Construction and Characterization of Large-Insert Genomic Libraries (BAC and Fosmid) from the Ascidian <Emphasis Type="Italic">Botryllus schlosseri</Emphasis> and Initial Physical Mapping of a Histocompatibility Locus

The colonial protochordate Botryllus schlosseri is genetically manipulable and represents a potential model organism for a variety of biological disciplines, including immunology, stem cell biology and development. This article presents the construction and characterization of both BAC and fosmid genomic libraries of the 725-Mbp B. schlosseri genome. The BAC library currently consists of 2× genome coverage with an average insert size of 80 kb. The fosmid library is at 11× genome coverage with an average insert of 40 kb. B. schlosseri is a small organism containing a large number of compounds that hinder DNA purification. Thus a number of protocols had to be modified in order to make purified, high molecular weight inserts for cloning, including both gel purification and insert concentration techniques. Both libraries were characterized by using them in initial physical mapping of a single histocompatibility locus, and were found to be representative and functional. These libraries are important tools for physical mapping and positional cloning in the B. schlosseri genome, and the techniques adapted to make them are suitable for use on other organisms in which high molecular weight DNA is difficult to purify.     

Application of tetranucleotide frequencies for the assignment of genomic fragments

A basic problem of the metagenomic approach in microbial ecology is the assignment of genomic fragments to a certain species or taxonomic group, when suitable marker genes are absent. Currently, the (G + C)-content together with phylogenetic information and codon adaptation for functional genes is mostly used to assess the relationship of different fragments. These methods, however, can produce ambiguous results. In order to evaluate sequence-based methods for fragment identification, we extensively compared (G + C)-contents and tetranucleotide usage patterns of 9054 fosmid-sized genomic fragments generated in silico from 118 completely sequenced bacterial genomes (40 982 931 fragment pairs were compared in total). The results of this systematic study show that the discriminatory power of correlations of tetranucleotide-derived z-scores is by far superior to that of differences in (G + C)-content and provides reasonable assignment probabilities when applied to metagenome libraries of small diversity. Using six fully sequenced fosmid inserts from a metagenomic analysis of microbial consortia mediating the anaerobic oxidation of methane (AOM), we demonstrate that discrimination based on tetranucleotide-derived z-score correlations was consistent with corresponding data from 16S ribosomal RNA sequence analysis and allowed us to discriminate between fosmid inserts that were indistinguishable with respect to their (G + C)-contents.     

Molecular analysis of the human MHC class I region using yeast artificial chromosome clones

The cloning of large genomic fragments corresponding to the major histocompatibility complex (MHC) class I region provides the necessary framework for a better understanding of its organization and for the localization of new genes involved in MHC-associated disease. Two human genomic libraries constructed in yeast artificial chromosomes (YACs) have been prepared using complete Not I or Mlu I digestion of source DNA. From these libraries three YAC clones with inserts belonging to the MHC class I region have been isolated. They correspond to exact copies of three genomic fragments of 210, 145, and 50 kilobases (kb), respectively and have been precisely located in the restriction map of the region. Detailed rare-cutter restriction maps of the inserts have been generated. Within these clones we have demonstrated the presence of two class I genes, one of which is HLA-E, and of at least three Hpa II tiny fragment (HTF) islands, corresponding to three putative new transcribed sequences. End clones, which are of particular interest in the extension and refinement of the regional map, have been rescued by systematic subcloning of purified YACs.     

A two-host fosmid system for functional screening of (meta)genomic libraries from extreme thermophiles

A new cloning system is described, which allows the construction of large-insert fosmid libraries in Escherichia coli and the transfer of the recombinant libraries to the extreme thermophile Thermus thermophilus via natural transformation. Libraries are established in the thermophilic host by site-specific chromosomal insertion of the recombinant fosmids via single crossover or double crossover recombination at the T. thermophilus pyr locus. Comparative screening of a fosmid library constructed from genomic DNA from the thermophilic spirochaete, Spirochaeta thermophila, for clones expressing thermoactive xylanase activity revealed that 50% of the fosmids that conferred xylanase activity upon the corresponding T. thermophilus transformants did not give rise to xylanase-positive E. coli clones, indicating that significantly more S. thermophila genes are functionally expressed in T. thermophilus than in E. coli. The novel T. thermophilus host/vector system may be of value for the construction and functional screening of recombinant DNA libraries from individual thermophilic or extremely thermophilic organisms as well as from complex metagenomes isolated from thermophilic microbial communities.     

