Browsing by Subject "Mutagenesis"
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Item Open Access Early postzygotic mutations contribute to de novo variation in a healthy monozygotic twin pair(B M J Group, 2014) Dal, G. M.; Ergüner, B.; Saǧıroǧlu, M. S.; Yüksel, B.; Onat, O. E.; Alkan C.; Özçelik, T.Background: Human de novo single-nucleotide variation (SNV) rate is estimated to range between 0.82-1.70×10-8 mutations per base per generation. However, contribution of early postzygotic mutations to the overall human de novo SNV rate is unknown. Methods: We performed deep whole-genome sequencing (more than 30-fold coverage per individual) of the whole-blood-derived DNA samples of a healthy monozygotic twin pair and their parents. We examined the genotypes of each individual simultaneously for each of the SNVs and discovered de novo SNVs regarding the timing of mutagenesis. Putative de novo SNVs were validated using Sanger-based capillary sequencing. Results: We conservatively characterised 23 de novo SNVs shared by the twin pair, 8 de novo SNVs specific to twin I and 1 de novo SNV specific to twin II. Based on the number of de novo SNVs validated by Sanger sequencing and the number of callable bases of each twin, we calculated the overall de novo SNV rate of 1.31×10-8 and 1.01×10-8 for twin I and twin II, respectively. Of these, rates of the early postzygotic de novo SNVs were estimated to be 0.34×10-8 for twin I and 0.04×10-8 for twin II. Conclusions: Early postzygotic mutations constitute a substantial proportion of de novo mutations in humans. Therefore, genome mosaicism resulting from early mitotic events during embryogenesis is common and could substantially contribute to the development of diseases.Item Open Access Mutational analysis of the major proline transporter (PrnB) of aspergillus nidulans(Taylor & Francis, 2003) Tavoularis, S. N.; Tazebay, U. H.; Diallinas, G.; Sideridou, M.; Rosa, A.; Scazzocchio, C.; Sophianopoulou, V.PrnB, the L-proline transporter of Aspergillus nidulans, belongs to the Amino acid Polyamine Organocation (APC) transporter family conserved in prokaryotes and eukaryotes. In silico analysis and limited biochemical evidence suggest that APC transporters comprise 12 transmembrane segments (TMS) connected with relatively short hydrophilic loops (L). However, very little is known on the structure-function relationships in APC transporters. This work makes use of the A. nidulans PrnB transporter to address structure-function relationships by selecting, constructing and analysing several prnB mutations. In the sample, most isolated missense mutations affecting PrnB function map in the borders of cytoplasmic loops with transmembrane domains. These are I119N and G120W in L2-TMS3, F278V in L6-TMS7, NRT378NRTNRT and PY382PYPY in L8-TMS9 and T456N in L10-TMS11. A single mutation (G403E) causing, however, a very weak phenotype, maps in the borders of an extracellular loop (L9-TMS10). An important role of helix TMS6 for proline binding and transport is supported by mutations K245L and, especially, F248L that clearly affect PrnB uptake kinetics. The critical role of these residues in proline binding and transport is further shown by constructing and analysing isogenic strains expressing selected prnB alleles fused to the gene encoding the Green Fluorescent Protein (GFP). It is shown that, while some prnB mutations affect proper translocation of PrnB in the membrane, at least two mutants, K245E and F248L, exhibit physiological cellular expression of PrnB and, thus, the corresponding mutations can be classified as mutations directly affecting proline binding and/or transport. Finally, comparison of these results with analogous studies strengthens conclusions concerning amino acid residues critical for function in APC transporters.Item Open Access Single-site mutation and secondary structure stability: an isodesmic reaction approach. The case of unnatural amino acid mutagenesis Ala→Lac(American Chemical Society, 2004) Cieplak, A. S.; Sürmeli, N. B.A method is described to evaluate backbone interactions in proteins via computational unnatural amino acid mutagenesis. Several N-acetyl polyalanyl amides (AcA nNH 2) were optimized in the representative helical (3 10-, 4 13-, and a "hybrid" κ-helix, n = 7, 9, 10, 14) and hairpin (two- and three-stranded antiparallel β-sheets with type I turns βααε, n =6, 9, 10) conformations, and extended conformers of N-acetyl polyalanyl methylamides (n = 2, 3) were used to derive multistranded β-sheet fragments. Subsequently, each residue of every model structure was substituted, one at a time, with L-lactic acid. The resulting mutant structures were again optimized, and group-transfer energies ΔE GT were obtained as heats of the isodesmic reactions: AcA nNHR + AcOMe → AcA xLacA yNHR + AcNHMe (R = H, C H 3). These group-transfer energies correlate with the degree of charge polarization of the substituted peptide linkages as measured by the difference Δe in H and O Mulliken populations in HN-C=O and with the H-bond distances in the "wild-type" structures. A good correlation obtains for the HF/3-21G and B3LYP/6-31G* group-transfer energies. The destabilization effects are interpreted in terms of loss of interstrand and intrastrand H-bonds, decrease in Lewis basicity of the C-O group, and O⋯O repulsion. On the basis of several comparisons of Ala → Lac ΔE GT's with heats of the NH → CH 2 substitutions, the latter contribution is estimated (B3LYP/6-31G*) to range between 1.5 and 2.4 kcal mol -1, a figure close to the recent experimental ΔδG° value of 2.6 kcal mol -1 (McComas, C. C.; Crowley, B. M.; Boger, D. L. J. Am. Chem. Soc. 2003, 125, 9314). The partitioning yields the following maximum values of the electronic association energy of H-bonds in the examined sample of model structures (B3LYP/6-31G* estimates): 3 10-helix D e = -1.7 kcal mol -1, α-helix D e = -3.8 kcal mol -1 β-sheet D e = -6.1 kcal mol -1. The premise of experimental evaluations of the backbone-backbone H-bonding that Ala → Lac substitution in proteins is isosteric (e.g., Koh, J. T.; Cornish, V. W.; Schultz, P. G. Biochemistry 1997, 36, 11314) is often but not always corroborated. Examination of the integrity of H-bonding pattern and ψ i, ψ i distribution identified several mutants with significant distortions of the "wild-type" structure resulting inter alia from the transitions between i, i + 3 and i, i + 4 H-bonding in helices, observed previously in the crystallographic studies of depsipeptides, (Ohyama, T.; Oku, H.; Hiroki, A.; Maekawa, Y.; Yoshida, M.; Katakai, R. Biopolymers 2000, 54, 875; Karle, I. L.; Das, C.; Balaram, P. Biopolymers 2001, 59, 276). Thus, the isodesmic reaction approach provides a simple way to gauge how conformation of the polypeptide chain and dimensions of the H-bonding network affect the strength of backbone-backbone C=O⋯HN bonds. The results indicate that the stabilization provided by such interactions increases on going from 3 10-helix to α-helix to β-sheet.