Chemosynthesizing Proteins: Difference between revisions
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| organelle = Chemosynthesizing Proteins | | organelle = Chemosynthesizing Proteins | ||
| icon = ChemoProteinsIcon.png | | icon = ChemoProteinsIcon.png | ||
| image = | | image = ChemosynthesizingProteinsOrganelle.png | ||
| cost = 45 | | cost = 45 | ||
| requiresNucleus = No | | requiresNucleus = No | ||
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}} | }} | ||
Small clusters of protein in the '''[[Cytoplasm]]''' that convert '''Hydrogen Sulfide''' {{CompoundIcon|image=HydrogenSulfideIcon.png|internalName=hydrogensulfide}}, gaseous '''Carbon Dioxide''' {{CompoundIcon|image=CarbonDioxideIcon.png|internalName= | Small clusters of protein in the '''[[Cytoplasm]]''' that convert '''Hydrogen Sulfide''' {{CompoundIcon|image=HydrogenSulfideIcon.png|internalName=hydrogensulfide}}, gaseous '''Carbon Dioxide''' {{CompoundIcon|image=CarbonDioxideIcon.png|internalName=carbondioxide}} and water into '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}} in a process called '''Bacterial Chemosynthesis'''. The rate of '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}} production scales with the concentration of '''Carbon Dioxide''' {{CompoundIcon|image=CarbonDioxideIcon.png|internalName=carbondioxide}}. | ||
== Requirements == | == Requirements == | ||
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== Processes == | == Processes == | ||
'''Bacterial Chemosynthesis:''' '''Hydrogen Sulfide''' {{CompoundIcon|image=HydrogenSulfideIcon.png|internalName=hydrogensulfide}} + '''Carbon Dioxide''' {{CompoundIcon|image=CarbonDioxideIcon.png|internalName= | '''Bacterial Chemosynthesis:''' '''Hydrogen Sulfide''' {{CompoundIcon|image=HydrogenSulfideIcon.png|internalName=hydrogensulfide}} + '''Carbon Dioxide''' {{CompoundIcon|image=CarbonDioxideIcon.png|internalName=carbondioxide}} → '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}} | ||
Converts '''Hydrogen Sulfide''' {{CompoundIcon|image=HydrogenSulfideIcon.png|internalName=hydrogensulfide}} into '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}}. Rate scales with concentration of environmental '''Carbon Dioxide''' {{CompoundIcon|image=CarbonDioxideIcon.png|internalName= | Converts '''Hydrogen Sulfide''' {{CompoundIcon|image=HydrogenSulfideIcon.png|internalName=hydrogensulfide}} into '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}}. Rate scales with concentration of environmental '''Carbon Dioxide''' {{CompoundIcon|image=CarbonDioxideIcon.png|internalName=carbondioxide}}. | ||
'''Glycolysis''': '''Glucose''' '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}} → '''ATP''' {{CompoundIcon|image=ATPIcon.png|internalName=atp}} | '''Glycolysis''': '''Glucose''' '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}} → '''ATP''' {{CompoundIcon|image=ATPIcon.png|internalName=atp}} | ||
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== Strategy == | == Strategy == | ||
With '''Chemosynthesizing Proteins''', cells gain access to one of the most abundant and reliable sources of energy in the volcanic vents, '''Hydrogen Sulfide''' {{CompoundIcon|image=HydrogenSulfideIcon.png|internalName=hydrogensulfide | With '''Chemosynthesizing Proteins''', cells gain access to one of the most abundant and reliable sources of energy in the volcanic vents, '''Hydrogen Sulfide''' {{CompoundIcon|image=HydrogenSulfideIcon.png|internalName=hydrogensulfide}}. This can be stockpiled and steadily processed into '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}}, allowing for more energy stores to be held at one time. | ||
To build an effective chemosynthesizing bacteria, you only need enough '''Chemosynthesizing Proteins''' to generate a net increase of '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}} within the cell. A great way to start is by placing two '''Chemosynthesizing Proteins''' in the first generation, then '''[[Metabolosomes]]''' and whichever part you would prefer to power in the generation after. From there on, it is typically safe practice to only place an additional hex of '''Chemosynthesizing Proteins''' per every two other parts. | To build an effective chemosynthesizing bacteria, you only need enough '''Chemosynthesizing Proteins''' to generate a net increase of '''Glucose''' {{CompoundIcon|image=GlucoseIcon.png|internalName=glucose}} within the cell. A great way to start is by placing two '''Chemosynthesizing Proteins''' in the first generation, then '''[[Metabolosomes]]''' and whichever part you would prefer to power in the generation after. From there on, it is typically safe practice to only place an additional hex of '''Chemosynthesizing Proteins''' per every two other parts. | ||
