Genome ploidy in different stages of the Giardia lamblia life cycle.

The early diverging eukaryotic parasite Giardia lamblia is unusual in that it contains two apparently identical nuclei in the vegetative trophozoite stage. We have determined the nuclear and cellular genome ploidy of G. lamblia cells during all stages of the life cycle. During vegetative growth, the nuclei cycle between a diploid (2N) and tetraploid (4N) genome content and the cell, consequently, cycles between 4N and 8N. Stationary phase trophozoites arrest in the G2 phase with a ploidy of 8N (two nuclei, each with a 4N ploidy). On its way to cyst formation, a G1 trophozoite goes through two successive rounds of chromosome replication without an intervening cell division event. Fully differentiated cysts contain four nuclei, each with a ploidy of 4N, resulting in a cyst ploidy of 16N. The newly excysted cell, for which we suggest the term 'excyzoite', contains four nuclei (cellular ploidy 16N). In a reversal of the events occurring during encystation, the excyzoite divides twice to form four trophozoites containing two diploid nuclei each. The formation of multiple cells from a single cyst is likely to be one of the main reasons for the low infectious doses of G. lamblia.

Developmental gene regulation in Giardia lamblia: first evidence for an encystation-specific promoter and differential 5' mRNA processing.

Giardia lamblia must encyst to survive in the environment and subsequently infect new hosts. We investigated the expression of glucosamine-6-phosphate isomerase (Gln6PI), the first enzyme required for biosynthesis of N-acetylgalactosamine, for the major cyst wall polysaccharide. We isolated two Gln6PI genes that encode proteins with large areas of identity, but distinctive central and terminal regions. Both recombinant enzymes have comparable kinetics. Interestingly, these genes have distinct patterns of expression. Gln6PI-A has a conventional, short 5' untranslated region (UTR), and is expressed at a low level during vegetative growth and encystation. The Gln6PI-B gene has two transcripts - one is expressed constitutively and the second species is highly upregulated during encystation. The non-regulated Gln6PI-B transcript has the longest 5'-UTR known for Giardia and is 5' capped or blocked. In contrast, the Gln6PI-B upregulated transcript has a short, non-capped 5'-UTR. A small promoter region (< 56 bp upstream from the start codon) is sufficient for the regulated expression of Gln6PI-B. Gln6PI-B also has an antisense overlapping transcript that is expressed constitutively. A shorter antisense transcript is detected during encystation. This is the first report of a developmentally regulated promoter in Giardia, as well as evidence for a potential role of 5' RNA processing and antisense RNA in differential gene regulation.

Novel protein-disulfide isomerases from the early-diverging protist Giardia lamblia.

Protein-disulfide isomerase is essential for formation and reshuffling of disulfide bonds during nascent protein folding in the endoplasmic reticulum. The two thioredoxin-like active sites catalyze a variety of thiol-disulfide exchange reactions. We have characterized three novel protein-disulfide isomerases from the primitive eukaryote Giardia lamblia. Unlike other protein-disulfide isomerases, the giardial enzymes have only one active site. The active-site sequence motif in the giardial proteins (CGHC) is characteristic of eukaryotic protein-disulfide isomerases, and not other members of the thioredoxin superfamily that have one active site, such as thioredoxin and Dsb proteins from Gram-negative bacteria. The three giardial proteins have very different amino acid sequences and molecular masses (26, 50, and 13 kDa). All three enzymes were capable of rearranging disulfide bonds, and giardial protein-disulfide isomerase-2 also displayed oxidant and reductant activities. Surprisingly, the three giardial proteins also had Ca(2+)-dependent transglutaminase activity. This is the first report of protein-disulfide isomerases with a single active site that have diverse roles in protein cross-linking. This study may provide clues to the evolution of key functions of the endoplasmic reticulum in eukaryotic cells, protein disulfide formation, and isomerization.

A signal recognition particle receptor gene from the early-diverging eukaryote, Giardia lamblia.

