Pneumocystis jirovecii genotype associated with increased death rate of HIV-infected patients with Pneumonia.
Several investigators have reported an association between failure of prophylaxis when using sulfa drugs and substitutions of 2 aa within the putative sulfa binding site of DHPS at positions 55 (Thr to Ala, mutation Ml) and 57 (Pro to Ser, M2) (1-4). These mutations were observed either as single (Ml or M2) or double (M3) mutation. This association strongly suggested that P. jirovecii DHPS mutations conferred a level of sulfa resistance sufficient to cause failure of anti-PCP prophylaxis. However, the mutations might have also conferred a clinically substantial resistance to sulfa treatment for overt PCP.
To investigate the issue, many studies have analyzed the effect of the mutations on the outcome of PCP. About half of those studies did not detect any association between the mutations and an increased risk of death caused by PCP (5-8) or a decreased response to sulfa drugs (3,9-11). Conversely, other studies detected an association with a poor outcome (12,13): sulfa treatment failure (14,15); more severe symptoms and need of assisted ventilation (13); or a trend for a worse prognosis (16). Thus, the effect of these mutations on PCP outcome is unclear and justifies investigation to improve PCP treatment and prognosis.
The possibility of other parameters influencing PCP outcome has also been explored. P. jirovecii genotype Ne of the internal transcribed spacers (ITSs) of the nuclear rRNA operon has been associated with milder disease (17), failure of PCP prophylaxis (18), and failure of PCP treatment (9). One ITS genotype observed in Australia was associated with reduced severity of PCP (13). Specific P. jirovecii genotypes defined by single-nucleotide polymorphisms in 3 loci were associated with low or high burden during the course of PCP (19). In comparison, some studies did not detect any associations between P. jirovecii genotypes, including Ne genotype, and several clinical parameters, such as severity and survival at 3 months (15,20). These observations suggested that some P. jirovecii genotypes might be more virulent or resistant to drugs, but further studies are needed to provide better understanding of the issue.
We previously examined P. jirovecii DHPS polymorphisms in clinical specimens of 158 immunosuppressed patients from 5 hospitals in the city of Lyon in France (7). We detected an association between DHPS mutation M2 and failure of prophylaxis when pyrimethamine/ sulfadoxine was used but not between DHPS mutations and death caused by PCP. In this study, we further analyzed the proportion of the organisms harboring DHPS mutations (36%) and of death attributed to PCP (20%) among these 158 patients. We investigated in more detail the effect of DHPS mutations on PCP prognoses, taking into account more clinical parameters. Moreover, to test the hypothesis of variable virulence of some P. jirovecii genotypes, we identified those present in the specimens. Because the disease signs and symptoms vary considerably between HIV-infected and HIV-uninfected patients, we limited our analyses to the HIV-infected patients.
Patients, Materials, and Methods
Patients and Specimens
The specimens consisted of 112 bronchoalveolar lavage (BAL) samples obtained from 110 HIV-infected patients with confirmed PCP who were hospitalized in 5 university hospitals in Lyon, France. These 110 patients were a subset of the 158 patients analyzed (7) who were HIV-infected and who had a medical chart complete enough to support the analyses performed in the present study (Tables 1,2). Two of the patients had second cases of PCP separated from their initial infections by 5 and 12 months, respectively; each was treated as an independent observation. BAL specimens were collected during April 1993 and December 1996 and were stored at -20[degrees]C before analysis. The 112 cases represented 47% of the PCP cases that occurred during this period in the 5 hospitals.
Characteristics of Patients
Specific information on demographic and clinical characteristics, treatment regimens, and PCP outcome were obtained from patients' medical charts. Death within 1 month after the date of PCP diagnosis was attributed to PCP when the physician recorded it as the primary cause of death in the medical chart and on the death certificate. Failure of sulfa treatment (SMX/TMP or dapsone) was defined by occurrence of [greater than or equal to]1 of the following events within 5 days after PCP diagnosis: a change of drug treatment because of lack of clinical improvement, worsening of clinical features or gas exchange parameters, addition of corticosteroids, new need of mechanical ventilation, or death attributed to PCP. Start-of-therapy dates were available for 81 patients. Therapy was started during 1 of 3 periods: before the day on which PCP was diagnosed (n = 34,42%); the day on which PCP was diagnosed (n = 37, 46%); or after that day (n = 10,12%). Therapy was started most frequently 1 or 2 days before the day on which BAL was obtained (n = 26, 77% of the 34 patients whose therapy was started before PCP was diagnosed). All chart abstractions were performed without knowledge of P. jirovecii and DHPS genotyping results. Informed consent was obtained from all patients. Study protocols and patient consent forms were approved by the institutional review board.
