Scientific drilling has identified a biosphere in marine sediments(1), which contain many uncultivated microbial groups known only by their DNA sequences(2-4). Recycling of organic matter in sediments is an important component of bio-geochemical cycles because marine sediments are critical for long-term carbon storage(5). Turnover of carbon is hypothesized to be driven by the secretion of enzymes by microbial organisms(5-7), which act to break down macromolecules into constitutive monomers that can be transported into cells. As such, the nature of the microbial secretome often influences the function of a community(6). However, the microbial groups involved in this process and the biochemistry they encode is poorly understood. Here, we show that expressed genes from 5 to 159 meters below the seafloor(8) (mbsf) encode numerous candidate peptidases and carbohydrate-active enzymes ('CAZymes')(9) targeted for secretion. The majority (90-99%) were assigned to Bacteria, of which 12% shared the highest sequence similarity with candidate phyla(10,11). The remaining putatively secreted proteins shared highest sequence similarity with archaeal and fungal enzymes, which peak in two redox transition zones(12). In the shallower redox zone at 30 mbsf, 20% of the transcripts encoding putative secreted peptidases were assigned to lineages(7,13,14) of uncultivated Archaea. The target compounds of the predicted secreted proteome show a preference for necromass in the form of microbial cell envelopes as well as plankton and algal detritus. The predicted fungal secreted proteome encodes CAZymes not present in the predicted bacterial or archaeal secreted proteomes, indicating that fungi putatively play a minimal but specialized role in subseafloor carbohydrate recycling.