According to the founders of quantum mechanics and quantum biology P. Jordan and E. Schrödinger, the main difference between living and inanimate objects is the dictatorial influence of genetic molecules on the whole living organism. Code biology can make a valuable contribution to understanding this dictatorial influence of genetic molecules whose ensemble is endowed with many interconnected alphabets and codes. The paper is devoted to probability rules of nucleotide sequences of single-stranded DNA in eukaryotic and prokaryotic genomes. These rules are connected with n-plets alphabets of DNA whose nucleotide sequences are considered as bunches of many parallel texts written in interconnected n-plets alphabets. The rules draw attention to genomic phenomena of special tetragroupings of n-plets and new genomic symmetries. A generalization of the second Chargaff's rule is described. They show the existence of long-range coherence in genomic DNA sequences and reveal new connections of structural features of genomic sequences with formalisms of quantum mechanics and quantum informatics. The author supposes that the received results are related to the known vibration-resonance theory of G. Frohlich about long-range coherence in biological systems, that is, about collective quantum effects there. The possible influence of the described genetiс probability phenomena on the genetically inherited physiological structures is noted and discussed.

根据量子力学和量子生物学的创始人 P. Jordan 和 E. Schrödinger 的说法，有生命的物体和无生命的物体之间的主要区别在于遗传分子对整个生命有机体的独裁影响。密码生物学可以为理解遗传分子的这种独裁影响做出有价值的贡献，这些遗传分子的集合被赋予了许多相互关联的字母和密码。本文致力于真核和原核基因组中单链DNA核苷酸序列的概率规律。这些规则与DNA 的n个字母相连，其核苷酸序列被认为是许多平行文本的束，这些文本以相互连接的n-plets 字母。这些规则提请注意n- plet 的特殊四组和新的基因组对称性的基因组现象。描述了第二个查格夫规则的概括。它们表明基因组 DNA 序列中存在长程相干性，并揭示了基因组序列结构特征与量子力学和量子信息学形式的新联系。作者假设收到的结果与 G. Frohlich 已知的关于生物系统中的长程相干性的振动共振理论有关，即关于那里的集体量子效应。注意到并讨论了所描述的遗传概率现象对遗传生理结构的可能影响。