Molecular verification of the integration ofTripsacum dactyloides DNA into wheat genome through wide hybridization

RAPD and RFLP analyses of double haploid lines which derived from hybridization between hexaploid wheat (Triticum aestivum L. 2n=42) and eastern gamagrass (Tripsacum dactyloides L. 2n=4x=72) are reported. Two of the 340 Operon primers have been screened, which stably amplified 处留情 (male parent) specific bands in the double haploid lines. These results confirm the fact that Tripsacum dactyloides DNA has been integrated into wheat genome by sexual hybridization at molecular level. This idea has been further testified by RFLP analysis. Application and potentials of transferring Tripsacum dactyloides DNA into wheat genome by sexual hybridization in wheat breeding are discussed.     

Haploidy or diploidy: which is better?

Although the evolutionary advantages of sexual reproduction have been extensively discussed, much less attention has been paid to haploid and diploid phases of the sexual life cycle. The relative lengths of these phases differ greatly in various taxa, including as extremes those with one or the other phase reduced to a single cell. Here we consider the efficiency of elimination of deleterious mutations as an evolutionary force and compare the mutation loads under haploid and diploid selection, Ln and L2n. With truncation-like selection, partial dominance, and heterozygous effect of a mutation less than about 1/4 its hemizygous effect, L2n less than Ln; otherwise L2n greater than Ln. The difference becomes important when the genomic deleterious mutation rate exceeds about 1 per genome. This suggests that the mutation rate, degree of dominance and mode of selection can be important in life-cycle evolution.     

Analysis of DNA methylation variation in wheat genetic background after alien chromatin introduction based on methylation-sensitive amplification polymorphism

During the process of alien germplasm introduced into wheat genome by chromosome engineering, extensive genetic variations of genome structure and gene expression in recipient could be induced. In this study, we performed GISH （genome in situ hybridization） and AFLP （amplified fragment length polymorphism） on wheat-rye chromosome translocation lines and their parents to detect the identity in genomic structure of different translocation lines. The results showed that the genome primary structure variations were not obviously detected in different translocation lines except the same 1RS chromosome translocation. Methylation sensitive amplification polymorphism （MSAP） analyses on genomic DNA showed that the ratios of fully-methylated sites were significantly increased in translocation lines （CN12, 20.15%; CN17, 20.91%; CN18, 22.42%）, but the ratios of hemimethylated sites were significantly lowered （CN12, 21.41%; CN17, 23.43%; CN18, 22.42%）, whereas 16.37% were fully-methylated and 25.44% were hemimethylated in case of their wheat parent. Twenty-nine classes of methylation patterns were identified in a comparative assay of cytosine methylation patterns between wheat-rye translocation lines and their wheat parent, including 13 hypermethylation patterns （33.74%）, 9 demethylation patterns （22.76%） and 7 uncertain patterns （4.07%）. In further sequence analysis, the alterations of methylation pattern affected both repetitive DNA sequences, such as retrotransposons and tandem repetitive sequences, and low-copy DNA.     

Size variation in chromosomes from independent cultured isolates of Plasmodium falciparum

The complexity of the life cycle of the protozoan malaria parasite Plasmodium falciparum has hindered genetic analysis; even the number of chromosomes in P. falciparum is uncertain. The blood stages of rodent malaria parasites are haploid and hybridization with cloned complementary DNAs similarly suggests a haploid genome in P. falciparum blood stages (ref. 4 and our unpublished results). A novel approach to karyoptic and linkage analysis in P. falciparum has been provided recently by the technique of pulsed-field gradient (PFG) gel electrophoresis, which allows the fractionation of DNA molecules of 30-3,000 kilobases (kb), a range including the sizes of intact chromosomal DNA molecules from eukaryotes such as yeast and trypanosomatids. We describe here the fractionation by PFG electrophoresis of chromosomal DNA molecules from P. falciparum into at least seven discrete species which vary in size by up to 20% between different isolates. Several genes for P. faciparum antigens which contain repetitive sequences are located on different chromosomes. Surprisingly, two of the chromosomes seem to contain the same sequences.     

