Crystal morphology of spherical viruses

IF 2.4 Q2 MINING & MINERAL PROCESSING Journal of Mining Institute Pub Date : 2021-05-25 DOI:10.31897/pmi.2021.2.3
Y. Voytekhovsky
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Abstract

The article discusses modern views on the structure of spherical virus capsids, which have the shape of icosahedrons (icosahedral viruses). Each face of icosahedron is composed of a single-layer closest packing of protein globules, which can have different orientation relative to the edges of icosahedron. If the lines of globules are parallel to the edges of icosahedron, then the capsid has a point symmetry group Ih (with symmetry planes), if they are not parallel – the symmetry group I (without planes). From a mathematical point of view, in both symmetry groups there are series that unite equally (up to similarity) arranged capsids. They are connected pairwise by transitions to dual forms (homologous series). A hypothesis is formulated that the largest spherical viruses can have even more diverse and complex capsid structures. Along with icosahedron, their basic forms can be any simple shapes, allowed in Ih and I symmetry groups (8 in total). A suggestion is made that transitions within similarity series and between homologous series have a phylogenetic significance. There are known spherical viruses of both symmetry groups. For example, the SARS-CoV-2 coronavirus has a symmetry group Ih and belongs to a well-known series. The crystallographic approach allows to construct a strict morphological classification of spherical viruses. This is important for their early recognition and separate examination. The article demonstrates practical application of crystal morphology in the study of viral systems – an urgent problem of geoecology and life protection.
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球形病毒的晶体形态
本文讨论了具有二十面体(二十面体病毒)形状的球形病毒衣壳结构的现代观点。二十面体的每个面都是由一层最紧密的蛋白质球组成的,这些蛋白质球相对于二十面体的边缘可以有不同的取向。如果球的线平行于二十面体的边缘,则衣壳有一个点对称群Ih(有对称面),如果它们不平行-对称群I(无平面)。从数学的角度来看,在这两个对称群中,都有一系列的衣壳排列相同(直至相似)。它们通过转换成对地连接到对偶形式(同源级数)。提出了一个假设,即最大的球形病毒可以有更多样化和复杂的衣壳结构。与二十面体一样,它们的基本形式可以是任何简单的形状,在I和I对称群中允许(总共8个)。提出了相似序列内部和同源序列之间的过渡具有系统发育意义。这两个对称群都有已知的球形病毒。例如,SARS-CoV-2冠状病毒具有对称群Ih,属于一个众所周知的系列。晶体学方法允许构建球形病毒的严格形态学分类。这对早期识别和单独检查很重要。本文阐述了晶体形态学在病毒系统研究中的实际应用,这是地质生态学和生命保护的迫切问题。
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来源期刊
Journal of Mining Institute
Journal of Mining Institute MINING & MINERAL PROCESSING-
CiteScore
7.50
自引率
25.00%
发文量
62
审稿时长
8 weeks
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