The molecular mechanisms for targeting and translocation of secreted proteins are highly conserved from bacteria to mammalian cells, although the machinery is more complex in higher eukaryotes. To investigate protein transport in the early-diverging eukaryote, Giardia lamblia, we cloned the gene encoding the alpha subunit (SRalpha) of the signal recognition particle (SRP) receptor. SRalpha is a small GTPase that functions in SRP-ribosome targeting to the ER. Sequence and phylogenetic analyses showed that SRalpha from G. lamblia is most homologous to SRalpha proteins from higher eukaryotes, although it lacks some conserved motifs. Specifically, giardial SRalpha has an N-terminal extension that enables SRalpha of higher eukaryotes to interact with a beta subunit that anchors it in the ER membrane. While the C-terminal regions are similar, giardial SRalpha lacks a prominent 13 amino acid regulatory loop that is characteristic of higher eukaryotic versions. Thus, giardial SRalpha resembles that of higher eukaryotes, but likely diverged before the advent of the regulatory loop. The 1.8 kb SRalpha transcript has extremely short untranslated regions (UTRs): a 1-2 nt 5'- and a 9 nt 3' UTR with the polyadenylation signal overlapping with the stop codon. RT-PCR, Northern and Western analyses showed that SRalpha is present at relatively constant levels during vegetative growth and encystation, even though there are extensive changes in endomembrane structures and secretory activity during encystation. Imnuno-EM showed that SRalpha localizes to ER-like structures, strengthening the observation of a typical ER in G. lamlia. Unexpectedly, SRalpha was also found in the lysosome-like peripheral vacuoles, suggesting unusual protein traffic in this early eukaryote. Our results indicate that the eukaryotic type of cotranslational transport appeared early in the evolution of the eukaryotic cell.

RNase P RNA structure and cleavage reflect the primary structure of tRNA genes.

The function of RNase P RNA depends on its folding in space. A majority of RNase P RNAs from various bacteria show a similar secondary structure to that of Escherichia coli (M1 RNA). However, there are exceptions as exemplified by the RNase P RNA derived from the low GC-content Gram-positive bacteria Bacillus subtilis and Mycoplasma hyopneumoniae (Hyo P RNA). Previous studies using M1 RNA and Hyo P RNA suggest differences both with respect to the kinetics of cleavage as well as to cleavage site recognition. Here we have studied cleavage by these two structurally different RNase P RNAs as a function of changes in the 5' leader and the 3'-terminal CCA motif in the substrate. Our data suggest that the nucleotide at the -2 position in the 5' leader plays a role both for cleavage site recognition and for the rate of cleavage. However, depending on the identity of the -2 residue differences in the cleavage pattern comparing these two types of RNase P RNAs were observed. The results also suggest that the identity of the -1/+73 base-pair in the substrate influences the cleavage site recognition process. These findings will be related to differences in structure comparing these types of RNase P RNAs and the "RCCA-RNase P RNA" interaction. In addition, our findings will be discussed with respect to the primary structure of the tRNA genes in different bacteria.

Cellular and transcriptional changes during excystation of Giardia lamblia in vitro.

Excystation of Giardia lamblia entails differentiation of dormant cysts into parasitic trophozoites. Despite its importance for infection, this transformation is not understood at the cellular or molecular levels. In these studies, we report that excystation entails detection of environmental stimuli across the tough extracellular cyst wall leading to highly coordinated physiological, structural, and molecular responses. We found that novel cytoplasmic rearrangements and changes in individual species of mRNA and in cytoplasmic pH occur within the cyst wall in the earliest stage of excystation, in response to conditions modeling cyst ingestion and passage into the human stomach. This suggests that cysts do not contain all the mRNA needed for excystation and emergence and supports our hypothesis that external stimuli, including hydrogen ions, may penetrate or be perceived across the cyst wall. In contrast, changes in cyst wall structure or proteins were detected only later in excystation, in the stage that models passage into the human small intestine, where trophozoites can emerge and survive. These findings show that excystation of G. lamblia is a highly complex and active process and provide important insights into its cellular and molecular components.

A mitochondrial-like chaperonin 60 gene in Giardia lamblia: evidence that diplomonads once harbored an endosymbiont related to the progenitor of mitochondria.

Diplomonads, parabasalids, as represented by trichomonads, and microsporidia are three protist lineages lacking mitochondria that branch earlier than all other eukaryotes in small subunit rRNA and elongation factor phylogenies. The absence of mitochondria and plastids in these organisms suggested that they diverged before the origin of these organelles. However, recent discoveries of mitochondrial-like heat shock protein 70 and/or chaperonin 60 (cpn60) genes in trichomonads and microsporidia imply that the ancestors of these two groups once harbored mitochondria or their endosymbiotic progenitors. In this report, we describe a mitochondrial-like cpn60 homolog from the diplomonad parasite Giardia lamblia. Northern and Western blots reveal that the expression of cpn60 is independent of cellular stress and, except during excystation, occurs throughout the G. lamblia life cycle. Phylogenetic analyses position the G. lamblia cpn60 in a clade that includes mitochondrial and hydrogenosomal cpn60 proteins. The most parsimonious interpretation of these data is that the cpn60 gene was transferred from the endosymbiotic ancestors of mitochondria to the nucleus early in eukaryotic evolution, before the divergence of the diplomonads and trichomonads from other extant eukaryotic lineages. A more complicated explanation requires that these genes originated from distinct alpha-proteobacterial endosymbioses that formed transiently within these protist lineages.

