Crystal structure of the 6-phosphogluconate dehydrogenase from Gluconobacter oxydans reveals tetrameric 6PGDHs as the crucial intermediate in the evolution of structure and cofactor preference in the 6PGDH family

Background: The enzyme 6-phosphogluconate dehydrogenase (6PGDH) is the central enzyme of the oxidative pentose phosphate pathway. Members of the 6PGDH family belong to different classes: either homodimeric enzymes assembled from long-chain subunits or homotetrameric ones assembled from short-chain subunits. Dimeric 6PGDHs bear an internal duplication absent in tetrameric 6PGDHs and distant homologues of the β-hydroxyacid dehydrogenase (βHADH) superfamily. Methods: We use X-ray crystallography to determine the structure of the apo form of the 6PGDH from Gluconobacter oxydans (Go6PGDH). We carried out a structural and phylogenetic analysis of short and long-chain 6PGDHs. We put forward an evolutionary hypothesis explaining the differences seen in oligomeric state vs. dinucleotide preference of the 6PGDH family. We determined the cofactor preference of Go6PGDH at different 6-phosphogluconate concentrations, characterizing the wild-type enzyme and three-point mutants of residues in the cofactor binding site of Go6PGDH. Results: The structural comparison suggests that the 6PG binding site initially evolved by exchanging C-terminal α-helices between subunits. An internal duplication event changed the quaternary structure of the enzyme from a tetrameric to a dimeric arrangement. The phylogenetic analysis suggests that 6PGDHs have spread from Bacteria to Archaea and Eukarya on multiple occasions by lateral gene transfer. Sequence motifs consistent with NAD+- and NADP+-specificity are found in the β2-α2 loop of dimeric and tetrameric 6PGDHs. Site-directed mutagenesis of Go6PGDH inspired by this analysis fully reverses dinucleotide preference. One of the mutants we engineered has the highest efficiency and specificity for NAD+ so far described for a 6PGDH. Conclusions: The family 6PGDH comprises dimeric and tetrameric members whose active sites are conformed by a C-terminal α-helix contributed from adjacent subunits. Dimeric 6PGDHs have evolved from the duplication-fusion of the tetrameric C-terminal domain before independent transitions of cofactor specificity. Changes in the conserved β2-α2 loop are crucial to modulate the cofactor specificity in Go6PGDH.

L'imagination poético-pratique dans l'identité narrative

Starting from a genesis of the concept of narrative identity, this article attemps to interpret the constitution process of our narrative identities through a systematic and synthetic review of the main contributions of the Ricœurian theory of imagination, from Freedom and Nature to Oneself as Another. In its complex imaginative constitution, narrative identity can then be characterized as a poetico-practical mix that mediates and puts in a dialectical relation two distinct functions of the imagination: a poetic and a practical one, which are themselves enlivened by a dialectic and an internal duplication.

NOTCH1 extracellular juxtamembrane expansion mutations in T-ALL

Heterodimerization domain (HD) mutations in NOTCH1 induce ligand-independent activation of the receptor and contribute to the pathogenesis of one-third of human T-cell lymphoblastic leukemias (T-ALLs). Here we report a novel class of activating mutations in NOTCH1 leading to aberrant activation of NOTCH1 signaling in T-cell lymphoblasts. These so-called juxtamembrane expansion (JME) alleles consist of internal duplication insertions in the vicinity of exon 28 of the NOTCH1 gene encoding the extracellular juxtamembrane region of the receptor. Notably, structure-function analysis of leukemia-derived and synthetic JME mutants demonstrated that the aberrant activation of NOTCH1 signaling is dependent on the number of residues introduced in the extracellular juxtamembrane region of the receptor and not on the specific amino acid sequence of these insertions. JME NOTCH1 mutants are effectively blocked by γ-secretase inhibitors and require an intact metalloprotease cleavage site for activation. Overall, these results show a novel mechanism of NOTCH1 activation in T-ALL and provide further insight on the mechanisms that control the activation of NOTCH1 signaling.

FLT3 and MLL intragenic abnormalities in AML reflect a common category of genotoxic stress

MLL rearrangements in acute myeloid leukemia (AML) include translocations and intragenic abnormalities such as internal duplication and breakage induced by topoisomerase II inhibitors. In adult AML, FLT3 internal tandem duplications (ITDs) are more common in cases with MLL intragenic abnormalities (33%) than those with MLL translocation (8%). Mutation/deletion involving FLT3 D835 are found in more than 20% of cases with MLL intragenic abnormalities compared with 10% of AML with MLL translocation and 5% of adult AML with normal MLL status. Real-time quantification of FLT3 in 141 cases of AML showed that all cases with FLT3 D835 express high level transcripts, whereas FLT3-ITD AML can be divided into cases with high-level FLT3 expression, which belong essentially to the monocytic lineage, and those with relatively low-level expression, which predominantly demonstrate PML-RARA and DEK-CAN. FLT3 abnormalities in CBF leukemias with AML1-ETO or CBFβ-MYH11 were virtually restricted to cases with variant CBFβ-MYH11 fusion transcripts and/or atypical morphology. These data suggest that the FLT3 and MLL loci demonstrate similar susceptibility to agents that modify chromatin configuration, including topoisomerase II inhibitors and abnormalities involving PML and DEK, with consequent errors in DNA repair. Variant CBFβ-MYH11 fusions and bcr3 PML-RARA may also be initiated by similar mechanisms.

Identification of the genomic locations of duplicate nucleotide sequences in maize by analysis of restriction fragment length polymorphisms.

While preparing a linkage map for maize based upon loci detected through the use of restriction fragment length polymorphisms (RFLPs), it was found that 62 of the 217 cloned maize sequences tested (29%) detected more than one fragment on genomic Southern blots. Thus, more than one nucleotide sequence is present within the maize genome which is in part homologous to each of these cloned sequences. The genomic locations of these ;;duplicate'' sequences were determined and it was found that they usually originated from different chromosomes. The process which produced them did not operate randomly as some pairs of chromosomes share many duplicate sequences while many other pairs share none. Furthermore, these shared duplicate sequences are generally arrayed in an ordered arrangement along these chromosomes. It is believed that chromosomal segments which contain several duplicate loci in a generally ordered arrangement must have had a common origin. The presence of these duplicated segments supports the idea that allopolyploidy may have been involved in the evolution of maize. Nevertheless, the duplicate loci do not primarily involve five pairs of chromosomes and thus, five pairs of homeologous chromosomes are not currently present within the maize genome. The data clearly indicate that maize is not a recent allotetraploid produced by hybridization between two individuals with similar genomic structures; however, the data are also consistent with the possibility of these shared duplicate chromosomal segments having been generated through internal duplication.