A tandem repeat of rat-derived Pneumocystis carinii genes encoding the major surface glycoprotein

Genomics and evolution of Pneumocystis species

The genus Pneumocystis comprises highly diversified fungal species that cause severe pneumonia in individuals with a deficient immune system. These fungi infect exclusively mammals and present a strict host species specificity. These species have co-diverged with their hosts for long periods of time (> 100 MYA). Details of their biology and evolution are fragmentary mainly because of a lack of an established long-term culture system. Recent genomic advances have unlocked new areas of research and allow new hypotheses to be tested. We review here new findings of the genomic studies in relation with the evolutionary trajectory of these fungi and discuss the impact of genomic data analysis in the context of the population genetics. The combination of slow genome decay and limited expansion of specific gene families and introns reflect intimate interactions of these species with their hosts. The evolutionary adaptation of these organisms is profoundly influenced by their population structure, which in turn is determined by intrinsic features such as their self-fertilizing mating system, high host specificity, long generation times, and transmission mode. Essential key questions concerning their adaptation and speciation remain to be answered. The next cornerstone will consist in the establishment of a long-term culture system and genetic manipulation that should allow unravelling the driving forces of Pneumocystis species evolution.

Variability of phenotypic traits in Cryptococcus varieties and species and the resulting implications for pathogenesis

Variability of phenotypic characteristics in Cryptococcus neoformans var. grubii and var. neoformans as well as Cryptococcus gattii can have diverse effects on the virulence of these fungi and are thus important for pathogenesis. This article summarizes the diverse phenotypic changes that these fungi can manifest. We divide changes into those that affect the entire fungal population and are predominantly induced by environmental signals, and those that involve subpopulations of the fungal population and have to be selected. Last, the article summarizes the experimental evidence that epitopes on the polysaccharide capsule also vary, which may have implications for the pathogenesis as these findings would further diversify the fungal population.

Antigenic and phenotypic variations in fungi

Mechanisms to vary the phenotypic characteristics of fungi are diverse and can be important for their life cycle. This review summarizes phenotypic variability in fungi and divides this phenomenon into three topics: (i) morphological transitions, which are environmentally induced and involve the entire fungal population, (ii) reversible phenotypic switching between different colony morphologies, which is restricted to a small fraction of the population, and (iii) antigenic variation of surface antigens, which can be immuno-dominant epitopes happens in individual fungal cells.

Complexity of the MSG gene family of Pneumocystis carinii

Background

The relationship between the parasitic fungus Pneumocystis carinii and its host, the laboratory rat, presumably involves features that allow the fungus to circumvent attacks by the immune system. It is hypothesized that the major surface glycoprotein (MSG) gene family endows Pneumocystis with the capacity to vary its surface. This gene family is comprised of approximately 80 genes, which each are approximately 3 kb long. Expression of the MSG gene family is regulated by a cis-dependent mechanism that involves a unique telomeric site in the genome called the expression site. Only the MSG gene adjacent to the expression site is represented by messenger RNA. Several P. carinii MSG genes have been sequenced, which showed that genes in the family can encode distinct isoforms of MSG. The vast majority of family members have not been characterized at the sequence level.

Results

The first 300 basepairs of MSG genes were subjected to analysis herein. Analysis of 581 MSG sequence reads from P. carinii genomic DNA yielded 281 different sequences. However, many of the sequence reads differed from others at only one site, a degree of variation consistent with that expected to be caused by error. Accounting for error reduced the number of truly distinct sequences observed to 158, roughly twice the number expected if the gene family contains 80 members. The size of the gene family was verified by PCR. The excess of distinct sequences appeared to be due to allelic variation. Discounting alleles, there were 73 different MSG genes observed. The 73 genes differed by 19% on average. Variable regions were rich in nucleotide differences that changed the encoded protein. The genes shared three regions in which at least 16 consecutive basepairs were invariant. There were numerous cases where two different genes were identical within a region that was variable among family members as a whole, suggesting recombination among family members.

Conclusion

A set of sequences that represents most if not all of the members of the P. carinii MSG gene family was obtained. The protein-changing nature of the variation among these sequences suggests that the family has been shaped by selection for protein variation, which is consistent with the hypothesis that the MSG gene family functions to enhance phenotypic variation among the members of a population of P. carinii.

