Structural basis for the design of selective inhibitors for Schistosoma mansoni dihydroorotate dehydrogenase.

Trematode worms of the genus Schistosoma are the causing agents of schistosomiasis, a parasitic disease responsible for a considerable economic and healthy burden worldwide. In the present work, the characterization of the enzyme dihydroorotate dehydrogenase from Schistosoma mansoni (SmDHODH) is presented. Our studies demonstrated that SmDHODH is a member of class 2 DHODHs and catalyzes the oxidation of dihydroorotate into orotate using quinone as an electron acceptor by employing a ping-pong mechanism of catalysis. SmDHODH homology model showed the presence of all structural features reported for class 2 DHODH enzymes and reveal the presence of an additional protuberant domain predicted to fold as a flexible loop and absent in the other known class 2 DHODHs. Molecular dynamics simulations showed that the ligand-free forms of SmDHODH and HsDHODH undergo different rearrangements in solution. Well-known class 2 DHODH inhibitors were tested against SmDHODH and HsDHODH and the results suggest that the variable nature of the quinone-binding tunnel between human and parasite enzymes, as well as the differences in structural plasticity involving rearrangements of the N-terminal α-helical domain can be exploited for the design of SmDHODH selective inhibitors, as a strategy to validate DHODH as a drug target against schistosomiasis.

Author Correction: Jungle Express is a versatile repressor system for tight transcriptional control.

In the original version of this Article, an incorrect URL was provided in the Data Availability Statement regarding the deposition of plasmids listed in Supplementary Table 4. The correct URL is https://public-registry.jbei.org/folders/378 . This error has been corrected in both the PDF and HTML versions of the Article.

Jungle Express is a versatile repressor system for tight transcriptional control.

Tightly regulated promoters are essential for numerous biological applications, where strong inducibility, portability, and scalability are desirable. Current systems are often incompatible with large-scale fermentations due to high inducer costs and strict media requirements. Here, we describe the bottom-up engineering of 'Jungle Express', an expression system that enables efficient gene regulation in diverse proteobacteria. This system is guided by EilR, a multidrug-binding repressor with high affinity to its optimized operator and cationic dyes that act as powerful inducers at negligible costs. In E. coli, the engineered promoters exhibit minimal basal transcription and are inducible over four orders of magnitude by 1 µM crystal violet, reaching expression levels exceeding those of the strongest current bacterial systems. Further, we provide molecular insights into specific interactions of EilR with its operator and with two inducers. The versatility of Jungle Express opens the way for tightly controlled and efficient gene expression that is not restricted to host organism, substrate, or scale.

Berkeley Screen: a set of 96 solutions for general macromolecular crystallization.

Using statistical analysis of the Biological Macromolecular Crystallization Database, combined with previous knowledge about crystallization reagents, a crystallization screen called the Berkeley Screen has been created. Correlating crystallization conditions and high-resolution protein structures, it is possible to better understand the influence that a particular solution has on protein crystal formation. Ions and small molecules such as buffers and precipitants used in crystallization experiments were identified in electron density maps, highlighting the role of these chemicals in protein crystal packing. The Berkeley Screen has been extensively used to crystallize target proteins from the Joint BioEnergy Institute and the Collaborative Crystallography program at the Berkeley Center for Structural Biology, contributing to several Protein Data Bank entries and related publications. The Berkeley Screen provides the crystallographic community with an efficient set of solutions for general macromolecular crystallization trials, offering a valuable alternative to the existing commercially available screens.

Plant cell wall glycosyltransferases: High-throughput recombinant expression screening and general requirements for these challenging enzymes.

Molecular characterization of plant cell wall glycosyltransferases is a critical step towards understanding the biosynthesis of the complex plant cell wall, and ultimately for efficient engineering of biofuel and agricultural crops. The majority of these enzymes have proven very difficult to obtain in the needed amount and purity for such molecular studies, and recombinant cell wall glycosyltransferase production efforts have largely failed. A daunting number of strategies can be employed to overcome this challenge, including optimization of DNA and protein sequences, choice of expression organism, expression conditions, co-expression partners, purification methods, and optimization of protein solubility and stability. Hence researchers are presented with thousands of potential conditions to test. Ultimately, the subset of conditions that will be sampled depends on practical considerations and prior knowledge of the enzyme(s) being studied. We have developed a rational approach to this process. We devise a pipeline comprising in silico selection of targets and construct design, and high-throughput expression screening, target enrichment, and hit identification. We have applied this pipeline to a test set of Arabidopsis thaliana cell wall glycosyltransferases known to be challenging to obtain in soluble form, as well as to a library of cell wall glycosyltransferases from other plants including agricultural and biofuel crops. The screening results suggest that recombinant cell wall glycosyltransferases in general have a very low soluble:insoluble ratio in lysates from heterologous expression cultures, and that co-expression of chaperones as well as lysis buffer optimization can increase this ratio. We have applied the identified preferred conditions to Reversibly Glycosylated Polypeptide 1 from Arabidopsis thaliana, and processed this enzyme to near-purity in unprecedented milligram amounts. The obtained preparation of Reversibly Glycosylated Polypeptide 1 has the expected arabinopyranose mutase and autoglycosylation activities.