@JustaDumbThriver @aah31415 @CatSquared @Cha @doomlightning @Rocketsgobrrrr
Sorry it took so long to post and finish this round.
Turn 8
Turn 8 Summary:
700 Million Years after the formation of the Phyade I system, life on the Treerilia-Xanrillon is diversifying more and more as time goes on.
Cablevenian Tidepool
Thrivium Lithus (Mutant 6) is still living after all this time. This ancestral organism, one of the first organisms to have Thylakoids, was slowly being out-competed by the new species emerging from it. Thrivium Lithus absolutely survives the night, and it will not die from a lack of Glucose. How long will this organism last?
Lithus uni (Ecotype 50) was the smallest surviving member of the Lithus lineage. Being so small meant it was faster, but it also had less ATP. Having only Thylakoids comes with a cost. In this case, running into the unfixable lag damage bug. Lithus uni also ran into groups of itself, and nearly into a poison cloud hazard. Life is tough for a microbe.
Lithus ambimpetus (Ecotype 51) had the highest active behavior in the Lithus lineage. It would need such a behavior to survive being eaten by larger organisms, like Rümbi pairahydro (Subspecies 50). It managed to evade one large organism and gather a large amount of Phosphate. But then, out of nowhere, Phaüs rombi (Ecotype 39) came in and ate it. Perhaps if it was more active, it may have survived. Lithus ambimpetus has become extinct due to predation pressure.
thrivium triumphes (Ecotype 52) was the only organism to evolve a slightly lower pressure tolerance. This did not help now, but small differences in tolerances are important the survival of life in immediate future. Being a small organism does not help thrivium triumphes to survive now that there are many organisms trying to eat it. Such as Phyting recepta (Mutant 27). Rümbi pairahydro (Subspecies 50), however, was the main nemesis to be concerned about. Near the spawn area, there were several larger organisms, which were barely dodged. After this, clouds of Phosphate and Ammonia were found juxtaposed, line-in-line. Near the end of the journey, a group of this ecotype temporarily blocked the organism, as they were running away from larger organisms. These pack of predator organisms almost engulfed thrivium triumphes, but somehow the organism avoided it (this was super stressful).
Responsitherma calci (Species 18) was the only organism present to successfully evolve a Calcium Carbonate shell. This allowed it to sprint a lot, which made up for its slower forward speed. The organism was able to swerve and juke several Rümbi ammoniaci (Subspecies 51). But then Responsitherma calci ran into a fellow member of its species, slowing it down enough to be eaten by Phyting phyting (Mutant 30). Responsitherma calci has become extinct due to being eaten by larger organism.
Verticus Melanos (Mutant 33) was one two organisms to evolve Melanokoids. Not seen for many millions of years, this Radiation-based organelle give 2 ATP from UV radiation during the day, and 2 ATP from Cytosolic Glycolsis. Not having interactions with other types of organisms did not make Verticus Melanos’ journey “boring” by any means. First, it came across a group of itself. And then, a dead zone of resources. One additional thing Verticus Melanos could do, due to having proper tolerances, was very limited sprinting.
Luxo conversu (Subspecies 65) has inversed organelle reproduction order of its Cytoplasm and Thylakoids, giving the organism slightly higher Photosynthesis. Being a light eater without Proteorhodopsin or Melanokoids, it did not have trouble surviving the Tidepool. The only annoying thing was trying finding Ammonia and Phosphate in a dead zone of resources. Good thing Luxo conversu could sprint a lot due to having excess ATP.
Lux Duo (Subspecies 41), like the genera it spawned, has a Cellulose membrane and more Focused behavior. While this different membrane prevented it from becoming engulfed, the real test was with Garlabius Eta (Mutant 12). Sprinting from resource cloud to resource cloud, Lux Duo avoided the toxic organism whenever it could. Being engulfed, only to come out, and then get hit in the microbial face with Cytotoxin never feels good. And Lux Duo had to endure this for a long time. Eventually, a large gange of Garlabius Eta (Mutant 12) encroached on the organism, and this deadly cycle became a deadly spiral of losing health. The same events, while not in the exact same order, occurred during the second life. Cat Squared has gone extinct from losing too much health by being caught by toxic predator organisms.
Duo devolvo (Species 19) was another very small organism in the Cablevenian Tidepool. Despite being a part of the Duo genera, having a Cellulose membrane was not enough to gain more speed in order to escape Garlabius Eta (Mutant 12). Somehow, this tiny organism managed to survive for a while. Eventually, members of the toxic predator organism blasted the tiny Duo devolvo out of existence. Is there any hope against this toxic onslaught? Duo devolvo went extinct due to overwhelming amounts of Cytotoxin.
