Novel mutations and hot-spots in patients with purine nucleoside phosphorylase deficiency

Purine nucleoside phosphorylase (PNP) deficiency results in severe immune dysfunction and early death from infections. Lymphopenia, reduced serum uric acid, and abnormal PNP enzymatic activity assist in the diagnosis of PNP-deficient patients. Analysis of the gene encoding PNP in these patients reveals several recurring mutations. Identification of these hot-spots for mutation may allow faster confirmation of the diagnosis in suspected cases.     

Intracellular delivery of purine nucleoside phosphorylase (PNP) fused to protein transduction domain corrects PNP deficiency in vitro

Purine nucleoside phosphorylase (PNP) is an intracellular enzyme crucial for purine degradation. PNP defects result in metabolic abnormalities and fatal T cell immunodeficiency. Protein transduction domains (PTD) transfer molecules across biological membranes. We hypothesized that fusion of PTD to PNP (PTD-PNP) would be an effective method for treating PNP deficiency. We find that PTD-PNP rapidly enters PNP-deficient lymphocytes and increases intracellular enzyme activity for 96 h. Similar to endogenous PNP, PTD-PNP is predominantly distributed in the cytoplasm. PTD-PNP improve viability and correct abnormal functions of PNP-deficient T lymphocytes including their response to stimulation and IL-2 secretion. Intracellular transduction protects PTD-PNP from antibody neutralization and from elimination, which may also provide significant in vivo therapeutic advantages to PNP. In conclusion, PTD fusion is an attractive method for extended PNP intracellular enzyme replacement therapy for PNP-deficient patients as well as for the intracellular delivery of other proteins.     

Unique substrate specificity of purine nucleoside phosphorylases from Thermus thermophilus

The degradation of purine nucleoside is the first step of purine nucleoside uptake. This degradation is catalyzed by purine nucleoside phosphorylase, which is categorized into two classes: hexameric purine nucleoside phosphorylase (6PNP) and trimeric purine nucleoside phosphorylase (3PNP). Generally, 6PNP and 3PNP degrade adenosine and guanosine, respectively. However, the substrate specificity of 6PNP and 3PNP of Thermus thermophilus (tt6PNP and tt3PNP, respectively) is the reverse of that anticipated based on comparison to other phosphorylases. Specifically, in this paper we reveal by gene disruption that tt6PNP and tt3PNP are discrete enzymes responsible for the degradation of guanosine and adenosine, respectively, in T. thermophilus HB8 cells. Sequence comparison combined with structural information suggested that Asn204 in tt6PNP and Ala196/Asp238 in tt3PNP are key residues for defining their substrate specificity. Replacement of Asn204 in tt6PNP with Asp changed the substrate specificity of tt6PNP to that of a general 6PNP. Similarly, substitution of Ala196 by Glu and Asp238 by Asn changed the substrate specificity of tt3PNP to that of a general 3PNP. Our results indicate that the residues at these positions determine substrate specificity of PNPs in general. Sequence analysis further suggested most 6PNP and 3PNP enzymes in thermophilic species belonging to the Deinococcus-Thermus phylum share the same critical residues as tt6PNP and tt3PNP, respectively.     

Spontaneous Unstable UNC-22 IV Mutations in C. ELEGANS Var. Bergerac

This paper describes a mutator system in the nematode Caenorhabditis elegans var. Bergerac for the gene unc-22. Of nine C. elegans and two C. briggsae strains tested only the Bergerac BO strain yielded mutant animals at a high frequency and the unc-22 IV gene is a preferred mutational target. The forward spontaneous mutation frequency at the unc-22 locus in Bergerac BO is about 1 x 10^-4 , and most of these spontaneous unc-22 mutations revert at frequencies between 2 x 10^-3 and 2 x 10 ^-4. Both the forward mutation frequency and the reversion frequency are sensitive to genetic background. Spontaneous unc-22 mutations derived in a Bergerac background and placed in a primarily Bristol background revert at frequencies of <10^-6. When reintroduced into a Bergerac/Bristol hybrid background the mutations once again become unstable.