Construction and Characterization of Two Bacterial Artificial Chromosome Libraries of Grass Carp

Bacterial artificial chromosome (BAC) library is an important tool in genomic research. We constructed two libraries from the genomic DNA of grass carp (Ctenopharyngodon idellus) as a crucial part of the grass carp genome project. The libraries were constructed in the EcoRI and HindIII sites of the vector CopyControl pCC1BAC. The EcoRI library comprised 53,000 positive clones, and approximately 99.94% of the clones contained grass carp nuclear DNA inserts (average size, 139.7 kb) covering 7.4× haploid genome equivalents and 2% empty clones. Similarly, the HindIII library comprised 52,216 clones with approximately 99.82% probability of finding any genomic fragments containing single-copy genes; the average insert size was 121.5 kb with 2.8% insert-empty clones, thus providing genome coverage of 6.3× haploid genome equivalents of grass carp. We selected gene-specific probes for screening the target gene clones in the HindIII library. In all, we obtained 31 positive clones, which were identified for every gene, with an average of 6.2 BAC clones per gene probe. Thus, we succeeded in constructing the desired BAC libraries, which should provide an important foundation for future physical mapping and whole-genome sequencing in grass carp.     

Cloning of peptidase genes from Lactobacillus helveticus CNRZ 32

Lactic acid bacteria express a complex proteolytic enzyme system that is capable of hydrolyzing casein to amino acids. We have begun to examine the number and specificity of exopeptidases from Lactobacillus helveticus CNRZ 32. A genomic library of L. helveticus CNRZ 32 DNA fragments from a Sau3A partial digestion was constructed in Escherichia coli DH5 utilizing pJDC9. This library was screened for the presence of aminopeptidase, X-prolyl dipeptidyl aminopeptidase (X-PDAP), and dipeptidase activities by two methods. The first screening identified an aminopeptidase II (APII) and X-PDAP. The X-PDAP was determined to be present on four independent DNA inserts ranging in size from 3.5 to 7.7 kilobase pairs (kbp). EcoRI/EcoRV digests of these plasmids suggested that all inserts had 1.0 and 1.8 kbp fragments in common. The gene for APII was determined to be present on three independent DNA inserts ranging in size from 8.2 to 11.3 kbp. EcoRI digestion of these plasmids indicated that 1.2 and 1.8 kbp fragments were in common. The second screening identified an additional aminopeptidase (API), a di/tripeptidase (DTP) with prolinase activity, a broad-specificity dipeptidase (DPI), and a narrow-specificity dipeptidase (DPII). The insert size of clones expressing API, DTP, DPI, DPII were 4.8, 9.5, 5.8, and 6.3 kbp, respectively. Histochemical staining of native polyacrylamide gels from recombinant E. coli cultures demonstrated that the cloned peptidase co-migrated with native L. helveticus CNRZ 32 enzymes. Correspondence to: J. L. Steele     

Coexisting/Coexpressing Genomic Libraries (CoGeL) identify interactions among distantly located genetic loci for developing complex microbial phenotypes

In engineering novel microbial strains for biotechnological applications, beyond a priori identifiable pathways to be engineered, it is becoming increasingly important to develop complex, ill-defined cellular phenotypes. One approach is to screen genomic or metagenomic libraries to identify genes imparting desirable phenotypes, such as tolerance to stressors or novel catabolic programs. Such libraries are limited by their inability to identify interactions among distant genetic loci. To solve this problem, we constructed plasmid- and fosmid-based Escherichia coli Coexisting/Coexpressing Genomic Libraries (CoGeLs). As a proof of principle, four sets of two genes of the l-lysine biosynthesis pathway distantly located on the E. coli chromosome were knocked out. Upon transformation of these auxotrophs with CoGeLs, cells growing without supplementation were found to harbor library inserts containing the knocked-out genes demonstrating the interaction between the two libraries. CoGeLs were also screened to identify genetic loci that work synergistically to create the considerably more complex acid-tolerance phenotype. CoGeL screening identified combination of genes known to enhance acid tolerance (gadBC operon and adiC), but also identified the novel combination of arcZ and recA that greatly enhanced acid tolerance by 9000-fold. arcZ is a small RNA that we show increases pH tolerance alone and together with recA.     