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== Scientific Background == | == Scientific Background == | ||
[https://en.wikipedia.org/wiki/Chemosynthesis Chemosynthesis] is a metabolic process found in many real-world microbes, where it essentially serves as an alternative to photosynthesis. Whereas photosynthesis utilizes photons from sunlight to provide energy for chemical reactions, chemosynthesis instead uses the oxidation of inorganic compounds such as iron or hydrogen sulfide to provide energy. | |||
As an example, hydrogen sulfide chemosynthesis can be summarized by the following chemical equation: | |||
18H<sub>2</sub>S + 6CO<sub>2</sub> + 3O<sub>2</sub> → C<sub>6</sub>H<sub>12</sub>O<sub>6</sub> (carbohydrate) + 12H<sub>2</sub>O + 18S | |||
In the above reaction, hydrogen sulfide serves as a source of electrons as it reacts with carbon dioxide and oxygen, resulting in the formation of a carbohydrate molecule along with water and free sulfur atoms. Thus, while photosynthesis results in the release of oxygen gas, hydrogen sulfide chemosynthesis produces sulfur, which typically aggregates into solid globules. | |||
Latest revision as of 19:06, 8 July 2025
| Organelle Details | |
|---|---|
| Chemosynthesizing Proteins |  |
| |
| Base Cost (MP) | 45 |
| Requires Nucleus | No |
| Processes | Bacterial Chemosynthesis, Glycolysis |
| Enzymes | None |
| Size (Hexes) | 1 |
| Osmoregulation Cost | 1 |
| Storage | 0.5 |
| Unique | No |
| Upgrades | None |
| Internal Name | chemoSynthesizingProteins |
Small clusters of protein in the Cytoplasm that convert Hydrogen Sulfide 
, gaseous Carbon Dioxide 
and water into Glucose 
in a process called Bacterial Chemosynthesis. The rate of Glucose production scales with the concentration of Carbon Dioxide .
Requirements
No requirements.
Processes
Bacterial Chemosynthesis: Hydrogen Sulfide + Carbon Dioxide → Glucose
Converts Hydrogen Sulfide into Glucose . Rate scales with concentration of environmental Carbon Dioxide .
Glycolysis: Glucose Glucose → ATP 
Since Chemosynthesizing Proteins are suspending in Cytoplasm, they also perform some Glycolysis.
Modifications
No modifications.
Effects
No special effects.
Upgrades
No upgrades.
Strategy
With Chemosynthesizing Proteins, cells gain access to one of the most abundant and reliable sources of energy in the volcanic vents, Hydrogen Sulfide . This can be stockpiled and steadily processed into Glucose , allowing for more energy stores to be held at one time.
To build an effective chemosynthesizing bacteria, you only need enough Chemosynthesizing Proteins to generate a net increase of Glucose within the cell. A great way to start is by placing two Chemosynthesizing Proteins in the first generation, then Metabolosomes and whichever part you would prefer to power in the generation after. From there on, it is typically safe practice to only place an additional hex of Chemosynthesizing Proteins per every two other parts.
Be wary however, as Hydrogen Sulfide is only present in a select few biomes in the world. Evolving yourself to rely on it as your primary energy source will effectively prevent you from safely traveling to many other environments.
Scientific Background
Chemosynthesis is a metabolic process found in many real-world microbes, where it essentially serves as an alternative to photosynthesis. Whereas photosynthesis utilizes photons from sunlight to provide energy for chemical reactions, chemosynthesis instead uses the oxidation of inorganic compounds such as iron or hydrogen sulfide to provide energy.
As an example, hydrogen sulfide chemosynthesis can be summarized by the following chemical equation:
18H2S + 6CO2 + 3O2 → C6H12O6 (carbohydrate) + 12H2O + 18S
In the above reaction, hydrogen sulfide serves as a source of electrons as it reacts with carbon dioxide and oxygen, resulting in the formation of a carbohydrate molecule along with water and free sulfur atoms. Thus, while photosynthesis results in the release of oxygen gas, hydrogen sulfide chemosynthesis produces sulfur, which typically aggregates into solid globules.