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virus-movement

1 article
Structural and phylogenetic analyses of umbravirus and umbra-like virus genomes suggest evolution of capsid-like proteins from 30K movement proteins.

PubMed · 2026-04-21

Researchers compared the genetic blueprints of plant umbraviruses and related umbra-like viruses, discovering that the protective protein shells (capsids) found in some of these viruses most likely evolved from proteins that originally served a completely different job: helping the virus move between plant cells.

1

Umbraviruses encode two distinct movement proteins but no capsid protein, making them dependent on helper viruses for insect-mediated transmission to new host plants.

2

Group 2 umbra-like viruses evolved functional capsid-like proteins that free them from helper-virus dependency, likely enabling independent vector acquisition.

3

Structural and phylogenetic analyses indicate these capsid-like proteins descended from 30K-type movement proteins, representing a repurposing of cell-to-cell movement machinery into an encapsidation role.

Species in Topic

Arborvitae Flossflower

Related Topics

plant-virus-evolution plant-pathology capsid-evolution plant-disease