Phyting recepta (Mutant 27) was the first organism to evolve two Chemoreceptors. Although they appear redundany, there is a possibility of one of them changing to detect another compound besides Glucose. Phyting recepta attempted to prey upon smaller organisms, like Verticus Melanos (Mutant 33) and Thrivium Lithus (Mutant 6). However, it was too slow to actually catch them, being outcompeted in hunting by larger organisms like Rümbi pairahydro (Subspecies 50). Worse still, came night. It slowly bled through its health, and unlike the heirs of gamblerobacter that had only one Chemoreceptor, the second Chemoreceptor was its death kneel. Phyting recepta became extinct due to a lack of proper ATP balance at night.
Phyting phyting (Mutant 30) was one the organisms that succeeded its ancestor, Chrysium phyto (Species 8). In fact, this was the organism that out competed it. Having an extra Thylakoids meant Phyting phyting was better at occupying the Light Photosynthesis Niche. However, because it was larger, it was also slower. Many microbe collisons occurred with fellow members of this type of mutant. And Phyting phyting took damage from attempting to engulf a small Phosphate chunk.
Archea cellulosu (Ecotype 41) was the first organism to evolve a Cellulose membrane. While this prevented it from being eaten, this organism still suffered from severe health loss at night time. Larger organisms, like Rümbi pairahydro (Subspecies 50), still attempted to eat this inedible organism. Interestingly, if Archea cellulosu gets eaten at the right moment at night, there was a possibility it could be saved from death due to engulfment invulenerablility. While the organism did get engulfed by Roündabouti hydrogeno (Subspecies 57) on the first night, it did not occur on the second night. And on its second life, Archea cellulosu spawned at night, which would be the last night of its life. Archea cellulosu went extinct from a lack of ATP at night.
Cellulosu orthollo (Subspecies 63) had only change compared to its ancestor Archea cellulosu (Ecotype 41). The rotational position of the Chemoreceptor had changed. Cellulosu orthollo was fortunate not to interact with any other organisms, as this meant it was not slowed down in its search for searches (this was mistyped, but it sounded hilarious, so I kept it). Not as though it would have mattered, due to having a currently undigestible Cellulose membrane. Like others in the Archea sublineage, night time was a battle for life and death due to a lack of ATP from light.
Proto meta (Subspecies 59), like its cousin Cellulosu orthollo (Subspecies 63), had a change in rotation position of its Chemoreceptor. Albiet, in a different rotational position than its Cellulosu cousin. Like the rest of the Proto sublineage, Proto meta did not have a Cellulose membrane, but it did have a lack of fear behavior. This light eater took quite a bit of damage at night time, barely living in its endless resource gathering. It did not help that Proto meta was occasionaly blocked by fellow membes of its subspecies.
Macrochrysis deleterio (Mutant 25) had deleted its Cytoplasm, leading to a majority of its ATP coming from Hydrogenase. While it was fine during the day, night was a different story. It appears that a Hydrogenase was insufficient to make enough ATP to live. But Macrochrysis deleterio did not die without fight. The crescent shaped organism managed to eat Lithus uni (Ecotype 50) before it went down to the underworld. Maybe getting rid of the Cytoplasm was too deleterious for its own good. Macrochrysis deleterio became extinct from a lack of ATP at night.
Phaüs roundabouti (Ecotype 38) had a different reproduction order, which is observed in the different sublineages that arose from it. On it quest for life, it encountered several organisms. While Lux Duo (Subspecies 41) cannot be eaten, Thrivium Lithus (Mutant 6) could. It would not be easy to hunt any organism, as Phaüs roundabout was larger and slower. So like any predator, it waited for it prey to come to it. And indeed, it did catch some Thrivium Lithus .
Roündabouti hydrogeno (Subspecies 57) was one two organisms to evolve a second Hydrogenase. This gave it more ATP, but even faster Glucose consumption. And now the organism is even larger and slower. If Roündabouti hydrogeno had been able to interact with other organisms, it may have been able to engulf them. Despite having a large amount of excess ATP created from the two Hydrognases, the larger size meant the organism had very small, if any, sprinting capabilities. Another issue was reproduction time, which was very slow to the slower gathering of resources. Not mention being accidentally pushed by a fellow member of the subspecies into a poison cloud hazard.
