Abstract
Non-additive interactions between genomes have important implications, not only for practical applications such as breeding, but also for understanding evolution. In extreme cases, genes from different genomic backgrounds may be incompatible and compromise normal development or physiology. Of particular interest are non-additive interactions of alleles at the same locus. For example, overdominant behavior of alleles, with respect to plant fitness, has been proposed as an important component of hybrid vigor, while underdominance may lead to reproductive isolation. Despite their importance, only a few cases of genetic over- or underdominance affecting plant growth or fitness are understood at the level of individual genes. Moreover, the relationship between biochemical and fitness effects may be complex: genetic overdominance, that is, increased or novel activity of a gene may lead to evolutionary underdominance expressed as hybrid weakness. Here, we describe a non-additive interaction between alleles at the Arabidopsis thaliana OAK (OUTGROWTH-ASSOCIATED PROTEIN KINASE) gene. OAK alleles from two different accessions interact in F1 hybrids to cause a variety of aberrant growth phenotypes that depend on a recently acquired promoter with a novel expression pattern. The OAK gene, which is located in a highly variable tandem array encoding closely related receptor-like kinases, is found in one third of A. thaliana accessions, but not in the reference accession Col-0. Besides recruitment of exons from nearby genes as promoter sequences, key events in OAK evolution include gene duplication and divergence of a potential ligand-binding domain. OAK kinase activity is required for the aberrant phenotypes, indicating it is not recognition of an aberrant protein, but rather a true gain of function, or overdominance for gene activity, that leads to this underdominance for fitness. Our work provides insights into how tandem arrays, which are particularly prone to frequent, complex rearrangements, can produce genetic novelty.
Highlights
Both evolutionary biologists and breeders have long been interested in non-additive interactions among alleles at the same locus
Several important classes of defense genes, including those encoding nucleotide bindingleucine rich repeat (NB-leucine-rich repeats (LRRs)) proteins and receptor-like kinases (RLKs), commonly occur in tandem arrays, and new alleles are created through gene duplication, illegitimate recombination and gene conversion [11,12,13,14,15,16,17,18,19]
We have identified an Arabidopsis thaliana hybrid with several aberrant growth phenotypes that are caused by divergence at a single locus encoding the receptor-like kinase OUTGROWTH-ASSOCIATED PROTEIN KINASE (OAK)
Summary
Both evolutionary biologists and breeders have long been interested in non-additive interactions among alleles at the same locus. Hybrid incompatibilities form a continuum from the grey zone of developmental abnormalities through the clearer phenotype of F1 sterility to the severest form, lethality, and it is important to understand the genetic and molecular causes for the entire spectrum of incompatibilities. Several similar cases in A. thaliana and other species involve interactions between alleles of disease resistance genes with other loci in the genome, which cause an autoimmune syndrome known as hybrid necrosis [6,7,8]. That hybrid necrosis is such a relatively common phenomenon is explained, since genes involved in plant defense are highly variable between different individuals of the same species [9,10], and make a perfect substrate for causing problems when different genomes are combined. Several important classes of defense genes, including those encoding nucleotide bindingleucine rich repeat (NB-LRR) proteins and receptor-like kinases (RLKs), commonly occur in tandem arrays, and new alleles are created through gene duplication, illegitimate recombination and gene conversion [11,12,13,14,15,16,17,18,19]
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