Naively - I'm assuming that if it is (single-celled) life, and when we get a sample of it, there's two broad categories of options.
Either a) it's the same DNA - in which case some basic panspermia - some material bounced between Venus and Earth, in one or both directions, some billions of years ago, or b) it is demonstrably not the same structure as life on this planet, in which case statisticians get to have a field day.
My understanding is that a half century is not long enough for distance-detectable amounts of phosphine to have been generated by whatever tiny populations we may have accidentally sent over - or that we're likely to have accidentally shipped well-adapted thermophiles on the outside of Soviet probes.
Let's assume, by chance, there's some strain of bacteria that can not only survive but thrive in Venus's environment.
This bacteria is introduced to an environment that has all it needs to spread quickly. There's absolutely nothing out there that it has to compete with. There's nothing out there consuming it or infecting it or otherwise inhibiting its growth other than a lack of whatever nutrient it consumes.
Rabbits went from 0 to over 200 million in under 200 years in Australia, and that's with snakes and disease. Apparently they spread across the continent in just 50 years.[1] Rabbits generally reproduce at a small fraction of the rate of bacteria, although exceptions exist.
Note: I'm not saying humans definitely introduced bacteria to Venus and that's the source. I'm saying if conditions are by some chance ideal, and these things are apparently thriving in the atmosphere, it shouldn't be hard to spread across the planet incredibly fast.
I don't mean this as a counterpoint to your argument, which I think is a valid one, or as any kind of sarcasm. But even as a relative layperson as far as these things go (1 college semester each of bio and o-chem, which I didn't do all that well in) I would be extremely interested in learning about any bacteria that could a) survive on Earth at a large enough scale to find its way onto a Soviet spacecraft; b) survive a trip through space; c) not only survive but thrive on Venus so much so that it reproduces enough for us to pick it up now.
Hopefully if they can get a probe out there they would be able to tell definitively if it was Soviet contamination or not, although I'm not sure how they would be able to do that. I could see them ruling it out (some entirely different DNA structure or something) but not sure how they'd say 100% that it was Soviet in origin.
I have a degee in chem. Your intuition is spot on. Lets assume Venera 3 wasn't sterilized (reports in 1966 say it was [1] but the effectiveness is contested [2]).
Even if spores did survive the space trip (actually quite plausible, [0], venus trip is ~110 days), the atmosphere is extremely dessicating and acidic (SO2, SO3, H2SO4), and the ground is too hot for any known life. The dessication and osmotic pressure is the real kicker. It's very unlikely spores would germinate without rehydration.
Exactly. I do not think that contamination by Venera probes is likely suspect. The atmosphere of Venus has no oxygen and most life on Earth needs oxygen. Even extremophile life on Earth isn't extreme enough for Venus so it would be extraordinary set of circumstances that Venera probe is contaminated with just the right type of bacteria that is then able to adapt to Venus and spread planetwide.
On the first two, bacteria are pretty much ubiquitous and constitute a significant chunk of total biomass on Earth. They can form spores some of which are exceptionally sturdy. It's not too hard to imagine some sort of conditions in which c) can happen - you sent a yeast probe to a sugar water ocean planet but that doesn't sound too much like Venus.
Seems from other comments[0] that the first indicators of these moving phosphene regions were detected a century ago, which would seem to rule out even rapid Soviet contamination?
Those regions contain an unknown substance that absorb UV light. There is currently no connection to this announcement. Though one of the possible causes of those regions is that they are caused by life in Venus’ atmosphere.
There is no connection but one of theories that was proposed for the unknown absorbers was that they are in fact microbes.
So not only do we have no good explanation for phosphine, we do not have a good explanation for the unknown absorbers. Well, we do have one good explanation although it seemed unlikely and that is life. Given that this is second effect that could be explained with microbes I feel it adds that much more weight to the theory.
it reminds me of an (asimov?) book where the plants on a planet live in limelight and when astronauts shine their lights on them they explode with growth.. anyone know it?
You very well may be correct. I have no way of calculating these things. But if the parent comment's DNA sample did actually match Earth-based organisms, you would have no choice but to assume contamination from human probes as the most likely explanation.
> you would have no choice but to assume contamination from human probes as the most likely explanation.
You would have considerable choice; it would be quite obvious whether they'd been on a separate evolutionary trajectory for billions of years or not. That's still the boring outcome, though; not related to us at all would be far more interesting.
Well, we don't know how unlikely it is. It increasingly looks like life showed up on earth almost as soon as it was geologically possible for it to show up, which, if true, would indicate either that abiogenesis is pretty easy or that panspermia is a thing.
