Transposon Assisted Gene Insertion Technology (TAGIT): A Tool for Generating Fluorescent Fusion Proteins

We constructed a transposon (transposon assisted gene insertion technology, or TAGIT) that allows the random insertion of gfp (or other genes) into chromosomal loci without disrupting operon structure or regulation. TAGIT is a modified Tn5 transposon that uses Kan^R to select for insertions on the chromosome or plasmid, β-galactosidase to identify in-frame gene fusions, and Cre recombinase to excise the kan and lacZ genes in vivo. The resulting gfp insertions maintain target gene reading frame (to the 5′ and 3′ of gfp) and are integrated at the native chromosomal locus, thereby maintaining native expression signals. Libraries can be screened to identify GFP insertions that maintain target protein function at native expression levels, allowing more trustworthy localization studies. We here use TAGIT to generate a library of GFP insertions in the Escherichia coli lactose repressor (LacI). We identified fully functional GFP insertions and partially functional insertions that bind DNA but fail to repress the lacZ operon. Several of these latter GFP insertions localize to lacO arrays integrated in the E. coli chromosome without producing the elongated cells frequently observed when functional LacI-GFP fusions are used in chromosome tagging experiments. TAGIT thereby faciliates the isolation of fully functional insertions of fluorescent proteins into target proteins expressed from the native chromosomal locus as well as potentially useful partially functional proteins.     

Selection against tandem splice sites affecting structured protein regions

Background  

Alternative selection of splice sites in tandem donors and acceptors is a major mode of alternative splicing. Here, we analyzed whether in-frame tandem sites leading to subtle mRNA insertions/deletions of 3, 6, or 9 nucleotides are under natural selection.     

Translation initiation at alternate in-frame AUG codons in the rabies virus phosphoprotein mRNA is mediated by a ribosomal leaky scanning mechanism.

The phosphoprotein of rabies virus is a 297-amino-acid polypeptide encoded by the longest open reading frame of the P gene. Immunoprecipitation experiments using a monoclonal antiserum directed against the P protein detected the P protein and at least four additional shorter products in infected cells, cells transfected with a plasmid encoding the wild-type P protein, and purified virus (CVS strain). By means of deletion analyses, these proteins were shown to be translated from secondary downstream in-frame AUG initiation codons. Immunofluorescence experiments indicated that all these P products were found in the cytoplasm of transfected cells; however, the proteins initiated from the third, fourth, and fifth AUG codons were found mostly in the nucleus. Changes in the 5'-terminal region of the P mRNA (including site-specific mutations, deletions, and insertions) demonstrated that a leaky scanning mechanism is responsible for translation initiation of the P gene at several sites.     

Single-stranded hexameric linkers: a system for in-phase insertion mutagenesis and protein engineering

An efficient method for introducing two (or four) codons into a cloned gene has been developed. Single-stranded (ss) hexameric linkers are inserted into a plasmid linearized at cohesive-end restriction sites. The resultant 6 (or 12)-bp insertion creates a new 6-bp restriction site. Plasmids containing linker insertions are enriched by using biochemical selection, or selected by using a kanamycin-resistance (KmR) cassette (biological selection). A total of 57 new linkers have been designed, and compatible KmR cassettes flanked by eleven different restriction sites have been constructed. Two-codon insertions into the tetracycline-resistance (TcR) gene of pBR322 yielded a series of new plasmid vectors. Moreover, proteins with internally duplicated domains have been constructed from beta-lactamase (ApR) insertions into the ApR gene of pBR322. Some of the resulting "gemini" proteins retained the beta-lactamase activity.     

A system using convertible vectors for screening soluble recombinant proteins produced in Escherichia coli from randomly fragmented cDNAs

Protein insolubility is a major problem when producing recombinant proteins (e.g., to be used as antigens) from large cDNAs in Escherichia coli. Here, we describe a system using three convertible plasmid vectors to screen for soluble proteins produced in E. coli. This system experimentally identified any random cDNA fragments producing soluble protein domains. Shotgun fragments introduced into any of our three plasmids, which contain Gateway recombination sites, fused in-frame to the ORF of the protein tag. These plasmids produced N-terminal GST- and C-terminal three-frame-adaptive FLAG-tagged proteins, kanamycin-resistant gene-tagged proteins (which were pre-selected for in-frame fused cDNAs), or GFP-tagged fusion proteins. The latter is useful as a fluorescence indicator of protein folding. The Gateway recombination sites promote smooth conversion for enrichment of in-frame clones and facilitate both protein solubility assays and final production of proteins without the C-terminal tag. This high-throughput screening method is particularly useful for procedures that require the handling of many cDNAs in parallel.     

