Regulatory sequences and a novel gene in the msp (GP63) gene cluster of Leishmania chagasi.

The surface protease GP63 of Leishmania chagasi is encoded by a cluster of more than 18 tandem major surface protease (msp) genes belonging to three classes (mspL, mspS, mspC). mspL and mspS transcripts are differentially expressed during parasite growth. RNAs from mspS genes predominate during stationary phase, the time when parasite virulence and GP63 expression are maximal. We hypothesized that the unique regions downstream of mspS genes contain signals important for gene expression. The 2.8 kb region between tandem mspS genes was found to contain an 882 bp open reading frame designated mag. Copies of mag were found downstream of all mspS genes in the cluster. mag hybridized faintly to bands on Northern blots and a fully processed mag cDNA was identified in a promastigote cDNA library, providing evidence that mag genes are expressed at low levels. Similar to mspS RNAs, the abundance of mag RNAs was greater in stationary phase than logarithmic phase organisms, although mag RNAs were less abundant than mspS RNAs throughout growth. Northern blots and enzyme assays of promastigotes containing plasmid constructs in which the beta-galactosidase gene was followed by sequences between mspS coding regions, either with or without mag and its downstream sequences, suggest these regions have several regulatory effects accounting for the growth-associated changes in mspS expression.

Glycoprotein 46 mRNA abundance is post-transcriptionally regulated during development of Leishmania chagasi promastigotes to an infectious form.

GP46 is an abundant glycoprotein of 46 kDa on the surface of the promastigote form of most Leishmania species. We show that the steady state level of GP46 mRNA increases >>30-fold as Leishmania chagasi promastigotes develop in vitro from a less infectious form during logarithmic growth to a highly infectious form in the stationary phase of cultivation. Nuclear run-on experiments demonstrate that this increase in GP46 mRNA abundance is regulated post-transcriptionally. Plasmids containing the 3'-untranslated regions (UTRs) and downstream intergenic regions (IRs) of two different GP46 genes fused immediately downstream of the beta-galactosidase coding region were transfected into L. chagasi, and beta-galactosidase activity and mRNA levels were examined. The presence of the 3'-UTR + IR of one GP46 gene (gp46A) resulted in a steady increase in beta-galactosidase activity and mRNA level as the transfected promastigotes developed from logarithmic to stationary phase. This differential effect parallels that of the 3'-UTRs + IRs of a family of genes for an unrelated Leishmania surface glycoprotein, GP63. Thus, post-transcriptional regulation of the genes for two different surface glycoproteins of Leishmania occurs via a similar mechanism.

Intergenic regions between tandem gp63 genes influence the differential expression of gp63 RNAs in Leishmania chagasi promastigotes.

The major surface protease, gp63, of Leishmania chagasi is encoded by 18 or more tandem msp genes that can be grouped into three classes on the basis of their unique 3'-untranslated sequences (3'-UTRs) and their differential expression. RNAs from the mspLs occur predominantly during the logarithmic phase of promastigote growth in vitro, RNAs from the mspSs are present mainly in stationary phase, and RNAs from mspCs occur throughout growth in culture. All three classes of gp63 genes are constitutively transcribed during all growth phases, indicating that their expression is post-transcriptionally regulated. Chimeric plasmids containing the three different 3'-UTRs and downstream intergenic regions (IRs) fused downstream of the beta-galactosidase (beta-gal) coding region were transfected into L. chagasi, and their effects on beta-gal RNA processing and enzymatic activity were examined. The presence of the 3'-UTRs by themselves had no substantive effect on beta-gal expression. However, the 3'-UTR from a mspS plus its IR resulted in about 20-fold more beta-gal activity and RNA in stationary phase relative to logarithmic phase cells. In contrast, the 3'-UTRs plus IRs of mspL and mspC had either no or little effect, respectively, on beta-gal expression. Thus, differential expression of the mspLs and mspSs is post-transcriptionally controlled by different mechanisms.

Use of monoclonal anti-light subunit antibodies to study the structure and function of the Entamoeba histolytica Gal/GalNAc adherence lectin.

