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Journal of Clinical Microbiology, January 2004, p. 242-249, Vol. 42, No. 1
0095-1137/04/$08.00+0     DOI: 10.1128/JCM.42.1.242-249.2004
Copyright © 2004, American Society for Microbiology. All Rights Reserved.

Surveillance Network for Herpes Simplex Virus Resistance to Antiviral Drugs: 3-Year Follow-Up

CHU Lyon, 69373 Lyon Cedex 08,¹ CHU Jean Bernard, 86021 Poitiers,² Laboratoire GlaxoSmithKline, 78163 Marly-le-Roi,³ CHU Nantes, 44035 Nantes,⁴ CH Annecy, 74011 Annecy,⁵ CHU Pellegrin, 33076 Bordeaux,⁶ CHU Brabois, 54500 Vandoeuvre les Nancy,⁷ CHU Clermont-Ferrand, 63001 Clermont-Ferrand,⁸ CHU Morvan, 29609 Brest,⁹ CHU Purpan, 31059 Toulouse,¹⁰ CHU Michallon, 38013 Grenoble,¹¹ CHU Saint Louis, 75475 Paris,¹² HIA Val de GrÂce, 75230 Paris,¹³ CHU Nord, 42055 Saint Etienne,¹⁴ CHU Timone, 13005 Marseille,¹⁵ CHU Saint Eloi, 34059 Montpellier, France,¹⁶

Received 16 May 2003/ Returned for modification 21 July 2003/ Accepted 2 September 2003

	ABSTRACT

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Herpes simplex virus (HSV) infections are very common in the general population and among immunocompromised patients. Acyclovir (ACV) is an effective treatment which is widely used. We deemed it essential to conduct a wide and coordinated survey of the emergence of ACV-resistant HSV strains . We have formed a network of 15 virology laboratories which have isolated and identified, between May 1999 and April 2002, HSV type 1 (HSV-1) and HSV-2 strains among hospitalized subjects. The sensitivity of each isolate to ACV was evaluated by a colorimetric test (C. Danve, F. Morfin, D. Thouvenot, and M. Aymard, J. Virol. Methods 105:207-217, 2002). During this study, 3,900 isolated strains among 3,357 patients were collected; 55% of the patients were immunocompetent. Only six immunocompetent patients excreted ACV-resistant HSV strains (0.32%), including one female patient not treated with ACV who was infected primary by an ACV-resistant strain. Among the 54 immunocompromised patients from whom ACV-resistant HSV strains were isolated (3.5%), the bone marrow transplantation patients showed the highest prevalence of resistance (10.9%), whereas among patients infected by human immunodeficiency virus, the prevalence was 4.2%. In 38% of the cases, the patients who excreted the ACV-resistant strains were treated with foscarnet (PFA), and 61% of them developed resistance to PFA. The collection of a large number of isolates enabled an evaluation of the prevalence of resistance of HSV strains to antiviral drugs to be made. This prevalence has remained stable over the last 10 years, as much among immunocompetent patients as among immunocompromised patients.

	INTRODUCTION

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Herpes simplex virus (HSV) infections are very common; they are localized on the face and torso in the case of HSV type 1 (HSV-1) and in the genital region in the case of HSV-2. HSV-1 infections in the genital region are on the increase (40). Ocular herpes is less frequent, and neonatal herpes and herpetic meningoencephalitis are very rare but have a severe functional and vital prognosis (37).

Since acyclovir (ACV) {9-[(2-hydroxyethoxy)methyl)guanine]} was introduced to the market in 1983, it has been used primarily in the prevention and treatment of HSV infections. ACV-resistant HSV strains have been observed in vivo since the first large therapeutic trials (5, 10, 36). These resistant strains are detected in vitro by phenotypic tests which determine the antiviral concentration inhibiting viral replication by 50%. Several methods have been used to evaluate the sensitivity of the HSV strains to ACV, including techniques to detect the intensity of the cytopathic effect, such as the plaque reduction (17, 31) and colorimetric (11, 22, 26) techniques, but also the detection of DNA replication by hybridization (39) or antigen production by flow cytometry (30).

Previous surveys among immunocompetent patients have shown a prevalence of resistance to ACV varying between 0 and 0.6%, whereas among immunocompromised patients, the prevalence varied between 3 and 6% (9, 16, 29). The use of ACV is constantly growing, particularly in the general population, where it is used mainly in self-medication (since 1996) for the treatment of labial herpes. Among immunocompromised patients, the increase in the use of ACV is linked to the growth in the number and survival of patients among whom it is used for prophylactic or curative treatment. Furthermore, the development of new antiviral molecules derived from ACV (thymidine kinase [TK] dependent), such as valacyclovir, penciclovir, and ganciclovir, increases the risk of selection pressure of resistant strains. We could not get accurate data about the consumption of various antiherpes drugs, hospitalized patients did not receive any over-the-counter drug.

