Stephan G. Zech

EP-2104R: A Fibrin-Specific Gadolinium-Based MRI Contrast Agent for Detection of Thrombus

Thrombus (blood clot) is implicated in a number of life threatening diseases, e.g., heart attack, stroke, pulmonary embolism. EP-2104R is an MRI contrast agent designed to detect thrombus by binding to the protein fibrin, present in all thrombi. EP-2104R comprises an 11 amino acid peptide derivatized with 2 GdDOTA-like moieties at both the C- and N-terminus of the peptide (4 Gd in total). EP-2104R was synthesized by a mixture of solid phase and solution techniques. The La(III) analogue was characterized by and 1D and 2D NMR spectroscopy and was found to have the expected structure. EP-2104R was found to be significantly more inert to Gd(III) loss than commercial contrast agents. At the most extreme conditions tested (pH 3, 60 degrees C, 96 hrs), less than 10% of Gd was removed from EP-2104R by a challenge with a DTPA based ligand, while the commercial contrast agents equilibrated within minutes to hours. EP-2104R binds equally to two sites on human fibrin (Kd = 1.7 +/- 0.5 microM) and has a similar affinity to mouse, rat, rabbit, pig, and dog fibrin. EP-2104R has excellent specificity for fibrin over fibrinogen (over 100-fold) and for fibrin over serum albumin (over 1000-fold). The relaxivity of EP-2104R bound to fibrin at 37 degrees C and 1.4 T was 71.4 mM(-1) s(-1) per molecule of EP-2104R (17.4 per Gd), about 25 times higher than that of GdDOTA measured under the same conditions. Strong fibrin binding, fibrin selectivity, and high molecular relaxivity enable EP-2104R to detect blood clots in vivo.

Fragment growing and linking lead to novel nanomolar lactate dehydrogenase inhibitors.

Lactate dehydrogenase A (LDH-A) catalyzes the interconversion of lactate and pyruvate in the glycolysis pathway. Cancer cells rely heavily on glycolysis instead of oxidative phosphorylation to generate ATP, a phenomenon known as the Warburg effect. The inhibition of LDH-A by small molecules is therefore of interest for potential cancer treatments. We describe the identification and optimization of LDH-A inhibitors by fragment-based drug discovery. We applied ligand based NMR screening to identify low affinity fragments binding to LDH-A. The dissociation constants (K(d)) and enzyme inhibition (IC(50)) of fragment hits were measured by surface plasmon resonance (SPR) and enzyme assays, respectively. The binding modes of selected fragments were investigated by X-ray crystallography. Fragment growing and linking, followed by chemical optimization, resulted in nanomolar LDH-A inhibitors that demonstrated stoichiometric binding to LDH-A. Selected molecules inhibited lactate production in cells, suggesting target-specific inhibition in cancer cell lines.

Novel Small Molecule Inhibitors of Choline Kinase Identified by Fragment-Based Drug Discovery

Choline kinase α (ChoKα) is an enzyme involved in the synthesis of phospholipids and thereby plays key roles in regulation of cell proliferation, oncogenic transformation, and human carcinogenesis. Since several inhibitors of ChoKα display antiproliferative activity in both cellular and animal models, this novel oncogene has recently gained interest as a promising small molecule target for cancer therapy. Here we summarize our efforts to further validate ChoKα as an oncogenic target and explore the activity of novel small molecule inhibitors of ChoKα. Starting from weakly binding fragments, we describe a structure based lead discovery approach, which resulted in novel highly potent inhibitors of ChoKα. In cancer cell lines, our lead compounds exhibit a dose-dependent decrease of phosphocholine, inhibition of cell growth, and induction of apoptosis at low micromolar concentrations. The druglike lead series presented here is optimizable for improvements in cellular potency, drug target residence time, and pharmacokinetic parameters. These inhibitors may be utilized not only to further validate ChoKα as antioncogenic target but also as novel chemical matter that may lead to antitumor agents that specifically interfere with cancer cell metabolism.

