Brain stem cells and IGF-I: implications in development, regeneration and cancer therapeutics

Integrative molecular medicine Pub Date : 2018-01-01 DOI:10.15761/IMM.1000319

S. J. Bueno, R. Santander, Alvaro Alvarez, J. J. Rey, J. Trojan.

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引用次数: 3

Abstract

For the past 40 years, our challenge has been finding a solution for the treatment of brain tumors using our knowledge of the evolution of life, the chemistry of proteins, genetics, and molecular biology. Efficient strategies were established by the construction of vectors targeting oncoproteins or growth factors (i.e. IGF-I, AFP) present during the development of the embryonic and fetal nervous system tissues originating from neural stem cells. The neoplastic stem cells, PCC3 and PCC4, derived from mouse teratocarcinoma – tumor mimicking the structures of developing central nervous system were transfected with the vectors expressing either antisense IGF-I RNA or IGF-I RNA forming a triple helix RNA-DNA. Both approaches completely stopped the synthesis of the IGF-I growth factor and converted the stem cells into immunogenic cells expressing MHC-I and B7. The immunogenic anti IGF-I transfected cells became antitumor vaccines. The role played by stem cells in the nervous system has motivated us in the search for knowledge focused on self-regeneration and therapeutic strategies. The strategy of Anti IGF-I vaccines was applied with success for therapy of glioblastoma.

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脑干细胞和igf - 1:在发育、再生和癌症治疗中的意义

在过去的40年里，我们面临的挑战一直是利用我们对生命进化、蛋白质化学、遗传学和分子生物学的知识，找到治疗脑肿瘤的解决方案。通过构建靶向胚胎和源自神经干细胞的胎儿神经系统组织发育过程中存在的癌蛋白或生长因子(如IGF-I, AFP)的载体，建立了有效的策略。用表达反义IGF-I RNA或IGF-I RNA的载体转染模拟发育中的中枢神经系统结构的小鼠畸胎癌肿瘤干细胞PCC3和PCC4，形成三螺旋RNA- dna。两种方法都完全停止了IGF-I生长因子的合成，将干细胞转化为表达MHC-I和B7的免疫原性细胞。免疫原性抗igf - 1转染细胞成为抗肿瘤疫苗。干细胞在神经系统中所扮演的角色激励着我们去寻找专注于自我再生和治疗策略的知识。抗igf - 1疫苗策略已成功应用于胶质母细胞瘤的治疗。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Integrative molecular medicine

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