Isolating promoters of multigene family members from the polyploid sugarcane genome by PCR-based walking in BAC DNA

The availability of a wider range of promoters for regulated expression in valuable transgenic crops would benefit functional genomics studies and current biotechnology programs aimed at improved productivity. Polymerase chain reaction (PCR)-based genome walking techniques are commonly used to isolate promoters or 5' flanking genomic regions adjacent to known cDNA sequences in genomes that are not yet completely sequenced. However, these techniques are problematic when applied directly to DNA isolated from crops with highly complex and large genomes. An adaptor ligation-mediated PCR-based BAC genome walking method is described here for the efficient isolation of promoters of multigene family members, such as the putative defense and fiber biosynthesis DIRIGENT genes that are abundant in the stem of sugarcane, a species with a highly polyploid genome. The advantage of this method is the efficient and specific amplification of the target promoter using BAC genomic DNA as template for the adaptor ligation-mediated PCR walking.     

NfCR1, the first non-LTR retrotransposon characterized in the Australian lungfish genome, Neoceratodus forsteri, shows similarities to CR1-like elements

The genomes of lungfish, together with those of some urodele amphibians, are the largest of all vertebrate genomes. It has been assumed that the bulk of the DNA making up these large genomes has been derived from repeat elements, like the noncoding DNA of those genomes that have been sequenced (e.g., human). In an attempt to characterize repeat sequences in the lungfish genome, we have isolated, by restriction enzyme digestion of genomic DNA, sequences of a repeat element in Neoceratodus forsteri, the most primitive of the living lungfishes. The fragments sequenced from the EcoRI and BglII digests were used to perform genome walking PCR in order to obtain the full sequence of the repeat element. This element shares homology with the non-LTR (LINE) element, Chicken Repeat 1 (CR1), described for several vertebrates and some invertebrates; we have called it N. forsteri CR1 (NfCR1). NfCR1 shares all the domains of other CR1 elements but it also has several unique features that suggest it may no longer be active in the lungfish genome. It occurs in both full-length and 5'-truncated versions and in its present "inactive" form represents approximately 0.05% of the lungfish genome.     

Genome walking in eukaryotes

Genome walking is a molecular procedure for the direct identification of nucleotide sequences from purified genomes. The only requirement is the availability of a known nucleotide sequence from which to start. Several genome walking methods have been developed in the last 20 years, with continuous improvements added to the first basic strategies, including the recent coupling with next generation sequencing technologies. This review focuses on the use of genome walking strategies in several aspects of the study of eukaryotic genomes. In a first part, the analysis of the numerous strategies available is reported. The technical aspects involved in genome walking are particularly intriguing, also because they represent the synthesis of the talent, the fantasy and the intelligence of several scientists. Applications in which genome walking can be employed are systematically examined in the second part of the review, showing the large potentiality of this technique, including not only the simple identification of nucleotide sequences but also the analysis of large collections of mutants obtained from the insertion of DNA of viral origin, transposons and transfer DNA (T-DNA) constructs. The enormous amount of data obtained indicates that genome walking, with its large range of applicability, multiplicity of strategies and recent developments, will continue to have much to offer for the rapid identification of unknown sequences in several fields of genomic research.     

The mitochondrial genome of the legume Vigna radiata and the analysis of recombination across short mitochondrial repeats

The mitochondrial genomes of seed plants are exceptionally fluid in size, structure, and sequence content, with the accumulation and activity of repetitive sequences underlying much of this variation. We report the first fully sequenced mitochondrial genome of a legume, Vigna radiata (mung bean), and show that despite its unexceptional size (401,262 nt), the genome is unusually depauperate in repetitive DNA and "promiscuous" sequences from the chloroplast and nuclear genomes. Although Vigna lacks the large, recombinationally active repeats typical of most other seed plants, a PCR survey of its modest repertoire of short (38-297 nt) repeats nevertheless revealed evidence for recombination across all of them. A set of novel control assays showed, however, that these results could instead reflect, in part or entirely, artifacts of PCR-mediated recombination. Consequently, we recommend that other methods, especially high-depth genome sequencing, be used instead of PCR to infer patterns of plant mitochondrial recombination. The average-sized but repeat- and feature-poor mitochondrial genome of Vigna makes it ever more difficult to generalize about the factors shaping the size and sequence content of plant mitochondrial genomes.     

