Characterization of Conserved Region 2-Deficient Mutants of the Cytomegalovirus Egress Protein pM53

Dominant-negative (DN) mutants are powerful tools for studying essential protein-protein interactions. A systematic genetic screen of the essential murine cytomegalovirus (MCMV) protein pM53 identified the accumulation of inhibitory mutations within conserved region 2 (CR2) and CR4. The strong inhibitory potential of these CR4 mutants is characterized by a particular phenotype. The DN effect of the small insertion mutations in CR2 was too weak to analyze (M. Popa, Z. Ruzsics, M. Lötzerich, L. Dölken, C. Buser, P. Walther, and U. H. Koszinowski, J. Virol. 84:9035–9046, 2010); therefore, the present study describes the construction of M53 alleles lacking CR2 (either completely or partially) and subsequent examination of the DN effect on MCMV replication upon conditional expression. Overexpression of CR2-deficient pM53 inhibited virus production by about 10,000-fold. This was due to interference with capsid export from the nucleus and viral genome cleavage/packaging. In addition, the fate of the nuclear envelopment complex in the presence of DN pM53 overexpression was analyzed. The CR2 mutants were able to bind to pM50, albeit to a lesser extent than the wild-type protein, and relocalized the wild-type nuclear envelope complex in infected cells. Unlike the CR4 DN, the CR2 DN mutants did not affect the stability of pM50.     

Generation of mutant murine cytomegalovirus strains from overlapping cosmid and plasmid clones

We have developed a cosmid and plasmid system to generate mutant strains of murine cytomegalovirus (MCMV). The system is based on a series of seven overlapping cosmid clones that regenerate MCMV when cotransfected into mouse cells. The unaltered cosmids produce MCMV that is indistinguishable from wild-type MCMV based on restriction enzyme digest patterns of virus DNA and growth rates both in vitro and in vivo. Analysis of viral DNA from plaque-purified recombinant isolates taken from in vitro and in vivo stocks indicated that regeneration did not introduce novel mutations in the recombinant viral genomes. Isolation of specific genes and subsequent generation of specific mutant MCMVs was accomplished by replacement of cosmids with overlapping plasmid subclones. A new vector, PmeSUB, featuring a multiple cloning site and a stringent origin of replication, was constructed to make large subclones for use with smaller subclones containing the gene of interest. The utility of this system was demonstrated by the generation of two different mutant MCMVs from different combinations of overlapping plasmid subclones of one cosmid. The advantages of this system are that (i) target genes are maintained as small clones making them amenable to standard in vitro mutagenesis manipulations and that (ii) no reporter or selection genes are necessary to identify mutants.     

Comparison between human cytomegalovirus pUL97 and murine cytomegalovirus (MCMV) pM97 expressed by MCMV and vaccinia virus: pM97 does not confer ganciclovir sensitivity

The UL97 protein (pUL97) of human cytomegalovirus (HCMV) is a protein kinase that also phosphorylates ganciclovir (GCV), but its biological function is not yet clear. The M97 protein (pM97) of mouse cytomegalovirus (MCMV) is the homolog of pUL97. First, we studied the consequences of genetic replacement of M97 by UL97. Using the infectious bacterial plasmid clone of the full-length MCMV genome (M. Wagner, S. Jonjic, U. H. Koszinowski, and M. Messerle, J. Virol. 73:7056-7060, 1999), we replaced the M97 gene with the UL97 gene and constructed an MCMV M97 deletion mutant and a revertant virus. In addition, pUL97 and pM97 were expressed by recombinant vaccinia virus to compare both for known functions. Remarkably, pM97 proved not to be the reason for the GCV sensitivity of MCMV. When expressed by the recombinant MCMV, however, pUL97 was phosphorylated and endowed MCMV with the capacity to phosphorylate GCV, thereby rendering MCMV more susceptible to GCV. We found that deletion of pM97, although it is not essential for MCMV replication, severely affected virus growth. This growth deficit was only partially amended by pUL97 expression. When expressed by recombinant vaccinia viruses, both proteins were phosphorylated and supported phosphorylation of GCV, but pUL97 was about 10 times more effective than pM97. One hint of the functional differences between the proteins was provided by the finding that pUL97 accumulates in the nucleus, whereas pM97 is predominantly located in the cytoplasm of infected cells. In vivo testing revealed that the UL97-MCMV recombinant should allow evaluation of novel antiviral drugs targeted to the UL97 protein of HCMV in mice.     