DHPS and Genotyping
DNA extraction from BAL specimens and DHPS binding site genotyping by using the PCR--single-strand conformation polymorphism (SSCP) technique were done as described (7). Four DHPS SSCP patterns were observed, each corresponding to 1 of the 4 known DHPS alleles (Ml, M2, M3, and wild type). P. jirovecii present in BAL specimens were typed as described by using PCR-SSCP of 4 variable genomic regions (21). The variable regions analyzed were ITS 1 of the nuclear rDN A operon, the intron of the nuclear 26S rRNA gene, the variable region of the mitochondrial 26S rRNA gene, and the region surrounding the intron no. 6 of the P-tubulin gene. In the PCR-SSCP technique, each allele is identified by a specific SSCP pattern made of 2 DNA bands, each corresponding to 1 of the 2 single strands of the allele.
Because of small sample sizes, we used Fisher exact tests for general association to compare proportions relative to the numbers presented in Tables 1 and 2. We estimated the 2-month survival curves after PCP by using the Kaplan-Meier method and compared those curves by using log-rank tests. Cox proportional hazards method was used to identify independent prognostic factors associated with survival. The risk factors were selected a priori based on theoretical considerations; because no deaths occurred among women, we did not include gender in the variables. Also, the variable CD4 cell count was not included because it had 1) numerous missing values (n = 11, including 3 deaths attributed to PCP), and 2) no significant association with death attributed to PCP in bivariate analysis (p = 0.09). We used logistic regression analysis to identify factors associated with sulfa treatment failure; odds ratios with 95% CIs are reported. We tested the proportionality assumption using the nonzero slope test based on the scaled Schoenfeld residuals, and checked the colinearity (mean variance inflation factor = 1.16). All statistical analyses were conducted by using STATA version 11.1 (StataCorp LP, College Station, TX, USA).
Specimens and Patients
One hundred twelve BAL specimens collected from 110 HIV-infected patients in whom PCP was diagnosed were included in the study. Two of the patients had second cases of PCP. Two patients also had tuberculosis, and 1 had histoplasmosis; each of the 3 recovered from PCP. The cohort ranged in age from 4-69 years (median 37 years); 94 (85%) were men. The most common risk factor for HIV was homosexuality (41%); the next most common risk factor was intravenous drug use (8%). CD4 counts at the diagnosis of PCP were documented in the medical charts of 101 patients and ranged from 0 to 390/uL (median 24). In 2 cases, patients had CD4 cell counts >200 cells/uL (242 and 390).
Detection of DHPS Alleles by using PCR-SSCP
We previously genotyped the P. jirovecii DHPS binding site from the 112 BAL specimens by PCR amplification of a region of 318 bp, then SSCP (7). To simplify the analyses, specimens that contained a mixture of wild type and mutant DHPS genotypes (n = 11) were classified in the corresponding mutant category. For most of the cases, the patients harbored P. jirovecii with wild type DHPS (n = 75, 67.0%). Seventeen (15.2%) episodes involved a M2 mutant DHPS genotype, and 20 (17.8%) involved a M3 allele. The overall proportion of cases in which the patient had mutant DHPS was 33.0% (n = 37). There was a variation of this proportion from 25% to 57% among the 5 hospitals, but the difference did not reach statistical significance (7). No significant differences (p = 0.05) were found between patients who harbored P. jirovecii with DHPS mutations and those who did not for all the demographic or clinical characteristics analyzed.
Genotyping by Using PCR-SSCP
Twenty-seven P. jirovecii genotypes were identified among the 112 BAL specimens by using the multitarget PCR-SSCP typing method (21). Fifty-nine (52.7%) specimens contained a single P. jirovecii type, 47 (42.0%) specimens contained 2 types, and 6 (5.3%) specimens contained more than 2 types that could not be identified. The 5 most prevalent genotypes were type 1 (n = 29 occurrences), type 7 (n = 15), type 10 (n = 12), type 2 (n = 10), and type 6 (n = 10). The 2 patients who had 2 cases each of PCP were infected with different types for each case, suggesting possible de novo infection for each case, rather than reactivation of the type that caused the first case.
