Study on the cellular internalization mechanisms and in vivo anti-bone metastasis prostate cancer efficiency of the peptide T7-modified polypeptide nanoparticles

Bone-metastasis prostate cancer (BMPCa)-targeting gene therapy is gaining increasing concern in recent years. The peptide T7-modified polypeptide nanoparticles for delivery DNA (CRD-PEG-T7/pPMEPA1) was prepared as our previous study. However, the feasibility of CRD-PEG-T7/pPMEPA1 for BMPCa treatment...

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Published in:Drug delivery 2020-01, Vol.27 (1), p.161-169
Main Authors: Gu, Yongwei, Chen, Xinmei, Zhang, Haiyan, Wang, Heyi, Chen, Hang, Huang, Sifan, Xu, Youfa, Zhang, Yuansheng, Wu, Xin, Chen, Jianming
Format: Article
Language:English
Subjects:
administration safety
Animals
anti-tumor effect
Arginine
Aspartic Acid
Bone Neoplasms - prevention & control
Bone Neoplasms - secondary
bone-metastases prostate cancer
Cell adhesion & migration
Cell Line, Tumor
Cell Movement
Cell Survival
cellular internalization mechanisms
Cysteine
Gene therapy
Genetic Vectors - chemistry
Genetic Vectors - pharmacology
Male
Membrane Proteins - genetics
Metastasis
Mice
Mice, Inbred BALB C
Nanoparticles
Nanoparticles - chemistry
Particle Size
Peptide Fragments
Peptide T
Polyethylene Glycols - chemistry
Polypeptides
Prostate cancer
Prostatic Neoplasms - genetics
Prostatic Neoplasms - pathology
Tumor Burden
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cited_by cdi_FETCH-LOGICAL-c515t-e1f19c4ec1c16c49d0209ae93b6785c7b8d839cd16964293bda8248d758facc03
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container_title Drug delivery
container_volume 27
creator Gu, Yongwei
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Zhang, Yuansheng
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Chen, Jianming
description Bone-metastasis prostate cancer (BMPCa)-targeting gene therapy is gaining increasing concern in recent years. The peptide T7-modified polypeptide nanoparticles for delivery DNA (CRD-PEG-T7/pPMEPA1) was prepared as our previous study. However, the feasibility of CRD-PEG-T7/pPMEPA1 for BMPCa treatment, the mechanisms underlying cellular uptake, anti-BMPCa effect, and administration safety requires further research. LNCaP cells treated with endocytosis inhibitors and excessive T7 under different culture condition were carried out to investigate the mechanisms of cellular uptake of the CRD-PEG-T7-pPMEPA1. A transwell assay was applied to evaluate the cell migration ability. Besides, the tumor volume and survival rates of the PCa xenograft mice model were recorded to estimate the anti-tumor effect. In addition, the weight profiles of the PCa tumor-bearing mice, the blood chemistry, and the HE analysis of visceral organs and tumor was conducted to investigate the administration safety of CRD-PEG-T7/pPMEPA1. The results showed that PCa cellular uptake was decreased after treating with excessive free T7, endocytosis inhibitors and lower incubation temperature. Besides, CRD-PEG-T7/pPMEPA1 could inhibit the LNCaP cells chemotaxis and tumor growth. In addition, the survival duration of the PCa tumor-bearing mice treating with CRD-PEG-T7/pPMEPA1 was significantly prolonged with any systemic toxicity or damage to the organs. In conclusion, this research proposes a promising stratagem for treatment BMPCa by providing the biocompatible and effective carrier for delivery DNA therapeutic agents.
doi_str_mv 10.1080/10717544.2019.1709923
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The peptide T7-modified polypeptide nanoparticles for delivery DNA (CRD-PEG-T7/pPMEPA1) was prepared as our previous study. However, the feasibility of CRD-PEG-T7/pPMEPA1 for BMPCa treatment, the mechanisms underlying cellular uptake, anti-BMPCa effect, and administration safety requires further research. LNCaP cells treated with endocytosis inhibitors and excessive T7 under different culture condition were carried out to investigate the mechanisms of cellular uptake of the CRD-PEG-T7-pPMEPA1. A transwell assay was applied to evaluate the cell migration ability. Besides, the tumor volume and survival rates of the PCa xenograft mice model were recorded to estimate the anti-tumor effect. In addition, the weight profiles of the PCa tumor-bearing mice, the blood chemistry, and the HE analysis of visceral organs and tumor was conducted to investigate the administration safety of CRD-PEG-T7/pPMEPA1. The results showed that PCa cellular uptake was decreased after treating with excessive free T7, endocytosis inhibitors and lower incubation temperature. Besides, CRD-PEG-T7/pPMEPA1 could inhibit the LNCaP cells chemotaxis and tumor growth. In addition, the survival duration of the PCa tumor-bearing mice treating with CRD-PEG-T7/pPMEPA1 was significantly prolonged with any systemic toxicity or damage to the organs. 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The peptide T7-modified polypeptide nanoparticles for delivery DNA (CRD-PEG-T7/pPMEPA1) was prepared as our previous study. However, the feasibility of CRD-PEG-T7/pPMEPA1 for BMPCa treatment, the mechanisms underlying cellular uptake, anti-BMPCa effect, and administration safety requires further research. LNCaP cells treated with endocytosis inhibitors and excessive T7 under different culture condition were carried out to investigate the mechanisms of cellular uptake of the CRD-PEG-T7-pPMEPA1. A transwell assay was applied to evaluate the cell migration ability. Besides, the tumor volume and survival rates of the PCa xenograft mice model were recorded to estimate the anti-tumor effect. In addition, the weight profiles of the PCa tumor-bearing mice, the blood chemistry, and the HE analysis of visceral organs and tumor was conducted to investigate the administration safety of CRD-PEG-T7/pPMEPA1. The results showed that PCa cellular uptake was decreased after treating with excessive free T7, endocytosis inhibitors and lower incubation temperature. Besides, CRD-PEG-T7/pPMEPA1 could inhibit the LNCaP cells chemotaxis and tumor growth. In addition, the survival duration of the PCa tumor-bearing mice treating with CRD-PEG-T7/pPMEPA1 was significantly prolonged with any systemic toxicity or damage to the organs. In conclusion, this research proposes a promising stratagem for treatment BMPCa by providing the biocompatible and effective carrier for delivery DNA therapeutic agents.</abstract><cop>England</cop><pub>Taylor &amp; Francis</pub><pmid>31913730</pmid><doi>10.1080/10717544.2019.1709923</doi><tpages>9</tpages><oa>free_for_read</oa></addata></record>
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source Open Access: PubMed Central; Taylor & Francis Open Access; Publicly Available Content (ProQuest)
subjects administration safety
Animals
anti-tumor effect
Arginine
Aspartic Acid
Bone Neoplasms - prevention & control
Bone Neoplasms - secondary
bone-metastases prostate cancer
Cell adhesion & migration
Cell Line, Tumor
Cell Movement
Cell Survival
cellular internalization mechanisms
Cysteine
Gene therapy
Genetic Vectors - chemistry
Genetic Vectors - pharmacology
Male
Membrane Proteins - genetics
Metastasis
Mice
Mice, Inbred BALB C
Nanoparticles
Nanoparticles - chemistry
Particle Size
Peptide Fragments
Peptide T
Polyethylene Glycols - chemistry
Polypeptides
Prostate cancer
Prostatic Neoplasms - genetics
Prostatic Neoplasms - pathology
Tumor Burden
title Study on the cellular internalization mechanisms and in vivo anti-bone metastasis prostate cancer efficiency of the peptide T7-modified polypeptide nanoparticles
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