Since the last French survey goes back to the beginning of the 1990s (29), we deemed it essential to conduct a prospective and coordinated multicenter national study of the emergence of ACV-resistant viruses. This would allow us to establish a correlation between in vitro resistance and clinical resistance and to show a possible cross-resistance among different antiviral drugs, by distinguishing a large number of isolated HSV strains among immunocompetent and immunocompromised patients. For this purpose, a surveillance network was maintained from May 1999 to April 2002 at the Laboratory of Virology in Lyon, France, with the participation of 14 other French virology laboratories, two-thirds of which had already participated in the previous surveillance network (29). For this study we developed a fast colorimetric test (11), a standardized form for clinical information concerning the patient, and a database for processing information.

	MATERIALS AND METHODS

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Cells. An African green monkey kidney cell line (Vero; American Type Culture Collection) was cultivated in 199 medium containing a penicillin-streptomycin mix (25,000 U and 25,000 µg, respectively, per ml) supplemented with 7% fetal calf serum and was maintained in Eagle minimum essential medium with the addition of 1% L-glutamine, 1% amino acids (Eagle minimum essential medium nonessential amino acid solution), penicillin-streptomycin mix (25,000 U and 25,000 µg, respectively, per ml), and 2% fetal calf serum. All of these the products were obtained from BioWhittakerEurope, Verviers, Belgium.

Virus. (i) Reference strains. The ACV-sensitive (SC16) and ACV-resistant (SC16-DM21) HSV-1 strains were from the Wellcome Laboratory (Paris, France) (15). The ACV-sensitive HSV-2 strain (G-HSV-2) was supplied by B. Roizman (University of Chicago, Chicago, Ill.). The ACV-resistant (average 50% inhibitory concentration, 100 µM) HSV-2 strain (91-411) was isolated at the Laboratory of Virology in Lyon (France) in 1991 from a patient who had received a bone marrow transplant. The TK gene of this strain shows a frameshift mutation due to the deletion of a thymine (T) at the level of the T homopolymer (nucleotide 482 to 485).

(ii) Clinical isolates. Between May 1999 and April 2002, HSV strains were isolated in 14 virology laboratories from fibroblast embryonic cells from human lung (MRC-5 and Hel cells) and in 1 laboratory from African green monkey kidney cells (BGM cells). The isolates were sent in dry ice to the Lyon Laboratory of Virology, where they were cultivated in Vero cells. The cytopathic effect of the viruses was checked every day, and when more than 70% of the cells were lysed, the cells and the medium were collected, aliquoted, and stored at -80°C.

Clinical record. Each isolate was accompanied by a standardized form of clinical information that included the following.

(i) Identification. The patient and the hospital department were identified.

(ii) Date and location of the sample. The date and the location of the sample were classified according to the following categories: (a) upper region, including eye, skin (face, hand, neck, and back), mouth, upper respiratory tract (URT), and lower respiratory tract (LRT); (b) lower region, including anus, genital apparatus, and skin (buttocks and legs); and (c) systematic follow-up, including samples taken mainly from the URT and bronchoalveolar lavage but also from urine of patients who were regularly monitored and not showing any clinical signs.

(iii) Clinical definition. Primary infection corresponds to the first infecting contact with HSV-1 or HSV-2. Primary manifestation corresponds to the first manifestation symptomatic of a herpetic infection, whether the subject was or was not previously infected by the other viral type. Recurrence corresponds to the clinical expression of a viral reactivation in a patient previously infected by the same viral type.

(iv) Antiviral treatments. Antiviral treatments administered before, during, or after isolation of HSV were noted.

(v) Immune status. Immune status (immunocompetent or immunocompromised) was as reported by the physicians. Immunocompromised patients were grouped into nine categories according to the type of pathology that brought about the immunosuppression: (a) patients with hemopathies, including leukemias, lymphomas, and myelomas; (b) patients with human immunodeficiency virus (HIV) infections; (c) patients who had received bone marrow transplantation (auto or heterologous); (d) patients who had received organ transplantations, (e) patients with cancers, (f) patients who had received corticotherapy, (g) patients with burns, (h) miscellaneous, which groups together patients who had received chemotherapy for a nonspecified cause and patients with immunodeficiency, Hodgkin's disease, Crohn's disease, Sezary's syndrome, Still's disease, Wegener's granuloma and Waldenstrom's macroglobulinemia, pemphigus, pneumopathy, and rectocolitis; and (i) patients with immunosuppression due to an unknown cause. Immune status had to be filled in for the patient to be included in the study.