Products of US22 Genes M140 and M141 Confer Efficient Replication of Murine Cytomegalovirus in Macrophages and Spleen

Efficient replication of murine cytomegalovirus (MCMV) in macrophages is a prerequisite for optimal growth and spread of the virus in its natural host. Simultaneous deletion of US22 gene family members M139, M140, and M141 results in impaired replication of MCMV in macrophages and mice. In this study, we characterized the proteins derived from these three genes and examined the impact of individual gene deletions on viral pathogenesis. The M139, M140, and M141 gene products were identified as early proteins that localize to both the nucleus and cytoplasm in infected cells. Gene M139 encodes two proteins, of 72 and 61 kDa, while M140 and M141 each encode a single protein of 56 (pM140) and 52 (pM141) kDa, respectively. No role for the M139 proteins in MCMV replication in macrophages or mice was determined in these studies. In contrast, deletion of either M140 or M141 resulted in impaired MCMV replication in macrophages and spleen tissue. Replication of the M140 deletion mutant was significantly more impaired than that of the virus lacking M141. Further analyses revealed that the absence of the pM140 adversely affected pM141 levels by rendering the latter protein unstable. Since the replication defect due to deletion of M140 was more profound than could be explained by the reduced half-life of pM141, pM140 must exert an additional, independent function in mediating efficient replication of MCMV in macrophages and spleen tissue. These data indicate that the US22 genes M140 and M141 function both cooperatively and independently to regulate MCMV replication in a cell type-specific manner and, thus, to influence viral pathogenesis.     

Complex formation among murine cytomegalovirus US22 proteins encoded by genes M139, M140, and M141

The murine cytomegalovirus (MCMV) proteins encoded by US22 genes M139, M140, and M141 function, at least in part, to regulate replication of this virus in macrophages. Mutant MCMV having one or more of these genes deleted replicates poorly in macrophages in culture and in the macrophage-dense environment of the spleen. In this report, we demonstrate the existence of stable complexes formed by the products of all three of these US22 genes, as well as a complex composed of the products of M140 and M141. These complexes form in the absence of other viral proteins; however, the pM140/pM141 complex serves as a requisite binding partner for the M139 gene products. Products from all three genes colocalize to a perinuclear region of the cell juxtaposed to or within the cis-Golgi region but excluded from the trans-Golgi region. Interestingly, expression of pM141 redirects pM140 from its predominantly nuclear residence to the perinuclear, cytoplasmic locale where these US22 proteins apparently exist in complex. Thus, complexing of these nonessential, early MCMV proteins likely confers a function(s) independent of each individual protein and important for optimal replication of MCMV in its natural host.     

Different strategies to recover the activity of monomeric triosephosphate isomerase by directed evolution

A monomeric version of triosephosphate isomerase from Trypanosoma brucei, MonoTIM, has very low activity, and the same is true for all of the additional monomeric variants so far constructed. Here, we subjected MonoTIM to directed evolution schemes to achieve an activity improvement. The construction of a suitable strain for genetic selection provided an effective way to obtain active catalysts from a diverse population of protein variants. We used this tool to identify active mutants from two different strategies of mutagenesis: random mutagenesis of the whole gene and randomization of loop 2. Both strategies converged in the isolation of mutations Ala43 to Pro and Thr44 to either Ala or Ser, when randomizing the entire gene or to Arg in the case of randomization of loop 2. The kinetic characterization of the two more active mutants showed an increase of 11-fold in k(cat) and a reduction of 4-fold in K(m) for both of them, demonstrating the sensitivity of the selection method. A small difference in growth rate is observed when both mutant genes are compared, which seems to be attributable to a difference in solubility of the expressed proteins.     

