Biophysical evidence to support and extend the vitamin D-folate hypothesis as a paradigm for the evolution of human skin pigmentation

Lucock, Mark D.; Jones, Patrice R.; Chaplin, George; Beckett, Emma L.; Veysey, Martin; Thota, Rohith; Garg, Manohar; Furst, John; Martin, Charlotte; Yates, Zoe; Scarlett, Christopher J.; Jablonski, Nina G.

Title: Biophysical evidence to support and extend the vitamin D-folate hypothesis as a paradigm for the evolution of human skin pigmentation
Creator: Lucock, Mark D.; Jones, Patrice R.; Chaplin, George; Beckett, Emma L.; Veysey, Martin; Thota, Rohith; Garg, Manohar; Furst, John; Martin, Charlotte; Yates, Zoe; Scarlett, Christopher J.; Jablonski, Nina G.
Relation: American Journal of Human Biology Vol. 34, Issue 4, no. e23667
Publisher Link: http://dx.doi.org/10.1002/ajhb.23667
Publisher: John Wiley & Sons
Resource Type: journal article
Date: 2021
Description: Objective: To test the “vitamin D-folate hypothesis for the evolution of human skin pigmentation.” Methods: Total ozone mapping spectrometer (TOMS) satellite data were used to examine surface UV-irradiance in a large (n = 649) Australian cross-sectional study population. Genetic analysis was used to score vitamin D- and folate-related gene polymorphisms (n = 22), along with two pigmentation gene variants (IRF4-rs12203592/HERC2-rs12913832). Red cell folate and vitamin D₃ were measured by immunoassay and HPLC, respectively. Results: i. Ultraviolet radiation (UVR) and pigmentation genes interact to modify blood vitamin levels; Light skin IRF4-TT genotype has greatest folate loss while light skin HERC2-GG genotype has greatest vitamin D₃ synthesis (reflected in both TOMS and seasonal data). ii. UV-wavelength exhibits a dose–response relationship in folate loss within light skin IRF4-TT genotype (305 > 310 > 324 > 380 nm). Significant vitamin D₃ photosynthesis only occurs within light skin HERC2-GG genotype, and is maximal at 305 nm. iii. Three dietary antioxidants (vitamins C, E, and β-carotene) interact with UVR and pigmentation genes preventing oxidative loss of labile reduced folate vitamers, with greatest benefit in light skin IRF4-TT subjects. The putative photosensitiser, riboflavin, did not sensitize red cell folate to UVR and actually afforded protection. iv. Four genes (5xSNPs) influenced blood vitamin levels when stratified by pigmentation genotype; MTHFR-rs1801133/rs1801131, TS-rs34489327, CYP24A-rs17216707, and VDR-ApaI-rs7975232. v. Lightest IRF4-TT/darkest HERC2-AA genotype combination (greatest folate loss/lowest vitamin D₃ synthesis) has 0% occurrence. The opposing, commonest (39%) compound genotype (darkest IRF4-CC/lightest HERC2-GG) permits least folate loss and greatest synthesis of vitamin D₃. Conclusion: New biophysical evidence supports the vitamin D-folate hypothesis for evolution of skin pigmentation.
Identifier: http://hdl.handle.net/1959.13/1447592
Identifier: uon:43197
Identifier: ISSN:1042-0533
Language: eng
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