Three temporal classes of gene expression during the Chlamydia trachomatis developmental cycle.

The obligate intracellular bacterium Chlamydia trachomatis has a unique developmental cycle that involves functionally and morphologically distinct cell types adapted for extracellular survival and intracellular multiplication. Infection is initiated by an environmentally resistant cell type called an elementary body (EB). Over the first several hours of infection, EBs differentiate into a larger replicative form, termed the reticulate body (RB). Late in the infectious process, RBs asynchronously begin to differentiate back to EBs, which accumulate within the lumen of the inclusion until released from the host cell for subsequent rounds of infection. In an effort to characterize temporal gene expression in relation to the chlamydial developmental cycle, we have used quantitative-competitive polymerase chain reaction (QC-PCR) and reverse transcription (RT)-PCR techniques. These analyses demonstrate that C. trachomatis double their DNA content every 2-3 h, with synthesis beginning between 2 and 4 h after infection. We determined the onset of transcription of specific temporal classes of developmentally expressed genes. RT-PCR analysis was performed on several genes encoding key enzymes or components of essential biochemical pathways and functions. This comparison encompassed approximately 8% of open reading frames on the C. trachomatis genome. In analysis of total RNA samples harvested at 2, 6, 12 and 20 h after infection, using conditions under which a single chlamydial transcript per infected cell is detected, three major temporal classes of gene expression were resolved. Initiation of transcription appears to occur in three temporal classes which we have operationally defined as: early, which are detected by 2 h after infection during the germination of EBs to RBs; mid-cycle, which appear between 6 and 12 h after infection and represent transcripts expressed during the growth and multiplication of RBs; or late, which appear between 12 and 20 h after infection and represent those genes transcribed during the terminal differentiation of RBs to EBs. Collectively, the data suggest that chlamydial early gene functions are weighted toward initiation of macromolecular synthesis and the establishment of their intracellular niche by modification of the inclusion membrane. Surprisingly, representative enzymes of intermediary metabolism and structural proteins do not appear to be transcribed until 10-12 h after infection; coinciding with the onset of observed binary fission of RBs. Late gene functions appear to be predominately those associated with the terminal differentiation of RBs back to EBs.

Identification and characterization of a Chlamydia trachomatis early operon encoding four novel inclusion membrane proteins.

Chlamydia trachomatis is a bacterial obligate intracellular parasite that replicates within a vacuole, termed an inclusion, that does not fuse with lysosomes. Within 2 h after internalization, the C. trachomatis inclusion ceases to interact with the endocytic pathway and, instead, becomes fusogenic with exocytic vesicles containing exogenously synthesized NBD-sphingomyelin. Both fusion of exocytic vesicles and long-term avoidance of lysosomal fusion require early chlamydial gene expression. Modification of the chlamydial inclusion probably occurs through the expression and insertion of chlamydial protein(s) into the inclusion membrane. To identify candidate inclusion membrane proteins, antisera were raised against a total membrane fraction purified from C. trachomatis-infected HeLa cells. By indirect immunofluorescence, this antisera recognized the inclusion membrane and, by immunoblot analysis, recognized three chlamydial-specific antigens of approximate molecular weights 15, 18 and 21 kDa. IncG, encoding an 18 kDa and 21 kDa doublet chlamydial antigen, was identified by screening a C. trachomatis, serovar L2, genomic expression library. Three additional genes, incD, incE and incF, were co-transcribed with incG. Monospecific antisera against each of the four genes of this operon demonstrated that the gene products were localized to the chlamydial inclusion membrane. Immediately downstream from the operon containing incD-G was the C. trachomatis homologue of incA. Like IncD, E, F and G, C. trachomatis IncA is also localized to the inclusion membrane. Reverse transcriptase-polymerase chain reaction (RT-PCR) analysis demonstrated that IncD-G, but not incA, are transcribed within the first 2 h after internalization, making them candidates for chlamydial factors required for the modification of the nascent chlamydial inclusion.

The Chlamydia trachomatis IncA protein is required for homotypic vesicle fusion.

Chlamydiae replicate within an intracellular vacuole, termed an inclusion, that is non-fusogenic with vesicles of the endosomal or lysosomal compartments. Instead, the inclusion appears to intersect an exocytic pathway from which chlamydiae intercept sphingomyelin en route from the Golgi apparatus to the plasma membrane. Chlamydial protein synthesis is required to establish this interaction. In an effort to identify those chlamydial proteins controlling vesicle fusion, we have prepared polyclonal antibodies against several Chlamydia trachomatis inclusion membrane proteins. Microinjection of polyclonal antibodies against three C. trachomatis inclusion membrane proteins, IncA, F and G, into the cytosol of cells infected with C. trachomatis demonstrates reactivity with antigens on the cytoplasmic face of the inclusion membrane, without apparent inhibition of chlamydial multiplication. Microinjection of antibodies against the C. trachomatis IncA protein, however, results in the development of an aberrant multilobed inclusion structure remarkably similar to that of C. psittaci GPIC. These results suggest that the C. trachomatis IncA protein is involved in homotypic vesicle fusion and/or septation of the inclusion membrane that is believed to accompany bacterial cell division in C. psittaci. This proposal is corroborated by the expression of C. trachomatis and C. psittaci IncA in a yeast two-hybrid system to demonstrate C. trachomatis, but not C. psittaci, IncA interactions. Despite the inhibition of homotypic fusion of C. trachomatis inclusions, fusion of sphingomyelin-containing vesicles with the inclusion was not suppressed.

Isolation and characterization of the dnaA gene of Rickettsia prowazekii.

