Project description:BACKGROUND:Recently, we have shown that peroxisomal protein expression was induced upon retinoic acid treatment in mouse embryonic stem cells during the process of neurogenesis. Thus, characterization of the respective promoter could elucidate the molecular aspects of transcriptional regulation of this gene. METHODS:Using the conventional software programs for promoter prediction, a putative promoter region was identified approximately 561 bp upstream of the peroxisomal protein coding sequence. In order to clone this region with a GC-content of 71.01%, a cocktail of ammonium sulfate buffer supplied with two additive components, betaine and dimethyl sulfoxide, and a high concentration of MgCl(2) was used. RESULTS:The modulated polymerase chain reaction composition significantly improved the amplification of GC-rich DNA target sequences. Improved amplification of this region was due to reduction in the formation of secondary structures by the GC-rich region. CONCLUSION:Therefore, this polymerase chain reaction composition could be generally used to facilitate the amplification of other GC-rich DNA sequences as verified by amplification of different GC rich regions.

Project description:Mammalian cells that have undergone gene amplification and/or gene rearrangement have been used as resources to gain insight into the questions of chromosome structure and dynamics. The multidrug resistant murine cell line J7.V2-1 has been shown previously to contain two distinct forms of the highly amplified mdr2 gene, a member of the mouse gene family responsible for the multidrug resistant (MDR) phenotype [Kirschner, L. S. (1995) DNA Cell Biol. 14, 47-59]. Characterization of both forms of the gene revealed that one form corresponded to the wild-type structure of the gene, whereas the other represented a rearrangement. Investigation of this altered gene demonstrated a deletion of 1.6 kb of the wild-type sequence, and replacement of this region with a poly(AT) tract that appears to have been generated de novo. Analysis of the native sequence in this region demonstrated the absence of repetitive elements, but was notable for the presence of two long stretches of polypurine: polypyrimidine strand asymmetry. Analysis of mdr2 transcripts in this cell line revealed that nearly all of the mRNA is transcribed from the rearranged form of the gene. This message is unable to code for a functional mdr2 gene product, owing to a deletion of the fourth exon during this event. Mechanisms of the rearrangement, as well as the significance of this curious effect on transcription, are discussed.

Project description:BACKGROUND:Polymerase chain reaction (PCR) is an extremely sensitive method that often demands optimization, especially when difficult templates need to be amplified. The aim of the present study was to optimize the PCR conditions for amplification of the epidermal growth factor receptor (EGFR) promoter sequence featuring an extremely high guanine-cytosine (GC) content in order to detect single nucleotide polymorphisms -216G>T and -191C>A. METHODS:Genomic DNA used for amplification was extracted from formalin-fixed paraffin-embedded lung tumor tissue and PCR products were detected by agarose gel electrophoresis. RESULTS:Results showed that addition of 5% dimethyl sulfoxide (DMSO), as well as DNA concentration in PCR reaction of at least 2 ?g/ml, were necessary for successful amplification. Due to high GC content, optimal annealing temperature was 7°C higher than calculated, while adequate MgCl2 concentration ranged from 1.5 to 2.0 mM. CONCLUSION:In conclusion, EGFR promoter region is a difficult PCR target, but it could be amplified after optimization of MgCl2 concentration and annealing temperature in the presence of DMSO and the DNA template of acceptable concentration.

Project description:A theoretical analysis is presented with experimental confirmation to conclusively demonstrate the critical role that annealing plays in efficient PCR amplification of GC-rich templates. The analysis is focused on the annealing of primers at alternative binding sites (competitive annealing) and the main result is a quantitative expression of the efficiency (eta) of annealing as a function of temperature (T(A)), annealing period (t(A)), and template composition. The optimal efficiency lies in a narrow region of T(A) and t(A) for GC-rich templates and a much broader region for normal GC templates. To confirm the theoretical findings, the following genes have been PCR amplified from human cDNA template: ARX and HBB (with 78.72% and 52.99% GC, respectively). Theoretical results are in excellent agreement with the experimental findings. Optimum annealing times for GC-rich genes lie in the range of 3-6s and depend on annealing temperature. Annealing times greater than 10s yield smeared PCR amplified products. The non-GC-rich gene did not exhibit this sensitivity to annealing times. Theory and experimental results show that shorter annealing times are not only sufficient but can actually aid in more efficient PCR amplification of GC-rich templates.

Project description:Single-cell genome sequencing has the potential to allow the in-depth exploration of the vast genetic diversity found in uncultured microbes. We used the marine cyanobacterium Prochlorococcus as a model system for addressing important challenges facing high-throughput whole genome amplification (WGA) and complete genome sequencing of individual cells.We describe a pipeline that enables single-cell WGA on hundreds of cells at a time while virtually eliminating non-target DNA from the reactions. We further developed a post-amplification normalization procedure that mitigates extreme variations in sequencing coverage associated with multiple displacement amplification (MDA), and demonstrated that the procedure increased sequencing efficiency and facilitated genome assembly. We report genome recovery as high as 99.6% with reference-guided assembly, and 95% with de novo assembly starting from a single cell. We also analyzed the impact of chimera formation during MDA on de novo assembly, and discuss strategies to minimize the presence of incorrectly joined regions in contigs.The methods describe in this paper will be useful for sequencing genomes of individual cells from a variety of samples.

