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Journal of Clinical Microbiology, July 2006, p. 2333-2337, Vol. 44, No. 7
0095-1137/06/$08.00+0     doi:10.1128/JCM.00330-06
Copyright © 2006, American Society for Microbiology. All Rights Reserved.

Mutations Prevalent among Rifampin- and Isoniazid-Resistant Mycobacterium tuberculosis Isolates from a Hospital in Vietnam

M. Caws,^1* Phan Minh Duy,¹ Dau Quang Tho,¹ Nguyen Thi Ngoc Lan,² Dai Viet Hoa,² and Jeremy Farrar¹

Oxford University Clinical Research Unit, Hospital for Tropical Diseases, 190 Ben Ham Tu, Quan 5, Ho Chi Minh City, Vietnam,¹ Pham Ngoc Thach Hospital for Tuberculosis and Lung Diseases, Huong Vuong, District 5, Ho Chi Minh City, Vietnam²

Received 15 February 2006/ Returned for modification 5 April 2006/ Accepted 23 April 2006

Top Abstract Introduction Materials and Methods Results Discussion References

 
Vietnam is ranked 13th among the WHO list of 22 high-burden countries, based upon estimated total number of tuberculosis cases. Despite having a model national tuberculosis program, consistently achieving and exceeding WHO targets for detection and cure, drug-resistant and multidrug-resistant tuberculosis cases continue to rise. Rapid multidrug-resistant tests applicable in this setting, coupled with effective treatment regimens, would be a useful tool in reversing this trend, allowing early identification of patients with multidrug-resistant tuberculosis and avoiding resistance-amplifying regimens. Sequencing of consecutive isolates identified by the National Tuberculosis Program showed 89% of isoniazid-resistant isolates could be detected by targeting just 2 codons, katG 315 and –15CT in the inhA promoter, while rifampin resistance will be more complex to detect, with many different mutation and insertion events in rpoB. The most prevalent rifampin resistance-conferring mutations, as in other countries, were in rpoB codons 531 (43%), 526 (31%), and 516 (15%). However, a hybridization-based resistance test with probes targeting the 5 most common mutations would only detect 78% of rifampin-resistant isolates. Overall, these data suggest that rifampin resistance may be used as a surrogate marker for multidrug-resistant tuberculosis and that a sensitivity of between 70 to 80% may be possible for rapid molecular detection of multidrug-resistant tuberculosis in this setting.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Few data are available on resistance among Mycobacterium tuberculosis isolates in Vietnam. The latest figures from the WHO are derived from the 1997 report on global drug resistance, which estimates resistance to any drug from a 1996 survey at 32.5% and multidrug-resistant (MDR) tuberculosis (TB) at 2.3% (35). The second national drug resistance survey was carried out between 2001 and 2002, but there were problems with data collection. The third survey is under way.

There are indications that the incidence of MDR TB has risen significantly since the first survey and, in the face of a rapidly increasing human immunodeficiency virus prevalence in Vietnam, is likely to continue to increase in the coming years. The International Organization for Migration (IOM) reported from a study of potential immigrants to Canada between 1989 and 2000 that the estimated MDR TB rate was approximately 4.5% (32), and data from our own studies show the rate of MDR TB in 2002 to 2004 to be approximately 6% (unpublished data).

The National Tuberculosis Program (NTP), while apparently achieving high rates of detection and cure (12), is not able to offer sensitivity testing on all isolates. Patients currently receive a standard regimen upon diagnosis of 2 months of streptomycin (S), isoniazid (H), rifampin (R), and pyrazinamide (Z), followed by 6 months of isoniazid and ethambutol (E) (2SHRZ/6HE). Following microbiological failure or relapse, there is a retreatment regimen of 2 months of streptomycin, isoniazid, rifampin, pyrazinamide, and ethambutol, followed by 1 month of isoniazid, rifampin, pyrazinamide, and ethambutol, and finally, 5 months of isoniazid, rifampin, and ethambutol (2SHRZE/1HRZE/5H₃R₃E₃). A 2003 study showed that 47% of patients who failed treatment within the NTP had primary MDR TB (24), and in a separate study, only 33% of MDR TB patients were sputum smear negative upon completion of 8 months of retreatment (17).

Effective control and treatment of MDR TB will require earlier diagnosis and a change in treatment patterns to avoid potential resistance-amplifying regimens (7).

Studies have shown that the mutations responsible for drug resistance in M. tuberculosis vary geographically (22). It is not clear if this is secondary to prescribing practices, M. tuberculosis strain subtypes, or other factors.