The mutator activity could not be localized to a discrete site in the Bergerac genome. Nor did mutator activity require the Bergerac unc-22 gene as a target since the Bristol unc-22 homolog placed in a Bergerac background also showed high mutation frequency. Intragenic mapping of two spontaneous unc-22 alleles, st136 and st137, place both mutations in the central region of the known unc-22 map. However, these mutations probably recombine with one another, suggesting that the unstable mutations can occur in more than one site in unc-22. Examination of the phenotypic effect of these mutations on muscle structure indicates that they are less severe in their effect than a known amber allele. We suggest that this mutator system is polygenic and dispersed over the nematode genome and could represent activity of the transposable element Tc1.

     

Exon skipping in purine nucleoside phosphorylase mRNA processing leading to severe immunodeficiency.

We report a defect in splicing of precursor messenger RNA (pre-mRNA) resulting from a naturally occurring mutation of the gene encoding purine nucleoside phosphorylase (PNP) in a patient with PNP-deficient severe combined immunodeficiency. This defects results from a G to T transversion at the terminal nucleotide of exon 2 within the 5' splice site of intron 2 and causes skipping of exon 2 during processing of PNP pre-mRNA. Translation of the misspliced mRNA results in a reading frameshift at the exon 1-exon 3 junction. The predicted polypeptide encoded by the aberrant mRNA is severely truncated, terminating at 31 amino acids. Only 4 residues at the NH2 terminus of the polypeptide correspond to PNP amino acids. Otherwise the translation product of the misspliced mRNA differs completely from PNP in amino acid sequence and has no PNP activity. The finding of exon skipping in PNP is the first report of a splicing defect resulting in PNP-deficient severe combined immunodeficiency. Analysis of the genomic context of the G-1 to T mutation of the 5' splice site lends support for the exon definition model of pre-mRNA splicing and contributes to the understanding of splice site selection.     

Attenuated Plasmodium yoelii lacking purine nucleoside phosphorylase confer protective immunity

Malaria continues to devastate sub-Saharan Africa owing to the emergence of drug resistance to established antimalarials and to the lack of an efficacious vaccine. Plasmodium species have a unique streamlined purine pathway in which the dual specificity enzyme purine nucleoside phosphorylase (PNP) functions in both purine recycling and purine salvage. To evaluate the importance of PNP in an in vivo model of malaria, we disrupted PyPNP, the gene encoding PNP in the lethal Plasmodium yoelii YM strain. P. yoelii parasites lacking PNP were attenuated and cleared in mice. Although able to form gametocytes, PNP-deficient parasites did not form oocysts in mosquito midguts and were not transmitted from mosquitoes to mice. Mice given PNP-deficient parasites were immune to subsequent challenge to a lethal inoculum of P. yoelii YM and to challenge from P. yoelii 17XNL, another strain. These in vivo studies with PNP-deficient parasites support purine salvage as a target for antimalarials. They also suggest a strategy for the development of attenuated nontransmissible metabolic mutants as blood-stage malaria vaccine strains.     

Mutational consequences of dNTP pool imbalances in E. coli

The accuracy of DNA synthesis depends on the accuracy of the polymerase as well as the quality and concentration(s) of the available 5′-deoxynucleoside-triphosphate DNA precursors (dNTPs). The relationships between dNTPs and error rates have been studied in vitro, but only limited insights exist into these correlations during in vivo replication. We have investigated this issue in the bacterium Escherichia coli by analyzing the mutational properties of dcd and ndk strains. These strains, defective in dCTP deaminase and nucleoside diphosphate kinase, respectively, are characterized by both disturbances of dNTP pools and a mutator phenotype. ndk strains have been studied before, but were included in this study, as controversies exist regarding the source of its mutator phenotype. We show that dcd strains suffer from increased intracellular levels of dCTP (4-fold) and reduced levels of dGTP (2-fold), while displaying, as measured using a set of lacZ reversion markers in a mismatch-repair defective (mutL) background, a strong mutator effect for G·C→T·A and A·T→T·A transversions (27- and 42-fold enhancement, respectively). In contrast, ndk strains possess a lowered dATP level (4-fold) and modestly enhanced dCTP level (2-fold), while its mutator effect is specific for just the A·T→T·A transversions. The two strains also display differential mutability for rifampicin-resistant mutants. Overall, our analysis reveals for both strains a satisfactory correlation between dNTP pool alterations and the replication error rates, and also suggests that a minimal explanation for the ndk mutator does not require assumptions beyond the predicted effect of the dNTP pools.     