Associations between DHPS and P. jirovecii SSCP Genotypes and between Each Genotype and Clinical Factors
Possible associations between DHPS and P. jirovecii SSCP genotypes and between each DHPS and P. jirovecii SSCP genotype and the clinical factors were investigated for the 112 PCP cases (Tables 1,2). Specimens co-infected with [greater than or equal to]2 P. jirovecii SSCP types were gathered into a specific category, and the 3 most prevalent types among specimens containing a single genotype were considered separately. The sample was stratified into 5 groups: type 1, type 7, type 10, other types, and co-infected specimens. The DHPS mutations were not distributed evenly among the P. jirovecii SSCP type (p<0.001, by Fisher exact test) (Table 1), type 7 being associated with genotype M3 (66.7% of the types 7). The DHPS mutations were also unevenly distributed among the CD4 cell count groups (p = 0.05); mutation M2 was associated with <50 cells/[micro]L (100%). Finally, the first-line treatment varied significantly according to the P. jirovecii SSCP type (p = 0.001) (Table 2), type 7 being most often treated with pentamidine or atovaquone rather than SMX/TMP (66.7%).
Predictors of Death Attributed to PCP
Of the 112 observed cases in this study, 21 (18.8%) patients died within 1 month. PCP was identified as the cause of death for 18 patients. Because of the small number of observations, the categories P. jirovecii type 10 and others types were further grouped with co-infected specimens, forming 3 groups: type 1, type 7, and other types. Bivariate analyses revealed that P. jirovecii SSCP type 7 and the need for mechanical ventilation at PCP diagnosis were possible predictors of death attributed to PCP (log-rank test, p = 0.08 and pO.0001, respectively) (Figure). No effect of the DHPS mutated alleles on the PCP mortality rate was observed within 1 month (p = 0.35). Because type 7 was associated with DHPS mutation M3 and with first-line treatment with pentamidine or atovaquone, we included these variables in a multivariable analysis (Table 3). This analysis showed that type 7 and the need for mechanical ventilation at PCP diagnosis were significantly associated with an increased risk of death caused by PCP (relative hazard = 4.2,95% CI 1.0-17.9, p = 0.05, and relative hazard = 5.0,95% CI 1.8-13.5, p = 0.002, respectively) (Table 3). Similar results were obtained when the DHPS genotype variable was removed from the model.
Predictors of Sulfa Drug Treatment Failure
To treat most cases, the patients received a sulfa drug as first-line treatment: for 88 (78.6%) cases, patients were treated with SMX/TMP, and for 2 (1.8%) cases, patients were treated with dapsone. Adverse effects of SMX/TMP in 5 patients led to a therapy change that excluded them from the analysis. Among the remaining 85 cases, 30 patients (35.3%) did not respond to the sulfa treatment at 5 days. Multivariate analysis of the same variables as for the analysis of predictors of death caused by PCP, except the first-line treatment, showed that an increased risk of failure of sulfa treatment was associated with the need for mechanical ventilation at PCP diagnosis (odds ratio 34.2, 95% CI 3.6-321.3, p = 0.002).
Analysis of the parameters of 112 PCP cases in HIV-infected patients involving a high proportion of P. jirovecii DHPS mutations and deaths attributed to PCP did not show an association between these mutations and a worse PCP outcome. This observation contrasts with studies that reported some negative influence of these mutations on PCP prognosis (12-15) but converges with results of other studies reporting no effect (3,5-11). The lack of standardization of the outcome parameters analyzed in the different studies, the confounders used for adjustment, and the small number of cases in some investigations might explain these conflicting conclusions. Nevertheless, a strong effect would have been identified even in studies with restricted sample sizes, suggesting that if these mutations have any effect on PCP outcome, it is small. Studies in the model organisms Saccharomyces cerevisiae (22) and Escherichia coli (23) strongly suggested that DHPS mutations confer some level of sulfa resistance to P. jirovecii. However, these reports did not speculate whether this level is sufficient to provoke clinical failure of sulfa treatment.
