RESUMO
Sulfate aerosol is responsible for a net cooling of the Earth's atmosphere due to its ability to backscatter light. Through atmospheric multiphase chemistry, it reacts with isoprene epoxydiols leading to the formation of aerosol and organic compounds, including organosulfates and high-molecular weight compounds. In this study, we evaluate how sulfate aerosol light backscattering is modified in the presence of such organic compounds. Our laboratory experiments show that reactive uptake of isoprene epoxydiols on sulfate aerosol is responsible for a decrease in light backscattering compared to pure inorganic sulfate particles of up to - 12% at 355 nm wavelength and - 21% at 532 nm wavelength. Moreover, while such chemistry is known to yield a core-shell structure, the observed reduction in the backscattered light intensity is discussed with Mie core-shell light backscattering numerical simulations. We showed that the observed decrease can only be explained by considering effects from the complex optical refractive index. Since isoprene is the most abundant hydrocarbon emitted into the atmosphere, and isoprene epoxydiols are the most important isoprene secondary organic aerosol precursors, our laboratory findings can aid in quantifying the direct radiative forcing of sulfates in the presence of organic compounds, thus more clearly resolving the impact of such aerosol particles on the Earth's climate.
RESUMO
Tandem repeats are intrinsically highly variable sequences since repeat units are often lost or gained during replication or following unequal recombination events. Because of their low complexity and their instability, these repeats, which are also called satellite repeats, are often considered to be useless 'junk' DNA. However, recent findings show that tandem repeats are frequently found within promoters of stress-induced genes and within the coding regions of genes encoding cell-surface and regulatory proteins. Interestingly, frequent changes in these repeats often confer phenotypic variability. Examples include variation in the microbial cell surface, rapid tuning of internal molecular clocks in flies, and enhanced morphological plasticity in mammals. This suggests that instead of being useless junk DNA, some variable tandem repeats are useful functional elements that confer 'evolvability', facilitating swift evolution and rapid adaptation to changing environments. Since changes in repeats are frequent and reversible, repeats provide a unique type of mutation that bridges the gap between rare genetic mutations, such as single nucleotide polymorphisms, and highly unstable but reversible epigenetic inheritance.
