Human DNA profiling using PCR at polymorphic short tandem repeat (STR) loci followed by capillary electrophoresis (CE) size separation and length-based allele typing has been the standard in the forensic community for over 20 years. Over the last decade, Next-Generation Sequencing (NGS) matured rapidly, bringing modern advantages to forensic DNA analysis. The MiSeq FGx™ Forensic Genomics System, comprised of the ForenSeq™ DNA Signature Prep Kit, MiSeq FGx™ Reagent Kit, MiSeq FGx™ instrument and ForenSeq™ Universal Analysis Software, uses PCR to simultaneously amplify up to 231 forensic loci in a single multiplex reaction. Targeted loci include Amelogenin, 27 common, forensic autosomal STRs, 24 Y-STRs, 7 X-STRs and three classes of single nucleotide polymorphisms (SNPs). The ForenSeq™ kit includes two primer sets: Amelogenin, 58 STRs and 94 identity informative SNPs (iiSNPs) are amplified using DNA Primer Set A (DPMA; 153 loci); if a laboratory chooses to generate investigative leads using DNA Primer Set B, amplification is targeted to the 153 loci in DPMA plus 22 phenotypic informative (piSNPs) and 56 biogeographical ancestry SNPs (aiSNPs). High-resolution genotypes, including detection of intra-STR sequence variants, are semi-automatically generated with the ForenSeq™ software. This system was subjected to developmental validation studies according to the 2012 Revised SWGDAM Validation Guidelines. A two-step PCR first amplifies the target forensic STR and SNP loci (PCR1); unique, sample-specific indexed adapters or "barcodes" are attached in PCR2. Approximately 1736 ForenSeq™ reactions were analyzed. Studies include DNA substrate testing (cotton swabs, FTA cards, filter paper), species studies from a range of nonhuman organisms, DNA input sensitivity studies from 1ng down to 7.8pg, two-person human DNA mixture testing with three genotype combinations, stability analysis of partially degraded DNA, and effects of five commonly encountered PCR inhibitors. Calculations from ForenSeq™ STR and SNP repeatability and reproducibility studies (1ng template) indicate 100.0% accuracy of the MiSeq FGx™ System in allele calling relative to CE for STRs (1260 samples), and >99.1% accuracy relative to bead array typing for SNPs (1260 samples for iiSNPs, 310 samples for aiSNPs and piSNPs), with >99.0% and >97.8% precision, respectively. Call rates of >99.0% were observed for all STRs and SNPs amplified with both ForenSeq™ primer mixes. Limitations of the MiSeq FGx™ System are discussed. Results described here demonstrate that the MiSeq FGx™ System meets forensic DNA quality assurance guidelines with robust, reliable, and reproducible performance on samples of various quantities and qualities.
Background: Global analysis of the genome, transcriptome, and proteome is facilitated by the recent development of tools for large-scale, highly parallel analysis. We describe a novel nucleic acid amplification system that generates products by several methods. 3-Ribo-SPIA TM primes cDNA synthesis at the 3 polyA tail, and whole transcript (WT)-Ribo-SPIA primes cDNA synthesis across the full length of the transcripts and thus provides whole-transcriptome amplification, independent of the 3 polyA tail. Methods: We developed isothermal linear nucleic acid amplification systems, which use a single chimeric primer, for amplification of DNA (SPIA) and RNA (Ribo-SPIA). The latter allows mRNA amplification from as little as 1 ng of total RNA. Amplification efficiency was calculated based on the delta threshold cycle between nonamplified cDNA targets and amplified cDNA. The amounts and quality of total RNA and amplification products were determined after purification of the amplification products. GeneChip ® array gene expression profiling and real-time PCR were used to test the accuracy and reproducibility of the method. Quantification of cDNA products (before and after amplification) at the 2 loci along the transcripts was used to assess product length (for evaluation of the 3-initiated Ribo-SPIA) and equal representation throughout the length of the transcript (for evaluation of the whole transcript amplification system, WT-Ribo-SPIA TM ). Results: Ribo-SPIA-based global RNA amplification exhibited linearity over 6 orders of magnitude of tran-
