Detecting high-resolution polymorphisms in human coding loci by combining PCR and single-strand conformation polymorphism (SSCP) analysis.

A strategy is described that allows the development of polymorphic genetic markers to be characterized in individual genes. Segments of the 3' untranslated regions are amplified, and polymorphisms are detected by digestion with frequently cutting enzymes and with the detection of single-stranded conformation polymorphisms. This allows these genes, or DNA segments, to be placed on the linkage maps of human chromosomes. Polymorphisms in two genes have been identified using this approach. A HaeIII polymorphism was detected in the KIT proto-oncogene, physically assigned to chromosome 4q11-12. This polymorphism is linked to other chromosome 4p markers and is in linkage disequilibrium with a HindIII polymorphism previously described at this locus. We have also identified in the insulin-like growth factor1 receptor gene (IGF1R) a 2-bp deletion that is present at a frequency of .25 in the Caucasian population. Pedigree analysis with this insertion/deletion polymorphism placed the IGF1R gene at the end of the current linkage map of chromosome 15q, consistent with the physical assignment of 15q2526. Thus, polymorphisms in specific genes can be used to related the physical, genetic, and comparative maps of mammalian genomes and to simplify the testing of candidate genes for human diseases.     

Random sequence oligonucleotide primers detect polymorphic DNA products which segregate in inbred strains of mice

The random amplification of polymorphic DNA (RAPD) using primers of arbitrary nucleotide sequence has been extremely valuable in identifying heritable markers in a variety of systems. The present studies examined whether the RAPD technique can identify large numbers of polymorphisms that can be used to construct genetic maps in inbred strains of mice. By screening the inbred mouse strains C57BL/6J and DBA/2J with 481 random 10-mer oligonucleotide primers, we identified 95 polymorphisms and mapped 76 of these by use of the BXD series of recombinant inbred (RI) strains. The results clearly demonstrate that the RAPD technique allows for the identification of large numbers of DNA-based polymorphisms that distinguish these two inbred strains of mice,and that such markers can readily be used to construct molecular genetic linkage maps.     

Genetic mapping by single sperm typing

The polymerase chain reaction makes it possible to analyse DNA sequences in a single cell and has led to a new approach for constructing genetic maps. We describe a procedure called 'sperm typing' which can accurately classify individual meiotic products as recombinant of non-recombinant. This permits the linkage relationships among DNA polymorphisms to be determined without pedigree analysis.     

Genetic and physical mapping of two centromere-proximal regions of chromosome IV in Aspergillus nidulans

Chromosome IV is the smallest chromosome of Aspergillus nidulans. The centromere-proximal portion of the chromosome was mapped physically using overlapping clones of a cosmid genomic library. Two contiguous segments of a physical map, based on restriction mapping of cosmid clones, were generated, together covering more than 0.4 Mb DNA. A reverse genetic mapping approach was used to establish a correlation between physical and genetic maps; i.e., marker genes were integrated into physically mapped segments and subsequently mapped by mitotic and meiotic recombination. The resulting data, together with additional classical genetic mapping, lead to a substantial revision of the genetic map of the chromosome, including the position of the centromere. Comparison of physical and genetic maps indicates that meiotic recombination is low in subcentromeric DNA, its frequency being reduced from 1 crossover per 0.8 Mb to approximately 1 crossover per 5 Mb per meiosis. The portion of the chromosome containing the functional centromere was not mapped because repeat-rich regions hindered further chromosome walking. The size of the missing segment was estimated to be between 70 and 400 kb.     

DNA遗传标记技术在林业生产中的应用

林木种子及苗木鉴别技术的准确性和可靠性是提高营林造林质量的关键环节。传统的种苗鉴别技术的局限性往往使之不能有效鉴别林木种子的品种及种源。ＤＮＡ遗传标记技术则能提供稳定、准确、可靠的种及品种特异性标记,因而成为林业生产上极具潜力的品种鉴定手段。本文综述了目前国际上ＤＮＡ遗传标记技术的研究进展,并讨论了开展我国林木种苗ＤＮＡ鉴定技术研究的若干设想。     

Sequence-based linkage analysis

The rapid decrease in the cost of DNA sequencing will enable its use for novel applications. Here, we investigate the use of DNA sequencing for simultaneous discovery and genotyping of polymorphisms in family linkage studies. In the proposed approach, short contiguous segments of genomic DNA, regularly spaced across the genome, are resequenced in each pedigree member, and all sequence polymorphisms discovered within a pedigree are used as genetic markers. We use computer simulations consistent with observed human sequence diversity to show that segments of 500-1,000 base pairs, spaced at intervals of 1-2 Mb across the genome, provide linkage information that equals or exceeds that of traditional marker-based approaches. We validate these results experimentally by implementing the sequence-based linkage approach for chromosome 19 in CEPH pedigrees.     

