Oat-maize addition (OMA) lines with one, or occasionally more, chromosomes of maize (Zea mays L., 2n = 2x = 20) added to an oat (Avena sativa L., 2n = 6x = 42) genomic background can be produced via embryo rescue from sexual crosses of oat x maize. Self-fertile disomic addition lines of different oat genotypes, mainly cultivar Starter, as recipient for maize chromosomes 1, 2, 3, 4, 5, 6, 7, 9, and the short arm of 10 and a monosomic addition line for chromosome 8, have been reported previously in which the sweet corn hybrid Seneca 60 served as the maize chromosome donor. Here we report the production and characterization of a series of new OMA lines with inbreds B73 and Mo17 as maize chromosome donors and with oat cultivars Starter and Sun II as maize chromosome recipients. Fertile disomic OMA lines were recovered for B73 chromosomes 1, 2, 4, 5, 6, 8, 9, and 10 and Mo17 chromosomes 2, 4, 5, 6, 8, and 10. These lines together with non-fertile (oat x maize) F(1) plants with chromosome 3 and chromosome 7 of Mo17 individually added to Starter oat provide DNA of additions to oat of all ten individual maize chromosomes between the two maize inbreds. The Mo17 chromosome 10 OMA line was the first fertile disomic OMA line obtained carrying a complete chromosome 10. The B73 OMA line for chromosome 1 and the B73 and Mo17 OMA lines for chromosome 8 represent disomic OMA lines with improved fertility and transmission of the addition chromosome compared to earlier Seneca 60 versions. Comparisons among the four oat-maize parental genotype combinations revealed varying parental effects and interactions on frequencies of embryo recovery, embryo germination, F(1) plantlets with maize chromosomes, the specific maize chromosomes retained and transmitted to F(2) progeny, and phenotypes of self-fertile disomic addition plants. As opposed to the previous use of a hybrid Seneca 60 maize stock as donor of the added maize chromosomes, the recovered B73 and Mo17 OMA lines provide predictable genotypes for use as tools in physical mapping of maize DNA sequences, including inter-genic sequences, by simple presence/absence assays. The recovered OMA lines represent unique materials for maize genome analysis, genetic, physiological, and morphological studies, and a possible means to transfer maize traits to oat. Descriptions of these materials can be found at http://agronomy.cfans.umn.edu/Maize_Genomics.html .
We have developed from crosses of oat (Avena sativa L.) and maize (Zea mays L.) 50 fertile lines that are disomic additions of individual maize chromosomes 1-9 and chromosome 10 as a short-arm telosome. The whole chromosome 10 addition is available only in haploid oat background. Most of the maize chromosome disomic addition lines have regular transmission; however, chromosome 5 showed diminished paternal transmission, and chromosome 10 is transmitted to offspring only as a short-arm telosome. To further dissect the maize genome, we irradiated monosomic additions with ␥ rays and recovered radiation hybrid (RH) lines providing low-to medium-resolution mapping for most of the maize chromosomes. For maize chromosome 1, mapping 45 simple-sequence repeat markers delineated 10 groups of RH plants reflecting different chromosome breaks. The present chromosome 1 RH panel dissects this chromosome into eight physical segments defined by the 10 groups of RH lines. Genomic in situ hybridization revealed the physical size of a distal region, which is represented by six of the eight physical segments, as being Ϸ20% of the length of the short arm, representing Ϸone-third of the genetic chromosome 1 map. The distal Ϸ20% of the physical length of the long arm of maize chromosome 1 is represented by a single group of RH lines that spans >23% of the total genetic map. These oat-maize RH lines provide valuable tools for physical mapping of the complex highly duplicated maize genome and for unique studies of interspecific gene interactions. P lants with one chromosome (monosomic) or one pair of homologous chromosomes (disomic) of an alien donor species added to the entire recipient species chromosome complement serve to dissect the donor genome into individual chromosome entities and separate them from their own genome remnant. The transfer liberates the added chromosome (pair) from the interactive gene expression network of the donor genome and puts the chromosome's genes into the environment of the host genome. This new structural and functional situation can create novel orthologous and nonhomologous gene-to-gene interactions and, hence, helps to answer fundamental questions about gene expression control, inheritance, and syntenic correspondence among different plant species, especially those with large genomes, including maize, with a 1C content of Ϸ2. By crossing maize to oat, (oat ϫ maize)F 1 proembryos were generated, of which 5-10% could be rescued in vitro. Molecular and cytological analyses showed retention of one or more maize chromosomes in addition to the haploid oat genome in 34% of the F 1 plants (2-7). Because haploid oat frequently develops unreduced gametes (8), subsequent self-fertilization of (oat ϫ maize)F 1 plants with one maize chromosome added to the haploid oat genome (n ϭ 3x ϩ 1 ϭ 22) can produce F 2 offspring with one homologous maize chromosome pair added to the doubled haploid (hexaploid) oat genome (2n ϭ 6x ϩ 2 ϭ 44) among other euploid and aneuploid types (9).A complete series of oat-maize chromosome a...
Centromere positions on 7 maize chromosomes were compared on the basis of data from 4 to 6 mapping techniques per chromosome. Centromere positions were first located relative to molecular markers by means of radiation hybrid lines and centric fission lines recovered from oat-maize chromosome addition lines. These centromere positions were then compared with new data from centric fission lines recovered from maize plants, half-tetrad mapping, and fluorescence in situ hybridizations and to data from earlier studies. Surprisingly, the choice of mapping technique was not the critical determining factor. Instead, on 4 chromosomes, results from all techniques were consistent with a single centromere position. On chromosomes 1, 3, and 6, centromere positions were not consistent even in studies using the same technique. The conflicting centromere map positions on chromosomes 1, 3, and 6 could be explained by pericentric inversions or alternative centromere positions on these chromosomes.
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