Differentiation-associated surface antigen variation in the ancient eukaryote Giardia lamblia.

Encystation of Giardia lamblia is required for survival outside the host, whereas excystation initiates infection. The dormant cyst was considered an adaptation to external survival and passage through the stomach. However, we found previously that trophozoites which had recovered after completion of the life cycle had switched their major variant surface protein (VSP), called TSA 417, but neither the timing nor the molecular mechanism of switching had been elucidated. Here we demonstrate that TSA 417 predominates in cysts, but is downregulated during the stage of excystation that models cyst arrival in the small intestine. Transcripts of new VSPs appear late in encystation, and during and after excystation. Trophozoites appear to prepare for switching during encystation, when the major VSP on the cell surface diminishes and is internalized in lysosome-like vacuoles. As short-range DNA rearrangements were not detected, giardial VSP switching during differentiation appears to resemble the in situ switching of surface glycoproteins in African trypanosomes. We also report a unique extended 15 nucleotide polyadenylation signal in all VSP transcripts, but not in other known giardial genes. Antigenic variation during encystation-excystation may be a novel form of immune evasion that could help explain the common occurrence of reinfection by Giardia and other parasites with similar life cycles.

Developmentally regulated transcripts and evidence of differential mRNA processing in Giardia lamblia.

Although encystation and excystation are crucial to transmission of Giardia lamblia, little is known about the regulation of these very distinct differentiation processes. Fingerprinting of giardial mRNA populations throughout the time course of differentiation demonstrated complex patterns in mRNA differential display. Certain transcripts appeared or increased, while others decreased or disappeared at specific times, in response to physiologic stimuli that mimic key stages in parasite descent through the host gastrointestinal tract. This approach has allowed the direct identification of critical stages in differentiation, as well as isolation of genes which may be crucial to the development of G. lamblia. One stage-specific single copy gene (ENC6) whose transcript is greatly upregulated during encystation was analyzed further. Partial sequence analysis revealed no correspondence with known genes. 3'-rapid amplification of cDNA ends (3'-RACE) analysis of ENC6 transcripts at various times of encystation revealed two polyadenylation sites. The more proximal site, 10 nucleotides past the single classic AGTAAA sequence, was utilized only during encystation and its transcript increased approximately 16-fold during the first 24 h of encystation. In contrast, a slightly divergent polyadenylation site 288 nucleotides downstream from the open reading frame (ORF) was used during both vegetative growth and encystation, although its transcript was present at low levels. These studies are the first evidence of differential mRNA processing in G. lamblia and suggest a potential role of the 3'-untranslated region (3'-UTR) in modulating gene expression during differentiation of this primitive eukaryote.

Phylogenetic comparative mutational analysis of the base-pairing between RNase P RNA and its substrate.

We have studied the base-pairing between the 3'-terminal CCA motif of a tRNA precursor and RNase P RNA by a phylogenetic mutational comparative approach. Thus, various derivatives of the Escherichia coli tRNA(Ser)Su1 precursor harboring all possible substitutions at either the first or the second C of the 3'-terminal CCA motif were generated. Cleavage site selection on these precursors was studied using mutant variants of M1 RNA, the catalytic subunit of E. coli RNase P, carrying changes at positions 292 or 293, which are involved in the interaction with the 3'-terminal CCA motif. From our data we conclude that these two C's in the substrate interact with the well-conserved G292 and G293 through canonical Watson-Crick base-pairing. Cleavage performed using reconstituted holoenzyme complexes suggests that this interaction also occurs in the presence of the C5 protein. Furthermore, we studied the interaction using various derivatives of RNase P RNAs from Mycoplasma hyopneumoniae and Mycobacterium tuberculosis. Our results suggest that the base-pairing between the 3'-terminal CCA motif and RNase P is present also in other bacterial RNase P-substrate complexes and is not limited to a particular bacterial species.

Base pairing between Escherichia coli RNase P RNA and its substrate.