Breeding and molecular cytogenetic identification of wheat-Thinopyrum intermedium addition lines resistant to powdery mildew

Wheat-related species Th. intermedium was used to cross with common wheat Yannong 15. In the self progenies of the hybrid, two addition lines, Ⅱ-1-7-1 and Ⅱ-3-3-2, stable in cytology, were developed by cytology and powdery mildew resistance identification. Their chromosome number were 2n = 44 and formed 22 bivalents at PMC MI. In F1 of the two addition lines crossing with Yannong 15, there appeared about one univalent at PMC MI, respectively. Resistance identification in greenhouse and field using the No. 15 and mixed strains of E. gramnis f. sp. tritici showed that they were immune to powdery mildew. Chromosome number and resistance identification using the F2 single plants of the addition line crossing with Yannong 15 indicated that the resistant gene was located on the alien chromosomes. In situ hybridization using St and E genomic DNA as probe showed that the added chromosome in the two addition lines probably came from the E genome of Th. intermedium, which indicated that a pair of E genome chromosomes carried a new resistant gene to powdery mildew.     

Microdissection of chromosome 7B of common wheat and cloning of low-copy specific DNA sequences

The 7B chromosome of common wheat was microdissected from pollen mother cells of the 7B monosomic line of common wheat cv. Chinese Spring (CS). After proteinase K and DNA topoisomerase Ⅰ treatments, the isolated chromosomes were subjected to 1-3 rounds of DOP-PCR amplification, which produced continuous DNA fragments ranging from 150 to 700 bp. Ge-nomic Southern hybridization confirmed that the PCR products were originated from the wheat genome. Cloning of portion ( > 200 bp) of the 3rd round DOP-PCR products (50 μL) could generate about 20 000 recombinant clones. Characterization of 50 randomly chosen clones indicated that 21 clones produced discrete PCR products with the size of 240-600 bp. Dot-blot hybridization showed that among the 21 clones, 11 ( ～ 55%) were of low-copy nature while 10 ( ～ 45%) were repetitive. Southern hybridization with the complete set of the CS "nullisomic-tetrasomic (NT)" lines demonstrated that all the 6 low-copy clones were specific to either chromosome 7B or the 7th homoeologous group, whereas the 3 arbitrarily chosen repetitive clones were non-specific, disperse sequences.     

浅谈叶绿体基因组分析技术在植物系统学中的应用

本文对植物叶绿体基因组做一简介,包括叶绿体基因组的发现、结构与特点、编码基因、进化特点和遗传方式。综述了DNA杂交、DNA限制酶谱分析、RFLP分析、PCR-RFLP分析、微卫星序列分析、SSCP分析和核酸序列分析等叶绿体DNA分析技术的原理、特点及应用。阐述了叶绿体DNA在植物系统学研究中广泛应用的利弊。     

Physical location ofHelminthosporium carbonum susceptibility gene hm1 by FISH of a RFLP marker umc119 in Maize

A fluorescencein situ hybridization (FISH) procedure was adopted to physically map a RFLP marker, umc119 near the centromere of the long arm of linkage group1 in maize. The hm1 gene (Helminthosporium carbonum susceptibility gene) was linked closely with the marker umc119. RFLP markers are very good landmarks for mapping genes. Therefore, we also determined the position of the gene hm1 on the chromosome based on the physical location of umc119. The disease induced by infection ofHelminthosporium carbonum is one of the serious maize diseases and it distributes in many countries including China. Hybridization sites were showed on 1 L (long arm of chromosome1) and 5 L. The percentage distance from centromere to the hybridization site was 22.86 on 1 L and 58.23 on 5 L the detection rate was about 12% for mitotic cells. In interphase nuclei five hybridized sites were detected. It demonstrated that umc119 was multiplicated sequences. FISH has more advantages overin situ hybridization (ISH) detected by DAB for increasing the detection ratio and contrast between chromosomes and hybridization signals. The ability to detect the hybridization signal of a small low copy DNA sequence is a very important key towards wide application of FISH for plant genome mapping. Supported by the National Natural Science Foundation and Doctorate Vesting Point Foundation of the Education Committee of China Li Lijia: born in 1967. Ph. D.     

