ABSTRACT The characterization of the seasonal dynamics of endophytic bacteria in beech leaves can be hindered by co‐amplification of chloroplast and mitochondrial plant DNA. This study applies established peptide nucleic acid (PNA) clamps to suppress host‐derived amplification while resolving bacterial succession across the vegetative season. Chloroplast‐ and mitochondrion‐specific PNAs inverted the proportion of host to bacterial reads, enabled the recovery of bacterial sequence variants, and increased alpha diversity accordingly. Beta‐diversity analyses showed that, once host contamination was removed, samples displayed a clear seasonal trajectory. Early‐season leaves contained high abundances of Pseudomonas together with taxa likely introduced through plant–insect–microbe interactions. As leaves matured, the microbiome shifted toward a more stable composition dominated by well‐established genera. The transition from early transient taxa to the later enrichment of phyllosphere‐adapted and nutrient‐cycling genera demonstrates that beech leaves host a temporally structured microbiome shaped by leaf development and seasonal environmental stress.
Giubilei et al. (Sun,) studied this question.