It would indicate that, but it's also somewhat expected if we're around to make that observation, which tempers how much information we can take away from it.
However, happening on two adjacent planets would really affect our estimations of the likelihood of abiogenesis.
> It would indicate that, but it's also somewhat expected if we're around to make that observation, which tempers how much information we can take away from it.
Life could have arisen on Earth much later than it did and we could still have been around to see it (or if not us, something like us) so the anthropic principle doesn't apply here. The fact that it arose so early is meaningful.
It is, but it's also sample size of 1. So yes, it indicates something but the confidence interval is really wide. Still, like you point out it's not meaningless as some people do try to argue.
If you take a bayesian approach to the problem it's far more likely that abiogenesis is common. This youtube video does a great job of explaining it: https://youtu.be/iLbbpRYRW5Y
We have basically zero data to tell us whether this outcome is "unlikely" or not. It could very easily turn out that this outcome is overwhelmingly likely.
If they matched, another possibility is that a stable life most easily forms a specific way, or this way only. Knowing for sure wouldn't be possible until more samples are found in the universe.
Nobody is sure, some parts are so nice that perhaps are inevitable, some parts are too random.
DNA and RNA: Perhaps they are inevitable, and any lifeforms have the same molecules and bases. Perhaps some lifeform can use only the methylated versions? Is ribose inevitable? Is 3 bases per codon inevitable? But I think there is a chance for inevitability.
The list of amino acids is somewhat random. We use 20, Some bacteria use a 1 or 2 more. And we can transform in place the amino acid inside a protein into another amino acid. I expect a similar list of 20+-5 amino acids. A perfect coincidence would be too hard, but it is not even true for terrestrial life.
The most interesting part is the Genetic Code https://en.wikipedia.org/wiki/Genetic_code that translate the 4^3=64 combinations of bases in the DNA to the 20 amino acids. As far as we know it is random. It has some internal structure, for example the code is mostly like 16 blocks to encode 15 amino acids and a stop signal, and a few tweaks here and there to break some block to encode the other 5 amino acids. But as far as we know there are no reasons to choose each block as us.
Some bacteria use versions with small tweaks, with one or two changes, so we know it if possible to change it, but very difficult to make a total rewrite.
If the life out there use the same Genetic Code (with a few tweaks) it is almost sure it is related to us.
Along those lines, I had a college professor who had just published a paper (now 25 years old?) talking about why "the 20 amino acids." He was equal parts bombastic and brilliant, and for some reason this paper of his stuck with me all these years.
Now, I'm not an expert or even an advanced layperson in this area, so I won't attempt to speak to the validity of the idea. I merely found the argument interesting at the time.
Did anyone advanced in this research line? It looks like a nice mathematical idea, but it is forced too much to fit into the genetic code.
First they propose a genetic code that is totally unrelated to the current one. It can be perfectly the table of a totally different lifeform. The transition they propose looks too difficult, almost impossible.
Probably we had a transition from RNA to DNA a loooong time ago, but they have a 1 to 1 translation, and the intermediate steps look useful. But no one is sure anyway.
They propose a change where almost all the table changes and almost all the internal structure of the table change.
It is very strange that they have 20 amino acids and no stop code. A proposal with 19 amino acids and a stop code looks more sensible. We know that it is possible to add new amino acids to the table (with enough time). I think the main problem is that using 19 amino acids and a stop code breaks the magical part of predicting the number 20 with pencil and paper.
To make the table work, you need the correct transfer-RNA. To get all the symmetries in their model you need to be really lucky. In the block model of 15+1 you any random selection of tRNA is fine if it ignore the last base.
Another big problem is that they predict that half of the proteins would have been constructed backward. But as they say this make proteins not fold correctly. They try to avoid the problem using palindromic proteins, that is not supported by evidence.
I wish I knew! I'm not in the field, and while I was close with this professor back in school we haven't kept in touch. The paper doesn't seem well cited, but I'm not sure what well cited looks like in this case.
This is about as likely as guessing a 1024 bit encrypted key.
“Match” means “match”. Not “similar structure and behavior”. If it is the same DNA then the only compelling explanation is that it is from the same origin.
Even if it is DNA, if it encodes the same proteins in the same way than the life here would a be very improbable event. Think in an alien alphabet looking like ours, but also making the same sounds and some common words and meanings with the similar looking symbols.
“Origin” in this case would be something in the very physically close and near term. Something that excludes the possibility of serious evolutionary change. Even relatively static species undergo mutations in the long term.
So if something is an exact match it is evident that they came from the same time and place (within some reasonable window). The origin would implicitly be Earth in the 1960s.