Comprehensive mutational analysis of a herpesvirus gene in the viral genome context reveals a region essential for virus replication

Essential viral proteins perform vital functions during morphogenesis via a complex interaction with other viral and cellular gene products. Here, we present a novel approach to comprehensive mutagenesis of essential cytomegalovirus genes and biological analysis in the 230-kbp-genome context. A random Tn7-based mutagenesis procedure at the single-gene level was combined with site-specific recombination via the FLP/FLP recognition target site system for viral genome reconstitution. We show the function of more than 100 mutants from a larger library of M50/p35, a protein involved in capsid egress from the nucleus. This protein recruits other viral proteins and cellular enzymes to the inner nuclear membrane. Our approach enabled us to rapidly discriminate between essential and nonessential regions within the coding sequence. Based on the prediction of the screen, we were able to map a site essential for viral protein-protein interaction at the amino acid level.     

The Identification of Transposon-Tagged Mutations in Essential Genes That Affect Cell Morphology in Saccharomyces Cerevisiae

The yeast Saccharomyces cerevisiae reproduces by budding, and many genes are required for proper bud development. Mutations in some of these genes cause cells to die with an unusual terminal morphology--elongated or otherwise aberrantly shaped buds. To gain insight into bud development, we set out to identify novel genes that encode proteins required for proper bud morphogenesis. Previous studies screened collections of conditional mutations to identify genes required for essential functions, including bud formation. However, genes that are not susceptible to the generation of mutations that cause a conditional phenotype will not be identified in such screens. To identify a more comprehensive collection of mutants, we used transposon mutagenesis to generate a large collection of lethal disruption mutations. This collection was used to identify 209 mutants with disruptions that cause an aberrant terminal bud morphology. The disruption mutations in 33 of these mutants identify three previously uncharacterized genes as essential, and the mutant phenotypes suggest roles for their products in bud morphogenesis.     

A conjugation-based system for genetic analysis of group II intron splicing in Lactococcus lactis

The conjugative element pRS01 from Lactococcus lactis encodes the putative relaxase protein LtrB. The ltrB gene is interrupted by the functional group II intron Ll.ltrB. Accurate splicing of the two ltrB exons is required for synthesis of the mRNA encoding the LtrB conjugative relaxase and subsequent plasmid transfer. A conjugation-based genetic assay was developed to identify Ll.ltrB mutations that affect splicing. In this assay a nonsplicing, transfer-defective pRS01 derivative (pM1014) and a shuttle vector carrying the ltrB region, including the Ll.ltrB intron (pCOM9), are used. pCOM9 provides splicing-dependent complementation of the transfer defect of pM1014. Site-directed mutations within Ll.ltrB, either in the catalytic RNA or in the intron-encoded protein gene ltrA, were generated in the context of pCOM9. When these mutants were tested in the conjugation-based assay, significantly reduced mating was observed. Quantitative molecular analysis of in vivo splicing activity confirmed that the observed mating defects resulted from reduced splicing. Once the system was validated for the engineered mutants, random mutagenesis of the intron followed by genetic and molecular screening for splicing defects resulted in identification of point mutations that affect splicing.     

Genetic analysis of innate resistance to mouse cytomegalovirus (MCMV).

Innate immunity is inherited and is, therefore, particularly susceptible to analysis by classical genetic methods. The 'phenotype first' approach has already revealed the principal receptors of the innate immune system as well as several essential signalling intermediates. It has recently emerged that innate resistance to mouse cytomegalovirus (MCMV) infection depends upon a large number of host genes with non-redundant functions; hence, random germline mutagenesis frequently causes susceptibility to this pathogen. Approximately one in 30 pedigrees derived from N-ethyl-N-nitrosourea-mutagenised progenitors bears a recessive mutation that disrupts resistance to MCMV. Moreover, many of the genes required for resistance to MCMV will undoubtedly prove to have broad roles in immunity, creating resistance to many other microbes. The forward genetics approach offers an excellent opportunity to identify many of the key components of the innate immune system.     

