Discordance in the distribution of markers of different inheritance systems (nDNA,mtDNA, and Chromosomes) in the superspecies complex <Emphasis Type="Italic">Mus musculus</Emphasis> as a result of extensive hybridization in primorye

The genetic structure of eight Mus musculus L. populations in Primorskii krai was studied with the use of taxon-specific markers of different inheritance systems: nDNA (RAPD), mtDNA (D-loop), and chromosomes. The results obtained demonstrate that although the compared nuclear marker characteristics (nDNA and chromosomes) have the same basis they are not linke with each other and, moreover, are often mutually inconsistent. Discordance in the inheritance of the marker characteristics in most of the animals studied is a result of extensive hybridization involving two to four house mouse subspecies. To identify taxonspecific nuclear markers revealed by RAPD, some RAPD PCR products were cloned, and their localization on chromosomes was determined. It was found that some fragments similar in size consist of two different comigrating sequences that are localized on different chromosomes and belong to different subspecies. All sequenced anonymous markers are localized in protein-coding genes. The functions of genes containing the marker sequences have been established. Differences in the taxon-specific RAPD fragments are associated with changes in the structure of important functional genes, and this can be considered as a significant genetic marker.     

Identification and mapping of polymorphic RAPD markers of pea (Pisum sativum L.) genome

Various pea cultivars, lines, and mutants were studied by the RAPD method. Polymorphic fragments characteristic of certain pea genotypes and which can be used for identifying genotypes were detected. Inheritance of some polymorphic RAPD fragments was studied. Mendelian inheritance of these fragments was shown. By analyzing the data obtained in studies of RAPD polymorphism, genetic distances between different pea cultivars, lines, and mutants were calculated and a genealogic dendogram showing a varying extent of differences between RAPD patterns was constructed. Ten new RAPD markers linked to various pea genes were detected. Genetic distances between RAPD markers and genes to which they are linked were calculated, and the respective disposition of RAPD markers on chromosomes was established.     

Identification and mapping of polymorphic RAPD markers of pea (<Emphasis Type="Italic">Pisum sativum</Emphasis> L.) genome

Various pea cultivars, lines, and mutants were studied by the RAPD method. Polymorphic fragments characteristic of certain pea genotypes and which can be used for identifying genotypes were detected. Inheritance of some polymorphic RAPD fragments was studied. Mendelian inheritance of these fragments was shown. By analyzing the data obtained in studies of RAPD polymorphism, genetic distances between different pea cultivars, lines, and mutants were calculated and a genealogic dendogram showing a varying extent of differences between RAPD patterns was constructed. Ten new RAPD markers linked to various pea genes were detected. Genetic distances between RAPD markers and genes to which they are linked were calculated, and the respective disposition of RAPD markers on chromosomes was established.Translated from Genetika, Vol. 41, No. 3, 2005, pp. 341–348.Original Russian Text Copyright © 2005 by Koveza, Kokaeva, Konovalov, Gostimsky.     

Nuclear mitochondrial pseudogenes

As has been demonstrated recently, the transfer of genetic material from mitochondria to the nucleus and its integration into the nuclear genome is a continuous and dynamic process. Fragments of mitochondrial DNA (mtDNA) are incorporated in the nuclear genome as noncoding sequences, which are called nuclear mitochondrial pseudogenes (NUMT pseudogenes or NUMT inserts). In various eukaryotes, NUMT pseudogenes are distributed through different chromosomes to form a “library” of mtDNA fragments, providing important information on genome evolution. The escape of mtDNA from mitochondria is mostly associated with mitochondrial damage and mitophagy. Fragments of mtDNA may be integrated into nuclear DNA (nDNA) during repair of double-strand breaks (DSBs), which are caused by endogenous or exogenous agents. DSB repair of nDNA with a capture of mtDNA fragments may occur via nonhomologous end joining or a similar mechanism that involves microhomologous terminal sequences. An analysis of the available data makes it possible to suppose that the NUMT pseudogene formation rate depends on the DSB rate in nDNA, the activity of the repair systems, and the number of mtDNA fragments leaving organelles and migrating into the nucleus. Such situations are likely after exposure to damaging agents, first and foremost, ionizing radiation. Not only do new NUMT pseudogenes change the genome structure in the regions of their integration, but they may also have a significant impact on the actualization of genetic information. The de novo integration of NUMT pseudogenes in the nuclear genome may play a role in various pathologies and aging. NUMT pseudogenes may cause errors in PCR-based analyses of free mtDNA as a component of total cell DNA because of their coamplification.     

