Structural characterization of aspartate-semialdehyde dehydrogenase from Pseudomonas aeruginosa and Neisseria gonorrhoeae.

Gonorrhoea infection rates and the risk of infection from opportunistic pathogens including P. aeruginosa have both risen globally, in part due to increasing broad-spectrum antibiotic resistance. Development of new antimicrobial drugs is necessary and urgent to counter infections from drug resistant bacteria. Aspartate-semialdehyde dehydrogenase (ASADH) is a key enzyme in the aspartate biosynthetic pathway, which is critical for amino acid and metabolite biosynthesis in most microorganisms including important human pathogens. Here we present the first structures of two ASADH proteins from N. gonorrhoeae and P. aeruginosa solved by X-ray crystallography. These high-resolution structures present an ideal platform for in silico drug design, offering potential targets for antimicrobial drug development as emerging multidrug resistant strains of bacteria become more prevalent.

Structure of tyrosine aminotransferase from Leishmania infantum.

The trypanosomatid parasite Leishmania infantum is the causative agent of visceral leishmaniasis (VL), which is usually fatal unless treated. VL has an incidence of 0.5 million cases every year and is an important opportunistic co-infection in HIV/AIDS. Tyrosine aminotransferase (TAT) has an important role in the metabolism of trypanosomatids, catalyzing the first step in the degradation pathway of aromatic amino acids, which are ultimately converted into their corresponding L-2-oxoacids. Unlike the enzyme in Trypanosoma cruzi and mammals, L. infantum TAT (LiTAT) is not able to transaminate ketoglutarate. Here, the structure of LiTAT at 2.35 Å resolution is reported, and it is confirmed that the presence of two Leishmania-specific residues (Gln55 and Asn58) explains, at least in part, this specific reactivity. The difference in substrate specificity between leishmanial and mammalian TAT and the importance of this enzyme in parasite metabolism suggest that it may be a useful target in the development of new drugs against leishmaniasis.

Structure of nitrilotriacetate monooxygenase component B from Mycobacterium thermoresistibile.

Mycobacterium tuberculosis belongs to a large family of soil bacteria which can degrade a remarkably broad range of organic compounds and utilize them as carbon, nitrogen and energy sources. It has been proposed that a variety of mycobacteria can subsist on alternative carbon sources during latency within an infected human host, with the help of enzymes such as nitrilotriacetate monooxygenase (NTA-Mo). NTA-Mo is a member of a class of enzymes which consist of two components: A and B. While component A has monooxygenase activity and is responsible for the oxidation of the substrate, component B consumes cofactor to generate reduced flavin mononucleotide, which is required for component A activity. NTA-MoB from M. thermoresistibile, a rare but infectious close relative of M. tuberculosis which can thrive at elevated temperatures, has been expressed, purified and crystallized. The 1.6 Å resolution crystal structure of component B of NTA-Mo presented here is one of the first crystal structures determined from the organism M. thermoresistibile. The NTA-MoB crystal structure reveals a homodimer with the characteristic split-barrel motif typical of flavin reductases. Surprisingly, NTA-MoB from M. thermoresistibile contains a C-terminal tail that is highly conserved among mycobacterial orthologs and resides in the active site of the other protomer. Based on the structure, the C-terminal tail may modulate NTA-MoB activity in mycobacteria by blocking the binding of flavins and NADH.

Structure of aldose reductase from Giardia lamblia.

Giardia lamblia is an anaerobic aerotolerant eukaryotic parasite of the intestines. It is believed to have diverged early from eukarya during evolution and is thus lacking in many of the typical eukaryotic organelles and biochemical pathways. Most conspicuously, mitochondria and the associated machinery of oxidative phosphorylation are absent; instead, energy is derived from substrate-level phosphorylation. Here, the 1.75 Å resolution crystal structure of G. lamblia aldose reductase heterologously expressed in Escherichia coli is reported. As in other oxidoreductases, G. lamblia aldose reductase adopts a TIM-barrel conformation with the NADP(+)-binding site located within the eight ß-strands of the interior.