Three-dimensional reconstruction of protein networks provides insight into human genetic disease

To better understand the molecular mechanisms and genetic basis of human disease, we systematically examine relationships between 3,949 genes, 62,663 mutations and 3,453 associated disorders by generating a three-dimensional, structurally resolved human interactome. This network consists of 4,222 high-quality binary protein-protein interactions with their atomic-resolution interfaces. We find that in-frame mutations (missense point mutations and in-frame insertions and deletions) are enriched on the interaction interfaces of proteins associated with the corresponding disorders, and that the disease specificity for different mutations of the same gene can be explained by their location within an interface. We also predict 292 candidate genes for 694 unknown disease-to-gene associations with proposed molecular mechanism hypotheses. This work indicates that knowledge of how in-frame disease mutations alter specific interactions is critical to understanding pathogenesis. Structurally resolved interaction networks should be valuable tools for interpreting the wealth of data being generated by large-scale structural genomics and disease association studies.     

Site-selected insertion of the transposon Tc1 into a Caenorhabditis elegans myosin light chain gene.

We used the polymerase chain reaction to detect insertions of the transposon Tc1 into mlc-2, one of two Caenorhabditis elegans regulatory myosin light chain genes. Our goals were to develop a general method to identify mutations in any sequenced gene and to establish the phenotype of mlc-2 loss-of-function mutants. The sensitivity of the polymerase chain reaction allowed us to identify nematode populations containing rare Tc1 insertions into mcl-2. mlc-2::Tc1 mutants were subsequently isolated from these populations by a sib selection procedure. We isolated three mutants with Tc1 insertions within the mlc-2 third exon and a fourth strain with Tc1 inserted in nearby noncoding DNA. To demonstrate the generality of our procedure, we isolated two additional mutants with Tc1 insertions within hlh-1, the C. elegans MyoD homolog. All of these mutants are essentially wild type when homozygous. Despite the fact that certain of these mutants have Tc1 inserted within exons of the target gene, these mutations may not be true null alleles. All three of the mlc-2 mutants contain mlc-2 mRNA in which all or part of Tc1 is spliced from the pre-mRNA, leaving small in-frame insertions or deletions in the mature message. There is a remarkable plasticity in the sites used to splice Tc1 from these mlc-2 pre-mRNAs; certain splice sites used in the mutants are very different from typical eukaryotic splice sites.     

Multiple, non-allelic, intein-coding sequences in eukaryotic RNA polymerase genes

Background  

Inteins are self-splicing protein elements. They are translated as inserts within host proteins that excise themselves and ligate the flanking portions of the host protein (exteins) with a peptide bond. They are encoded as in-frame insertions within the genes for the host proteins. Inteins are found in all three domains of life and in viruses, but have a very sporadic distribution. Only a small number of intein coding sequences have been identified in eukaryotic nuclear genes, and all of these are from ascomycete or basidiomycete fungi.     

General mutagenesis of F plasmid TraI reveals its role in conjugative regulation

Bacteria commonly exchange genetic information by the horizontal transfer of conjugative plasmids. In gram-negative conjugation, a relaxase enzyme is absolutely required to prepare plasmid DNA for transit into the recipient via a type IV secretion system. Here we report a mutagenesis of the F plasmid relaxase gene traI using in-frame, 31-codon insertions. Phenotypic analysis of our mutant library revealed that several mutant proteins are functional in conjugation, highlighting regions of TraI that can tolerate insertions of a moderate size. We also demonstrate that wild-type TraI, when overexpressed, plays a dominant-negative regulatory role in conjugation, repressing plasmid transfer frequencies approximately 100-fold. Mutant TraI proteins with insertions in a region of approximately 400 residues between the consensus relaxase and helicase sequences did not cause conjugative repression. These unrestrictive TraI variants have normal relaxase activity in vivo, and several have wild-type conjugative functions when expressed at normal levels. We postulate that TraI negatively regulates conjugation by interacting with and sequestering some component of the conjugative apparatus. Our data indicate that the domain responsible for conjugative repression resides in the central region of TraI between the protein's catalytic domains.     

Methods for generating precise deletions and insertions in the genome of wild-type Escherichia coli: application to open reading frame characterization.

