Calculating the modelled K dwarf spectrum at the planetary surface

We calculated the wavelength resolved flux received at the surface of the K dwarf planet by multiplying the wavelength resolved top-of-the-atmosphere (TOA) flux with the transmission (telluric) spectrum of Earth provided to us by Baker et al. (Reference Baker, Blake and Reiners2020). Their code wraps the Planetary Spectrum Generator (PSG) radiative transfer tool to calculate the Earth spectra and has a lower limit at 200 nm (Villanueva et al., Reference Villanueva, Smith, Protopapa, Faggi and Mandell2018). This transmission spectrum was calculated at zenith over Göttingen, Germany on a random fall day and reveals the composition of Earth's atmosphere, with its prominent water vapour absorption bands (see Fig. 7). The transmission spectrum of Earth serves as a first proxy towards assessing surface conditions of potentially habitable exoplanets. To the best of our knowledge, we calculated for the first time the stellar spectrum of a K dwarf star transmitted to the surface of a hypothetical habitable zone planet with an Earth-like atmosphere using Earth's telluric spectrum (see upper panel of Fig. 7). Analogously, we modelled the emission spectrum of the Sun using the PHOENIX spectral library and placed the Earth at 1 AU, where it receives one Solar constant S ₀. We calculated the emission spectrum at TOA as well as the Solar daily averaged spectrum transmitted to the surface of Earth using Earth's telluric spectrum (see lower panel of Fig. 7). A numerical summary for the Earth–Sun and Exoplanet–K dwarf systems is presented in Table 2.

Garden cress: dry matter accumulation and water intake

Garden cress seeds (Lepidium sativum) were exposed to simulated Solar and K dwarf radiation and the dry and fresh masses of the seedlings were measured to determine the changes in biomass through time. The garden cress is a rapidly growing annual herb which is adaptable to diverse climates and soil conditions, and as such makes an excellent astrobiological target (Nehdi et al., Reference Nehdi, Sbihi, Tan and Al-Resayes2012; Wadhwa et al., Reference Wadhwa, Panwar, Agrawal, Saini and Patidar2012). The experiment was also run under dark conditions to ensure that the relative growth of garden cress under K dwarf and solar conditions is in fact due to radiation and not due to the intrinsic availability of nutrients in the plant seeds themselves. The irradiated samples were positioned at a stand at 3 cm to the base of the setup, equalling 8 cm to the irradiation source. Sand was used as the substrate as it allowed for the complete daily extraction of the sample, i.e. of the sprouted seedlings and the entirety of their roots. The methodology of measuring the fresh and dry mass of the sample is based on several works for measuring biomass accumulation (‘Dry mass change during germination of bean seeds’, n.d.; Hoh, Reference Hoh2002; Filson, Reference Filson2005). Four independent biological replicates of garden cress were used for the experiments.

The following steps were implemented:

1. 1) Control group:

A sample of 90 control garden cress seeds was used.

1. a) The fresh masses of nine groups à la ten control seeds were measured on a digital 1.0 × 10⁻⁴ g precision scale. The mean and standard deviation for the nine groups of ten control seeds was calculated.

2. b) The nine groups à la ten seeds were desiccated by drying in an oven at 40°C for two to three days and subsequently in a vacuum desiccator until a constant dry mass was reached. This was the case after a further two to three days.

3. c) The final dry masses of nine groups à la ten control seeds were measured, and the mean and standard deviation were calculated once more.

1. 2) Experimental group:

A further sample of 90 experimental garden cress seeds was used. The following steps were performed for the Solar and K dwarf radiation sources implementing a 12-h day night cycle, as well as for dark conditions.

Pre-experiment

1. a) The fresh masses of nine groups à la 9 experimental group garden cress seeds were measured on the digital 1.0 × 10⁻⁴ g precision scale. The mean and standard deviation for the 9 groups of 10 control seeds was calculated.

2. b) Those 90 seeds were soaked and rinsed with tap water.

3. c) A sand substrate was placed in a 5 cm-diameter Petri dish and wetted with water.

4. d) The ninety rinsed seeds were initially placed on the wet sand using laboratory tweezers and then placed under the radiation (or in a closed 40 × 40 × 20 cm box for the dark scenario).

During experiment

1. e) Temperatures and relative humidity levels were tracked and logged with a temperature- and humidity sensor throughout the full duration of the experiment (see Fig. S3 in the Supplementary Materials).

2. f) The plants were watered daily with a constant amount of water, ensuring consistent hydration levels throughout the duration of the experiments.

3. g) A random selection of 10 seeds, including roots, was extracted from the population every 24 h for a total of 9 days – the interval between consecutive measures remained equal for consistency.

4. h) The extracted seeds/seedlings/plant matter were thoroughly rinsed to remove sand remnants.

Post-experiment

1. i) The fresh masses of the extracted material were measured on the digital 1.0 × 10⁻⁴ g precision scale every 24 h.

2. j) The extracted material was desiccated until a constant mass was reached, including 2–3 days in the oven at 40°C and a further 2–3 days in the vacuum desiccator.

3. k) The final dry masses of the extracted seeds/seedlings/plant matter were measured.

Although the experiments conducted under different radiation regimes share the confounding variable of seed proximity, potentially resulting in shading and altered growth patterns due to the rapid germination of the first seeds (Casal, Reference Casal2013), the random selection of seedlings for analysis in both scenarios facilitates a comparative evaluation of the plant's reaction to the modified light conditions. While acknowledging the potential influence of seed proximity on plant growth, the random sampling approach helps mitigate any systematic biases associated with this shared variable. Consequently, we contend that the observed differences in plant responses predominantly reflect the effects of the varying light conditions.

