I’m more in protein design than origin of life, so it may be that people in that field have more informed opinions. That said, I think most people agree that life on earth, regardless of where it started out, started with self-assembling self-replicating RNAs, so the logic is pretty simply that if we’re finding nucleic acids out in space it’s likely the same life. Unlike amino-acids which are the smallest polymer with a solvent byproduct, there’s nothing about nucleic acids that makes that molecule (those base pairs or closely related bases) special or optimal. I’m more protein than RNA, so maybe someone else has a different opinion, but to me it seems like it’d be almost trivial to come up with alternative bases or even modified backbones that meet the broad requirements of folding (for functions) and dimerizing (for genes).
Additionally, (and I know a lot less about this) apparently Mars had a lot of water for quite some time but loss most of it due to the lack of a magnetic field. So add in some asteroids flinging stuff off the planet and the timeline may add up.
Panspermia may not be the right term. I think panspermia is generally discussed among the public as life coming from outside the solar system, and I think most scientists would be extremely skeptical of that notion. Space is a really harsh environment and the odds of randomly getting between solar systems in bad before you start talking about survival parameters. I suspect you’d find more people who think an in-solar-system panspermia event occurred than life evolving twice in one solar system and both converged on the same base genetic molecules, and it’s increasingly obvious that the life on mars hypothesis is at least worth testing, so that’s the narrative. Perhaps I should’ve said Mars-spermia.
As I understand it we’ve identified nucleobases outside of Earth, but not nucleic acids. I don’t personally know how big a step it is between those components and then some actual assembled nucleic acids, but it’s definitely farther removed from what we generally consider to be life.
apparently Mars had a lot of water for quite some time
It did lose a lot, but it also still has quite a lot! It’s just mostly frozen and underground
Space is a really harsh environment and the odds of randomly getting between solar systems in bad before you start talking about survival parameters
While I agree, isn’t that still true for an in-solar-system event? It’s a lot less space, but we’re still going from “a ludicrous distance more than humans can really conceptualise” to “also a ludicrous distance more than humans can really conceptualise even though it’s orders of magnitude smaller”
I do agree that it’s absolutely worth testing, though, because whatever we find or disprove is interesting to know
I’m more in protein design than origin of life, so it may be that people in that field have more informed opinions. That said, I think most people agree that life on earth, regardless of where it started out, started with self-assembling self-replicating RNAs, so the logic is pretty simply that if we’re finding nucleic acids out in space it’s likely the same life. Unlike amino-acids which are the smallest polymer with a solvent byproduct, there’s nothing about nucleic acids that makes that molecule (those base pairs or closely related bases) special or optimal. I’m more protein than RNA, so maybe someone else has a different opinion, but to me it seems like it’d be almost trivial to come up with alternative bases or even modified backbones that meet the broad requirements of folding (for functions) and dimerizing (for genes).
Additionally, (and I know a lot less about this) apparently Mars had a lot of water for quite some time but loss most of it due to the lack of a magnetic field. So add in some asteroids flinging stuff off the planet and the timeline may add up.
Panspermia may not be the right term. I think panspermia is generally discussed among the public as life coming from outside the solar system, and I think most scientists would be extremely skeptical of that notion. Space is a really harsh environment and the odds of randomly getting between solar systems in bad before you start talking about survival parameters. I suspect you’d find more people who think an in-solar-system panspermia event occurred than life evolving twice in one solar system and both converged on the same base genetic molecules, and it’s increasingly obvious that the life on mars hypothesis is at least worth testing, so that’s the narrative. Perhaps I should’ve said Mars-spermia.
As I understand it we’ve identified nucleobases outside of Earth, but not nucleic acids. I don’t personally know how big a step it is between those components and then some actual assembled nucleic acids, but it’s definitely farther removed from what we generally consider to be life.
It did lose a lot, but it also still has quite a lot! It’s just mostly frozen and underground
While I agree, isn’t that still true for an in-solar-system event? It’s a lot less space, but we’re still going from “a ludicrous distance more than humans can really conceptualise” to “also a ludicrous distance more than humans can really conceptualise even though it’s orders of magnitude smaller”
I do agree that it’s absolutely worth testing, though, because whatever we find or disprove is interesting to know