P. jirovecii type 7 was independently associated (i.e., nonnull partial correlation) with an increased risk for death caused by PCP. However, this type was also associated with DHPS mutation M3 (66.7% of the single infections), suggesting that the combination of the 2 parameters might have been necessary for its pathogenicity, even if mutation M3 alone was not a predictor of death caused by PCP. Consequently, we cannot exclude the role of mutation M3 for the increased virulence of P. jirovecii type 7. Type 7 was also associated with first-line treatment with pentamidine or atovaquone rather than SMX/TMP, suggesting that use of these less effective drugs might have contributed to an increased number of deaths of patients infected with type 7. However, the proportion of deaths attributed to PCP among these patients was higher with SMX/TMP than with pentamidine or atovaquone (2 of 3 vs. 2 of 6 patients, respectively). P. jirovecii PCR-SSCP type 7 has not been reported to have a higher virulence than the other types. P. jirovecii ITSs type B2al, as well as other genotypes, were suggested to have higher and modified virulence (9,13,17--19).
We observed that the need for mechanical ventilation at PCP diagnosis was associated with an increased risk for death caused by PCP, as was failure of sulfa treatment. An association of this comorbidity factor with an increased risk for death has already been reported (24,25). Several other clinical parameters were reported to be predictors for death caused by PCP in HIV-infected patients (26), and a scoring tool was recently proposed (27). Host polymorphisms within receptors involved in the immune response have also been reported to be related to P. jirovecii infection (28,29). This study confirms that certain P. jirovecii genotypes might have different pathogenic traits. Further studies of PCR-SSCP type 7 could help understanding of P. jirovecii virulence and drug resistance by clinicians and public health professionals.
1. You are seeing a 30-year-old man with HIV Infection and a new diagnosis of Pneumocystis jirovecii pneumonia (PCP). You are concerned regarding the possibility of genetic mutations In this organism. What was the overall rate of dihydropteroate synthase (DHPS) mutations among cases of PCP In the current study?
2. DHPS mutations were most associated with which of the following patient characteristics In the current study?
A. CD4 count less than 50 cells/[micro]L
B. Age over 40 years
C. Male sex
D. Diagnosis of PCP after 1995
3. You Initiate treatment with trimethoprim-sulfamethoxazole. Which of the following variables was most associated with sulfa resistance of P. jirovecii In the current study?
A. Need for mechanical ventilation at the time of PCP diagnosis
B. type 10
C. type 7
D. DHPS M2 mutation
4. Which of the following variables was most associated with a higher risk of death due to PCP In the current study?
A. DHPS M2 mutation
B. DHPS M3 mutation
C. P. jirovecii type 7
D. Older age
Activity Evaluation 1. The activity supported the learning objectives. Strongly Disagree Strongly Agree 1 2 3 4 5 2. The material was organized clearly for learning to occur. Strongly Disagree Strongly Agree 1 2 3 4 5 3. The content learned from this activity will impact my practice. Strongly Disagree Strongly Agree 1 2 3 4 5 4. The activity was presented objectively and free of commercial bias. Strongly Disagree Strongly Agree 1 2 3 4 5
Release date: December 14, 2012;
Expiration date: December 14, 2013
Upon completion of this activity, participants will be able to:
* Distinguish the rate of dihydropteroate synthase (DHPS) mutations among patients with Pneumocystis jirovecii pneumonia (PCP) in the current study
* Analyze patient characteristics associated with a higher rate of DHPS mutations
* Assess variables associated with sulfa resistance among cases of PCP in the current study
*Evaluate the effects of DHPS mutations on the risk of death among cases of PCP in the current study.
Jean Michaels Jones, Technical Writer/Editor, Emerging I nfectious Diseases. Disclosure: Jean Michaels Jones has disclosed no relevant financial relationships.
Charles P. Vega, MD, Health Sciences Clinical Professor; Residency Director, Department of Family Medicine, University of California, Irvine. Disclosure: Charles P. Vega, MD, has disclosed no relevant financial relationships.
Disclosures: Meja Rabodonirina, MD, PhD; Laetitia Vaillant, MD; Patrick Taffe, PhD; Aimable Nahimana, PhD; Rene-Pierre Gillibert, PhD; and Philippe Hauser, PhD, have disclosed no relevant financial relationships. Philippe Vanhems, MD, PhD, has disclosed the following relevant financial relationships: received grants for clinical research from Sanofi Pasteur.
We thank J.L. Touraine, D. Peyramond, and C. Trepo and the physicians responsible for the involved wards in Lyon for access to patients' charts.
Funding for this study was provided by the Swiss National Science Foundation grant 310030-124998; Centre de Coordination de la Lutte contre les Infections Nosocomiales Sud-Est et Hospices Civils de Lyon; Swiss Federal Office for Education and Science for participation in EUROCARINII project, Framework V Program, European Commission (contract QLK2-CT-2000-01369); and the North-South fellowship from the University of Lausanne (supporting A.N.)