Construction and characterization of a bacterial artificial chromosome library of peach

This report briefly describes the construction and characterization of a peach [ prunus persica (L.) Batch] Var. Jingyu bacterial artificial chromosome (BAC) library. The variety Jingyu has many important agronomic characters of stone fruits, and it is a main parent in Chinese peach breeding. After cloning of the high molecular weight peach DNA into pBeloBAC 11, we obtained over 22 000 recombinant clones. The BAC library has an average insert size of 95 kb and represents approximately 7 times peach haploid genome equivalents. After being screened with two randomly amplified polymorphic DNA markers, W4 and P20, which are linked to yellow flesh and nectarine genes of peach respectively, ten positive clones have been detected. This library is very useful for map-based cloning of peach genes and physical mapping of peach genome.     

Speciation- induced heritable cytosine methylation changes in polyploid wheat

To study possible epigenetic changes accompanying polyploid speciation, genomic DNA from natural polyploid wheats and their putative diploid progenitors were digested with a pair of isoschizomers Hpa II / Msp I and hybridized to 21 different types of low-copy DNA sequences. It was found that cytosine methylation changes were abundant in natural polyploid wheats after their speciation. The hybridization of the same set of sequences to a synthetic hexaploid wheat along with its parental lines indicated that the extensive DNA methylation changes already existed in the early generations (S5, S6 and Sy) of this plant. Moreover, the high similarity of the changed restriction fragment length polymorphism (RFLP) patterns among three randomly chosen individual plants suggested that the methylation changes occurred even earlier, and/or were of a nonrandom nature. The changed patterns were stably inherited in the three successive selfed generations. Though methylation changes are probably a genome-wide occurrence, they appeared to be confined to the specific types of DNA sequences. The possible implications of the rapid and extensive cytosine methylation changes for several attributes of allopolyploid genome evolution, such as genetic diploidization and gene diversification, are discussed .     

Breeding and molecular cytogenetic identification of wheat-Thinopyrum intermedium addition lines resistant to powdery mildew

Wheat-related species Th. intermedium was used to cross with common wheat Yannong 15. In the self progenies of the hybrid, two addition lines, Ⅱ-1-7-1 and Ⅱ-3-3-2, stable in cytology, were developed by cytology and powdery mildew resistance identification. Their chromosome number were 2n = 44 and formed 22 bivalents at PMC MI. In F₁ of the two addition lines crossing with Yannong 15, there appeared about one univalent at PMC MI, respectively. Resistance identification in greenhouse and field using the No. 15 and mixed strains of E. gramnis f. sp. tritici showed that they were immune to powdery mildew. Chromosome number and resistance identification using the F² single plants of the addition line crossing with Yannong 15 indicated that the resistant gene was located on the alien chromosomes. In situ hybridization using St and E genomic DNA as probe showed that the added chromosome in the two addition lines probably came from the E genome of Th. intermedium, which indicated that a pair of E genome chromosomes carried a new resistant gene to powdery mildew.     

叶绿体DNA分析技术及其在植物系统学研究中的应用

叶绿体DNA在植物系统学研究中已得到广泛应用。综述了DNA杂交、DNA限制酶谱分析、RFLP分析、PCR_RFLP分析、微卫星序列分析、SSCP分析和核酸序列分析等叶绿体DNA分析技术的原理、特点及应用     

Pseudoautosomal DNA sequences in the pairing region of the human sex chromosomes

A DNA probe from a human Y chromosome-derived cosmid detects a single-copy genomic DNA fragment which can appear in different allelic forms shared by both sex chromosomes. Variants at this DNA locus show an autosomal pattern of inheritance, undergo recombination with sexual phenotype and can therefore be described as 'pseudoautosomal'. Another probe from the same cosmid detects a sequence repeated 15-20 times per haploid genome. These repeats also appear pseudoautosomal and map exclusively to the short-arm terminal region of each sex chromosome.     