The clinical record and the viral strain corresponding to the same patient were given the same identification number, and then the clinical information was entered into an ACCESS database (Microsoft Windows).

Typing of HSV strains. Typing of HSV strains was carried out in each of the 15 participating laboratories by indirect immunofluorescence with three monoclonal antibodies (anti-HSV-1, anti-HSV-2, and anti-HSV-1 and -2) (Argène-Biosoft, Varhiles, France), developed with fluorescein-conjugated goat anti-mouse antibodies (Argène-Biosoft).

Colorimetric test for detecting sensitivity to ACV. The colorimetric test for detecting sensitivity to ACV (11) was based on the chessboard technique developed by Langlois et al. (22) but with only two virus dilutions (10^-1 and 10^-2) tested in relation to two antiviral doses (5 and 10 µM). The results were expressed as the percent reduction of viral replication in the presence of the antiviral drug, for each virus dose and each antiviral concentration. For all of the ACV-resistant strains, the 50% inhibitory concentrations of ACV, foscarnet (PFA), ganciclovir (GCV), and penciclovir (PCV) were measured by the chessboard technique (22). The resistance thresholds had been defined by Langlois et al. (22) for ACV (6.5 µM for HSV-1 and 13.5 µM for HSV-2), for PFA (>400 µM for HSV-1 and HSV-2), and for GCV (>5 µM for HSV-1 and HSV-2) and by Edert et al. (14) for PCV (25 µM for HSV-1 and 60 µM for HSV-2).

Information from the study was published in a monthly bulletin.

	RESULTS

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General characteristics of the population studied. Between May 1999 and April 2002, 4,098 isolates, corresponding to 3521 patients, were collected. In 95% of the cases the patients had been hospitalized, and in 5% of cases they were outpatients, patients of doctors in private practice, or patients from state-run clinics.

As some isolate cultures were negative (1.6%) or came from patients whose immune status could not be revealed (2.9%), the study was carried out with 3,923 strains excreted by 3,357 patients. The population studied was 55% immunocompetent patients (n = 1,855) and 45% immunocompromised patients (n = 1,502) (Table 1). The 2,848 strains of HSV-1 and the 1,075 strains of HSV-2 were excreted by 1,781 women and 1,512 men; the genders of 64 patients (2%) were not specified. In total, of the 3,357 patients, 60 excreted ACV-resistant strains.

The patient infected primarily by HSV-1 had been hospitalized for Kaposi Juliusberg syndrome. She was pregnant and had suffered from an atopic condition with eczema since childhood. This woman was probably infected by her young daughter (age unknown), who was undergoing treatment for herpetic stomatitis. This hypothesis could not be confirmed, because no samples were taken from the child.

Immunocompromised patients. The population studied consisted of 1,502 immunocompromised patients, 1,168 having excreted HSV-1 strains and 334 having excreted HSV-2 strains (Table 1). The main causes of immunosuppression were hemopathy (32% of the cases), HIV infections (21% of the cases), organ transplantations (13.5% of the cases), and bone marrow transplantations (13.5% of the cases) (Table 5). Eleven patients had leukemia and received a bone marrow transplant during the study; they have been included in the bone marrow transplantation category. HSV-1 strains were isolated to the upper region in 98% of the cases (958 of 976) and to the lower region in 17% of the cases (58 of 287) (Table 2). Infections of both the upper and lower regions were observed in 2.7% of the cases. There was a primary infection in 3.5% of the cases, a primary manifestation in 15.5% of the cases, and a recurrence in 54% of the cases. More than 55% of patients had not received antiviral treatment when the samples were taken (Table 3).

(i) Patients who received a bone marrow transplant. Of the 201 patients who received bone marrow transplants, 22 excreted ACV-resistant HSV-1 strains (10.9%). This value was 18.4% for allotransplantations (16 of 87) and 1.2% for autotransplantations (1 of 81) (P < 0.001). In all the cases there were herpetic recurrences in the upper region, with 11 of these patients having stomatitis. Nineteen patients had used ACV before, and 2 had used GCV for a cytomegalovirus infection (prophylaxis not specified). Of the 12 ACV-resistant patients treated with PFA, 7 excreted PFA-resistant strains (Table 6).