We have developed a new system of chromosomal mutagenesis in order to study the functions of uncharacterized open reading frames (ORFs) in wild-type Escherichia coli. Because of the operon structure of this organism, traditional methods such as insertional mutagenesis run the risk of introducing polar effects on downstream genes or creating secondary mutations elsewhere in the genome. Our system uses crossover PCR to create in-frame, tagged deletions in chromosomal DNA. These deletions are placed in the E. coli chromosome by using plasmid pKO3, a gene replacement vector that contains a temperature-sensitive origin of replication and markers for positive and negative selection for chromosomal integration and excision. Using kanamycin resistance (Kn(r)) insertional alleles of the essential genes pepM and rpsB cloned into the replacement vector, we calibrated the system for the expected results when essential genes are deleted. Two poorly understood genes, hdeA and yjbJ, encoding highly abundant proteins were selected as targets for this approach. When the system was used to replace chromosomal hdeA with insertional alleles, we observed vastly different results that were dependent on the exact nature of the insertions. When a Kn(r) gene was inserted into hdeA at two different locations and orientations, both essential and nonessential phenotypes were seen. Using PCR-generated deletions, we were able to make in-frame deletion strains of both hdeA and yjbJ. The two genes proved to be nonessential in both rich and glucose-minimal media. In competition experiments using isogenic strains, the strain with the insertional allele of yjbJ showed growth rates different from those of the strain with the deletion allele of yjbJ. These results illustrate that in-frame, unmarked deletions are among the most reliable types of mutations available for wild-type E. coli. Because these strains are isogenic with the exception of their deleted ORFs, they may be used in competition with one another to reveal phenotypes not apparent when cultured singly.     

Insertional mutagenesis of Bordetella pertussis adenylate cyclase.

We developed an improved method of linker insertion mutagenesis for introducing 2 or 16 codons into the Bordetella pertussis cyaA gene which encodes a calmodulin-dependent adenylate cyclase. A recombinant kanamycin resistance cassette, containing oligonucleotide linkers, was cloned in plasmids which carried a truncated cyaA gene, fused at its 3' end to the 5' end of the Escherichia coli lacZ gene, specifying the alpha-peptide. This construction permitted a double selection for in-frame insertions by using screening for kanamycin resistance and for lactose-positive phenotype, resulting from alpha-complementation. We showed that most of the two-amino acid insertions within the N-terminal moiety of the catalytic domain of adenylate cyclase abolished enzymatic activity and/or altered the stability of the protein. All two-amino acid insertions within the C-terminal part of adenylate cyclase resulted in fully stable and active enzymes. These results confirm the modular structure of the catalytic domain of adenylate cyclase, previously proposed on the basis of proteolytic studies. Two-amino acid insertions between residues 247-248 and 335-336 were shown to affect the calmodulin responsiveness of adenylate cyclase, suggesting that the corresponding region in the enzyme is involved in the binding of calmodulin or in the process of calmodulin activation. In addition, we have identified within the primary structure of adenylate cyclase several permissive sites which tolerate 16-amino acid insertions without interfering with the catalytic activity or calmodulin binding. By inserting foreign antigenic determinants into these permissive sites the resulting recombinant adenylate cyclase toxin could be used to deliver specific epitopes into antigen-presenting cells.     

Site-specific reflex response of ubiquitin to loop insertions

Predicting the structural effects of insertions in proteins by homology modeling remains a challenge. To investigate the molecular basis for conformational adaptations to insertions, ten mutants of ubiquitin were generated by introducing five different inserts, varying from five to 11 residues in size, at two different sites. Most insertion sequences were derived from homologous positions in structurally homologous ubiquitin-like proteins; to test sequence specificity, insertions were made into both homologous and non-homologous sites in ubiquitin. Structural inferences from NMR data suggest that each insertion site shows a reflex response to insertions: the sequence of the insertion has much less impact on structural adaptations than does the site of the insertion. Further, each site responds to insertions in a unique but consistent manner. For a given insertion site, different inserted sequences give rise to different stabilities, but the relationship between stability and sequence is not yet clear. However, the change in stability is similar for all insertions in a given site.     

A BlnI restriction map of the Salmonella typhimurium LT2 genome.

BlnI or AvrII (5'-CCTAGG) sites are very rare in the Salmonella typhimurium LT2 genome. BlnI was used to construct a physical map which was correlated with the genetic map by using three methods. First, Tn10 carries BlnI sites, and the extra restriction sites produced by 34 genetically mapped Tn10 insertions were physically mapped by using pulsed-field gel electrophoresis. Second, six genetically mapped Mud-P22 prophage insertions were used to assign BlnI fragments. Integration of Mud-P22 introduces 30 kb of DNA that can easily be detected by a "shift up" in all but the largest BlnI fragments. Finally, induced Mud-P22 insertions package more than 100 kb of genomic DNA adjacent to one side of the insertion. Some of the smaller BlnI fragments were localized by hybridization to a dot blot array of 52 lysates from induced Mud-P22 insertions. Of the 10 BlnI sites mapped, 6 probably occur in or near the 16S rRNA genes at about 55, 71, 83, 86, 88.5, and 89.5 min. There is one BlnI site in the 90-kb pSLT plasmid. Two additional BlnI fragments of about 7 and 4 kb have not been localized. The size of the genome was estimated as 4.78 Mb (+/- 0.1 Mb) excluding pSLT but including prophages Fels-1 and Fels-2. One BlnI fragment that maps between 55 and 59 min showed a 40-kb reduction in size in a strain cured of the approximately 40-kb Fels-2 prophage.     