[Pnemocystis jiroveci pneumonia: Comparison between conventional PCR and staining techniques]

Diagnosis of pneumocystis pneumonia is usually based on clinical features and X-rays photography and confirmed in the laboratory by visualisation of Pneumocystis organisms in stained preparations of respiratory specimens using several techniques (Gomori-Grocott, May-Grünwald Giemsa, bleu de toluidine O). Actually, PCR has considerably increased sensitivity of detection of Pneumocystis. The aim of this study is to compare conventional PCR results to those of staining techniques (Gomori-Grocott, May-Grünwald Giemsa) in addition to the X-ray and clinical findings in order to evaluate the contribution of each method. Sixty-four respiratory specimens were collected from 54 immuno-compromised patients with clinical symptoms of pulmonary infection. We diagnosed pneumocystis pneumonia in 16 patients according to staining techniques and/or typical clinical and radiological findings and/or response to treatment. Of the 15 patients, 14 were positive by PCR and only five were positive by direct examination, yielding a sensitivity and specificity of 93.3 and 87.1% for PCR and 33.3 and 100% for staining techniques. Conventional PCR provides a sensitive and objective method for the detection Pneumocystis jiroveci from less invasive sample.

Antigenic variation in pneumocystis

Pneumocystis is a genus containing many species of non-culturable fungi, each of which infects a different mammalian host. Pneumonia caused by Pneumocystis is a problem in immunodeficient humans, but not in normal humans. Nevertheless, it appears that Pneumocystis organisms cannot survive and proliferate outside of their mammalian hosts, suggesting that Pneumocystis parasitizes immunocompetent mammals. Residence in immunocompetent hosts may rely on camouflage perpetrated by antigenic variation. In P. carinii, which is found in rats, there exist three families of genes that appear to be designed to create antigenic variation. One gene family, which encodes the major surface glycoprotein (MSG), contains nearly 100 members. Expression of the MSG family is controlled by restricting transcription to the one gene that is linked to a unique expression site. Changes in the sequence of the MSG gene linked to the expression site occur and appear to be caused by recombination with MSG genes not at the expression site. Preliminary evidence suggests that gene conversion is the predominant recombination mechanism.

Pneumocystis murina MSG gene family and the structure of the locus associated with its transcription

Analysis of the Pneumocystis murina MSG gene family and expression-site locus showed that, as in Pneumocystis carinii, P. murina MSG genes are arranged in head-to-tail tandem arrays located on multiple chromosomes, and that a variety of MSG genes can reside at the unique P. murina expression site. Located between the P. murina expression site and attached MSG gene is a block of 132 basepairs that is also present at the beginning of MSG genes that are not at the expression site. The center of this sequence block resembles the 28 basepair CRJE of P. carinii, but the block of conserved sequence in P. murina is nearly five times longer than in P. carinii, and much shorter than in P. wakefieldiae. These data indicate that the P. murina expression-site locus has a distinct structure.

Expression of the Pneumocystis carinii major surface glycoprotein epitope is correlated with linkage of the cognate gene to the upstream conserved sequence locus

The major surface glycoprotein (MSG) is a variable surface antigen of the pathogenic fungus Pneumocystis carinii. Many forms of MSG are encoded by a gene family. Expression of the MSG gene family is believed to be controlled in a cis-dependent fashion. Transcription of a given MSG gene is correlated with linkage of that gene to a unique locus called the upstream conserved sequence (UCS). These data predict that the MSG protein on a given organism will match that encoded by the MSG gene at the UCS locus in that organism. To test this hypothesis, a monoclonal antibody (mAb) that recognizes a small number of MSG isoforms was identified, and the DNA sequence encoding the mAb epitope (epitope-encoding sequence, EES) was determined. Western blotting, immunofluorescence and DNA hybridization showed that expression of the mAb epitope was associated with the presence of the EES at the UCS locus. Correlation of epitope expression and UCS linkage supports the hypothesis that expression of a particular MSG on the surface requires UCS linkage of the gene encoding it.