(iii) Patients with HIV infection. Of the 310 patients with HIV infection, 13 excreted ACV-resistant HSV-2 strains (4.2%). Among these, eight had a CD4 level of less than 200/mm³ (between 18 and 200/mm³), and four had a higher level (up to 800/mm³). These recurrent infections were localized to the anogenital region (Table 6). Treatment with ACV had been administered to 10 of the 11 patients, and among the 5 patients who had been treated with PFA, 2 excreted PFA-resistant strains.

(iv) Patients who received an organ transplant. Of the 201 patients who received an organ transplant, 5 excreted ACV-resistant strains (2.5%). These transplants consisted of two heart transplants, two heart-lung transplants, and one liver transplant. The HSV-1 strains were isolated to the upper region (n = 3) and to the lower region (n = 1), and there were three cases of recurrent infection (Table 6). A type 2 strain was detected in the urine during systematic monitoring of a patient who had already had herpetic infections (Table 6). For the four patients for whom we received information regarding treatment, three had been treated with ACV and one had been treated only with GCV for a cytomegalovirus infection (prophylaxis not specified). PFA treatment had been administered to the patient who excreted a PFA-resistant strain.

(v) Patients in the miscellaneous category. Three of the 119 patients belonging to the miscellaneous category excreted ACV-resistant strains. Two patients with common variable immune deficiency excreted ACV-resistant HSV-2 strains during recurrent genital infections (Table 6); they had previously been treated with ACV. It should be noted that the first patient excreted an ACV-resistant strain (sacrum) and a ACV-sensitive strain (vulva) on the same day at two different sites and that the second patient excreted four ACV-resistant strains, two of which were resistant to PFA under treatment with PFA, and then a strain sensitive to ACV and to PFA. The third patient had pemphigus, for which he was treated with corticotherapy, and he excreted the herpesvirus during a recurrent infection of the upper region. This patient had previously been treated with ACV.

(vi) Other immunocompromised patients who did not excrete ACV-resistant HSV strains. The other immunocompromised patients included in the study did not excrete ACV-resistant strains; 84 of these patients had solid cancer, 58 were treated with corticotherapy for causes such as asthma or lupus or while waiting for a transplantation, and 24 who had serious burns excreted HSV-1 strains. The type of cancer and the cause of the immunosuppression were not specified for 13 and for 29 patients, respectively.

During the course of the 6 half-years of surveillance, the prevalence of resistance to ACV of immunocompetent patients varied between 0.5 and 0.2%, and that of immunocompromised patients varied between 5 and 3.6%. These overall half-yearly variations are negligible for both the immunocompetent patients and for each category of immunocompromised patients.

In conclusion, 0.3% of immunocompetent patients excreted ACV-resistant strains, in contrast to 3.6% of immunocompromised patients (P < 0.001). The percentage of ACV-resistant HSV-2 strains is not significantly higher than the percentage of HSV-1 strains. The prevalence of resistance is highest (10.9%) in patients who have had a bone marrow transplant, particularly for those who have had allotransplants (18.4%), with a significant difference in relation to the other categories of immunocompromised patients (P < 0.001).

Relationship between excretion of ACV-resistant strains and clinical resistance. Clinical resistance, reported by the doctor, can be seen through persistent lesions with chronic excretion and multiple clinical recurrences. The viral excretions have therefore been put into four categories according to their duration: chronic if the excretion was continuous for longer than 1 month, recurrent if the time between the excretion of two strains was longer than 1 month, short term when the period of excretion was less than 1 month, and "one strain only" when we had only one sample available.

Of the six immunocompetent patients, the female patient with monoclonal gammopathy had persistent genital lesions with chronic excretion of resistant strains. Only one strain was isolated from each one of five other patients, and clinical resistance was not reported.

Of the 54 immunocompromised patients, 36 had clinical resistance, 24 of whom excreted chronic strains and 5 of whom had multiple recurrences. Ten excreted short-term strains, and 15 excreted only a single strain; for 4 of these patients, a resistance to treatment was noted (Table 7).

	DISCUSSION

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The network for surveillance of the resistance of HSV strains to ACV consisted of 15 French virology laboratories. Patients were recruited between May 1999 and April 2002. The colorimetric test for sensitivity to ACV (11), which is fast and reasonably inexpensive, appears to be well adapted to evaluating a large number of isolates, as only 5% have been taken up by the conventional checkerboard technique (22).

