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Fasnall

目录号 : GC25411

Fasnall, a thiophenopyrimidine, is a selective fatty acid synthase (FASN) inhibitor that shows potent anti-tumor activity.

Fasnall Chemical Structure

Cas No.:929978-58-5

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产品描述

Fasnall, a thiophenopyrimidine, is a selective fatty acid synthase (FASN) inhibitor that shows potent anti-tumor activity.

Fasnall and IU1 have different modes of metabolic variability in cancer cells.[2]

[1] Yazan Alwarawrah, et al. Cell Chem Biol. 2016 Jun 23;23(6):678-88. [2] Yang JS, et al. Int J Mol Sci. 2021 Dec 14;22(24):13437.

Chemical Properties

Cas No. 929978-58-5 SDF Download SDF
分子式 C19H22N4S 分子量 338.47
溶解度 DMSO: 13 mg/mL (38.41 mM);Water: Insoluble;Ethanol: 25 mg/mL (73.86 mM) 储存条件 Store at -20°C
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1 mM 2.9545 mL 14.7724 mL 29.5447 mL
5 mM 0.5909 mL 2.9545 mL 5.9089 mL
10 mM 0.2954 mL 1.4772 mL 2.9545 mL
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Research Update

Fasnall Induces Atypically Transient Stress Granules Independently of FASN Inhibition

iScience 2020 Sep 10;23(10):101550.PMID:33083719DOI:10.1016/j.isci.2020.101550.

Stress Granule formation has been linked to the resistance of some cancer cells to chemotherapeutic intervention. A number of studies have proposed that certain anti-tumor compounds promote cancer cell survival by inducing Stress Granule formation, leading to increased cellular fitness and apoptosis avoidance. Here we show that a potent fatty acid synthase inhibitor, Fasnall, known for its anti-tumor capabilities, triggers the formation of atypical Stress Granules, independently of fatty acid synthase inhibition, characterized by high internal mobility and rapid turnover.

Fasnall, a Selective FASN Inhibitor, Shows Potent Anti-tumor Activity in the MMTV-Neu Model of HER2(+) Breast Cancer

Cell Chem Biol 2016 Jun 23;23(6):678-88.PMID:27265747DOI:10.1016/j.chembiol.2016.04.011.

Many tumors are dependent on de novo fatty acid synthesis to maintain cell growth. Fatty acid synthase (FASN) catalyzes the final synthetic step of this pathway, and its upregulation is correlated with tumor aggressiveness. The consequences and adaptive responses of acute or chronic inhibition of essential enzymes such as FASN are not fully understood. Herein we identify Fasnall, a thiophenopyrimidine selectively targeting FASN through its co-factor binding sites. Global lipidomics studies with Fasnall showed profound changes in cellular lipid profiles, sharply increasing ceramides, diacylglycerols, and unsaturated fatty acids as well as increasing exogenous palmitate uptake that is deviated more into neutral lipid formation rather than phospholipids. We also showed that the increase in ceramide levels contributes to some extent in the mediation of apoptosis. Consistent with this mechanism of action, Fasnall showed potent anti-tumor activity in the MMTV-Neu model of HER2(+) breast cancer, particularly when combined with carboplatin.

Adipose Tissue-Breast Cancer Crosstalk Leads to Increased Tumor Lipogenesis Associated with Enhanced Tumor Growth

Int J Mol Sci 2021 Nov 2;22(21):11881.PMID:34769312DOI:10.3390/ijms222111881.