Polymorphic microsatellite DNA amplification customized for chimpanzee paternity testing

DNA segments containing GT/AC dinucleotide repeats in the chimpanzee (Pan troglodytes) genome were screened. Thirteen transformedE. coli colonies were identified with the (GT)₁₀ probe to have chimpanzee DNA fragments containing (GT)_n repeats. These potentially polymorphic (variable n) DNA segments were sequenced. Primers for the polymerase chain reaction (PCR) amplifying these DNA segments were designed. Six pairs of primers yielded polymorphic PCR products. Three of them revealed considerable length polymorphisms and heterozygosities in a group of captive chimpanzees. For studies on chimpanzees in the wild and in captivity, these primers should be useful for paternity testing, for investigating genetic variations, and for improving the genetic maintenance of breeding colonies. The strategy adopted in the present study to obtain PCR primers amplifying polymorphic microsatellite DNA segments may well be applicable to almost all eukaryotic organisms.     

The molecular organization of the H-2K region of two t-haplotypes: implications for the evolution of genetic diversity.

The genetic diversity between the t12 and tw5 haplotype chromosomes was studied by analyzing the molecular organization of the H-2K region. Twenty-one cosmid clones spanning over 150 kb of the H-2K region of both t-haplotypes were defined, and high resolution restriction maps were determined. Detailed comparison of the t12 and tw5 restriction maps revealed the following. (i) The H-2K regions of both t-haplotypes retain a very similar molecular organization to that reported for B10, BALB/c and AKR. The nucleotide sequence diversity estimated from restriction site polymorphism is 0.68% between the t12 and tw5 haplotypes; these two t-haplotypes are no more similar to one another than BALB/c is to AKR. (ii) Genetic recombination is strongly implicated in generating H-2 polymorphism. (iii) Genetic polymorphisms, defined as small restriction fragment size differences, are observed at multiple sites along the H-2K region. An Alu-like B2 sequence and BAM5-R homologous sequence were identified as the inserted/deleted DNA segments of two of these sites, suggesting that insertion/deletion of mobile elements is a general mechanism for generating genetic diversity.     

Codominant PCR-based markers for Pinus taeda developed from mapped cDNA clones

 We report a strategy for developing codominant PCR-based genetic markers by using sequenced cDNA clones from loblolly pine (Pinus taeda L.). These clones were previously used as probes for detecting restriction fragment length polymorphisms (RFLPs) to generate linkage maps. After assessing the complexity of banding patterns from Southern blots, we selected clones representing relatively simple gene families, and then determined nucleotide sequences for about 200 bp at each end of the cDNA inserts. Specific PCR primers were designed to amplify samples of genomic DNA derived from two loblolly pine mapping populations. Polymorphisms were detected after digesting the amplified DNA fragments with a battery of restriction endonucleases, and most polymorphisms were inherited in a Mendelian fashion. These newly identified genetic markers are codominant and relatively simple to use. By assaying DNA from individuals used to construct RFLP maps, we show that most of these markers map to the same position as the RFLP loci detected using their corresponding cDNAs as probes, implying that these markers have been converted from RFLP to PCR-based methods. These PCR-based markers will be useful for genome mapping and population genetics. Received: 10 February 1998 / Accepted: 25 February 1998     

Polymorphism in the structure of the yeast mitochondrial tRNA synthesis locus.

Yeast mitochondrial DNA contains a genetic locus, called the tRNA synthesis locus, which codes for information necessary for mitochondrial tRNA biosynthesis. A 9S RNA molecule coded by this locus is thought to be the trans-acting element required for the removal of 5' extensions from tRNA precursors. The DNA coding for this RNA maps to a region of mitochondrial DNA known to contain strain specific restriction site polymorphisms. Comparison of the tRNA synthesis locus in two such strains by sequence analysis demonstrates that the restriction enzyme polymorphisms are due to the deletion/insertion of a 50 base pair GC-rich element in the 5' flanking sequence of the 9S RNA coding region. There are also several differences between the 9S RNA coding region of these two strains which do not interfere with the tRNA synthesis function.