Sequencing of pooled DNA samples (Pool-Seq) uncovers complex dynamics of transposable element insertions in Drosophila melanogaster

Transposable elements (TEs) are mobile genetic elements that parasitize genomes by semi-autonomously increasing their own copy number within the host genome. While TEs are important for genome evolution, appropriate methods for performing unbiased genome-wide surveys of TE variation in natural populations have been lacking. Here, we describe a novel and cost-effective approach for estimating population frequencies of TE insertions using paired-end Illumina reads from a pooled population sample. Importantly, the method treats insertions present in and absent from the reference genome identically, allowing unbiased TE population frequency estimates. We apply this method to data from a natural Drosophila melanogaster population from Portugal. Consistent with previous reports, we show that low recombining genomic regions harbor more TE insertions and maintain insertions at higher frequencies than do high recombining regions. We conservatively estimate that there are almost twice as many "novel" TE insertion sites as sites known from the reference sequence in our population sample (6,824 novel versus 3,639 reference sites, with on average a 31-fold coverage per insertion site). Different families of transposable elements show large differences in their insertion densities and population frequencies. Our analyses suggest that the history of TE activity significantly contributes to this pattern, with recently active families segregating at lower frequencies than those active in the more distant past. Finally, using our high-resolution TE abundance measurements, we identified 13 candidate positively selected TE insertions based on their high population frequencies and on low Tajima's D values in their neighborhoods.     

Genetics of P-element transposition into Drosophila melanogaster centric heterochromatin

Heterochromatin is a major component of higher eukaryotic genomes, but progress in understanding the molecular structure and composition of heterochromatin has lagged behind the production of relatively complete euchromatic genome sequences. The introduction of single-copy molecular-genetic entry points can greatly facilitate structure and sequence analysis of heterochromatic regions that are rich in repeated DNA. In this study, we report the isolation of 502 new P-element insertions into Drosophila melanogaster centric heterochromatin, generated in nine different genetic screens that relied on mosaic silencing (position-effect variegation, or PEV) of the yellow gene present in the transposon. The highest frequencies of recovery of variegating insertions were observed when centric insertions were used as the source for mobilization. We propose that the increased recovery of variegating insertions from heterochromatic starting sites may result from the physical proximity of different heterochromatic regions in germline nuclei or from the association of mobilizing elements with heterochromatin proteins. High frequencies of variegating insertions were also recovered when a potent suppressor of PEV (an extra Y chromosome) was present in both the mobilization and selection generations, presumably due to the effects of chromatin structure on P-element mobilization, insertion, and phenotypic selection. Finally, fewer variegating insertions were recovered after mobilization in females, in comparison to males, which may reflect differences in heterochromatin structure in the female and male germlines. FISH localization of a subset of the insertions confirmed that 98% of the variegating lines contain heterochromatic insertions and that these schemes produce a broader distribution of insertion sites. The results of these schemes have identified the most efficient methods for generating centric heterochromatin P insertions. In addition, the large collection of insertions produced by these screens provides molecular-genetic entry points for mapping, sequencing, and functional analysis of Drosophila heterochromatin.     

Characterization of functionally important sites in the bacteriophage Mu transposase protein

The 663 amino acid Mu transposase protein is absolutely required for Mu DNA transposition. Mutant proteins were constructed in vitro in order to locate regions of transposase that may be important for the catalysis of DNA transposition. Deletions in the A gene, which encodes the transposase, yielded two stable mutant proteins that aid in defining the end-specific DNA-binding domain. Linker insertion mutagenesis at eight sites in the Mu A gene generated two proteins, FF6 and FF14 (resulting from two and four amino acid insertions, respectively, at position 408), which were thermolabile for DNA binding in vitro at 43°C. However, transposition activity in vivo was severely reduced for all mutant proteins at 37°C, except those with insertions at positions 328 and 624. In addition, site-specific mutagenesis was performed to alter tyrosine 414, which is situated in a region that displays amino acid homology to the active sites of a number of nicking/closing enzymes. Tyrosine 414 may reside within an important, yet non-essential, site of transposase, as an aspartate-substituted protein had a drastically reduced frequency of transposition, while the remaining mutants yielded reduced, but substantial, frequencies of Mu transposition in vivo.