Universal Fast Walking for direct and versatile determination of flanking sequence

Primer extension refractory PCR: an efficient and reliable genome walking method

Genome walking, a molecular technique for obtaining unknown flanking genomic sequences from a known genomic sequence, has been broadly applied to determine transgenic sites, mine new genetic resources, and fill in chromosomal gaps. This technique has advanced genomics, genetics, and related disciplines. Here, an efficient and reliable genome walking technique, called primer extension refractory PCR (PER-PCR), is presented. PER-PCR uses a set of primary, secondary, and tertiary walking primers. The middle 15 nt of the primary walking primer overlaps with the 3' parts of the secondary and tertiary primers. The 5' parts of the three primers are heterologous to each other. The short overlap allows the walking primer to anneal to its predecessor only in a relaxed-stringency PCR cycle, resulting in a series of single-stranded DNAs; however, the heterologous 5' part prevents the creation of a perfect binding site for the walking primer. In the next stringent cycle, the target single strand can be extended into a double-stranded DNA molecule by the sequence-specific primer and thus can be exponentially amplified by the remaining stringent cycles. The nontarget single strand fails to be enriched due to the lack of a perfect binding site for any primer. PER-PCR was validated by extension into unknown flanking regions of the hyg gene in rice and the gadR gene in Levilactobacillus brevis CD0817. In summary, in this study, a new practical PER-PCR method was constructed as a potential alternative to existing genome walking methods.

Protocol to access unknown flanking DNA sequences using Wristwatch-PCR for genome-walking

Here we describe a protocol for wristwatch PCR, an approach based on wristwatch-like structure formed between walking primers to obtain unknown flanks. We specify the criteria for designing wristwatch primers and gene-specific primers. We detail how to set wristwatch primer permutations to obtain personalized walking outcomes and improve walking efficiency. We describe experimental procedures for isolating a DNA of interest using three rounds of nested wristwatch PCR as well as the subsequent steps for DNA purification, cloning, and sequencing. For complete details on the use and execution of this protocol, please refer to Wang et al. (2022).1.

Semi-Site-Specific Primer PCR: A Simple but Reliable Genome-Walking Tool

Genome-walking has been frequently applied to molecular biology and related areas. Herein, a simple but reliable genome-walking technique, termed semi-site-specific primer PCR (3SP-PCR), is presented. The key to 3SP-PCR is the use of a semi-site-specific primer in secondary PCR that partially overlaps its corresponding primary site-specific primer. A 3SP-PCR set comprises two rounds of nested amplification reactions. In each round of reaction, any primer is allowed to partially anneal to the DNA template once only in the single relaxed-stringency cycle, creating a pool of single-stranded DNAs. The target single-stranded DNA can be converted into a double-stranded molecule directed by the site-specific primer, and thus can be exponentially amplified by the subsequent high-stringency cycles. The non-target one cannot be converted into a double-strand due to the lack of a perfect binding site to any primer, and thus fails to be amplified. We validated the 3SP-PCR method by using it to probe the unknown DNA regions of rice hygromycin genes and Levilactobacillus brevis CD0817 glutamic acid decarboxylase genes.

Fusion primer driven racket PCR: A novel tool for genome walking

The limitations of the current genome-walking strategies include strong background and cumbersome experimental processes. Herein, we report a genome-walking method, fusion primer-driven racket PCR (FPR-PCR), for the reliable retrieval of unknown flanking DNA sequences. Four sequence-specific primers (SSP1, SSP2, SSP3, and SSP4) were sequentially selected from known DNA (5'→3′) to perform FPR-PCR. SSP3 is the fragment that mediates intra-strand annealing (FISA). The FISA fragment is attached to the 5′ end of SSP1, generating a fusion primer. FPR-PCR comprises two rounds of amplification reactions. The single-fusion primary FPR-PCR begins with the selective synthesis of the target first strand, then allows the primer to partially anneal to some place(s) on the unknown region of this strand, producing the target second strand. Afterward, a new first strand is synthesized using the second strand as the template. The 3′ end of this new first strand undergoes intra-strand annealing to the FISA site, followed by the formation of a racket-like DNA by a loop-back extension. This racket-like DNA is exponentially amplified in the secondary FPR-PCR performed using SSP2 and SSP4. We validated this FPR-PCR method by identifying the unknown flanks of Lactobacillus brevis CD0817 glutamic acid decarboxylase genes and the rice hygromycin gene.

Promoter P PSP1-5-BnPSP-1 From Ramie (Boehmeria nivea L. Gaud.) Can Drive Phloem-Specific GUS Expression in Arabidopsis thaliana

Isolation of phloem-specific promoters is one of the basic conditions for improving the fiber development and resistance of ramie phloem using genetic engineering. In this study, we isolated a ramie endogenous promoter (named P_PSP1-BnPSP-1) and analyzed the function of its truncated fragments in Arabidopsis. The results show that P_PSP1-BnPSP-1 can drive the GUS reporter gene to be specifically expressed in the veins of Arabidopsis. After hormone and simulated drought treatment of the independent Arabidopsis lines carrying P_PSP1-BnPSP-1 and its truncated fragments, only P_PSP1–5-BnPSP-1 (−600 to −1 bp region of P_PSP1-BnPSP-1) is stably expressed and exhibits phloem specificity. Our findings suggest that P_PSP1–5-BnPSP-1 can be used as a phloem specific promoter for further research.

