Janet Loring

Hybrid vigor, fetal overgrowth, and viability of mice derived by nuclear cloning and tetraploid embryo complementation

To assess whether heterozygosity of the donor cell genome was a general parameter crucial for long-term survival of cloned animals, we tested the ability of embryonic stem (ES) cells with either an inbred or F1 genetic background to generate cloned mice by nuclear transfer. Most clones derived from five F1 ES cell lines survived to adulthood. In contrast, clones from three inbred ES cell lines invariably died shortly after birth due to respiratory failure. Comparison of mice derived from nuclear cloning, in which a complete blastocyst is derived from a single ES cell, and tetraploid blastocyst complementation, in which only the inner cell mass is formed from a few injected ES cells, allows us to determine which phenotypes depend on the technique or on the characteristics of the ES cell line. Neonatal lethality also has been reported in mice entirely derived from inbred ES cells that had been injected into tetraploid blastocysts (ES cell-tetraploids). Like inbred clones, ES cell-tetraploid pups derived from inbred ES cell lines died shortly after delivery with signs of respiratory distress. In contrast, most ES cell-tetraploid neonates, derived from six F1 ES cell lines, developed into fertile adults. Cloned pups obtained from both inbred and F1 ES cell nuclei frequently displayed increased placental and birth weights whereas ES cell-tetraploid pups were of normal weight. The potency of F1 ES cells to generate live, fertile adults was not lost after either long-term in vitro culture or serial gene targeting events. We conclude that genetic heterozygosity is a crucial parameter for postnatal survival of mice that are entirely derived from ES cells by either nuclear cloning or tetraploid embryo complementation. In addition, our results demonstrate that tetraploid embryo complementation using F1 ES cells represents a simple, efficient procedure for deriving animals with complex genetic alterations without the need for a chimeric intermediate.

Complementary roles of BDNF and NT-3 in vestibular and auditory development

The physiological role of BDNF and NT-3 in the development of the vestibular and auditory systems was investigated in mice that carry a deleted BDNF and/or NT-3 gene. BDNF was the major survival factor for vestibular ganglion neurons, and NT-3, for spiral ganglion neurons. Lack of BDNF and NT-3 did not affect ingrowth of nerve fibers into the vestibular epithelium, but BDNF mutants failed to maintain afferent and efferent innervation. In the cochlea, BDNF mutants lost type 2 spiral neurons, causing an absence of outer hair cell innervation. NT-3 mutants showed a paucity of afferents and lost 87% of spiral neurons, presumably corresponding to type 1 neurons, which innervate inner hair cells. Double mutants had an additive loss, lacking all vestibular and spiral neurons. These results show that BDNF and NT-3 are crucial for inner ear development and, although largely coexpressed, have distinct and nonoverlapping roles in the vestibular and auditory systems.

Trisomy eight in ES cells is a common potential problem in gene targeting and interferes with germ line transmission.

The ability to contribute to the germ line is the most important experimental feature of embryonic stem (ES) cells. Using ES cells, it is possible to introduce targeted mutations into any gene and to derive the corresponding mutant mice. A common problem with this technology is that the ES cells often lack or have only a low efficiency of germ line transmission. To address this issue, we examined the relationship between the growth rate and karyotype of ES cells, and their ability to contribute to the germ line. We found that chromosomal abnormalities occurred rather frequently in ES cells. Cells having an abnormal number of chromosomes, in particular trisomy 8, were found in three independently derived ES cell lines, and this abnormality conferred a selective growth advantage on these cells. Selection of abnormal cells led to depletion and eventual loss of normal ES cells during consecutive passages. In comparison with parental ES cells, ES cells with trisomy 8 contributed rarely to the germ line. This realization allowed us to select, based upon ES cell clone morphology, those clones with the highest probability of contributing to the germ line. This insight is of practical value for any given gene targeting experiment as it permits optimization of the rate of success without having to rely on more elaborate tests such as karyotyping individual clones prior to blastocyst injection. Dev. Dyn. 209:85–91, 1997.

Male and female mice derived from the same embryonic stem cell clone by tetraploid embryo complementation

We have devised a general strategy for producing female mice from 39,X0 embryonic stem (ES) cells derived from male cell lines carrying a targeted mutation of interest. We show that the Y chromosome is lost in 2% of subclones from 40,XY ES cell lines, making the identification of targeted 39,X0 subclones a routine procedure. After gene targeting, male and female mice carrying the mutation can be generated by tetraploid embryo complementation from the 40,XY ES cell line and its 39,X0 derivatives. A single intercross then produces homozygous mutant offspring. Because this strategy avoids outcrossing and therefore segregation of mutant alleles introduced into the ES cells, the time and expense required for production of experimental mutant animals from a targeted ES cell clone are substantially reduced. Our data also indicate that ES cells have inherently unstable karyotypes, but this instability does not interfere with production of adult ES cell–tetraploid mice.

Requirement for Neurotrophin-3 in the Development of the Muscle Proprioceptive System

Publisher Summary The phenotype of mice carrying a mutation of the p75 NGFR gene suggests that the low-affinity receptor is also important for neurotrophin interactions in vivo , and it modulates ligand interactions with the high-affinity receptor. The high-affinity receptors are restricted to a subpopulation of neurons expressing p75 NGFR . The identification and cDNA cloning of the members of the Trk family of tyrosine kinase receptors led to the discovery that these are signal-transducing receptors for the neurotrophins. Nerve growth factor binds and activates the TrkA receptor, brain-derived neurotrophic factor and NT-4 share the signal-transducing receptor, and TrkB and NT-3 bind and activate TrkC. There are conflicting results as to whether NT-3 also interacts with the TrkA and TrkB receptors. However, in a more neuronal-like context of PC12 cells, NT-3 insufficiently activates the TrkA and TrkB receptors. The NT-3 mutant mice display a loss of neurons in all the peripheral sensory and sympathetic ganglia examined. However, the survival of α-motor neurons was not affected in the NT-3 mutant mice. These results are consistent with previous results from culture studies and manipulations of the embryo and confirm a physiological role for NT-3 during development of the nervous system.