Multiple levels of gene regulation mediate differentiation of the intracellular pathogen Leishmania.

For many years, mRNA abundance has been used as the surrogate measure of gene expression in biological systems. However, recent genome-scale analyses in both bacteria and eukaryotes have revealed that mRNA levels correlate with steady-state protein abundance for only 50-70% of genes, indicating that translation and post-translation processes also play important roles in determining gene expression. What is not yet clear is whether dynamic processes such as cell cycle progression, differentiation, or response to environmental changes change the relationship between mRNA and protein abundance. Here, we describe a systems approach to interrogate promastigote-to-amastigote differentiation in the obligatory intracellular parasitic protozoan Leishmania donovani. Our results indicate that regulation of mRNA levels plays a major role early in the differentiation process, while translation and post-translational regulation are more important in the latter part. In addition, it appears that the differentiation signal causes a transient global increase in the rate of protein synthesis, which is subsequently down-regulated by phosphorylation of α-subunit of translation initiation factor 2. Thus, Leishmania dynamically changes the relationship between mRNA and protein abundance as it adapts to new environmental circumstances. It is likely that similar mechanisms play a more important role than previously recognized in regulation of gene expression in other organisms.

The Seattle Structural Genomics Center for Infectious Disease (SSGCID).

The NIAID-funded Seattle Structural Genomics Center for Infectious Disease (SSGCID) is a consortium established to apply structural genomics approaches to potential drug targets from NIAID priority organisms for biodefense and emerging and re-emerging diseases. The mission of the SSGCID is to determine approximately 400 protein structures over the next five years. In order to maximize biomedical impact, ligand-based drug-lead discovery campaigns will be pursued for a small number of high-impact targets. Here we review the center's target selection processes, which include pro-active engagement of the infectious disease research and drug therapy communities to identify drug targets, essential enzymes, virulence factors and vaccine candidates of biomedical relevance to combat infectious diseases. This is followed by a brief overview of the SSGCID structure determination pipeline and ligand screening methodology. Finally, specifics of our resources available to the scientific community are presented. Physical materials and data produced by SSGCID will be made available to the scientific community, with the aim that they will provide essential groundwork benefiting future research and drug discovery.

Analysis of the Leishmania donovani transcriptome reveals an ordered progression of transient and permanent changes in gene expression during differentiation.

Leishmania donovani is an intracellular protozoan parasite that causes kala-azar in humans. During infection the extracellular insect forms (promastigotes) undergo rapid differentiation to intracellular amastigotes that proliferates in phagolysosomes of mammalian macrophages. We used microarray-based expression profiling to investigate the time-course of changes in RNA abundance during promastigote-to-amastigote differentiation in a host-free system that mimics this process. These studies revealed that several hundred genes underwent an ordered progression of transient or permanent up- and down-regulation during differentiation. Genes that were permanently up-regulated in amastigotes were enriched for transporters and surface proteins, but under-represented in genes involved in protein and other metabolism. Most of these changes occurred late in the differentiation process, when morphological differentiation was essentially complete. Down-regulated genes were over-represented in those involved in cell motility, growth and/or maintenance, and these changes generally occurred earlier in the process. Genes that were transiently up- or down-regulated during differentiation included those encoding heat shock proteins, ubiquitin hydrolases, RNA binding proteins, protein kinases, a protein phosphatase, and a histone deacetylase. These results suggest that changes in mRNA abundance may be important in signal transduction, as well as protein and mRNA turnover, during differentiation. In addition to these mRNA changes, other transcripts including one or more rRNAs and snoRNAs, and non-coding RNAs from several telomeres, also showed substantial changes in abundance during the differentiation process. This paper provides the first genome-scale quantitative analysis of gene expression during the transition from promastigotes to amastigotes and demonstrates the utility of the host-free differentiation system.

Protozoan genomes: gene identification and annotation.