Isolation and functional characterization of SUCROSE SYNTHASE 1 and SUCROSE TRANSPORTER 2 promoters from ramie (Boehmeria nivea L. Gaudich)

Sucrose synthase and sucrose transporter are involved in sucrose metabolism and partitioning of photosynthetic products, respectively. In this study, we cloned SUCROSE SYNTHASE 1 and SUCROSE TRANSPORTER 2 genes from ramie. Real-time quantitative PCR revealed that BnSUS1 and BnSUT2 were widely expressed in the analyzed tissues. Subsequently, the two promoters of BnSUS1 and BnSUT2 were isolated and truncated. The two promoters and their truncated fragments were fused GUS to transform into Arabidopsis. GUS staining showed that BnSUS1_pro-1690 and BnSUS1_pro-1420 had vascular specificity in cotyledons and mature leaves while BnSUT2_pro-2239, BnSUT2_pro-1681, BnSUT2_pro-1199 and BnSUT2_pro-618 had a constitutive function in seedlings and mature organs. Notably, the activity of BnSUT2_pro-2239 and its fragments (except that of BnSUT2_pro-231) are strongly induced by mechanical wounding. Moreover, BnSUS1_pro-1051 and BnSUS1_pro-485 are sensitive to CuSO₄ treatment while BnSUT2_pro-2239 and BnSUT2_pro-1681 are sensitive to PEG and ABA treatments, respectively. Our findings will provide the foundation for deciphering the functions of BnSUS1 and BnSUT2, and also expand the promoter library to provide more options for plant genetic engineering.

Identification and expression characterization of the Phloem Protein 2 (PP2) genes in ramie (Boehmeria nivea L. Gaudich)

Phloem protein 2 (PP2) is one of the most abundant and enigmatic proteins in sieve elements and companion cells, which play important roles in the maintenance of morphology, photoassimilate transportation and wound protection in higher plants, but to date, no PP2 (BnPP2) genes had been identified in ramie. Here, a total of 15 full-length BnPP2 genes were identified. These BnPP2 genes exhibited different responses to abiotic stresses. Interestingly, the BnPP2 genes are more sensitive to insect pests than to other stresses. A study of the BnPP2-15 promoter revealed that pBnPP2-15 could drive specific GUS expression in the petiole, root and stamen and could also be induced by mechanical wounding and aphid infection in transgenic Arabidopsis lines. The subcellular localization of six BnPP2 proteins showed that GFP-BnPP2-1, GFP-BnPP2-6, GFP-BnPP2-7, GFP-BnPP2-9, GFP-BnPP2-11 and GFP-BnPP2-12 were predominantly located in the cytoplasm. These results provide useful information elucidating the functions of BnPP2 genes in ramie.

Current and new approaches in GMO detection: challenges and solutions

In many countries, genetically modified organisms (GMO) legislations have been established in order to guarantee the traceability of food/feed products on the market and to protect the consumer freedom of choice. Therefore, several GMO detection strategies, mainly based on DNA, have been developed to implement these legislations. Due to its numerous advantages, the quantitative PCR (qPCR) is the method of choice for the enforcement laboratories in GMO routine analysis. However, given the increasing number and diversity of GMO developed and put on the market around the world, some technical hurdles could be encountered with the qPCR technology, mainly owing to its inherent properties. To address these challenges, alternative GMO detection methods have been developed, allowing faster detections of single GM target (e.g., loop-mediated isothermal amplification), simultaneous detections of multiple GM targets (e.g., PCR capillary gel electrophoresis, microarray, and Luminex), more accurate quantification of GM targets (e.g., digital PCR), or characterization of partially known (e.g., DNA walking and Next Generation Sequencing (NGS)) or unknown (e.g., NGS) GMO. The benefits and drawbacks of these methods are discussed in this review.

Cloning of expansin genes in ramie (Boehmeria nivea L.) based on universal fast walking

Gene cloning is the first step to study the expression profiles and functions of a particular gene; considerable cloning methods have been developed. Expansin, thought to involve in the cell-wall modification events, was not cloned in ramie (Boehmeria nivea L.), which is one of the most important bast fiber crops with little conducted molecular research, especially on its fiber development. Studying the expansin gene family will uncover its possible relationship with ramie fiber development and other growth events. As a result, five expansin genes were cloned with full-length and their sequence information was investigated. Additionally, the phylogenetic analysis was conducted, which suggested that the cloned genes belong to the α-subfamily, and these genes expressed differently during ramie fiber developmental process. In this study, we aimed to apply a strategy for cloning novel full-length genes from genomic DNA of ramie, based on using degenerate primers, touchdown polymerase chain reaction and universal fast walking protocols. By cloning five full-length expansin genes, we believe the polymerase chain reaction-based gene cloning strategy could be applied to general gene studies in ramie and other crops.