Mapping of avirulence genes in the rice blast fungus, Magnaporthe grisea, with RFLP and RAPD markers

Three genetically independent avirulence genes, AVR1-Irat7, AVRI-MedNoi; and AVR1-Ku86, were identified in a cross involving isolates Guy11 and 2/0/3 of the rice blast fungus, Magnaporthe grisea. Using 76 random progeny, we constructed a partial genetic map with restriction fragment length polymorphism (RFLP) markers revealed by probes such as the repeated sequences MGL/MGR583 and Pot3/MGR586, cosmids from the M. grisea genetic map, and a telomere sequence oligonucleotide. Avirulence genes AVR1-MedNoi and AVR1-Ku86 were closely linked to telomere RFLPs such as marker TelG (6 cM from AVR1-MedNoi) and TelF (4.5 cM from AVR1-Ku86). Avirulence gene AVR1-Irat7 was linked to a cosmid RFLP located on chromosome 1 and mapped at 20 cM from the avirulence gene AVR1-CO39. Using bulked segregant analysis, we identified 11 random amplified polymorphic DNA (RAPD) markers closely linked (0 to 10 cM) to the avirulence genes segregating in this cross. Most of these RAPD markers corresponded to junction fragments between known or new transposons and a single-copy sequence. Such junctions or the whole sequences of single-copy RAPD markers were frequently absent in one parental isolate. Single-copy sequences from RAPD markers tightly linked to avirulence genes will be used for positional cloning.     

RAPD-based genetic linkage maps of Tribolium castaneum.

A genetic map of the red flour beetle (Tribolium castaneum) integrating molecular with morphological markers was constructed using a backcross population of 147 siblings. The map defines 10 linkage groups (LGs), presumably corresponding to the 10 chromosomes, and consists of 122 randomly amplified polymorphic DNA (RAPD) markers, six molecular markers representing identified genes, and five morphological markers. The total map length is 570 cM, giving an average marker resolution of 4.3 cM. The average physical distance per genetic distance was estimated at 350 kb/cM. A cluster of loci showing distorted segregation was detected on LG9. The process of converting RAPD markers to sequence-tagged site markers was initiated: 18 RAPD markers were cloned and sequenced, and single-strand conformational polymorphisms were identified for 4 of the 18. The map positions of all 4 coincided with those of the parent RAPD markers.     

Development and study of SCAR markers in pea (Pisum sativum L.)

In order to develop more specific markers that characterize particular regions of the pea genome, the data on nucleotide sequences of RAPD fragments were used for choosing more extended primers, which may be helpful in amplifying a fragment corresponding to the particular DNA region. Of the 14 STS markers obtained from 14 polymorphic RAPD fragments, 12 were polymorphic, i.e., they are SCAR markers that can be used in genetic analysis. The transition from complex RAPD spectra to amplification of a particular SCAR marker substantially facilitates analysis of large samples for the presence or absence of the examined fragment. Inheritance of the developed SCAR markers was studied in F1 and F2. SCAR markers were used to identify various pea lines, cultivars, and mutants. It was established that the study of amplification of STS markers in various pea genotypes at varying temperatures of annealing and the comparison with amplification of the original RAPD fragments in the same genotypes provide an approach for analysis of RAPD polymorphism type.     

Characterization of chromosome-specific S-SAP markers and their use in studying genetic diversity in Aegilops species.

The short interspersed nuclear element (SINE), Au, was used to develop sequence-specific amplified polymorphism (S-SAP) markers for U- and M-genome chromosomes. The markers were localized using Triticum aestivum (wheat)-- Aegilops geniculata and wheat-- Aegilops biuncialis disomic chromosome addition lines. Thirty-seven markers distributed over 6 U and 6 M chromosomes were produced. A genetic diversity study carried out on 37 accessions from Ae. biuncialis, Ae. comosa, Ae. geniculata, and Ae. umbellulata suggested that Ae. biuncialis have arisen from its diploid ancestors more recently than Ae. geniculata. Several earlier studies indicated that the M genomes in polyploid Aegilops species had accumulated substantial rearrangements, whereas the U genomes remained essentially unmodified. However, this cannot be attributed to the preferential insertion of retroelements into the M genome chromosomes. Fourteen markers from a total of 8 chromosomes were sequenced; 3 markers were similar to known plant genes, 1 was derived from a long terminal repeat (LTR) retrotransposon, and 10 markers did not match to any known DNA sequences, suggesting that they were located in the highly variable intergenic regions.     

