An improved method for routine preparation of intact artificial chromosome DNA (340-1000 kb) for transfection into human cells.

The transfer of high molecular weight (HMW) DNA into mammalian cells is an important strategy for assessing human gene expression and chromosome structure and function. However, using current methods, it is difficult to dependably prepare intact HMW DNA because of the susceptibility of the DNA to degradation and physical shearing. Here we describe a strategy whereby intact artificial chromosome DNA (as large as 1 Mb) can be routinely prepared from yeast. Strict adherence to this protocol has resulted in: (i) >90% of liquid DNA preparations containing largely intact DNA; (ii) transfection efficiencies for the development of stable human clonal cell lines ranging from 5 x 10(-7) to 8.8 x 10(-5); and (iii) the presence of markers from both YAC arms in 30-42% of the human fibrosarcoma cell HT1080 clones and 100% of the CF lung epithelial cell lines IB3-1 and CFT1 clones, suggesting that the HMW DNA is potentially intact in a substantial proportion of clones. Using this protocol for DNA preparation, successful transfection of functional 1 Mb human artificial chromosome DNA into human cells has also been achieved. This methodology should prove useful to those interested in using HMW human DNA for gene expression and functional analysis or for linear artificial chromosome construction, since integrity is absolutely critical for the success of these studies.

Human artificial chromosomes generated by modification of a yeast artificial chromosome containing both human alpha satellite and single-copy DNA sequences.

A human artificial chromosome (HAC) vector was constructed from a 1-Mb yeast artificial chromosome (YAC) that was selected based on its size from among several YACs identified by screening a randomly chosen subset of the Centre d'Etude du Polymorphisme Humain (CEPH) (Paris) YAC library with a degenerate alpha satellite probe. This YAC, which also included non-alpha satellite DNA, was modified to contain human telomeric DNA and a putative origin of replication from the human beta-globin locus. The resultant HAC vector was introduced into human cells by lipid-mediated DNA transfection, and HACs were identified that bound the active kinetochore protein CENP-E and were mitotically stable in the absence of selection for at least 100 generations. Microdissected HACs used as fluorescence in situ hybridization probes localized to the HAC itself and not to the arms of any endogenous human chromosomes, suggesting that the HAC was not formed by telomere fragmentation. Our ability to manipulate the HAC vector by recombinant genetic methods should allow us to further define the elements necessary for mammalian chromosome function.

Transient gene expression from yeast artificial chromosome DNA in mammalian cells is enhanced by adenovirus.

The introduction of high molecular weight DNA into mammalian cells is useful for gene expression studies. However, current transfection strategies are inefficient, necessitating propagation of stable DNA transformants prior to analysis of gene expression. Here we demonstrate that transient lipid-mediated DNA transfection can be used to assess gene expression from yeast artificial chromosomes (YACs) containing the 230 kb cystic fibrosis transmembrane conductance regulator gene ( CFTR ) and Escherichia coli lacZ . We also show that psoralen-UV inactivated adenovirus significantly enhances transfection efficiency. The ability to deliver high molecular weight DNA using lipid-mediated transfection should expedite the analysis of large human genes contained within artificial chromosome vectors.

Hematopoietic repopulation of adult mice with beta-thalassemia.

Deletion of the murine beta-major globin gene on chromosome 7 causes a severe, hypochromic anemia in homozygous mice. We show that over 50% of the homozygous mice die either in utero or at birth. Mice heterozygous for the deletion have a slightly increased percentage of reticulocytes when compared with normal mice, but no clinical anemia. As a therapeutic measure, we transplanted 2 x 10(6) congenic genetically marked normal (+/+) marrow cells into adult homozygous and control heterozygous mice. Pretreatment with marrow ablative irradiation was required to obtain significant percentages of donor peripheral blood cells in the homozygous mice. Red blood cell (RBC) counts normalized after pretransplantation irradiation of thalassemic mice with nonlethal doses as low as 400 R. The thalassemic mice irradiated with 200, 400, and 600 R were erythroid-cell chimeras and remained so for at least 8 months posttransplantation, whereas those irradiated with 800 R had primarily donor erythrocytes by 8 weeks. RBC replacement preceded non-erythroid cell replacement at 200, 400, and 600 R. This selective repopulation was more noticeable in the thalassemic mice than in control mice. The fact that chimeric mice are cured, coupled with a recent observation by others that erythroid replacement occurs in unirradiated newborn thalassemic mice, suggest transplantation therapy in utero might augment survival.

Temporal replacement of donor erythrocytes and leukocytes in nonanemic W44J/W44J and severely anemic W/Wv mice.

The dominant white spotting, W, locus in the mouse encodes Kit, a receptor molecule with cytosolic tyrosine kinase activity. Mutations in Kit deplete hematopoietic cells by an as yet unknown mechanism, but one that presumably affects the early progenitors of all cell lineages. To examine cell lineage-specific changes caused by different W mutations, we injected genetically marked normal marrow cells into mutant mice and monitored repopulation kinetics. In the present report, we compare repopulation of the various peripheral blood cells in nonanemic W44J/W44J and severely anemic W/Wv mice administered increasing increments of donor cells. At all doses of cells tested, donor erythrocyte repopulation precedes leukocyte repopulation regardless of the recipient phenotype. There is, in fact, little difference in the rate or extent of nonerythroid repopulation in W44J/W44J mice injected with between 6 x 10(6) and 2 x 10(7) donor cells. The fact that donor cells rapidly replace erythrocytes, even in the nonanemic W44J/W44J host, while other cell lineages become donor type more slowly provides further evidence that mutations at the W locus are especially damaging to erythrocyte progenitors. We suggest that host nonerythroid hematopoietic cells compete with normal cells, probably at the level of early progenitors rather than at the level of the totipotent hematopoietic stem cell. The fact that successively higher doses of donor cells do not markedly alter nonerythroid repopulation kinetics implies that it may be possible to maximize autologous therapeutic marrow transplantation.