The draft sequence of several complete protozoan genomes is now available and genome projects are ongoing for a number of other species. Different strategies are being implemented to identify and annotate protein coding and RNA genes in these genomes, as well as study their genomic architecture. Since the genomes vary greatly in size, GC-content, nucleotide composition, and degree of repetitiveness, genome structure is often a factor in choosing the methodology utilised for annotation. In addition, the approach taken is dictated, to a greater or lesser extent, by the particular reasons for carrying out genome-wide analyses and the level of funding available for projects. Nevertheless, these projects have provided a plethora of material that will aid in understanding the biology and evolution of these parasites, as well as identifying new targets that can be used to design urgently required drug treatments for the diseases they cause.

Genomic organization and functional characterization of the Leishmania major Friedlin ribosomal RNA gene locus.

The sequence and gene organization of the ribosomal RNA (rRNA) genes of Leishmania major Friedlin (LmjF) were determined. Interestingly, the rDNA repeat unit contained a duplicated 526 bp fragment at the 3' end of the unit with two copies of the LSUepsilon rRNA gene. Our results suggested the presence of only approximately 24 copies of the rRNA unit per diploid genome in LmjF. Repetitive elements (IGSRE) of 63 bp occurred in the intergenic spacer (IGS) between the LSUepsilon and the SSU rRNA genes. Among the different rDNA units, the region containing the IGSRE fluctuated in length from approximately 1.3 to approximately 18 kb. The transcription initiation site (TIS) of the rRNA unit was localized by primer extension to 1043 bp upstream of the SSU gene and 184 bp downstream of the IGSRE. Sequence comparison among several species of Leishmania showed a high degree of conservation around the TIS. Moreover, the IGSRE also showed considerable similarity between Leishmania species. In transient transfection assays, a fragment containing the TIS directed a 164- to 178-fold increase in luciferase activity over the no-insert control, indicating the presence of a promoter within this 391 bp fragment. The LmjF promoter region was also functional in other species of Leishmania. Nuclear run-on analyses demonstrated that only the rRNA-coding strand is transcribed, downstream of this RNA polymerase I (pol I) promoter. These experiments also suggested that transcription terminates upstream of the IGSRE.

Cathepsin B-like cysteine proteases and Caenorhabditis elegans homologues dominate gene products expressed in adult Haemonchus contortus intestine.

Proteins expressed by nematode intestinal cells are potential targets for parasite control by immune or chemical based strategies. To expand our knowledge on nematode intestinal proteins, expressed sequence tags were generated for 131 cDNA clones from the intestine of adult female Haemonchus contortus. An estimated 55 distinct protein genes or gene families were identified. Predicted proteins represented diverse functions. Several predicted polypeptides were related to H. contortus proteins implicated in inducing protective immunity against challenge infections of this parasite. The dominant intestinal transcripts were represented by cathepsin B-like cysteine protease genes (cbl) (17% of protein coding expressed sequence tags (ESTs) analyzed). An estimated 11 previously undescribed cbl genes were identified, doubling the recognized members of this gene family. Multiple C-type lectin sequences were identified. Other notable sequences included a predicted Y-box binding protein, serine/threonine kinases and a cyclin E-like sequence. Predicted protein homologues were found in Caenorhabditis elegans for all but one H. contortus sequence (99%), while fewer homologues from other parasitic nematodes were found. Many of the proteases, lipase and C-type lectin homologues in C. elegans had apparent signal peptides, suggesting that they are secreted. Several gene products had no obvious similarity outside the phylum Nematoda. The ESTs identified intestinal genes with potential application to immune control, understanding of basic intestinal regulatory processes and refinement of nematode genomic resources.

Tetracycline regulated gene expression in Leishmania donovani.

The prokaryotic tetracycline-responsive repressor/operator system has proven to be useful for studying the function of essential genes and the expression of toxic gene products in a number of organisms, including Trypanosoma brucei. We report here the adaptation of this system for use in Leishmania. The inducible promoter construct contains a bleomycin resistance-luciferase fusion (BLE-LUC) gene driven by an rRNA promoter with two copies of the TetO sequence inserted two nucleotides upstream of the transcriptional start site. This construct showed regulation of BLE-LUC expression by two orders of magnitude when targeted into the rDNA locus in the reverse orientation relative to transcription of the rRNA genes in a Leishmania donovani cell line expressing TETR. The luciferase expression level in the absence of tetracycline was approximately 50-fold lower than that in the tubulin locus (where it is transcribed by pol II), while the expression level in the presence of tetracycline was approximately five-fold higher than that from the tubulin locus. There was no linear relationship between the level of TETR expression and the regulation, and changing of positions of operator did not increase regulation.