Molecular characterization of RAPD and SCAR markers linked to the Tm-1 locus in tomato

We have cloned and sequenced six RAPD fragments tightly linked to the Tm-1 gene which confers tomato mosaic virus (ToMV) resistance in tomato. The terminal ten bases in each of these clones exactly matched the sequence of the primer for amplifying the corresponding RAPD marker, except for one in which the 5-endmost two nucleotides were different from those of the primer. These RAPD clones did not cross-hybridize with each other, suggesting that they were derived from different loci. From Southern-hybridization experiments, five out of the six RAPD clones were estimated to be derived from middle- or high-repetitive sequences, but not from any parts of the ribosomal RNA genes (rDNA), which are known to be tightly linked with the Tm-1 locus. The remaining clone appeared to be derived from a DNA family consisting of a few copies. These six RAPD fragments were converted to sequence characterized amplified region (SCAR) markers, each of which was detectable using a pair of primers having the same sequence as that at either end of the corresponding RAPD clone. All pairs of SCAR primers amplified distinct single bands whose sizes were the same as those of the RAPD clones. In four cases, the SCAR markers were present in the line with Tm-1 but absent in the line without it, as were the corresponding RAPD markers. In the two other cases, the products of the same size were amplified in both lines. When these SCAR products were digested with different restriction endonucleases which recognize 4-bp sequences, however, polymorphisms in fragment length were found between the two lines. These co-dominant markers are useful for differentiating heterozygotes from both types of homozygote.     

Cloning of AFLP markers linked to resistance to Peronosclerospora sorghi in maize

Genetic mapping of resistance genes for sorghum downy mildew (SDM) in maize revealed multiple-locus inheritance. A combination of AFLP (amplified fragment length polymorphism) technique with bulked segregant analysis (BSA) was applied to map the genes involved in the resistance to SDM (Peronosclerospora sorghi) in a recombinant inbred population. Three AFLP markers were identified and mapped to chromosomes 1 and 9, in regions previously associated with SDM resistance. One other AFLP marker was found to be associated with disease susceptibility but could not be linked to any chromosome. These four AFLP fragments were isolated, cloned and sequenced. A BLAST search of the GenBank database showed that none of these four sequences was closely related to resistance genes that have been reported previously. Sequence-characterized amplified regions (SCARs) were produced and used to assess the presence of SDM resistance genes and characterize specific genotypes. These markers may be useful in marker-assisted breeding programs.     

Development and Study of SCAR Markers in Pea (<Emphasis Type="Italic">Pisum sativum</Emphasis> L.)

In order to develop more specific markers that characterize particular regions of the pea genome, the data on nucleotide sequences of RAPD fragments were used for choosing more extended primers, which may be helpful in amplifying a fragment corresponding to the particular DNA region. Of the 14 STS markers obtained from 14 polymorphic RAPD fragments, 12 were polymorphic, i.e., they are SCAR markers that can be used in genetic analysis. The transition from complex RAPD spectra to amplification of a particular SCAR marker substantially facilitates analysis of large samples for the presence or absence of the examined fragment. Inheritance of the developed SCAR markers was studied in F₁ and F₂. SCAR markers were used to identify various pea lines, cultivars, and mutants. It was established that the study of amplification of STS markers in various pea genotypes at varying temperatures of annealing and the comparison with amplification of the original RAPD fragments in the same genotypes provide an approach for analysis of RAPD polymorphism origin.     

Development and utilization of new sequenced characterized amplified region markers specific for E genome of Thinopyrum

Species containing E genome of Thinopyrum offered potential to increase the genetic variability and desirable characters for wheat improvement. However, E genome specific marker was rare. The objective of the present report was to develop and identify sequenced characterized amplified region (SCAR) markers that can be used in detecting E chromosome in wheat background for breeding purpose. Total 280 random amplified polymorphic DNA (RAPD) primers were amplified for seeking of E genome specific fragments by using the genomic DNA of Thinopyrum elongatum and wheat controls as templates. As a result, six RAPD fragments specific for E genome were found and cloned, and then were converted to SCAR markers. The usability of these markers was validated using a number of Egenome-containing species and wheat as controls. These markers were subsequently located on E chromosomes using specific PCR and fluorescence in situ hybridization (FISH). SCAR markers developed in this research could be used in molecular marker assisted selection of wheat breeding with Thinopyrum chromatin introgressions.     

A RAPD marker associated with B chromosomes in Partamona helleri (Hymenoptera, Apidae)

The hymenopteran Partamona helleri is found in southwestern Brazil in the Mata Atlantica from the north of the state of Santa Catarina until the south of Bahia. This work shows that P. helleri can carry up to four B chromosomes per individual. In order to obtain more information about P. helleri B chromosomes, the RAPD technique was used to detect DNA fragments associated with these chromosomes. The results showed that the RAPD technique is useful to detect specific sequences associated with B chromosomes. One RAPD marker was identified, cloned and used as probe in a DNA blot analysis. This RAPD marker hybridized with sequences present only in individuals containing B chromosomes.     

两个不同地区东方田鼠杂交子代RAPD标记分析

目的研究不同地区东方田鼠杂交后产下的子代的遗传特性.方法筛选4条10bp随机引物对宁夏和洞庭湖地区东方田鼠杂交子代的基因组进行随机扩增多态DNA(RAPD)分析,并对不同地区亲代以及子代相互之间的基因组DNA进行相似性分析.结果①所有东方田鼠均有相同的扩增片段出现;②两个不同地区的亲代分别有特异性片般;③亲代的DNA带型均能在子代中找到;④同一胎次东方田鼠之间基因共享度大约在72%～96%之间.结论RAPD分析能在一定程度上反映出东方田鼠种的特性以及亚种的特异性,而且同一胎次之间基因共享度较高.     

