Allelic diversification at the wx locus in landraces of Asian rice.

To examine continuous variation of amylose levels in Asian rice (Oryza sativa) landraces, the five putative alleles (Wx a, Wx in, Wx b, Wx op, and wx) at the wx locus were investigated in near-isogenic lines (NILs). Apparent amylose levels ranged from 0.5 to 29.9% in the NILs, showing a positive relation with the levels of Wx gene product, granule-bound starch synthase (GBSS) as well as the enzymatic activity per milligram starch granule. Only opaque (Wx op) accessions had an enzymatic activity per GBSS that was reduced to half the level of the others. Nucleotide sequences in the Wx gene were compared among 18 accessions harboring the five different alleles. Each of the Wx alleles had a unique replacement, frame-shift or splice donor site mutation, suggesting that these nucleotide changes could be reflected in phenotype alterations. A molecular phylogenetic tree constructed using the Wx gene indicated that ssp. japonica forms a distinct clade, whereas ssp. indica forms different clades together with the wild progenitor. Unexpectedly, the wx allele of 160 (indica from Taiwan) joined the japonica lineage; however, comparisons using linked genes for two Taiwanese accessions revealed that the wx gene was the product of gene flow from japonica to indica. Therefore, the japonica lineage frequently included Wx in, Wx b and wx, while Wx a and Wx op were found in the other lineages, strongly suggesting that allelic diversification occurred after divergence of the two subspecies. The present results were discussed in relation to the maintenance of agronomically valuable genes in various landraces.

Auxin response factor family in rice.

We isolated 11 rice genes homologous to the genes encoding auxin response factors (ARFs) in Arabidopsis. All of the genes encoded a well-conserved amino acid sequence in the N-terminal region, which is considered to be a DNA-binding domain (DBD). Phylogenetic analysis based on comparison of the DBDs indicated that rice has one or two closely related orthologs corresponding to a given respective ARF gene in Arabidopsis. We also analyzed the amino acid sequences of another conserved domain in the C-terminal conserved domain (CTD), which was shared by almost all the rice ARFs, with the exception of OsETTIN1 and OsETTIN2. These results agreed well with the evolutionary relationship deduced from the DBD comparison. In contrast to many ARFs, OsETTIN1 and OsETTIN2 do not contain the conserved C-terminal domain, but do share another consensus motif that is also found in Arabidopsis ETTIN. All of the above observations indicate that rice has functionally diversified ARF genes whose structures and functions correspond to those of various Arabidopsis ARFs, with one or two rice ARFs corresponding to a given Arabidopsis ARF. Thus, auxin signal transduction mechanisms may be well conserved between monocot and dicot plants.

Mutations that cause amino acid substitutions at the invariant positions in homeodomain of OSH3 KNOX protein suggest artificial selection during rice domestication.

KNOX homeodomain (HD) proteins encoded by KNOTTED1-like homeobox genes (KNOX genes) are considered to work as important regulators for plant developmental and morphogenetic events. We found that OSH3, one of the KNOX genes isolated from a cultivar of Oryza sativa (Nipponbare), encodes a novel HD, which has two amino acid substitutions at invariant positions. Sequence analysis of OSH3 from various domesticated and wild species of rice has revealed that these substitutions are distributed only in Japonica and Javanica type of O. sativa, two groups of domesticated rice in Asia. Surprisingly, nucleotide sequences in the first intron are almost conserved in the rice strains that have the substitutions at the invariant amino acids. Overexpression studies revealed that these invariant amino acids are critical for the function of OSH3 in vivo. The facts that these substitutions occurred specifically at the functionally important amino acids and the sequences are conserved in intron where neutral mutations accumulate suggest the substitutions at the invariant positions of OSH3 have been fixed by artificial selections during domestication. Based on these observations, we hypothesize that OSH3 is responsible for one of the traits that are selectively introduced during the domestication of most of Japonica and a part of Javanica type of rice.

Analysis of intragenic recombination at wx in rice: correlation between the molecular and genetic maps within the locus.

In plant genomes as well as other eukaryotic genomes, meiotic recombination does not occur uniformly. At the level of the gene, high recombination frequencies are often observed within genetic loci in maize, but this feature of intragenic recombination is not seen at the csr1 locus in Arabidopsis. These observations suggest that meiotic recombination in plant genomes varies considerably among species. In the present study we investigated meiotic recombination at the wx locus in rice. The mutation sites of wx mutants induced by ethyl methanesulfonate (EMS) treatment or gamma-ray irradiation and a spontaneous wx mutant were physically characterized, and the genetic distances between those wx mutation sites were estimated by pollen analysis. Based on these results, the recombination frequency at the wx locus in rice was estimated as 27.3 kb/cM, which was about 10 times higher than the average for the genome, suggesting that there was a radically different rate of meiotic recombination for intra- and intergenic regions in the rice genome.

Molecular analysis of the NAC gene family in rice.