Dr Rabodonirina is a parasitologist and a mycologist at the Hospices Civils de Lyon, as well as a lecturer at Lyon University. Her research interests include diagnosis, epidemiology, and drug resistance of opportunistic infections.
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Address for correspondence: Philippe M. Hauser, Institute of Microbiology, Rue du Bugnon 48, Centre Hospitalier Universitaire Vaudois and University of Lausanne, 1011 Lausanne, Switzerland; email: firstname.lastname@example.org
Meja Rabodonirina, Laetitia Vaillant, Patrick Taffe, Aimable Nahimana, Rene-Pierre Gillibert, Philippe Vanhems, and Philippe M. Hauser
Author affiliations: Hospices Civils de Lyon, Lyon, France (M. Rabodonirina); Service d'Hygiene, Epidemiologie et Prevention, Hopital Edouard Herriot, Lyon (L. Vaillant, R.-P. Gillibert, P. Vanhems); Institut de Veille Sanitaire, Paris, France (L. Vaillant); Centre Hospitalier Universitaire Vaudois and University of Lausanne, Lausanne, Switzerland (P. Taffe, A. Nahimana, P.M. Hauser); and Claude Bernard Lyon 1 University, Lyon (P. Vanhems)
DOI: http://dx.org/ 10.3201/eid1901.120140
Table 1. Pneumocystis jiroveci dihydropteroate synthase genotype distribution according to clinical parameters of 112 cases of pneumonia in 110 HIV-positive patients from 5 university hospitals in Lyon, France * DHPS genotype Characteristic Wild type, n = 75 M2, n = 17 Age at PCP diagnosis, y 1-40 41 10 41-60 31 7 61-80 3 0 Sex M 62 14 F 13 3 Diagnosis year 1993 6 2 1994 24 3 1995 20 5 1996 25 7 CD4cell count, median cells/[micro]l ([dagger]) 0-50 42 15 51-100 17 0 >100 10 0 First-line treatment SMX/TMP 59 14 Pentamidine or atovaquone 14 3 Others 2 0 SMX/TMP allergy Yes 4 0 No 71 17 Corticotherapy at PCP diagnosis Yes 18 1 No 57 16 Mechanical ventilation at PCP diagnosis Yes 11 0 No 64 17 P. jirovecii SSCP type 1 3 6 7 3 0 10 2 1 Others 30 3 Co-infected 37 7 Outcome within 1 month Favorable 61 16 Death attributed to PCP 12 1 Death not attributed to PCP 2 0 DHPS genotype Characteristic M3, n = 20 p value Age at PCP diagnosis, y 1-40 14 0.62 41-60 5 61-80 1 Sex M 19 0.38 F 1 Diagnosis year 1993 0 0.58 1994 4 1995 6 1996 10 CD4cell count, median cells/[micro]l ([dagger]) 0-50 11 0.05 51-100 4 >100 2 First-line treatment SMX/TMP 15 0.90 Pentamidine or atovaquone 5 Others 0 SMX/TMP allergy Yes 3 0.27 No 17 Corticotherapy at PCP diagnosis Yes 3 0.25 No 17 Mechanical ventilation at PCP diagnosis Yes 3 0.26 No 17 P. jirovecii SSCP type 1 1 <0.001 7 6 10 1 Others 3 Co-infected 9 Outcome within 1 month Favorable 14 0.39 Death attributed to PCP 5 Death not attributed to PCP 1 * Data derived from Fisher's exact test. DHPS, dihydropteroate synthase; M, mutation; SSCP, single-strand conformation polymorphism; PCP, P. jirovecii pneumonia; SMX/TMP, sulfamethoxazole and trimethoprim. ([dagger]) Data missing for 11 patients. Table 2. Pneumocystis jiroveci SSCP genotype distribution according to clinical parameters of 112 cases of pneumonia in 110 HIV-positive patients from 5 university hospitals in Lyon, France * P. jirovecii SSCP type Characteristic 1, n = 10 7, n = 9 Age at PCP diagnosis, y 1-40 8 5 41-60 2 4 61-80 0 0 Sex M 3 1 F 7 8 Diagnosis year 1993 1 0 1994 3 2 1995 2 2 1996 4 5 CD4 cell count, median cells/[micro]L ([dagger]) 0-50 7 5 51-100 0 2 >100 1 1 First-line treatment SMX/TMP 7 3 Pentamidine or atovaquone 2 6 Others 1 0 SMX/TMP allergy Yes 0 2 No 10 7 Corticotherapy at PCP diagnosis Yes 0 4 No 10 5 Mechanical ventilation at PCP diagnosis Yes 0 2 No 10 7 Outcome within 1 month Favorable 9 5 Death attributed to PCP 1 4 Death not attributed to PCP 0 0 P. jirovecii SSCP type Characteristic 10, n = 4 Others, n = 36 Age at PCP diagnosis, y 1-40 2 22 41-60 2 13 61-80 0 1 Sex M 1 6 F 3 30 Diagnosis year 1993 0 2 1994 2 8 1995 1 9 1996 1 17 CD4 cell count, median cells/[micro]L ([dagger]) 0-50 3 23 51-100 1 6 >100 0 5 First-line treatment SMX/TMP 3 26 Pentamidine or atovaquone 1 9 Others 0 1 SMX/TMP allergy Yes 0 3 No 4 33 Corticotherapy at PCP diagnosis Yes 0 7 No 4 29 Mechanical ventilation at PCP diagnosis Yes 0 2 No 4 34 Outcome within 1 month Favorable 4 28 Death attributed to PCP 0 6 Death not attributed to PCP 0 2 P. jiroveccii SSCP type Characteristic Co-infected, n = 53 p value Age at PCP diagnosis, y 1-40 28 0.89 41-60 22 61-80 3 Sex M 6 0.44 F 47 Diagnosis year 1993 5 0.90 1994 16 1995 17 1996 15 CD4 cell count, median cells/[micro]L ([dagger]) 0-50 30 0.87 51-100 12 >100 5 First-line treatment SMX/TMP 49 0.001 Pentamidine or atovaquone 4 Others 0 SMX/TMP allergy Yes 2 0.27 No 51 Corticotherapy at PCP diagnosis Yes 11 0.17 No 42 Mechanical ventilation at PCP diagnosis Yes 10 0.19 No 43 Outcome within 1 month Favorable 45 0.44 Death attributed to PCP 7 Death not attributed to PCP 1 * Data derived from Fisher's exact test. SSCP, single-strand conformation polymorphism; PCP, P. jirovecii pneumonia; SMX/TMP, sulfamethoxazole and trimethoprim. ([dagger]) Data missing for 11 patients. Table 3. Multivariate analysis of risk factors for death attributed to PCP among 112 cases in 110 patients from 5 university hospitals, Lyon, France Death attributed to PCP Risk factor Yes No P. jirovecii PCR-SSCP type 7 4 5 Others 14 89 Mechanical ventilation at PCP diagnosis Yes 8 6 No 10 88 DHPS genotype M3 5 15 M2 1 16 Wild type 12 63 Mean age at PCP diagnosis, y 38.5 40.6 First-line treatment Others 3 19 Sulfonamides 15 75 Adjusted RH Risk factor (95% Cl) ([dagger]) p value P. jirovecii PCR-SSCP type 7 4.2(1.0-17.9) 0.05 Others 1.0 (Reference) Mechanical ventilation at PCP diagnosis Yes 5.0(1.8-13.5) 0.002 No 1.0 (Reference) DHPS genotype M3 1.1 (0.4-3.4) 0.82 M2 0.6(0.08-5.1) 0.66 Wild type 1.0 (Reference) Mean age at PCP diagnosis, y 1.0 0.95 First-line treatment Others 0.4 (0.1-2.0) 0.29 Sulfonamides 1.0 (Reference) * PCP, Pneumocystis jirovecii pneumonia; RH, relative hazard; SSCP, single-strand conformation polymorphism; DHPS, dihydropteroate synthase; M, mutation. ([dagger]) RH for death attributed to PCP after adjustment for the 5 variables presented in the table. The global p value of the test for proportionality was 0.55, and no individual test was statistically significant at the 0.05 level.
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|Title Annotation:||RESEARCH; human immunodeficiency virus|
|Author:||Rabodonirina, Meja; Vaillant, Laetitia; Taffe, Patrick; Nahimana, Aimable; Gillibert, Rene-Pierre; V|
|Publication:||Emerging Infectious Diseases|
|Date:||Jan 1, 2013|
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