Comprehensive genetic screening programs have led to the identification of pathogenic methyl-CpGbinding protein 2 (MECP2) mutations in up to 95% of classical Rett syndrome (RTT) patients. This high rate of mutation detection can partly be attributed to specialised techniques that have enabled the detection of large deletions in a substantial fraction of otherwise mutation-negative patients. These cases would normally be missed by the routine PCR-based screening strategies. Here, we have identified large multi-exonic deletions in 12/149 apparently mutation-negative RTT patients using multiplex ligationdependent probe amplification (MLPA). These deletions were subsequently characterised using real-time quantitative PCR (qPCR) and long-range PCR with the ultimate aim of defining the exact nucleotide positions of the breakpoints and rearrangements. We detected an apparent deletion in one further patient using MLPA; however, this finding was contradicted by subsequent qPCR and long-range PCR results. The patient group includes an affected brother and sister with a large MECP2 deletion also present in their carrier mother. The X chromosome inactivation pattern of all female patients in this study was determined, which, coupled with detailed clinical information, allowed meaningful genotype -phenotype correlations to be drawn. This study reaffirms the view that large MECP2 deletions are an important cause of both classical and atypical RTT syndrome, and cautions that apparent deletions detected using high-throughput diagnostic techniques require further characterisation.
Tetrahydropyran rings are a common feature of complex polyketide natural products, but much remains to be learned about the enzymology of their formation. The enzyme SalBIII from the salinomycin biosynthetic pathway resembles other polyether epoxide hydrolases/cyclases of the MonB family, but SalBIII plays no role in the conventional cascade of ring opening/closing. Mutation in the salBIII gene gave a metabolite in which ring A is not formed. Using this metabolite in vitro as a substrate analogue, SalBIII has been shown to form pyran ring A. We have determined the X-ray crystal structure of SalBIII, and structure-guided mutagenesis of putative active-site residues has identified Asp38 and Asp104 as an essential catalytic dyad. The demonstrated pyran synthase activity of SalBIII further extends the impressive catalytic versatility of α+β barrel fold proteins.
Neoantimycins (NATs) are members of antimycin-types of depsipeptides with outstanding anticancer activities. We isolated NAT-A (1) and -F (2) from the fermentation extract of Streptomyces conglobatus. The NAT biosynthetic gene cluster ( nat BGC) was identified by genome sequencing and bioinformatics analysis. nat BGC includes two nonribosomal peptide synthetase (NRPS) and one polyketide synthase (PKS) gene, and a gene cassette (10 genes), of which the encoded enzymes share high homology to the ones responsible for 3-formamidosalicylate (3-FAS) biosynthesis in the antimycin biosynthetic pathway. Heterologous expression of the partial nat BGC without the 3-FAS gene cassette in the antimycin producer, Streptomyces albus J1074, results in the production of 1 and 2, suggesting that the nat BGC indeed directs NATs biosynthesis. Targeted in-frame deletion of the reductase gene ( natE) abolished the production of 1 and 2 but accumulated two NAT derivatives, the known NAT-H (3) and a new NAT-I (4). Biochemical verification demonstrated that the recombinant NatE indeed catalyzes an NADPH-dependent reaction of 3 or 4 to 1 or 2, respectively. Compound 3 presented significantly stronger activities against eight cancer cell lines than the ones using cisplatin, the clinical chemotherapy medicine. In particular, 3 displayed 559- and 57-fold higher activity toward human melanoma and cervix epidermoid carcinoma cells, respectively, compared with cisplatin. The new derivative, 4, was 1.5- to 10.9-fold more active than cisplatin toward five cancer cell lines. The evaluation of NATs biosynthesis depicted here will pave the way to generate new NAT derivatives through rational pathway engineering.
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