Construction of tomato genomic DNA libraries in a binary-BAC (BIBAC) vector

This is the first report of large insert genomic DNA libraries constructed in a binary-BAC (BIBAC) vector. Genomic DNA libraries containing approximately 4.6 haploid nuclear genomic equivalents were constructed for Lycopersicon esculentum (cv. Mogeor) and Lycopersicon pennellii (LA716) in the BIBAC2 vector. The L. esculentum library has an average insert size of 125 kb and is comprised of 42 272 individual colonies stored as frozen cultures in a 384-well format (108 plates). The L. pennellii library has an average insert size of 90 kb and is comprised of 53 760 individual clones (140 384-well plates). In each of the libraries, it is estimated that 90% of the colonies contain genomic DNA inserts. The composition of the L. esculentum and L. pennellii libraries was determined by analyzing a series of randomly selected clones. The L. esculentum library was surveyed for clones containing chloroplast DNA (1.4%), mitochondrial DNA (0.012%) and repetitive DNA motifs. BIBAC clones that may contain a gene of interest can be identified from these libraries by colony hybridization with homologous or heterologous probes or by PCR pooling techniques. Once identified, BIBAC genomic DNA library clones are immediately suitable for Agrobacterium tumefaciens-mediated plant transformation.     

Improved glycerol to ethanol conversion by <Emphasis Type="Italic">E. coli</Emphasis> using a metagenomic fragment isolated from an anaerobic reactor

Crude glycerol obtained as a by-product of biodiesel production is a reliable feedstock with the potential to be converted into reduced chemicals with high yields. It has been previously shown that ethanol is the primary product of glycerol fermentation by Escherichia coli. However, few efforts were made to enhance this conversion by means of the expression of heterologous genes with the potential to improve glycerol transport or metabolism. In this study, a fosmid-based metagenomic library constructed from an anaerobic reactor purge sludge was screened for genetic elements that promote the use and fermentation of crude glycerol by E. coli. One clone was selected based on its improved growth rate on this feedstock. The corresponding fosmid, named G1, was fully sequenced (41 kbp long) and the gene responsible for the observed phenotype was pinpointed by in vitro insertion mutagenesis. Ethanol production from both pure and crude glycerol was evaluated using the parental G1 clone harboring the ethanologenic plasmid pLOI297 or the industrial strain LY180 complemented with G1. In mineral salts media containing 50 % (v/v) pure glycerol, ethanol concentrations increased two-fold on average when G1 was present in the cells reaching up to 20 g/L after 24 h fermentation. Similar fermentation experiments were done using crude instead of pure glycerol. With an initial OD₆₂₀ of 8.0, final ethanol concentrations after 24 h were much higher reaching 67 and 75 g/L with LY180 cells carrying the control fosmid or the G1 fosmid, respectively. This translates into a specific ethanol production rate of 0.39 g h^?1 OD^?1 L^?1.     

Phylogenetic and metagenomic analysis of Verrucomicrobia in former agricultural grassland soil

The bacterial phylum Verrucomicrobia has a widespread distribution, and is known to be one of the most common and diverse phyla in soil habitats. However, members of this phylum have typically been recalcitrant to cultivation methods, hampering the study of this presumably important bacterial group. In this study, we examine the phylogenetic diversity of the Verrucomicrobia in a former agricultural field and gain access to genomic information via a metagenomic approach. We examined Verrucomicrobia -like 16S rRNA gene sequences recovered from general bacterial and phylum-specific libraries, revealing a dominance of subdivisions 1 and 2. A PCR-based screening method was developed to identify inserts containing verrucomicrobial 16S rRNA genes within a large-insert metagenomic library, and on screening of 28 800 clones, four fosmids were identified as containing verrucomicrobial genomic DNA. Full-length sequencing of fosmid inserts and gene annotation identified a total of 98 ORFs, representing a range of functions. No conservation of gene order was observed adjacent to the ribosomal operons. Fosmid inserts were further analyzed for tetranucleotide frequencies to identify remnants of past horizontal gene transfer events. The metagenomic approach utilized proved to be suitable for the recovery of verrucomicrobial genomic DNA, thereby providing a window into the genomes of members of this important, yet poorly characterized, bacterial phylum.     

