Crossing barriers: How the rabbit virus myxoma leapt into a new species


Date:
April 26, 2022
Source:
Arizona State University
Summary:
New research explores the spillover of myxoma virus from European
rabbits to Iberian hares. In addition to shedding new light on
species-jumping viruses, the study shows that the protein permitting
the species jump from rabbits to hares may help improve myxoma as
a cancer-fighting agent.



FULL STORY ========================================================================== Viruses are among the most protean entities in nature, ceaselessly
mutating and acquiring new characteristics. These tiny entities follow
a simple and relentless imperative: infect as many host organisms as
possible. Occasionally, a virus' genomic alterations enable it to leap
from one species to another, in a process known as spillover.


==========================================================================
In new research appearing in the journal mBio,Masmudur Rahman and his
Arizona State University colleagues join international researchers
to investigate one such spillover event, when the myxoma virus (MYXV)
made a species leap from European rabbits to Iberian hares.

The study describes M159, a virus protein called a "host range factor"
that arose very recently through a fortuitous gene pickup in the myxoma
virus. The resultant hybrid strain, known as MYXV-Tol, has enabled the
virus to expand its existing host range, traversing the species barrier
and causing lethal disease in Iberian hares.

Researchers would like to better understand these genomic transitions,
as spillover events have profound implications for both human and
animal health.

One such recent event, caused by mutations in a novel, SARS-like virus
of unknown origin, is responsible for the global pandemic of COVID-19
disease, which has killed over five million people globally.

Understanding the subtle alterations enabling viruses to make species
jumps may help better prepare for outbreaks of new diseases, limit their transmission, and perhaps allow researchers to outwit viral mechanisms
that set the stage for spillover events. Human-engineered therapies
against pathogens (including viruses) are part of a never-ending arms
race between infectious agents and their host organisms.

In addition to its importance for the study of host- pathogen coevolution, myxoma virus has been investigated for its remarkable ability to target
and kill human cancer cells, while leaving their normal healthy cell counterparts unharmed. It is one of the most promising viruses available
in the new field of virotherapy, which uses cancer fighting or oncolytic viruses, including myxoma.



==========================================================================
The new study suggests that the M159 protein not only enables MYXV-Tol
to leap over the species barrier and infect hares but also appears to
help this strain replicate even better in human cancer cells, potentially improving MYXV as a cancer-fighting agent.

"M159 protein is a member of the poxvirus C7-like host range factors. In
the future, identifying the protein(s) that interact with M159 in hares
and human cancer cells will allow us to understand whether M159 targets
similar or diverse signaling pathways," said Rahman.

Rahman is a researcher in the Biodesign Center for Immunotherapy, Vaccines
and Virotherapy at ASU. He is joined by Grant McFadden, director of
the center and by Arvind Varsani, a researcher in the Biodesign Center
for Fundamental and Applied Microbiomics. McFadden, Varsani and Rahman
are also researchers in ASU's School of Life Sciences. Additional ASU researchers include first author Ana Agueda-Pinto, Simona Kraberger,
Anne Everts, Ami Gutierrez-Jensen and Honor L. Glenn.

Collaborators on the new study include researchers from Universidade
do Porto, Vaira~o, Portugal; Universidad de Oviedo, Campus El Cristo,
Oviedo, Spain; and (IRIAF), CIAG del Chaparrillo, Ciudad Real, Spain.

Specialized killer In studying the mechanisms underlying the ability
of viruses to cross species barriers, researchers rely on model
organisms. The myxoma virus is a particularly attractive candidate for
such investigations and is the most extensively researched field model
for this type of study. This fact is due to a historical event in which
MYXV was used to control populations of European rabbits in Europe and Australia, beginning in 1950.



==========================================================================
MYXV belongs to the poxvirus family of viruses, a very large assemblage
of double-stranded DNA viruses which includes many benign members as well
as the virus that once caused the notoriously lethal disease smallpox.