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.

Lariat-dependent nested PCR for flanking sequence determination

Methods detailed in this chapter relate to the use of Lariat-dependent Nested (LaNe) PCR to characterize unknown RNA or DNA sequence flanking known regions. A multitude of approaches designed to determine flanking sequences have been described in the literature. Variously, problems related to these approaches include lack of resolution or failure, depending on experimental context, and complex handling. LaNe-based methods are designed to harness "two-sided" gene-specific PCR with the option of nesting but without the requirement for inefficient and involved enzyme preprocessing steps.

Molecular cloning and characterization of the porcine FTO promoter and coding regions

The fat mass and obesity associated gene (FTO) has been widely reported to be associated with fat mass or fat deposition in different species. In the present study, we cloned both promoter and coding regions of the gene in pigs with over 5 Kb of sequence for the former region and 1,596 bp for the latter region. Comparative analysis of the promoter region among 20 species including pig revealed four conserved regions that harbor transcriptional factors involved in adipose differentiation. Using a pooled DNA sequencing approach, we discovered 39 single nucleotide polymorphisms (SNPs) in the pig FTO gene and four of them were genotyped on 716 pigs representing 3 European and 18 Chinese indigenous pig breeds plus samples of wild boars. We found that TCGG is a favored haplotype in Chinese wild boars and 16 indigenous pig breeds, while Li Cha Black and Tong Cheng pigs had the specific dominant haplotypes of TTGG and TCGA, respectively. ATGA was the main haplotype found in Large White and Duroc pigs, but the haplotype of ATGG was the major type in Landrace. Taken together, these data provide a valuable foundation for the community to fully study the function of FTO gene in pigs.

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 degrees C to 47.5 degrees C in the first round of amplification and a high annealing temperature of 65 degrees C in the second round of amplification. During the entire process, a lower ramp rate of 1.5 degrees C s(-1) and cooling rate of 2.5 degrees 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.

Novel genes retrieved from environmental DNA by polymerase chain reaction: current genome-walking techniques for future metagenome applications

Environmental DNA is an extremely rich source of genes encoding enzymes with novel biocatalytic activities. To tap this source, function-based and sequence-based strategies have been established to isolate, clone, and express these novel metagenome-derived genes. Sequence-based strategies, which rely on PCR with consensus primers and genome walking, represent an efficient and inexpensive alternative to activity-based screening of recombinant strains harbouring fragments of environmental DNA. This review covers the diverse array of genome-walking techniques, which were originally developed for genomic DNA and currently are also used for PCR-based recovery of entire genes from the metagenome. These sequence-based gene mining methods appear to offer a powerful tool for retrieving from the metagenome novel genes encoding biocatalysts with potential applications in biotechnology.

Large-scale functional annotation and expanded implementations of the P{wHy} hybrid transposon in the Drosophila melanogaster genome

Whole genome sequencing of the model organisms has created increased demand for efficient tools to facilitate the genome annotation efforts. Accordingly, we report the further implementations and analyses stemming from our publicly available P{wHy} library for Drosophila melanogaster. A two-step regime-large scale transposon mutagenesis followed by hobo-induced nested deletions-allows mutation saturation and provides significant enhancements to existing genomic coverage. We previously showed that, for a given starting insert, deletion saturation is readily obtained over a 60-kb interval; here, we perform a breakdown analysis of efficiency to identify rate-limiting steps in the process. Transrecombination, the hobo-induced recombination between two P{wHy} half molecules, was shown to further expand the P{wHy} mutational range, pointing to a potent, iterative process of transrecombination-reconstitution-transrecombination for alternating between very large and very fine-grained deletions in a self-contained manner. A number of strains also showed partial or complete repression of P{wHy} markers, depending on chromosome location, whereby asymmetric marker silencing allowed continuous phenotypic detection, indicating that P{wHy}-based saturational mutagenesis should be useful for the study of heterochromatin/positional effects.

Ectopic recombination of a malaria var gene during mitosis associated with an altered var switch rate

The Plasmodium falciparum var multigene family encodes P. falciparum erythrocyte membrane protein 1, which is responsible for the pathogenic traits of antigenic variation and adhesion of infected erythrocytes to host receptors during malaria infection. Clonal antigenic variation of P. falciparum erythrocyte membrane protein 1 is controlled by the switching between exclusively transcribed var genes. The tremendous diversity of the var gene repertoire both within and between parasite strains is critical for the parasite's strategy of immune evasion. We show that ectopic recombination between var genes occurs during mitosis, providing P. falciparum with opportunities to diversify its var repertoire, even during the course of a single infection. We show that the regulation of the recombined var gene has been disrupted, resulting in its persistent activation although the regulation of most other var genes is unaffected. The var promoter and intron of the recombined var gene are not responsible for its atypically persistent activity, and we conclude that altered subtelomeric cis sequence is the most likely cause of the persistent activity of the recombined var gene.

