Microbial genome analyses: global comparisons of transport capabilities based on phylogenies, bioenergetics and substrate specificities.

We have conducted genome sequence analyses of seven prokaryotic microorganisms for which completely sequenced genomes are available (Escherichia coli, Haemophilus influenzae, Helicobacter pylori, Bacillus subtilis, Mycoplasma genitalium, Synechocystis PCC6803 and Methanococcus jannaschii). We report the distribution of encoded known and putative polytopic cytoplasmic membrane transport proteins within these genomes. Transport systems for each organism were classified according to (1) putative membrane topology, (2) protein family, (3) bioenergetics, and (4) substrate specificities. The overall transport capabilities of each organism were thereby estimated. Probable function was assigned to greater than 90% of the putative transport proteins identified. The results show the following: (1) Numbers of transport systems in eubacteria are approximately proportional to genome size and correspond to 9.7 to 10.8% of the total encoded genes except for H. pylori (5.4%), Synechocystis (4.7%) and M. jannaschii (3.5%) which exhibit substantially lower proportions. (2) The distribution of topological types is similar in all seven organisms. (3) Transport systems belonging to 67 families were identified within the genomes of these organisms, and about half of these families are also found in eukaryotes. (4) 12% of these families are found exclusively in Gram-negative bacteria, but none is found exclusively in Gram-positive bacteria, cyanobacteria or archaea. (5) Two superfamilies, the ATP-binding cassette (ABC) and major facilitator (MF) superfamilies account for nearly 50% of all transporters in each organism, but the relative representation of these two transporter types varies over a tenfold range, depending on the organism. (6) Secondary, pmf-dependent carriers are 1.5 to threefold more prevalent than primary ATP-dependent carriers in E. coli, H. influenzae, H. pylori and B. subtilis while primary carriers are about twofold more prevalent in M. genitalium and Synechocystis. M. jannaschii exhibits a slight preference for secondary carriers. (7) Bioenergetics of transport generally correlate with the primary forms of energy generated via available metabolic pathways but ecological niche and substrate availability may also be determining factors. (8) All organisms display a similar range of transport specificities with quantitative differences presumably reflective of disparate ecological niches. (9) M. jannaschii and Synechocystis have a two to threefold increased proportion of transporters for inorganic ions with a concomitant decrease in transporters for organic compounds. (10) 6 to 18% of all transporters in these bacteria probably function as drug export systems showing that these systems are prevalent in non-pathogenic as well as pathogenic organisms. (11) All seven prokaryotes examined encode proteins homologous to known channel proteins, but none of the channel types identified occurs in all of these organisms. (12) The phosphoenolpyruvate:sugar phosphotransferase system is prevalent in the large genome organisms, E. coli and B. subtilis, and is present in the small genome organisms, H. influenzae and M. genitalium, but is totally lacking in H. pylori, Synechocystis and M. jannaschii. Details of the information summarized in this article are available on our web sites, and this information will be periodically updated and corrected as new sequence and biochemical data become available.

Microbial genome analyses: comparative transport capabilities in eighteen prokaryotes.

Here, we present a comprehensive analysis of solute transport systems encoded within the completely sequenced genomes of 18 prokaryotic organisms. These organisms include four Gram-positive bacteria, seven Gram-negative bacteria, two spirochetes, one cyanobacterium and four archaea. Membrane proteins are analyzed in terms of putative membrane topology, and the recognized transport systems are classified into 76 families, including four families of channel proteins, four families of primary carriers, 54 families of secondary carriers, six families of group translocators, and eight unclassified families. These families are analyzed in terms of the paralogous and orthologous relationships of their protein members, the substrate specificities of their constituent transporters and their distributions in each of the 18 organisms studied. The families vary from large superfamilies with hundreds of represented members, to small families with only one or a few members. The mode of transport generally correlates with the primary mechanism of energy generation, and the numbers of secondary transporters relative to primary transporters are roughly proportional to the total numbers of primary H(+) and Na(+) pumps in the cell. The phosphotransferase system is less prevalent in the analyzed bacteria than previously thought (only six of 14 bacteria transport sugars via this system) and is completely lacking in archaea and eukaryotes. Escherichia coli is shown to be exceptionally broad in its transport capabilities and therefore, at a membrane transport level, does not appear representative of the bacteria thus far sequenced. Archaea and spirochetes exhibit fewer proteins with multiple transmembrane segments and fewer net transporters than most bacteria. These results provide insight into the relevance of transport to the overall physiology of prokaryotes.