Adherence of Entamoeba histolytica trophozoites to host cells is mediated by a galactose (Gal) and N-acetylgalactosamine (GalNAc)-specific surface lectin. The lectin is a heterodimeric protein composed of heavy (170 kDa) and light (35-31 kDa) subunits linked by disulfide bonds. Polyclonal and monoclonal antibodies (mAb) raised against a light subunit-glutathione-S-transferase fusion protein were used to probe its structure and function. Four light subunit-specific mAb were produced which recognized distinct epitopes on five different light subunit isoforms. Immunoblots with these mAb demonstrated co-migration of light and heavy subunits when nonreduced trophozoite proteins were analysed by SDS-PAGE, indicating that the subunits do not exist free of the heterodimer in significant quantities. While anti-heavy subunit antibodies had previously been shown to alter adherence, anti-light subunit antibodies did not, suggesting that the heavy subunit contains the carbohydrate recognition domain.

Fiber-optic pressure sensors for internal combustion engines.

Two designs incorporating embedded fiber Fabry-Perot interferometers as strain gauges were used for monitoring gas pressure in internal combustion engines. Measurements on a Diesel engine, a gasoline-fueled engine, and a natural-gas engine are reported.

Structural analysis of the light subunit of the Entamoeba histolytica galactose-specific adherence lectin.

Adherence of Entamoeba histolytica trophozoites to colonic mucins and resistance to lysis by the membrane attack complex of complement are mediated by a galactose- and N-acetyl-D-galactosamine-specific cell-surface lectin. This lectin is a heterodimeric glycoprotein of heavy (170 kDa) and light (35/31 kDa) subunits. In this work, the amino acid sequence and membrane anchor of the light subunit were analyzed. The light subunit cDNA encoded a protein with a calculated molecular mass of 32 kDa containing two potential sites for N-linked glycosylation and putative amino- and carboxyl-terminal signal sequences characteristic of glycosylphosphatidylinositol (GPI)-anchored proteins. No classical carbohydrate-binding domains common to C- or S-type eukaryotic lectins were detected by sequence analysis of either the heavy or light subunits, leaving the location of the ligand-binding site of the lectin unknown. Analysis of restriction enzyme-digested E. histolytica DNA by Southern blotting was consistent with the presence of more than one light subunit gene. Two light subunit isoforms of 31 and 35 kDa were identified by SDS-polyacrylamide gel electrophoresis analysis of affinity-purified lectin, and the isoforms were shown on two-dimensional gel analysis to form distinct 170/35- and 170/31-kDa heterodimers. The amino acid compositions and cyanogen bromide peptide patterns of the two light subunit isoforms were nearly identical. The 35-kDa isoform labeled more efficiently than the 31-kDa isoform with [3H]glucosamine, while only the 31-kDa isoform labeled with [3H]myristate and [3H]palmitate. Nitrous acid deamination released lipid from the 31-kDa isoform, which co-migrated on thin layer chromatography with acylphosphatidylinositol, a component of some GPI anchors. Gas chromatography and mass spectrometry of the deamination product from the 31-kDa subunit identified both myo- and chiro-inositols, supporting the presence of a GPI membrane anchor. The covalent association of a transmembrane protein with a GPI-anchored protein, as suggested by the cDNA sequences of the lectin heavy and light subunits, is novel and suggests unique roles for the two subunits in the pathogenesis of amebiasis.

Inhibition of the complement membrane attack complex by the galactose-specific adhesion of Entamoeba histolytica.

The human complement system is an important early host defense against infection. Entamoeba histolytica activates the complement system but is resistant to killing by complement C5b-9 complexes deposited on the membrane surface. Our aim was to identify components of the amebic plasma membrane that mediate resistance to human complement C5b-9 by screening for neutralizing monoclonal antibodies. A monoclonal antibody was identified that abrogated amebic resistance to C5b-9, and the mAb was shown to recognize the parasite's galactose-specific adhesin. The purified adhesin bound to C8 and C9 and conferred C5b-9 resistance to sensitive ameba upon reconstitution; these activities of the adhesin were inhibited by the antiadhesin mAb. The E. histolytica adhesin shared sequence similarities and antigenic cross-reactivity with CD59, a membrane inhibitor of C5b-9 in human blood cells, suggesting both molecular mimicry and shared complement-inhibitory functions.