Discovery of a novel carboxylesterase through functional screening of a pre-enriched environmental library

AIMS

The aim of this study was to demonstrate the application of environmental sample pre-enrichment to access novel carboxylesterases from environmental genomes, along with subsequent heterologous expression and characterization of the discovered enzyme(s).

METHODS AND RESULTS

A positive recombinant clone (UVCL29), conferring an esterase phenotype was identified from a shotgun gene library. The complete sequence of the 3.0 kb DNA insert from the pUVCL29 recombinant plasmid was obtained using primer-walking strategies. Nucleotide sequence analysis revealed a complete 945 bp open reading frame (ORF1). Translational analysis of the ORF1 showed a protein of 314 amino acids (named EstAM) with a predicted molecular weight of 34 kDa. EstAM's primary structure showed a classical (-G-D-S-A-G-) motif, corresponding with the generally conserved (G-x-S-x-G) esterase signature motif. Identity searches indicated that EstAM has high sequence similarity with esterases from family IV. EstAM was successfully expressed in Escherichia coli in a biologically active form. Partial purification was achieved using a one-step Pro-PurTM IMAC column. Biochemical characterization revealed that EstAM has a temperature optimum of 40 degrees C.

CONCLUSION

Based on its substrate profile, EstAM was classified as a carboxylesterase because of its preference for short p-nitrophenyl ester substrates.

SIGNIFICANCE AND IMPACT OF THE STUDY

This study is a demonstration of the successful application of environmental sample pre-enrichment technology in accessing novel esterases from a mining environment.

Metagenomics in animal gastrointestinal ecosystem: a microbiological and biotechnological perspective

Metagenomics- the application of the genomics technologies to nonculturable microbial communities, is coming of age. These approaches can be used for the screening and selection of nonculturable rumen microbiota for assessing their role in gastrointestinal (GI) nutrition, plant material fermentation and the health of the host. The technologies designed to access this wealth of genetic information through environmental nucleic acid extraction have provided a means of overcoming the limitations of culture-dependent microbial genetic exploitation. The molecular procedures and techniques will result in reliable insights into the GI microbial structure and activity of the livestock gut microbes in relation to functional interactions, temporal and spatial relationships among different microbial consortia and dietary ingredients. Future developments and applications of these methods promise to provide the first opportunity to link distribution and identity of rumen microbes in their natural habitats with their genetic potential and in situ activities.

The pathway to detangle a scrambled gene

Background

Programmed DNA elimination and reorganization frequently occur during cellular differentiation. Development of the somatic macronucleus in some ciliates presents an extreme case, involving excision of internal eliminated sequences (IESs) that interrupt coding DNA segments (macronuclear destined sequences, MDSs), as well as removal of transposon-like elements and extensive genome fragmentation, leading to 98% genome reduction in Stylonychia lemnae. Approximately 20–30% of the genes are estimated to be scrambled in the germline micronucleus, with coding segment order permuted and present in either orientation on micronuclear chromosomes. Massive genome rearrangements are therefore critical for development.

Methodology/Principal Findings

To understand the process of DNA deletion and reorganization during macronuclear development, we examined the population of DNA molecules during assembly of different scrambled genes in two related organisms in a developmental time-course by PCR. The data suggest that removal of conventional IESs usually occurs first, accompanied by a surprising level of error at this step. The complex events of inversion and translocation seem to occur after repair and excision of all conventional IESs and via multiple pathways.

Conclusions/Significance

This study reveals a temporal order of DNA rearrangements during the processing of a scrambled gene, with simpler events usually preceding more complex ones. The surprising observation of a hidden layer of errors, absent from the mature macronucleus but present during development, also underscores the need for repair or screening of incorrectly-assembled DNA molecules.

Metagenomics in animal gastrointestinal ecosystem: Potential biotechnological prospects

Microbial metagenomics---the applications of the genomics suit of technologies to nonculturable microorganisms, is coming of age. These approaches can be used for the screening and identification of nonculturable gastrointestinal (GI) microflora for assessing and exploiting them in nutrition and the health of the host. Advances in technologies designed to access this wealth of genetic information through environmental nucleic acids extraction and analysis have provided the means of overcoming the limitations of conventional culture-dependent microbial genetic exploitation. The molecular techniques and bioinformatics tools will result in reliable insights into the animals' GI microbial structure and activity of the livestock gut microbes in relation to functional interactions, temporal and spatial relationships among different microbial consortia and dietary ingredients. Further developments and applications of these methods promise to provide the opportunity to link distribution and identity of various GI microbes in their natural habitats, and explore their use for promoting livestock health and industrial development.

