Chronic granulomatous disease (CGD) is an inherited immunodeficiency characterized by severe recurrent bacterial and fungal infections of several organs. The disease is due to the inability of ...phagocytic leukocytes to generate reactive oxygen species upon phagocytosis. The defect arises as a consequence of mutations of the genes encoding for the subunits of a membrane NADPH oxidase, which catalyzes the production of superoxide anion (O2-). CGD represents an ideal candidate disorder for gene therapy, since the disease has a recessive inheritance, its phenotype is exclusively expressed in phagocytic cells, and a partial correction is likely to be effective. Given the short half-life of mature phagocytes, the optimal target cell population for gene transfer is the pluripotent hematopoietic stem cell. Transduction of CD34+ hematopoietic progenitors with retroviral vectors carrying the cDNA of the defective gene results in the correction of the enzymatic defect in myeloid cells differentiated in vitro. Still, the effective development of a clinical gene therapy protocol for this disease will await a substantial improvement in our current technology for the identification and manipulation of hematopoietic stem cells, and in our understanding of their biological and molecular properties.
The attempts at identifying precise replication origins (ori) in mammalian DNA have been pursued mainly through physico-chemical and biochemical approaches, in view of the essential failure of the ...search for autonomously replicating sequences in cultured cells. These approaches involve the mapping of short stretches of nascent DNA, the identification of the regions where either leading or lagging strands switch polarity, or the localization of replication intermediates by two-dimensional gel electrophoresis. Due to the complexity of animal cell genomes, most of these studies have been performed on amplified domains and with the use of synchronization procedures. The results obtained have been controversial. In order to avoid the use of experimental procedures potentially affecting the physiological mechanism of DNA replication, we have developed a method for the localization of ori in single-copy loci in exponentially growing cells. This method entails the absolute quantification of the abundance of selected DNA fragments along a genomic region within samples of newly synthesized DNA by competitive polymerase chain reaction (PCR); the latter is immune to all the uncontrollable variables which severely affect the reproducibility of conventional PCR. The application of this method to SV40 ori-driven plasmid replication precisely identifies the known ori localization. Using the same approach, we have mapped an ori for bi-directional DNA replication in a 13.7-kb locus of human chromosome 19 encoding lamin B2.
A previously described human DNA fragment which is replicated early in S-phase of HL-60 cell DNA (C. Tribioli, G. Biamonti, M. Giacca, M. Colonna, S. Riva, and A. Falaschi, Nucleic Acids Res. ...15:10211-10232, 1987) was used to screen a genomic library in XCh28. A clone which contained a 13.7-kb insert (L30E) found to code for several transcripts was isolated. The transcription of L30E DNA exhibited a complex pattern and a tissue-specific and proliferation-dependent type of regulation. The data were consistent with two tandemly arranged transcription units, the 3′ end of one separated from the 5′ end of the other by a sequence of about 600 bp containing an active promoter. The isolation and sequencing of L30E-specific cDNAs permitted identification of two genes, one of which encoded a B-type human lamin (analogous to mouse lamin B
2
). L30E DNA was mapped by in situ hybridization at the G-negative subtelomeric band p13.3 of chromosome 19. Interestingly, in synchronized HL-60 cells, L30E DNA is replicated in the first minute of S-phase. Replication of the lamin gene early in S-phase may reflect a coupling between early replication and transcription of genes for S-phase-specific proteins such as lamins.
