Increased cloning efficiency by cycle restriction−ligation (CRL)

Flux, toxicity, and expression costs generate complex genetic interactions in a metabolic pathway

Our ability to predict the impact of mutations on traits relevant for disease and evolution remains severely limited by the dependence of their effects on the genetic background and environment. Even when molecular interactions between genes are known, it is unclear how these translate to organism-level interactions between alleles. We therefore characterized the interplay of genetic and environmental dependencies in determining fitness by quantifying ~4000 fitness interactions between expression variants of two metabolic genes, starting from various environmentally modulated expression levels. We detect a remarkable variety of interactions dependent on initial expression levels and demonstrate that they can be quantitatively explained by a mechanistic model accounting for catabolic flux, metabolite toxicity, and expression costs. Complex fitness interactions between mutations can therefore be predicted simply from their simultaneous impact on a few connected molecular phenotypes.

PCR-Induced Sequence Alterations Hamper the Typing of Prehistoric Bone Samples for Diagnostic Achondroplasia Mutations

Achondroplasia (ACH) is a skeletal disorder (MIM100800) with an autosomal dominant Mendelian inheritance and complete penetrance. Here we report the screening of ancient bone samples for diagnostic ACH mutations. The diagnostic G-->A transition in the FGFR3 gene at cDNA position 1138 was detected in cloned polymerase chain reaction (PCR) products obtained from the dry mummy of the Semerchet tomb, Egypt (first dynasty, approximately 4,890-5,050 BP [before present]), and from an individual from Kirchheim, Germany (Merovingian period, approximately 1,300-1,500 BP), both of which had short stature. However, these mutations were also reproducibly observed in four ancient control samples from phenotypically healthy individuals (false-positives), rendering the reliable molecular typing of ancient bones for ACH impossible. The treatment of a false-positive DNA extract with uracil N-glycosylase (UNG) to minimize type 2 transitions (G-->A/C-->T) did not reduce the frequency of the false-positive diagnostic ACH mutations. Recently, it was suggested that ancient DNA extracts may induce mutations under PCR. Contemporary human template DNA from a phenotypically healthy individual was therefore spiked with an ancient DNA extract from a cave bear. Again, sequences with the diagnostic G-->A transition in the FGFR3 gene were observed, and it is likely that the false-positive G-->A transitions result from errors introduced during the PCR reaction. Amplifications in the presence of MnCl(2) indicate that position 1138 of the FGFR3 gene is particularly sensitive for mutations. Our data are in line with previously published results on the occurrence of nonrandom mutations in PCR products of contemporary human mitochondrial HVRI template DNA spiked with ancient DNA extracts.