The dnaA gene encoding the initiator protein of DNA replication was isolated from the obligate intracellular bacterium, Rickettsia prowazekii. Comparison of the deduced amino acid sequence of R. prowazekii DnaA with other bacterial DnaA proteins revealed extensive similarity. However, the rickettsial sequence is unique in the number of basic lysine residues found within a highly conserved portion of the putative DNA binding region, suggesting that the rickettsial protein may recognize a DNA sequence that differs from the consensus DnaA box sequence identified in other bacteria. Consensus DnaA box sequences, found upstream of many bacterial dnaA genes, were not identified upstream of rickettsial dnaA gene. In addition, gene organization within this region differed from that of other bacteria. The putative start of transcription of the rickettsial dnaA gene was localized to a site 522 nucleotides (nt) upstream of the DnaA start codon.

Transcriptional characterization of the Rickettsia prowazekii major macromolecular synthesis operon.

Recent studies have demonstrated that Rickettsia prowazekii can regulate transcription of selected genes at the level of initiation. However, little information concerning the existence of operons and coordinate gene regulation in this obligate intracellular parasitic bacterium is available. To address these issues, we have focused on the rpoD gene linkage group (greA-open reading frame 23 [ORF23]-dnaG-rpoD), which includes the rickettsial analog (ORF23-dnaG-rpoD) of the major macromolecular synthesis operon (MMSO). The rickettsial MMSO consists of an ORF coding for a protein of unknown function the structural genes for DNA primase (dnaG) and the major sigma factor of RNA polymerase (rpoD). RNase protection assays (RPA) were used to determine if these genes are organized into an operon controlled by multiple promoters and the quantities of transcripts produced by these genes relative to each other. RPA with a probe spanning the 270-base greA-ORF23 intervening region identified a putative transcriptional promoter within the intervening sequence. Multiple RPA probes spanning the next 4,041 bases of the linkage group demonstrated the presence of a continuous transcript and thus the existence of an operon. A probe spanning the dnaG-rpoD region revealed that two additional mRNA fragments were also protected, which enabled us to identify additional putative promoters for rpoD within dnaG. Primer extension determined that the 5' ends of the three transcripts consist separately of adenine (located 227 bases upstream of ORF23) and uracil and adenine (located 336 and 250 bases upstream of rpoD, respectively). Quantitation of transcripts produced by the three ORFs determined the relative amounts of transcripts (ORF23 to dnaG to rpoD) to be 1:2.7:5.1.

Characterization of a Rickettsia rickettsii DNA fragment analogous to the fir A-ORF17-lpxA region of Escherichia coli.

The firA and lpxA genes, as well as an ORF coding for a putative 16-kDa protein of unknown function, have been identified and characterized in the obligate intracellular bacterium. Rickettsia rickettsii. This is the first description of these genes, which code for enzymes involved in the biosynthesis of lipid A, in a species outside of the Enterobacteriaceae. The deduced amino acid (aa) sequences of FirA, ORF16 and LpxA of R. rickettsii, when compared to their Escherichia coli analogs, exhibited 35, 44 and 41% aa identity, respectively. In addition, the order of genes in R. rickettsii, firA-ORF16-lpxA, was identical to that found in E. coli; however, the spacing between the rickettsial genes was greater. Interestingly, the R. rickettsii FirA and LpxA deduced proteins retain an unusual hexapeptide repeat pattern found in E. coli and Salmonella typhimurium FirA/Ssc and E. coli LpxA, as well as other acyltransferases, providing additional support for the importance of this structure.

Spin-label substitutions in cisplatin reduce toxicity and interaction with radiation.

A piperidinyl-labeled platinum(II) complex, cis-Pt[2,2,6,6-tetramethyl-4-aminopiperidine-N-oxyl]2dichloride , is an ESR-traceable analog of the antitumor agent, cis-diamminedichloroplatinum(II), DDP. The toxicity of the analog (PDN-1) in Chinese hamster ovary (CHO) cells is 22 times less than that of the parent compound: D0 (where D0 = slope-1 of the straight-line portion of the survival curve) = 0.11 mM versus 0.0053 mM for 1.5-h treatments with PDN-1 and DDP, respectively. At PDN-1 doses that cause 10% killing when used alone, no statistically significant increase in cell killing of hypoxic, irradiated cells was observed. PDN-1 does not have significant dose-modifying properties but may be a useful probe to study platinum in mammalian cells.

Conditions necessary for quantifying ethyl methanesulfonate-induced mutations to purine-analogue resistance in Chinese hamster V79 cells.

We have investigated conditions necessary to quantify the relationship between exposure to a mutagen, ethyl methanesulfonate (EMS), and the frequency of mutation induction at the hypoxanthine-guanine phosphoribosyl transferase locus in V79 cells. Maximal expression of potential mutants has been achieved by either subculturing at fewer than 5 X 10(5) cells/100-mm dish at 2-day intervals or by daily feeding of cultures. An expression period of 5 days (measure from 1 day after the initiation of treatment with the chemical mutagen) should be allowed, since at least 4 days of expression is required to reach to steady maximum of mutation frequency. It appears that there is no concentration dependence of expression time necessary to reach a plateau of mutation frequency with increasing concentrations of EMS up to 1.6 mg/ml. About 1.25 X 10(5) cells/100-mm dish or fewer should be plated for selection to avoid the loss of mutants which occurs at 1.5 X 10(5) cells/dish, presumably through cross-feeding (metabolic cooperation). The use of 6-thioguanine in hypoxanthine-free medium (supplemented with dialyzed fetal calf serum) appears to be a very stringent condition for selection. Mutation induction by EMS as a function of EMS exposure (EMS concentration X treatment time) increases linearly with concentration up to 12 h. For these treatment periods, the observed mutation frequencies for EMS are directly proportional to mutagen exposure regardless of the duration of the treatment.