Are Infectious Viruses Actually Alive?

SciShow

5 May 202111:48

Summary

TLDRViruses are a fascinating, yet perplexing subject in biology, blurring the lines between life and non-life. While traditionally not considered alive due to their inability to reproduce or metabolize on their own, their complexity challenges these definitions. With examples like mimiviruses and mitochondria, the idea of life becomes less clear-cut. Some scientists propose redefining life to include entities like viruses and self-replicating genes, suggesting that all biological entities could be viewed as 'replicators.' This nuanced exploration of life’s boundaries not only deepens our understanding of viruses but also impacts how we might search for life beyond Earth.

Takeaways

😀 Viruses are controversial because they blur the lines between living and non-living things, leading to debates in biology.
😀 Traditional definitions of life focus on hallmarks like metabolism, reproduction, and evolution, but viruses don’t meet these criteria.
😀 Some things we consider 'alive' (like certain bacteria and Wolbachia) lack essential traits that viruses also lack, complicating the definition of life.
😀 Mimiviruses, discovered in 1992, are large and have complex genomes, challenging the idea that viruses lack necessary cellular machinery.
😀 Mitochondria, which are essential parts of eukaryotic cells, were once free-living bacteria, which raises questions about the boundary between life and symbiosis.
😀 There are simpler infectious agents like narnaviruses and plasmids that lack cellular structures, further complicating our understanding of life.
😀 Retroviruses and 'selfish' DNA elements like transposons raise questions about what counts as living and whether they should be considered life forms.
😀 Scientists are proposing new definitions of life, such as considering a virus 'alive' when it hijacks cellular machinery to reproduce and evolve.
😀 One theory suggests that all biological entities, from viruses to elephants, are part of a larger category of 'replicators' that reproduce autonomously.
😀 The study of viruses and the definition of life could provide insights into early Earth conditions and even the search for life beyond our planet.
😀 Different definitions of life can lead to different kinds of scientific questions, such as how to approach the search for life on Mars and other planets.

Q & A

Why are viruses considered not alive by most scientists?
-Viruses are typically considered non-living because they cannot carry out essential life processes like metabolism or reproduction independently. They must hijack the machinery of a host cell to replicate, which leads scientists to exclude them from the traditional definition of life.
How do viruses evolve if they are not considered alive?
-Despite not being considered fully alive, viruses can evolve through a process of mutation and natural selection. This ability to evolve is a key reason why viruses often appear to adapt to new environments or evade medical treatments like vaccines.
What are Mimiviruses and why are they significant in the virus-life debate?
-Mimiviruses are large viruses with complex genomes that challenge the traditional view of viruses. Their genome contains over 900 genes, and they possess some machinery necessary for protein production. This suggests they might have once been able to reproduce independently, raising questions about whether they should be classified as living.
What is the significance of mitochondria in the debate about what is alive?
-Mitochondria, once independent bacteria, now exist as essential organelles inside eukaryotic cells. Despite having their own DNA and the ability to reproduce, mitochondria are not considered alive because they no longer function autonomously, similar to how some argue viruses are not truly alive.
What is the 'virocell' concept?
-The 'virocell' concept suggests that viruses can be considered living cellular organisms once they hijack the machinery of a host cell. In this phase, they can reproduce, metabolize, and evolve, making them more 'alive' than in their virion form (the seed-like version of a virus).
How does the idea of viruses as 'replicators' alter the traditional view of life?
-The 'replicator' concept suggests that all biological entities, from viruses to humans, are essentially units of reproduction. Viruses, like genes or cells, are considered replicators because they can reproduce independently, which shifts the focus away from whether viruses are alive or dead to whether they participate in life processes.
Why do some scientists argue that viruses should be included in the tree of life?
-Some scientists argue that viruses should be included in the tree of life because they play significant roles in evolution, gene transfer, and ecosystem functions. Their ability to influence genetics and shape evolutionary processes suggests that they have an essential biological function.
What role do viruses play in ecosystems, particularly in the ocean?
-Viruses play a critical role in the ocean's nutrient cycle by preying on and breaking apart bacteria and phytoplankton. This helps regulate microbial populations and contributes to the recycling of nutrients, making viruses important players in marine ecosystems.
How can redefining life change how we search for life elsewhere in the universe?
-Redefining life to include more complex processes like replication and evolution—rather than just metabolism—could lead to new ways of searching for life on other planets. For instance, a broader definition could have influenced the choice of experiments during NASA's Viking mission to Mars, potentially leading to different conclusions about the presence of life on Mars.
What is the connection between viruses and the origins of life on Earth?
-Some theories suggest that viruses, or proto-viruses, may have existed before the first cells. This raises intriguing questions about the role viruses could have played in the early stages of life on Earth, possibly influencing the development of cellular life forms or acting as intermediaries in early evolutionary processes.