Retinalophototroph

A retinalophototroph is one of two different types of photoautotrophs, a subcategory of phototrophs, and are named for retinal-binding proteins they utilize for cell signaling and converting light into energy.[1][2][3][4] Like all photoautotrophs, retinalophototrophs absorb photons to initiate their cellular processes.[2][3][4] However, unlike all photoautotrophs, retinalophototrophs do not use chlorophyll or an electron transport chain to power their chemical reactions.[5][2][3] This means retinalophototrophs are incapable of traditional carbon fixation, a fundamental photosynthetic process that transforms inorganic carbon (carbon contained in molecular compounds like carbon dioxide) into organic compounds.[5][4] For this reason, experts consider them to be less efficient than their photoautotrophic counterparts, chlorophototrophs.[6]

Energy conversion

Retinalophototrophs achieve adequate energy conversion via a proton-motive force.[3][4] In retinalophototrophs, proton-motive force is generated from rhodopsin-like proteins, primarily bacteriorhodopsin and proteorhodopsin, acting as proton pumps along a cellular membrane.[1][4]

To capture photons needed for activating a protein pump, retinalophototrophs employ organic pigments known as carotenoids, namely beta-carotenoids.[7][3][4] Beta-carotenoids present in retinalophototrophs are unusual candidates for energy conversion, but they possess high Vitamin-A activity necessary for retinaldehyde, or retinal, formation.[7][3][4] Retinal, a chromophore molecule configured from Vitamin A, is formed when bonds between carotenoids are disrupted in a process called cleavage.[7][3][4] Due to its acute light sensitivity, retinal is ideal for activation of proton-motive force and imparts a unique purple coloration to retinalophototrophs.[1][4] Once retinal absorbs enough light, it isomerizes, thereby forcing a conformational (i.e., structural) change among the covalent bonds of the rhodopsin-like proteins.[1][3][4] Upon activation, these proteins mimic a gateway, allowing passage of ions to create an electrochemical gradient between the interior and exterior of the cellular membrane.[1][4] Ions diffusing outwards across the gradient through proton pumps are then bound to ATP synthase proteins on the cell’s surface.[1][4] As they diffuse back into the cell, their protons catalyze the creation of ATP (from ADP and a phosphorus ion), providing energy for retinalophototrophic self-sustenance and proliferation.[1][4]

Taxonomy

Retinalophototrophs are found across all domains of life but predominantly in the Bacteria and Archaea taxonomic groups.[5][2][6] Scientists believe retinalophototroph’s general ecological abundance correlates to horizontal, or lateral, gene transfer since only two genes are required for retinalophototrophy to occur: essentially, one gene for retinal-binding protein synthesis (bop) and one for retinal chromophore synthesis (blh).[3][4]

Interactions with environment

Despite their apparent simplicity, retinalophototrophs boast versatile ion usage that translates to their existence in relatively extreme environments.[3] For instance, retinalophototrophs can thrive at depths over 200 meters where, despite a lack of inorganic carbon, sufficient light as well as sodium, hydrogen, or chloride concentrations harbor conditions capable of supporting their vital metabolic processes.[3] Studies have also shown sodium and hydrogen ions correlate directly with retinalophototroph’s nutrient uptake and ATP synthesis, while chloride drives processes responsible for osmotic equilibrium.[4] Even though retinalophototrophs are widespread, research has shown they can be niche too.[1][6] Depending on their proximity to the oceans surface, retinalophototrophs have evolved to be better at absorbing light within specific wavelengths.[1][6] Most importantly, retinalophototrophs prevalence as a primary producer contributes substantially to the bottom-up mechanics of marine environments and, consequently, success of fauna and flora worldwide.[1][6]

References
  1. Béjà, Oded; Spudich, Elena N.; Spudich, John L.; Leclerc, Marion; DeLong, Edward F. (June 2001). "Proteorhodopsin phototrophy in the ocean". Nature. 411 (6839): 786–789. doi:10.1038/35081051. ISSN 0028-0836.
  2. Chew, Aline Gomez Maqueo; Bryant, Donald A (October 2007). "Chlorophyll Biosynthesis in Bacteria: The Origins of Structural and Functional Diversity". Annual Review of Microbiology. 61 (1): 113–129. doi:10.1146/annurev.micro.61.080706.093242. ISSN 0066-4227.
  3. Hallenbeck, Patrick C., ed. (2017). "Modern Topics in the Phototrophic Prokaryotes". doi:10.1007/978-3-319-51365-2. Cite journal requires |journal= (help)
  4. "Academic Press encyclopedia of physical science and technology, 2nd ed". Choice Reviews Online. 35 (02): 35–0665-35-0665. 1997-10-01. doi:10.5860/choice.35-0665. ISSN 0009-4978.
  5. Burnap, Robert; Wim, Vermaas (2012). Functional Genomics and Evolution of Photosynthetic Systems. Springer Netherlands.
  6. Gómez-Consarnau, Laura; Raven, John A.; Levine, Naomi M.; Cutter, Lynda S.; Wang, Deli; Seegers, Brian; Arístegui, Javier; Fuhrman, Jed A.; Gasol, Josep M.; Sañudo-Wilhelmy, Sergio A. (August 2019). "Microbial rhodopsins are major contributors to the solar energy captured in the sea". Science Advances. 5 (8): eaaw8855. doi:10.1126/sciadv.aaw8855. ISSN 2375-2548.
  7. Graham, Joel E.; Bryant, Donald A. (2008-12-15). "The Biosynthetic Pathway for Synechoxanthin, an Aromatic Carotenoid Synthesized by the Euryhaline, Unicellular Cyanobacterium Synechococcus sp. Strain PCC 7002". Journal of Bacteriology. 190 (24): 7966–7974. doi:10.1128/JB.00985-08. ISSN 0021-9193.
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