Many kinds of viruses have spillover potential. Annual outbreaks of
influenza, for example, are the result of spillover events occurring when migratory birds, acting as reservoirs for the virus, spread the disease to other species, including ducks, chickens, pigs and humans. As the virus
moves from species to species, mutating strains acquire new abilities
to aid their transmission and ability to evade host immune defenses.

Although the natural hosts of the MYXV virus are Sylvilagus rabbits (known
in the Americas as cottontails), exposure of European rabbit populations
to this virus proved 99% fatal, without any further adaptation of the
virus to the European rabbit host. The highly contagious virus, spread
through rabbit populations by fleas or mosquitos, produces a lethal
rabbit disease known as myxomatosis. MYXV-Tol was found to cause a very
similar lethal disease in hares.

Over the long term, the rabbit control strategy with MYXV failed,
as evolutionary selective pressures acting on both the virus
and host resulted in MYXV-resistant rabbits and attenuated virus
variants. Nevertheless, MYXV provides a valuable laboratory tool for
the study of the poorly understood dance between infectious agents and
the molecular transformations used by species to thwart them.

"Every time a virus leaps from one host species into another, we learn something new about Mother Nature," McFadden says. "In the case of
MYXV-Tol, we learned that the acquisition of a single new virus gene
allowed this new virus strain access to a new host species that was
previously resistant to the virus." New virus on the block Evidence
suggests that Iberian hares had long been exposed to MYXV or a similar
virus since at least the 1990's, with no resulting outbreak of myxomatosis occurring. Then, an altered virus strain known as MYXV-Tol appeared,
seemingly out of nowhere. This new variant showed high similarity to
the previously endemic form of the virus, known as MYXV-Lau, with
one notable genomic exception. The new strain had acquired a small
suite of new genes, which it acquired through recombination with an as-yet-unidentified poxvirus. The result was a supercharged variant that
proved both infectious and highly lethal to hares living on the Iberian Peninsula, killing hundreds of them beginning in the Autumn of 2018.

Among the genes found in the MYXV-Tol variant was a gene coding for a
protein known as M159. The new study explores this single protein as a
possible culprit in MYXV-Tol's species-hopping capacity. The researchers examined laboratory cell lines of rabbit, hare and human cells exposed
to MYXV variants with and without the M159 protein.

While strains containing the novel protein did not appear more infectious
to cells of European rabbits, the M159-containing strains were now
highly infectious to cells from European hares, whereas strains without
the protein were not, establishing M159 as the key ingredient allowing
MYXV to cross the species barrier.

The study also tested two human cancer cell lines that are normally
resistant to MYXV, exposing them to the M159-enhanced version. The
results were dramatic.

Human pancreatic cancer and melanoma cells are typically semipermissive or nonpermissive to MYXV, meaning that the virus usually replicates poorly
in these cell types. However, when the M159 protein was inserted into
the MYXV-Lau strain, viral replication in both cancer cell lines was significantly enhanced, suggesting the protein could be used to improve
MYXV as a cancer-fighting agent against some classes of human tumors.

Further research promises to shed new light on the highly pathogenic
MYXV-Tol variant as well as illuminate the mechanisms used by other
poxviruses to spillover into new animal species, including humans.


========================================================================== Story Source: Materials provided by Arizona_State_University. Original
written by Richard Harth. Note: Content may be edited for style and
length.


========================================================================== Journal Reference:
1. Ana A'gueda-Pinto, Simona Kraberger, Anne Everts, Ami
Gutierrez-Jensen,
Honor L. Glenn, Kevin P. Dalton, Ana Podadera, Francisco Parra,
Monica Martinez-Haro, Jose' Alberto Vin~uelas, Arvind Varsani, Grant
McFadden, Masmudur M. Rahman, Pedro J. Esteves. Identification
of a Novel Myxoma Virus C7-Like Host Range Factor That Enabled
a Species Leap from Rabbits to Hares. mBio, 2022; 13 (2) DOI:
10.1128/mbio.03461-21 ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2022/04/220426153639.htm

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