Monitoring and Source Tracking of Tetracycline Resistance Genes in Lagoons and Groundwater Adjacent to Swine Production Facilities over a 3-Year Period

To monitor the dissemination of resistance genes into the environment, we determined the occurrence of tetracycline resistance (Tc^r) genes in groundwater underlying two swine confinement operations. Monitoring well networks (16 wells at site A and 6 wells at site C) were established around the lagoons at each facility. Groundwater (n = 124) and lagoon (n = 12) samples were collected from the two sites at six sampling times from 2000 through 2003. Total DNA was extracted, and PCR was used to detect seven Tc^r genes [tet(M), tet(O), tet(Q), tet(W), tet(C), tet(H), and tet(Z)]. The concentration of Tc^r genes was quantified by real-time quantitative PCR. To confirm the Tc^r gene source in groundwater, comparative analysis of tet(W) gene sequences was performed on groundwater and lagoon samples. All seven Tc^r genes were continually detected in groundwater during the 3-year monitoring period at both sites. At site A, elevated detection frequency and concentration of Tc^r genes were observed in the wells located down-gradient of the lagoon. Comparative analysis of tet(W) sequences revealed that the impacted groundwater contained gene sequences almost identical (99.8% identity) to those in the lagoon, but these genes were not found in background libraries. Novel sequence clusters and unique indigenous resistance gene pools were also found in the groundwater. Thus, antibiotic resistance genes in groundwater are affected by swine manure, but they are also part of the indigenous gene pool.     

Relocation of urf a from the mitochondrion to the nucleus cures the mitochondrial mutator phenotype in the fission yeast Schizosaccharomyces pombe

In previous papers we have reported the characterisation of mitochondrial mutator mutants of Schizosaccharomyces pombe. In contrast to nuclear mutator mutants known from other eucaryotes, this mutator phenotype correlates with mutations in an unassigned open reading frame (urf a) in the mitochondrial genome. Since an efficient biolistic transformation system for fission yeast mitochondria is not yet available, we relocated the mitochondrial urf a gene to the nucleus. As host strain for the ectopic expression, we used the nonsense mutant ana ^r -6, which carries a premature stop codon in the urf a gene. The phenotype of this mutant is characterised by continuous segregation of progeny giving rise to fully respiration competent colonies, colonies that show moderate growth on glycerol and a fraction of colonies that are unable to grow on glycerol. The phenotype of this mutant provides an excellent tool with which to study the effects on the mutator phenotype of ectopic expression of the urf a gene. Since a UGA codon encoding tryptophan is present in the original mitochondrial gene, we constructed two types of expression cassettes containing either the mitochondrial version of the urf a gene (mt-urf a) or a standard genetic code version (nc-urf a; UGA replaced by UGG) fused to the N-terminal import leader sequence of the cox4 gene of Saccharomyces cerevisiae. We show that the expression of the mt-urf a gene in its new location is able to cure, at least in part, the phenotype of mutant ana ^r -6, whereas the expression of the nc-urf a gene completely restores the wild-type (non-mutator) phenotype. The significant similarity of the urf a gene to the mitochondrial var1 gene of S. cerevisiae and homologous genes in other yeasts suggests that the urf a gene product might be a ribosomal protein with a dual function in protein synthesis and maintenance of mitochondrial DNA integrity.     

Characterization of para-Nitrophenol-Degrading Bacterial Communities in River Water by Using Functional Markers and Stable Isotope Probing

Microbial degradation is a major determinant of the fate of pollutants in the environment. para-Nitrophenol (PNP) is an EPA-listed priority pollutant with a wide environmental distribution, but little is known about the microorganisms that degrade it in the environment. We studied the diversity of active PNP-degrading bacterial populations in river water using a novel functional marker approach coupled with [¹³C₆]PNP stable isotope probing (SIP). Culturing together with culture-independent terminal restriction fragment length polymorphism analysis of 16S rRNA gene amplicons identified Pseudomonas syringae to be the major driver of PNP degradation in river water microcosms. This was confirmed by SIP-pyrosequencing of amplified 16S rRNA. Similarly, functional gene analysis showed that degradation followed the Gram-negative bacterial pathway and involved pnpA from Pseudomonas spp. However, analysis of maleylacetate reductase (encoded by mar), an enzyme common to late stages of both Gram-negative and Gram-positive bacterial PNP degradation pathways, identified a diverse assemblage of bacteria associated with PNP degradation, suggesting that mar has limited use as a specific marker of PNP biodegradation. Both the pnpA and mar genes were detected in a PNP-degrading isolate, P. syringae AKHD2, which was isolated from river water. Our results suggest that PNP-degrading cultures of Pseudomonas spp. are representative of environmental PNP-degrading populations.     

