Autogenic engineered living materials (ELMs) involve in situ production and engineering of native extracellular matrix (ECM). However, the existing autogenic ELMs have limited scope and functionalities. Herein, we report a platform for de novo autogenic functional ELMs. By protein mining, we have discovered CsgA-like 33,564 homologs that can find potential utility as de novo ECM of protein nanofibers. By employing AlphaFold2 and molecular dynamics simulations, we shed insights into the CsgA-like β-solenoid protein structures and stability. By hacking Escherichia coli curli machinery, we demonstrate the production of de novo autogenic ELMs from CsgA-like proteins (≤9-times the molecular weight and β-sheet repeat units) of extremophilic non-model bacteria. Additionally, we biomanufacture macroscopic materials with tunable mechanical properties (enhancing storage modulus by 3-times) and programmable functionalities (3D printability, binding to nanoparticles/antibodies). This work showcases a versatile platform to discover, rationally design, and harness the sophisticated functionalities of natural systems for futuristic autogenic ELMs.