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Known world-wide as the standard introductory text to this important and exciting area, the seventh edition of Gene Cloning and DNA Analysis addresses new and growing areas of research whilst retaining the philosophy of the previous editions. Assuming the reader has little prior knowledge of the subject, its importance, the principles of the techniques used and their applications are all carefully laid out, with over 250 clearly presented four-colour illustrations. In addition to a number of informative changes to the text throughout the book, the chapters on DNA sequencing and genome studies have been rewritten to reflect the continuing rapid developments in this area of DNA analysis: In depth description of the next generation sequencing methods and descriptions of their applications in studying genomes and transcriptomes New material on the use of ChiP-seq to locate protein-binding sites Extended coverage of the strategies used to assemble genome sequences Description of how the Neanderthal genome has been sequenced and what that sequence tells us about interbreeding between Neanderthals and Homo sapiens Gene Cloning and DNA Analysis remains an essential introductory text to a wide range of biological sciences students; including genetics and genomics, molecular biology, biochemistry, immunology and applied biology. It is also a perfect introductory text for any professional needing to learn the basics of the subject. All libraries in universities where medical, life and biological sciences are studied and taught should have copies available on their shelves.

Colloidal semiconductor nanocrystals are widely used as lumiphores in biological imaging because their luminescence is both strong and stable, and because they can be biofunctionalized. During synthesis, nanocrystals are typically passivated with hydrophobic organic ligands 1 , so it is then necessary either to replace these ligands or encapsulate the nanocrystals with hydrophilic moieties to make the lumiphores soluble in water. Finally, biological labels must be added to allow the detection of nucleic acids, proteins and specific cell types 2 , 3 , 4 , 5 , 6 , 7 , 8 . This multistep process is time- and labour-intensive and thus out of reach of many researchers who want to use luminescent nanocrystals as customized lumiphores. Here, we show that a single designer ligand—a chimeric DNA molecule—can controllably program both the growth and the biofunctionalization of the nanocrystals. One part of the DNA sequence controls the nanocrystal passivation and serves as a ligand, while another part controls the biorecognition. The synthetic protocol reported here is straightforward and produces a homogeneous dispersion of nanocrystal lumiphores functionalized with a single biomolecular receptor. The nanocrystals exhibit strong optical emission in the visible region, minimal toxicity and have hydrodynamic diameters of ∼6 nm, which makes them suitable for bioimaging 4 . We show that the nanocrystals can specifically bind DNA, proteins or cells that have unique surface recognition markers. Colloidal semiconductor nanocrystals are widely used in biological imaging, but existing synthesis techniques are difficult and require specialized expertise. Here it is shown that the use of DNA as a ligand allows a simpler synthetic protocol to be used, producing biofunctionalized nanocrystals that exhibit strong optical emission in the visible spectrum, minimal toxicity and small hydrodynamic diameter.

Concerns have been raised about the potential effects of transgenic introductions on the genetic diversity of crop landraces and wild relatives in areas of crop origin and diversification, as this diversity is considered essential for global food security. Direct effects on non-target species 1 , 2 , and the possibility of unintentionally transferring traits of ecological relevance onto landraces and wild relatives have also been sources of concern 3 , 4 . The degree of genetic connectivity between industrial crops and their progenitors in landraces and wild relatives is a principal determinant of the evolutionary history of crops and agroecosystems throughout the world 5 , 6 . Recent introductions of transgenic DNA constructs into agricultural fields provide unique markers to measure such connectivity. For these reasons, the detection of transgenic DNA in crop landraces is of critical importance. Here we report the presence of introgressed transgenic DNA constructs in native maize landraces grown in remote mountains in Oaxaca, Mexico, part of the Mesoamerican centre of origin and diversification of this crop 7 , 8 , 9 .