The development of a sensitive, rapid, and economical genotypic test for MDR TB will require knowledge of the prevalent mutations among MDR TB isolates in Vietnam. This study aimed to characterize the mutations conferring resistance in 100 consecutive rifampin (RIF)-resistant isolates and 100 consecutive isoniazid (INH)-resistant isolates identified at Pham Ngoc Thach Hospital, the WHO coordinating center for the NTP in southern Vietnam.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Pham Ngoc Thach Hospital is a 500-bed hospital for tuberculosis and lung disease serving Ho Chi Minh City and is a tertiary referral hospital for southern Vietnam. The microbiology laboratory is a WHO international reference laboratory. Between January and March 2005, consecutive M. tuberculosis isolates identified at Pham Ngoc Thach Hospital and shown to be resistant to either RIF or INH had their relevant genes sequenced at the Hospital for Tropical Diseases, Ho Chi Minh City. Isolates are tested in the NTP following failure of directly observed therapy-short course (DOTS) or at the request of the treating physician.

Susceptibility testing was routinely performed by the standard 1% proportion method on Lowenstein-Jensen media for INH (0.2 µg/ml), RIF (40 µg/ml), streptomycin (4 µg/ml), and ethambutol (2 µg/ml). All isolates were identified as M. tuberculosis by standard phenotypic identification tests. Data on the residential district were collected to ensure that isolates were not part of a single outbreak or from one residential district of the city (data not shown).

PCR and DNA sequencing. For isolates resistant to rifampin, the rpoB rifampin resistance-determining region (RRDR, codons 409 to 493) was sequenced. If no mutations were found, further sequencing was done at the rpoB N-terminal (codons 111 to 200) and cluster 3 (codons 575 to 656) regions. For isoniazid-resistant isolates, a 381-bp (codons 266 to 392) region of katG was sequenced. If no mutations were seen in katG, two further regions involved in INH resistance were sequenced: the oxyR-ahpC intergenic region (codons oxyR 56 to ahpC 97) and inhA promoter region (codons –93 to 27). Primers (Proligo, Singapore) are given in Table 1.

View this table: [in this window] [in a new window]

TABLE 1. Primers for sequencing of rifampin and isoniazid resistance-determining regions

PCRs for rpoB N-terminal, cluster III, oxyR-ahpC intergenic, and inhA promoter regions were performed with 0.75 U of Bioline Taq (Bioline, United Kingdom) polymerase, RRDR PCR used 0.75 U of Amersham Taq polymerase (Amersham, United Kingdom), and katG whole-gene PCR used 1.3 U of the Expand high-fidelity polymerase system (Roche, United Kingdom). Amplifications were carried out in an Eppendorf Mastercycler as follows: an initial step of 95°C for 3 min, 30 cycles of 95°C for 15 s, appropriate annealing temperature (T_a) for 15 s, 72°C for 15 s, and a final step of 72°C for 2 min. katG whole-gene PCR used 2.5 min at 72°C for extension and a final step of 72°C for 7 min.

PCR products were purified with QIAgen PCR purification kits (QIAGEN, United Kingdom) and then served as templates for cycle sequencing reactions. Both strands of each product were sequenced with CEQ dye terminator cycle sequencing quick start kits (Beckman Coulter, Singapore) in a half-volume reaction using PCR primers, except for katG, which was sequenced with katGP5 and katGP6 (21). The thermal cycling program was 96°C for 20 s, appropriate T_a for 20 s, and 60°C for 4 min for 30 cycles, followed by holding at 4°C. The cycle sequencing products were subjected to ethanol precipitation steps according to the manufacturer's instructions and sequenced on the CEQ8000 system (Beckman Coulter, Singapore).

Top Abstract Introduction Materials and Methods Results Discussion References

 
One hundred thirty-one consecutive isolates resistant to either RIF or INH were collected. Resistance patterns to first-line drugs are shown in Table 2. One hundred four isolates (79%) were RIF resistant; 129 isolates (98%) were INH resistant. Only 2 (1.9%) RIF-resistant isolates were not MDR: one of these was RIF monoresistant and the other was resistant to RIF and streptomycin.

View this table: [in this window] [in a new window]

TABLE 2. Resistance patterns in 131 consecutive isolates resistant to either isoniazid or rifampin identified at Pham Ngoc Thach Hospital for Tuberculosis and Lung Diseases in southern Vietnam

One hundred four RIF-resistant isolates had the rpoB RRDR sequenced. The most prevalent mutations were at codons 531 (43%), 526 (31%), and 516 (15%). In total, mutations were found in 11 different codons, 10 isolates had mutations at multiple codons, and two insertions in codons 514 and 521 were also identified. Mutations identified in rpoB in 104 rifampin-resistant isolates are shown in Table 3.