Overexpression of the Lactobacillus plantarum peptidoglycan biosynthesis murA2 gene increases the tolerance of Escherichia coli to alcohols and enhances ethanol production

A major challenge in producing chemicals and biofuels is to increase the tolerance of the host organism to toxic products or byproducts. An Escherichia coli strain with superior ethanol and more generally alcohol tolerance was identified by screening a library constructed by randomly integrating Lactobacillus plantarum genomic DNA fragments into the E. coli chromosome via Cre-lox recombination. Sequencing identified the inserted DNA fragment as the murA2 gene and its upstream intergenic 973-bp sequence, both coded on the negative genomic DNA strand. Overexpression of this murA2 gene and its upstream 973-bp sequence significantly enhanced ethanol tolerance in both E. coli EC100 and wild type E. coli MG1655 strains by 4.1-fold and 2.0-fold compared to control strains, respectively. Tolerance to n-butanol and i-butanol in E. coli MG1655 was increased by 1.85-fold and 1.91-fold, respectively. We show that the intergenic 973-bp sequence contains a native promoter for the murA2 gene along with a long 5′ UTR (286 nt) on the negative strand, while a noncoding, small RNA, named MurA2S, is expressed off the positive strand. MurA2S is expressed in E. coli and may interact with murA2, but it does not affect murA2’s ability to enhance alcohol tolerance in E. coli. Overexpression of murA2 with its upstream region in the ethanologenic E. coli KO11 strain significantly improved ethanol production in cultures that simulate the industrial Melle-Boinot fermentation process.     

Distinct seasonal dynamics of responses to elevated CO2 in two understorey grass species differing in shade‐tolerance

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Homology-independent genome integration enables rapid library construction for enzyme expression and pathway optimization in Yarrowia lipolytica

Yarrowia lipolytica is an important oleaginous industrial microorganism used to produce biofuels and other value-added compounds. Although several genetic engineering tools have been developed for Y. lipolytica, there is no efficient method for genomic integration of large DNA fragments. In addition, methods for constructing multigene expression libraries for biosynthetic pathway optimization are still lacking in Y. lipolytica. In this study, we demonstrate that multiple and large DNA fragments can be randomly and efficiently integrated into the genome of Y. lipolytica in a homology-independent manner. This homology-independent integration generates variation in the chromosomal locations of the inserted fragments and in gene copy numbers, resulting in the expression differences in the integrated genes or pathways. Because of these variations, gene expression libraries can be easily created through one-step integration. As a proof of concept, a LIP2 (producing lipase) expression library and a library of multiple genes in the β-carotene biosynthetic pathway were constructed, and high-production strains were obtained through library screening. Our work demonstrates the potential of homology-independent genome integration for library construction, especially for multivariate modular libraries for metabolic pathways in Y. lipolytica, and will facilitate pathway optimization in metabolic engineering applications.     

Characterization of large-insert DNA libraries from soil for environmental genomic studies of Archaea

Complex genomic libraries are increasingly being used to retrieve complete genes, operons or large genomic fragments directly from environmental samples, without the need to cultivate the respective microorganisms. We report on the construction of three large-insert fosmid libraries in total covering 3 Gbp of community DNA from two different soil samples, a sandy ecosystem and a mixed forest soil. In a fosmid end sequencing approach including 5376 sequence tags of approximately 700 bp length, we show that mostly bacterial and, to a much lesser extent, archaeal and eukaryotic genome fragments (approximately 1% each) have been captured in our libraries. The diversity of putative protein-encoding genes, as reflected by their distribution into different COG clusters, was comparable to that encoded in complete genomes of cultivated microorganisms. A huge variety of genomic fragments has been captured in our libraries, as seen by comparison with sequences in the public databases and by the large variation in G+C contents. We dissect differences between the libraries, which relate to the different ecosystems analysed and to biases introduced by different DNA preparations. Furthermore, a range of taxonomic marker genes (other than 16S rRNA) has been identified that allows the assignment of genome fragments to specific lineages. The complete sequences of two genome fragments identified as being affiliated with Archaea, based on a gene encoding a CDC48 homologue and a thermosome subunit, respectively, are presented and discussed. We thereby extend the genomic information of uncultivated crenarchaeota from soil and offer hints to specific metabolic traits present in this group.     