Murine cytomegalovirus m142 and m143 are both required to block protein kinase R-mediated shutdown of protein synthesis

Cytomegaloviruses carry the US22 family of genes, which have common sequence motifs but diverse functions. Only two of the 12 US22 family genes of murine cytomegalovirus (MCMV) are essential for virus replication, but their functions have remained unknown. In the present study, we deleted the essential US22 family genes, m142 and m143, from the MCMV genome and propagated the mutant viruses on complementing cells. The m142 and the m143 deletion mutants were both unable to replicate in noncomplementing cells at low and high multiplicities of infection. In cells infected with the deletion mutants, viral immediate-early and early proteins were expressed, but viral DNA replication and synthesis of the late-gene product glycoprotein B were inhibited, even though mRNAs of late genes were present. Global protein synthesis was impaired in these cells, which correlated with phosphorylation of the double-stranded RNA-dependent protein kinase R (PKR) and its target protein, the eukaryotic translation initiation factor 2alpha, suggesting that m142 and m143 are necessary to block the PKR-mediated shutdown of protein synthesis. Replication of the m142 and m143 knockout mutants was partially restored by expression of the human cytomegalovirus TRS1 gene, a known double-stranded-RNA-binding protein that inhibits PKR activation. These results indicate that m142 and m143 are both required for inhibition of the PKR-mediated host antiviral response.     

Dominant Negative Mutants of the Murine Cytomegalovirus M53 Gene Block Nuclear Egress and Inhibit Capsid Maturation