Agrobacterium tumefaciens transfers a piece of its Ti plasmid DNA (transferred DNA or T-DNA) into plant cells during crown gall tumorigenesis. A. tumefaciens can transfer its T-DNA to a wide variety of hosts, including both dicotyledonous and monocotyledonous plants. We show that the host range of A. tumefaciens can be extended to include Saccharomyces cerevisiae. Additionally, we demonstrate that while T-DNA transfer into S. cerevisiae is very similar to T-DNA transfer into plants, the requirements are not entirely conserved. The Ti plasmid-encoded vir genes ofA. tumefaciens that are required for T-DNA transfer into plants are also required for T-DNA transfer into S. cerevisiae, as is vir gene induction. However, mutations in the chromosomal virulence genes of A. tumefaciens involved in attachment to plant cells have no effect on the efficiency of T-DNA transfer into S. cerevisiae. We also demonstrate that transformation efficiency is improved 500-fold by the addition of yeast telomeric sequences within the T-DNA sequence.Agrobacterium tumefaciens causes crown gall tumors in plants by transferring a segment of DNA (transferred DNA or T-DNA) from its tumor-inducing (Ti) plasmid to the nucleus of plant cells. The T-DNA becomes integrated into the plant nuclear genome where it functions to give rise to the characteristic tumor (reviewed in refs. 1 and 2). This process depends on the induction of a set of Ti plasmid-encoded virulence (vir) genes. vir genes are induced via the virA/virG two-component regulatory system which senses monosaccharides and phenolic compounds from wounded plants (reviewed in ref.3). The T-DNA is a single-stranded DNA molecule produced by a virDl/D2-encoded site-specific endonuclease that nicks within two 24-bp direct repeat sequences on the Ti plasmid (4). These repeats, termed border sequences, flank the T-DNA. Following cleavage and excision, the T-DNA is coated by the singlestranded DNA binding protein VirE2 (5), and the resulting T-DNA complex is transferred to the plant cell.The mechanism by which the T-DNA complex is transported through the inner and outer bacterial membranes and into the plant cell is not well understood. It is believed on the basis of several lines of evidence that the VirB proteins and VirD4 are involved in T-DNA transport (reviewed in ref. 6). Once the T-DNA complex enters the plant cell, it is targeted to the nucleus via nuclear localization sequences in the VirD2 and VirE2 proteins (7,8). Upon entering the nucleus, the T-DNA is integrated into the plant genome by illegitimate recombination, a process likely mediated by host factors (9).The study of host factors involved in T-DNA transfer has been difficult and would be greatly facilitated by the availability of a host model amenable to genetic manipulation. Given the similarities between T-DNA transfer and conjugative transfer of broad-host-range plasmids (reviewed in refs. 1, 6, and 10), we set out to determine if A. tumefaciens can transfer T-DNA to the yeast Saccharomyces cerevisiae. It has been demo...
The structure of I-Crel provides the first view of a protein encoded by a gene within an intron. This endonuclease recognizes a long DNA site approximately 20 base pairs in length and facilitates the lateral transfer of that intron. The protein exhibits a DNA-binding surface consisting of four antiparallel beta-strands that form a 20 A wide groove which is over 70 A long. The architecture of this fold is different from that of the TATA binding protein, TBP, which also contains an antiparallel beta-saddle. The conserved LAGLIDADG motif, which is found in many mobile intron endonucleases, maturases and inteins, forms a novel helical interface and contributes essential residues to the active site.
