To the Editor:Ruiz-Pesini et al. (2000xHuman mtDNA haplogroups associated with high or reduced spermatozoa motility. Ruiz-Pesini, E, Lapena, A-C, Diez-Sanchez, C, Perez-Martos, A, Montoya, J, Alvarez, E, Diaz, M, Urries, A, Montoro, L, Lopez-Perez, MJ, and Enriquez, J. Am J Hum Genet. 2000; 67: 682–696Abstract | Full Text | Full Text PDF | PubMed | Scopus (300)See all References2000) cleverly show that extant human mtDNA variation affects sperm function. They find that mitochondrial haplogroup T is overrepresented in asthenozoospermic populations and shows reduced sperm oxidative phosphorylation pathway (OXPHOS) activity, relative to the H haplogroup that is overrepresented in nonasthenozoospermic populations. These authors—as well as Moore and Reijo-Pera (2000xMale sperm motility dictated by mother's mtDNA. Moore, FL and Reijo-Pera, RA. Am J Hum Genet. 2000; 67: 543–548Abstract | Full Text | Full Text PDF | PubMed | Scopus (40)See all References2000), in the accompanying invited editorial—stress that, because of the exclusive matrilinear inheritance of mitochondria, mutations of mtDNA purely affecting male fertility are not selected against and therefore can become fixed. The absence of a direct check against mitochondrial mutations that affect male fertility is unfortunate and begs the question of why such a pattern became established.In keeping with an earlier suggestion (Giannelli 1986xDNA maintenance and its relation to human pathology. Giannelli, F. J Cell Science Suppl. 1986; 4: 383–416Crossref | PubMedSee all References1986), I propose that the exclusion of sperm mitochondria from the zygote is part of a scheme enabling mitochondria to provide an indirect measure of sperm quality and, hence, to favor fertilization by optimal spermatozoa while avoiding the risk of passing on mtDNA exposed to high physiological stress and, hence, potential damage. This would clearly have adaptive value and could help justify the establishment of matrilineal mitochondrial inheritance.There is evidence that mitochondria have a role in germ-cell selection. Krakauer and Mira (1999xMitochondria and germ-cell death. Krakauer, DC and Mira, A. Nature. 1999; 400: 125–126Crossref | PubMed | Scopus (95)See all References1999), in a phylogenetic study, note that species producing fewer offspring have fewer egg mitochondria and experience greater ovarian atresia, and these authors conclude that lower numbers of mitochondria offer greater opportunities for variation in mitochondrial function and, thus, for elimination of eggs with poor mitochondria. This results in purifying selective pressure on mitochondrial genomes. Some proof of a mitochondrial role in ovarian atresia exists, as microinjection of 5 × 103 mitochondria from nonapoptotic follicular granulosa rescues the oocytes from FVB-strain mice that undergo an inherently high rate of apoptosis in vitro (Perez et al. 2000xMitochondria and the death of oocytes. Perez, GI, Trbovich, AM, Gosden, RG, and Tilly, JL. Nature. 2000; 403: 500–501Crossref | PubMed | Scopus (98)See all References2000). With regard to spermatozoa, Ruiz-Pesini et al. (2000xHuman mtDNA haplogroups associated with high or reduced spermatozoa motility. Ruiz-Pesini, E, Lapena, A-C, Diez-Sanchez, C, Perez-Martos, A, Montoya, J, Alvarez, E, Diaz, M, Urries, A, Montoro, L, Lopez-Perez, MJ, and Enriquez, J. Am J Hum Genet. 2000; 67: 682–696Abstract | Full Text | Full Text PDF | PubMed | Scopus (300)See all References2000) provide direct evidence that mitochondrial function is critical to their motility and hence presumably to their success in fertilization.Nevertheless, egg and sperm differ dramatically in their mitochondrial complement, since the human oocyte has 106 mtDNA molecules, whereas mature spermatozoa have only 100 (Cummings 1998xMitochondrial DNA in mammalian reproduction. Cummings, J. Rev Reprod. 1998; 3: 172–182Crossref | PubMed | Scopus (106)See all References1998). It follows that spermatozoa should be exquisitely sensitive to mitochondrial malfunction.I suggest that this allows mitochondria to become both a sensitive meter of genetic damage to sperm and the means of selecting, at fertilization, spermatozoa derived from the germ-cell lines that have best preserved the quality of their genome during postzygotic life. However, reliance on a small complement of mitochondria to produce very high levels of kinetic energy in conditions of unusually high oxygen tension in the female genital tract exposes sperm mtDNA to extraordinary risks from oxygen radicals, and, therefore, the disposal of mtDNA at zygote formation also seems advantageous. To provide a sensitive, indirect measure of the quality of the sperm genome, the mitochondrial complement of a spermatozoon must meet two conditions: it should not afford a high degree of functional redundancy, and it must offer a target for deleterious mutations larger than the nuclear genome.The results of Ruiz-Pesini et al. (2000xHuman mtDNA haplogroups associated with high or reduced spermatozoa motility. Ruiz-Pesini, E, Lapena, A-C, Diez-Sanchez, C, Perez-Martos, A, Montoya, J, Alvarez, E, Diaz, M, Urries, A, Montoro, L, Lopez-Perez, MJ, and Enriquez, J. Am J Hum Genet. 2000; 67: 682–696Abstract | Full Text | Full Text PDF | PubMed | Scopus (300)See all References2000) suggest that the former is true, because a mitochondrial haplogroup associated with modest OXPHOS deficit is associated with asthenozoospermia. More-direct experimental evidence on this point would require the inactivation of a proportion of the mitochondria and subsequent examination of sperm function. Such evidence is not available, but, since each human spermatozoon competes with 108 colleagues for a single oocyte, it seems probable that a sperm needs all of the energy its 100 mitochondria can produce.It is reasonable to conclude that the mitochondrial complement of a spermatozoon offers a sufficiently large target for deleterious mutations, for the following reasons. The germinal mutation rate for mtDNA is 50-fold greater than that for genomic DNA. Human mitochondria have no introns, intergenic sequences, or complex, large centromeres and telomeres, and they have nonredundant gene sequences that even show some overlap. In contrast, nuclear coding sequences are highly dispersed (International Human Genome Sequencing Consortium 2001xInitial sequencing and analysis of the human genome. International Human Genome Sequencing Consortium. Nature. 2001; 409: 860–921Crossref | PubMed | Scopus (12719)See all References2001) and show some degree of functional redundancy. Therefore, the essential information content of mtDNA can be considered to be at least 100-fold greater than that of a nuclear DNA segment of similar length. It follows that the effective target for deleterious mutations presented by a mtDNA molecule should be equivalent to 16,569 bp × 50 × 100 = 83 Mb of genomic DNA. This is ∼1/36 of the haploid genome. Therefore, the 100 mtDNA molecules of a spermatozoon offer a target for deleterious mutation equivalent to 2.8 haploid genomes. Thus, if the functional redundancy of the mitochondrial complement of a spermatozoon, in terms of its competition with 108 other spermatozoa, is