Lessons from Earth Aerobiology for Venus Astrobiology Diana Gentry, NASA/Ames Venus's clouds have often suggested as a possible habitat. The constraints governing putative airborne life in such a habitat in turn inform priorities and strategies for remote and in situ exploration, methods by which resulting biosignatures might be detected, exoplanet habitability assessment, and planetary protection concerns. Lessons drawn from studying Earth's aerobiosphere can help improve this understanding. There are altitude ranges within Venus's clouds in which temperature, pressure, particle size, and radiation appear to be within the limits of microbial life on Earth, and life cycles involving S- and Fe-based redox metabolism have been proposed. However, given the lack of a habitable surface reservoir, a long-term stable Venus aerobiosphere would require that the reproduction rate of the airborne microbes be faster than the settling rate of airborne microbes due to gravity, or eventually the population would be depleted; put another way, the mean generation time would need to exceed the mean residence time. This creates a joint constraint of aerosol dynamics, potential nutrient availability and energy influx, and bioenergetic costs such as desiccation and radiation damage. Even at an optimistic estimate of 75% H2SO4, Venus aerosol water activity (aw) is still ~0.02, far below the observed microbial growth limit of ~0.6. Long-term desiccation with brief spurts of repair and growth in response to transient water influx, such as from volcanism, is the most likely model for Earth-like life on Venus - a 'desert bloom' scenario. Several high priority science goals : cloud aerosol composition, internal radiative flux, and aerosol residence time and circulation models – thus will also improve our understanding of Venus in an astrobiology context. In Earth's troposphere, warm water clouds can carry 10^3 - 10^5 cells/mL, some metabolically active. However, Earth's stratospheric sulfate aerosol layer may be a better analogue: supercooled sulfuric acid aerosols (acid weight fraction 0.6 to 0.85, 0.1 to 1 um diameter, 0.1 to 1 cm^-3) with little water activity, long residence times, high UV radiation, and only sporadic influx from surface particle sources. Though 'hot spots' can occur associated with tropospheric mixing, viable cells in stratospheric samples are rare (approx 10^2 cells/m3), and primarily inactive forms such as spores. It is not yet clear whether such bioaerosols are associated with sulfate aerosols or simply co-located, and reproduction in situ has not yet been observed. In this model of a sparse, largely dormant Venus ecosystem, a single transect on descent is likely to pass through a low-water, inactive region, missing potential signs of habitability or biosignatures. A targeted strategy would sample through an aerial region with some upwelling from surface sources, and take multiple transects separated in time and space. This is compatible with other in situ science goals seeking to understand the dynamics and heterogeneities of Venus's clouds.