Phaüs rombi (Ecotype 39) lost its chemoreceptor, which gave it better ATP balance. Its rhombic shape made have slightly better turning speed, which may have helped it catch smaller organisms. Or even run away from larger ones. Phaüs rombi was not alone, having Proto meta (Subspecies 59) for company. Being too small to eat it, the rhombic organism just shoved its triangular neighbor aside when it could. And getting larger from reproduction only made it slower to catch Proto meta, due to having the Hydrogenase duplicate later on.
Rümbi pairahydro (Subspecies 50) was very similar to Roündabouti hydrogeno (Subspecies 57) in that it had a second Hydrogenase. The key difference was a lack of a Chemoreceptor, which was the main trait of the Rümbi sublineage, giving the organism a higher ATP balance. Another difference was that the second Hydrogenase was located in a different position, giving Rümbi pairahydro a little bit more forward speed and turning speed. Like other light eaters desecended from Macro Phaüs, this organism survived the night time.
Rümbi ammoniaci (Subspecies 51) was the first organism to evolve and live with a Nitrogenase. This was extremely usefull, as it shortened the time needed for reproduction. And based on other organisms, Ammonia always appears to be the limiting resource. Rümbi ammoniaci managed to eat a few thrivium triumphes (Ecotype 52) and Lithus ambimpetus (Ecotype 51), but those were not its main target. This organism was attempting to endosymbiosis Proto meta (Subspecies 59), and it was ultimately successful.
Garlabius Eta (Mutant 12) was the only organism in the Cablvenian Tidepool to have toxin. Although the Delta genera is no longer the only lineage to have Toxisomes, any organism containing these chemical microweapons is not to be messed with. Garlabius Eta has more opportunistic behavior, which makes this organism all the more deadly in the presence of other organisms. Fortunately, or unfortunately, this toxic light eater did not interact with other organisms. Its only foe was the passage of time in finding resources. And the occasional toxic cloud hazards along the way.
Banana Biome
Like the Cablevenian Estuary, the Banana Biome seems to be paradise. But there are dangers in paradise, due to improper pressure tolerances.
Responsivum therma (Subspecies 43) was one of two organism to house a Thermosynthase. Not that it helped much in the Banana Biome. Responsivum therma had a bad spawn, spawning in a very cold area. Unable to find a high enough temperature gradient, this thermophilic subspecies died. However, it was not gone, yet. Having high enough population, Responsivum therma had a second life. This second life was equally unlucky. It was dying not only to a lack of proper temperature gradient, but also a lack of Glucose. Responsivum therma has gone extinct from a lack of ATP.
Responsitherma notherma (Species 20) had lost its thermosynthase, making this species smaller. However, will its more responsive behavior aid in avoiding predators, like Garlabius Delta (Species 7)? Unfortunately, it did not. Responsitherma notherma tried its best to avoid the fired toxins to no avail. Nearly killed by a gang of Cytoxin from Garlabius Delta (Species 7), it was then engulfed by a member of the toxic species. Responsitherma notherma has become extinct to due Cytotoxin and engulfment.
Coccupsidownu apaz (Species 11) was a species with slightly less cordial interactions due to having more aggressive behavior. If it had interacted with anything else, that is. Coccupsidownu apaz only had three options for interactions itself: me, myself, and I. And of course, there was the unfixable lag damage bug, too. But it appeared that Coccupsidownu apaz became panicked, choosing to move, even thought it would damage itself. This caused even more issues, like death. Not once, but twice. A sad day for the Banana Biome, indeed. Coccupsidownu apaz has gone extinct due to taking damage from moving without ATP.
Coccapaz ferrin (Mutant 40), unlike its ancestor, had a Rusticyanin. This fledgling Iron-Eater nearly died when it spawned, having no Iron. Fortunately, at the last second, Coccapaz ferrin was able to obtain Iron. And so, it search for resources continued. After finding large clouds of Ammonnia and Phophate, there very once again no Iron clouds in the vicinity. Nearly dying a second time, Coccapaz ferrin , managed to find a Large Iron chunk. Now all it needed was more Ammonia. And that was when it ran into a deadzone of resources, ultimately dying near the completetion of its cell division (insert raging meme here). Coccapaz ferrin became extinct from a lack of Iron.