Diversity at the locus associated with transcription of a variable surface antigen of Pneumocystis carinii as an index of population structure and dynamics in infected rats

Pneumocystis carinii expresses a surface glycoprotein called MSG. Different isoforms of MSG are encoded by a gene family spread over at least 15 telomeric sites. Only one locus, called UCS, supports the production of MSG mRNA. Previous studies showed that P. carinii populations from individual rats exhibited high degrees of diversity with respect to the MSG genes attached to the UCS locus. This diversity could have been generated primarily in the rats studied. Alternatively, the rats may have been infected by P. carinii organisms that were already different at the UCS locus. To investigate this issue, we examined the UCS locus in P. carinii from rats that had been exposed to few of the microbes at a specified time, which produced a bottleneck in the microbial population. Some of the rats with bottlenecks produced P. carinii populations in which a single MSG sequence resided at the UCS locus in 80 to 90% of the organisms, showing that P. carinii can proliferate within a rat without generating the very high levels of UCS diversity previously seen. From the degree of diversity observed in the bottlenecked populations, the maximum rate of switching appeared to be 0.01 event per generation. These data also suggest that the infectious dose is as low as one organism, that rats that share a cage readily infect each other, and that the doubling time of P. carinii in vivo is approximately 3 days. In addition, we found that inoculation with 10(7) P. carinii organisms from a population highly heterogeneous at the UCS locus reproduced this heterogeneity. By contrast, shifts in population structure occurred in rats given 10(4) P. carinii organisms, suggesting that a small fraction of these proliferated.

Pneumocystis carinii: genetic diversity and cell biology

As an important opportunistic pulmonary pathogen, Pneumocystis carinii has been the focus of extensive research over the decades. The use of laboratory animal models has permitted a detailed understanding of the host-parasite interaction but an understanding of the basic biology of P. carinii has lagged due in large part to the inability of the organism to grow well in culture and to the lack of a tractable genetic system. Molecular techniques have demonstrated extensive heterogeneity among P. carinii organisms isolated from different host species. Characterization of the genes and genomes of the Pneumocystis family has supported the notion that the family comprises different species rather than strains within the genus Pneumocystis and contributed to the understanding of the pathophysiology of infection. Many of the technical obstacles in the study of the organisms have been overcome in the past decade and the pace of research into the basic biology of the organism has accelerated. Biochemical pathways have been inferred from the presence of key enzyme activities or gene sequences, and attempts to dissect cellular pathways have been initiated. The Pneumocystis genome project promises to be a rich source of information with regard to the functional activity of the organism and the presence of specific biochemical pathways. These advances in our understanding of the biology of this organism should provide for future studies leading to the control of this opportunistic pathogen.

Functional glycosylphosphatidylinositol anchor signal sequences in the Pneumocystis carinii PRT1 protease family

Pneumocystis carinii is fungus which is a frequent cause of severe pneumonia in immunocompromised individuals. The P. carinii genome contains the PRT1 subtelomeric multigene family that encodes a kexin-like serine protease which is expressed on the surface of P. carinii. Analysis of the sequence of the carboxy-terminal sequence of many copies of PRT1 showed that they contained motifs characteristic of a glycosylphosphatidylinositol (GPI) anchor signal sequence. The ability of the C-terminal sequences of PRT1 to direct the addition of a GPI anchor was tested. CD14, a GPI-anchored monocyte glycoprotein antigen, was used as the basis of a heterologous system. CD14 was truncated to remove the carboxy-terminal sequences responsible for GPI-anchor addition. Addition of carboxy-terminal sequences from PRT1 restored high-level surface expression to the truncated CD14. Further, the majority of CD14-PRT1 recombinant protein was removed from the cell membrane by treatment with GPI-specific phospholipase C. These results suggest that the carboxy-terminal residues of most of the members of the PRT1 family of proteases have the potential to form a functional GPI-attachment signal.

Genetics of surface antigen expression in Pneumocystis carinii

This article reviews the molecular genetic data pertaining to the major surface glycoprotein (MSG) gene family of Pneumocystis carinii and its role in surface variation and compares this fungal system to antigenic variation systems in the protozoan Trypanosoma brucei and the bacteria Borrelia spp.