The 11 gene products of the Agrobacterium tumefaciens virB operon, together with the VirD4 protein, are proposed to form a membrane complex which mediates the transfer of T-DNA to plant cells. This study examined one putative component of that complex, VirB4. A deletion of the virB4 gene on the Ti plasmid pTiA6NC was constructed by replacing the virB4 gene with the kanamycin resistance-conferring nptII gene. The virB4 gene was found to be necessary for virulence on plants and for the transfer of IncQ plasmids to recipient cells of A. tumefaciens. Genetic complementation of the deletion strain by the virB4 gene under control of the virB promoter confirmed that the deletion was nonpolar on downstream virB genes. Genetic complementation was also achieved with the virB4 gene placed under control of the lac promoter, even though synthesis of the VirB4 protein from this promoter is far below wild-type levels. Having shown a role for the VirB4 protein in DNA transfer, lysine-439, found within the conserved mononucleotide binding domain of VirB4, was changed to a glutamic acid, methionine, or arginine by oligonucleotide-directed mutagenesis. virB4 genes bearing these mutations were unable to complement the virB4 deletion for either virulence or for IncQ transfer, showing that an intact mononucleotide binding site is necessary for the function of VirB4 in DNA transfer. The necessity of the VirB4 protein with an intact mononucleotide binding site for extracellular complementation of virE2 mutants was also shown. In merodiploid studies, lysine-439 mutations present in trans decreased IncQ plasmid transfer frequencies, suggesting that VirB4 functions within a complex to facilitate DNA transfer.
virB11, one of the 11 genes of the virB operon, is absolutely required for transport of T-DNA from Agrobacterium tumefaciens into plant cells. Previous studies reported that VirB11 is an ATPase with autophosphorylation activity and localizes to the inner membrane even though the protein does not contain the consensus N-terminal export sequence. In this report, we show that VirB11 localizes to the inner membrane even in the absence of other tumor-inducing (Ti) plasmid-encoded proteins. To facilitate the further characterization of VirB11, we purified this protein from the soluble fraction of an Escherichia coli extract by fusing VirB11 to the maltose-binding protein. The maltose-binding protein-VirB11 fusion was able to complement a virB11 deletion mutant of A. tumefaciens for tumor formation and also localized properly to the inner membrane of A. tumefaciens. The 72-kDa protein, purified from E. coli, exhibited no autophosphorylation, ATPase activity, or ATP-binding activity. To study the importance of the Walker nucleotide-binding site present in VirB11, mutations were generated to replace the conserved lysine residue with either alanine or arginine. Expression of the virB11K175A mutant gene resulted in an avirulent phenotype, and expression of the virB11K175R mutant gene gave rise to an attenuated virulence phenotype. Both mutant proteins were present at levels three to four times higher than that of VirB11 in the wild-type strain. The mutant genes did not exhibit a transdominant phenotype on tumor formation in bacteria that were expressing wild-type virB11. The mutant proteins also localized properly to the inner membrane of A. tumefaciens, but the VirB11K175R protein appeared to be unstable after lysis of the cells.The soil bacterium Agrobacterium tumefaciens causes the plant disease crown gall. The bacteria can infect dicotyledonous plants at a wound site and induce the formation of tumors at the site of infection. Virulent strains of A. tumefaciens contain a large tumor-inducing (Ti) plasmid that carries the factors responsible for formation of the crown gall tumors. The bacteria have the unusual property of being able to transfer a segment of DNA (T-DNA) from the Ti plasmid into the host plant cells. The T-DNA is integrated into the plant genome, and expression of the oncogenes present in the T-DNA results in formation of the tumor (for recent reviews, see references 26, 70, and 73).The genes required for the transfer of T-DNA into the recipient plant cells are divided into eight vir operons on the octopine-type Ti plasmid (54). These genes are expressed only when the bacteria are exposed to wounded plant cells as a result of the action of several plant signal molecules acting in concert with the virA and virG gene products. Once the vir genes have been expressed, the gene products act in a coordinated fashion to synthesize T-DNA strands and direct the transfer of the T-DNA into a recipient plant cell.The T-DNA and associated proteins are transported through the bacterial inner and outer membranes and thr...
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