Project description:Next-generation-sequencing (NGS) has revolutionized the field of genome assembly because of its much higher data throughput and much lower cost compared with traditional Sanger sequencing. However, NGS poses new computational challenges to de novo genome assembly. Among the challenges, GC bias in NGS data is known to aggravate genome assembly. However, it is not clear to what extent GC bias affects genome assembly in general. In this work, we conduct a systematic analysis on the effects of GC bias on genome assembly. Our analyses reveal that GC bias only lowers assembly completeness when the degree of GC bias is above a threshold. At a strong GC bias, the assembly fragmentation due to GC bias can be explained by the low coverage of reads in the GC-poor or GC-rich regions of a genome. This effect is observed for all the assemblers under study. Increasing the total amount of NGS data thus rescues the assembly fragmentation because of GC bias. However, the amount of data needed for a full rescue depends on the distribution of GC contents. Both low and high coverage depths due to GC bias lower the accuracy of assembly. These pieces of information provide guidance toward a better de novo genome assembly in the presence of GC bias.

Project description:Recent evidence demonstrates that novel protein-coding genes can arise de novo from non-genic loci. This evolutionary innovation is thought to be facilitated by the pervasive translation of non-genic transcripts, which exposes a reservoir of variable polypeptides to natural selection. Here, we systematically characterize how these de novo emerging coding sequences impact fitness in budding yeast. Disruption of emerging sequences is generally inconsequential for fitness in the laboratory and in natural populations. Overexpression of emerging sequences, however, is enriched in adaptive fitness effects compared to overexpression of established genes. We find that adaptive emerging sequences tend to encode putative transmembrane domains, and that thymine-rich intergenic regions harbor a widespread potential to produce transmembrane domains. These findings, together with in-depth examination of the de novo emerging YBR196C-A locus, suggest a novel evolutionary model whereby adaptive transmembrane polypeptides emerge de novo from thymine-rich non-genic regions and subsequently accumulate changes molded by natural selection.

Project description:BACKGROUND:Resection of the primary tumor is recommended for symptom relief in de novo stage IV breast cancer. We explored whether local surgery could provide a survival benefit in these patients and attempted to characterize the population that could benefit from surgery. METHODS:Metastatic Breast cancer patients (N?=?313) with intact primary tumor between January 2006 and April 2013 were separated into two groups according to whether or not they had undergone surgery. The difference in characteristics between the two groups was analyzed using chi-square test, Fisher's exact test and Mann-Whitney test. Univariable and multivariable Cox regression and stratified survival analysis were used to assess the effect of surgery on survival. RESULTS:Of the 313 patients, 188 (60.1%) underwent local surgery. Patients with local surgery had a 47% reduction in mortality risk vs. those with no surgery (median survival 78 months vs. 37 months; HR?=?0.53; 95% CI, 0.36-0.78) after adjustment for clinical and tumor characteristics. Stratified survival analysis showed that patients with bone metastasis alone (and primary tumor ?5 cm), soft tissue metastasis, or???3 metastasis sites benefit from surgery. CONCLUSION:Surgical resection of the primary tumor can improve survival in selected de novo stage IV breast cancer patients.

Project description:A point mutation in Prnp that converts tyrosine (Y) at position 145 into a stop codon leading to a truncated prion molecule as found in an inherited transmissible spongiform encephalopathy (TSE), Gertsmann-Sträussler-Scheincker syndrome, suggests that the N-terminus of the molecule (spanning amino acids 23-144) likely plays a critical role in prion misfolding as well as in protein-protein interactions. We hypothesized that Y145Stop molecule represents an unstable part of the prion protein that is prone to spontaneous misfolding. Utilizing protein misfolding cyclic amplification (PMCA) we show that the recombinant polypeptide corresponding to the Y145Stop of sheep and deer PRNP can be in vitro converted to PK-resistant PrP (Sc) in presence or absence of preexisting prions. In contrast, recombinant protein full-length PrP (C) did not show a propensity for spontaneous conformational conversion to protease resistant isoforms. Further, we show that seeded or spontaneously misfolded Y145Stop molecules can efficiently convert purified mammalian PrP (C) into protease resistant isoforms. These results establish that the N-terminus of PrP (C) molecule corresponding to residues 23-144 plays a role in seeding and misfolding of mammalian prions.

Project description:Human fibroblasts can be induced into pluripotent stem cells (iPS cells), but the reprogramming efficiency is quite low. Here, we screened a panel of candidate factors in the presence of OCT4, SOX2, KLF4 and c-MYC in an effort to improve the reprogramming efficiency from human adult fibroblasts. We found that p53 siRNA and UTF1 enhanced the efficiency of iPS cell generation up to 100-fold, even when the oncogene c-MYC was removed from the combinations. We further demonstrated that by using a novel combination of the four factors OCT4, SOX2, KLF4 and UTF1, iPS cells could be generated at a frequency at least 10 times higher than using the original four reprogramming factors without c-MYC. The iPS cells generated in this work have a similar gene expression profile and differentiation potential as human embryonic stem (hES) cells. In conclusion, two novel supporting factors that increase the efficiency of direct reprogramming have been identified, and a more-efficient method for the generation of human iPS cells has been developed in the absence of the oncogene c-MYC. Keywords: cell type comparison Total RNA from hFSF, hAFF, hES cells (H1, H7) and 7 established iPS cell lines were labeled with Cy5, hybridized to a human Oligo Microarray (Phalanx Human Whole Genome OneArray™, Phalanx Biotech) according to the manufacturer's protocol. Three technical repetitions were performed. After hybridization, arrays were scanned using GenePix 4000B scanner (Molecular Devices) and processed using the GenePix Pro 6.0 software (Molecular Devices). After removing control probes, a 14/33 presence call (SNR>=5 and foreground-background>0) was used to filter probes for the 33 microarrays, resulting in 12311 probes for further quantile normalization.