Abstract 2644: AP32788, a potent, selective inhibitor of EGFR and HER2 oncogenic mutants, including exon 20 insertions, in preclinical models

In non-small cell lung cancer (NSCLC), multiple classes of activating mutations have been identified in EGFR and HER2 that vary widely in their sensitivity to available tyrosine kinase inhibitors (TKIs). Erlotinib, gefitinib, and afatinib are approved for use in patients with the most common forms of EGFR activating mutations (ie, exon 19 deletions or L858R substitutions). However, no TKIs are approved for patients with EGFR activated by any other mutation, including exon 20 insertions or other uncommon substitutions, or for patients with any class of HER2 activating mutation (including exon 20 insertions). As inhibition of wild-type (WT) EGFR is associated with dose-limiting toxicities, a TKI that inhibits oncogenic EGFR and HER2 variants more potently than WT EGFR is more likely to be able to be dosed to efficacious levels. AP32788 is a potent inhibitor of all oncogenic forms of EGFR and HER2, including exon 20 insertions, with selectivity over WT EGFR. Activity of AP32788 and other TKIs was assessed by measuring viability of Ba/F3 cell lines engineered to express 20 mutant variants of EGFR (n = 14) or HER2 (n = 6): 4 EGFR variants containing a common activating mutation with or without a T790M resistance mutation, 8 EGFR/HER2 variants containing an exon 20 activating insertion (eg, EGFR ASV, HER2 YVMA), and 8 EGFR/HER2 variants containing other uncommon activating mutations (eg, EGFR G719A, HER2 G776V). Inhibition of WT EGFR was assessed by measuring effects on EGFR phosphorylation in cells (A431) that over-express WT EGFR. Consistent with their clinical activity, erlotinib and gefitinib generally only inhibited the 2 EGFR variants with common activating mutations more potently than WT EGFR (IC50s 71 and 56 nM, respectively), and afatinib generally only inhibited EGFR with common activating mutations or uncommon substitutions more potently than WT EGFR (IC50 4 nM). In contrast, AP32788 inhibited all 14 mutant variants of EGFR (IC50s 2.4-22 nM), and all 6 mutant variants of HER2 (IC50s 2.4-26 nM), more potently than it inhibited WT EGFR (IC50 35 nM), including all 8 variants with exon 20 activating insertions. In mice implanted with a patient-derived tumor containing an EGFR exon 20 activating insertion, or with engineered Ba/F3 cells containing a HER2 exon 20 activating insertion, once daily oral dosing of AP32788 induced regression of tumors at doses that were well tolerated (30-100 mg/kg). In vivo efficacy was associated with inhibition of EGFR signaling in the tumor. AP32788 potently inhibited all activated forms of EGFR and HER2 tested, including exon 20 insertions, more potently than WT EGFR, suggesting it may have the selectivity necessary to achieve efficacious levels of exposure in patients. A phase 1/2 clinical trial of AP32788 in NSCLC patients is planned. Citation Format: Francois Gonzalvez, Xiaotian Zhu, Wei-Sheng Huang, Theresa E. Baker, Yaoyu Ning, Scott D. Wardwell, Sara Nadworny, Sen Zhang, Biplab Das, Yongjin Gong, Matthew T. Greenfield, Hyun G. Jang, Anna Kohlmann, Feng Li, Paul M. Taslimi, Meera Tugnait, Yongjin Xu, Emily Y. Ye, Willmen W. Youngsaye, Stephan G. Zech, Yun Zhang, Tianjun Zhou, Narayana I. Narasimhan, David C. Dalgarno, William C. Shakespeare, Victor M. Rivera. AP32788, a potent, selective inhibitor of EGFR and HER2 oncogenic mutants, including exon 20 insertions, in preclinical models. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 2644.

