Optimizing the strain engineering process for industrial-scale production of bio-based molecules.

Biomanufacturing could contribute as much as ${\$}$30 trillion to the global economy by 2030. However, the success of the growing bioeconomy depends on our ability to manufacture high-performing strains in a time- and cost-effective manner. The Design-Build-Test-Learn (DBTL) framework has proven to be an effective strain engineering approach. Significant improvements have been made in genome engineering, genotyping, and phenotyping throughput over the last couple of decades that have greatly accelerated the DBTL cycles. However, to achieve a radical reduction in strain development time and cost, we need to look at the strain engineering process through a lens of optimizing the whole cycle, as opposed to simply increasing throughput at each stage. We propose an approach that integrates all 4 stages of the DBTL cycle and takes advantage of the advances in computational design, high-throughput genome engineering, and phenotyping methods, as well as machine learning tools for making predictions about strain scale-up performance. In this perspective, we discuss the challenges of industrial strain engineering, outline the best approaches to overcoming these challenges, and showcase examples of successful strain engineering projects for production of heterologous proteins, amino acids, and small molecules, as well as improving tolerance, fitness, and de-risking the scale-up of industrial strains.

Unique Polypharmacology Nuclear Receptor Modulator Blocks Inflammatory Signaling Pathways.

Obesity and rheumatic disease are mechanistically linked via chronic inflammation. The orphan receptor TREM-1 (triggering receptor expressed on myeloid cells-1) is a potent amplifier of proinflammatory and noninfectious immune responses. Here, we show that the pan modulator SR1903 effectively blocks TREM-1 activation. SR1903 emerged from a chemical series of potent RORγ inverse agonists, although unlike close structural analogues, it has modest agonist activity on LXR and weak repressive activity (inverse agonism) of PPARγ, three receptors that play essential roles in inflammation and metabolism. The anti-inflammatory and antidiabetic efficacy of this unique modulator in collagen-induced arthritis and diet-induced obesity mouse models is demonstrated. Interestingly, in the context of obesity, SR1903 aided in the maintenance of the thymic homeostasis unlike selective RORγ inverse agonists. SR1903 was well-tolerated following chronic administration, and combined, these data suggest that it may represent a viable strategy for treatment of both metabolic and inflammatory disease. More importantly, the ability of SR1903 to block LPS signaling suggests the potential utility of this unique polypharmacological modulator for treatment of innate immune response disorders.

Identification of potent RORß modulators: Scaffold variation.

We sought to develop RORß-selective probe molecules in order to investigate the function of the receptor in vitro and in vivo and its role in the pathophysiology of disease. To accomplish this, we modified a potent dual RORß/RORγ inverse agonist from the primary literature with the goal of improving selectivity for RORß vs RORγ. Truncation of the Western portion of the molecule ablated activity at RORγ and led to a potent series of RORß modulators. Continued exploration of this series investigated alternate replacement cores for the aminothiazole ring. Numerous suitable replacements were found during the course of our SAR investigations and are reported herein.

Structure-Activity Relationship of 2,4-Dichloro-N-(3,5-dichloro-4-(quinolin-3-yloxy)phenyl)benzenesulfonamide (INT131) Analogs for PPARγ-Targeted Antidiabetics.

Peroxisome proliferator-activated receptor γ (PPARγ) is a nuclear receptor central to fatty acid and glucose homeostasis. PPARγ is the molecular target for type 2 diabetes mellitus (T2DM) therapeutics TZDs (thiazolidinediones), full agonists of PPARγ with robust antidiabetic properties, which are confounded with significant side effects. Partial agonists of PPARγ, such as INT131 (1), have displayed similar insulin-sensitizing efficacy as TZDs, but lack many side effects. To probe the structure-activity relationship (SAR) of the scaffold 1, we synthesized 14 analogs of compound 1 which revealed compounds with higher transcriptional potency for PPARγ and identification of moieties of the scaffold 1 key to high transcriptional potency. The sulfonamide linker is critical to activity, substitutions at position 4 of the benzene ring A were associated with higher transcriptional activity, substitutions at position 2 aided in tighter packing and activity, and the ring type and size of ring A affected the degree of activity.