View this table: [in this window] [in a new window]

TABLE 3. Mutations in the rpoB gene of 104 consecutive rifampin-resistant isolates identified in southern Vietnam

Five isolates showing no RRDR mutations had their N-terminal regions sequenced. One previously reported mutation, V146F, was found in the N-terminal region, and three isolates carried a mutation at codon 561, just outside cluster 2. These five isolates also had the cluster 3 region sequenced, but no further mutations were identified.

The first 100 isolates resistant to INH had katG sequenced. The majority of isolates, 71%, carried the G944C (S315T) mutation, while two isolates carried G944A (S315N) mutations, two carried G944T (S315I) mutations, and one carried a A943G (S315G) mutation. Two isolates carried double mutations: one G944C/C924T (S315T/T308T) and one a dual mutation in codon 315, G944C/C945G (S315T). One isolate appeared to have a deleted katG gene.

Twenty-one isolates with wild-type katG had their inhA and oxyR-ahpC region sequences determined. Ten isolates carried a –15CT mutation in the inhA promoter, 1 isolate had a silent mutation in ahpC (C21A), 11 isolates carried a silent mutation in the oxyR pseudogene (G37A), and 6 isolates carried different mutations in the oxyR-ahpC intergenic region (–81C-T, –51G-A, –48G-A, –74G-A, –72C-T, and –51G-A).

Top Abstract Introduction Materials and Methods Results Discussion References

 
These data indicate that rifampin resistance would be a good surrogate marker for MDR TB in this setting, with 98% of rifampin-resistant isolates also MDR. However, the molecular detection of rifampin resistance in Vietnam will be complex, with many single point mutations scattered in the RRDR, multiple mutations, and insertion events. The general pattern of rpoB mutations reflects those found worldwide, with codons 531 (43%), 526 (31%), and 516 (15%) being the most commonly mutated. Four isolates (4%) had no mutations in any region sequenced for rifampin resistance, as has been previously reported (11, 22). While it is possible that these isolates are due to laboratory error in the assignment of resistance, consistent reports from many laboratories suggest that another mechanism is responsible for resistance in these isolates. Alternatively, these isolates may contain a mixed population of resistant and susceptible organisms (8).

Two rare insertions were identified, 514F, reported elsewhere (10) and 521SGL. The V146F mutation, in the N-terminal (cluster 2) region, has also been reported elsewhere and associated with low-level resistance, though not exclusively so (9).

Seventy-one percent of INH-resistant isolates carried an S315T mutation in katG. This mutation has been associated with high-level (>5 µg/ml) INH resistance (31) but, again, not exclusively so (25, 31), with MICs ranging from 0.38 to 12 µg/ml. A further 7 (7%) isolates had different mutations in codon 315. In total, 78% of INH-resistant isolates carried a mutated KatG codon 315. One of these isolates carried a double mutation in codon 315 and one carried a second mutation at base 924. However, this mutation is synonymous, T308T, and therefore does not contribute to the resistant phenotype. Although S315T is the most common mutation worldwide, the precise functional effect of the mutation remains unclear. The threonine residue may block access to the active site and reduce the INH affinity of the enzyme, or it may alter redox potentials and local hydrogen bonds (2). The catalase peroxidase remains functional but with reduced activity (26, 33).

One isolate appears to have a deleted katG gene, a rare but previously reported event. Loss of katG confers high-level (>256 µg/ml) INH resistance but probably confers a biological cost for the bacteria in the form of a decreased ability to fight oxidative stress (34). Twenty-one isolates carried a wild-type katG gene. Ten of these (50%) had a –15CT mutation in the inhA promoter. This mutation generally confers intermediate-level (0.1 to 0.4 µg/ml) resistance (18). Mutations in this promoter region lead to increased inhA expression, overwhelming the effect of INH at low levels. The INH reactive form, isonicotinic acyl radical, reacts with NAD(H) to form a covalent adduct which blocks the active site of the NADH-dependent enoyl ACP reductase product of inhA (27).

No mutations were found in ahpC which conferred resistance to INH. One isolate carried a C21A synonymous mutation. Ten isolates also carried the G37A polymorphism in oxyR, which is nonfunctional in M. tuberculosis, carrying multiple deletions and mutations (4); therefore, this mutation is unlikely to confer INH resistance.

Six isolates carried mutations in the oxyR-ahpC intergenic region, but the significance of this is unclear. Some mutations in this region, such as C–30T, have been shown to upregulate alkylhydroperoxidase (15), thought to be a compensatory mechanism for loss of catalase peroxidase activity; other mutations, such as –46GA (1), have been found in both resistant and susceptible isolates and are not related to INH resistance but have phylogenetic significance. The functional effect, if any, of the mutations seen here is not yet known.

