Broad spectrum of mimiviridae virophage allows its isolation using a mimivirus reporter.

The giant virus Mimiviridae family includes 3 groups of viruses: group A (includes Acanthamoeba polyphaga Mimivirus), group B (includes Moumouvirus) and group C (includes Megavirus chilensis). Virophages have been isolated with both group A Mimiviridae (the Mamavirus strain) and the related Cafeteria roenbergensis virus, and they have also been described by bioinformatic analysis of the Phycodnavirus. Here, we found that the first two strains of virophages isolated with group A Mimiviridae can multiply easily in groups B and C and play a role in gene transfer among these virus subgroups. To isolate new virophages and their Mimiviridae host in the environment, we used PCR to identify a sample with a virophage and a group C Mimiviridae that failed to grow on amoeba. Moreover, we showed that virophages reduce the pathogenic effect of Mimivirus (plaque formation), establishing its parasitic role on Mimivirus. We therefore developed a co-culture procedure using Acanthamoeba polyphaga and Mimivirus to recover the detected virophage and then sequenced the virophage's genome. We present this technique as a novel approach to isolating virophages. We demonstrated that the newly identified virophages replicate in the viral factories of all three groups of Mimiviridae, suggesting that the spectrum of virophages is not limited to their initial host.

Provirophages and transpovirons as the diverse mobilome of giant viruses.

A distinct class of infectious agents, the virophages that infect giant viruses of the Mimiviridae family, has been recently described. Here we report the simultaneous discovery of a giant virus of Acanthamoeba polyphaga (Lentille virus) that contains an integrated genome of a virophage (Sputnik 2), and a member of a previously unknown class of mobile genetic elements, the transpovirons. The transpovirons are linear DNA elements of ~7 kb that encompass six to eight protein-coding genes, two of which are homologous to virophage genes. Fluorescence in situ hybridization showed that the free form of the transpoviron replicates within the giant virus factory and accumulates in high copy numbers inside giant virus particles, Sputnik 2 particles, and amoeba cytoplasm. Analysis of deep-sequencing data showed that the virophage and the transpoviron can integrate in nearly any place in the chromosome of the giant virus host and that, although less frequently, the transpoviron can also be linked to the virophage chromosome. In addition, integrated fragments of transpoviron DNA were detected in several giant virus and Sputnik genomes. Analysis of 19 Mimivirus strains revealed three distinct transpovirons associated with three subgroups of Mimiviruses. The virophage, the transpoviron, and the previously identified self-splicing introns and inteins constitute the complex, interconnected mobilome of the giant viruses and are likely to substantially contribute to interviral gene transfer.

Legionella tunisiensis sp. nov. and Legionella massiliensis sp. nov., isolated from environmental water samples.

Two isolates of intra-amoeba-growing bacteria, LegA(T) ( = DSM 24804(T) = CSUR P146(T)) and LegM(T) ( = DSM 24805(T) = CSUR P145(T)), were characterized on the basis of microscopic appearance, staining characteristics, axenic growth at different temperatures and the sequences of the mip, rpoB, 16S rRNA and rnpb genes, as well as the 23S-5S region. Phylogenetic analysis showed that these two isolates lay within the radius of the family Legionellaceae. Furthermore, the analysis of these genes yielded congruent data that indicated that, although strain LegM(T) clusters specifically with Legionella feeleii ATCC 35072(T) and LegA(T) clusters with Legionella nautarum ATCC 49596(T), the divergence observed between these species was greater than that observed between other members of the family. Taken together, these results support the proposal that these two isolates represent novel members of the genus Legionella, and we propose to name them Legionella tunisiensis sp. nov. for LegM(T) ( = DSM 24805(T) = CSUR P145(T)) and Legionella massiliensis sp. nov. for LegA(T) ( = DSM 24804(T) = CSUR P146(T)).

Virus géants associés aux amibes.

The discovery of Acanthamoeba polyphaga Mimivirus, a giant amoeba-associated virus less than a decade ago, has shattered the definition of what is a virus. With an exceptional size of 500 nm, a genome of more than 1 Mb, a particle containing both DNA and RNA, possibility to be infected by another virus are unusual characteristics that make it immediately exceptional. Since then, several giant viruses have been isolated such as Marseillevirus. It is highly probable that closely related viruses will be isolated as it is now understood that they were not previously isolated because they are not filterable. Environmental metagenomic studies suggest that these viruses are ubiquitous. The discovery of virophages, small viruses able to infect Mimivirus as bacteriophage infect bacteria, fuel the debate about the nature of viruses and their place in the evolution of life. Current works, especially genome sequencing of these new viruses, open new perspectives about evolution and lateral gene transfer with their host but also with bacteria and other viruses. The knowledge about these viruses is only at the first step and increasing interest for it suggests that we are only at the dawn of the understanding of their role in evolution and ecosystems regulation.

Mimivirus shows dramatic genome reduction after intraamoebal culture.

Most phagocytic protist viruses have large particles and genomes as well as many laterally acquired genes that may be associated with a sympatric intracellular life (a community-associated lifestyle with viruses, bacteria, and eukaryotes) and the presence of virophages. By subculturing Mimivirus 150 times in a germ-free amoebal host, we observed the emergence of a bald form of the virus that lacked surface fibers and replicated in a morphologically different type of viral factory. When studying a 0.40-µm filtered cloned particle, we found that its genome size shifted from 1.2 (M1) to 0.993 Mb (M4), mainly due to large deletions occurring at both ends of the genome. Some of the lost genes are encoding enzymes required for posttranslational modification of the structural viral proteins, such as glycosyltransferases and ankyrin repeat proteins. Proteomic analysis allowed identification of three proteins, probably required for the assembly of virus fibers. The genes for two of these were found to be deleted from the M4 virus genome. The proteins associated with fibers are highly antigenic and can be recognized by mouse and human antimimivirus antibodies. In addition, the bald strain (M4) was not able to propagate the sputnik virophage. Overall, the Mimivirus transition from a sympatric to an allopatric lifestyle was associated with a stepwise genome reduction and the production of a predominantly bald virophage resistant strain. The new axenic ecosystem allowed the allopatric Mimivirus to lose unnecessary genes that might be involved in the control of competitors.

Tentative characterization of new environmental giant viruses by MALDI-TOF mass spectrometry.

OBJECTIVE: Metagenomic studies have revealed that Acanthamoeba polyphaga Mimivirus relatives are common in the environment; however, only three Acanthamoeba-growing giant viruses have been isolated from hundreds of environmental samples. We attempted herein to isolate new Acanthamoeba-growing giant viruses from environmental samples. METHODS: We inoculated 105 environmental samples by our usual procedure but with the addition of selected antibiotics to inhibit bacterial overgrowth. RESULTS: We isolated 19 giant viruses with capsid sizes of 150 to 600 nm, including one associated with a virophage. For the first time some were isolated from saltwater and soil samples. Tentative characterization using the PolB gene sequence was possible for some of these viruses. They were closely related to each other but different from the two previous isolates of Acanthamoeba polyphaga Mimivirus. Results obtained by MALDI-TOF MS analysis of viral particles were congruent with that of PolB sequencing. CONCLUSION: Our data confirm that Acanthamoeba-growing giant viruses are common in the environment. Additionally, MALDI-TOF MS analysis can be used for the initial screening of new viruses to avoid redundant analysis. However, due to their genetic variability, it is likely that the genome sequences of most of these viruses will have to be determined for accurate classification.