The alphaherpesvirus proteins UL31 and UL34 and their homologues in other herpesvirus subfamilies cooperate at the nuclear membrane in the export of nascent herpesvirus capsids. We studied the respective betaherpesvirus proteins M53 and M50 in mouse cytomegalovirus (MCMV). Recently, we established a random approach to identify dominant negative (DN) mutants of essential viral genes and isolated DN mutants of M50 (B. Rupp, Z. Ruzsics, C. Buser, B. Adler, P. Walther and U. H. Koszinowski, J. Virol 81:5508-5517). Here, we report the identification and phenotypic characterization of DN alleles of its partner, M53. While mutations in the middle of the M53 open reading frame (ORF) resulted in DN mutants inhibiting MCMV replication by ∼100-fold, mutations at the C terminus resulted in up to 1,000,000-fold inhibition of virus production. C-terminal DN mutants affected nuclear distribution and steady-state levels of the nuclear egress complex and completely blocked export of viral capsids. In addition, they induced a marked maturation defect of viral capsids, resulting in the accumulation of nuclear capsids with aberrant morphology. This was associated with a two-thirds reduction in the total amount of unit length genomes, indicating an accessory role for M53 in DNA packaging.Our understanding of herpesvirus morphogenesis is mainly derived from studies of Alphaherpesvirinae, such as herpes simplex virus type 1 (HSV-1) and pseudorabies virus (PrV). A faster replication cycle and a more productive infection in tissue culture aided genetic analysis of alphaherpesvirus morphogenesis. In addition, deletion mutants of key morphogenesis genes in alphaherpesviruses often maintain basic replication capacity, whereas the mutations of their homologues in Betaherpesvirinae or Gammaherpesvirinae mostly result in a lethal phenotype (for the UL31 and the UL34 family, see references 3, 6, 9-11, 16, 20, 21, and 42). These genes became amenable to comprehensive genetic analysis in betaherpesviruses only after their genomes were cloned as infectious bacterial artificial chromosomes (BACs), which obviated the need to generate replication-competent intermediates or complementing cell lines (3, 21, 23). BAC-based mutagenesis allowed viability screens mapping essential genes (8, 43) or even functional sites of essential genes in cytomegaloviruses (3, 21). However, these approaches cannot easily be applied to reveal the null phenotypes in the context of virus replication, as mutant viruses are not easily reconstituted. In addition, deletion of an essential viral gene can reveal the null phenotype of only the first of perhaps several essential functions during virus morphogenesis. This problem can be addressed to some extent by using dominant negative (DN) mutations (36). DN mutants are loss-of-function mutants that induce a null phenotype in the presence of the wild-type (wt) allele (14). Analysis of phenotypes induced by DN mutants proved to be extremely useful in genetics and cell biology, signaling, and biochemistry. Such inhibitory mutants of cellular proteins are often designed based on knowledge on the structural or functional role of a well-characterized protein domain. Unfortunately, we lack the structural information that would allow knowledge-based design of viral DN mutants for the majority of herpesvirus gene products. Thus, we established a random screen consisting of three steps to identify mutants of viral genes with DN potential (36): (i) a library of mutants is generated by random insertion of 5 amino acids (aa) or a stop codon into the open reading frame (ORF) of interest using transposon mutagenesis, (ii) nonfunctional mutants are identified by cis complementation of the respective deletion mutant mouse cytomegalovirus (MCMV) BAC, and (iii) nonfunctional mutants are tested for their inhibitory potential upon reconstitution of the wt BAC cloned genomes. In the last screen, mutants that have a specific inhibitory effect on the activity of the wt allele are selected. The specific phenotype obtained upon induction of the inhibitory mutants in the context of virus replication is then verified and further characterized using a tetracycline (Tet) regulon-based viral conditional expression system (36, 37).One intriguing aspect of herpesvirus morphogenesis is the transition of capsids from the nuclear to the cytoplasmic phase of virus morphogenesis. Two conserved nonstructural proteins, the homologues of the membrane protein pUL34 and its nuclear partner protein pUL31, form a nuclear egress complex (NEC) (18, 27, 42), which is required for primary envelopment and export of nuclear capsids to the cytoplasm (reviewed in references 24 and 25). Recent studies have revealed that the homologues of alphaherpesvirus pUL34 and pUL31, the M50 and the M53 gene products of the betaherpesvirus MCMV (pM50 and pM53, respectively) and the BFRF1 and the BFLF2 gene products of the gammaherpesvirus Epstein-Barr virus (EBV), apparently share the major functions of these two proteins. The lack of one or both proteins of the NEC generally results in the retention of viral capsids in the nucleus. This is lethal for beta- and gammaherpesvirus production (3, 9-11, 16, 18, 21, 27, 35, 42).The details of the mechanisms by which the NEC proteins mediate capsid export through the nuclear envelope are poorly understood. We (3, 21, 36, 38) and others (1, 19, 34) have started to dissect details of the NEC function using a genetic approach based on subtle mutagenesis of the respective genes. Analysis of the MCMV M50 gene by comprehensive mutagenesis localized two different functional sites. They were the M53 binding site within the N-terminal domain of M50, as well as the transmembrane region at its C terminus (3). Liang and Baines located the respective binding site in HSV-1 UL34 at aa 137 to 181 (19). Our approach, based on screens for DN mutants, identified a proline-rich sequence (aa 179 to 207) in the M50 gene product as an additional essential region (36). A recombinant virus expressing an M50 mutant lacking this site was defective in capsid egress from the nucleus despite the presence of the wt M50 protein. Consequently, the production of infectious particles after infection was reduced by more than 2 orders of magnitude. The UL34 homologues of alpha- and gammaherpesviruses lack a similar polyproline motif, but the result was confirmed by mutating the human cytomegalovirus (HCMV) homologue UL50 at the corresponding region, which is conserved within betaherpesviruses (36). The M50 mutants lacking the proline-rich motif still bind and colocalize to their respective NEC partner, pM53. Interestingly, Bjerke and coworkers also provided genetic evidence for the existence of at least one additional, yet-unknown, but essential functional entity in pUL34 of HSV-1, besides its known pUL31 binding activity, using a screen based on charged-cluster mutations (1). Further analysis of one of the noncomplementing charged-cluster mutants carrying the defect in the N-terminal domain of pUL34 also revealed a DN activity and suggested a new functional site involved in membrane curvature formation, together with the C-terminal domain of UL31 (34).The genetic analysis of M53 by Tn7-based linker scanning mutagenesis, followed by a cis complementation assay, localized the M50-binding site between aa 112 and 137 within the first of the four conserved regions (CRs) shared among the herpesvirus UL31 homologues (21). This analysis, together with a study we performed for further characterization of pM50/pM53 interaction, revealed that the large C-terminal part of pM53, comprising CR2 to -4, must carry at least one additional, yet-unknown, but essential functional site (21, 38).Here, we screened loss-of-function mutants of the MCMV M53 gene to retrieve M53 alleles with DN activity to localize this new functional domain. Mutants with a very strong inhibitory potential accumulated within CR4 of pM53 close to its C terminus. These CR4 mutants induced a block of capsid export from the nucleus. In addition, we could associate these mutations with the induction of a defect in capsid maturation and/or DNA packaging. These data suggested that pM53 is not only crucial for nuclear egress, but also involved in earlier steps of MCMV morphogenesis.     

