Gain of deleterious function causes an autoimmune response and Bateson–Dobzhansky–Muller incompatibility in rice

Yamamoto, Eiji; Takashi, Tomonori; Morinaka, Yoichi; Lin, Shaoyang; Wu, Jianzhong; Matsumoto, Takashi; Kitano, Hidemi; Matsuoka, Makoto; Ashikari, Motoyuki

doi:10.1007/s00438-010-0514-y

Cited by 104 publications

(116 citation statements)

References 46 publications

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“…On the other hand, it was recently shown that a hybrid lethality allele has risen to high frequency in a population of M. guttatus due to linked selection for an allele that confers copper tolerance (Wright et al 2013). Natural selection is also presumed to play a role in divergence among disease resistance genes that cause hybrid necrosis in Arabidopsis and rice (Kruger et al 2002;Alcazar et al 2009;Jeuken et al 2009;Yamamoto et al 2010;Chen et al 2014), although direct population genetic evidence is lacking. Likewise, the genes that cause cytoplasmic male sterility between Mimulus species (involving the same IM62 and SF lines used in this study) seem more likely to have evolved by selfish mitochondrial evolution and compensatory nuclear coevolution than by genetic drift (Barr and Fishman 2010).…”

Section: Discussionmentioning

confidence: 99%

“…There are also hints that natural selection can contribute to the spread of incompatible alleles within populations and species. For example, plant hybrid necrosis has been mapped repeatedly to disease resistance genes (Krüger et al 2002; Alcazar et al 2009;Jeuken et al 2009;Yamamoto et al 2010;Chen et al 2014), which are likely targets of adaptive divergence to unique pathogen communities (Bomblies and Weigel 2007). Additionally, many hybrid incompatibility genes show molecular signatures of positive selection (Presgraves et al 2003;Brideau et al 2006;Maheshwari et al 2008;Oliver et al 2009;Phadnis and Orr 2009;Tang and Presgraves 2009), but, interestingly, few of these genes seem to be involved in classical ecological adaptation.…”

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Evidence of Natural Selection Acting on a Polymorphic Hybrid Incompatibility Locus in Mimulus

Sweigart

Flagel

2014

Genetics

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As a common cause of reproductive isolation in diverse taxa, hybrid incompatibilities are fundamentally important to speciation. A key question is which evolutionary forces drive the initial substitutions within species that lead to hybrid dysfunction. Previously, we discovered a simple genetic incompatibility that causes nearly complete male sterility and partial female sterility in hybrids between the two closely related yellow monkeyflower species Mimulus guttatus and M. nasutus. In this report, we fine map the two major incompatibility loci-hybrid male sterility 1 (hms1) and hybrid male sterility 2 (hms2)-to small nuclear genomic regions (each ,70 kb) that include strong candidate genes. With this improved genetic resolution, we also investigate the evolutionary dynamics of hms1 in a natural population of M. guttatus known to be polymorphic at this locus. Using classical genetic crosses and population genomics, we show that a 320-kb region containing the hms1 incompatibility allele has risen to intermediate frequency in this population by strong natural selection. This finding provides direct evidence that natural selection within plant species can lead to hybrid dysfunction between species.KEYWORDS speciation; hybrid incompatibilities; postzygotic reproductive isolation; Mimulus; monkeyflower S PECIATION occurs when diverging populations accumulate genetic differences that cause reproductive isolation. Many forms of prezygotic reproductive isolation likely evolve as byproducts of adaptation to different ecological conditions (e.g., habitat or behavioral differences), but the evolutionary dynamics of intrinsic postzygotic isolation are less clear. This is because the production of dead or sterile hybrids cannot be favored by natural selection. Dobzhansky (1937) and Muller (1942) proposed a solution to this long-standing mystery (Darwin 1859), explaining that a new mutation might function perfectly well with alleles present in its native species, and only cause sterility or inviability when found in a hybrid genetic background. The so-called Dobzhansky-Muller model shows that natural selection need not oppose the evolution of hybrid dysfunction, but it makes no predictions about the nature of the genetic changes or the evolutionary forces that give rise to hybrid incompatibilities.The recent identification of several hybrid incompatibility genes in diverse taxa has begun to reveal some insights into the evolution of hybrid dysfunction (reviewed in Presgraves 2010; Maheshwari and Barbash 2011;Sweigart and Willis 2012). In Arabidopsis and rice, genetic incompatibilities have been mapped to duplicate genes that carry loss-of-function alleles in alternate copies (Bikard et al. 2009;Mizuta et al. 2010;Yamagata et al. 2010), suggesting that divergence among paralogs via mutation and genetic drift might cause postzygotic reproductive isolation (Lynch and Force 2000). There are also hints that natural selection can contribute to the spread of incompatible alleles within populations and species. For example, ...