In total, 3,357 patients, corresponding to 3,923 strains, have been included in this study. Of the population studied, the vast majority (95%) of whom were recruited from hospitals, 55% were immunocompetent and 45% were immunocompromised. The immunocompetent patients had never received antiviral treatment in 72% of the cases, in comparison to 55% of the immunocompromised patients (P < 0.001).

For immunocompetent patients, the prevalence of resistance to ACV of 0.3% is not significantly different from the prevalences observed by Nugier et al. (29) in France (0.33%) in 601 patients and by Christophers et al. (9) in England (0.28%) in 1,775 patients. Acquisition of resistance to ACV remains rare, and the cases described are mostly cases of genital herpes (21, 27, 38). Besides the female patient described by Mouly et al. (27), we report two new cases of recurrent genital herpes caused by ACV-resistant strains, or a prevalence of 0.55%, which is close to that observed by Christophers et al. (9) (0.47%). Two recent studies have reported cases of resistance to ACV during recurrent orolabial herpetic infections in immunocompetent patients. The prevalence observed by Boon et al. (2) was 0.11%, and that observed by Bacon et al. (1) was 0.2%. In this study, we report two cases of orolabial ACV-resistant HSV strains: one stemming from a recurrent infection, with a prevalence of 0.4%, and one stemming from a primary infection in an untreated female patient, with a prevalence of 0.24%. Some patients with genital herpes excreted ACV-resistant HSV strains without having received antiviral treatment (9) (3 patients out of 708 [0.42%]).

Selection of ACV-resistant strains can be fast; indeed, in the case of patient 01-473, an ACV-resistant strain was observed 2 days after treatment began. Sarisky et al. (35) described the case of a resistant strain isolated 17 h after beginning treatment with PCV. The heterogeneity of HSV populations, i.e., the coexistence of viruses sensitive and resistant to antiviral drugs, facilitates this rapid selection of ACV-resistant strains.

In immunocompromised patients, the prevalence of resistance of 3.6% is lower but not significantly different from those observed in the different studies carried out during the last 10 years: 4.7% of 148 patients (16), 5.4% of 184 patients (29), 6.3% of 95 patients (9), and 4.2% of 971 patients (result of a study carried out at the Laboratory of Virology in Lyon between 1986 and 1996 [M. Aymard et al., unpublished data]). The prevalence of resistance to ACV is very strongly linked to the type of immunosuppression, and when serious immunosuppression is combined with lengthy exposure to ACV, the risk of appearance of strains resistant to antiviral drugs increases considerably. Thus, the study of Englund et al. (16) shows a prevalence of resistance to ACV of 13.7% in bone marrow transplant patients. In our investigation, the prevalence of resistance in these same patients was 10.9% overall and reached 18.4% in patients receiving allotransplants. A recent study showed an incidence of 30% while monitoring allotransplant patients for 4 years in the same hospital department (F. Morfin, K. Bilger, F. Najioullah, A. Boucher, A. Thiebaut, N. Raus, S. Bosshard, M. Aymard, M. Michallet, and D. Thouvenot, submitted for publication).

The prevalence of resistance in HIV-infected patients decreased from 7 to 3.4% during the last 10 years (9, 16, 20). The overall prevalence of 4.2% that we report confirms this decrease, which is probably linked to a reduction in the number of opportunistic infections since the implementation of tritherapy (24).

For 51 of the 54 immunocompromised patients who excreted ACV-resistant strains, treatment with ACV was reported; in 10 cases this was prophylactic treatment. In the cases of a bone marrow transplantation (two cases) and a heart transplantation (one case), there was only one treatment with GCV reported, and we do not know if it was preventive for cytomegalovirus infection. The risk of cross-resistance during administration of antiviral drugs in which the mode of action is TK dependent was previously reported in the literature (16, 29, 32). However, during a study carried out at the Laboratory of Virology in Lyon between 1986 and 1996, prophylactic treatment with ACV was found to carry less risk of a resistant virus emerging in comparison to curative treatments (0.6 versus 2.7%). Prophylactic treatment with GCV in cytomegalovirus-seropositive patients is also accompanied by a decrease in the risk of ACV-resistant HSV strains emerging (6).