Genomic and genic sequence variation in synthetic hexaploid wheat （AABBDD） as compared to their parental species

In order to understand the genomic changes during the evolution of hexaploid wheat, two sets of synthetic hexaploid wheat from hybridization between maternal tetraploid wheat （AABB） and paternal diploid goat grass （DD） were used for DNA-AFLP and single strand conformation polymorphism （SSCP） analysis to determine the genomic and genic variation in the synthetic hexaploid wheat. Results indicated that more DNA sequences from paternal diploid species were eliminated in the synthetic hexaploid wheat than from maternal tetraploid wheat, suggesting that genome from parental species of lower ploidity tends to be eliminated preferentially. However, sequence variation detected by SSCP procedure was much lower than those detected by DNA-AFLP, which indicated that much less variation in the genic regions occurred in the synthetic hexaploid wheat, and sequence variations detected by DNA-AFLP could be derived mostly from non-coding regions and repetitive sequences. Our results also indicated that sequence variation in 4 genes can be detected in hybrid F1, which suggested that this type of sequence variation could be resulted from distant hybridization. It was interesting to note that 3 out of the 4 genes were mapped and clustered on the long arm of chromosome 2D, which indicated that variation in genic sequences in synthetic hexaploid wheat might not be a randomized process.     

Breeding of T. aestivum-Ag. intermedium translocation lines with T. timopheevii cytoplasm and characterization by GISH

A male-sterileT. aestivum-Ag. intermedium partial amphiploid with cytoplasm ofT. timopheevii as a female parent was crossed to common wheat. The hybrid was backcrossed to the male parent several times continually and setf-crossed at last. Two stable lines with common wheat phenotype, H96269-2 and H96278, have been obtained. The chromosome numbers of the two lines are all2n = 42 in somatic cetls. By inoculation test, the two lines show a high levet of resistance to yetlow rust. Through genomicin situ hybridization (GISH) withAg. intermedium total genomic DNA as a probe, it is demonstrated that the two stable lines are all small segmental translocation lines, and the translocated chromosome segments fromAg. intermedium are located on the short arm terminals of wheat chromosomes. Genetics analysis suggests that the yetlow rust resistance gene(s) are probably located on the translocated chromosome segments ofAg. intermedium.     

Genomic and genie sequence variation in synthetic hexaploid wheat(AABBDD)as compared to their parental species

In order to understand the genomic changes during the evolution of hexaploid wheat,two sets of synthetic hexaploid wheat from hybridization between maternal tetraploid wheat (AABB) and paternal diploid goat grass(DD)were used for DNA-AFLP and single strand conformation polymorphism (SSCP) analysis to determine the genomic and genie variation in the synthetic hexaploid wheat.Results indicated that more DNA sequences from paternal diploid species wen eliminated in the synthetic hexaploid wheat than from maternal tetraploid wheat,suggesting that genome from parental species of lower ploidity tends to be eliminated preferentially.However,sequence variation detected by SSCP procedure was much lower than those detected by DNA-AFLP.which indicated that much less variation in the genie regions occurred in the synthetic hexaploid wheat.and sequence variations detected by DNA-AFLP could be derived mostly from non-coding regions and repetitive sequences.Our results also indicated that sequence variation in 4 genes can be detected in hybrid F1.which suggested that this type of sequence variation could be resulted from distant hybridization.It was interesting to note that 3 out of the 4 genes were mapped and clustered on the long alTll of chromosome 2D,which indicated that variation in genic sequences in synthetic hexaploid wheat might not be a randomized process.     

