In Silico and In Vivo Studies of a Tumor-Penetrating and Interfering Peptide with Antitumoral Effect on Xenograft Models of Breast Cancer

The combination of a tumor-penetrating peptide (TPP) with a peptide able to interfere witha given protein–protein interaction (IP) is a promising strategy with potential clinical application.Little is known about the impact of fusing a TPP with an IP, both in terms of internalization andfunctional effect. Here, we analyze these aspects in the context of breast cancer, targeting PP2A/SET interaction, using both in silico and in vivo approaches. Our results support the fact that state-of-theart deep learning approaches developed for protein–peptide interaction modeling can reliably identify good candidate poses for the IP-TPP in interaction with the Neuropilin-1 receptor. The association of the IP with the TPP does not seem to affect the ability of the TPP to bind to Neuropilin-1. Molecular simulation results suggest that peptide IP-GG-LinTT1 in a cleaved form interacts with Neuropilin-1 in a more stable manner and has a more helical secondary structure than the cleaved IP-GG-iRGD.Surprisingly, in silico investigations also suggest that the non-cleaved TPPs can bind the Neuropilin-1 in a stable manner. The in vivo results using xenografts models show that both bifunctional peptides resulting from the combination of the IP and either LinTT1 or iRGD are effective against tumoral growth. The peptide iRGD-IP shows the highest stability to serum proteases degradation while having the same antitumoral effect as Lin TT1-IP, which is more sensitive to proteases degradation.Our results support the development of the TPP-IP strategy as therapeutic peptides against cancerFacultad de Ciencias Médica

In Silico and In Vivo Studies of a Tumor-Penetrating and Interfering Peptide with Antitumoral Effect on Xenograft Models of Breast Cancer

The combination of a tumor-penetrating peptide (TPP) with a peptide able to interfere with a given protein–protein interaction (IP) is a promising strategy with potential clinical application. Little is known about the impact of fusing a TPP with an IP, both in terms of internalization and functional effect. Here, we analyze these aspects in the context of breast cancer, targeting PP2A/SET interaction, using both in silico and in vivo approaches. Our results support the fact that state-of-the-art deep learning approaches developed for protein–peptide interaction modeling can reliably identify good candidate poses for the IP-TPP in interaction with the Neuropilin-1 receptor. The association of the IP with the TPP does not seem to affect the ability of the TPP to bind to Neuropilin-1. Molecular simulation results suggest that peptide IP-GG-LinTT1 in a cleaved form interacts with Neuropilin-1 in a more stable manner and has a more helical secondary structure than the cleaved IP-GG-iRGD. Surprisingly, in silico investigations also suggest that the non-cleaved TPPs can bind the Neuropilin-1 in a stable manner. The in vivo results using xenografts models show that both bifunctional peptides resulting from the combination of the IP and either LinTT1 or iRGD are effective against tumoral growth. The peptide iRGD-IP shows the highest stability to serum proteases degradation while having the same antitumoral effect as Lin TT1-IP, which is more sensitive to proteases degradation. Our results support the development of the TPP-IP strategy as therapeutic peptides against cancer

PRECLINICAL VALIDATION OF A TUMOR PENETRATING AND INTERFERING PEPTIDES AGAINST CHRONIC LYMPHOCYTIC LEUKEMIA

International audienceChronic lymphocytic leukemia (CLL) is the most common form of leukemia in adults. The disease is characterized by the accumulation of tumoral B cells resulting from a defect of apoptosis. We have in vitro and in vivo preclinically validated a tumor-penetrating peptide (named TT1) coupled to an interfering peptide (IP) that dissociates the interaction between the serine/threonine protein phosphatase 2A (PP2A) from its physiological inhibitor, the oncoprotein SET. This TT1-IP peptide has an antitumoral effect on CLL, as shown by the increased survival of mice bearing xenograft models of CLL, compared to control mice. The peptide did not show toxicity, as indicated by the mouse body weight and the biochemical parameters, such as renal and hepatic enzymes. In addition, the peptide-induced apoptosis in vitro of primary tumoral B cells isolated from CLL patients but not of those isolated from healthy patients. Finally, the peptide had approximately 5 h half-life in human serum and showed pharmacokinetic parameters compatible with clinical development as a therapeutic peptide against CLL

Identification of PP2A/Set binding sites and design of interacting peptides with potential clinical applications

Protein phosphatase 2A (PP2A) is known to be a negative regulator of several survival and proliferating pathways that are frequently altered in cancer. In addition to chemical enzymatic inhibitors of the PP2A activity, the oncoprotein SET has been described as a physiological PP2A inhibitor by forming a complex with PP2A catalytic subunit (PP2Ac). Increased SET protein levels therefore directly reduce the tumor suppressor function of PP2A and promote tumor progression. We have used the PEP-Scan approach to identify the binding site between the serine/threonine phosphatase PP2A and the oncoprotein SET. For in vivo validation of the peptides, we have used chronic lymphocytic leukemia (CLL) xenograft models. In this manuscript we describe the identification of amino acid sequences involved in the complex formation, both at the PP2Ac and SET sides. The amino acid sequences of the binding sites were coupled to an optimized penetrating peptide in order to generate chimeras (Mut3DPT-PP2A and Mut3DPT-SET) able to target the PP2A/SET interaction. We demonstrate that these peptides have an in vitro apoptotic effect on breast and lung cancer cell lines, as well as an antitumoral effect on CLL and lymphoma xenograft models. The new generated chimeric peptides allow the modulation of the PP2Ac/SET interaction and might have a potential as a new therapeutic approach for cancer treatment.status: publishe

Bifunctional Therapeutic Peptides for Targeting Malignant B Cells and Hepatocytes: Proof of Concept in Chronic Lymphocytic Leukemia

International audienceProtein-protein interactions are well recognized as therapeutic targets and therefore interfering peptides (IP) that block these interactions are receiving increasing attention. Four different tumor-penetrating peptides (TPPs) (iRGD, RPARPAR, Linear TT1 (LinTT1), and cyclic TT1 (TT1)) are associated to an IP that blocks the interaction between the protein phosphatase PP2A and its binding protein SET, generating new bifunctional peptides able to intracellularly target the PP2A/SET interaction in malignant B cells and tumoral hepatocytes. The TPPs are able to penetrate into B cells of patients suffering chronic lymphocytic leukemia (CLL) and into tumoral hepatocytes but not into B cells from healthy donors and healthy hepatocytes. The association of cargo does not affect the penetration of the TPPs in CLL B cells. All the bifunctional peptides induce apoptosis in human CLL B cells and tumoral hepatocytes, and stability tests reveal that iRGD-IP, RPARPAR-IP, and TT1-IP are stable after 24 h incubation in human serum. The iRGD associated with the IP significantly increases the survival of mice bearing xenograft models of CLL without any symptom of toxicity, suggesting that the bifunctional peptides may have a therapeutic application for selective tumoral targeting of PP2A/SET interaction, which is deregulated in several cancers, including CLL

Redirecting the Immune Response: Role of Adoptive T Cell Therapy

In this article, Mondino and colleagues examine the importance of pretransplantation host conditioning and posttransplantation strategies in adoptive T cell therapy