Major surface glycoprotein genes from Pneumocystis carinii f. sp. ratti

Pneumocystis carinii occurs in a variety of mammals, each of which harbors one or more genetically distinct "special forms" of the microbe. Laboratory rats can be infected by two special forms, P. carinii f. sp. ratti and P. carinii f. sp. carinii. P. carinii f. sp. carinii has a variable antigen, the major surface glycoprotein (MSG), the expression of which is controlled by genetic recombination. Recombination may involve the CRJE, a 23-bp DNA sequence element invariant among P. carinii f. sp. carinii MSG genes. To better understand the role of the CRJE in MSG gene expression and to explore the possible role of MSG in P. carinii infection in rats, P. carinii f. sp. ratti MSG genes were studied. These genes were found to be related to MSG genes of P. carinii f. sp. carinii, but less so than MSG genes from P. carinii f. sp. carinii are to each other. P. carinii f. sp. ratti MSG genes were present throughout the genome and were expressed as an abundant mRNA species slightly smaller than that found in P. carinii f. sp. carinii. P. carinii f. sp. ratti MSG transcripts included a CRJE-like sequence only 78% identical to the CRJE of P. carinii f. sp. carinii. Comparison of MSG proteins from the two rat special forms of P. carinii to those from human, ferret, and mouse P. carinii did not support the hypothesis that growth in the rat lung requires certain primary MSG peptide sequences.

Development of a PCR assay for diagnosis of Pneumocystis carinii pneumonia based on amplification of the multicopy major surface glycoprotein gene family

We have evaluated a PCR technique using primers based on Pneumocystis carinii major surface glycoprotein (MSG) genes, a multicopy gene family, for utility in detection of P. carinii in BAL and oropharyngeal samples obtained from immunosuppressed patients. These primers were able to detect P. carinii DNA in as little as 16 fg of genomic DNA. PCR using MSG primers detected P. carinii DNA in 7 smear-positive BAL samples (100% sensitivity), and found no P. carinii DNA in 12 smear-negative BAL samples (100% specificity). Mitochondrial ribosomal RNA (mrRNA) primers, commonly used in PCR studies of PCP, detected P. carinii in six of seven positive samples (85.7% sensitivity) and none of 12 were negative samples (100% specificity). Diagnosis of PCP by amplification of 81 oropharyngeal samples using MSG primers had a 50% sensitivity (4/8) and 96% specificity (70/73). PCR with mrRNA primers was 37.5% sensitive (3/8) and 100% specific (73/73). All three false-positive MSG results showed a very low intensity on Southern hybridization. PCR using MSG gene primers should prove valuable in the diagnosis of PCP.

Cell surface protease PRT1 identified in the fungal pathogen Pneumocystis carinii

The subtelomeric regions of the chromosomes of many organisms contain gene families that allow adaptation to a changing environment. In a number of parasites, these subtelomeric gene families encode cell surface proteins that undergo antigenic variation. Proteases are another important virulence determinant in pathogenic microorganisms. We report the localization of the PRT1 protease of the pathogenic fungus Pneumocystis carinii sp. f. carinii, encoded by a subtelomeric gene family, to the cell surface of both the trophozoite and the cyst phase of the organism. Using anti-PRT1 antiserum, we demonstrated specificity to P. carinii sp. f. carinii in sections of infected rat lungs and, using immunofluorescence, we showed that the PRT1 protease has the characteristic distribution of a surface protein. The anti-PRT1 antiserum showed cross-reactivity with a number of P. carinii sp. f. carinii proteins migrating between 185 kDa and 28 kDa, the majority migrating between 42 kDa and 52 kDa, a region that has been shown by serological studies to contain important immunodominant P. carinii proteins. Cross-reactivity was also observed with P. carinii sp. f. hominis proteins. We have also cloned a portion of the catalytic domain of PRT1 from P. carinii sp. f. hominis, P. carinii sp. f. muris and P. carinii sp. f. rattus. Our data suggest that the PRT1 protease plays an important role in the pathogenicity of P. carinii.