P-element mutagenesis

Mobile elements were first used as a mutagenesis tool that introduces a molecular tag in the genes of interest. This facilitated subsequent molecular cloning and eventually promoted molecular analysis of a large number of fly genes. Soon after, P-elements were modified to detect genes not only based on a mutant phenotype but rather through revealing RNA or protein expression patterns (enhancer trap, gene trap). Owing to the typically imprecise mobilization of the P-elements these enhancer trap or gene trap insertions also provided means to generate (excision) mutants. Whereas the excision mutants are valuable deletions they are induced in a random fashion and the exact breakpoints have to be determined following molecular analysis. More recently, the introduction of recombination targets (flipase recombination targets) into P-elements has provided the ability to generate precise chromosomal deletions between preselected sites. Here we will summarize the current genetic approaches to generate different type of insertional and deletion mutations using specifically designed P-elements.

A modified universal fast walking method for single-tube transposon mapping

An enhanced universal fast walking (UFW) method adapted for the mapping of transposons is described. This protocol combines the original UFW method with the use of agarase to unravel composite nucleotide sequence, thereby forgoing molecular cloning steps and the use of restriction enzymes and ligases necessary in other available genome walking methods such as the prominent inverse PCR. The minuscule automatable chemistry of UFW is completed within one reaction vessel using a constant enzyme buffer, and the intrinsic DNA fingerprints, from which amplicons may be quantitatively recovered, offer quality assurance. The core steps of the protocol, spanning half a day or less, comprise first-strand synthesis, primer destruction, random-ended-primer annealing, distal branched-end repair, second-primer destruction, lariat formation and final amplification. Distinctively, no starting or intermediate templates are wasted during the reaction series, thus achieving yields comparable to direct PCR. Ultimate per-reaction walk-lengths are schematically illimitable and sequence-ready amplicons can be produced immediately from prevalent single-copy genomic walk origins. The core UFW protocol may be applied, as described here, to expedited transposon boundary retrieval, but is also applicable to general genome walking and cDNA walking, as well as viral and other insertional element mapping.

Recombinational micro-evolution of functionally different metallothionein promoter alleles from Orchesella cincta

Background

Metallothionein (mt) transcription is elevated in heavy metal tolerant field populations of Orchesella cincta (Collembola). This suggests that natural selection acts on transcriptional regulation of mt in springtails at sites where cadmium (Cd) levels in soil reach toxic values This study investigates the nature and the evolutionary origin of polymorphisms in the metallothionein promoter (pmt) and their functional significance for mt expression.

Results

We sequenced approximately 1600 bp upstream the mt coding region by genome walking. Nine pmt alleles were discovered in NW-European populations. They differ in the number of some indels, consensus transcription factor binding sites and core promoter elements. Extensive recombination events between some of the alleles can be inferred from the alignment. A deviation from neutral expectations was detected in a cadmium tolerant population, pointing towards balancing selection on some promoter stretches. Luciferase constructs were made from the most abundant alleles, and responses to Cd, paraquat (oxidative stress inducer) and moulting hormone were studied in cell lines. By using paraquat we were able to dissect the effect of oxidative stress from the Cd specific effect, and extensive differences in mt induction levels between these two stressors were observed.

Conclusion

The pmt alleles evolved by a number of recombination events, and exhibited differential inducibilities by Cd, paraquat and molting hormone. In a tolerant population from a metal contaminated site, promoter allele frequencies differed significantly from a reference site and nucleotide polymorphisms in some promoter stretches deviated from neutral expectations, revealing a signature of balancing selection. Our results suggest that the structural differences in the Orchesella cincta metallothionein promoter alleles contribute to the metallothionein -over-expresser phenotype in cadmium tolerant populations.

Heat-shock promoters: targets for evolution by P transposable elements in Drosophila

Transposable elements are potent agents of genomic change during evolution, but require access to chromatin for insertion—and not all genes provide equivalent access. To test whether the regulatory features of heat-shock genes render their proximal promoters especially susceptible to the insertion of transposable elements in nature, we conducted an unbiased screen of the proximal promoters of 18 heat-shock genes in 48 natural populations of Drosophila. More than 200 distinctive transposable elements had inserted into these promoters; greater than 96% are P elements. By contrast, few or no P element insertions segregate in natural populations in a “negative control” set of proximal promoters lacking the distinctive regulatory features of heat-shock genes. P element transpositions into these same genes during laboratory mutagenesis recapitulate these findings. The natural P element insertions cluster in specific sites in the promoters, with up to eight populations exhibiting P element insertions at the same position; laboratory insertions are into similar sites. By contrast, a “positive control” set of promoters resembling heat-shock promoters in regulatory features harbors few P element insertions in nature, but many insertions after experimental transposition in the laboratory. We conclude that the distinctive regulatory features that typify heat-shock genes (in Drosophila) are especially prone to mutagenesis via P elements in nature. Thus in nature, P elements create significant and distinctive variation in heat-shock genes, upon which evolutionary processes may act.