Identification of novel rapamycin derivatives as low-level impurities in active pharmaceutical ingredients

We describe the identification of novel rapamycin derivatives present as low-level impurities in active pharmaceutical ingredients using an integrated, multidisciplinary approach. Rapamycin, a fermentation-derived natural product is itself used clinically and provides the starting material for several rapamycin analog drugs, typically used in oncology. LC-MS proved a sensitive means to analyze impurity profiles in batches of rapamycin. MS fragmentation was used to gain structural insight into these impurities, usually fermentation by-products, structurally very similar to rapamycin. In cases where MS fragmentation was unable to provide unambiguous structural identification, the impurities were isolated and purified using orthogonal HPLC methods. Using the higher mass sensitivity of small-volume NMR microprobes, submilligram amounts of isolated impurities were sufficient for further characterization by multidimensional NMR spectroscopy. Full assignment of the 1H and 13C NMR signals revealed the structure of these impurities at an atomic level. This systematic workflow enabled the identification of several novel rapamycin congeners from active pharmaceutical ingredient without the need for large-scale isolation of impurities. For illustration, two novel rapamycin derivatives are described in this study: 12-ethyl-rapamycin and 33-ethyl-rapamycin, which exemplify previously unreported modifications on the carbon skeleton of the rapamycin macrocycle. The methodologies described here can be of wide use for identification of closely related structures found; for example as fermentation by-products, metabolites or degradants of natural product-based drugs.

Abstract 3236: Small molecule inhibitors of choline kinase lead to reduced phosphocholine levels and induction of apoptosis in cancer cells

Proceedings: AACR 103rd Annual Meeting 2012‐‐ Mar 31‐Apr 4, 2012; Chicago, IL Choline Kinase (ChoK) catalyzes the synthesis of phosphocholine (pCho) as the first step in the Kennedy pathway towards synthesis of the major membrane phospholipid, phosphatidylcholine. Increased phosphorylation of choline is a hallmark of the malignant phenotype and ChoK over-expression (primarily ChoKβ) has been reported in a variety of human cancers including breast, lung, colorectal and prostate. These observations have recently motivated efforts to develop anti-cancer agents targeting ChoK. Here we summarize our efforts to further validate ChoKα as an oncogenic target by characterizing its tumorigenic potential and exploring the activity of novel small molecule inhibitors. We transduced the ChoKα gene into HEK293 cells to examine the effects of ChoK expression in vitro and in vivo. Under reduced serum conditions, over-expression of ChoK promoted cell growth, increased phospho-ERK and phospho-AKT levels, and reduced p21 levels. ChoKα, but not vector-expressing cells, formed tumors in immune-compromised mice and ChoKα expression levels were positively associated with tumor growth rates. Together, these data suggest that ChoK maintains proliferative pathways in the absence of growth factors, and itself provides an oncogenic driver capable of inducing tumor growth in the absence of other transforming mutations. Recently we identified a novel chemical series that inhibits ChoKα in both enzymatic and cellular assays. The binding of these inhibitors to ChoK protein was confirmed in surface plasmon resonance experiments. A representative member of this lead series, compound A, was characterized in more detail and demonstrated potent enzyme inhibition against ChoKα with an IC50 of 70 nM. Compound A also inhibited the growth of ChoKα -expressing breast cancer lines, MDA-MB-468 and MDA-MB-415, with GI50s of 7 and 2 uM respectively. In contrast, compound A exhibited much lower activity against the non-transformed breast epithelial cell line MCF-12A, with a GI50 >40 uM. Consistent with its effects on cell growth, pCho levels in MDA-MB-415 cells, as measured by NMR, were dose-dependently inhibited up to ∼80% by 24 hours with an IC50 of ∼750 nM. In MDA-MB-415 cells, but not MCF-12A cells, levels of apoptotic markers were increased at 24 hours with compound concentrations β5 uM. In summary, we demonstrated that small molecule inhibition of ChoK results in a dose-dependent decrease of pCho levels, inhibition of proliferation and induction of apoptosis in ChoKα expressing breast cancer cells. We established that exogenous expression of ChoKα in HEK293 cells drives both oncogenic transformation and constitutive activation of proliferative signaling pathways. Taken together, these data further validate ChoKα as a potential therapeutic target in cancer and support the continued investigation into the utility of ChoKα inhibitors as anti-oncogenic agents. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 3236. doi:1538-7445.AM2012-3236