The Leishmania genome project: new insights into gene organization and function.

The sequencing of Leishmania major Friedlin chromosome 1 (Chr1), Chr3, and Chr4 has been completed. and several other chromosomes are well underway. The complete genome sequence should be available by 2003. Over 1,000 full-length new genes have been identified, with the majority (approximately 75%) having unknown function. Many of these may be Leishmania (or kinetoplastid) specific. Most interestingly, the genes are organized into large (> 100-500 kb) polycistronic clusters of adjacent genes on the same DNA strand. Chr1 contains two such clusters organized in a "divergent" manner, i.e., the mRNAs for the two sets of genes are both transcribed towards the telomeres. Nuclear run-on analysis suggests that transcription is initiated in both directions within the "divergent" region. Chr3 and Chr4 contain two "convergent" clusters, with a single "divergent" gene at one telomere of Chr3. Sequence analysis of several genes from the LD1 region of Chr35 indicates a high degree of sequence conservation between L. major and L. donovani/L. infantum within protein-coding open reading frames (ORFs), with a lower degree of conservation within the non-coding regions. Immunization of mice with recombinant antigen from two of these genes, BTI (formerly ORFG) and ORFF, results in significant reduction in parasite burden following Leishmania challenge. Recombinant ORFF antigen shows promise as a serodiagnostic. We have also developed a tetracycline-regulated promoter system, which allows us to modulate gene expression in Leishmania.

Genomic organization and gene function in Leishmania.

Sequencing of the Leishmania major Friedlin genome is well underway with chromosome 1 (Chr1) and Chr3 having been completely sequenced, and Chr4 virtually complete. Sequencing of several other chromosomes is in progress and the complete genome sequence may be available as soon as 2003. A large proportion ( approximately 70%) of the newly identified genes remains unclassified, with many of these being potentially Leishmania- (or kinetoplastid-) specific. Most interestingly, the genes are organized into large (>100-300 kb) polycistronic clusters of adjacent genes on the same DNA strand. Chr1 contains two such clusters organized in a 'divergent' manner, i. e. the mRNAs for the two sets of genes are both transcribed towards the telomeres. Chr3 contains two 'convergent' clusters, with a single 'divergent' gene at one telomere, with the two large clusters separated by a tRNA gene. We have characterized several genes from the LD1 (Leishmania DNA 1) region of Chr35. BT1 (formerly ORFG) encodes a biopterin transporter and ORFF encodes a nuclear protein of unknown function. Immunization of mice with recombinant antigens from these genes results in significant reduction in parasite burden following Leishmania challenge. Recombinant ORFF antigen shows promise as a serodiagnostic. We have also developed a tetracycline-regulated promoter system, which allows us to modulate gene expression in Leishmania.

Trypanosoma brucei: four tandemly linked genes for fatty acyl-CoA synthetases.

We have cloned four acyl CoA synthetase (ACS) genes from Trypanosoma brucei strain 927. Each of these genes encodes a polypeptide about 78 kDa in size and all four contain the "ACS signature motif." Sequence alignments indicate that these proteins are 46%-95% identical in amino acid sequence. Interestingly, three of them share almost identical C-termini (about 215 amino acid residues). Southern blots suggest that these genes are present in a single copy, and Northern blots reveal that all four are expressed in both bloodstream and procyclic trypanosomes.

Immunization with recombinant LD1 antigens protects against experimental leishmaniasis.