Base pairing between the substrate and the ribozyme has previously been shown to be essential for catalytic activity of most ribozymes, but not for RNase P RNA. By using compensatory mutations we have demonstrated the importance of Watson-Crick complementarity between two well-conserved residues in Escherichia coli RNase P RNA (M1 RNA), G292 and G293, and two residues in the substrate, +74C and +75C (the first and second C residues in CCA). We suggest that these nucleotides base pair (G292/+75C and G293/+74C) in the ribozyme-substrate complex and as a consequence the amino acid acceptor stem of the precursor is partly unfolded. Thus, a function of M1 RNA is to anchor the substrate through this base pairing, thereby exposing the cleavage site such that cleavage is accomplished at the correct position. Our data also suggest possible base pairing between U294 in M1 RNA and the discriminator base at position +73 of the precursor. Our findings are also discussed in terms of evolution.

Characterization of the Borrelia burgdorferi RNase P RNA gene reveals a novel tertiary interaction.

Characterization of the RNase P RNA gene derived from Borrelia burgdorferi reveals covariation of the conserved nucleotides at positions corresponding to nucleotides 128 and 230 in Escherichia coli RNase P RNA (M1 RNA). Single base substitutions at either of these positions in M1 RNA resulted in a lack of complementation of the temperature-sensitive phenotype associated with rnpA49 in vivo whereas complementation was observed for the double mutant M1 RNA or wild-type M1 RNA. Our in vitro data showed that M1 RNA harbouring a substitution at 128 or 230 cleaved a tRNA precursor both in the absence and presence of C5 with reduced efficiency compared to the wild-type and the double mutant M1 RNA. We conclude that the nucleotides at positions 128 and 230 establish a long-range tertiary interaction in RNase P RNA. Our data also suggest that this interaction together with the identity of the nucleotide at position 230 is important for Pb2+ induced cleavage at specific positions in M1 RNA.

Cloning and characterization of the RNase P RNA genes from two porcine mycoplasmas.

We report the cloning of the RNase P RNA genes from the primary aetiological agent of porcine pneumonia, Mycoplasma hyopneumoniae, and the closely related commensal, Mycoplasma flocculare. The monocistronic genes each have promoters with AT-rich -35 regions and Rho-independent-like transcription terminators which are retained in the RNase P RNA. Both of these RNase P RNA variants are shown to be catalytically active in vitro in spite of a low overall GC content (30%). Our results suggest a new example of a stable mini-helix in the conserved core of the mycoplasmal RNase P RNAs. Deletion of the corresponding structural element in Escherichia coli RNase P RNA (M1 RNA) generated an RNase P RNA with an impaired substrate interaction. Displacement of this structural element with the mycoplasmal mini-helix resulted in an enzyme with a phenotype similar to that of wild-type M1 RNA. In addition, this structural element is important for lead ion-induced cleavage at specific sites in M1 RNA.

A novel tertiary interaction in M1 RNA, the catalytic subunit of Escherichia coli RNase P.

Phylogenetic covariation of the nucleotides corresponding to the bases at positions 121 and 236 in Escherichia coli RNase P RNA (M1 RNA) has been demonstrated in eubacterial RNase P RNAs. To investigate whether the nucleotides at these positions interact in M1 RNA we introduced base substitutions at either or at both of these positions. Single base substitutions at 121 or at 236 resulted in M1 RNA molecules which did not complement the temperature-sensitive phenotype associated with rnpA49 in vivo whereas wild-type M1 RNA or the double mutant M1 RNA, with restored base-pairing between 121 and 236, did. In addition, wild-type and the double mutant M1 RNA were efficiently cleaved by Pb++ between positions 122 and 123 whereas the rate of this cleavage was significantly reduced for the singly mutated M1 RNA variants. From these data we conclude that the nucleotides at positions 121 and 236 in M1 RNA establish a novel long-range tertiary interaction in M1 RNA. Our results also demonstrated that this interaction is not absolutely required for cleavage in vitro, however, a disruption resulted in a reduction in cleavage efficiency (kcat/Km), both in the absence and presence of C5.

Identification of a region within M1 RNA of Escherichia coli RNase P important for the location of the cleavage site on a wild-type tRNA precursor.