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Evidence of Natural Selection Acting on a Polymorphic Hybrid Incompatibility Locus in Mimulus

Sweigart

Flagel

2014

Genetics

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“…Alcázar et al (2009) fine mapped a causal gene of incompatibility or hybrid breakdown to a cluster of TIR-NB-LRR genes in Arabidopsis. Yamamoto et al (2010) reported that hbd3, a causal gene controlling hybrid breakdown in rice, is located on the cluster of NB-LRR genes. These reports suggest that plant immune systems conditioned by NB-LRR protein(s) induce hybrid weakness, as reported by Bomblies and Weigel (2007).…”

Section: T14×(t65×ptb7)]mentioning

confidence: 99%

Chromosomal Location of HWA1 and HWA2, Complementary Hybrid Weakness Genes in Rice

Ichitani

Taura

Tezuka

et al. 2011

Rice

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Hybrid weakness phenomena in rice reportedly have two causes: those of HWC1 and HWC2 genes and those of HWA1 and HWA2 genes. No detailed study of the latter has been reported. For this study, we first produced crosses among cultivars carrying the weakness-causing allele on the HWA1 and HWA2 loci to confirm the phenotype of the hybrid weakness and the genotypes of the cultivars on the two loci, as reported earlier. We then confirmed that these cultivars belong to Indica. Subsequent linkage analysis of HWA1 and HWA2 genes conducted using DNA markers revealed that both genes are located in the 1,637-kb region, surrounded by the same DNA markers on the long arm of chromosome 11. The possibility of allelic interaction inducing hybrid weakness is discussed.

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“…The molecular basis of hybrid incompatibility has been variously attributed to cisor trans-regulatory changes, copy number changes, and amino acid changes (Krüger et al, 2002;Bomblies et al, 2007;Dilkes et al, 2008;, and, thus far, there is little overlap between genes detected in one genus to another (reviewed in Rieseberg and Blackman, 2010). These interactions can affect different targets including pathogen responses (Bomblies et al, 2007;Jeuken et al, 2009;Yamamoto et al, 2010;Mizuno et al, 2011), suppression of transposable elements (TEs) (McClintock, 1984;Shaked et al, 2001;Kashkush et al, 2003;Madlung et al, 2005;Josefsson et al, 2006;Ungerer et al, 2006;Martienssen, 2010), small RNA pathways (Ha et al, 2009;Ng et al, 2012;Shivaprasad et al, 2012;Zhang et al, 2012), and developmental regulatory pathways, such as genomic imprinting in the seed (Josefsson et al, 2006). Importantly, although all these molecular mechanisms have been documented as affected by hybridization in at least one system, their relative contribution to hybrid incompatibility is unclear.…”

Section: Introductionmentioning

confidence: 99%

Early Disruption of Maternal–Zygotic Interaction and Activation of Defense-Like Responses inArabidopsisInterspecific Crosses

et al. 2013

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Seed death resulting from hybridization between Arabidopsis thaliana and Arabidopsis arenosa has complex genetic determination and involves deregulation 5 to 8 d after pollination (DAP) of AGAMOUS-LIKE genes and retroelements. To identify causal mechanisms, we compared transcriptomes of compatible and incompatible hybrids and parents at 3 DAP. Hybrids misexpressed endosperm and seed coat regulators and hyperactivated genes encoding ribosomal, photosynthetic, stress-related, and immune response proteins. Regulatory disruption was more severe in Columbia-0 hybrids than in C24 hybrids, consistent with the degree of incompatibility. Maternal loss-of-function alleles for endosperm growth factor TRANSPARENT TESTA GLABRA2 and HAIKU1 and defense response regulators NON-EXPRESSOR OF PATHOGENESIS RELATED1 and SALICYLIC ACID INDUCTION-DEFICIENT2 increased hybrid seed survival. The activation of presumed POLYCOMB REPRESSIVE COMPLEX (PRC) targets, together with a 20-fold reduction in expression of FERTILIZATION INDEPENDENT SEED2, indicated a PRC role. Proximity to transposable elements affected natural variation for gene regulation, but transposon activation did not differ from controls. Collectively, this investigation provides candidates for multigenic orchestration of the incompatibility response through disruption of endosperm development, a novel role for communication between endosperm and maternal tissues and for pathways previously connected to immunity, but, surprisingly, does not identify a role for transposons.

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Gain of deleterious function causes an autoimmune response and Bateson–Dobzhansky–Muller incompatibility in rice

Cited by 104 publications

References 46 publications

Evidence of Natural Selection Acting on a Polymorphic Hybrid Incompatibility Locus in Mimulus

Evidence of Natural Selection Acting on a Polymorphic Hybrid Incompatibility Locus in Mimulus

Chromosomal Location of HWA1 and HWA2, Complementary Hybrid Weakness Genes in Rice

Early Disruption of Maternal–Zygotic Interaction and Activation of Defense-Like Responses inArabidopsisInterspecific Crosses

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