The genome of Pneumocystis carinii

The best understood special form of P. carinii, P. carinii formae specialis (f.sp.) carinii, appears to be haploid and contains about 8 million base pairs of DNA (8.5 fg) per nucleus. The genome of P. carinii f.sp. carinii is divided into 13-15 linear chromosomes that range from 300 to 700 kb in size. Eight different P. carinii f.sp. carinii karyotypes have been observed. The karyotypes of P. carinii f.sp. carinii differ due to slight variations in the lengths of chromosomes, but the 8 karyotype-forms of P. carinii f.sp. carinii exhibit very little variation in DNA sequence. By contrast, the genome of P. carinii f.sp. carinii differs markedly in sequence from the genomes of P. carinii from other hosts, such as mouse, ferret and human. In addition, chromosomes and DNA sequences from P. carinii from mouse, ferret, and human also differ greatly from each other. The genome of a ferret P. carinii appears to be up to 1.7 times larger than those of P. carinii from other hosts. Nearly two dozen P. carinii genes have been cloned and sequenced. The typical P. carinii gene sequence is 60-65% A+T. P. carinii genes usually contain introns, which are typically less than 50 bp in length, but can be as numerous as 9 per gene. A system for naming P. carinii genes is proposed in which each gene would be designated by an italic three-letter lower case symbol. The first allele (i.e. sequence) that is found would have a superscript 1, such as xyz1(1). Any subsequent alleles would be designated as xyz1(2), etc. A protein would have the same symbol as the gene that produced it, but written in roman print with the first letter an uppercase, such as Msg1. Some of the P. carinii genome is comprised of DNA sequences that are present dozens of times. Three families of such repeated DNA sequences have been described. Two of these families (MSG and PRT) encode proteins. The third family is the telomere repeat, which is found at the ends of each chromosome, and sometimes at internal chromosomal sites, in which case it has been called the alpha repeat. Determination of the complete sequence of the P. carinii genome is both practicable and of primary importance to the understanding of this organism. The small size of the P. carinii genome and its packaging into chromosomes that are resolvable by PFGE will facilitate sequence analysis.

Genetic heterogeneity in Pneumocystis carinii: an introduction

Molecular techniques have played an important role in demonstrating a high level of heterogeneity among the different types of organisms which are collectively known as Pneumocystis carinii. Genetic heterogeneity has been observed in Pneumocystis organisms isolated from different host species, suggesting that Pneumocystis infection is host-species specific. On the basis of this genetic divergence a provisional trinomial nomenclature has been adopted, in which different types of Pneumocystis organisms are designated a 'special form'. Multiple special forms of Pneumocystis have been detected in some host species, for example in infected rat and ferret lungs, but not in human lungs. Lower levels of genetic heterogeneity have been observed within each Pneumocystis special form, and in particular in human-derived Pneumocystis. Analysis of the genetic heterogeneity of populations of Pneumocystis is contributing to the understanding of the epidemiology and pathophysiology of this infection.

Immunization with the major surface glycoprotein of Pneumocystis carinii elicits a protective response

Pneumocystis carinii, a leading opportunistic pulmonary pathogen, contains a major surface glycoprotein (MSG) which plays a central role in its interaction with the host. Naive Lewis rats were immunized with varying concentrations of purified native MSG and a recombinant form of the protein (MSG-B), placed in a conventional rat colony with exposure to P. carinii, and immunosuppressed with corticosteroids for 10 weeks to induce the development of pneumocystosis. Immunization elicited humoral and cellular immune responses to MSG which persisted throughout the experiment. Compared with animals immunized with ovalbumin or adjuvant alone, the MSG-immunized rats had improved survival (29 vs 66%, p < 0.001), lowered organism burden (log10 9.03 +/- 0.33/lung vs 7.51 +/- 0.38/lung, p < 0.001), less alveolar involvement as assessed by lung histologic score (3.54 +/- 0.42 vs 2.50 +/- 0.42, p < 0.01) and lung weight:body weight ratio (18.2 +/- 1.4 vs 14.6 +/- 1.7, p < 0.01). Animals immunized with MSG-B also showed a significantly lower organism burden, lung histologic score and lung weight:body weight ratio than control rats. Thus, MSG is the first P. carinii antigen which can elicit a protective response in the immunosuppressed rat model of pneumocystosis and this finding supports the rationale of developing a P. carinii vaccine.

Identification of a putative precursor to the major surface glycoprotein of Pneumocystis carinii

The major surface glycoprotein (MSG) of Pneumocystis carinii f. sp. carinii is a family of proteins encoded by a family of heterogeneous genes. Messenger RNAs encoding different MSGs each begin with the same 365-bp sequence, called the Upstream Conserved Sequence (UCS), which is in frame with the contiguous MSG sequence. The UCS contains several potential start sites for translation. To determine if translation of MSG mRNAs begins in the UCS, polyclonal antiserum was raised against the 123-amino-acid peptide encoded by the UCS. The anti-UCS serum reacted with a P. carinii protein that migrated at 170 kDa; however, it did not react with the mature MSG protein, which migrates at 116 kDa. A 170-kDa protein was immunoprecipitated with anti-UCS serum and shown to react with a monoclonal antibody against a conserved MSG epitope. To explore the functional role of the UCS in the trafficking of MSG, the nucleotide sequence encoding the UCS peptide was ligated to the 5' end of an MSG gene and incorporated into a recombinant baculovirus. Insect cells infected with the UCS-MSG hybrid gene expressed a 160-kDa protein which was N-glycosylated. By contrast, insect cells infected with a baculovirus carrying an MSG gene lacking the UCS expressed a nonglycosylated 130-kDa protein. These data suggest that in P. carinii, translation begins in the UCS to produce a pre-MSG protein, which is subsequently directed to the endoplasmic reticulum and processed to the mature form by proteolytic cleavage.