Garden cress: photosynthetic efficiency

The photosynthetic efficiency of garden cress under Solar-, K dwarf and dark conditions was measured with the Mini-PAM II (Pulse-Amplitude-Modulation, Walz, Germany) fluorometer which determined chlorophyll a (Chl a) fluorescence yields. Chl a fluorescence yields serve as an indicator for photosynthetic performance and are often used to identify chemical or environmental stressors (Ogren, Reference Ogren1990; Percival and Sheriffs, Reference Percival and Sheriffs2002; Percival, Reference Percival2005). In this work, the fibre optics tip of the Mini-PAM was placed at 2 cm to sample level and was aligned at a 60° angle relative to the measuring plane with a 1 cm-diameter measuring area. The maximum photochemical quantum yield (F _v/F _m) of the photosystem II (PSII) is given by the equation: F _v/F _m = (F _m – F ₀) / F _m, where F _m is the maximum fluorescence level in mV generated by a 0.6 s saturation pulse (SP) which closes all PSII reaction centres and F ₀ is the minimum fluorescence level in mV excited by a very low-intensity measuring light (ML; frequency = 5 Hz) to keep PSII reaction centres open (Kitajima and Butler, Reference Kitajima and Butler1975; Genty et al., Reference Genty, Briantais and Baker1989). A ML intensity setting of 12 corresponds to 6000 μmol m⁻² s⁻¹ at a 7 mm fibre-optics-to-sample-level distance and is adjusted at increments of 500 μmol m⁻² s⁻¹. The final PAM settings can be found in Fig. S2. F _v/F _m was measured on a sample which had been acclimated to the dark for 25–30 min.

To ensure a denser plant population and a more uniform surface area, we conducted the photosynthetic efficiency experiments by sprinkling a handful of garden cress seeds onto a sterile cotton substrate. We opted for sterile cotton as the substrate because the weight and adhesive properties of wetted sand grains would have hindered the growth of the cress seeds. All measurements under the PAM settings were obtained from four independent biological replicates of garden cress under Solar, K dwarf and dark conditions. The parameter values were measured every 24 h for 9 days per illumination-type and biological replica.

Cyanobacteria: photosynthetic efficiency and integrated density

We used the desert cyanobacterium Chroococcidiopsis sp. CCMEE 029 (Culture Collection of Microorganisms from Extreme Environments) extracted from the Negev Desert in Israel for this portion of the study. Cyanobacteria are believed to contribute to 20–30% of the Earth's primary photosynthetic productivity and have a collective worldwide biomass of approximately 3 × 10¹⁴ grams of carbon (Garcia-Pichel et al., Reference Garcia-Pichel, Belnap, Neuer and Schanz2003; Pisciotta et al., Reference Pisciotta, Zou and Baskakov2010). As such, this strain makes an excellent astrobiological target which can withstand a variety of extreme conditions and can be found in numerous environments (Cumbers and Rothschild, Reference Cumbers and Rothschild2014; Billi et al., Reference Billi, Baqué, Verseux, Rothschild, de Vera, Stan-Lotter and Fendrihan2017, Reference Billi, Staibano, Verseux, Fagliarone, Mosca, Baqué, Rabbow and Rettberg2019). We grew the cyanobacterium culture in a liquid BG-11 medium with a 10⁻¹ dilution in a 25°C incubator without shaking under a 4000 Kelvin cold LED lamp until it reached an exponential growth phase. At this point we transferred the culture to a BG-11 Agar plate in 20 microliter-sized drops. Given that this cyanobacterial strain exhibits an optimal growth at intensities much smaller than garden cress, i.e. PAR intensities of 30–40 μmol (photons) m⁻² s⁻¹, we decreased the wavelength-distributed flux of the modelled Solar emission spectrum as well as its corresponding simulated LED spectrum by 48 times. The PPFD used for the Solar sample was therefore 30 μmol (photons) m⁻² s⁻¹. To keep the original photonal ratio of the two spectral types, the K dwarf PAR intensity was decreased to 10 μmol (photons) m⁻² s⁻¹ (see Table 2). We then exposed the Agar plate to these radiation regimes for 13 days, implementing a 12-h day night cycle. Every few days we documented the visual changes of the culture with a camera. Four independent biological replicates of the cyanobacterial strain were used for the experiments.

We measured the photosynthetic efficiencies of dark-acclimated samples with the mini-PAM fluorometer. We used Gain level 3 and a ML intensity of 12 in the PAM settings to capture the low photosynthetic signal of the cyanobacterium spots in the initial phases of the experiments. The remaining settings were as for the garden cress experiments (see Fig. S2). We calculated the corresponding integrated densities (IntD) with Python by summing up the raw values of all the pixels (RawIntD) within a region of interest (ROI) in the image (see e.g. Fig. 5 in the main text) and multiplying it by the ratio of the image area in scaled units to the area in pixels:

(1)$${\rm IntD} = {\rm RawIntD\ }\!\!\times( {{\rm Area\;in\;scaled\;units}} ) {\rm /}( {{\rm Area\;in\;pixels}} ) $$

We used an RGB (red, green and blue) pixel range of ±10 around the average RGB values of all regions of interest as a colour threshold and calculated the integrated densities of each spot. The threshold captures all tonalities of pixels in the samples in accordance with their contribution to the culture growth.