一株高蛋白含量小球藻TX的分离鉴定及其诱变育种

【背景】小球藻由于蛋白含量高、营养丰富,在水产养殖上可直接作为鱼、虾、贝类的优质饵料。【目的】对从养殖环境中分离的小球藻进行诱变,选育生长快、蛋白含量高的突变株,为水产养殖天然饵料生产提供优良藻种资源。【方法】以从养殖环境中筛选的生长相对较快且蛋白含量较高的TX作为出发藻株,对该藻株进行分子鉴定,并对该藻株进行紫外诱变、甲基磺酸乙脂(ethyl methyl sulfonate,EMS)诱变和复合诱变,采用96孔板高通量筛选技术和递进式重复筛选方法选育高生物量、高蛋白突变株。【结果】经18SrRNA基因序列分析,TX鉴定为Chlorella sorokiniana,从540个可能的突变株中筛选到8个遗传稳定且生长较快的突变株,其中H10的总蛋白含量达64.2%,可溶性蛋白含量达0.44g/L,干重达0.72g/L,分别较出发藻株提高3.4%、15.8%和26.2%。【结论】突变株H10蛋白含量高且生长较快,可用于天然饵料生产。     

A novel member of the rho family of small GTP-binding proteins is specifically required for cytokinesis

Several members of the rho/rac family of small GTP-binding proteins are known to regulate the distribution of the actin cytoskeleton in various subcellular processes. We describe here a novel rac protein, racE, which is specifically required for cytokinesis, an actomyosin-mediated process. The racE gene was isolated in a molecular genetic screen devised to isolate genes required for cytokinesis in Dictyostelium. Phenotypic characterization of racE mutants revealed that racE is not essential for any other cell motility event, including phagocytosis, chemotaxis, capping, or development. Our data provide the first genetic evidence for the essential requirement of a rho-like protein, specifically in cytokinesis, and suggest a role for these proteins in coordinating cytokinesis with the mitotic events of the cell cycle.     

