Transmission of human mitochondrial DNA along the paternal lineage in transmitochondrial mice.

Previously we obtained heteroplasmic mice carrying murine and human mitochondrial DNA (mtDNA). Even the fourth generation of such mice had human mtDNA in their organs, hence, they were used to study the possibility of paternal mtDNA transmission. A lineage was obtained in which human mtDNA was transmitted by males to the progeny in four successive generations. This is the first observation of such a continuous paternal transmission of mtDNA. Persistence of paternal mtDNA in several successive generations of animals suggests that mechanisms aimed at elimination of paternally inherited mtDNA species are not as strict as has been postulated.

Assaying the probabilities of obtaining maternally inherited heteroplasmy as the basis for modeling OXPHOS diseases in animals.

Gross alterations in cell energy metabolism underlie manifestations of hereditary OXPHOS (oxidative phosphorylation) diseases, many of which depend on proportion of mutant mitochondrial DNA (mtDNA) in tissues. An animal model of OXPHOS disease with maternal inheritance of mitochondrial heteroplasmy might help understanding the peculiarities of abnormal mtDNA distribution and its effect on pre- and postnatal development. Previously we obtained mice that carry human mtDNA in some tissues. It co-existed with murine mtDNA (heteroplasmy) and was transmitted maternally to the progeny of animals developed from zygotes injected with human mitochondria. To analyze the probability of obtaining heteroplasmic mice we increased the number of experiments with early embryos and obtained more specimens from F1. About 33% of zygotes injected with human mtDNA developed into post-implantation embryos (7th-13th days). Lower amount of such developed into neonate mice (ca. 21%). Among post-implantation embryos and in generations F0 and F1 percentages of human mtDNA-carriers were ca. 14-16%. Such percentages are sufficient for modeling maternally inherited heteroplasmy in small animal groups. More data are needed to understand the regularities of anomalous mtDNA distribution among cells and tissues and whether heart and muscles frequently carrying human mtDNA in our experiments are particularly susceptible to heteroplasmy.

Obtaining mice that carry human mitochondrial DNA transmitted to the progeny.

To study human diseases associated with mutations in mitochondrial DNA one needs an animal model in which the distribution of abnormal mtDNA and its impact on the phenotype might be followed. We isolated human mitochondria from HepG2 cell culture and microinjected them into murine zygotes, upon which those were transplanted to the pseudopregnant mice. PCR with species-specific primers allowed detecting human mtDNA in the tissues of 7-13-day embryos. No serious alterations in the development of transmitochondrial embryos were noticed. Among various organs/tissues of the 13-day embryos, human mtDNA was detected only in the heart, skeletal muscles, and stomach, which is in line with its uneven distribution among the blastomeres of an early mouse embryo that we described previously. In four recipient females, the microinjected zygotes were allowed to develop to term, the four neonate males of their joint litter were sacrificed, and in three of them human mtDNA was detected in the heart, skeletal muscles, stomach, brain, testes, and bladder. Six females of that joint litter were grown and mated to intact males. In the progeny (F1) of one of the females two mice were carrying human mtDNA in the heart, skeletal muscles, stomach, brain, lungs, uterus, ovaries, and kidneys. The study confirms the possibility to obtain transmitochondrial mice carrying human mtDNA that is transmitted to the animals of the next generation. Our results also indicate that among the organs to which human mtDNA is distributed some are more likely to receive it than others.

A Russian family of Slavic origin carrying mitochondrial DNA with a 9-bp deletion in region V and a long C-stretch in D-loop.

A 9-bp deletion first described in the mitochondrial DNA (mtDNA) for East Asian, Polynesian or Indian American populations of the B haplogroup is now discovered in Slavs. The Russian family carrying that deletion belongs to a new branch of the T haplogroup as deduced from D-loop sequence and haplogroup-specific restriction fragment length polymorphism analysis. One family member had a Kearns-Sayre syndrome with a 5.5 kb mtDNA deletion. This family also presented a long C-stretch in the D-loop. Whether or not the formation of the 5.5 kb deletion might be related to the 9-bp deletion or to the long C-stretch in the D-loop is discussed.