Microcloning of maize chromosome 9 by using a flow-sorting technique

We constructed a chromosome 9 lambda DNA library from flow-sorted maize chromosomes. Approximately 3 million maize chromosome 9 were collected with high purity by flow cytometric sorting of chromosomes isolated from an oat-maize chromosome 9 addition line based on the cytogram of fluorescent pulse area versus fluorescent pulse width. Chromosome 9 DNA was partially digested withBamH I, dephosphorylated, and ligated with arms ofBamH I-digested lambda DASH vector (Stratagene). A total of 2.0×10⁶ independent recombinants with an average insert size of 15 kb were obtained. For a 99% probability that every sequence of chromosome 9 is represented in at least one chimeric phage, 5.6×10⁴ cloned fragments are needed. This library covers the entire maize chromosome 9. Hybridizing cloned fragments with labeled maize genomic DNA showed that the high, middle, or low copy number DNA sequences presented in the different phage clones. This individual chromosome library is useful in plant genome mapping and gene isolation.     

Maize DNA enrichment by representational difference analysis in a maize chromosome addition line of oat

 The recent recovery of maize (Zea mays L.) single-chromosome addition lines of oat (Avena sativa L.) from oat x maize crosses has provided novel source materials for the potential isolation of maize chromosome-specific sequences for use in genetic mapping and gene cloning. We report here the application of a technique, known as representational difference analysis (RDA), to selectively isolate maize sequences from a maize chromosome-3 addition line of oat. DNA fragments from the addition line and from the oat parent were prepared using BamHI digestion and primer ligation followed by PCR amplification. A subtractive hybridization technique using an excess of the oat parental DNA was employed to reduce the availability for amplification of DNA fragments from the addition lines that were in common with the ones from the oat parental line. After three rounds of hybridization and amplification, the resulting DNA fragments were cloned into a plasmid vector. A DNA library containing 400 clones was constructed by this method. In a test of 18 clones selected at random from this library, four (22%) detected maize-specific repetitive DNA sequences and nine (50%) showed strong hybridization to genomic DNA of maize but weak hybridization to genomic DNA of oat. Among these latter nine clones, three detected low-copy DNA sequences and two of them detected DNA sequences specific to chromosome 3 of maize, the chromosome retained in the source maize addition line of oat. The other eight out of the 13 clones that had strong hybridization to maize DNA detected repetitive DNA sequences or high-copy number sequences present on most or all maize chromosomes. We estimate that the maize DNA sequences were enriched from about 1.8% to over 72% of the total DNA by this procedure. Most of the isolated DNA fragments detected multiple or repeated DNA sequences in maize, indicating that the major part of the maize genome consists of repetitive DNA sequences that do not cross-hybridize to oat genomic sequences. Received: 18 November 1997 / Accepted: 12 March 1998     