We sought to identify therapeutic targets for breast cancer by investigating the metabolic symbiosis between breast cancer and adipose tissue. To this end, we compared orthotopic E0771 breast cancer tumors that were in direct contact with adipose tissue with ectopic E0771 tumors in mice. Orthotopic tumors grew faster and displayed increased de novo lipogenesis compared to ectopic tumors. Adipocytes release large amounts of lactate, and we found that both lactate pretreatment and adipose tissue co-culture augmented de novo lipogenesis in E0771 cells. Continuous treatment with the selective FASN inhibitor Fasnall dose-dependently decreased the E0771 viability in vitro. However, daily Fasnall injections were effective only in 50% of the tumors, while the other 50% displayed accelerated growth. These opposing effects of Fasnall in vivo was recapitulated in vitro; intermittent Fasnall treatment increased the E0771 viability at lower concentrations and suppressed the viability at higher concentrations. In conclusion, our data suggest that adipose tissue enhances tumor growth by stimulating lipogenesis. However, targeting lipogenesis alone can be deleterious. To circumvent the tumor's ability to adapt to treatment, we therefore believe that it is necessary to apply an aggressive treatment, preferably targeting several metabolic pathways simultaneously, together with conventional therapy.

USP14 Regulates Cancer Cell Growth in a Fatty Acid Synthase-Independent Manner

Int J Mol Sci 2021 Dec 14;22(24):13437.PMID:34948233DOI:10.3390/ijms222413437.

Fatty acid synthase (FASN) plays an important role in cancer development, providing excess lipid sources for cancer growth by participating in de novo lipogenesis. Although several inhibitors of FASN have been developed, there are many limitations to using FASN inhibitors alone as cancer therapeutics. We therefore attempted to effectively inhibit cancer cell growth by using a FASN inhibitor in combination with an inhibitor of a deubiquitinating enzyme USP14, which is known to maintain FASN protein levels in hepatocytes. However, when FASN and USP14 were inhibited together, there were no synergistic effects on cancer cell death compared to inhibition of FASN alone. Surprisingly, USP14 rather reduced the protein levels and activity of FASN in cancer cells, although it slightly inhibited the ubiquitination of FASN. Indeed, treatment of an USP14 inhibitor IU1 did not significantly affect FASN levels in cancer cells. Furthermore, from an analysis of metabolites involved in lipid metabolism, metabolite changes in IU1-treated cells were significantly different from those in cells treated with a FASN inhibitor, Fasnall. These results suggest that FASN may not be a direct substrate of USP14 in the cancer cells. Consequently, we demonstrate that USP14 regulates proliferation of the cancer cells in a fatty acid synthase-independent manner, and targeting USP14 in combination with FASN may not be a viable method for effective cancer treatment.

Cellular fatty acid synthase is required for late stages of HIV-1 replication

Retrovirology 2017 Sep 29;14(1):45.PMID:28962653DOI:10.1186/s12977-017-0368-z.

Background: Like all viruses, HIV-1 relies on host systems to replicate. The human purinome consists of approximately two thousand proteins that bind and use purines such as ATP, NADH, and NADPH. By virtue of their purine binding pockets, purinome proteins are highly druggable, and many existing drugs target purine-using enzymes. Leveraging a protein affinity media that uses the purine-binding pocket to capture the entire purinome, we sought to define purine-binding proteins regulated by HIV-1 infection. Results: Using purinome capture media, we observed that HIV-1 infection increases intracellular levels of fatty acid synthase (FASN), a NADPH-using enzyme critical to the synthesis of de novo fatty acids. siRNA mediated knockdown of FASN reduced HIV-1 particle production by 80%, and treatment of tissue culture cells or primary PBMCs with Fasnall, a newly described selective FASN inhibitor, reduced HIV-1 virion production by 90% (EC50 = 213 nM). Despite the requirement of FASN for nascent virion production, FASN activity was not required for intracellular Gag protein production, indicating that FASN dependent de novo fatty acid biosynthesis contributes to a late step of HIV-1 replication. Conclusions: Here we show that HIV-1 replication both increases FASN levels and requires host FASN activity. We also report that Fasnall, a novel FASN inhibitor that demonstrates anti-tumor activity in vivo, is a potent and efficacious antiviral, blocking HIV-1 replication in both tissue culture and primary cell models of HIV-1 replication. In adults, most fatty acids are obtained exogenously from the diet, thus making FASN a plausible candidate for pharmacological intervention. In conclusion, we hypothesize that FASN is a novel host dependency factor and that inhibition of FASN activity has the potential to be exploited as an antiretroviral strategy.