微生物完整基因组测定中的Gap closure策略

微生物基因组空缺区域(Gap)中可能存在重要的生物学信息,如果无法补齐所有Gap,不仅不能获得完整的基因组图谱,还会给后续的基因组信息解读造成很大困难。而基因组空缺区域填充(Gap closure)是获得微生物基因组完成图的关键,本文结合作者以及借鉴上海人类基因组研究中心在微生物基因组Gap closure中的经验,针对微生物基因组Gap closure常用的6种策略:参考序列比对、多引物PCR、基因组步移、基因组文库克隆末端测序、末端配对(Paired-End)以及基因组光学图谱技术进行综述。     

Small repeated sequences and the structure of plant mitochondrial genomes.

The structure of plant mitochondrial genomes has proven to be complex and difficult to study. Recombination across large and small repeated sequences can result in genome diversity within individual plants, as well as rapid evolutionary change in genome structure. The role of these repeats is becoming more obvious as mitochondrial genomes are examined in detail.     

Complete nucleotide mtDNA sequence of Barbary sheep (Ammotragus lervia).

In this report we describe the complete sequence of the mtDNA genome of Ammotragus lervia (Barbary sheep or aoudad) as obtained by PCR and sequencing with primer walking using flanking sequences. The molecule is 16,530 base pairs in length, resulting similar to those of goat and sheep. The genome organization matches to those of other mammalian mitochondrial genomes. The phylogenetic position of the Ammotragus relative to twelve other mammalian species was assessed based on protein-coding sequences. A goat-aoudad split of 9.9-8.9 MYBP has been estimated, whereas the divergence ancestor/caprines was dated at 12.1-10.8 MYBP.     

The Mitochondrial Genome of Soybean Reveals Complex Genome Structures and Gene Evolution at Intercellular and Phylogenetic Levels

Determining mitochondrial genomes is important for elucidating vital activities of seed plants. Mitochondrial genomes are specific to each plant species because of their variable size, complex structures and patterns of gene losses and gains during evolution. This complexity has made research on the soybean mitochondrial genome difficult compared with its nuclear and chloroplast genomes. The present study helps to solve a 30-year mystery regarding the most complex mitochondrial genome structure, showing that pairwise rearrangements among the many large repeats may produce an enriched molecular pool of 760 circles in seed plants. The soybean mitochondrial genome harbors 58 genes of known function in addition to 52 predicted open reading frames of unknown function. The genome contains sequences of multiple identifiable origins, including 6.8 kb and 7.1 kb DNA fragments that have been transferred from the nuclear and chloroplast genomes, respectively, and some horizontal DNA transfers. The soybean mitochondrial genome has lost 16 genes, including nine protein-coding genes and seven tRNA genes; however, it has acquired five chloroplast-derived genes during evolution. Four tRNA genes, common among the three genomes, are derived from the chloroplast. Sizeable DNA transfers to the nucleus, with pericentromeric regions as hotspots, are observed, including DNA transfers of 125.0 kb and 151.6 kb identified unambiguously from the soybean mitochondrial and chloroplast genomes, respectively. The soybean nuclear genome has acquired five genes from its mitochondrial genome. These results provide biological insights into the mitochondrial genome of seed plants, and are especially helpful for deciphering vital activities in soybean.     

Improved inverse PCR scheme for metagenome walking

Inverse PCR has been used for the recovery of genome regions flanking a known sequence, although its application to metagenome walking is limited due to inefficient amplification from low copy number fragments. Here we present an improved inverse PCR scheme that enables walking of rare fragments in environmental metagenomes. Our scheme includes the following steps: (i) inverse PCR in which one primer is connected to an affinity tag; (ii) affinity purification of PCR products for removing background metagenome; and (iii) nested PCR to recover target flanking regions (IAN-PCR). In a model experiment, flanking regions of a gene fragment in Ralstonia eutropha were recovered from mixtures of Ralstonia and Escherichia genomes by standard inverse PCR, inverse PCR coupled to nested PCR (IN-PCR), and IAN-PCR, showing that they were recovered when ratios of Ralstonia genome to the background Escherichia genome were greater than 10(-1), 10(-3), and 10(-5), respectively. The utility of IAN-PCR was also examined by recovering flanking regions of PCR-amplified putative chitinase gene fragments from a groundwater metagenome, showing that IAN-PCR obtained flanking regions for more diverse gene fragments than IN-PCR. Since rare sequences are a critical element of natural genetic diversity, IAN-PCR enables access to undiscovered diverse genes in the environment.     