Cytological and molecular characterization of oat x maize partial hybrids

In cereals, interspecific and intergeneric hybridizations (wide crosses) which yield karyotypically stable hybrid plants have been used as starting points to widen the genetic base of a crop and to construct stocks for genetic analysis. Also, uniparental genome elimination in karyotypically unstable hybrids has been utilized for cereal haploid production. We have crossed hexaploid oat (2n=6x=42, Avena sativa L.) and maize (2n=2x=20, Zea mays L.) and recovered 90 progenies through embryo rescue. Fifty-two plants (58%) produced from oatxmaize hybridization were oat haploids (2n=3x=21) following maize chromosome elimination. Twenty-eight plants (31%) were found to be stable partial hybrids with 1–4 maize chromosomes in addition to a haploid set of 21 oat chromosomes (2n=21+1 to 2n=21+4). Ten of the ninety plants produced were found to be apparent chromosomal chimeras, where some tissues in a given plant contained maize chromosomes while other tissues did not, or else different tissues contained a different number of maize chromosomes. DNA restriction fragment length polymorphisms (RFLPs) were used to identify the maize chromosome(s) present in the various oat-maize progenies. Maize chromosomes 2, 3, 4, 5, 6, 7, 8, and 9 were detected in partial hybrids and chromosomal chimeras. Maize chromosomes 1 and 10 were not detected in the plants analyzed to-date. Furthermore, partial self-fertility, which is common in oat haploids, was also observed in some oat-maize hybrids. Upon selfing, partial hybrids with one or two maize chromosomes showed nearly complete transmission of the maize chromosome to give self-fertile maize-chromosome-addition oat plants. Fertile lines were recovered that contained an added maize chromosome or chromosome pair representing six of the ten maize chromosomes. Four independently derived disomic maize chromosome addition lines contained chromosome 4, one line carried chromosome 7, two lines had chromosome 9, one had chromosome 2, and one had chromosome 3. One maize chromosome-8 monosomic addition line was also identified. We also identified a double disomic addition line containing both maize chromosomes 4 and 7. This constitutes the first report of the production of karyotypically stable partial hybrids involving highly unrelated species from two subfamilies of the Gramineae (Pooideae — oat, and Panicoideae — maize) and the subsequent recovery of fertile oat-maize chromosome addition lines. These represent novel material for gene/ marker mapping, maize chromosome manipulation, the study of maize gene expression in oat, and the transfer of maize DNA, genes, or active transposons to oat.Joint contribution of the Minnesota Agricultural Experiment Station and USDA-ARS. Scientific journal series paper No. 21 859 of the Minnesota Agricultural Experiment Station. Mention of a trademark or proprietary product does not constitute a guarantee or warranty by the USDA-ARS or the University of Minnesota and does not imply approval over other products that also may be suitable     

Mapping maize sequences to chromosomes using oat-maize chromosome addition materials

Oat- (Avena sativa) maize (Zea mays) chromosome additions are produced by crossing maize and oat. During early embryo development maize chromosomes are preferentially eliminated, and oat plants are often recovered that retain a single maize chromosome. Each of the 10 maize chromosomes recently has been isolated as a separate oat-maize addition. We describe here the mapping of 400 maize sequences to chromosomes using polymerase chain reaction and DNA from the oat-maize addition material. Fifty of the sequences were from cloned markers that had been previously mapped by linkage analysis, and our results were consistent with those obtained using Southern-blot analysis. Previously unmapped expressed sequence tags and sequence tagged sites (350) were mapped to chromosomes. Maize gene sequences and expression data are rapidly being accumulated. Coupling this information with positional information from high throughput mapping programs provides plant biologists powerful tools for identifying candidate genes of interest.     

A complete set of maize individual chromosome additions to the oat genome

All 10 chromosomes of maize (Zea mays, 2n = 2x = 20) were recovered as single additions to the haploid complement of oat (Avena sativa, 2n = 6x = 42) among F(1) plants generated from crosses involving three different lines of maize to eight different lines of oat. In vitro rescue culture of more than 4,300 immature F(1) embryos resulted in a germination frequency of 11% with recovery of 379 F(1) plantlets (8.7%) of moderately vigorous growth. Some F(1) plants were sectored with distinct chromosome constitutions among tillers of the same plant and also between root and shoot cells. Meiotic restitution facilitated development of un-reduced gametes in the F(1). Self-pollination of these partially fertile F(1) plants resulted in disomic additions (2n = 6x + 2 = 44) for maize chromosomes 1, 2, 3, 4, 6, 7, and 9. Maize chromosome 8 was recovered as a monosomic addition (2n = 6x + 1 = 43). Monosomic additions for maize chromosomes 5 and 10 to a haploid complement of oat (n = 3x + 1 = 22) were recovered several times among the F(1) plants. Although partially fertile, these chromosome 5 and 10 addition plants have not yet transmitted the added maize chromosome to F(2) offspring. We discuss the development and general utility of this set of oat-maize addition lines as a novel tool for maize genomics and genetics.     

