The first embryo, the origin of cancer and animal phylogeny. III. The totipotency as revealed by morphogenesis and the neoplasia controlled by cellular differentiation

IF 2.1 4区 生物学 Q2 BIOLOGY
Jaime Cofre
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Abstract

We have extensively described that the neoplastic process (NP) has deep evolutionary roots and we have made specific predictions about the connection between cancer and the formation of the first embryo, which allowed for the evolutionary radiation of metazoans. My main hypothesis is that the NP is at the heart of cellular mechanisms responsible for animal morphogenesis, and given its embryological basis, also at the center of cell differentiation—one of the most interesting and relevant aspects of embryogenesis. In this article, I take forward the idea of the role of physics in the modeling of the neoplastic functional module (NFM) and its contribution to morphogenesis to reveal the totipotency of the zygote. In my consideration of these arguments, I examine mechanical and biophysical clues and their intimate connection with cellular differentiation. I expound on how cancer biology is perfectly intertwined with embryonic differentiation and why it is considered a disease of cell differentiation. The neoplasia is controlled by textural gradients that lead to cell differentiation within the embryo. Thus, the embryo would be a benign tumor. Finally, inspired by evolutionary history and by what the nervous system represents for current biology and based on the impressive nervous system of ctenophores as seen in fossil records, I propose a hypothesis with physical foundations (mechanical morphogenesis) for the formation of a preneural pattern of the nervous system of the first animal embryo.

Abstract Image

第一个胚胎、癌症的起源和动物系统发育。III.形态发生揭示的全能性和细胞分化控制的肿瘤性
我们广泛地描述了肿瘤过程(NP)具有深厚的进化根源,并对癌症与第一个胚胎的形成之间的联系做出了具体预测,这使得元古宙的进化辐射成为可能。我的主要假设是,NP 是负责动物形态发生的细胞机制的核心,鉴于其胚胎学基础,它也是细胞分化的中心--胚胎发生中最有趣、最相关的方面。在本文中,我提出了物理学在新生儿功能模块(NFM)建模中的作用及其对形态发生的贡献这一观点,以揭示合子的全能性。在考虑这些论点时,我研究了机械和生物物理线索及其与细胞分化的密切联系。我阐述了癌症生物学如何与胚胎分化完美地交织在一起,以及为什么癌症被认为是一种细胞分化疾病。胚胎内细胞分化的纹理梯度控制着肿瘤的发生。因此,胚胎将是一种良性肿瘤。最后,受进化史和神经系统对当前生物学的意义的启发,并基于化石记录中令人印象深刻的栉水母神经系统,我提出了一个具有物理基础(机械形态发生)的假说,即第一个动物胚胎神经系统前神经模式的形成。
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来源期刊
Journal of Biosciences
Journal of Biosciences 生物-生物学
CiteScore
5.80
自引率
0.00%
发文量
83
审稿时长
3 months
期刊介绍: The Journal of Biosciences is a quarterly journal published by the Indian Academy of Sciences, Bangalore. It covers all areas of Biology and is the premier journal in the country within its scope. It is indexed in Current Contents and other standard Biological and Medical databases. The Journal of Biosciences began in 1934 as the Proceedings of the Indian Academy of Sciences (Section B). This continued until 1978 when it was split into three parts : Proceedings-Animal Sciences, Proceedings-Plant Sciences and Proceedings-Experimental Biology. Proceedings-Experimental Biology was renamed Journal of Biosciences in 1979; and in 1991, Proceedings-Animal Sciences and Proceedings-Plant Sciences merged with it.
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