Known world-wide as the standard introductory text to this important and exciting area, the sixth edition of Gene Cloning and DNA Analysis addresses new and growing areas of research whilst retaining the philosophy of the previous editions. Assuming the reader has little prior knowledge of the subject, its importance, the principles of the techniques used and their applications are all carefully laid out, with over 250 clearly presented four-colour illustrations. In addition to a number of informative changes to the text throughout the book, the final four chapters have been significantly updated and extended to reflect the striking advances made in recent years in the applications of gene cloning and DNA analysis in biotechnology. Gene Cloning and DNA Analysis remains an essential introductory text to a wide range of biological sciences students; including genetics and genomics, molecular biology, biochemistry, immunology and applied biology. It is also a perfect introductory text for any professional needing to learn the basics of the subject. All libraries in universities where medical, life and biological sciences are studied and taught should have copies available on their shelves. \"… the book content is elegantly illustrated and well organized in clear-cut chapters and subsections… there is a Further Reading section after each chapter that contains several key references… What is extremely useful, almost every reference is furnished with the short but distinct author's remark.\" -Journal of Heredity, 2007 (on the previous edition).

To address food safety concerns of the public regarding the potential transfer of recombinant DNA (cry1Ab) and protein (Cry1Ab) into the milk of cows fed genetically modified maize (MON810), a highly specific and sensitive quantitative real-time PCR (qPCR) and an ELISA were developed for monitoring suspicious presence of novel DNA and Cry1Ab protein in bovine milk. The developed assays were validated according to the assay validation criteria specified in the European Commission Decision 2002/657/EC. The detection limit and detection capability of the qPCR and ELISA were 100 copies of cry1Ab μL⁻¹ milk and 0.4 ng mL⁻¹ Cry1Ab, respectively. Recovery rates of 84.9% (DNA) and 97% (protein) and low (<15%) imprecision revealed the reliable and accurate estimations. A specific qPCR amplification and use of a specific antibody in ELISA ascertained the high specificity of the assays. Using these assays for 90 milk samples collected from cows fed either transgenic (n = 8) or non-transgenic (n = 7) rations for 6 months, neither cry1Ab nor Cry1Ab protein were detected in any analyzed sample at the assay detection limits. [graphic removed]

Homologous recombination within plastids directs plastid genome transformation for foreign gene expression and study of plastid gene function. Though transgenes are generally efficiently targeted to their desired insertion site, unintended homologous recombination events have been observed during plastid transformation. To understand the nature and abundance of these recombination events, we analyzed transplastomic tobacco lines derived from three different plastid transformation vectors utilizing two different loci for foreign gene insertion. Two unintended recombinant plastid DNA species were formed from each regulatory plastid DNA element included in the transformation vector. Some of these recombinant DNA species accumulated to as much as 10-60% of the amount of the desired integrated transgenic sequence in T0 plants. Some of the recombinant DNA species undergo further, “secondary” recombination events, resulting in an even greater number of recombinant plastid DNA species. The abundance of novel recombinant DNA species was higher in T0 plants than in T1 progeny, indicating that the ancillary recombination events described here may have the greatest impact during selection and regeneration of transformants. A line of transplastomic tobacco was identified containing an antibiotic resistance gene unlinked from the intended transgene insertion as a result of an unintended recombination event, indicating that the homologous recombination events described here may hinder efficient recovery of plastid transformants containing the desired transgene.

Background and aimHepatitis B virus (HBV) C/D recombinant is predominant in Tibet in Western China. Although the geographical and ethnic distributions of the C/D recombinant have been described, the clinical implication and the characteristics of viral mutation in the basal core promoter (BCP)/pre-core (PC) region remain unclear.MethodsA total of 174 chronic HBV carriers, including 115 with chronic hepatitis B, 45 with liver cirrhosis, and 14 with hepatocellular carcinoma, were enrolled. Using next-generation sequencing, the S and BCP/PC genes were determined and analyzed.ResultsGenotypes B, C2, D, and C/D recombinant were detected in 1.1% (2/174), 19.5% (34/174), 0.6% (1/174) and 78.7% (137/174) of the patients, respectively. The clinical parameters and viral mutation frequency in the BCP/PC region were compared between C2- and C/D recombinant-infected patients. The distribution of C2 and C/D did not differ by disease status or liver function. Significantly higher levels of HBV DNA (6.7 ± 1.6 vs. 5.9 ± 1.5, p = 0.014), HBeAg (263.5 vs. 20.0, p = 0.013) and A1762T/G1764A double-mutations (81.0 vs. 61.8%, p = 0.018), but a lower frequency of G1896A stop mutation (33.6 vs. 76.5%, p < 0.001) was observed in patients with the C/D recombinant than in patients with genotype C2. The clonal frequencies of A1762T, G1764A, G1896A and A1846T were lower in patients with C/D than C2.ConclusionThe C/D recombinant has different mutation pattern in the BCP/PC region compared with genotype C2. The lower clonal frequencies of BCP/PC mutations may explain the higher levels of HBV DNA and HBeAg in C/D-infected patients.