Genomic and genic sequence variation in synthetic hexaploid wheat (AABBDD) as compared to their parental species

In order to understand the genomic changes during evolution of hexaploid wheat, two sets of synthetic hexaploid wheat from hybridization between maternal tetraploid wheat (AABB) and paternal diploid goat grass (DD) were used for DNA-AFLP and single strand conformation polymorphism (SSCP) analysis to determine the genomic and genic variation in the synthetic hexaploid wheat. Results indicated that more DNA sequences from paternal diploid species were eliminated in the synthetic hexaploid wheat than from maternal tetraploid wheat, suggesting that genome from parental species of lower ploidity tends to be eliminated preferentially. However, sequence variation detected by SSCP procedure was much lower than those detected by DNA-AFLP, which indicated that much less variation in the genic regions occurred in the synthetic hexaploid wheat, and sequence variations detected by DNA-AFLP could be derived mostly from non-coding regions and repetitive sequences. Our results also indicated that sequence variation in 4 genes can be detected in hybrid F1, which suggested that this type of sequence variation could be resulted from distant hybridization. It was interesting to note that 3 out of the 4 genes were mapped and clustered on the long arm of chromosome 2D, which indicated that variation in genic sequences in synthetic hexaploid wheat might not be a randomized process.     

Expression of lysine-rich protein gene and analysis of lysine content in transgenic wheat

Expression vector pBPC102, which carries winged bean lysine-rich protein (wblrp) gene and dihydropicolinate synthase (DHDPS) gene, was transferred into hexaploid winter wheat cv. Jinghua No.l, Jing411, You899 and Yangnongl5 explants of immature inflorescence and immature embryos by particle bombardment. More than 100 transgenic plants were obtained under the selection of s-(2-aminoethyl)-L-cysteine (AEC). Confirmed transgenic plants of To and TI generation by PCR and PCR-Southern blotting analyses showed successful integration of wblrp gene into wheat genome. Analysis of transgenic plant lines of T2 by Northern dot-blotting showed good expression of wblrp gene in offspring seed. The content of free lysine in leaves, contents of bound lysine and total proteins in seeds of T2 transgenie wheat lines were determined and analyzed. Among 34 tested transgenic lines, levels of free lysine content in leaves of 9 transgenic lines are 2~3times higher than un-trans-formed wild-type cultivars. Among 17 analyzed transgenic lines, bound lysine content of 4 transgenic lines is more than 10% higher than that of wild-type cultivars. Our research suggests that introducing wblrp gene into wheat is an effective way to improve its nutrition quality.     

Genome linking with yeast artificial chromosomes

The haploid genome of Caenorhabditis elegans consists of some 80 x 10(6) base pairs of DNA contained in six chromosomes. The large number of interesting loci that have been recognized by mutation, and the accuracy of the genetic map, mean that a physical map of the genome is highly desirable, because it will facilitate the molecular cloning of chosen loci. The first steps towards such a map used a fingerprinting method to link cosmid clones together. This approach reached its practical limit last year, when 90-95% of the genome had been cloned into 17,500 cosmids assembled into some 700 clusters (contigs), but the linking clones needed were either non-existent or extremely rare. Anticipating this, we had planned to link by physical means--probably by hybridization to NotI fragments separated by pulse field gel electrophoresis. NotI recognizes an eight base sequence of GC pairs; thus the fragments should be large enough to bridge regions that clone poorly in cosmids, and, with no selective step involved, would necessarily be fully representative. However, with the availability of a yeast artificial chromosome (YAC) vector, we decided to use this alternative source of large DNA fragments to obtain linkage. The technique involves the ligation of large (50-1,000 kilobase) genomic fragments into a vector that provides centromeric, telomeric and selective functions; the constructs are then introduced into Saccharomyces cerevisiae, and replicate in the same manner as the host chromosomes.