植物基因富集研究进展

高等植物的基因组大小差异十分巨大, 在大基因组植物的基因组中, 各种重复序列占据了基因组中相当大一部分, 而低拷贝或单拷贝的基因序列仅占了很少一部分。对于大基因组物种而言, 大量的重复序列给基因组的研究工作带来很大困难, 使得大规模获得基因信息成为一项很有挑战性的工作。目前, 在基因组范围内富集基因的方法有cDNA文库、甲基化过滤文库、高Cot值文库、转座子标签富集法等。文章综述了这几种方法的技术原理和特性, 结合近年来国内外运用甲基化过滤技术的研究进展, 探讨了根据不同研究材料和研究目标, 如何高效选择适合的方法或者方法的组合。     

The maize genome as a model for efficient sequence analysis of large plant genomes

The genomes of flowering plants vary in size from about 0.1 to over 100 gigabase pairs (Gbp), mostly because of polyploidy and variation in the abundance of repetitive elements in intergenic regions. High-quality sequences of the relatively small genomes of Arabidopsis (0.14 Gbp) and rice (0.4 Gbp) have now been largely completed. The sequencing of plant genomes that have a more representative size (the mean for flowering plant genomes is 5.6 Gbp) has been seen as a daunting task, partly because of their size and partly because of the numerous highly conserved repeats. Nevertheless, creative strategies and powerful new tools have been generated recently in the plant genetics community, so that sequencing large plant genomes is now a realistic possibility. Maize (2.4-2.7 Gbp) will be the first gigabase-size plant genome to be sequenced using these novel approaches. Pilot studies on maize indicate that the new gene-enrichment, gene-finishing and gene-orientation technologies are efficient, robust and comprehensive. These strategies will succeed in sequencing the gene-space of large genome plants, and in locating all of these genes and adjacent sequences on the genetic and physical maps.     

What transposable elements tell us about genome organization and evolution: the case of Drosophila

Transposable elements (TEs) have been identified in every organism in which they have been looked for. The sequencing of large genomes, such as the human genome and those of Drosophila, Arabidopsis, Caenorhabditis, has also shown that they are a major constituent of these genomes, accounting for 15% of the genome of Drosophila, 45% of the human genome, and more than 70% in some plants and amphibians. Compared with the 1% of genomic DNA dedicated to protein-coding sequences in the human genome, this has prompted various researchers to suggest that the TEs and the other repetitive sequences that constitute the so-called "noncoding DNA", are where the most stimulating discoveries will be made in the future (Bromham, 2002). We are therefore getting further and further from the original idea that this DNA was simply "junk DNA", that owed its presence in the genome entirely to its capacity for selfish transposition. Our understanding of the structures of TEs, their distribution along the genomes, their sequence and insertion polymorphisms within genomes, and within and between populations and species, their impact on genes and on the regulatory mechanisms of genetic expression, their effects on exon shuffling and other phenomena that reshape the genome, and their impact on genome size has increased dramatically in recent years. This leads to a more general picture of the impact of TEs on genomes, though many copies are still mainly selfish or junk DNA. In this review we focus mainly on discoveries made in Drosophila, but we also use information about other genomes when this helps to elucidate the general processes involved in the organization, plasticity, and evolution of genomes.     

GONOME: measuring correlations between GO terms and genomic positions

Background

The design of oligonucleotides and PCR primers for studying large genomes is complicated by the redundancy of sequences. The eukaryotic genomes are particularly difficult to study due to abundant repeats. The speed of most existing primer evaluation programs is not sufficient for large-scale experiments.

Results

In order to improve the efficiency and success rate of automatic primer/oligo design, we created a novel method which allows rapid masking of repeats in large sequence files, for example in eukaryotic genomes. It also allows the detection of all alternative binding sites of PCR primers and the prediction of PCR products. The new method was implemented in a collection of efficient programs, the GENOMEMASKER package. The performance of the programs was compared to other similar programs. We also modified the PRIMER3 program, to be able to design primers from lowercase-masked sequences.

Conclusion

The GENOMEMASKER package is able to mask the entire human genome for non-unique primers within 6 hours and find locations of all binding sites for 10 000 designed primer pairs within 10 minutes. Additionally, it predicts all alternative PCR products from large genomes for given primer pairs.     

A-T linker adapter polymerase chain reaction for determining flanking sequences by rescuing inverse PCR or thermal asymmetric interlaced PCR products

The polymerase chain reaction (PCR)-based genome walking method has been extensively used to isolate unknown flanking sequences, whereas nonspecific products are always inevitable. To resolve these problems, we developed a new strategy to isolate the unknown flanking sequences by combining A-T linker adapter PCR with inverse PCR (I–PCR) or thermal asymmetric interlaced PCR (TAIL–PCR). The result showed that this method can be efficiently achieved with the flanking sequence from the Arabidopsis mutant and papain gene. Our study provides researchers with an additional method for determining genomic DNA flanking sequences to identify the target band from bulk of bands and to eliminate the cloning step for sequencing.     