Expression, structure, and location of epitopes of the major surface glycoprotein of Pneumocystis carinii f. sp. carinii

The major surface glycoprotein (MSG) of Pneumocystis carinii f. sp. carinii consists of a heterogeneous family of proteins that are encoded by approximately 100 unique genes. A genomic expression library was screened with a panel of MSG-specific monoclonal antibodies (MAbs) to identify conserved and rare epitopes. All of the antibodies reacted with epitopes that are encoded within the 5' end of MSG. The results from the expression screening identified antibodies that recognize highly conserved, moderately conserved, and rare epitopes. Four MAbs (MAbs RA-F1, RA-E7, RA-G10, and RB-E3) reacted with a maltose binding protein-MSG-B fusion protein ([MBP]MSG-B41-1065) by immunoblotting and enzyme-linked immunosorbent assay. Three of the MAbs (MAbs RA-F1, RA-G10, and RA-E7) reacted with the same continuous epitope that was localized to amino acids 278 to 290 of MSG-B. Comparison of the sequence of the RA-F1-, RA-G10-, and RA-E7-reactive epitope to the deduced amino acid sequences of multiple MSGs demonstrated that it is highly conserved. The reactivity of RB-E3 with MSG-B was shown to be dependent on amino acids 184 to 192, which may comprise a portion of a discontinuous epitope.

Pneumocystis carinii pneumonia: the status of Pneumocystis biochemistry

Pneumocystis carinii pneumonia remains a prevalent opportunistic disease among immunocompromised individuals. Although aggressive prophylaxis has decreased the number of acute P. carinii pneumonia cases, many patients cannot tolerate the available drugs, and experience recurrence of the infection, which can be fatal. It is now generally agreed that the organism should be placed with the fungi, but the identification of extant fungal species representing its closest kins, remains debated. Most recent data indicate that P. carinii represents a diverse group of organisms. Since the lack of methods for the continuous subcultivation of this organism hampered P. carinii research, molecular cloning and nucleotide sequencing approaches led the way for understanding the biochemical nature of this pathogen. However, within the last 5 years, the development of improved protocols for isolating and purifying viable organisms from infected mammalian host lungs has enabled direct biochemical and metabolism studies on the organism. The protein moiety of the major high mol. wt surface antigen, represented by numerous isoforms, is encoded by different genes. These proteins are post-transcriptionally modified by carbohydrates and lipids. The organism has the shikimic acid pathway that leads to the formation of compounds which mammals cannot synthesise (e.g., folic acid), hence drugs that inhibit these pathways are effective against the pathogen. Ornithine decarboxylase has now been detected; rapid and complete depletion of polyamines occurs in response to difluoromethylornithine (DFMO). Instead of ergosterol (the major sterol of higher fungi), P. carinii synthesises distinct delta7, C-24-alkylated sterols. An unusual C32 sterol, pneumocysterol, has been identified in human-derived P. carinii. Another signature lipid discovered is cis-9,10-epoxy stearic acid. CoQ10, identified as the major ubiquinone homologue, is synthesised de novo by P. carinii. Atovaquone and other hydroxynaphthoquinone drugs with anti-P. carinii activity probably inhibit pathogen respiration as CoQ analogues. Unlike its effects on Plasmodium, atovaquone does not inhibit the P. carinii dihydroorotate dehydrogenase and pyrimidine metabolism.