Genes that encode products containing a NAC domain, such as NO APICAL MERISTEM (NAM) in petunia, CUP-SHAPED COTYLEDON2 (CUC2) and NAP in Arabidopsis thaliana, have crucial functions in plant development. We describe here molecular aspects of the OsNAC genes that encode proteins with NAC domains in rice (Oryza sativa L.). Sequence analysis revealed that the NAC genes in plants can be divided into several subfamilies, such as the NAM, ATAF, and OsNAC3 subfamilies. In rice, OsNAC1 and OsNAC2 are classified in the NAM subfamily, which includes NAM and CUC2, while OsNAC5 and OsNAC6 fall into the ATAF subfamily. In addition to the members of these subfamilies, the rice genome contains the NAC genes OsNAC3, OsNAC4 (both in the OsNAC3 subfamily), OsNAC7, and OsNAC8. These results and Southern analysis indicate that the OsNAC genes constitute a large gene family in the rice genome. Each OsNAC gene is expressed in a specific pattern in different organs, suggesting that this family has diverse and important roles in rice development.

Comparison of Waxy gene regulation in the endosperm and pollen in Oryza sativa L.

The Waxy (Wx) gene controls amylose synthesis in rice (Oryza sativa) and its expression is regulated organ-specifically. The Wx gene is expressed in the endosperm and pollen but not in other organs. In order to know whether Wx gene regulation is the same in the endosperm and pollen, we compared expression patterns of the rice Wx gene in these two organs by immunoblot analysis. We focused on the allelic differences (Wxa and Wxb), cool temperature response and effects of the mutation at the du loci. The results obtained are as follows. First, the quantitative regulation depending on two alleles, Wxa and Wxb, was common to both organs; Wx protein levels from the Wxa allele were about 10-fold higher than those from the Wxb allele in the pollen as well as in the endosperm. Second, in both the endosperm and pollen, expression of the Wxb gene, but not the Wxa gene, was enhanced in response to cool temperature. In contrast to these two types of regulation, analysis of two du mutants, 2035 (du1) and 76-3 (du2), revealed that the pattern of reduction in Wx protein levels in the pollen was distinct from that in the endosperm, suggesting that functions of the two du+ genes differ in these two organs.

A single base change altered the regulation of the Waxy gene at the posttranscriptional level during the domestication of rice.

The rice waxy (wx) locus has two functional alleles, Wxa and Wxb, which are defined by a large difference in the amount of the gene product, called Wx protein, that accumulates in mature seeds. To elucidate the molecular mechanism underlying this difference and to identify the base change causing the alteration of the regulation of the Wx gene during rice evolution, we determined the nucleotide sequences of the regulatory region of Wx alleles and analyzed their function in a transient assay system using rice protoplasts. All Wxa alleles from Oryza sativa Indica, O. rufipogon, and O. glaberrima have a normal sequence of GT at the 5' splice junction of the first intron, representing a high expression level of the Wx transcripts in the endosperm and a high beta-glucuronidase (GUS) activity in protoplasts. On the other hand, Wxb alleles from two strains of O. sativa Japonica have TT at the 5' splice junction, representing a low expression level of the mature transcripts and a low GUS activity. Northern blot analysis also indicated that a larger transcript, consisting of the unspliced first intron, is closely correlated with the function of the Wxb allele. These results suggest that a single base change at the 5' splice junction causes inefficient splicing and, as a result, reduces the level of mature transcript and the GUS activity in the Wxb allele. The Wxb allele in O. saativa Japonica may have been differentiated from the Wxa allele of O. rufipogon, its wild progenitor, by this mutation, and, therefore, a single base change that has altered the regulation of the Wx gene at the posttranscriptional level probably occurred during the domestication of rice.

Retrotransposition of a plant SINE into the wx locus during evolution of rice.

A new type of plant retroposon, p-SINE1, has been found in the wx locus of rice (Oryza sativa). It has some structural characteristics similar to those of mammalian SINEs, such as members of the Alu or B1 family. In order to estimate the time at which the integration of p-SINE1 into a single locus occurred during rice evolution, we examined the distribution of two members of p-SINE1 in several species of the Oryza genus by the polymerase chain reaction (PCR). We found that one member of p-SINE1 (p-SINE1-r2) in the ninth intron of the wx+ gene was present only in two closely related species, O. sativa and O. rufipogon, and was not present in the other species carrying the AA genome within the Oryza genus. This result indicates that p-SINE1-r2 was integrated into the wx locus after O. sativa and O. rufipogon had diverged from other species with the AA genome. In contrast to p-SINE1-r2, another member (p-SINE1-r1) located in the untranslated 5'-region of the wx+ gene was present not only in all species with the AA genome but also in species with a different genome (CCDD). This result suggests that p-SINE1-r1 was integrated into that position prior to the genomic divergence. Thus, it appears that each member of p-SINE1 was retroposed at a specific site at a different time during rice evolution.

Analysis of intergenic spacer regions in the nuclear rDNA of Pharbitis nil.

The nucleotide sequence of a 4.2-kb EcoRI fragment from the intergenic region between the genes for 25S and 18S ribosomal RNA of Pharbitis nil Choisy was determined. The region contained a unique repetitive family of DNA sequences, called the RsaI family, composed of 32-bp units. The 32-bp unit was tandemly repeated in the intergenic region, and four subfamilies of repeating units were clustered as discrete blocks. The RsaI family of repeats was shown to be specific to the genus Pharbitis by Southern blot hybridization.