A method for generation of arbitrary peptide libraries using genomic DNA

Random peptide libraries can be constructed either by in vitro synthesis of random peptides, or through translation of DNA sequences from synthetic random oligonucleotides. Here we describe an alternative way of making arbitrary peptide libraries with high diversity that can be used in screening as random peptide libraries. Genomic DNA digested with a frequent-cutting restriction enzyme recognizing four nucleotides will theoretically consist of small DNA pieces with average length of 256 nucleotides, and on average around 10⁷ fragments can be generated from a genome of 3 × 10⁹ bases. A peptide library translated from these fragments will have sufficient diversity for some protein interaction screening experiments. Moreover, the same genome digested with a different four-cutter enzyme or ligated into different reading frames will result in different nonoverlapping libraries. A series of such libraries could be generated with genomic DNAs from different species. In this study, human genomic DNA was digested with four-cutter restriction enzymes DpnII and Tsp509I, respectively, and cloned into yeast expression vector pGADT7 to generate arbitrary peptide libraries. These libraries were used in yeast two-hybrid assays to screen for binding motifs of the PDZ domain containing protein synectin. Our results showed that in addition to various native carboxy-terminal tails, synectin could also bind to many artificial ones, some of which contained a consensus sequence—(S/T)XC-COOH.     

Comparative analyses of actinobacterial genomic fragments from Lake Kinneret

The high genomic G+C group of Actinobacteria possesses a variety of physiological and metabolic properties, and exhibits diverse lifestyles and ecological distribution. In recent years, Actinobacteria have been found to frequently dominate samples obtained from freshwater samples. Furthermore, phylogenetic analyses have shown that 16S rRNA genes from uncultured actinobacterial freshwater samples cluster in four distinct lineages. While these lineages are abundant, little is known about them and currently no pure‐culture representatives or genomic fragments of them are available. In a screen of a genomic library from the moderately eutrophic freshwater Lake Kinneret, five fosmid clones containing actinobacterial genomic fragments were found. Three ～40 kb genomic fragments were chosen for sequencing. Fosmids K003 and K005 showed high similarity and were affiliated with the acIV actinobacterial freshwater lineage. Fosmid K004 was affiliated with the highly abundant acI lineage. A comparative genomic analysis revealed high synteny between the two freshwater clones K003 and K005 but a lower synteny between these two and the K004 fosmid. Fosmids K003 and K005 share an identical arrangement of arginine biosynthesis gene while K004 showed a slightly different arrangement by lacking the argF gene. Fosmid Ant4E12, an Antarctic actinobacterial clone, showed a higher synteny with K003/5 than K004 and a similar arginine operon, but in a different genomic context. The Clusters of Orthologous Groups categories assignment of the three fosmids yielded genes that were mostly involved in amino acid and nucleotide metabolism, as well as transport and ribosomal RNA translation, structure and biogenesis. These genomic fragments represent the first sequences to be published from these lineages, providing a cornerstone for future work on this environmentally dominant group.     

An insight into the complex prion-prion interaction network in the budding yeast Saccharomyces cerevisiae

The budding yeast Saccharomyces cerevisiae is a valuable model system for studying prion-prion interactions as it contains multiple prion proteins. A recent study from our laboratory showed that the existence of Swi1 prion ([SWI⁺]) and overproduction of Swi1 can have strong impacts on the formation of 2 other extensively studied yeast prions, [PSI⁺] and [PIN⁺] ([RNQ⁺]) (Genetics, Vol. 197, 685–700). We showed that a single yeast cell is capable of harboring at least 3 heterologous prion elements and these prions can influence each other's appearance positively and/or negatively. We also showed that during the de novo [PSI⁺] formation process upon Sup35 overproduction, the aggregation patterns of a preexisting inducer ([RNQ⁺] or [SWI⁺]) can undergo significant remodeling from stably transmitted dot-shaped aggregates to aggregates that co-localize with the newly formed Sup35 aggregates that are ring/ribbon/rod- shaped. Such co-localization disappears once the newly formed [PSI⁺] prion stabilizes. Our finding provides strong evidence supporting the “cross-seeding” model for prion-prion interactions and confirms earlier reports that the interactions among different prions and their prion proteins mostly occur at the initiation stages of prionogenesis. Our results also highlight a complex prion interaction network in yeast. We believe that elucidating the mechanism underlying the yeast prion-prion interaction network will not only provide insight into the process of prion de novo generation and propagation in yeast but also shed light on the mechanisms that govern protein misfolding, aggregation, and amyloidogenesis in higher eukaryotes.     

