Chemistry: molecular biology and microbiology – Process of mutation – cell fusion – or genetic modification – Introduction of a polynucleotide molecule into or...
Reexamination Certificate
1997-01-09
2001-03-20
Campell, Bruce R. (Department: 1632)
Chemistry: molecular biology and microbiology
Process of mutation, cell fusion, or genetic modification
Introduction of a polynucleotide molecule into or...
C435S320100, C435S325000, C435S352000, C435S354000, C435S363000, C435S455000
Reexamination Certificate
active
06204061
ABSTRACT:
TECHNICAL FIELD OF THE INVENTION
The invention relates to cells and non-human organisms containing predetermined genomic modifications of the genetic material contained in such cells and organisms. The invention also relates to methods and vectors for making such modifications.
BACKGROUND OF THE INVENTION
Many unicellular and multicellular organisms have been made containing genetic material which is not otherwise normally found in the cell or organism. For example, bacteria, such as
E. coli,
have been transformed with plasmids which encode heterologous polypeptides, i.e., polypeptides not normally associated with that bacterium. Such transformed cells are routinely used to express the heterologous gene to obtain the heterologous polypeptide. Yeasts, filamentous fungi and animal cells have also been transformed with genes encoding heterologous polypeptides. In the case of bacteria, heterologous genes are readily maintained by way of an extra chromosomal element such as a plasmid. More complex cells and organisms such as filamentous fungi, yeast and mammalian cells typically maintain the heterologous DNA by way of integration of the foreign DNA into the genome of the cell or organism. In the case of mammalian cells and most multicellular organisms such integration is most frequently random within the genome.
Transgenic animals containing heterologous genes have also been made. For example, U.S. Pat. No. 4,736,866 discloses transgenic non-human mammals containing activated oncogenes. Other reports for producing transgenic animals include PTC Publication No. W082/04443 (rabbit &bgr;-globin gene DNA fragment injected into the pronucleus of a mouse zygote); EPO Publication No. 0 264 166 (Hepatitis B surface antigen and tPA genes under control of the whey acid protein promotor for mammary tissue specific expression); EPO Publication No. 0 247 494 (transgenic mice containing heterologous genes encoding various forms of insulin); PTC Publication No. W088/00239 (tissue specific expression of a transgene encoding factor IX under control of a whey protein promoter); PTC Publication No. W088/01648 (transgenic mammal having mammary secretory cells incorporating a recombinant expression system comprising a mammary lactogen-inducible regulatory region and a structural region encoding a heterologous protein); and EPO Publication No. 0 279 582 (tissue specific expression of chloramphenicol acetyltrans-ferase under control of rat &bgr;-casein promoter in transgenic mice). The methods and DNA constructs (“transgenes”) used in making these transgenic animals also result in the random integration of all or part of the transgene into the genome of the organism. Typically, such integration occurs in an early embryonic stage of development which results in a mosaic transgenic animal. Subsequent generations can be obtained, however, wherein the randomly inserted transgene is contained in all of the somatic cells of the transgenic animals.
Transgenic plants have also been produced. For example, U.S. Pat. No. 4,801,540 to Hiatt, et al., discloses the transformation of plant cells with a plant expression vector containing tomato polygalacturonase (PG) oriented in the opposite orientation for expression. The anti-sense RNA expressed from this gene is capable of hybridizing with endogenous PG mRNA to suppress translation. This inhibits production of PG and as a consequence the hydrolysis of pectin by PG in the tomato.
While the integration of heterologous DNA into cells and organisms is potentially useful to produce transformed cells and organisms which are capable of expressing desired genes and/or polypeptides, many problems are associated with such systems. A major problem resides in the random pattern of integration of the heterologous gene into the genome of cells derived from multicellular organisms such as mammalian cells. This often results in a wide variation in the level of expression of such heterologous genes among different transformed cells. Further, random integration of heterologous DNA into the genome may disrupt endogenous genes which are necessary for the maturation, differentiation and/or viability of the cells or organism. In the case of transgenic animals, gross abnormalities are often caused by random integration of the transgene and gross rearrangements of the transgene and/or endogenous DNA often occur at the insertion site. For example, a common problem associated with transgenes designed for tissue-specific expression involves the “leakage” of expression of the transgenes. Thus, transgenes designed for the expression and secretion of a heterologous polypeptide in mammary secretory cells may also be expressed in brain tissue thereby producing adverse effects in the transgenic animal. While the reasons for transgene “leakage” and gross rearrangements of heterologous and endogenous DNA are not known with certainty, random integration is a potential cause of expression leakage.
One approach to overcome problems associated with random integration involves the use gene of targeting. This method involves the selection for homologous recombination events between DNA sequences residing in the genome of a cell or organism and newly introduced DNA sequences. This provides means for systematically altering the genome of the cell or organism.
For example, Hinnen, J. B., et al. (1978)
Proc. Natl. Acad. Sci. U.S.A.,
75, 1929-1933 report homologous recombination between a leu2+ plasmid and a leu2
−
gene in the yeast genome. Successful homologous transformants were positively selected by growth on media deficient in leucine.
For mammalian systems, several laboratories have reported the insertion of exogenous DNA sequences into specific sites within the mammalian genome by way of homologous recombination. For example, Smithies, O., et al. (1985)
Nature,
317, 230-234 report the insertion of a linearized plasmid into the genome of cultured mammalian cells near the &bgr;-globin gene by homologous recombination. The modified locus so obtained contained inserted vector sequences containing a neomycin resistance gene and a sup F gene encoding an amber suppressor t-RNA positioned between the &dgr; and &bgr;-globin structural genes. The homologous insertion of this vector also resulted in the duplication of some of the DNA sequence between the &dgr; and &bgr;-globin genes and part of the &bgr;-globin gene itself. Successful transformants were selected using a neomycin related antibiotic. Since most transformation events randomly inserted this plasmid, insertion of this plasmid by homologous recombination did not confer a selectable, cellular phenotype for homologous recombination mediated transformation. A laborious screening test for identifying predicted targeting events using plasmid rescue of the supF marker in a phage library prepared from pools of transfected colonies was used. Sib selection utilizing this assay identified the transformed cells in which homologous recombination had occurred.
A significant problem encountered in detecting and isolating cells, such as mammalian and plant cells, wherein homologous recombination events have occurred lies in the greater propensity for such cells to mediate non-homologous recombination. See Roth, D. B., et al. (1985)
Proc. Natl. Acad. Sci. U.S.A.,
82 3355-3359; Roth, D. B., et al. (1985),
Mol. Cell. Biol.,
5 2599-2607; and Paszkowski, J., et al. (1988),
EMBO J.,
7, 4021-4026. In order to identify homologous recombination events among the vast pool of random insertions generated by non-homologous recombination, early gene targeting experiments in mammalian cells were designed using cell lines carrying a mutated form of either a neomycin resistance (neo
r
) gene or a herpes simplex virus thymidine kinase (HSV-tk) gene, integrated randomly into the host genome. Such exogenous defective genes were then specifically repaired by homologous recombination with newly introduced exogenous DNA carrying the same gene bearing a different mutation. Productive gene targeting events were identified by selection for cells with the wild type phenot
Capecchi Mario R.
Thomas Kirk R.
Baker Ann-Marie
Campell Bruce R.
Townsend and Townsend / and Crew LLP
University of Utah Research Foundation
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