Flow sorting and microcloning of maize chromosome 1

Flow sorting maize chromosome 1 and construction of the first chromosome 1 DNA Lambda library are described. Maize metaphase chromosome suspensions were prepared from synchronized seedling root tip cells of the maize hybrid line Seneca 60 and stained with propidium iodide for flow karyotyping and sorting. The observed flow karyotype was very similar to the predicted flow karyotype constructed based on published values for the relative chromosome sizes of Seneca 60. The estimated size of chromosomes from the peak for the chromosome 1 matched the expected size of maize chromosome 1. The peak for the chromosome 1 was well resolved from other peaks on the flow karyotype. An average of 7 x 10(3) chromosomes of chromosome 1 could be produced from 10 root tips. About 0.6 million chromosomes of maize chromosome 1 were sorted and pooled based on the cytogram of fluorescent pulse area Vs fluorescent pulse width and stored at -20 degrees C in the freezer. DNA isolated from sorted chromosomes was good quality of more than 100 kb in size. Chromosome 1 DNA was partially digested with BamHI, dephosphorylated and ligated with arms of BamHI digested Lambda Dash vector. A total of 1.2 x 10(5) independent recombinants with the average insert size 12.6 kb was obtained. This library covered approximately 90% of maize chromosome 1. Hybridization of cloned fragments with labeled maize genomic DNA showed that the high, middle, or low copy number DNA sequences presented in the different phage clones. PCR (polymerase chain reaction) using chromosome-specific primers confirmed the specificity of this library. The individual chromosome library is useful in plant genome mapping and gene isolation.     

Maize individualized chromosome and derived radiation hybrid lines and their use in functional genomics

The duplicated and rearranged nature of plant genomes frequently complicates identification, chromosomal assignment and eventual manipulation of DNA segments. Separating an individual chromosome from its native complement by adding it to an alien genetic background together with the generation of radiation hybrids from such an addition line can enable or simplify structural and functional analyses of complex duplicated genomes. We have established fertile disomic addition lines for each of the individual maize chromosomes, except chromosome 10, with oat as the host species; DNA is available for chromosome 10 in a haploid oat background. We report on instability and transmission in disomic additions of maize chromosomes 1, 5, and 8; the chromosome 2, 3, 4, 6, 7, and 9 additions appear stable. The photoperiodic response of the two recovered maize chromosome 1 addition lines contrasts to the long-day flowering response of the oat parents and the other addition lines. Only when grown under short days did maize chromosome 1 addition lines set seed, and only one line transmitted the maize chromosome 1 to offspring. Low resolution radiation hybrid maps are presented for maize chromosomes 2 and 9 to illustrate the use of radiation hybrids for rapid physical mapping of large numbers of DNA sequences, such as ESTs. The potential of addition and radiation hybrid lines for mapping duplicated sequences or gene families to chromosome segments is presented and also the use of the lines to test interactions between genes located on different maize chromosomes as observed for ectopic expression of cell fate alterations. Electronic Publication     

Production and characterization of maize chromosome 9 radiation hybrids derived from an oat-maize addition line

In maize (Zea mays L., 2n = 2x = 20), map-based cloning and genome organization studies are often complicated because of the complexity of the genome. Maize chromosome addition lines of hexaploid cultivated oat (Avena sativa L., 2n = 6x = 42), where maize chromosomes can be individually manipulated, represent unique materials for maize genome analysis. Maize chromosome addition lines are particularly suitable for the dissection of a single maize chromosome using radiation because cultivated oat is an allohexaploid in which multiple copies of the oat basic genome provide buffering to chromosomal aberrations and other mutations. Irradiation (gamma rays at 30, 40, and 50 krad) of a monosomic maize chromosome 9 addition line produced maize chromosome 9 radiation hybrids (M9RHs)-oat lines possessing different fragments of maize chromosome 9 including intergenomic translocations and modified maize addition chromosomes with internal and terminal deletions. M9RHs with 1 to 10 radiation-induced breaks per chromosome were identified. We estimated that a panel of 100 informative M9RHs (with an average of 3 breaks per chromosome) would allow mapping at the 0. 5- to 1.0-Mb level of resolution. Because mapping with maize chromosome addition lines and radiation hybrid derivatives involves assays for the presence or absence of a given marker, monomorphic markers can be quickly and efficiently mapped to a chromosome region. Radiation hybrid derivatives also represent sources of region-specific DNA for cloning of genes or DNA markers.     