Computational generation and screening of RNA motifs in large nucleotide sequence pools

Although identification of active motifs in large random sequence pools is central to RNA in vitro selection, no systematic computational equivalent of this process has yet been developed. We develop a computational approach that combines target pool generation, motif scanning and motif screening using secondary structure analysis for applications to 10¹²–10¹⁴-sequence pools; large pool sizes are made possible using program redesign and supercomputing resources. We use the new protocol to search for aptamer and ribozyme motifs in pools up to experimental pool size (10¹⁴ sequences). We show that motif scanning, structure matching and flanking sequence analysis, respectively, reduce the initial sequence pool by 6–8, 1–2 and 1 orders of magnitude, consistent with the rare occurrence of active motifs in random pools. The final yields match the theoretical yields from probability theory for simple motifs and overestimate experimental yields, which constitute lower bounds, for aptamers because screening analyses beyond secondary structure information are not considered systematically. We also show that designed pools using our nucleotide transition probability matrices can produce higher yields for RNA ligase motifs than random pools. Our methods for generating, analyzing and designing large pools can help improve RNA design via simulation of aspects of in vitro selection.     

The roles of RNA polymerase and RNAase I in stable RNA degradation in Escherichia coli carrying the srnB+ gene

In Escherichia coli cells carrying the srnB⁺ gene of the F plasmid, rifampin, added at 42°C, induces the extensive rapid degradation of the usually stable cellular RNA (Ohnishi, Y., (1975) Science 187, 257–258; Ohnishi, Y., Iguma, H., Ono, T., Nagaishi, H. and Clark, A.J. (1977) J. Bacteriol. 132, 784–789). We have studied further the necessity for rifampin and for high temperature in this degradation. Streptolidigin, another inhibitor of RNA polymerase, did not induce the RNA degradation. Moreover, the stable RNA of some strains in which RNA polymerase is temperature-sensitive did not degrade at the restrictive temperature in the absence of rifampin. These data suggest that rifampin has an essential role in the RNA degradation, possibly by the modification of RNA polymerase function. A protein (M_r 12 000) newly synthesized at 42°C in the presence of rifampin appeared to be the product of the srnB⁺ gene that promoted the RNA degradation. In a mutant deficient in RNAase I, the extent of the RNA degradation induced by rifampin was greatly reduced. RNAase activity of cell-free crude extract from the RNA-degraded cells was temperature-dependent. The RNAase was purified as RNAase I in DEAE-cellulose column chromatography and Sephadex G-100 gel filtration. Both in vivo and with purified RNAase I, a shift of the incubation mixture from 42 to 30°C, or the addition of Mg²⁺ ions, stopped the RNA degradation. Thus, an effect on RNA polymerase seems to initiate the expression of the srnB⁺ gene and the activation of RNAase I, which is then responsible for the RNA degradation of E. coli cells carrying the srnB⁺ gene.     

Suppression of the E. coli SOS response by dNTP pool changes

The Escherichia coli SOS system is a well-established model for the cellular response to DNA damage. Control of SOS depends largely on the RecA protein. When RecA is activated by single-stranded DNA in the presence of a nucleotide triphosphate cofactor, it mediates cleavage of the LexA repressor, leading to expression of the 30⁺-member SOS regulon. RecA activation generally requires the introduction of DNA damage. However, certain recA mutants, like recA730, bypass this requirement and display constitutive SOS expression as well as a spontaneous (SOS) mutator effect. Presently, we investigated the possible interaction between SOS and the cellular deoxynucleoside triphosphate (dNTP) pools. We found that dNTP pool changes caused by deficiencies in the ndk or dcd genes, encoding nucleoside diphosphate kinase and dCTP deaminase, respectively, had a strongly suppressive effect on constitutive SOS expression in recA730 strains. The suppression of the recA730 mutator effect was alleviated in a lexA-deficient background. Overall, the findings suggest a model in which the dNTP alterations in the ndk and dcd strains interfere with the activation of RecA, thereby preventing LexA cleavage and SOS induction.     