Transposable elements can be a major source of evolutionary change. Their insertion can directly affect the genes into, or next to, which they insert. To insert, however, they must first gain access to the host gene. The authors reasoned that, because the DNA in the promoters (i.e., regulatory regions) of heat-shock genes is unusually accessible, these genes might harbor many transposable elements. With a technique that can detect any insertion into a gene, they discovered more than 200 distinctive transposable elements in the promoter regions of heat-shock genes in fruit flies from the wild—but few or none in the promoter regions of more typical genes. Surprisingly, out of the one hundred kinds of transposable elements in fruit flies, almost all were P elements. P elements are remarkable because they invaded the fruit fly genome only during the last century. These findings imply that the combination of accessible DNA and the recent invasion of P elements have left a distinctive imprint on the promoters of heat-shock genes.

A specific and versatile genome walking technique

We describe here a nested PCR-based strategy for genome walking to extend a known sequence region to its uncharacterized flanking regions. This technique involves the use of a partially degenerate primer as a walker primer and a set of nested specific primers to perform two to three successive rounds of nested PCR. To increase the success rate of genome walking, four different walker primers were designed to allow the setup of parallel reactions. This technique was applied to amplify flanking sequences of known genomic loci of two highly divergent photosynthetic organisms, Rhodobacter capsulatus and Heliophilum fasciatum. Specific products were preferentially amplified using this strategy, which were verified using DNA sequencing. The extremely high success rate of extension of genomic regions in these two organisms suggests that this technique can be applied to a wide range of genomes.

Conserved linkage of two genes on the same macronuclear chromosome in spirotrichous ciliates

Macronuclear chromosomes of spirotrichous ciliates are mainly "nanochromosomes" containing only a single gene. We identified a two-gene chromosome in the spirotrich Sterkiella histriomuscorum (formerly Oxytricha trifallax) which, unlike other characterized two-gene molecules, contains reading frames oriented tail to tail. These are homologs of ribosomal protein L29 (RPL29) and cyclophilin. We found that both genes are transcribed, with their polyadenylation sites on opposite strands separated by only 135 bp. Furthermore, both genes in S. histriomuscorum are present only on one macronuclear chromosome and do not occur alone or linked to other genes. The corresponding micronuclear locus is fragmented into three nonscrambled gene segments (MDSs), separated by two noncoding segments (IESs). We also found that these two genes are linked on a macronuclear chromosome, similarly arranged tail to tail, in the three spirotrichs Stylonychia lemnae, Uroleptus sp., and Holosticha sp.. In addition, single-gene macronuclear chromosomes containing only the RPL29 gene were detected in the earlier diverged Holosticha and Uroleptus. These observations suggest a possible evolutionary trend towards loss of chromosomal breakage between these two genes. This study is the first to examine gene linkage in the macronucleus of several spirotrichs and may provide insight into the evolution of multi-gene macronuclear chromosomes and chromosomal fragmentation in spirotrichs.

Two families of non-LTR retrotransposons, Syrinx and Daphne, from the Darwinulid ostracod, Darwinula stevensoni

Two novel families of non-LTR retrotransposons, named Syrinx and Daphne, were cloned and characterized in a putative ancient asexual ostracod Darwinula stevensoni. Phylogenetic analysis reveals that Daphne is the founding member of a novel clade of non-LTR retroelements, which also contains retrotransposon families from the sea urchin and the silkworm and forms a sister clade to L2-like elements. The Syrinx family of non-LTR retrotransposons exhibits evidence of relatively recent activity, manifested in high levels of sequence similarity between individual copies and a three- to ten-fold excess of synonymous substitutions, which is indicative of purifying selection. The Daphne family may have very few copies with intact open reading frames, and exhibits neutral within-family ratio of non-synonymous to synonymous substitutions. It can additionally be characterized by formation of inverted truncated head-to-head structures. All of these features make recent activity less likely than in the Syrinx family. Our results are discussed in light of the evolutionary consequences of long-term asexuality in general and in D. stevensoni in particular.

Gene trapping in embryonic stem cells

Gene trapping in embryonic stem cells (ESCs) generates random, sequence-tagged insertional mutations, which can often report the gene expression pattern of the mutated gene. This mutagenesis strategy has often been coupled to expression or function-based assays in gene discovery screens. The availability of the mouse genome sequence has shifted gene trapping from a gene discovery platform to a high-throughput mutagenesis platform. At present, a concerted worldwide effort is underway to develop a library of loss-of-function mutations in all mouse genes. The International Gene Trap Consortium (IGTC) is leading the way by making a first pass of the genome by random mutagenesis before a high-throughput gene targeting program takes over. In this chapter, we provide a methods guidebook to exploring and using the IGTC resource, explain the different kinds of vectors and insertions that reside in the different libraries, and provide advice and methods for investigators to design novel expression-based "cottage industry" screens.