Antiviral drugs with a non-TK-dependent mode of action, such as PFA, have been used since the emergence of ACV-resistant strains (7, 28), and PFA-resistant strains have appeared (8, 13, 33, 34). In our study, among the 22 ACV-resistant patients who received PFA, 14 excreted PFA-resistant strains (64%). Likewise, a prevalence of 50% of strains resistant to ACV and to PFA was reported by Chen et al. (8) for 14 patients who received bone marrow transplants. Among the 11 patients who received PFA alternating with ACV following excretion of ACV-resistant strains, 8 excreted PFA-resistant strains (72%) in an average of 13 days after the treatment was administered (between 5 and 43 days). This speed of development in PFA-resistant strains was first reported by Chen et al. (8). They describe three patients who excreted PFA-resistant strains when they received PFA for the first time and two patients, having previously received treatment with PFA, who developed PFA-resistant strains after only 5 and 7 days of treatment. Langston et al. (23) described three bone marrow transplantation patients who excreted ACV-resistant HSV strains and who rapidly developed PFA-resistant strains while under treatment with PFA (after 3, 6, and 10 weeks). Alternation of antiviral treatments remains, however, the best strategy for overcoming the emergence of resistant strains, because when antiviral treatment stops, the strains again become sensitive to the antiviral drugs. In this study, for three of the six patients who received PFA alternating with ACV (50%), strains sensitive to ACV and to PFA were isolated.

Resistance to ACV is demonstrated by the presence of mutations in the TK gene (12, 18) and, more rarely, in the DNA polymerase gene (25). Resistance to PFA is explained by the presence of a mutation in the DNA polymerase gene (19). The combination of phenotypic tests for cross-resistance and genetic tests would allow us to improve our knowledge about the molecular mechanism of resistance to antiviral drugs, to develop fast methods to detect resistant mutants (for example, by direct sequencing of the pathological product), and to implement a rational therapeutic strategy in the choice of secondary antiviral drugs, such as PFA and cidofovir (the latter is still reserved for patients excreting strains resistant to both ACV and PFA) (3, 4).

It was necessary to collect a large number of isolates in order to evaluate the prevalence of resistance to antiviral drugs and to study changes in resistance. It is interesting to observe the stability of frequency of resistance in the immunocompetent and immunocompromised populations, as well as the tendency to a reduction in resistance of the HSV in subjects infected by HIV. Indeed, despite self-medication by immunocompetent patients and curative and prophylactic treatments for immunocompromised patients, resistance to ACV has not increased during the course of the last 10 years. In bone marrow transplantation patients receiving multiple antiviral treatments as a prophylactic or therapeutic measure, the risk of selecting ACV-resistant HSV strains is very high and justifies virological surveillance as well as a phenotypic study of cross-sensitivity to other antiviral drugs. With more than 3,300 patients, this study has demonstrated the benefit of regularly monitoring patients at risk to detect in vitro resistance in order to adapt therapeutic care to the needs of immunocompromised patients.

	ACKNOWLEDGMENTS

 
We thank GlaxoSmithKline laboratories for financial support.

We thank S. Lambert and S. Mundweiler for excellent technical assistance.

	FOOTNOTES

 
* Corresponding author. Mailing address: CHU Lyon, 8 avenue Rockefeller, 69373 Lyon Cedex 08, France. Phone: 33 4 78 77 70 29. Fax: 33 4 78 01 48 87. E-mail: christelle.szatanek{at}free.fr.