Recent reports (5) and theoretical models (6) suggest that MDR TB can be controlled and reduced through effective first-line DOTS programs such as the one functioning in Vietnam. The reasons for increasing drug resistance, particularly MDR, despite an effective NTP network remain unclear. However, both DOTS studies were based on lower underlying levels of primary drug resistance, and the use of a primary ethambutol-based continuation phase, as in Vietnam, has been shown to be less effective than rifampin-based regimens and may be a contributing factor (13). High rates of primary INH (20%) and streptomycin (31%) resistance and resistance to other first-line drugs (40% resistant to one or more) may well be a contributing factor, with many patients effectively receiving ethambutol monotherapy in the continuation phase.

A previous report suggests that 9% of smear-positive TB patients detected in the Vietnamese NTP in 2000 were not registered for treatment, suggesting that while detection rates were high, many of these patients did not progress through NTP-controlled DOTS (3). Efforts have been made to address this issue by changes in data management to record all patients at time of diagnosis, whereas prior to 2000, patients were only registered at commencement of therapy (12). Private treatment in Vietnam is associated with significantly lower treatment success rates than the NTP (48.9% versus 85%, P < 0.001) (20), probably due to incorrect prescriptions and poor adherence to therapy for financial and other reasons. It has been estimated that 40% of all antituberculosis drug dispensing in Vietnam occurs outside the NTP and that a quarter of these sales are made without a prescription (19).

It is likely that the prevalence figures on which WHO estimates of NTP performance are based (incidence of smear-positive TB, 85/100,000; prevalence, 96/100,000) (36) are also low. Wide regional variation in NTP performance, particularly in rural areas, may be hindering TB control in Vietnam. A prevalence survey in a rural district of Northwest Vietnam (30) estimated smear-positive prevalence at 90 to 110/100,000, but detection in the NTP is only 39% for females and 12% for males, significantly below the national detection rates. Efforts are being made by the government to improve NTP performance in rural areas.

Screening of applicants for Australian visas in Ho Chi Minh City by the IOM estimates rates of 157/100,000 for new smear-positive TB and 489/100,000 of new bacteriologically confirmed (smear and culture) TB, a rate 2.5 times that estimated by the WHO (23). The true incidence rates are unknown. TB notification rates vary widely across Vietnam, and it is also possible that the incentive system in the NTP leads to an overestimation of the cure rate (12). More accurate tuberculosis incidence and drug resistance prevalence data will be useful in addressing MDR TB in Vietnam.

It is likely that the sensitivity of hybridization tests for RIF resistance will be low in this setting. The commercial INNO-LiPA Rif.TB test (Innogenetics, Belgium) will directly detect only 73% through the resistant probes, though sensitivity may be higher when prediction of resistance through nonhybridization to probes for wild-type sequence is included. Probes directed to the 5 most prevalent mutations would achieve a sensitivity of only 78%. Molecular INH resistance detection may be simpler, though still incomplete, with combined detection of mutated codon 315 and –15CT mutation in the inhA promoter, allowing a sensitivity of up to 89%. Early detection of INH resistance may be particularly important in Vietnam, with high underlying INH resistance (>20%) (16; also unpublished data) in conjunction with the use of an ethambutol-based continuation phase possibly fuelling the development of MDR TB. Ideally, such a test should be cheap, rapid, and applicable in low-technology environments to have an impact in Vietnam.

However, while the molecular detection of neither RIF nor INH resistance is 100% accurate and the importance of phenotypic tests for the exclusion of drug resistance remains, the earlier detection of resistant cases, particularly MDR TB, will be an important tool in controlling MDR TB and achieving the millennium development goals for reductions in TB mortality.

 
The Wellcome Trust of Great Britain funded the study.

We thank the staff of the Hospital for Tropical Diseases and Pham Ngoc Thach Hospital for Tuberculosis and Lung Diseases for assistance with culture and maintenance of isolates.

 
* Corresponding author. Mailing address: Oxford University Clinical Research Unit, Hospital for Tropical Diseases, 190 Ben Ham Tu, Quan 5, Ho Chi Minh City, Vietnam. Phone: 84 8 8384013. Fax: 84 8 8353904. E-mail: mcaws{at}hotmail.com.

Top Abstract Introduction Materials and Methods Results Discussion References

 

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Journal of Clinical Microbiology, July 2006, p. 2333-2337, Vol. 44, No. 7
0095-1137/06/$08.00+0     doi:10.1128/JCM.00330-06
Copyright © 2006, American Society for Microbiology. All Rights Reserved.

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