In genetics, paternal mtDNA transmission and paternal mtDNA inheritance refer to the incidence of paternal mitochondrial DNA (mtDNA) being passed on to offspring. Paternal mtDNA inheritance is observed in a small number of species, but in the vast majority, mtDNA is believed to be passed unchanged^[1] from a mother to her offspring.

In animals

Paternal mtDNA inheritance in animals varies. For example, in Mytilidae mussels, paternal mtDNA "is transmitted through the sperm and establishes itself only in the male gonad." ^[2][3][4] In testing 172 sheep, "The Mitochondrial DNA from three lambs in two half-sib families were found to show paternal inheritance."^[5]

Mitochondria in mammalian sperm are usually destroyed by the egg cell after fertilization. In 1999 it was reported that paternal sperm mitochondria (containing mtDNA) are marked with ubiquitin to select them for later destruction inside the embryo^[6]. Some in vitro fertilization techniques, particularly injecting a sperm into an oocyte, may interfere with this.

In humans

Many sources, notably companies that sell genealogical DNA tests, state that paternal mtDNA is never transmitted to offspring. This belief is central to mtDNA genealogical DNA testing and to the theory of mitochondrial Eve. However, there have been some studies that claimed to have found some cases of paternal mitochondrial inheritance in humans (e.g. Schwarz & Vissing 2002), and it was proposed that in sexual reproduction, the tail of the sperm does enter the egg, and thus "paternal leakage" may occur.

The ideas about human paternal leakage were summed up in the 1996 study Misconceptions about mitochondria and mammalian fertilization: Implications for theories on human evolution: ^[7]

The mixing of maternal and paternal mtDNA was thought to have been found in humans and chimpanzees.^[8][9] However, there has been only a single possible case of human paternal mitochondrial DNA transmission. All other reported cases can be ascribed solely to contamination and sample mix up.

Responses to this evidence involves saying that so little paternal mtDNA is transmitted as to be negligible ("Some researchers argue that a fragment of the father's mtDNA is in fact passed on, though it represents much less than 1 percent of the total."^[10]) or saying that paternal mtDNA is so rarely transmitted as to be negligible ("Nevertheless, studies have established that paternal mtDNA is so rarely transmitted to offspring that mtDNA analyses remain valid..."^[11]). It has also been said in early studies that about 1-2% of a person's mitochondria can be inherited from the father ^[12].

According to the 2005 study More evidence for non-maternal inheritance of mitochondrial DNA?: ^[13] In addition, heteroplasmy is a "newly discovered form of inheritance for mtDNA. Heteroplasmy introduces slight statistical uncertainty in normal inheritance patterns."^[14] Heteroplasmy occurs when two slightly different mitochondrial sequences are inherited from the mother, as a result of several hundred mitochondria being present in the ovum.

On the other side of the issue are people who want to dismiss maternal mtDNA inheritance completely. A surname project tutorial states, "A male will rarely get his father's mtDNA. So far, this has been observed one time in the past 20 years of research." ^[15] This single instance is cited as evidence that the whole field of human mitochondrial genetics is invalid.

In either case, these phenomena throw doubt on the theory that all mtDNA can be traced back to a single female. This theory of mitochondrial Eve, which aims to trace all humans to "a woman living in sub-Saharan Africa about 200,000 years ago"^[16] allows no room for the inheritance of paternal mtDNA.

In protozoa

Some organisms, such as Cryptosporidium, have mitochondria with no DNA whatsoever.

In plants

It has also been reported that mitochondria can occasionally be inherited from the father, e.g. in bananas. Some Conifers also show paternal inheritance of mitochondria, such as the coast redwood, Sequoia sempervirens.

References and notes

See also

• Y-chromosomal Adam
• Patrilineality
• Matrilineality
• Human mitochondrial genetics
• Human migration
• RecLOH
• List of genetic genealogy topics

External links

• No evidence for paternal mtDNA transmission to offspring or extra-embryonic tissues after ICSI by D.R. Marchington, M.S.G. Scott Brown, V.K. Lamb, R.J.T. van Golde, J.A.M. Kremer, J.H.A.M. Tuerlings, E.C.M. Mariman, A.H. Balen and J. Poulton
• The Mutation Rate in the Human mtDNA Control Region by Sigrún Sigurđardóttir, Agnar Helgason, Jeffrey R. Gulcher, Kári Stefansson, and Peter Donnelly
• Mitochondrial disorders by Massimo Zeviani and Stefano Di Donato
• The Mitochondrial Genome in Embryo Technologies by S Hiendleder and E Wolf
• Inheritance and recombination of mitochondrial genomes in plants, fungi and animals (PDF) by Camille M. Barr, Maurine Neiman and Douglas R. Taylor, 2005
• No evidence for paternal mtDNA transmission to offspring or extra-embryonic tissues after ICSI by D.R. Marchington, M.S.G. Scott Brown, V.K. Lamb, R.J.T. van Golde, J.A.M. Kremer, J.H.A.M. Tuerlings, E.C.M. Mariman, A.H. Balen and J. Poulton
• Paternal inheritance of mitochondrial DNA (PDF) by Marianne Schwartz and John Vissing, 2002
• Paradise lost: Mitochondrial eve refuted by M. Pickford, July 2006
• PubMed:
  • search results for "paternal leakage"
  • search results for "paternal mtDNA"
  • search results for "father's mtDNA"
  • search results for "papers about human mitochondrial DNA phylogenetics"

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