	REFERENCES

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1. Bacon, T., R. Boon, M. Schlutz, and C. Hodges-Savola. 2002. Surveillance for antiviral agent-resistant herpes simplex virus in the general population with recurrent herpes labialis. Antimicrob. Agents Chemother. 46:3042-3044.[Abstract/Free Full Text]
2. Boon R. J., T. H. Bacon, H. L. Robey, T. J. Coleman, A. Connolly, P. Crosson, and D. L. Sacks. 2000. Antiviral susceptibility of herpes simplex virus from immunocompetent subjects with recurrent herpes labialis: an IK-based survey. J. Antimicrob. Chemother. 46:324-325.[Free Full Text]
3. Blot, N., P. Shneider, P. Young, C. Janvresse, D. Dehesdin, P. Tron, and J. P. Vannier. 2000. Treatment of an acyclovir and foscarnet resistant herpes simplex virus infection with cidofovir in a child after unrelated bone marrow transplant. Bone Marrow Transplant. 26:903-905.[CrossRef][Medline]
4. Bryant, P., J. Sasadeusz, J. Carapetis, K. Waters, and N. Curtis. 2001. Successful treatment of foscarnet resistant herpes simplex stomatis with intravenous cidofovir in a child. Pediatr. Infect. Dis. 20:1083-1806.
5. Burns, W. H., R. Saral, G. W. Santos, O. L. Laskin, P. S. Leitman, C. McLaren, and D. W. Barry. 1982. Isolation and characterization of resistant herpes simplex virus after acyclovir therapy. Lancet i:421-423.
6. Chakrabarti, S., D. Pillay, D. Ratcliffe, P. A. Cane, K. E. Collinghan, and D. W. Milligan. 2000. Resistance to antiviral drugs in herpes simplex virus infections among allogeneic stem cell transplant recipients: risk factors and prognostic significance. J. Infect. Dis. 181:2055-2058.[CrossRef][Medline]
7. Chatis P. A., C. H. Miller, L. Schrager, and C. C. Crumpacker. 1989. Successful treatment with foscarnet of an acyclovir resistant mucocutaneous infection with herpes simplex virus in a patient with acquired immunodeficiency syndrome. N. Engl. J. Med. 320:297-300.[Medline]
8. Chen, Y., C. Scieux, V. Garrait, G. Socié, V. Rocha, J. M. Molina, D. Thouvenot, F. Morfin, L. Hocqueloux, L. Garderet, H. Esperou, F. Selimi, A. Dervergie, G. Leleu, M. Aymard, F. Morinet, E. Gluckman, and P. Ribaud. 2000. Resistant herpes simplex virus type 1 infection: an emerging concern after allogeneic stem cell transplantation. Clin. Infect. Dis. 31:927-935.[Medline]
9. Christophers, J., J. Clayton, J. Craske, R. Ward, P. Collins, M. Trowbridge, and G. Darby. 1998. Survey of resistance of herpes simplex virus to acyclovir in northwest England. Antimicrob. Agents Chemother. 42:868-872.[Abstract/Free Full Text]
10. Crumpacker, C. S., L. E. Schnipper, S. I. Marlowe, P. N. Kowalsky, B. J. Hershey, and M. J. Levin. 1982. Resistance to antiviral drugs of herpes simplex virus isolates from a patient treated with acyclovir. N. Engl. J. Med. 306:343-346.[Medline]
11. Danve, C., F. Morfin, D. Thouvenot, and M. Aymard. 2002. A screening dye-uptake assay to evaluate in vitro susceptibility of herpes simplex virus isolates to acyclovir. J. Virol. Methods 105:207-217.[CrossRef][Medline]
12. Darby, G., B. A. Larder, and M. M. Inglis. 1986. Evidence that the active centre of the herpes simplex virus thymidine kinase involves an interaction between three distinct regions of the polypeptide. J. Gen. Virol. 67:753-758.[Abstract/Free Full Text]
13. Darville, J. M., B. E. Ley, A. Roome, and A. Foot. 1998. Acyclovir resistant herpes simplex virus infections in a bone marrow transplant population. Bone Marrow Transplant. 22:587-589.[CrossRef][Medline]
14. Edert, D., C. Finance, and A. Le Faou. 2000. Susceptibility of clinical strains of herpes simplex virus to three nucleoside analogues. Exp. Chemother. 46:195-197.[CrossRef]
15. Efstathiou, S., S. Kemp, G. Darby, and A. C. Minson. 1989. The role of herpes simplex virus type 1 thymidine kinase in pathogenesis. J. Gen. Virol. 70:869-879.[Abstract/Free Full Text]
16. Englund J. A., M. E. Zimmerman, E. M. Swierkosz, J. L. Googman, D. R. Scholl, and H. H. Balfour. 1990. Herpes simplex virus resistant to acyclovir: a study in a tertiary care centre. Ann. Intern. Med. 112:416-422.
17. Erlich K. S., J. Mills, P. Chatis, G. J. Mertz, D. F. Busch, S. E. Follansbee, R. M. Grant, and C. S. Crumpacker. 1989. Acyclovir-resistant herpes simplex virus infection in patients with the acquired immunodeficiency syndrome. N. Engl. J. Med. 302:293-296.