The genes, ORFF and BT1 (previously ORFG), are part of the multigenic LD1 locus on chromosome 35 which is frequently amplified in Leishmania. BT1 encodes a biopterin transporter, while the function of the ORFF gene product is unknown, but it is localized to the nucleus. We show here that immunization of mice with recombinant ORFF and BT1 proteins, individually, or in combination, conferred partial protection against challenge with Leishmania donovani. Protection correlated with the production of antigen-specific antibodies and in vitro splenocyte proliferation. Thus, these antigens can be potential vaccine candidates against visceral leishmaniasis.

Recent developments from the Leishmania genome project.

A first generation cosmid contig map of the Leishmania major Friedlin genome has been constructed, and genomic sequencing is well underway. Chromosome 1 (Chr1) and Chr3 have been completely sequenced, and Chr4 is virtually complete. Sequencing of several other chromosomes is in progress and the complete genome sequence may be available as soon as 2003. More than 600 completely sequenced new genes have been identified, representing approximately 8% of the total gene complement (approximately 8,600 genes) of Leishmania. Notably, a large proportion (approximately 69%) of the genes remain unclassified, with 40% of these being potentially Leishmania- (or kinetoplastid-) specific. Most interestingly, the genes are organized into large (>100-300 kb) polycistronic clusters of adjacent genes on the same DNA strand. Chr1 contains two such clusters organized in a 'divergent' manner, whereas Chr3 contains two 'convergent' clusters, with a single 'divergent' gene at one telomere, with the two large clusters separated by a tRNA gene. Statistical analyses of Chr1 show that the 'divergent junction' region between the two polycistronic gene clusters may be a candidate for an origin of DNA replication.

The size difference between leishmania major friedlin chromosome one homologues is localized to sub-telomeric repeats at one chromosomal end.

Leishmania species are members of the evolutionarily ancient protozoan order Kinetoplastidae and are important human pathogens. The Leishmania genome is relatively small (approximately 34 Mbp) and is distributed among 36 chromosome pairs, ranging in size from 0.3 to 2.5 Mbp. The smallest chromosome of Leishmania major Friedlin, chrl, consists of three homologues which differ in size by approximately 29 kb. Previous sequence and Southern analyses of all three homologues reveal a conserved chromosomal core, consisting of coding and adjacent 'non-informational' sequence. Here we show the size difference between homologues is largely restricted to variation in both the number and content of several sub-telomeric repetitive elements localized on one chromosomal end. These repetitive elements also occur on other chromosomes, but some are more dispersed in the Leishmania genome than others.

The unusual gene organization of Leishmania major chromosome 1 may reflect novel transcription processes.

The complete chromosomal sequence for chromosome 1 from Leishmania major Friedlin predicts that this chromosome has 79 protein-coding genes. Surprisingly, the first 29 of these genes are encoded in tandem on one strand of DNA, and the remaining 50 genes are encoded in tandem on the other. No RNA polymerase promoters, centromeric sequences or origins of DNA replication have been identified in the DNA sequence. Statistical analyses of the nucleotide content reveal striking, non-random, sequence-biases that are correlated with genome organization. Analysis of coding regions suggests that novel transcription processes in Leishmania may be responsible for the nucleotide bias, which in turn affects gene organization in the chromosome. These results also suggest that the region between the two units of in-tandem genes is a candidate for an origin of DNA replication.

Cloning and characterization of Leishmania donovani telomeres.

We describe here the cloning and sequence characterization of the absolute termini of several telomeres from the human parasite Leishmania donovani using a vector-adapter protocol. The 3' protruding strand of L. donovani telomeres terminates with the sequence 5'-GGTTAGGGT-OH 3'. This single-stranded sequence is adjacent to tandemly repeated blocks of double-stranded sequence consisting of variable numbers of the hexameric repeat 5'-TAGGGT-3', variable numbers of an octameric repeat 5'-TGGTCATG-3', and a single 62-bp sequence, in that order. A number of additional, more chromosome-internal, nonrepeated sequences were found adjacent to the telomere sequences. Hybridization analyses indicated that some of these telomere adjacent sequences are found on all L. donovani chromosomes, some are more abundant on certain subsets of chromosomes, and some are unique to individual chromosomes.