Coccupsidownu verticus (Species 15) is similar to other Photosynthetic organisms, except it looks vertical/straight. This gives the organism higher forward speed, but lower rotational speed. Coccupsidownu verticus started well enough, following its sibling as the Banana-shaped Phyade I started to set in the Banana Biome. However, this was where it ran into trouble, as its sibling organism died from a lack of Glucose. Coccupsidownu verticus attempted to stay still to minimize the damage done when it ran out of glucose. Phyade I began to rise, but it was not a rising Banana-shape smile. Due to the view of the star being partially blocked that night by Treerilia’s moon, Xanrillon, the Moon looked like a frown. Coccupsidownu verticus became extinct from a lack of Glucose at night.
Coccupsidownu vertistrango (Mutant 32) had the Cytoplasm change its hex position, giving it slightly higher forward and turning speed. It would need the speed against predators like Macrochrysis temperatus (Mutant 24). Dodging larger organisms right and left, Coccupsidownu vertistrango managed to get to a large Glucose cloud. Phyting squig (Mutant 29), however, managed to belgium the organism hiding in the Glucose cloud. Coccupsidownu vertistrango has gone extinct by eaten by flagelic predator.
Duo photonu (Species 17) has more Foused behavior and a Cellulose membrane, like the rest of the Duo genera. It also has evolved Proteorhodopsin, which gives it more ATP from light. However, it had to deal with Garlabius Delta (Species 7) and its’ Cytotoxin. Having a Celllulose membrane meant Duo photonu took little damage from Cytotoxin. Unfortunately, being surrounded by a toxic predator may have been too much for this organism. Duo photonu went extinct from attempting to tank toxic compounds.
Phyting squig (Mutant 29) was the only organism to have evolved a Flagella. Since this Flagella was small and in a different direction than the one of forward movement, it did not drain that much ATP. However, despite its larger size, this did not deter Garlabius Delta (Species 7) from attacking Phyting squig in defense. Because of the large size, the organism could not move very fast. Phyting squig has gone extinct from attempting to flee Cytotoxins fired at it.
Macrochrysis temperatus (Mutant 24) was another organism with Thermosynthase. Being a larger organism means it could prey upon smaller organisms if it came into contact with them. Unfortunately for Coccupsidownu vertistrango (Mutant 32), it did. While it could not eat Duo photonu (Species 17), a member of Coccupsidownu vertistrango was stuck on a Banana-shaped Large Iron chunk. Beyond finding Banana-shaped resource chunks in its search for resources, nothing else of note occurred. Except for being pushed into a poison cloud.
Garlabius Delta (Species 7) was the only organism in the Banana Biome to have a Toxisome. Knowing this species, it would have attacked any other organism other than itself. While Garlabius Delta did not interact with other organism, it did run into the unfixable lag damage bug. Having nothing else to do, it decide to randomly go in circles when not looking for resources. Almost like a run-and-tumble behavior that would be seen in many Bacteria literally eons later.
Another strange mystery of the Banana Biome occurred, as all surviving organisms became different shades of yellow. Now, these organism looked more like, well, Bananas.
Cablevenian Estuary
Meanwhile in the Cablevenian Estuary, Responsitherma pararoto (Species 21), was dealing with the unfixable lag damage bug. Having a Thermosynthase is normally usefull in very high temperature areas, which continued to make survival tricky for anything with Thermosynthase on the surface. One member of this new species, which had a different position rotation of its Thylakoids, did not appear to help it survive in the Estuary. Responsitherma pararoto had one member of its species die due to not finding the proper temperature gradients, and possibly due to is more responsive behavior. It managed to find a large Phosphate chunk, but then needed to find Ammonia, which it did, eventually.
Coccupsidownu thermoxio (Species 12) had evolved a Thermosynthase and 15% Oxygen Tolerance. Unfortunately, neither of those things helped with surviving this time. The first time, Coccupsidownu thermoxio spawned in a bad spot, and could not generate enough ATP to survive. In the second life, it managed to get to a relatively hotter area and survived by regenerating its health. Until the thermophilic organism was driven away by Heregamblerobacter koinosmesonea (Subspecies 61) from the best spot. Coccupsidownu thermoxio has gone extinct due to a predator organism chasing it.
Coccithermoxio byi (Mutant 36) lost its Thermosynthase, but still had the 15% Oxygen Tolerance. Like other organisms in the Cablevenian Estuary, it had to deal with improper Pressure Tolerances. While the increased Oxygen Tolerance did not help the organism to survive, it may become a usefull trait in its descendants. Its smaller size meant Coccithermoxio byi was faster, but it also did not have as much storage. Fortunately, the Glucose stores were enough for it to survive and gather everything it needed.