In silico analysis of Burkholderia pseudomallei genome sequence for potential drug targets

Recent advances in DNA sequencing technology have enabled elucidation of whole genome information from a plethora of organisms. In parallel with this technology, various bioinformatics tools have driven the comparative analysis of the genome sequences between species and within isolates. While drawing meaningful conclusions from a large amount of raw material, computer-aided identification of suitable targets for further experimental analysis and characterization, has also led to the prediction of non-human homologous essential genes in bacteria as promising candidates for novel drug discovery. Here, we present a comparative genomic analysis to identify essential genes in Burkholderia pseudomallei. Our in silico prediction has identified 312 essential genes which could also be potential drug candidates. These genes encode essential proteins to support the survival of B. pseudomallei including outer-inner membrane and surface structures, regulators, proteins involved in pathogenenicity, adaptation, chaperones as well as degradation of small and macromolecules, energy metabolism, information transfer, central/intermediate/miscellaneous metabolism pathways and some conserved hypothetical proteins of unknown function. Therefore, our in silico approach has enabled rapid screening and identification of potential drug targets for further characterization in the laboratory.     

Application of Mu in vitro transposition for high-precision mapping of protein–protein interfaces on a yeast two-hybrid platform

High-precision mapping of regions involved in protein–protein interfaces of interacting protein partners is an essential component on a path to understand various cellular functions. Transposon-based systems, particularly those involving in vitro reactions, offer exhaustive insertion mutant libraries and high-throughput platforms for many types of genetic analyses. We present here a genetic strategy to accurately map interacting protein regions at amino acid precision that is based on transposition-assisted construction, sampling, and analysis of a comprehensive insertion mutant library. The methodology integrates random pentapeptide mutagenesis of proteins, yeast two-hybrid screening, and high-resolution genetic footprinting. This straightforward strategy is general, and it provides a rapid and easy means to identify critical contact regions in proteins without the requirement of prior structural knowledge.     

Gene trap mutagenesis-based forward genetic approach reveals that the tumor suppressor OVCA1 is a component of the biosynthetic pathway of diphthamide on elongation factor 2

OVCA1 is a tumor suppressor identified by positional cloning from chromosome 17p13.3, a hot spot for chromosomal aberration in breast and ovarian cancers. It has been shown that expression of OVCA1 is reduced in some tumors and that it regulates cell proliferation, embryonic development, and tumorigenesis. However, the biochemical function of OVCA1 has remained unknown. Recently, we isolated a novel mutant resistant to diphtheria toxin and Pseudomonas exotoxin A from the gene trap insertional mutants library of Chinese hamster ovary cells. In this mutant, the Ovca1 gene was disrupted by gene trap mutagenesis, and this disruption well correlated with the toxin-resistant phenotype. We demonstrated direct evidence that the tumor suppressor OVCA1 is a component of the biosynthetic pathway of diphthamide on elongation factor 2, the target of bacterial ADP-ribosylating toxins. A functional genetic approach utilizing the random gene trap mutants library of mammalian cells should become a useful strategy to identify the genes responsible for specific phenotypes.     

Genome-wide LORE1 retrotransposon mutagenesis and high-throughput insertion detection in Lotus japonicus

Use of insertion mutants facilitates functional analysis of genes, but it has been difficult to identify a suitable mutagen and to establish large populations for reverse genetics in most plant species. The main challenge is developing efficient high-throughput procedures for both mutagenesis and identification of insertion sites. To date, only floral-dip T-DNA transformation of Arabidopsis has produced independent germinal insertions, thereby allowing generation of mutant populations from seeds of single plants. In addition, advances in insertion detection have been hampered by a lack of protocols, including software for automated data analysis, that take full advantage of high-throughput next-generation sequencing. We have addressed these challenges by developing the FSTpoolit protocol and software package, and here we demonstrate its efficacy by detecting 8935 LORE1 insertions in 3744 Lotus japonicus plants. The identified insertions show that the endogenous LORE1 retrotransposon is well suited for insertion mutagenesis due to homogenous gene targeting and exonic insertion preference. As LORE1 transposition occurs in the germline, harvesting seeds from a single founder line and cultivating progeny generates a complete mutant population. This ease of LORE1 mutagenesis, combined with the efficient FSTpoolit protocol, which exploits 2D pooling, Illumina sequencing and automated data analysis, allows highly cost-efficient development of a comprehensive reverse genetic resource.