“Matching DNA” has only one meaning that I am aware of and it is an exact 1:1 sequence. The goal is to identify a living organism from DNA that has fallen off it.
There is an old line of thought on this, that views DNA/RNA as crystals. Crystals branch out/reproduce in predictable or unpredictable ways depending on scale. At large scales a dry lakebed may seem a mass of randomly-aligned crystals but at the smallest scale each crystal is identical. They each formed from the same starting conditions from which random precursors settled into identical patterns. Such logic would suggest that DNA/RNA, if beginning in near-identical conditions, might also settle into nearly-identical patterns. At large scales the crystals would appear different and random but at the smallest scales life could well be similar or even identical... if one sees life as a form of crystal.
Even if there's a "good reason" that life forms in a specific way (e.g. water + carbon based, RNA & DNA encoding information, etc.) there's very little reason that DNA should encode proteins in exactly the way ours does (on Earth-based life, AFAIK the code is nearly universal, indicating common origin).
While there might be eartg life that can live in those extreme environments, that type of life usually can't live at what we consider more comfortable temperatures and couldn't survive being on the probe while it was on earth being loaded into s rocket etc. That's why even though there is life that thrives in the cknditions inside an autoclave (pressure/steam cookers used to sterilize things in labs or medicine), you don't have to worry about them since they can only survive in those conditions.
There is a possibly habitable layer (for non-extremophiles) in the atmosphere of Venus. Microbes live in Earth's atmosphere.
This of course does not account for other differences such as the rate at which microbes are transported into Earth's atmosphere, and whether that possibly habitable layer on Venus is stable enough to sustain a population.
That layer of Venus’ atmosphere isn’t habitable even for Earth extremeophiles. It’s true that the pressure and temperature are similar to that of the Earth, but the only water there is contained in droplets of nearly pure sulfuric acid. No known extremeophiles can survive that.
That is true and could be a way for anthropogenic panspermia to occur. My totally uneducated gut feeling is that the chemists and geologists are going to get more out of this finding than the biologists though. Theres a lot of cool rocks and an atmosphere full of SO2 (a pretty decent reducing agent) on venus - and abiogenic phosphenes are found in other parts of the solar system. Some chemical reaction with perhaps some recently expelled volcanic ash (there was recent evidence that it might still have active volcanic activity right?) seems more plausible than life, but hey, thats why we have experiments to see if the unlikely is true after all!
I know this would be tough and take a long time but we could have 2 extra planets with enough work.
1. Bombarded mars with junk (everything from the astroid belt and some rocks from the kuipler belt) to raise its mass to somewhat earth level. We'd have to be careful not to mess up Mars's orbit too much.
2. Slurp some of venus's thick atmosphere into a massive space tanker
3. Dump the atmosphere onto Mars++
4. Let time and some engineered bacteria/plants clean up the mess
The idea that these regions may contain life (and the observations that suggest this) predate those probes.
That doesn’t rule out a ‘contamination’. But considering this is just another observation in a long line of interesting data I think makes it less likely.
Last time I checked, which was about four years ago, the conditions on Venus 40km were such that humans could walk around outside with nothing more than an oxygen supply.
> the conditions on Venus 40km were such that humans could walk around outside with nothing more than an oxygen supply.
The Wikipedia page on Venus's atmosphere suggests that at that altitude Venus's atmosphere is a sulphuric acid haze at 110°C and about 2atm of pressure, which, even if there was something to walk on, doesn't sound like you'd be able to walk around with just an oxygen supply for very long.
Which as far as I can tell isn't terrible if you don't breath it in and if you do the official allowed exposure time is 10 minutes for 5 ppm. I would recommend you wear goggles in addition to breathing equipment, though.
> Which as far as I can tell isn't terrible if you don't breath it in and if you do the official allowed exposure time is 10 minutes for 5 ppm.
Presumably that's 5ppm under terrestrial conditions, Venus at 40km has substantially higher pressure, more than is explained by the higher temperature alone, so any given ppm is a greater number of molecules per cm³, right?
7 ppm of atomized H2SO4 will definitely sting a bit. That's roughly 7 g/m^3, TLV for sulfuric acid mist is 1 mg/m^3. Survivable but you would want to minimize time in it.
Panspermia could work via both planets moving through nebulae and space dust that contained biological compounds, it doesn't have to be direct seeding from one planet to the other because they're both moving through millions of miles of spatial debris and rocks and dust as the milky way moves.
Either a) it's the same DNA - in which case some basic panspermia - some material bounced between Venus and Earth, in one or both directions, some billions of years ago, or b) it is demonstrably not the same structure as life on this planet, in which case statisticians get to have a field day.