Efficient amplification of genes involved in microbial secondary metabolism by an improved genome walking method

Genome walking is a commonly used technique for the identification of DNA sequences adjacent to known regions. Despite the development of various genome walking methods, nonspecific products are often produced in certain circumstances, especially when GC-rich DNA sequences are dealt with. To effectively resolve such technical issues, a simple nested polymerase chain reaction-based genome walking method has been developed by implementing a progressively decreased annealing temperature from 70°C to 47.5°C in the first round of amplification and a high annealing temperature of 65°C in the second round of amplification. During the entire process, a lower ramp rate of 1.5°C s⁻¹ and cooling rate of 2.5°C s⁻¹ are performed to reach the annealing temperature. Using this method, we successfully obtained the upstream and downstream sequences of three GC-rich genes involved in the biosynthetic pathways of secondary metabolites from two bacterial genomes. The efficient amplification of DNA target longer than 1.5 Kb with GC content up to 75.0% indicates that the present technique could be a valuable tool for the investigation of biosynthetic pathways of various secondary metabolites.     

Shotgun haplotyping: a novel method for surveying allelic sequence variation

Haplotypic sequences contain significantly more information than genotypes of genetic markers and are critical for studying disease association and genome evolution. Current methods for obtaining haplotypic sequences require the physical separation of alleles before sequencing, are time consuming and are not scaleable for large surveys of genetic variation. We have developed a novel method for acquiring haplotypic sequences from long PCR products using simple, high-throughput techniques. This method applies modified shotgun sequencing protocols to sequence both alleles concurrently, with read-pair information allowing the two alleles to be separated during sequence assembly. Although the haplotypic sequences can be assembled manually from the resultant data using pre-existing sequence assembly software, we have devised a novel heuristic algorithm to automate assembly and remove human error. We validated the approach on two long PCR products amplified from the human genome and confirmed the accuracy of our sequences against full-length clones of the same alleles. This method presents a simple high-throughput means to obtain full haplotypic sequences potentially up to 20 kb in length and is suitable for surveying genetic variation even in poorly-characterized genomes as it requires no prior information on sequence variation.     

Pulsed-field gel mapping of maize mitochondrial chromosomes

Pulsed-field gel electrophoresis (PFGE) in combination with infrequently cutting restriction enzymes was used to investigate the structure of the mitochondrial (mt) genome of the maize variety Black Mexican Sweet (BMS). The mt genome of this variety was found to resemble that of the closely related B37N variety, with one recombination and five insertion/deletion events being sufficient to account for the differences observed between the two genomes. The majority of the BMS genome is organized as a number of subgenomic chromosomes with circular restriction maps. Several large repeated sequences are found in the BMS mt genome, but not all appear to be in recombinational equilibrium. No molecules large enough to contain the entire mt genome were discernible using these techniques. The mapping approach described here provides a means of quickly analyzing the large and complex rut genomes of plants.     

Fugu genome does not contain mitochondrial pseudogenes

Contrary to previous observations that fish genomes are devoid of nuclear mitochondrial pseudogenes, a genome-wide survey identified a large number of "recent" and "ancient" nuclear mitochondrial DNA fragments (Numts) in the whole-genome sequences of the fugu (Takifugu rubripes), Tetraodon nigroviridis, and zebrafish (Danio rerio). We have analyzed the latest assembly (v4.0) of the fugu genome and show that, like the Anopheles genome, the fugu nuclear genome does not contain mitochondrial pseudogenes. Fugu assembly v4.0 contains a single scaffold representing the near complete sequence of the fugu mitochondria. The "recent" Numts identified by the previous study in fugu assembly v2.0 are in fact shotgun sequences of mitochondrial DNA that were misassembled with the nuclear sequences, whereas the "ancient" Numts appear to be the result of spurious matches. It is likely that the Numts identified in the genomes of Tetraodon and zebrafish are also similar artifacts. Shotgun sequences of whole genomes often include some mitochondrial sequences. Therefore, any Numts identified in shotgun-sequence assemblies should be verified by Southern hybridization or PCR amplification.     

Identification of DNA sequences flanking T-DNA insertions by PCR-walking

In recent years, concerns over genetic modification issues have resulted in regulatory authorities requiring comprehensive analysis of transgene insertion events in the plants that are to be commercialized. Determining that plants are devoid of vector backbone sequences is a trivial task that is best achieved by Southern blot analysis; however, identifying the DNA sequences flanking the T-DNA insertions can be arduous. In this paper, we present a robust method of characterizing this insertion event. We have applied and modified a genomic walking method that combines vectorette and suppression PCR walking.