Intrathecal administration of AAV vectors for the treatment of lysosomal storage in the brains of MPS I mice.

Mucopolysaccharidosis type I (MPS I) is caused by an inherited deficiency of alpha-L-iduronidase (IDUA). The result is a progressive, lysosomal storage disease with central nervous system (CNS) as well as systemic involvement. To target gene therapy to the CNS, recombinant adeno-associated virus (AAV) vectors carrying IDUA sequence were administered to MPS I mice via injection into cerebrospinal fluid. In contrast to intravenous administration, this intrathecal administration was effective in generating widespread IDUA activity in the brain, with the cerebellum and olfactory bulbs having highest activities. In general, IDUA levels correlated with vector dose, although this correlation was obscured in cerebellum by particularly high variability. High doses of vector (4 x 10(10) particles) provided IDUA levels approaching or exceeding normal levels in the brain. Histopathology indicated that the number of cells with storage vacuoles was reduced extensively or was eliminated entirely. Elimination of storage material in Purkinje cells was particularly dramatic. A lower vector dose (2 x 10(9) particles) reduced both the number of storage cells and the extent of storage per cell, but the effect was not complete. Some perivascular cells with storage persisted, and this cell type appeared to be more resistant to treatment than neurons or glial cells. We conclude that intrathecal administration of AAV-IDUA delivers vector to brain cells, and that this route of administration is both minimally invasive and effective.

The PR264/c-myb connection: expression of a splicing factor modulated by a nuclear protooncogene.

We have previously reported that expression of the c-myb gene in normal avian thymic cells proceeds through the intermolecular recombination of ET (thymus-specific) and c-myb coding sequences, thereby generating a novel type of c-myb product. Antisense transcripts expressed from the ET locus encode the extremely well-conserved splicing factor PR264/SC35. We now show that the human PR264 promoter sequences contain several myb-recognition elements that efficiently interact in vitro with the c-myb DNA-binding domain. Moreover, expression from the PR264 promoter is transactivated, both in vitro and in cultured cells, by different c-myb products. Thus, the PR264 gene is most likely a physiological target for the c-myb family of transcription factors.

A potential splicing factor is encoded by the opposite strand of the trans-spliced c-myb exon.

We previously established that the expression of a thymic c-myb mRNA species requires the intermolecular recombination of coding sequences expressed from transcriptional units localized on different chromosomes, in both chicken and human. We now report that a putative splicing factor (PR264), extremely well conserved in chicken and human, is encoded by the opposite strand of the c-myb trans-spliced exon. The PR264 polypeptide, which contains a typical ribonucleoprotein 80 and an arginine/serine-rich domain, is highly homologous to the Drosophila splicing regulators tra, tra-2, and su(wa) and to the human alternative splicing factor ASF/SF2. Furthermore, we show that PR264-specific mRNAs are expressed in normal hematopoietic cells of chicken and human origin and that the relative proportion of the PR264 transcripts is developmentally regulated in chicken.

C-myb proto-oncogene: evidence for intermolecular recombination of coding sequences.

We have characterized a novel chicken c-myb exon whose sequences are specifically expressed in thymic cells. In situ hybridization experiments indicate that this thymus-specific coding exon is localized on a small chromosome, distinct from the large acrocentric chromosome 3 on which we recently mapped the bulk of 15 exons, common to the c-myb mRNA species expressed in hematopoietic cells of both B and T lineages. These observations indicate that intermolecular recombination is required for the tissue-specific expression of the c-myb proto-oncogene. We also show that these thymus-specific sequences are conserved in human DNA and lie on chromosome 17q25, whereas the human c-myb locus is localized on chromosome 6q22-23. Sequencing data obtained from genomic DNA and PCR analyses performed with c-myb mRNA species expressed in chicken thymic cells strongly suggest that a repeated decameric sequence plays a key role in the recombination process.

A novel type of RNA-binding protein is potentially encoded by the opposite strand of the trans-spliced c-myb coding exon.

Recently, we reported evidence suggesting that expression of c-myb thymic mRNA species involves the intermolecular recombination of coding sequences (ET and c-myb) localized on two different chromosomes, both in chicken and human. Our present studies demonstrate that the ET locus encodes, in the antisense orientation, a novel member of the RNA binding protein family in these two species.

Chromosomal reallocation of the chicken c-myb locus and organization of 3'-proximal coding exons.

In the course of our studies concerning the tissue-specific expression of the c-myb proto-oncogene, we have established the nucleotide sequence of the chicken c-myb 3'-proximal coding exons. In situ hybridization performed with different genomic DNA probes corresponding to nearly all the c-myb gene allowed us to localize the corresponding locus on the large acrocentric chromosome 3 in chicken. Our sequencing data also indicate that the 3'-proximal noncoding sequences represented in c-myb mRNA species are derived from non-contiguous exons.

Intermolecular recombination of the c-myb proto-oncogene coding sequences in chicken: clues for a mechanism.

The physical separation of c-myb coding exons on two different chromosomes, both in chicken and human, indicated that intermolecular recombination events might occur in higher eucaryotes. We present evidence in this paper suggesting that the expression of "antisens" mRNA species could be involved in the regulation of the intermolecular recombination process.

Organization of 5'-proximal c-myb exons in chicken DNA. Implications for c-myb tissue-specific transcription.

The organization of 5'-proximal c-myb exons in chicken DNA has been established by restriction enzyme mapping and nucleotide sequencing. Hybridization studies performed with cDNA probes revealed that yolk sac and thymic c-myb RNAs differ in their 5'-termini. A comparison of the genomic c-myb sequence with that of cDNAs isolated from normal thymic and lymphoma avian cells suggests that different promoter regions are used to initiate c-myb transcription in hematopoietic cells of different origins.