Bubble mediated polymerization of RNA and DNA

IF 1.1 Q4 BIOPHYSICS
R. Marks
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引用次数: 2

Abstract

Research dedicated to trace rotational motion of bubbles in saline water revealed that these may generate either single cationic or cationic/anionic motions, including spliced double helix flow. In all cases, the aggregated ionic flows propagate in spiraling as well as rotational manner. However, if bi-ionic or double helix motion is generated, the flow is oppositely directed and has opposite electric charges. Next, the assembled flow is forced to pirouette within the bubble vortex. During that processing the narrowing of spiraling flow takes place and result in increase of revolutions to even millions per second. As a result, a significant friction is induced between revolving ionic hydrates allowing continuous detachment of electrons from covalent atomic shells of electropositive elements. Then, free electrons may be attracted by electronegative elements that are dissolved in seawater. Afterwards, that negatively charged elements may undergo electrical condensation around cationic centers of revolutions. That explain a unique mechanism which operates when negatively charged phosphate compounds and pentagonal blocks found in RNA and DNA as ribose as well as pentagonal rings in nitrogenous bases A and G are being winded. The compensative anionic flow and revolutions may conduct winding of hexagonal blocks found in nitrogenous bases A, G and C, T or U. These assume to gather more positive charge needed to bridge negatively charged sugar molecules in nucleic acids. Thus, the continuity in generation of electronegative compounds and spiral manner of arranging them within the sub-bubble vortices should be regarded as a mechanism responsible for precise, rotational-electric polymerization of elongated macromolecules of RNA/DNA architecture. Reported research refers mainly to physical processes activated by rising bubbles thus should be confronted with other experimental methods used in genetics, microbiology and chemistry.
气泡介导的RNA和DNA聚合
致力于追踪气泡在盐水中的旋转运动的研究表明,这些可能产生单阳离子或阳离子/阴离子运动,包括拼接双螺旋流。在所有情况下,聚集的离子流以螺旋和旋转的方式传播。然而,如果产生双离子或双螺旋运动,则流动方向相反,具有相反的电荷。接下来,集合流被迫在气泡漩涡内旋转。在这个过程中,螺旋流的变窄发生,导致转数增加到每秒数百万转。结果,在旋转的离子水合物之间产生了显著的摩擦,使得电子从正电元素的共价原子壳层中连续分离。然后,自由电子可能被溶解在海水中的电负性元素所吸引。然后,带负电荷的元素可能在正离子中心周围发生电凝结。这解释了一种独特的机制,当带负电荷的磷酸盐化合物和在RNA和DNA中发现的五角形块以及在氮基a和G中的五角形环被缠绕时,这种机制就会起作用。代偿性阴离子流动和旋转可以使氮基A、G和C、T或u中的六角形块缠绕在一起,这些被认为可以收集更多的正电荷,以桥接核酸中带负电荷的糖分子。因此,电负性化合物产生的连续性和它们在亚泡漩涡内的螺旋排列方式应被视为负责RNA/DNA结构的细长大分子的精确旋转电聚合的机制。报告的研究主要是指气泡上升激活的物理过程,因此应该面对遗传学,微生物学和化学中使用的其他实验方法。
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来源期刊
AIMS Biophysics
AIMS Biophysics BIOPHYSICS-
CiteScore
2.40
自引率
20.00%
发文量
16
审稿时长
8 weeks
期刊介绍: AIMS Biophysics is an international Open Access journal devoted to publishing peer-reviewed, high quality, original papers in the field of biophysics. We publish the following article types: original research articles, reviews, editorials, letters, and conference reports. AIMS Biophysics welcomes, but not limited to, the papers from the following topics: · Structural biology · Biophysical technology · Bioenergetics · Membrane biophysics · Cellular Biophysics · Electrophysiology · Neuro-Biophysics · Biomechanics · Systems biology
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