From Cytoplasmic Membrane to Thylakoids: Evolution of Membrane Biogenesis and Photosystem II assembly in early diverging Cyanobacteria

Thylakoid membranes (TM) in cyanobacteria and chloroplasts host the light-dependent reactions of oxygenic photosynthesis, which involve a linear electron transfer (LET) chain composed of multi-subunit complexes, including notably Photosystem II (PSII). Gloeobacterales, the earliest-diverging cyanobacterial lineage, lack TM and perform photosynthesis within specialized regions of the cytoplasmic membrane (CM), thereby representing an ancestral state with respect to other cyanobacteria, all equipped with TM and known as Phycobacteria. The emergence of TM, which increased the membrane surface available for oxygenic photosynthesis, was a key innovation that likely contributed to the Great Oxidation Event. This evolutionary transition involved the formation of a distinct membrane compartment, followed by the relocation of LET components from the CM to TM. Here, we present a phylogenomic analysis identifying three candidate proteins associated with membrane trafficking that may contribute to TM biogenesis, including the SPFH family member Slr1106, which we show was acquired via lateral gene transfer. Moreover, evolutionary analysis of 36 PSII assembly factors indicates key modifications in late-stage PSII assembly, notably in manganese homeostasis. We further highlight structural changes in the early-acting YidC translocase that may have facilitated the relocation of LET components from the CM to TM. Altogether, our phylogenetic and functional prediction analyses of proteins involved in membrane dynamics and PSII assembly factors bring new insights into the molecular innovations that led to the emergence of TM.