The puddled layer of paddy soils represents a highly dynamic environment regarding the spatio-temporal variability of biogeochemical conditions. To study these effects on the abundance and community structure of microbial populations, a rhizotron experiment was conducted throughout an entire growing season of wetland rice. Soil samples were taken from selected areas of the puddled layer (bulk soil, oxidized layer, rhizosphere) at main plant developmental stages such as (i) the initial stage, (ii) tillering, (iii) panicle initiation, (iv) flowering, and (v) maturity. Cell numbers of archaea, bacteria, and selected phyla were assessed by catalyzed reporter deposition-fluorescence in situ hybridization (CARD-FISH). The structure and diversity of microbial communities was analyzed by polymerase chain reaction-denaturing gradient gel electrophoresis (PCR-DGGE) along with sequencing of selected bands. Following submergence of the paddy soil, shifts of bacterial community structure were observed in the oxidized layer and the rhizosphere. Members of the β-Proteobacteria became predominant in the rhizosphere at tillering stage and were affiliated with aerobic, iron-oxidizing bacteria of the genus Sideroxydans. Seasonal effects were mainly visible in the rhizosphere, as several phylogenetic subgroups including methanotrophic bacteria showed increased cell numbers at flowering stage. Cell numbers of methanogenic archaea were also highest at flowering stage (bulk soil, rhizosphere) and members of the Methanocellales were identified as predominant archaeal populations in areas of oxic and anoxic conditions. In contrast to bacteria, the communities of archaea in the puddled layer of the studied paddy soil were less influenced by spatio-temporal variations of biogeochemical conditions.