Mutant selection and phenotypic and genetic characterization of ethanol-tolerant strains of <Emphasis Type="Italic">Clostridium thermocellum</Emphasis>

Clostridium thermocellum is a model microorganism for converting cellulosic biomass into fuels and chemicals via consolidated bioprocessing. One of the challenges for industrial application of this organism is its low ethanol tolerance, typically 1–2% (w/v) in wild-type strains. In this study, we report the development and characterization of mutant C. thermocellum strains that can grow in the presence of high ethanol concentrations. Starting from a single colony, wild-type C. thermocellum ATCC 27405 was sub-cultured and adapted for growth in up to 50 g/L ethanol using either cellobiose or crystalline cellulose as the growth substrate. Both the adapted strains retained their ability to grow on either substrate and displayed a higher growth rate and biomass yield than the wild-type strain in the absence of ethanol. With added ethanol in the media, the mutant strains displayed an inverse correlation between ethanol concentration and growth rate or biomass yield. Genome sequencing revealed six common mutations in the two ethanol-tolerant strains including an alcohol dehydrogenase gene and genes involved in arginine/pyrimidine biosynthetic pathway. The potential role of these mutations in ethanol tolerance phenotype is discussed.     

Modeling the cucumber fermentation: Growth ofLactobacillus plantarum

Summary Specific growth rate models of product-inhibited cell growth exist but are rarely applied to fermentations beyond ethanol and large-scale antibiotic production. The present paper summarizes experimental data and the development of a model for growth of the commercially important bacterium,Lactobacillus plantarum, in cucumber juice. The model provides an excellent correlation of data for the influence on bacterial growth rate of NaCl, protons (H⁺), and the neutral, inhibitory forms of acetic acid and the fermentation product, lactic acid. The effects of each of the variables are first modeled separately using established functional forms and then combined in the final model formulation.Nomenclature [C] inhibitory component concentration, mM - [C]_max concentration of the inhibitory component where the specific growth rate is zero, mM, determined by model fitting - [H⁺] hydrogen ion concentration, mM - [HLa] undissociated lactic acid concentration, mM - [La^–] dissociated lactic acid concentration, mM - [La_t] total lactic acid ([HLa]+[La^–]) concentration, mM - [HAc] undissociated acetic acid concentration, mM - [Ac^–] dissociated acetic acid concentration, mM - [Ac_t] total acetic acid ([HAc]+[Ac^–]) concentration, mM - [NaCl] sodium chloride concentration, %, w/v - specific growth rate, h^–1 - _max maximum specific growth rate, h^–1 - ₀ specific growth rate, h^–1, at 0 concentration of additive - K _ij inhibition coefficient - , ,K _m coefficients determined by model fitting Mention of a trademark or proprietary product does not constitute a guarantee or warranty of the product by the US Department of Agriculture or North Carolina Agricultural Research Service, nor does it imply approval to the exclusion of other products that may be suitable.     

Effect of replacing [NTf2] by [PF6] anion on the [BMIm][NTf2] ionic liquid confined by gold

The effect of replacing bis(trifluoromethylsulphonyl)imide ([NTf₂]) by hexafluorophosphate ([PF₆]) in room temperature ionic liquid (IL) 1-butyl-3-methylimidazolium bis(trifluoromethylsulphonyl)imide ([BMIm][NTf₂]) confined between two gold interfaces is herein reported through molecular dynamics simulations using all-atom non-polarisable force-fields. Five systems were studied ranging from pure [BMIm][NTf₂] to pure [BMIm][PF₆], with [PF₆] molar fractions of 0, 0.125, 0.25, 0.375 and 0.5. Special attention was drawn to investigate the impact of the [PF₆] anion on the IL, in particular on the first layers of the liquid in close contact with the solid gold surface.