SARS-CoV-2 infects human cells through its surface spike glycoprotein (SgP), which relies on host cell surface heparan sulfate (HS) proteoglycans that facilitate interaction with the ACE2 receptor. Targeting this process could lead to inhibitors of early steps in viral entry. Screening a microarray of 24 HS oligosaccharides against recombinant S1 and receptor-binding domain (RBD) proteins led to identification of only eight sequences as potent antagonists; results that were supported by detailed dual-filter computational studies. Competitive studies using the HS microarray suggested almost equivalent importance of IdoA2S–GlcNS6S and GlcNS3S structures, which were supported by affinity studies. Exhaustive virtual screening on a library of >93 000 sequences led to a novel pharmacophore with at least two 3- O -sulfated GlcN residues that can engineer unique selectivity in recognizing the RBD. This work puts forward the key structural motif in HS that should lead to potent and selective HS or HS-like agents against SARS-CoV-2.
The insulin-like growth factor-1 receptor (IGF-1R) is a receptor tyrosine kinase (RTK) that plays critical roles in cancer. Microarray, computational, thermodynamic, and cellular imaging studies reveal that activation of IGF-1R by its cognate ligand IGF1 is inhibited by shorter, soluble heparan sulfate (HS) sequences (e.g., HS06), whereas longer polymeric chains do not inhibit the RTK, a phenomenon directly opposed to the traditional relationship known for GAG-protein systems. The inhibition arises from smaller oligosaccharides binding in a unique pocket in the IGF-1R ectodomain, which competes with the natural cognate ligand IGF1. This work presents a highly interesting observation on preferential and competing inhibition of IGF-1R by smaller sequences, whereas polysaccharides are devoid of this function. These insights will be of major value to glycobiologists and anti-cancer drug discoverers.
The insulin‐like growth factor‐1 receptor (IGF‐1R) is a receptor tyrosine kinase (RTK) that plays critical roles in cancer. Microarray, computational, thermodynamic, and cellular imaging studies reveal that activation of IGF‐1R by its cognate ligand IGF1 is inhibited by shorter, soluble heparan sulfate (HS) sequences (e.g., HS06), whereas longer polymeric chains do not inhibit the RTK, a phenomenon directly opposed to the traditional relationship known for GAG‐protein systems. The inhibition arises from smaller oligosaccharides binding in a unique pocket in the IGF‐1R ectodomain, which competes with the natural cognate ligand IGF1. This work presents a highly interesting observation on preferential and competing inhibition of IGF‐1R by smaller sequences, whereas polysaccharides are devoid of this function. These insights will be of major value to glycobiologists and anti‐cancer drug discoverers.
Sulfated glycosaminoglycans (GAGs), or synthetic mimetics thereof, are not favorably viewed as orally bioavailable drugs owing to their high number of anionic sulfate groups. Devising an approach for oral delivery of such highly sulfated molecules would be very useful. This work presents the concept that conjugating cholesterol to synthetic sulfated GAG mimetics enables oral delivery. A focused library of sulfated GAG mimetics was synthesized and found to inhibit the growth of a colorectal cancer cell line under spheroid conditions with a wide range of potencies ( 0.8 to 46 μM). Specific analogues containing cholesterol, either alone or in combination with clinical utilized drugs, exhibited pronounced in vivo anticancer potential with intraperitoneal as well as oral administration, as assessed by ex vivo tertiary and quaternary spheroid growth, cancer stem cell (CSC) markers, and/or self-renewal factors. Overall, cholesterol derivatization of highly sulfated GAG mimetics affords an excellent approach for engineering oral activity.
Glycosaminoglycans (GAGs), such as heparan sulfate (HS), have been implicated in tumor initiation, progression and metastasis. Earlier we have shown that a defined GAG sequence of six residues, but not four or eight residues, inhibits colorectal cancer stem cells (CSCs) by inducing activation of p38 MAPK. To transform this sequence into a drug-like molecule, we developed a synthetic mimetic of the GAG sequence, labeled as G2.2, which was also found to selectively target CSCs over bulk adherent tumor cells. Unfortunately, G2.2’s oral bioavailability was low. To improve upon its drug-like properties, we pursued a hypothesis-driven analog design to derive three lipid-modified analogs (LMAs). Across a panel of > 15 patient-derived colorectal cancer (CRC) cell lines, which could be stratified according to their clinically-relevant consensus molecular subtypes, LMAs showed enhanced potency while retaining selectivity against CSCs in spheroid inhibition assays. Both G2.2 and LMAs displayed better inhibition of cell lines with mesenchymal phenotypes and metabolic dysregulation. Microarray-based screening against more than a dozen receptor tyrosine kinases led to identification of IGF1R as a potential receptor of the synthetic GAG mimetics. To ascertain these screening results, biophysical studies were performed to clarify preferred soluble and/or cell surface target receptors. In line with microarray results, G2.2 preferentially bound to IGF1R in comparison to its soluble ligand IGF-1. G2.2 also preferred IGF1R as compared to an alternative receptor FGFR1. Further, LMAs bound to IGF1R with improved affinities as compared to parent mimetic G2.2, which could explain anti-CSC inhibition results. Unexpectedly, detailed fluorescence titrations revealed that IGF1R affinity of LMAs is minimally impacted by salt concentration, suggesting that these GAG mimetics utilize non-ionic forces in binding, which support the selectivity of target engagement. Overall, this work proves a powerful proof of concept that synthetic GAG mimetics, such as G2.2 and LMAs, present a unique class of anti-cancer therapeutics with high potential for selective elimination of the tumor initiating subpopulation of CRC cells in patient tumors. Citation Format: Connor O'Hara, Shravan Morla, Ravikumar Ongolu, Nirmita Patel, Rio Boothello, Bhaumik Patel, Umesh Desai. Synthetic, small molecule glycosaminoglycan mimetics induce novel anti-cancer activity through preferential targeting of a growth factor receptor [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2653.
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