFs have been considered ideal candidates as neuroprotective and neurorestorative agents.

A peculiar type of therapeutic genes are those coding for gene-engineered antibodies aimed at ablating the abnormal function of specific intracellular proteins [3, 4]. Natural antibodies can be genetically engineered to obtain the so-called “intrabodies” (iAbs), i.e., smaller molecules which are more suitable to be intracellularly expressed. Among intrabody formats, the first choice is the single chain variable fragment (scFv) which consists of the variable domains of the immunoglobulin heavy (VH) and light (VL) chains kept together by a flexible polypeptide linker. The resulting molecule is a monovalent antibody fragment which still retains the binding specificity of full-length antibody but is encoded by a single gene. Intrabodies for...