Comprehensive analyses on promoters of four cellulase and one xylanase genes of Trichoderma reesei were performed expressing a single reporter uidA from Escherichia coli to construct highly functional cellulase-overproducing strains. GUS amount expressed under each promoter correlated entirely with each mRNA amount, suggesting that GUS production was controlled at the transcriptional level. The uidA transcript levels were much lower than the native gene mRNAs, but they were produced in proportion to the mRNA of native cellulase and xylanase genes driven by the same promoters except for the cbh2 promoter. Cellulose-degrading activity and protein amount was reduced in cbh1 and cbh2 disruptant mutants compared to the wild-type T. reesei PC-3-7 and other uidA transformants. The cbh1 disruptant strain was observed to produce more CBH II, EG I, EG III, and xylanases than native PC-3-7 and the other uidA transformants with the same amounts of protein in SDS-PAGE gels. This observation was further analyzed by measuring mRNA levels of cellulase and xylanase genes in the disruptants using quantitative real-time PCR. In the Pcbh1-gus, mRNA levels for cbh2 and egl1 genes were higher than those in native T. reesei PC-3-7 and all other disruptant strains. The cbh2 disruptant strain had the highest amount of cbh1 mRNA among the strains tested. Homologous integration of uidA at the egl1, egl3, and xyn3 loci was also found to cause a slight increased level of cbh1 mRNA, whereas mRNA levels for egl1, egl3, and xyn3 in all the disruptants were similar to those of T. reesei PC-3-7.

Genetically modified corn has been approved as an animal feed in several countries, but information about the fate of genetically modified DNA and protein in vivo is insufficient. Genetically modified corn Bt11 is developed by inserting a recombinant DNA sequence encoding insecticidal Cry1Ab protein from Bacillus thuringiensis subsp. kurstaki. We examined the presence of corn intrinsic and recombinant cry1Ab gene by PCR, and the Cry1Ab protein by immunological tests in the gastrointestinal contents of five genetically modified corn Bt11-fed and five nongenetically modified corn-fed pigs. Fragments of corn zein (242 bp), invertase (226 bp) and of ribulose-1,5-bisphosphate carboxylase/ oxygenase genes (1,028 bp) were detected in the gastrointestinal contents of both Bt11 and nongenetically modified corn-fed pigs. Fragments of recombinant cry1Ab gene (110 bp and 437 bp) were detected in the gastrointestinal contents of the Bt11-fed pigs but not in the control pigs. Neither corn intrinsic nor cry1Ab gene fragments were detected in the peripheral blood by PCR. The gastrointestinal contents were positive for Cry1Ab protein by ELISA, immunochromatography, and immunoblot; however, these methods did not work for blood and precluded conclusions about any potential absorption of the protein. These results suggest that ingested corn DNA and Cry1Ab protein were not totally degraded in the gastrointestinal tract, as shown by their presence in a form detectable by PCR or immunological tests.

A genetically modified Bt176 corn hybrid, which contains an insecticidal protein against the European corn borer, and its conventional, nonmodified counterpart were evaluated in 4 separate trials to verify substantial equivalence in feeding value and animal performance. Thirty-six individually kept laying hens and 3 replicates of 94 broiler chickens each, assigned to 12 cages, were fed 2 different hen and broiler diets containing either 60% conventional or 60% Bt176 corn. The nutrient compositions of the 2 corn hybrids and the 2 corn diets revealed no major differences. Furthermore, metabolism and performance data revealed no significant differences between the birds that received the conventional, nonmodified corn, and those that received the modified corn diets. The detection of the genetic modification, by PCR, in feed obtained from insect-resistant Bt corn, in tissues and products from animals fed Bt corn is described. In all evaluated chicken tissues of muscle, liver, and spleen, the corn-chloroplast ivr gene fragment was amplified. It can be deduced from these findings and from other studies that the transfer of DNA fragments into the body is a normal process that takes place constantly. Nevertheless, no recombinant plant DNA fragments such as recombinant bla or cry1A(b) fragments could be found. Bt-gene specific constructs from the Bt corn were not detected in any of the poultry samples, neither in organs, meat, nor eggs.