Thrivum Lux (Ecotype 29) still survived at all this time. Maybe its more focused behavior was a blessing, after all. Or perhaps not. One daughter cell nearly died, having 3/30 health remaining on the first night. The second daughter cell was not so lucky, dying before Phyade I came up. It seems a star is not always a herald of good things to come. Regardless, Thrivum Lux remained focused on gather resources, being more ambitious over getting to chunks. Only the unfixable lag damage bug stood in the microbe’s way.
Heregamblerobacter koinosmesonea (Subspecies 61) was the only other organism to evolve a toxisome. Having Channel Inhibitors, this was an entirely different toxic predator. If it could move without dying. Unfortuately, the larger organisms like Macrochrysis melanos (Mutant 26) and Rümbi oxo (Subspecies 54) came too close and Heregamblerobacter koinosmesonea had to shoot to scare them off. This caused its downfall. JustaDumbThriver has gone extinct from trying to move without proper ATP due to toxisome recharging.
Heregamblerobacterachea proto (Ecotype 44) had no fear. But this behavior might not be the best for survival in presence of larger organisms, like Rümbi oxo (Subspecies 54). Since it was night time, Heregamblerobacterachea proto could not move due to negative ATP balance. While the first organism without fear managed to avoid the first organism, and at great health cost, it eventually was captured by another organism. Macrochrysis melanos (Mutant 26), the other organism to evolve Melanokoids, cornered the dying organism underneath the full moonshine of Xanrillon. Heregamblerobacterachea proto became extinct by an organism with another colored pigment.
Proto chiti (Subspecies 60) was the only organism that evolved a Chitin membrane. Just like most of the light eaters, night time was very belgium these types of organisms. Its existence at night was on the edge of life and death. Unfortunately, being a part of the Proto sublineage meant Proto chiti was more cavalier with its life, due to having no fear. Thus, one member of this subspecies ended up killing itself, even though another member of the species barely managed to limp on.
Chrysos Macro (Species 5) was the first organism to evolve a Hydrogenase, and has survived for several million years. Now, it faces its biggest hurdle, one of its distant offshoots, Heregamblerobacter koinosmesonea (Subspecies 61). The second hurdle was the unfixable lag damage bug. But Chrysos Macro’s fate was sealed when a troupe of its distant family started to hunt it and fired green-colored Channel Inhibitors at it. Being hit by several of these Channel Inhibiting toins, the organism started to get damage from a lack of ATP. Despite moving away from the heirs of gamblerobacter, the damage would not stop. Chrysos Macro had a second life, and it tried to do its best with gathering resourced. Its best was not enough to avoid Channel Inhibitors. Chrysos Macro has become extinct from dyinig due to Channel Inhibitors.
Roündabouti deproteo (Subspecies 56) had lost one of its Proteorhodopsins. This made the organism more brickshaped. The sister Roündabouti deproteo randomly decided to block its other sibling for no reason, slowing it down. Perhaps due to karma, this other sibling died from a lack of Glucose. Beyond that event, Roündabouti deproteo was just roaming around and getting clouds of Ammonia and Phosphate.
Rümbi oxo (Subspecies 54) was the other organism to have evolved a different environmental tolerance. This 15% Oxygen tolerance did not help it against the Channel Inhibitors of Heregamblerobacter koinosmesonea (Subspecies 61). When the one member of the heirs of gamblerobacter could not fire due to recharging, that toxic organism instead decided to try and push it out of the way. This saving grace allowed Rümbi oxo to go to a new area with less predators, and ultimately survive.
Macrochrysis melanos (Mutant 26) was the only organism in the Cablevenian Estuary to have Melanokoids. Having enough ATP storage, it did not encounter the unfixable lag damage bug. Besides eating some Thrivum Lux (Ecotype 29), it was not fast enough to chase Orthophyta macrevsi (Ecotype 48). Everything else about the resource gathering was pretty standard, including the lack of Ammonia clouds.
Macro orthophyta (Mutant 16.5) was one of the organism that had a Thylakoids in a strange spot. Perhaps that was the reason for why it acted out-of-sorts this time, leading to the deaths of one of its fellow odd-numbered mutant. It nearly died twice, but the Phyade I sun became Macro orthophyta’s beacon of hope for survival. After this, you already know the rest of tale, and that it had a good ending.