A Pneumocystis carinii multi-gene family with homology to subtilisin-like serine proteases

Copies of multi-gene family, named PRT1 (protease 1), encoding a subtilisin-like serine protease were cloned from the opportunistic fungal pathogen Pneumocystis carinii. Comparison of the nucleotide sequence of a genomic clone and a cDNA clone of PRT1 from P. carinii f. sp. carinii revealed the presence of seven short introns. Several different domains were predicted from the deduced amino acid sequence: an N-terminal hydrophobic signal sequence, a pro-domain, a subtilisin-like catalytic domain, a P-domain (essential for proteolytic activity), a proline-rich domain, a serine/threonine-rich domain and a C-terminal hydrophobic domain. The catalytic domain showed high homology to other eukaryotic subtilisin-like serine proteases and possessed the three essential residues of the catalytic active site. Karyotypic analysis showed that PRT1 was a multi-gene family, copies of which were present on all but one of the P. carinii f. sp. carinii chromosomes. The different copies of the PRT1 genes showed nucleotide sequence heterogeneity, the highest level of divergence being in the proline-rich domain, which varied in both length and composition. Some copies of PRT1 were contiguous with genes encoding the P. carinii major surface glycoprotein.

Characterization of rat CD4 T cell clones specific for the major surface glycoprotein of Pneumocystis carinii

Pneumocystis carinii are coated by abundant heterogenous major surface glycoproteins (MSGs), which facilitate interaction with the host. We have produced MSG-specific T-cell clones from the spleens of P. carinii-exposed Lewis rats and analyzed five for antigen specificity to native MSG and a recombinant form of MSG, cell surface markers, and cytokine profiles. All five of the clones were CD4+. All of the clones proliferated specifically to both the native MSG and the recombinant MSG only in the presence of antigen presenting cells demonstrating that the response is antigen/driven rather than mitogen/driven. All five of the clones secreted IL-2 and IFN-gamma, although in differing amounts, implicating a Th1 response. Only one of the clones produced any detectable IL-4. This is the first report of T cell clones responsive to a specific antigen of P. carinii, MSG. We conclude that the T cell clones will be helpful in mapping protective epitopes present in MSG and in functional studies of MSG.

Pneumocystis carinii

Improved understanding of Pneumocystis carinii, in particular the widespread use of chemoprophylaxis, has resulted in a declining incidence of infection in patients infected with HIV since the late 1980s. Despite these advances, P. carinii pneumonia continues to represent an important cause of pulmonary disease in HIV-seropositive individuals who do not receive chemoprophylaxis or when breakthrough episodes occur. This article reviews the history, biology, clinical manifestations, prognostic markers, therapy, and chemoprophylaxis of P. carinii pneumonia in HIV-seropositive patients.

A single expression site with a conserved leader sequence regulates variation of expression of the Pneumocystis carinii family of major surface glycoprotein genes

The major surface glycoprotein (MSG) of Pneumocystis carinii is encoded by a family of related but distinct genes distributed throughout the P. carinii genome. Previous reports of the genomic and mRNA MSG structure suggested that there was a highly conserved 5'-untranslated region and a highly variable translated region. In the current study, we demonstrate that there is a single expression site for MSG expression and that different MSG genes are located downstream of this expression site. Isolation of a genomic clone containing the putative 5'-untranslated region has demonstrated that there was a single base sequencing error in what was considered to be the untranslated region. The corrected sequence reveals an extended open reading frame encoding a constant amino-terminal leader domain, with a typical signal peptide, for the MSG protein family. Since this constant amino-terminal domain is encoded by a single copy genomic sequence, a recombination/gene conversion-mediated antigenic switching event is required to effect the known variability in expressed MSG sequences. Therefore, like some bacterial and protozoan pathogens, the opportunistic fungal pathogen P. carinii contains a constant genomic site dedicated to MSG expression and a switchable downstream region for the variable part of the MSG gene family.

Pneumocystis carinii: what is it, exactly?

The identity of Pneumocystis carinii has been uncertain for many years. Until recently, it was widely regarded to be a protozoan because it does not grow in culture and is not susceptible to antifungal drugs. Although these and a number of other phenotypic characteristics of P. carinii differ from those of typical fungi, analysis of DNA sequences has shown that P. carinii is a member of the fungal lineage of eukaryotes. However, a close phylogenetic relative of P. carinii has not yet been found. Analysis of gene sequences has also revealed that P. carinii is not a single entity but that the genus Pneumocystis contains a complex group of organisms. P. carinii organisms from one host species do not grow when introduced into another host species, and P. carinii isolates from different host species are more genetically divergent from one another than might be expected for members of the same species. Genetic variation of a lesser degree also occurs among P. carinii organisms from the same host species, suggesting that it may be possible to identify strains and to conduct transmission and epidemiological studies. Results of early studies exploiting genetic variation among P. carinii isolates from patients have suggested that recurrent P. carinii pneumonia may not always be caused by reactivation of latent organisms, as is commonly believed. However, other features of P. carinii suggest that this microbe has established a long-term relationship with its host. A striking new development in this regard is the discovery of a genetic system that is designed to allow variation in the structure of a major antigen on the surface of P. carinii.

