Surface biosignatures of exo-Earths: Remote detection of extraterrestrial life

Hegde, Siddharth; Paulino-Lima, I. G.; Kent, Ryan; Kaltenegger, Lisa; Rothschild, Lynn J.

doi:10.1073/pnas.1421237112

Cited by 56 publications

(49 citation statements)

References 23 publications

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“…A promising approach in the search for traces of Earth-like life is also focused on the examination of surface and subsurface rock/dust material of meteorites, comets or the nearest Earth neighbors (McKay et al 1996 ; 4/30 Kebukawa et al 2009 ;De Gregorio et al 2013 ). For the remote detection of biosignatures, photosynthetic and non-photosynthetic pigments (Varnali and Edwards 2013 ;Hegdea et al 2015 ;Schwieterman et al 2015 ), biogenic gases from anoxygenic photosynthesis in microbial mats or other biosignature gases (Seager and Bains 2015 ) are new biosignatures of life which have been proposed by researches. One of the strategies for substantiation of the extraterrestrial life existence probability in the Universe is to investigate the stability of selected putative biosignatures in the extraterrestrial analog environments, e.g., within martian simulation chambers or under low Earth orbit in specially designed devices with Marslike atmosphere .…”

Section: Introductionmentioning

confidence: 99%

The First Space-Related Study of a Kombucha Multimicrobial Cellulose-Forming Community: Preparatory Laboratory Experiments

Podolich

Zaets

Kukharenko

et al. 2016

Orig Life Evol Biosph

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Biofilm-forming microbial communities are known as the most robust assemblages that can survive in harsh environments. Biofilm-associated microorganisms display greatly increased resistance to physical and chemical adverse conditions, and they are expected to be the first form of life on Earth or anywhere else. Biological molecules synthesized by biofilm -protected microbiomes may serve as markers of the nucleoprotein life. We offer a new experimental model, a kombucha multimicrobial culture (KMC), to assess a structural integrity of a widespread microbial polymer - cellulose - as a biosignature of bacteria-producers for the multipurpose international project "BIOlogical and Mars Experiment (BIOMEX)", which aims to study the vitality of pro- and eukaryotic organisms and the stability of organic biomolecules in contact with minerals to analyze the detectability of life markers in the context of a planetary background. In this study, we aimed to substantiate the detectability of mineralized cellulose with spectroscopy and to study the KMC macrocolony phenotype stability under adverse conditions (UV, excess of inorganics etc.). Cellulose matrix of the KMC macrocolony has been mineralized in the mineral-water interface under assistance of KMC-members. Effect of bioleached ions on the cellulose matrix has been visible, and the FT-IR spectrum proved changes in cellulose structure. However, the specific cellulose band vibration, confirming the presence of β(1,4)-linkages between monomers, has not been quenched by secondary minerals formed on the surface of pellicle. The cellulose-based KMC macrocolony phenotype was in a dependence on extracellular matrix components (ionome, viriome, extracellular membrane vesicles), which provided its integrity and rigidness in a certain extent under impact of stressful factors.

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Section: Introductionmentioning

confidence: 99%

The First Space-Related Study of a Kombucha Multimicrobial Cellulose-Forming Community: Preparatory Laboratory Experiments

Podolich

Zaets

Kukharenko

et al. 2016

Orig Life Evol Biosph

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“…Vegetation is only one among many surface features life produces on Earth (see, e.g., Kiang et al 2007a, Cockell et al 2009, Huet al 2012, Sanroma et al 2013, Hegde et al 2015. Land plants have been widespread on Earth for only approximately 460 Myr (e.g., Zahnle et al 2007), whereas much of the history of life has been dominated by single-celled microbial life.…”

Section: Surface Biosignaturesmentioning

confidence: 99%

“…Biota on Earth generates a wide range of characteristic reflectivity and colors. To mimic detectable surface reflection features of known life, Hegde et al (2015) measured the spectral characteristics of 137 phylogenetically diverse microorganisms containing a range of pigments, including ones isolated from Earth's most extreme environments. The team used an integrating sphere, which mimics the observing geometry of an exoplanet that is modeled as a Lambertian sphere.…”

Section: Surface Biosignaturesmentioning

confidence: 99%

How to Characterize Habitable Worlds and Signs of Life

Kaltenegger

2017

Annu. Rev. Astron. Astrophys.

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226

231

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The detection of exoplanets orbiting other stars has revolutionized our view of the cosmos. First results suggest that it is teeming with a fascinating diversity of rocky planets, including those in the habitable zone. Even our closest star, Proxima Centauri, harbors a small planet in its habitable zone, Proxima b. With the next generation of telescopes, we will be able to peer into the atmospheres of rocky planets and get a glimpse into other worlds. Using our own planet and its wide range of biota as a Rosetta stone, we explore how we could detect habitability and signs of life on exoplanets over interstellar distances. Current telescopes are not yet powerful enough to characterize habitable exoplanets, but the next generation of telescopes that is already being built will have the capabilities to characterize close-by habitable worlds. The discussion on what makes a planet a habitat and how to detect signs of life is lively. This review will show the latest results, the challenges of how to identify and characterize such habitable worlds, and how nearfuture telescopes will revolutionize the field. For the first time in human history, we have developed the technology to detect potential habitable worlds. Finding thousands of exoplanets has taken the field of comparative planetology beyond the Solar System.

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“…Note the diversity in edge wavelengths caused by absorption at different wavelengths and higher reflectance where pigments are not absorbing. Hegde et al (2015) measured the reflectance spectra from 0.35 to 2.5 µm of pure cultures of 137 microorganisms with a variety of pigments suited to different functions, generating a publically available spectral database (biosignatures.astro.cornell.edu). In general, these authors found that the strongest features (e.g., 'edges') in the ensemble of microorganisms were present in the visible to NIR (> 1.0 µm) range due to pigment absorption.…”

Section: Alternative Reflectance Biosignaturesmentioning

confidence: 99%

Surface and Temporal Biosignatures

Schwieterman¹

2018

Handbook of Exoplanets

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Recent discoveries of potentially habitable exoplanets have ignited the prospect of spectroscopic investigations of exoplanet surfaces and atmospheres for signs of life. This chapter provides an overview of potential surface and temporal exoplanet biosignatures, reviewing Earth analogues and proposed applications based on observations and models. The vegetation red-edge (VRE) remains the most well-studied surface biosignature. Extensions of the VRE, spectral 'edges' produced in part by photosynthetic or nonphotosynthetic pigments, may likewise present potential evidence of life. Polarization signatures have the capacity to discriminate between biotic and abiotic 'edge' features in the face of false positives from band-gap generating material. Temporal biosignaturesmodulations in measurable quantities such as gas abundances (e.g., CO 2 ), surface features, or emission of light (e.g., fluorescence, bioluminescence) that can be directly linked to the actions of a biosphere -are in general less well studied than surface or gaseous biosignatures. However, remote observations of Earth's biosphere nonetheless provide proofs of concept for these techniques and are reviewed here. Surface and temporal biosignatures provide complementary information to gaseous biosignatures, and while likely more challenging to observe, would contribute information inaccessible from study of the time-averaged atmospheric composition alone.

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Surface biosignatures of exo-Earths: Remote detection of extraterrestrial life

Cited by 56 publications

References 23 publications

The First Space-Related Study of a Kombucha Multimicrobial Cellulose-Forming Community: Preparatory Laboratory Experiments

The First Space-Related Study of a Kombucha Multimicrobial Cellulose-Forming Community: Preparatory Laboratory Experiments

How to Characterize Habitable Worlds and Signs of Life

Surface and Temporal Biosignatures

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