Orthophyta macrevsi (Ecotype 48) had lost the Thylakoids that its ancestor had gained. To make it worse, this organism had to face the gauntlet of two toxic organisms. Heregamblerobacter koinosmesonea (Subspecies 61) had Channel Inhibitors, while Delta paraproteo (Mutant 21) had Cytotoxin. Caught in the cross fire of two species at toxic warefare, there was no hope for any survival. Orthophyta macrevsi quite literally had to pick its poison, and neither of them pan out. Orthophyta macrevsi has become extinct due to too many Cytotoxins.
Delta paraproteo (Mutant 21) had an extra Proteorhodopsin compared to the rest of the Delta genera. But it was not only organism with a toxisome. Heregamblerobacter koinosmesonea (Subspecies 61) had Channel Inhibitors instead of Cytotoxin. And when these two toxic organisms met, it was the Good, the Bad, and the Microbe. Delta paraproteo had slightly better ATP ratio, allowing it to move and get two good hits. But on the finish shot, the Cytotoxin got deflected by the slightly better shot incoming from the heir of gamblerbacter. With Delta paraproteo getting hit by Channel Inhibitors, it was all over, as the toxisome inside itself prevented the ATP from balancing properly. However, Heregamblerobacter koinosmesonea also died from a lack of ATP when it the toxisome was recharging, as it had insufficient health to survive. Delta paraproteo went extinct from a duel with another toxic predator.
Cablevenian Underwater cave
Within the Cablevenian Underwater cave, light eaters would have a difficult time surviving the den of darkness.
Upsidownus coccus (Subspecies 30,31,33) was only a single hex of Thylakoids. It managed to survive the previous 25 millions years in the cave environment. Will Upsidownus coccus be lucky this time? Not for the time being. Heading off in the Northwest direction, the unfixable lag damage bug was very annoying, as it could not move. After finding a cloud of Phosphate, Upsidownus coccus ran into a Radiation Chunk, taking some damage. The small organism could not find any Glucose, either, dying at the end. For the second life, Upsidownus coccus went Northeast. It did not find Glucose, but it did find a dreaded Sulfur Cube next to a giant Iron chunk. Hopefully, Upsidownus coccus it isn’t cursed by the Cubic Sulfur chunk. Heading South on its last life, the organism managed to find some resources. Upsidownus coccus, however, could not find enough Glucose to survive, accidentally coming into contact with another Radiaton chunk. Upsidownus coccus has gone extinct from excess Radiation damage.
Cavidownus anoxia (Species 16) evolved from Upsidownus coccus , having a Hydrogenase. Its greater ATP from Glucose meant it did not encounter the unfixable lag damage bug. While this was a plus, the Hydrogenoase also creates higher rate of Glucose consumption, causing the Glucose stores within the cell to deplete faster. Cavidownus anoxia came across a group of its predessor, but it was not fast enough to catch them. Instead, Rümbi fluidus (Subspecies 55) got the bounty. With the opportunity for food gone, Cavidownus anoxia had no way to get Glucose. Cavidownus anoxia has become extinct due to a lack of Glucose in the dark.
Rümbi fluidus (Subspecies 55) has a more fluid membrane than the rest of its fellow Rümbi organisms. The trade off for this was 18% less health. Another issue was the lack of ATP from the lack of light. Since Rümbi fluidus had a Hydrogenosome, it could still move in the darkness, but not for long. It ran into a group of itself, and then attempted to chase Upsidownus coccus . Unfortunately, like all in the Cablevenian Underwater cave, it ran out of Glucose. Rümbi fluidus has gone extinct due to a lack of resources.
Eta confusia (Ecotype 46) was the only member of the Delta genera in the cave, having an inverted reproduction order of its Thylakoids and Proteorhodopsin. It managed to kill Cavidownus anoxia with Cytotoxin, and engulf Upsidownus coccus. However, this was not enough for to Eta confusia live. Its overzealousness with Cytotoxin meant a fellow member of the ecotype died from not having sufficient ATP as the Cytotoxin was replenishing. Eta confusia has gone extinct from a confusing set of circumstances.
…Volcanoes begin to erupt in the Banana Biome, making Macrochrysis temperatus (Mutant 24) extinct. Volcanoes spew lava in the Cablevenian Estuary, making Rümbi oxo (Subspecies 54), Coccithermoxio byi (Mutant 36), and Roündabouti deproteo (Subspecies 56) extinct.
…A fireball is seen over the skies of Treerilia, hitting the Cablevenian Estuary, making Responsitherma pararoto (Species 21), Thrivum Lux (Ecotype 29), Proto chiti (Subspecies 60), Macrochrysis melanos (Mutant 26), and Macro orthophyta (Mutant 16.5) extinct.