Genes Involved in Degradation of para-Nitrophenol Are Differentially Arranged in Form of Non-Contiguous Gene Clusters in Burkholderia sp. strain SJ98

Biodegradation of para-Nitrophenol (PNP) proceeds via two distinct pathways, having 1,2,3-benzenetriol (BT) and hydroquinone (HQ) as their respective terminal aromatic intermediates. Genes involved in these pathways have already been studied in different PNP degrading bacteria. Burkholderia sp. strain SJ98 degrades PNP via both the pathways. Earlier, we have sequenced and analyzed a ~41 kb fragment from the genomic library of strain SJ98. This DNA fragment was found to harbor all the lower pathway genes; however, genes responsible for the initial transformation of PNP could not be identified within this fragment. Now, we have sequenced and annotated the whole genome of strain SJ98 and found two ORFs (viz., pnpA and pnpB) showing maximum identity at amino acid level with p-nitrophenol 4-monooxygenase (PnpM) and p-benzoquinone reductase (BqR). Unlike the other PNP gene clusters reported earlier in different bacteria, these two ORFs in SJ98 genome are physically separated from the other genes of PNP degradation pathway. In order to ascertain the identity of ORFs pnpA and pnpB, we have performed in-vitro assays using recombinant proteins heterologously expressed and purified to homogeneity. Purified PnpA was found to be a functional PnpM and transformed PNP into benzoquinone (BQ), while PnpB was found to be a functional BqR which catalyzed the transformation of BQ into hydroquinone (HQ). Noticeably, PnpM from strain SJ98 could also transform a number of PNP analogues. Based on the above observations, we propose that the genes for PNP degradation in strain SJ98 are arranged differentially in form of non-contiguous gene clusters. This is the first report for such arrangement for gene clusters involved in PNP degradation. Therefore, we propose that PNP degradation in strain SJ98 could be an important model system for further studies on differential evolution of PNP degradation functions.     

Immucillin-H,a purine nucleoside phosphorylase transition state analog,causes non-lethal attenuation of growth in Staphylococcus aureus

Purine nucleoside phosphorylase (PNP; EC: 2.4.2.1) is a key enzyme involved in the purine salvage pathway. A recent bioinformatic study by Yadav, P. K. et al. (Bioinformation 2012, 8(14), 664–672) reports PNP as an essential enzyme and potential drug target in community-acquired methicillin-resistant Staphylococcus aureus (CA-MRSA). We conducted an analysis using the methodology outlined by the authors, but were unable to identify PNP as an essential gene product in CA-MRSA. In addition, the treatment of Staphylococcus aureus cultures with immucillin-H, a powerful inhibitor of PNP, resulted in the non-lethal attenuation of growth, suggesting that PNP activity is not essential for cell viability.     

Effects of T4 phage infection and anaerobiosis upon nucleotide pools and mutagenesis in nucleoside diphosphokinase-defective Escherichia coli strains.

Bacteriophage T4 encodes nearly all of its own enzymes for synthesizing DNA and its precursors. An exception is nucleoside diphosphokinase (ndk gene product), which catalyzes the synthesis of ribonucleoside triphosphates and deoxyribonucleoside triphosphates (dNTPs) from the corresponding diphosphates. Surprisingly, an Escherichia coli ndk deletion strain grows normally and supports T4 infection. As shown elsewhere, these ndk mutant cells display both a mutator phenotype and deoxyribonucleotide pool abnormalities. However, after T4 infection, both dNTP pools and spontaneous mutation frequencies are near normal. An E. coli strain carrying deletions in ndk and pyrA and pyrF, the structural genes for both pyruvate kinases, also grows and supports T4 infection. We examined anaerobic E. coli cultures because of reports that in anaerobiosis, pyruvate kinase represents the major route for nucleoside triphosphate synthesis in the absence of nucleoside diphosphokinase. The dNTP pool imbalances and the mutator phenotype are less pronounced in the anaerobic than in the corresponding aerobic ndk mutant strains. Anaerobic dNTP pool data, which have not been reported before, reveal a disproportionate reduction in dGTP, relative to the other pools, when aerobic and anaerobic conditions are compared. The finding that mutagenesis and pool imbalances are mitigated in both anaerobic and T4-infected cultures provides strong, if circumstantial, evidence that the mutator phenotype of ndk mutant cells is a result of the dNTP imbalance. Also, the viability of these cells indicates the existence of a second enzyme system in addition to nucleoside diphosphokinase for nucleoside triphosphate synthesis.     