Expression of variants of the major surface glycoprotein of Pneumocystis carinii

Previously, we have shown that a multicopy family of related but unique genes encodes the major surface glycoprotein (MSG) of Pneumocystis carinii. To examine whether different members of this gene family are expressed by P. carinii, antisera were prepared against peptides whose sequences were determined from the deduced amino acid sequences of variants of rat-derived MSG. Immunohistochemical staining of serial sections of rat lungs of infected animals showed that at least three variants of MSG were expressed in an individual lobe, that there was a focal expression of these variants within the lung, and that the relative numbers of these foci were different. Indirect immunofluorescent staining of purified P. carinii organisms using these antisera revealed that at least three variants of MSG were present in organisms isolated from an individual rat and that both cysts and trophozoites reacted with each antiserum. A substantial difference in the fraction of organisms reacting with a specific antipeptide antiserum was seen when comparing organisms isolated from rats raised in a single colony over a period of two years as well as organisms isolated at one time point from rats raised in different colonies. This demonstration of antigenic variation in P. carinii supports the hypothesis that P. carinii utilizes such variation for evading host defense mechanisms.

Antigenic differences associated with genetically distinct Pneumocystis carinii from rats

Pneumocystis carinii is a family of organisms found in a wide variety of mammalian lungs. In immunocompromised hosts, the organisms are able to produce an oftentimes fatal pneumonia. The existence of distinct types of Pneumocystis populations is strongly supported by antigenic and genetic evidence. In the present study, we assessed the antigenic profiles of two genetically distinct Pneumocystis carinii populations, P. carinii f. sp. carinii and P. carinii f. sp. ratti, as well as two types of P. carinii f. sp. carinii defined by electrophoretic karyotyping (forms 1 and 2). The separated and blotted proteins of the organism preparations were probed with four monoclonal antibodies (MAbs) generated to the major surface glycoproteins of rat-derived P. carinii, one anti-human P. carinii MAb, and two polyclonal antisera made with rat-derived P. carinii as the immunogen. Differences in reactivities between the P. carinii f. sp. carinii and P. carinii f. sp. ratti preparations were detected with two of the MAbs, and both of the rat P. carinii polyclonal antisera in the 45- to 55-kDa molecular mass range, but not with the human P. carinii MAb. The reactivities of the 16 P. carinii f. sp. carinii preparations were the same with two exceptions. Two preparations of form 1 showed strong reactivity with the anti-MSG MAb RA-C11. The ratios of cyst forms to trophic forms evaluated by microscopy were not associated with any of the differences observed in the antigenic profiles. The antigenic differences between P. carinii f. sp. carinii and P. carinii f. sp. ratti are consistent with the distinction of these two populations made by molecular genetic techniques, while the two differences detected among the P. carinii f. sp. carinii preparations suggest the organism may be able to modulate antigenic epitopes. The use of immunoblotting to differentiate infecting organism populations and assess antigenic modulation holds promise for future epidemiologic studies.

Adoptive transfer of lymphocytes sensitized to the major surface glycoprotein of Pneumocystis carinii confers protection in the rat

Pneumocystis carinii is a major opportunistic pathogen and a leading cause of morbidity in patients with AIDS. CD4+ cells have been shown to be important in host defenses against P. carinii, but the antigen(s) involved with this response have not been identified. We undertook the present study to determine whether the major surface glycoprotein (MSG) of P. carinii contains epitopes that can elicit a protective cellular immune response. Spleen cells and purified CD4+ cells isolated from Lewis rats, pulsed 1-4 d with MSG, and injected into corticosteroid-treated Lewis rats with pneumocystosis resulted in significant reduction in the P. carinii burden, as judged by organism quantitation and lung histology. The protective response demonstrated by the donor cells was dependent on previous exposure to P. carinii, cell concentration, and time of incubation with MSG. In addition, reconstitution with MSG-specific CD4+ cells resulted in an early hyperinflammatory response within the lungs of these animals with a high percentage of mortality. Thus, in this model, MSG can elicit an immune response mediated by CD4+ cells, which has a harmful as well as helpful effect on the host, and these responses occur despite the presence of corticosteroids.