Rare creation of recombinant mtDNA haplotypes in mammalian tissues

被引：44

作者：

Sato, A

Nakada, K

Akimoto, M

Ishikawa, K

Ono, T

Shitara, H

Yonekawa, H

Hayashi, JL ^{[1
]}

机构：

[1] Univ Tsukuba, Inst Biol Sci, Grad Sch Life & Environm Sci, Tsukuba, Ibaraki 3058572, Japan

[2] Univ Tsukuba, Ctr Tsukuba Adv Res Alliance, Tsukuba, Ibaraki 3058572, Japan

[3] Tokyo Metropolitan Inst Med Sci, Dept Lab Anim Sci, Tokyo 1138613, Japan

[4] Japan Sci & Technol Agcy, Precursory Res Embryon Sci & Technol, Saitama 3320012, Japan

来源：

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA | 2005年 / 102卷 / 17期

关键词：

mammalian mtDNA; gene conversion; somatic hybrids; mito-mice; PCR jumping;

D O I：

10.1073/pnas.0408666102

中图分类号：

O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];

学科分类号：

07 ; 0710 ; 09 ;

摘要：

The problem of whether recombinant mtDNAs are created in mammalian cells has been controversial for many years. We show convincing evidence for the very rare creation of recombinant mtDNA haplotypes by isolating human somatic hybrid cells and by generating mice carrying two different mtDNA haplotypes. To avoid misinterpretation of PCR-jumping products as recombinants, we used purified rntDNAs for cloning and sequencing. The results showed that only three of 318 clones of mtDNA purified from mouse tissues corresponded to recombinant mtDNA haplotypes, whereas no recombinants were found in human somatic hybrid cells. Such an extremely low frequency of mtDNA recombination does not require any revision of important concepts on human evolution that are based on its absence. Considering the high concentration of reactive oxygen species around the mtDNA and its frequent strand breakage, recombinant clones would correspond to gene conversion products created by repair of nucleotide mismatches.

引用

页码：6057 / 6062

页数：6

共 38 条

[1] Reanalysis and revision of the Cambridge reference sequence for human mitochondrial DNA
Andrews, RM
Kubacka, I
Chinnery, PF
Lightowlers, RN
Turnbull, DM
Howell, N
[J]. NATURE GENETICS, 1999, 23 (02) : 147 - 147
[2] Inter-mitochondrial complementation of mtDNA mutations and nuclear context
Attardi, G
Enriquez, JA
Cabezas-Herrera, J
[J]. NATURE GENETICS, 2002, 30 (04) : 360 - 360
[3] Linkage disequilibrium and recombination in hominid mitochondrial DNA
Awadalla, P
Eyre-Walker, A
Smith, JM
[J]. SCIENCE, 1999, 286 (5449) : 2524 - 2525
[4] MITOCHONDRIAL RECOMBINATION IN CYTOPLASMIC HYBRIDS OF NICOTIANA-TABACUM BY PROTOPLAST FUSION
BELLIARD, G
VEDEL, F
PELLETIER, G
[J]. NATURE, 1979, 281 (5730) : 401 - 403
[5] SEQUENCE AND GENE ORGANIZATION OF MOUSE MITOCHONDRIAL-DNA
BIBB, MJ
VANETTEN, RA
WRIGHT, CT
WALBERG, MW
CLAYTON, DA
[J]. CELL, 1981, 26 (02) : 167 - 180
[6] RELAXED CELLULAR CONTROLS AND ORGANELLE HEREDITY
BIRKY, CW
[J]. SCIENCE, 1983, 222 (4623) : 468 - 475
[7] NOVEL COMPOSITION OF MITOCHONDRIAL GENOMES IN PETUNIA SOMATIC HYBRIDS DERIVED FROM CYTOPLASMIC MALE STERILE AND FERTILE PLANTS
BOESHORE, ML
LIFSHITZ, I
HANSON, MR
IZHAR, S
[J]. MOLECULAR & GENERAL GENETICS, 1983, 190 (03): : 459 - 467
[8] MITOCHONDRIAL-DNA AND HUMAN-EVOLUTION
CANN, RL
STONEKING, M
WILSON, AC
[J]. NATURE, 1987, 325 (6099) : 31 - 36
[9] MELAS MUTATION IN MTDNA BINDING-SITE FOR TRANSCRIPTION TERMINATION FACTOR CAUSES DEFECTS IN PROTEIN-SYNTHESIS AND IN RESPIRATION BUT NO CHANGE IN LEVELS OF UPSTREAM AND DOWNSTREAM MATURE TRANSCRIPTS
CHOMYN, A
MARTINUZZI, A
YONEDA, M
DAGA, A
HURKO, O
JOHNS, D
LAI, ST
NONAKA, I
ANGELINI, C
ATTARDI, G
[J]. PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 1992, 89 (10) : 4221 - 4225
[10] DUJON B, 1974, GENETICS, V78, P415

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