The virus takes the form of a roughly spherical particle, approximately 0.6 μm long, containing a genome of approximately 650,000 base pairs coding for more than 500 proteins. Most of these proteins bear no resemblance to those of its Siberian predecessor, Pithovirus sibericum. Furthermore, unlike Pithovirus, which only requires the cytoplasmic resources of its cellular host to multiply, Mollivirus sibericum uses the cell nucleus to replicate6 in the amoeba, which makes it as host-dependent as most “small” viruses. This strategy, and other specific traits, such as a deficiency in certain key enzymes that allow synthesis of its DNA building blocks, mean that Mollivirus sibericum is more similar to the common viral types, including human pathogens such as Adenovirus, Papillomavirus, or Herpesvirus. Pithovirus, on the other hand, replicates in the cytoplasm in the same way as Poxvirus, a family that counts the now officially eradicated smallpox virus. In terms of its shape, mode of replication and metabolism, Mollivirus sibericum thus represents a new type of virus never previously observed and distinct from the three giant virus families discovered to date.
This discovery, which suggests that giant viruses are not so rare and are highly diversified, also proves that the ability of viruses to survive in the permafrost for very long periods is not restricted to a particular viral type, but probably covers viral families with varied — and hence potentially pathogenic — replication strategies. The results of the metagenomic analysis of this permafrost sample, which revealed very low concentrations of Mollivirus (around a few parts per million), have important public health implications today. In the presence of a susceptible host, a few particles that are still infectious could indeed be sufficient to cause the resurgence of potentially pathogenic viruses in Arctic regions that are increasingly coveted for their mining and oil resources, and whose accessibility and industrial exploitation have been facilitated by climate change.
In order to determine whether other giant viruses are still hidden in the permafrost, the scientists are now studying7 even more ancient layers of the Siberian soil, working in a region that should enable them to go back a million years.
© IGS CNRS/AMU
Scanning electron microscopy of particles of 4 families of giant viruses that have now been identified. The largest dimensions can reach between 0.6 microns (Mollivirus) and 1.5 microns (Pandoravirus).
On the same subject:
1From the Institut de Recherche en Technologies et Sciences pour le Vivant (CEA-IRTSV), at the Institut de Génomique (CEA-IG)
2The layer of permanently frozen soil found in Arctic regions.
3See the end of this document, referring to a press release in 2014 on the discovery of Pithovirus.
4These techniques are called “omic approaches”. They offer a clearer understanding of the complexity of life as a whole, at the scale of an organism in terms of “genomics” (study of the genome), “transcriptomics” (study of gene expression) or “proteomics” (study of protein composition), or at the scale of an entire ecosystem (soil, air, oceans, intestine) for “metagenomics” (diversity of genomes).
5Mollivirus comes from the Latin Mollis, meaning flexible. Indeed, this virus is particular for being deformable once in a cellular medium.
6Viral replication is the series of processes that occur in a cell infected by a virus, resulting in the production of new units of this virus (or virions).
7With the support of national France-Génomique ProFi infrastructures (Investissements d’avenir).
In-depth study of Mollivirus sibericum, a new 30,000-y old giant virus infecting Acanthamoeba
Matthieu Legendre, Audrey Lartigue, Lionel Bertaux, Sandra Jeudy, Julia Bartoli, Magali Lescot, Jean-Marie Alempic, Claire Ramus, Christophe Bruley, Karine Labadie, Lyubov Shmakova, Elizaveta Rivkina, Yohann Couté, Chantal Abergel, Jean-Michel Claverie. PNAS. 7 September 2015.
Scientist l Chantal Abergel l T +33 (0)4 91 82 54 22 l firstname.lastname@example.org
Scientist l Jean-Michel Claverie l T +33 (0)4 91 82 54 47 l email@example.com
CNRS Press l Alexiane Agullo l T +33 (0)1 44 96 43 90 l firstname.lastname@example.org