Comparative analysis of nucleotide sequences of chromosomal DNA isolated from nuclear envelopes and cores of rosette-like structures of murine interphase chromosomes]

Six DNA fragments of interphase chromosomes isolated from nuclear envelopes of murine hepatocytes were cloned and sequenced. Analysis of their structural-functional organization suggests that these fragments are highly specified protein-nonencoding fractions of a eukaryotic genome. In the evolutionary process, they appear already in archaebacteria and may be "ancestral" for DNA sequences involved in structuring chromosomal domains (rosette-like structures) of tissue-specific genes. In their composition, these fragments have nucleotide sequences homologous to the repeats of the SINE and LINE families and to the satellite DNA of murine centromeres.     

两个地区东方田鼠基因组RAPD分析比较研究

目的　从DNA的水平分析比较两个地区东方田鼠的分子遗传特征,探讨以RAPD标记鉴别两个地区的东方田鼠。方法　筛选6条10bp的随机引物对洞庭湖和青铜峡地区的东方田鼠基因组进行了随机扩增多态DNA(RAPD)分析,并对这两个地区的东方田鼠的基因组DNA进行了比较。结果　①两个地区东方田鼠的所有受试个体中共有的片段数为20条,这是两个地区东方田鼠的共性所在;②两个地区东方田鼠各有其特异性扩增片段;③引物S17和S80可作为鉴别两个地区东方田鼠的特异性引物;④不同地区的东方田鼠其不同个体之间的共享度较低,且存在较大差异;两个地区东方田鼠的遗传背景均呈非均一性。结论　运用RAPD方法可以作为鉴别不同地区东方田鼠的基因多态性的标记。     

SCAR markers for discriminating species of two genera of medicinal plants, Liriope and Ophiopogon

The development of DNA markers that can closely discriminate between Liriope and Ophiopogon species is vital for efficient and accurate identification of these species, and to ensure the quality, safety, and efficacy of medicines made from these plants. We developed species-specific molecular markers for these two genera. Forty RAPD primers were tested to detect polymorphism; species-specific RAPD bands were gel-purified, cloned, and sequenced. Primers for sequence-characterized amplified regions (SCARs) were then designed, based on nucleotide sequences of specific RAPD primers. SCAR markers SA06 and SB05, specific to Ophiopogon japonicus, amplified 460- and 553-bp DNA fragments, respectively. The marker SA12 amplified a 485-bp fragment specific to Liriope platyphylla. This is the first report of a species-specific SCAR marker for this group. These markers will be useful for rapid identification of closely related Liriope and Ophiopogon species.     

质体基因工程中选择标记基因研究进展

与细胞核基因工程相比,质体基因工程能更安全、精确和高效地对外源基因进行表达,作为下一代转基因技术已广泛用于基础研究和生物技术应用领域。与细胞核基因工程一样,质体基因工程中也需要合适的选择标记基因用于转化子的筛选和同质化,但基于质体基因组的多拷贝性和母系遗传特点,转化子的同质化需要一个长期的筛选过程,这就决定了质体基因工程中选择标记基因的选择标准将不同于细胞核基因工程中广泛使用的现行标准。目前,质体基因工程的遗传转化操作中使用较多的是抗生素选择标记基因,出于安全性考虑,需要找到可替换、安全的选择标记基因或有效的标记基因删除方法。本文在对质体基因工程研究的相关文献分析基础之上,对主要使用的选择标记基因及其删除体系进行了综述,并对比了其优缺点,同时探讨了质体基因工程中所使用的报告基因,以期为现有选择标记基因及其删除体系的改进和开发提供一定参考,进一步推动质体基因工程,尤其是单子叶植物质体基因工程的发展。     

The use of random amplified polymorphic DNA markers in wheat

Summary An evaluation was made of the use of random amplified polymorphic DNA (RAPD) as a genetic marker system in wheat. Reproducible amplification products were obtained from varietal, homozygous single chromosome recombinant line and wheat/alien addition line genomic DNA with selected primers and rigorously optimized reaction conditions. Factors influencing the RAPD patterns are DNA concentration, Mg²⁺ concentration, polymerase concentration and denaturing temperature. In wheat, the non-homoeologous, non-dose responsive and dominant behaviour of RAPD products devalues their use as genetic markers for the construction of linkage maps, and the high probability that the amplified fragments derive from repetitive DNA limits their use as a source of conventional RFLP probes. However, RAPD markers will most certainly find many applications in the analysis of genotypes where single chromosomes or chromosome segments are to be manipulated.