{"title":"可重建的生物计时器:真核生物计时系统的推论和假设","authors":"Ming-Jia Fu","doi":"arxiv-2402.16271","DOIUrl":null,"url":null,"abstract":"The biochronometers used to keep time in eukaryotes include short-period\nbiochronometer (SPB) and long-period biochronometer (LPB). Because the\ncircadian clock reflects the biological time rhythm of a day, it is considered\nas SPB. Telomere shortening, which reflects the decreasing of telomere DNA\nlength of chromosomes with the increase of cell division times, can be used to\ntime the lifespan of organisms, so it is regarded as LPB. It is confirmed that\nSPB and LPB exist in most eukaryotes, and it is speculated that SPB and LPB are\nclosely related. In this paper, based on existing studies, it is speculated\nthat SPB and LPB of most eukaryotes can be co-attenuated with cell division in\nthe process of aging. Due to the attenuated phenomenon of key components in the\nbiochronometers during the growth and development of organisms, the\nbiochronometers attenuate with the aging. Based on existing research results,\nit is preliminarily determined that the biochronometers can be rebuilt in the\nco-attenuated process. When the key components of biochronometers are reversed\nand increased in the organism, it can lead to the reversal of biochronometers,\nwhich further leads to the phenomenon of biological rejuvenation and makes the\norganism younger. In addition, the rebuilding of biochronometers can also lead\nto the acceleration of biochronometers and the shortening of the original\ntiming time of biochronometers, thus shortening the life span of organisms. The\nrebuilding of biochronometers includes the reversal of biochronometers, the\ntruncation of biochronometers timing and Uncoordinated co-attenuation of\nbiochronometer and so on. The reversal of the biochronometers, which leads to\nrejuvenation, can give us a whole new understanding of life expectancy to be\ndifferent from anti-aging.","PeriodicalId":501321,"journal":{"name":"arXiv - QuanBio - Cell Behavior","volume":"1 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-02-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Rebuildable biochronometer: inferences and hypothesis on eukaryotic timing system\",\"authors\":\"Ming-Jia Fu\",\"doi\":\"arxiv-2402.16271\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The biochronometers used to keep time in eukaryotes include short-period\\nbiochronometer (SPB) and long-period biochronometer (LPB). Because the\\ncircadian clock reflects the biological time rhythm of a day, it is considered\\nas SPB. Telomere shortening, which reflects the decreasing of telomere DNA\\nlength of chromosomes with the increase of cell division times, can be used to\\ntime the lifespan of organisms, so it is regarded as LPB. It is confirmed that\\nSPB and LPB exist in most eukaryotes, and it is speculated that SPB and LPB are\\nclosely related. In this paper, based on existing studies, it is speculated\\nthat SPB and LPB of most eukaryotes can be co-attenuated with cell division in\\nthe process of aging. Due to the attenuated phenomenon of key components in the\\nbiochronometers during the growth and development of organisms, the\\nbiochronometers attenuate with the aging. Based on existing research results,\\nit is preliminarily determined that the biochronometers can be rebuilt in the\\nco-attenuated process. When the key components of biochronometers are reversed\\nand increased in the organism, it can lead to the reversal of biochronometers,\\nwhich further leads to the phenomenon of biological rejuvenation and makes the\\norganism younger. In addition, the rebuilding of biochronometers can also lead\\nto the acceleration of biochronometers and the shortening of the original\\ntiming time of biochronometers, thus shortening the life span of organisms. The\\nrebuilding of biochronometers includes the reversal of biochronometers, the\\ntruncation of biochronometers timing and Uncoordinated co-attenuation of\\nbiochronometer and so on. 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引用次数: 0
摘要
真核生物用于计时的生物钟包括短周期生物钟(SPB)和长周期生物钟(LPB)。由于昼夜节律钟反映了一天的生物时间节律,因此被认为是 SPB。端粒缩短反映了染色体端粒 DNA 长度随着细胞分裂次数的增加而减少,可用于计算生物的寿命,因此被视为 LPB。研究证实,大多数真核生物都存在SPB和LPB,并推测SPB和LPB密切相关。本文在已有研究的基础上,推测大多数真核生物的 SPB 和 LPB 在衰老过程中会随着细胞分裂而共同衰减。由于在生物的生长发育过程中,生物同步器中的关键成分会出现衰减现象,因此生物同步器会随着衰老而衰减。根据已有的研究成果,初步判断生物钟可以在衰减过程中重建。当生物计时器的关键成分在机体内逆转和增加时,可导致生物计时器逆转,从而进一步导致生物年轻化现象,使机体更年轻。此外,生物钟的重建也会导致生物钟的加速,缩短生物钟的原始计时时间,从而缩短生物的寿命。生物同步器的构建包括生物同步器的逆转、生物同步器时间的截断和生物同步器的非协调共衰减等。生物时间计的逆转导致了生物的返老还童,可以让我们对预期寿命有一个全新的认识,从而有别于抗衰老。
Rebuildable biochronometer: inferences and hypothesis on eukaryotic timing system
The biochronometers used to keep time in eukaryotes include short-period
biochronometer (SPB) and long-period biochronometer (LPB). Because the
circadian clock reflects the biological time rhythm of a day, it is considered
as SPB. Telomere shortening, which reflects the decreasing of telomere DNA
length of chromosomes with the increase of cell division times, can be used to
time the lifespan of organisms, so it is regarded as LPB. It is confirmed that
SPB and LPB exist in most eukaryotes, and it is speculated that SPB and LPB are
closely related. In this paper, based on existing studies, it is speculated
that SPB and LPB of most eukaryotes can be co-attenuated with cell division in
the process of aging. Due to the attenuated phenomenon of key components in the
biochronometers during the growth and development of organisms, the
biochronometers attenuate with the aging. Based on existing research results,
it is preliminarily determined that the biochronometers can be rebuilt in the
co-attenuated process. When the key components of biochronometers are reversed
and increased in the organism, it can lead to the reversal of biochronometers,
which further leads to the phenomenon of biological rejuvenation and makes the
organism younger. In addition, the rebuilding of biochronometers can also lead
to the acceleration of biochronometers and the shortening of the original
timing time of biochronometers, thus shortening the life span of organisms. The
rebuilding of biochronometers includes the reversal of biochronometers, the
truncation of biochronometers timing and Uncoordinated co-attenuation of
biochronometer and so on. The reversal of the biochronometers, which leads to
rejuvenation, can give us a whole new understanding of life expectancy to be
different from anti-aging.