Multicellular living organisms and unmodified parts thereof and – Method of making a transgenic nonhuman animal – Via microinjection of a nucleus into an embryo – egg cell – or...
Reexamination Certificate
2000-08-29
2003-02-25
Crouch, Deborah (Department: 1632)
Multicellular living organisms and unmodified parts thereof and
Method of making a transgenic nonhuman animal
Via microinjection of a nucleus into an embryo, egg cell, or...
C800S014000, C800S015000, C800S016000, C800S017000, C800S018000, C435S325000, C435S375000, C435S376000, C435S377000
Reexamination Certificate
active
06525243
ABSTRACT:
This invention relates to the generation of animals including but not being limited to genetically selected and/or modified animals, and to cells useful in their generation.
The reconstruction of mammalian embryos by the transfer of a donor nucleus to an enucleated oocyte or one cell zygote allows the production of genetically identical individuals. This has clear advantages for both research (i.e. as biological controls) and also in commercial applications (i.e. multiplication of genetically valuable livestock, uniformity of meat products, animal management).
Embryo reconstruction by nuclear transfer was first proposed (Spemann, Embryonic Development and Induction 210-211 Hofner Publishing Co., New York (1938)) in order to answer the question of nuclear equivalence or do nuclei change during development?. By transferring nuclei from increasingly advanced embryonic stages these experiments were designed to determine at which point nuclei became restricted in their developmental potential. Due to technical limitations and the unfortunate death of Spemann these studies were not completed until 1952, when it was demonstrated in the frog that certain nuclei could direct development to a sexually mature adult (Briggs and King,
Proc. Natl. Acad. Sci. USA
38 455-461 (1952)). Their findings led to the current concept that equivalent totipotent nuclei from a single individual could, when transferred to an enucleated egg, give rise to “genetically identical” individuals. In the true sense of the meaning these individuals would not be clones as unknown cytoplasmic contributions in each may vary and also the absence of any chromosomal rearrangements would have to be demonstrated.
Since the demonstration of embryo cloning in amphibians, similar techniques have been applied to mammalian species. These techniques fall into two categories:
1) transfer of a donor nucleus to a matured metaphase II oocyte which has had its chromosomal DNA removed and
2) transfer of a donor nucleus to a fertilised one cell zygote which has had both pronuclei removed. In ungulates the former procedure has become the method of choice as no development has been reported using the latter other than when pronuclei are exchanged.
Transfer of the donor nucleus into the oocyte cytoplasm is generally achieved by inducing cell fusion. In ungulates fusion is induced by application of a DC electrical pulse across the contact/fusion plane of the couplet. The same pulse which induces cell fusion also activates the recipient oocyte. Following embryo reconstruction further development is dependent on a large number of factors including the ability of the nucleus to direct development i.e. totipotency, developmental competence of the recipient cytoplast (i.e. oocyte maturation), oocyte activation, embryo culture (reviewed Campbell and Wilmut in Vth
World Congress on Genetics as Applied to Livestock
20 180-187 (1994)).
In addition to the above we have shown that maintenance of correct ploidy during the first cell cycle of the reconstructed embryo is of major importance (Campbell et al.,
Biol. Reprod
. 49 933-942 (1993); Campbell et al.,
Biol. Reprod
. 50 1385-1393 (1994)). During a single cell cycle all genomic DNA must be replicated once and only once prior to mitosis. If any of the DNA either fails to replicate or is replicated more than once then the ploidy of that nucleus at the time of mitosis will be incorrect. The mechanisms by which replication is restricted to a single round during each cell cycle are unclear, however, several lines of evidence have implicated that maintenance of an intact nuclear membrane is crucial to this control. The morphological events which occur in the donor nucleus after transfer into an enucleated metaphase II oocyte have been studied in a number of species including mouse (Czolowiska et al.,
J. Cell Sci
. 69 19-34 (1984)), rabbit (Collas and Robl,
Biol. Reprod
. 45 455-465 (1991)), pig (Prather et al.,
J. Exp. Zool
. 225 355-358 (1990)), cow (Kanka et al.,
Mol. Reprod. Dev
. 29 110-116 (1991)). Immediately upon fusion the donor nuclear envelope breaks down (NEBD), and the chromosomes prematurely condense (PCC). These effects are catalysed by a cytoplasmic activity termed maturation/mitosis/meiosis promoting factor (MPF). This activity is found in all mitotic and meiotic cells reaching a maximal activity at metaphase. Matured mammalian oocytes are arrested at metaphase of the 2 nd meiotic division (metaphase II) and have high MPF activity. Upon fertilisation or activation MPF activity declines, the second meiotic division is completed and the second polar body extruded, the chromatin then decondenses and pronuclear formation occurs. In nuclear transfer embryos reconstructed when MPF levels are high NEBD and PCC occur; these events are followed, when MPF activity declines, by chromatin decondensation and nuclear reformation and subsequent DNA replication. In reconstructed embryos correct ploidy can be maintained in one of two ways; firstly by transferring nuclei at a defined cell cycle stage, e.g. diploid nuclei of cells in G
1
, into metaphase II oocytes at the time of activation; or secondly by activating the recipient oocyte and transferring the donor nucleus after the disappearance of MPF activity. In sheep this latter approach has yielded an increase in the frequency of development to the blastocyst stage from 21% to 55% of reconstructed embryos when using blastomeres from 16 cell embryos as nuclear donors (Campbell et al.,
Biol. Reprod
. 50 1385-1393 (1994)).
These improvements in the frequency of development of is reconstructed embryos have as yet not addressed the question of nuclear reprogramming. During development certain genes become “imprinted” i.e. are altered such that they are no longer transcribed. Studies on imprinting have shown that this “imprinting” is removed during germ cell formation (i.e. reprogramming). One possibility is that this reprogramming is affected by exposure of the chromatin to cytoplasmic factors which are present in cells undergoing meiosis. This raises the question of how we may mimic this situation during the reconstruction of embryos by nuclear transfer in order to reprogram the developmental clock of the donor nucleus.
It has now been found that nuclear transfer into an oocyte arrested in metaphase II can give rise to a viable embryo if normal ploidy (i.e. diploidy) is maintained and if the embryo is not activated at the time of nuclear transfer. The delay in activation allows the nucleus to remain exposed to the recipient cytoplasm.
According to a first aspect of the present invention there is provided a method of reconstituting an animal embryo, the method comprising transferring a diploid nucleus into an oocyte which is arrested in the metaphase of the second meiotic division without concomitantly activating the oocyte, keeping the nucleus exposed to the cytoplasm of the recipient for a period of time sufficient for the reconstituted embryo to become capable of giving rise to a live birth and subsequently activating the reconstituted embryo while maintaining correct ploidy. At this stage, the reconstituted embryo is a single cell.
In principle, the invention is applicable to all animals, including birds such as domestic fowl, amphibian species and fish species. In practice, however, it will be to non-human animals, especially non-human mammals, particularly placental mammals, that the greatest commercially useful applicability is presently envisaged. It is with ungulates, particularly economically important ungulates such as cattle, sheen, goats, water buffalo, camels and pigs that the invention is likely to be most useful, both as a means for cloning animals and as a means for generating transgenic animals. It should also be noted that the invention is also likely to be applicable to other economically important animal species such as, for example, horses, llamas or rodents, e.g. rats or mice, or rabbits.
The invention is equally applicable in the production of transgenic, as well as non-transgenic animals. Transgenic animals may be
Campbell Keith Henry Stockman
Wilmut Ian
Crouch Deborah
Roslin Institute
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