A new scrambled gene in the ciliate Uroleptus

In the germline micronucleus of spirotrichous ciliates, the gene segments, or macronuclear destined sequences (MDSs), that give rise to the somatic macronucleus are interrupted by internal eliminated sequences (IESs). For some genes, the MDSs are not arranged sequentially, but rather are scrambled, in the micronucleus. Three scrambled genes have been extensively studied in many species: actin I, alpha-telomere binding protein, and DNA polymerase alpha. However, in the past decade, no new scrambled genes have been reported, and the prevalence of scrambled genes is still an important question. To screen for scrambled genes, we completely sequenced 11 macronuclear chromosomes in the spirotrich Uroleptus sp., and then pursued their micronuclear organization. This allowed us to identify new scrambled genes, which also display novel features. In this study we describe one of these newly discovered scrambled genes. This gene, tentatively named USG1 (Unknown Scrambled Gene 1), encodes a putative protein of 1016 aa. While the function of this protein product is not clear, dN/dS calculated from the two alleles suggests the encoded protein is under purifying selection. USG1 consists of 16 germline MDSs, of which 14 are located on one locus. The other locus, which is at least 3 kb away from the main locus, contains two scrambled MDSs separated by a nonscrambled IES. Curiously, one MDS and its outgoing (3') pointer (direct repeat) overlap intron splice sites, indicating that these DNA sequences may be under dual (or multiple) constraints. Our findings identify a new scrambled gene in the micronuclear genome of a spirotrichous ciliate, and suggest that even more complicated structures may be present.

Complex germline architecture: two genes intertwined on two loci

The germline micronuclear genome of some ciliated protists can be scrambled, with coding segments disordered relative to the expressed macronuclear genome. Here, we report a surprisingly complex pair of genes that assemble from interwoven segments on two germline loci in the ciliate Uroleptus. This baroque organization requires two scrambled genes to be disentangled from each other from two clusters in the genome, one containing segments 1-2-4-5-6-8-11-13-15-16 and the other 7-9-3-10-12-14, with pieces 1-5 comprising the first gene and 6-16 the second gene. Both genes remain linked in the somatic genome on a 1.5-kb "nanochromosome." This study is the first to reveal that two genes can become scrambled during evolution with their coding segments intertwined. These twin scrambled genes underscore the beauty and exceptions of protist genome architecture, pointing to the critical need for evolutionary biologists to survey protist genomes broadly.

Identification of genetically modified potato (Solanum tuberosum) cultivars using event specific polymerase chain reaction

Several genetically modified (GM) cultivars are registered in Canada although they are not currently in commercial production. The GM cultivars can be distinguished from the non-GM and other GM cultivars by analyzing the DNA nucleotide sequence at the insertion site of the transgene corresponding to a single transformation event in the plant genome. Techniques based on modified polymerase chain reaction (PCR) strategies were used to generate sequence information from the plant genome flanking the insertion site of transgenic DNA for specific GM potato events. The plant genome sequence adjacent to the transgenic insertion was used to design PCR primers, which could be used in combination with a primer annealing to one of the nearby inserted genetic elements to amplify an event specific DNA fragment. The event specific PCR fragments generated were sequenced to confirm the specificity of the method.

Metagenomic gene discovery: past, present and future

It is now widely accepted that the application of standard microbiological methods for the recovery of microorganisms from the environment has had limited success in providing access to the true extent of microbial biodiversity. It follows that much of the extant microbial genetic diversity (collectively termed the metagenome) remains unexploited, an issue of considerable relevance to a wider understanding of microbial communities and of considerable importance to the biotechnology industry. The recent development of technologies designed to access this wealth of genetic information through environmental nucleic acid extraction has provided a means of avoiding the limitations of culture-dependent genetic exploitation.

Diverse DNA transposons in rotifers of the class Bdelloidea

We surveyed the diversity, structural organization, and patterns of evolution of DNA transposons in rotifers of the class Bdelloidea, a group of basal triploblast animals that appears to have evolved for millions of years without sexual reproduction. Representatives of five superfamilies were identified: ITm (IS630/Tc/mariner), hAT, piggyBac, helitron, and foldback. Except for mariners, no fully intact copies were found. Mariners, both intact and decayed, are present in high copy number, and those described here may be grouped in several closely related lineages. Comparisons across lineages show strong evidence of purifying selection, whereas there is little or no evidence of such selection within lineages. This pattern could have resulted from repeated horizontal transfers from an exogenous source, followed by limited intragenomic proliferation, or, less plausibly, from within-host formation of new lineages under host- or element-based selection for function, in either case followed by eventual inactivation and decay. Unexpectedly, the flanking sequences surrounding the majority of mariners are very similar, indicating either insertion specificity or proliferation as part of larger DNA segments. Members of all superfamilies are present near chromosome ends, associated with the apparently domesticated retroelement Athena, in large clusters composed of diverse DNA transposons, often inserted into each other, whereas the examined gene-rich regions are nearly transposon-free.

