Petra Janning

Natural product–inspired cascade synthesis yields modulators of centrosome integrity

In biology-oriented synthesis, the scaffolds of biologically relevant compound classes inspire the synthesis of focused compound collections enriched in bioactivity. This criterion is, in particular, met by the scaffolds of natural products selected in evolution. The synthesis of natural product-inspired compound collections calls for efficient reaction sequences that preferably combine multiple individual transformations in one operation. Here we report the development of a one-pot, twelve-step cascade reaction sequence that includes nine different reactions and two opposing kinds of organocatalysis. The cascade sequence proceeds within 10-30 min and transforms readily available substrates into complex indoloquinolizines that resemble the core tetracyclic scaffold of numerous polycyclic indole alkaloids. Biological investigation of a corresponding focused compound collection revealed modulators of centrosome integrity, termed centrocountins, which caused fragmented and supernumerary centrosomes, chromosome congression defects, multipolar mitotic spindles, acentrosomal spindle poles and multipolar cell division by targeting the centrosome-associated proteins nucleophosmin and Crm1.

Identification of Acyl Protein Thioesterases 1 and 2 as the Cellular Targets of the Ras-Signaling Modulators Palmostatin B and M

Finding the target: activity-based proteomic profiling probes based on the depalmitoylation inhibitors palmostatin B and M have been synthesized and were found to target acyl protein thioesterase 1 (APT1) and 2 (APT2) in cells.

Expanded Click Conjugation of Recombinant Proteins with Ubiquitin‐Like Modifiers Reveals Altered Substrate Preference of SUMO2‐Modified Ubc9

Wrestling with SUMO: the chemical conjugation of proteins with small ubiquitin-like modifiers (SUMO) can be achieved by a copper(I)-catalyzed cycloaddition and unnatural amino acid mutagenesis. This approach overcomes previous restrictions related to the primary sequence of proteins and coupling conditions. Moreover, biochemical data suggests that this triazole linkage presents the modifier in a proper distance and orientation relative to the target protein.

PhzA/B catalyzes the formation of the tricycle in phenazine biosynthesis.

Phenazines are redox-active bacterial secondary metabolites that participate in important biological processes such as the generation of toxic reactive oxygen species and the reduction of environmental iron. Their biosynthesis from chorismic acid depends on enzymes encoded by the phz operon, but many details of the pathway remain unclear. It previously was shown that phenazine biosynthesis involves the symmetrical head-to-tail double condensation of two identical amino-cyclohexenone molecules to a tricyclic phenazine precursor. While this key step can proceed spontaneously in vitro, we show here that it is catalyzed by PhzA/B, a small dimeric protein of the Delta(5)-3-ketosteroid isomerase/nuclear transport factor 2 family, and we reason that this catalysis is required in vivo. Crystal structures in complex with analogues of the substrate and product suggest that PhzA/B accelerates double imine formation by orienting two substrate molecules and by neutralizing the negative charge of tetrahedral intermediates through protonation. HPLC-coupled NMR reveals that the condensation product rearranges further, which is probably important to prevent back-hydrolysis, and may also be catalyzed within the active site of PhzA/B. The rearranged tricyclic product subsequently undergoes oxidative decarboxylation in a metal-independent reaction involving molecular oxygen. This conversion does not seem to require enzymatic catalysis, explaining why phenazine-1-carboxylic acid is a major product even in strains that use phenazine-1,6-dicarboxylic acid as a precursor of strain-specific phenazine derivatives.

A Natural Product Inspired Tetrahydropyran Collection Yields Mitosis Modulators that Synergistically Target CSE1L and Tubulin

A Prins cyclization between a polymer-bound aldehyde and a homoallylic alcohol served as the key step in the synthesis of tetrahydropyran derivatives. A phenotypic screen led to the identification of compounds that inhibit mitosis (as seen by the accumulation of round cells with condensed DNA and membrane blebs). These compounds were termed tubulexins as they target the CSE1L protein and the vinca alkaloid binding site of tubulin.

Minimally Invasive Mutagenesis Gives Rise to a Biosynthetic Polyketide Library

Not in the public domain: Site-directed mutagenesis of megasynthases was the key to the generation of a library of polyketides in bacteria. Redox derivatizations are used to change the bioactivity profile of the compounds.

Covalent-Allosteric Kinase Inhibitors

Targeting and stabilizing distinct kinase conformations is an instrumental strategy for dissecting conformation-dependent signaling of protein kinases. Herein the structure-based design, synthesis, and evaluation of pleckstrin homology (PH) domain-dependent covalent-allosteric inhibitors (CAIs) of the kinase Akt is reported. These inhibitors bind covalently to a distinct cysteine of the kinase and thereby stabilize the inactive kinase conformation. These modulators exhibit high potency and selectivity, and represent an innovative approach for chemical biology and medicinal chemistry research.

Direct Binding Assay for the Detection of Type IV Allosteric Inhibitors of Abl

Abelson (Abl) tyrosine kinase is an important cellular enzyme that is rendered constitutively active in the breakpoint cluster region (BCR)-Abl fusion protein, contributing to several forms of leukemia. Although inhibiting BCR-Abl activity with imatinib shows great clinical success, many patients acquire secondary mutations that result in resistance to imatinib. Second-generation inhibitors such as dasatinib and nilotinib can overcome the majority of these mutations but fail to treat patients with an especially prevalent T315I mutation at the gatekeeper position of the kinase domain. However, a combination of nilotinib with an allosteric type IV inhibitor was recently shown to overcome this clinically relevant point mutation. In this study, we present the development of a direct binding assay that enables the straightforward detection of allosteric inhibitors which bind within the myristate pocket of Abl. The assay is amenable to high-throughput screening and exclusively detects the binding of ligands to this unique allosteric site.

Small-Molecule Target Engagement in Cells

Monitoring how, when, and where small molecules engage their targets inside living cells is a critical step in chemical biology and pharmacological research, because it enables compound efficacy and confirmation of mode of action to be assessed. In this mini-review we summarize the currently available methodologies to detect and prove direct target engagement in cells and offer a critical view of their key advantages and disadvantages. As the interest of the field shifts toward discovery and validation of high-quality agents, we expect that efforts to develop and refine these types of methodologies will also intensify in the near future.

The Ras Pathway Modulator Melophlin A Targets Dynamins

The Ras/mitogen-activated protein (MAP) kinase signal transduction pathway regulates numerous biological programs including cell growth and differentiation, and harbors several important anticancer-drug targets. Recent research, in particular inspired by systems biology approaches, revealed the importance of dynamic spatiotemporal regulation of and interplay between the Ras network members and their interaction with other signaling modules for fully functional Ras signaling. Because of their rapid, conditional, and reversible mode of action, small-molecule modulators of protein function are particularly suitable tools for the conditional analysis of such dynamic biological processes, and hold great promise for the study of biological systems. Therefore, the identification of novel small-molecule modulators of signaling through the Ras network and the identification of their molecular targets are of major interest. 6] The naturally occurring tetramic acids melophlin A and B (1 and 2, Scheme 1A) reverse the morphology of HRas-transformed NIH3T3 fibroblasts at a concentration of 5 mgmL 1 (that is, IC50= 14 mm). [7] However, the biological targets of the melophlins and their link to the Ras network have not been identified. Herein, we report the synthesis of a melophlin-inspired compound collection and a subsequent chemical proteomics investigation, which revealed that melo-