Transmission of maize chromosome 9 rearrangements in oat-maize radiation hybrids.

Oat-maize radiation hybrids are oat (Avena sativa L.) plants carrying radiation-induced subchromosome fragments of a given maize (Zea mays L.) chromosome. Since first-generation radiation hybrids contain various maize chromosome rearrangements in a hemizygous condition, variation might be expected in the transmission of these rearrangements to subsequent generations. The transmission and integrity of maize chromosome 9 rearrangements were evaluated in progenies of 30 oat-maize radiation hybrids by using a series of DNA-based markers and by genomic in situ hybridization. Maize chromosome 9 rearrangements were reisolated by self-fertilization in 24 of the 30 radiation hybrid lineages. Normal and deleted versions of maize chromosome 9 were transmitted at similar frequencies of 9.1% and 7.6%, respectively, while intergenomic translocations were transmitted at a significantly higher frequency of 47.6%. Most lines (93%) that inherited a rearrangement had it in the hemizygous condition. Lines with a rearrangement in the homozygous state (7%) were only identified in lineages with intergenomic translocations. Homozygous lines are more desirable from the perspective of stock maintenance, since they may stably transmit a given rearrangement to a subsequent generation. However, their isolation is not strictly required, since hemizygous lines can also be used for genome mapping studies.     

The molecular characterization of maize B chromosome specific AFLPs

INTRODUCTIONB chromosomes (Bs) are also called supernumer-ary chromosomes, accessory chromosomes or extrachromosomes. They are supernumerary to the stan-dard chromosome (A chromosomes) set, which arefound in hundreds of plants and animals. They areoften morphologicaIly distinct from A chromosomes,being sma1ler and more highly heterochromatic inmost cases. B chromosomes are inherited in a non-Mendelian wap They dO not pair with A chromo-somes, and exhibite meiotic and mitotic instabiIit…     

Flow sorting of wheat chromosome arms from the ditelosomic line 7BL

Flow cytometric analysis confirmed that root tip cells can be synchronized with 1.25 mM hydroxyurea (DNA synthesis inhibitor) for 12 h and 1 μM trifluralin (metaphase blocking reagent) treatment for 5 h. Chromosome suspensions prepared from homogenized tissue were suitable for chromosome sorting. A flow karyotypic histogram showed that the genome of common wheat (Triticum aestivum L.) ‘Chinese Spring’ was divided into 4 chromosome peaks, but the 7BL ditelosomic line had an additional chromosome peak. PCR amplification of sorted chromosome arms indicated that the extra chromosome peak consisted of 7BL telosomics. Some technical details of sample preparation and parameter setting for flow cytometric analysis are described.     

Identification and fate of a marker chromosome in methotrexate-resistant V79,B7 cells by flow karyotyping and sorting, metaphase analysis and in situ hybridization.

The chromosomes from a methotrexate (MTX)-resistant and its parental V79,B7 Chinese hamster cell line were analysed by the combined use of flow karyotyping and sorting, metaphase analysis and in situ hybridization with a probe for the dihydrofolate reductase (DHFR) gene responsible for methotrexate resistance. A marker chromosome with an elongated arm carrying the amplified DHFR gene was identified by in situ hybridization of metaphase cells of the methotrexate-resistant line. In the flow karyotype the marker chromosome was found as an additional peak with a higher DNA content compared with the largest chromosome of the sensitive line. This was additionally verified by G-banding of the chromosomes sorted from the marker peak. Several other chromosomal rearrangements not associated with the amplified gene could be identified in the methotrexate-resistant line by the combined use of flow karyotyping and metaphase analysis. The fate of the original marker chromosome was studied in cells growing several weeks in the absence of methotrexate, comparing flow karyotyping and metaphase analysis. The original marker chromosome was lost in about 50% of the cells after 5 weeks and in about 60% of the cells after 8 weeks; between 80 and 90% of the cells, however, contained marker chromosomes of various sizes. The MTX-resistance decreased in parallel during loss of the original marker chromosome. In conclusion, the study shows that the power of cytogenetic analysis is improved by the combined use of conventional cytogenetics, molecular cytogenetics and flow cytometry.     