Nitrate reduction byDesulfovibrio desulfuricans: A periplasmic nitrate reductase system that lacks NapB, but includes a unique tetrahemec-type cytochrome, NapM

Many sulphate reducing bacteria can also reduce nitrite, but relatively few isolates are known to reduce nitrate. Although nitrate reductase genes are absent from Desulfovibrio vulgaris strain Hildenborough, for which the complete genome sequence has been reported, a single subunit periplasmic nitrate reductase, NapA, was purified from Desulfovibrio desulfuricans strain 27774, and the structural gene was cloned and sequenced. Chromosome walking methods have now been used to determine the complete sequence of the nap gene cluster from this organism. The data confirm the absence of a napB homologue, but reveal a novel six-gene organisation, napC-napM-napA-napD-napG-napH. The NapC polypeptide is more similar to the NrfH subgroup of tetraheme cytochromes than to NapC from other bacteria. NapM is predicted to be a tetra-heme c-type cytochrome with similarity to the small tetraheme cytochromes from Shewanella oneidensis. The operon is located close to a gene encoding a lysyl-tRNA synthetase that is also found in D. vulgaris. We suggest that electrons might be transferred to NapA either from menaquinol via NapC, or from other electron donors such as formate or hydrogen via the small tetraheme cytochrome, NapM. We also suggest that, despite the absence of a twin-arginine targeting sequence, NapG might be located in the periplasm where it would provide an alternative direct electron donor to NapA.

Universal fast walking applied to cDNA

The elucidation of cDNA sequence remains problematic in cases such as genes possessing long coding regions, low expression levels, or poor library coverage. The recently described Universal Fast Walk (UFW) procedure offers a means of determining DNA sequence adjacent to characterised regions. To date, however, the approach has been applied only to genomic DNA. We demonstrate the first successful application of the UFW procedure to the elucidation of cDNA sequence, a previously unknown region of the large tammar wallaby ATRX gene in the theoretically more challenging 3' direction. To do this, we modified the previously published method by including an initial linear amplification and a final, fully nested PCR. We also exchanged buffers between preparative enzyme reactions to ensure optimal conditions for successive steps. These additional steps ensured a product not observed in their absence. UFW, therefore, represents a powerful alternative mechanism for the cloning and sequencing of cDNA, harnessing the exquisite sensitivity and specificity of fully nested PCR in challenging cloning scenarios where conventional 5' or 3' RACE may fail.

Restricted distribution of the butyrate kinase pathway among butyrate-producing bacteria from the human colon

The final steps in butyrate synthesis by anaerobic bacteria can occur via butyrate kinase and phosphotransbutyrylase or via butyryl-coenzyme A (CoA):acetate CoA-transferase. Degenerate PCR and enzymatic assays were used to assess the presence of butyrate kinase among 38 anaerobic butyrate-producing bacterial isolates from human feces that represent three different clostridial clusters (IV, XIVa, and XVI). Only four strains were found to possess detectable butyrate kinase activity. These were also the only strains to give PCR products (verifiable by sequencing) with degenerate primer pairs designed within the butyrate kinase gene or between the linked butyrate kinase/phosphotransbutyrylase genes. Further analysis of the butyrate kinase/phosphotransbutyrylase genes of one isolate, L2-50, revealed similar organization to that described previously from different groups of clostridia, along with differences in flanking sequences and phylogenetic relationships. Butyryl-CoA:acetate CoA-transferase activity was detected in all 38 strains examined, suggesting that it, rather than butyrate kinase, provides the dominant route for butyrate formation in the human colonic ecosystem that contains a constantly high concentration of acetate.

Using the P{wHy} Hybrid Transposable Element to Disrupt Genes in Region 54D-55B in Drosophila melanogaster

Understanding the function of each gene in the genome of a model organism such as Drosophila melanogaster is an important goal. The development of improved methods for uncovering the mutant phenotypes of specific genes can accelerate achievement of this goal. The P{wHy} hybrid transposable element can be used to generate nested sets of precisely mapped deletions in a given region of the Drosophila genome. Here we use the P{wHy} method to generate overlapping, molecularly defined deletions from a set of three P{wHy} insertions in the 54E-F region of chromosome 2. Deletions that span a total of 0.5 Mb were identified and molecularly mapped precisely. Using overlapping deletions, the mutant phenotypes of nine previously uncharacterized genes in a 101-kb region were determined, including identification of new loci required for viability and female fertility. In addition, the deletions were used to molecularly map previously isolated lethal mutations. Thus, the P{wHy} method provides an efficient method for systematically determining the phenotypes of genes in a given region of the fly genome.

A deletion-generator compound element allows deletion saturation analysis for genomewide phenotypic annotation

With the available eukaryotic genome sequences, there are predictions of thousands of previously uncharacterized genes without known function or available mutational variant. Thus, there is an urgent need for efficient genetic tools for genomewide phenotypic analysis. Here we describe such a tool: a deletion-generator technology that exploits properties of a double transposable element to produce molecularly defined deletions at high density and with high efficiency. This double element, called P[wHy], is composed of a "deleter" element hobo, bracketed by two genetic markers and inserted into a "carrier" P element. We have used this P[wHy] element in Drosophila melanogaster to generate sets of nested deletions of sufficient coverage to discriminate among every transcription unit within 60 kb of the starting insertion site. Because these two types of mobile elements, carrier and deleter, can be found in other species, our strategy should be applicable to phenotypic analysis in a variety of model organisms.