Plant Desiccation and Protein Synthesis : V. Stability of Poly (A) and Poly (A) RNA during Desiccation and Their Synthesis upon Rehydration in the Desiccation-Tolerant Moss Tortula ruralis and the Intolerant Moss Cratoneuron filicinum

Upon desiccation of gametophytes of the desiccation-tolerant moss Tortula ruralis preexisting pools of poly(A)⁻ RNA (rRNA) remain inact, regardless of the speed at which desiccation is achieved. Preexisting poly(A)⁺ RNA pools (mRNA) are unaffected by slow desiccation but are substantially reduced during rapid desiccation. Poly(A)⁻ RNA involved in protein synthesis is also unaffected by desiccation, whereas the levels of polysomal poly(A)⁺ RNA in rapid- and slow-dried moss closely reflect the state of the protein synthetic complex in these dried samples.

Poly(A)⁻ RNA pools, both total and polysomal, are also stable during the rehydration of both rapid- and slow-dried moss. The total poly(A)⁺ RNA pool decreases upon rehydration, but this reduction is simply an expression of the normal turnover of poly(A)⁺ RNA in this moss. Analysis of polysomal fractions during rehydration reveals the continued use of conserved poly(A)⁺ RNA for protein synthesis. The rate of synthesis of poly(A)⁺ RNA upon rehydration appears to depend upon the speed at which prior desiccation is administered. Rapidly dried moss synthesizes poly(A)⁺ RNA at a faster rate, 60 to 120 minutes after the addition of water, than does rehydrated slowly dried moss. Recruitment of this RNA into the protein synthetic complex also follows this pattern. Comparative studies involving the aquatic moss Cratoneuron filicinum are used to gain an insight into the relevance of these findings with respect to the cellular mechanisms associated with desiccation tolerance.

     

Novel Mutations and Hot‐Spots in Patients with Purine Nucleoside Phosphorylase Deficiency

Purine nucleoside phosphorylase (PNP) deficiency results in severe immune dysfunction and early death from infections. Lymphopenia, reduced serum uric acid, and abnormal PNP enzymatic activity assist in the diagnosis of PNP‐deficient patients. Analysis of the gene encoding PNP in these patients reveals several recurring mutations. Identification of these hot‐spots for mutation may allow faster confirmation of the diagnosis in suspected cases.     

Characterization of RNase R-digested cellular RNA source that consists of lariat and circular RNAs from pre-mRNA splicing

Besides linear RNAs, pre-mRNA splicing generates three forms of RNAs: lariat introns, Y-structure introns from trans-splicing, and circular exons through exon skipping. To study the persistence of excised introns in total cellular RNA, we used three Escherichia coli 3′ to 5′ exoribonucleases. Ribonuclease R (RNase R) thoroughly degrades the abundant linear RNAs and the Y-structure RNA, while preserving the loop portion of a lariat RNA. Ribonuclease II (RNase II) and polynucleotide phosphorylase (PNPase) also preserve the lariat loop, but are less efficient in degrading linear RNAs. RNase R digestion of the total RNA from human skeletal muscle generates an RNA pool consisting of lariat and circular RNAs. RT–PCR across the branch sites confirmed lariat RNAs and circular RNAs in the pool generated by constitutive and alternative splicing of the dystrophin pre-mRNA. Our results indicate that RNase R treatment can be used to construct an intronic cDNA library, in which majority of the intron lariats are represented. The highly specific activity of RNase R implies its ability to screen for rare intragenic trans-splicing in any target gene with a large background of cis-splicing. Further analysis of the intronic RNA pool from a specific tissue or cell will provide insights into the global profile of alternative splicing.