Confocal analysis of chromosome behavior in wheat x maize zygotes.

Herein, we profile the first embryonic mitosis in a hybrid of wheat and maize by using a whole-mount genomic in situ hybridization method and immunofluorescence staining with a tubulin-specific antibody. We have successfully captured the dynamics of each set of parental chromosomes in the first zygotic division of the hybrid embryo 24-28 h after crossing. During the first zygotic metaphase, although both sets of parental chromosomes congressed into the equatorial plate of the zygote, the maize chromosomes tended to lag in comparison with the wheat chromosomes. During anaphase, each parental chromosome separated into its sister chromosomes; however, some of the maize chromosomes lagged around the metaphase plate as segregants. The maize sister chromosomes that did move toward the pole showed delayed and asymmetric movement as compared with the wheat ones. Immunological staining of tubulin revealed a bipolar spindle structure in the first zygotic metaphase. The kinetochores of the maize chromosomes that lagged around the metaphase plate did not attach to the spindle microtubules. These results suggest that factors on the kinetochores of maize chromosomes that are required to control chromosome movement are deficient in the zygotic cell cycle.     

Flow Karyotyping of Wheat Addition Line “T240” with a Haynaldia villosa 6VS Telosome

To construct a chromosome-specific DNA library of chromosome 6VS from Haynaldia villosa, a wheat alien chromosome addition line T240 with a 6VS chromosome arm and its parental common wheat cv. CA921 were used to optimize protocols for preparing chromosome suspension amenable to flow sorting of the 6VS chromosome. Our results showed that root tips incubated sequentially in Hogland’s solution containing 1.25 mM hydroxyurea (DNA synthesis inhibitor) for 18 h, a hydroxyurea-free period for 2 h, and 1 μM trifluralin for 4 h (metaphase blocking reagent) increased the metaphase index (MI) by up to 62 % . Many metaphase chromosomes were released to form a chromosome suspension when root tips fixed in 2 % paraformaldehyde were treated in a homogenizer at 9,500 rpm for 10–15 s. Most of the released chromosomes had intact morphology. The background solution of chromosome suspension was clear and relatively few of cell debris and chromosome clumps. Univariate flow karyotypes were established with chromosome suspension flow through FACS Vantage 2000 SE flow cytometer. The flow karyotype of CA921 consisted of four chromosome peaks, whereas that for T240 had a fifth peak. This fifth peak in T240 contained the telosome, which was further confirmed to be 6VS through fluorescence in situ hybridization.     

Comparative mapping in grasses. Oat relationships

The development of RFLP linkage maps in hexaploid and diploid oat allows us to study genetic relationships of these species at the DNA level. In this report, we present the extension of a previously developed diploid oat map (Avena atlantica x A. hirtula) and its molecular-genetic relationships with wheat, rice and maize. Examination of 92–99% of the length of the oat genome map with probes common to Triticeae species, rice or maize showed that 84, 79 and 71%, respectively, was conserved between these species and oat. Generally, the orders of loci among chromosomes homoeologous to oat chromosomes A and D were the most conserved and those of chromosomes homoeologous to oat chromosome G were the least conserved. Conservation was observed for blocks ranging from whole chromosomes 101 cM long to small segments 2.5 cM long containing two loci. Comparison of the homoeologous segments of Triticeae, rice and maize relative to oat indicated that certain regions have been maintained in all four species. The relative positions of major genes governing traits such as seed storage proteins and resistance to leaf rusts have been conserved between cultivated oat and Triticeae species. Also, the locations of three vernalization/or photo-period response genes identified in hexaploid oat correspond to the locations of similar genes in homoeologous chromosomes of wheat, rice or maize. The locations of the centromeres for six of the seven oat chromosomes were estimated based on the homoeologous segments between oat and Triticeae chromosomes.     