Unified inventory of established and putative transporters encoded within the complete genome of Saccharomyces cerevisiae.

We present the complete inventory of currently recognized and putative transporters encoded within the genome of Saccharomyces cerevisiae. These 258 transporters are classified into 42 families according to phylogenetic and substrate specificity criteria. Twelve of these yeast families are found only in eukaryotic organisms, and four are so far unique to yeast. Putative yeast-specific families transport heavy metals, arsenite and calcium. The phylogenetic analyses reported allow classification of 139 functionally uncharacterized yeast transporters into families of known functions. The relative proportions of yeast transporters specific for different classes of substrates differ only slightly from those reported for Escherichia coli. However, the ratio of secondary transporters (uniporters, cation symporters and antiporters) to primary ATP-driven transporters is much higher for yeast than for bacteria.

Evolutionary divergence of LFY function in the mustards Arabidopsis thaliana and Leavenworthia crassa.

LEAFY (LFY), a transcription factor involved in the regulation of flower development in Arabidopsis thaliana, has been identified as a candidate gene in the diversification of plant architecture in Brassicaceae. Previous research with Leavenworthia crassa, which produces solitary flowers in the axils of rosette leaves, has shown that the L. crassa LFY ortholog, LcrLFY, rescues most aspects of flower development in A. thaliana but showed two novel traits: flowers produced additional petals and inflorescences produced terminal flowers. In this paper, we explore the molecular mechanisms responsible for these novel phenotypes. We used microarray hybridizations to identify 32 genes differentially expressed between a transgenic LcrLFY line and a control transgenic LFY line. Of particular interest, TERMINAL FLOWER 1 (TFL1) transcripts were found at elevated levels in LcrLFY lines. To distinguish regulatory versus functional changes within the LcrLFY locus, reciprocal chimeric transgenes between LcrLFY and LFY were constructed. These lines implicate divergence of LcrLFY cis-regulation as the primary cause of both novel transgenic phenotypes but implicate divergence of LcrLFY protein function as the primary cause of elevated TFL1 levels. Taken together these results show that LcrLFY has diverged from A. thaliana in both the cis-regulatory and protein-coding regions and imply that molecular coevolution of LcrLFY and the L. crassa TFL1 ortholog, LcrTFL1, contributed to the evolution of rosette flowering.

Evolutionary origins of multidrug and drug-specific efflux pumps in bacteria.

The available genomic sequences of three pathogenic and three nonpathogenic bacteria were analyzed to identify known and putative drug-specific and multidrug resistance transport systems. Escherichia coli was found to encode 29 such pumps, and with the exception of the archaebacterium Methanococcus jannaschii, the numbers of multidrug efflux pumps encoded within genomes of the other organisms were found to be approximately proportional to their total numbers of encoded transport systems as well as to total genome size. The similar numbers of chromosomally encoded multidrug efflux systems in pathogens and nonpathogens suggests that these transporters have not arisen recently in pathogens in response to antimicrobial chemotherapy. Phylogenetic analyses of the four transporter families that contain drug efflux permeases indicate that drug resistance arose rarely during the evolution of each family and that the diversity of current drug efflux pumps within each family arose from just one or a very few primordial systems. However, although the ability to confer drug efflux appears to have emerged on only a few occasions in evolutionary time and was stably maintained as an evolutionary trait, modulation of the substrate specificities of these systems has occurred repeatedly. A speculative model is presented that may explain the apparent capability of these multidrug transport systems to mediate drug transport from the cytoplasm or directly from the phospholipid bilayer.