To investigate the function of the catalytic subunit of Escherichia coli RNase P, M1 RNA, we studied cleavage by different M1 RNA mutants of wild-type precursors to tRNA(TyrSu3), tRNA(His) and tRNA(SerSu1). We showed that deletion or substitution of the conserved nucleotides G291, G292, U294 and A295 in M1 RNA resulted in a shift of the cleavage site for the tRNA(SerSu1) precursor, whereas the other two tRNA precursors were cleaved at the normal position. By using chimeric tRNA precursors in which the acceptor-stem of the tRNA(TyrSu3) precursor was replaced by the acceptor-stem derived from the tRNA(SerSu1) precursor, we showed that the aberrant cleavage by M1 RNA mutants could be reversed by substituting the nucleotide at position -2 in one of the chimeric precursors. These results suggest, in support of our previous findings, that different tRNA precursors are processed differently and that the primary structure of the amino acid acceptor-stem of a tRNA precursor plays a significant role in the RNase P cleavage reaction. Furthermore, in agreement with a previous report, a truncated tRNA(TyrSu3) precursor was cleaved aberrantly by a mutant M1 RNA in which the nucleotide at position 92 had been deleted. In contrast, a corresponding truncated tRNA(SerSu1) precursor was cleaved at the same position both by the wild-type and by this mutant M1 RNA. We conclude that not only the primary structures of the acceptor-stems of tRNA precursors, but also the primary structures in different regions of M1 RNA determine the location of the cleavage site on various tRNA precursors. Here we have identified the region G291 to A295 to be important for the selection of the cleavage site on the tRNA(SerSu1) precursor. We discuss the possibility that the conformation of M1 RNA in the enzyme-substrate complex is dependent on the identity of the substrate.

Determinants of Escherichia coli RNase P cleavage site selection: a detailed in vitro and in vivo analysis.

The location of the Escherichia coli RNase P cleavage site was studied both in vitro and in vivo. We show that selection of the cleavage site is dependent on the nucleotide at the cleavage site and the length of the acceptor-stem. Within the acceptor-stem the number of nucleotides on the 5'-half of the acceptor-stem appears to be the important determinant, rather than the number of base pairs in the acceptor-stem. We also demonstrate that the length of the T-stem and a G to C substitution at position 57 in the tRNA(Tyr)Su3 precursor influence the location of the cleavage site under certain conditions. With respect to the function of the subunits of RNase P our data suggest that the nucleotide at position 333 in M1 RNA, and the C5 protein, are important for the identification of the cleavage site.

Several regions of a tRNA precursor determine the Escherichia coli RNase P cleavage site.

The RNase P cleavage reaction was studied as a function of the number of base-pairs in the acceptor-stem and/or T-stem of a natural tRNA precursor, the tRNA(Tyr)Su3 precursor. Our data suggest that the location of the Escherichia coli RNase P cleavage site does not depend merely on the lengths of the acceptor-stem and T-stem as previously suggested. Surprisingly, we find that precursors with only four base-pairs in the acceptor-stem are cleaved by M1 RNA and by holoenzyme. Furthermore, we show that both disruption of base-pairing, and alteration of the nucleotide sequence (without disruption of base-pairing) proximal to the cleavage site result in aberrant cleavage. Thus, the identity of the nucleotides near the cleavage site is important for recognition of the cleavage site rather than base-pairing. The important nucleotides are those at positions -2, -1, +1, +72, +73 and +74. We propose that the nucleotide at position +1 functions as a guiding nucleotide. These results raise the possibility that Mg2+ binding near the cleavage site is dependent on the identity of the nucleotides at these positions. In addition, we show that disruption of base-pairing in the acceptor-stem affects both Michaelis-Menten constants, Km and kcat.

The kinetics and specificity of cleavage by RNase P is mainly dependent on the structure of the amino acid acceptor stem.

Cleavage by RNase P of the tRNA(His precursor yields a mature tRNA with an 8 base pair amino acid acceptor stem instead of the usual 7 base pair stem. Here we show, both in vivo and in vitro, that this is mainly dependent on the primary structure and length of the acceptor stem in the precursor. Furthermore, the tRNA(His) precursor used in this study was processed with a change in both kinetic constants, Km and kcat, in comparison to the kinetics of cleavage of the precursor to tRNA(Tyr)Su3. Cleavage of a chimeric tRNA precursor showed that these altered kinetics were due to a difference in the primary structure and in the length of the acceptor stems of these two tRNA precursors. We also studied the cleavage reaction as a function of base substitutions at positions -1 and/or +73 in the precursor to tRNA(His). Our results suggest that the nucleotide at position +73 in tRNA(His) plays a significant role in the kinetics of cleavage of its precursor, possibly in product release. In addition, it appears that the C5 protein of RNase P is involved in the interaction between the enzyme and its substrate in a substrate-dependent manner, as previously suggested.