High-resolution flow karyotyping and chromosome sorting in Vicia faba lines with standard and reconstructed karyotypes

Flow cytometric analysis has been performed on chromosomes isolated from formaldehyde-fixed root tips in a Vicia faba (2n = 12) line with a standard (wild-type) karyotype and in six V. faba translocation lines with reconstructed karyotypes. The resolution of individual chromosome types on histograms of chromosome fluorescence intensity (flow karyotypes) depended on the type of fluorochrome used for chromosome staining. The highest degree of resolution was achieved with 4,6-diamidino-2-phenylindole (DAPI). The lower resolution obtained after staining with mithramycin A (MIT) and propidium iodide (PI) was probably due to the sensitivity of these stains to changes in chromatin structure induced by formaldehyde fixation. After the staining with DAPI, only 1 chromosome type could be discriminated in the line with a standard karyotype. In the translocation lines, the number of chromosome types resolved on flow karyotypes ranged from 2 in the G and the ACB lines to all (6) chromosome types in the EFK and EF lines. Refined flow karyotyping permitted the sorting of a total of 15 different chromosome types from five of the translocation lines. It is expected that flow sorting of chromosomes from reconstructed karyotypes will become a powerful tool in the study of nuclear genome organisation in V. faba.     

Flow karyotyping and chromosome sorting in bread wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

Previously, we reported on the development of procedures for chromosome analysis and sorting using flow cytometry (flow cytogenetics) in bread wheat. That study indicated the possibility of sorting large quantities of intact chromosomes, and their suitability for analysis at the molecular level. However, due to the lack of sufficient differences in size between individual chromosomes, only chromosome 3B could be sorted into a high-purity fraction. The present study aimed to identify wheat stocks that could be used to sort other chromosomes. An analysis of 58 varieties and landraces demonstrated a remarkable reproducibility and sensitivity of flow cytometry for the detection of numerical and structural chromosome changes. Changes in flow karyotype, diagnostic for the presence of the 1BL·1RS translocation, have been found and lines from which translocation chromosomes 5BL·7BL and 4AL·4AS-5BL could be sorted have been identified. Furthermore, wheat lines have been identified which can be used for sorting chromosomes 4B, 4D, 5D and 6D. The ability to sort any single arm of the hexaploid wheat karyotype, either in the form of a ditelosome or a isochromosome, has also been demonstrated. Thus, although originally considered recalcitrant, wheat seems to be suitable for the development of flow cytogenetics and the technology can be applied to the physical mapping of DNA sequences, the targeted isolation of molecular makers and the construction of chromosome- and arm-specific DNA libraries. These approaches should facilitate the analysis of the complex genome of hexaploid bread wheat.     

Separation of large quantities of chinese hamster chromosomes by velocity sedimentation at unit gravity followed by flow sorting (FACS II)

Separation of large quantities of isolated metaphase chromosomes of Chinese hamster cells was performed by velocity sedimentation at unit gravity in a specially designed sedimentation chamber. This simple and easy technique results in chromosome fractions of relatively high purity as determined by flow cytometry and microscopy. Up to 10¹⁰ chromosomes can be processed depending upon the size of the sedimentation device, and enrichments up to 10 times of individual chromosomes were achieved. In addition, further chromosome purification was performed by fluorescence activated flow sorting using fractions, pre-enriched at unit gravity. The flow sorted chromosomal fractions were pure according to flow cytometric analyses. The combination of l g sedimentation and flow-sorting opens the possibility for preparative chromosome sorting by reducing the flow sorting time considerably.