The basic jelly roll structure consists of eight beta strands arranged in two four-stranded antiparallel beta sheets which pack together across a hydrophobic interface [Where citation... uniprot]. The strands are traditionally labeled B through I for the historical reason that the first solved structure, of a jelly roll capsid protein from the tomato bushy stunt virus, had an additional strand A outside the fold's common core.[6][7] The sheets are composed of strands BIDG and CHEF, folded such that strand B packs opposite strand C, I opposite H, etc.[4][8]
Viral proteins
A large number of viruses build their exterior capsids from proteins containing either a single or a double jelly roll fold. This shared capsid architecture is thought to reflect ancient evolutionary relationships, possibly dating to before the last universal common ancestor (LUCA) of cellular life.[8][9][10] Other viral lineages use evolutionarily unrelated proteins to build their enclosed capsids, which likely evolved independently at least twice[9][11] and possibly many times, with links to proteins of cellular origin.[12]
Single jelly roll capsid proteins
Single jelly roll capsid (JRC) proteins are found in at least sixteen distinct viral families, mostly with icosahedral capsid structures and including both RNA viruses and DNA viruses.[13] Many viruses with single jelly roll capsids are positive-sense single-stranded RNA viruses. Two groups of double-stranded DNA viruses with single-JRC capsids are the Papillomaviridae and Polyomaviridae, both of which have fairly small capsids; in these viruses, the architecture of the assembled capsid orients the axis of the jelly roll parallel or "horizontally" relative to the capsid surface.[11] A large-scale analysis of viral capsid components suggested that the single horizontal jelly roll is the most common fold among capsid proteins, accounting for about 28% of known examples.[12]
Another group of viruses uses single jelly roll proteins in their capsids, but in the vertical rather than horizontal orientation. These viruses are evolutionarily related to the large group of double jelly-roll viruses known as the PRD1-adenovirus viral lineage, with similar capsid architecture realized through assembly of two distinct single jelly-roll major capsid proteins expressed from distinct genes.[14][15] These single vertical jelly-roll viruses comprise the taxon Helvetiavirae.[16] Known viruses with vertical single jelly roll capsids infect extremophilicprokaryotes.[14][12]
Double jelly roll proteins
Double jelly roll capsid proteins consist of two single jelly roll folds connected by a short linker region. They are found in both double-stranded DNA viruses and single-stranded DNA viruses of at least ten different viral families, including viruses that infect all domains of life, and spanning a large capsid size range.[4][11][18] In the double jelly roll capsid architecture, the jelly roll axis is oriented perpendicular or "vertically" relative to the capsid surface.[19]
Double jelly roll proteins are believed to have evolved from single jelly roll proteins by gene duplication.[11][19] It is likely that vertical single jelly roll viruses represent a transitional form, and that the vertical and horizontal jelly roll capsid proteins have independent evolutionary origins from ancestral cellular proteins.[12] The degree of structural similarity among double-jelly-roll virus capsids has led to the conclusion that these viruses likely have a common evolutionary origin despite their diversity in size and in host range; this has become known as the PRD1-adenovirus lineage (Bamfordvirae).[19][16][20][21] Many members of this group have been identified through metagenomics and in some cases have few to no other viral genes in common.[12][22] Although most members of this group have icosahedral capsid geometry, a few families such as the Poxviridae and Ascoviridae have oval or brick-shaped mature virions; poxviruses such as Vaccinia undergo dramatic conformational changes mediated by highly derived double jelly roll proteins during maturation and likely derive from an icosahedral ancestor.[11][23] Shared double-jelly-roll capsid proteins, along with other homologous proteins, have also been cited in support of the proposed orderMegavirales containing the nucleocytoplasmic large DNA viruses (NCLDV).[24]
Initially, it was believed that double jelly roll proteins are unique to viruses, because they were not observed in cellular proteins.[11] However, in 2022, comparison of protein structures revealed several families of bona fide cellular proteins with the double jelly roll fold [25]
Non-capsid proteins
Single jelly rolls also occur in non-capsid viral proteins, including minor components of the assembled virion as well as non-virion proteins such as polyhedrin.[11] In plant viruses, the 30K superfamily movement proteins responsible for intercellular transport of viral genomes or entire capsids through plasmodesmata channels have the single jelly-roll fold and have evolved from the capsid proteins of small icosahedral viruses.[26]
Cellular proteins
Both single and double jelly roll folds are found in proteins of cellular origin.[11][12][25] One class of cellular proteins with single jelly roll fold is the nucleoplasmins, which serve as molecular chaperone proteins for histone assembly into nucleosomes. The N-terminaldomain of nucleoplasmins possesses a single jelly roll fold and assembled into a pentamer.[27] Similar structures have since been reported in additional groups of chromatin remodeling proteins.[28] Jelly roll motifs with identical beta-sheet connectivity are also found in tumor necrosis factor ligands[29] and proteins from the bacterium Yersinia pseudotuberculosis that belong to a class of viral and bacterial proteins known as superantigens.[30][31]
A notable difference between PNGases F and the other double jelly roll proteins is the absence of the α-helices, which follow the F and F' strands in capsid proteins and DUF2961. The equivalent regions are variable in the PNGases F and contain either long loops or insertions. By contrast, jelly-roll domains of DUF2961 proteins contain an insertion of short β-hairpins upstream of the G and G' strands of the double jelly roll fold. Importantly, DUF2961 family proteins form trimers resembling viral capsomers.[25]
Evolution
Comparative studies of proteins classified as jelly roll and Greek key structures suggest that the Greek key proteins evolved significantly earlier than their more topologically complex jelly roll counterparts.[5]Structural bioinformatics studies comparing virus capsid jelly-roll proteins to other proteins of known structure indicates that the capsid proteins form a well-separated cluster, suggesting that they are subject to a distinctive set of evolutionary constraints.[4] One of the most notable features of viral capsid jelly roll proteins is their ability to form oligomers in a repeated tiling pattern to produce a closed protein shell; the cellular proteins that are most similar in fold and topology are mostly also oligomers.[4] It has been proposed that viral jelly-roll capsid proteins have evolved from cellular jelly-roll proteins, potentially on several independent occasions, at the earliest stages of cellular evolution.[12]
History and nomenclature
The name "jelly roll" was first used for the structure composed of an elaboration on the Greek key motif by Jane S. Richardson in 1981 and was intended to reflect the structure's resemblance to a jelly or Swiss roll cake.[2] The structure has been given a variety of descriptive names, including a wedge, beta barrel, and beta roll. The edges of the two sheets do not meet to form regular hydrogen bonding patterns, and so it is often not considered to be a true beta barrel,[3] though the term is in common use in describing viral capsid architecture.[14][15] Cellular proteins containing jelly roll-like structures may be described as a cupin fold, a JmjC fold, or a double-stranded beta helix.[34]
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^ abAik W, McDonough MA, Thalhammer A, Chowdhury R, Schofield CJ (December 2012). "Role of the jelly-roll fold in substrate binding by 2-oxoglutarate oxygenases". Current Opinion in Structural Biology. 22 (6): 691–700. doi:10.1016/j.sbi.2012.10.001. PMID23142576.