Comprehensive analysis of genome-wide expression patterns during growth of the hyperthermophilic bacterium Thermotoga maritima on 14 monosaccharide and polysaccharide substrates was undertaken with the goal of proposing carbohydrate specificities for transport systems and putative transcriptional regulators. Saccharide-induced regulons were predicted through the complementary use of comparative genomics, mixedmodel analysis of genome-wide microarray expression data, and examination of upstream sequence patterns. The results indicate that T. maritima relies extensively on ABC transporters for carbohydrate uptake, many of which are likely controlled by local regulators responsive to either the transport substrate or a key metabolic degradation product. Roles in uptake of specific carbohydrates were suggested for members of the expanded Opp/Dpp family of ABC transporters. In this family, phylogenetic relationships among transport systems revealed patterns of possible duplication and divergence as a strategy for the evolution of new uptake capabilities. The presence of GC-rich hairpin sequences between substrate-binding proteins and other components of Opp/Dpp family transporters offers a possible explanation for differential regulation of transporter subunit genes. Numerous improvements to T. maritima genome annotations were proposed, including the identification of ABC transport systems originally annotated as oligopeptide transporters as candidate transporters for rhamnose, xylose, -xylan, and -glucans and identification of genes likely to encode proteins missing from current annotations of the pentose phosphate pathway. Beyond the information obtained for T. maritima, the present study illustrates how expression-based strategies can be used for improving genome annotation in other microorganisms, especially those for which genetic systems are unavailable.Thermotoga maritima, a hyperthermophilic anaerobe with an optimal growth temperature of 80°C, has been found in diverse high-temperature locations and is capable of using a wide variety of simple and complex carbohydrate substrates for growth. The complexity of its carbohydrate utilization strategies, revealed by genome sequencing (48) and through previous work (11,12,47,51), is surprising, given the primitive features of this microorganism. Considerable genomic plasticity has been observed even within the Thermotoga genus, with respect to the gene content of carbohydrate active enzymes and transporter subunits, which may to some extent relate to lateral gene transfer events (48,49). Despite the range of sugar-active enzymes found within T. maritima MSB8 genome (Table S1 in the supplemental material) (6,9,10,23,27,34,35,37,38,39,42,45,46,54,70,71), a PTS (phosphoenolpyruvatedependent phosphotransferase system) similar to those used by other species for preferential uptake of selected sugars is apparently absent (48). No homologs of the PTS components EI and HPr (phosphocarrier proteins) and no sugar-specific EII sugar transporter subunits have been identified ...