18. Gaudreau, A., E. Hill, H. J. Balfour, A. Erice, and G. Boivin. 1998. Phenotypic and genotypic characterization of acyclovir-resistant herpes simplex viruses from immunocompromised patients. J. Infect. Dis. 178:297-303.[Medline]
19. Gibbs J., H. Chiou, K. Bastow, Y. C. Cheng, and D. Coen. 1988. Identification of amino acids in herpes simplex virus DNA polymerase involved in substrate and drug recognition. Proc. Natl. Acad. Sci. USA 85:6672-6676.[Abstract/Free Full Text]
20. Harden E. A., R. J. Ryback, C. Hartline, J. W. Gnann, C. A. Hodges-Savola, N. T. Weterhall, E. R. Kern, et al. 2000. Cross susceptibility patterns and neuro-virulence of acyclovir resistant herpes simplex virus isolates in a national surveillance study. Antiviral Res. 46:A78.
21. Kost, R., E. L. Hill, M. Tigges, and S. E. Straus . 1993. Recurrent acyclovir-resistant genital herpes in an immunocompetent patient. N. Engl. J. Med. 329:1777-1781.[Free Full Text]
22. Langlois, M., J. P. Allard, F. Nugier, and M. Aymard. 1986. A rapid and automated colorimetric assay for evaluating the sensitivity of herpes simplex strains to antiviral drugs. J. Biol. Stand. 14:201-211.[CrossRef][Medline]
23. Langston, A. A., I. Redei, A. M. Caliendo, et al. 2002. Development of drug resistant herpes simplex virus infection after haploidentical hemopoietic cell transplantation Blood. 99:1085-1088.[Abstract/Free Full Text]
24. Ledergerber, B., M. Egger, et al. 1999. AIDS-related opportunistic illness occurring after initiation of potent antiretroviral therapy: the Swiss HIV cohort. JAMA 282:2220-2226.[Abstract/Free Full Text]
25. Matthews, J., R. Carroll, J. Stevens, and M. Haffay. 1989. In vitro mutagenesis of herpes simplex virus type 1 DNA polymerase gene results in altered drug sensitivity of the enzyme. J. Virol. 63:4913-4918.[Abstract/Free Full Text]
26. McLaren, C., M. N. Ellis, and G. A. Hunter. 1983. A colorimetric assay for measurement of sensitivity of herpes simplex viruses to antiviral agents. Antiviral Res. 3:233-234.
27. Mouly, F., M. Baccard, C. Scieux, L. Schnell, S. Locq-Ebner, F. Morinet, and P. Morel. 1995. Chronic recurrent aciclovir-resistant genital herpes in an immunocompetent patient. Dermatology 190:177.[Medline]
28. Naik, H. R., N. Siddique, and P. H. Chandrasekar. 1995. Foscarnet therapy for acyclovir resistant herpes simplex virus 1 infection in allogenic bone marrow transplant recipients. Clin. Infect. Dis. 21:1514-1515.[Medline]
29. Nugier, F., J. N. Colin, M. Aymard, and M. Langlois1992. Occurrence and characterization of acyclovir-resistant herpes simplex virus isolates: report on a two-year sensitivity screening survey. J. Med. Virol. 36:1-12.[CrossRef][Medline]
30. Pavic, I., A. Hartmann, A. Zimmermann, D. Michel, W. Hampl, I. Schleyer, and T. Mertens. 1997. Flow cytometric analysis of herpes simplex virus type 1 susceptibility to acyclovir, ganciclovir, and foscarnet. Antimicrob. Agents Chemother. 41:2686-2692.[Abstract]
31. Plummer, G., and M. Benyesh-Melnick. 1964. A plaque reduction neutralization test for human cytomegalovirus. Proc. Soc. Exp. Biol. Med. 117:145-150.
32. Reusser P., C. Cordonnier, H. Einsele, D. Engelhard, H. Link, A. Locasciulli, P. Ljungman, et al.. 1996. European survey of herpes virus resistance to antiviral drugs in bone marrow transplant recipients Bone Marrow Transplant. 17:813-817.[Medline]
33. Safrin S., S. Kemmerly, B. Plotkin, T. Smith, N. Weissbach, D. De Veranez, L. Phan, and D. Cohn. 1994. Foscarnet-resistant herpes simplex virus infection in patients with AIDS. J. Infect. Dis. 169:193-196.[Medline]
34. Saïjo, M., Y. Yasuda, et al. 2002. Bone marrow transplantation in a child with Wiskott-Aldrich syndrome latently infected acyclovir resistant herpes simplex virus type 1: emergence of a foscarnet resistant virus originating from the ACV^r virus. J. Med. Virol. 68:99-104.[CrossRef][Medline]
35. Sarisky, R. T., T. Bacon, R. Boon, L. Locke, T. T. Ngyuen, J. Leary, K. Esser, and R. Saltzman. 2002. Penciclovir susceptibility of herpes simplex virus isolates from patients using penciclovir cream for treatment of recurrent herpes labialis. Antimicrob. Agents Chemother. 46:2848-2853.[Abstract/Free Full Text]
36. Sibrack, C. D., L. T. Gutman, C. M. Wilfert, C. MacLaren, M. H. St. Clair, P. M. Keller, and D. W. Barry. 1982. Pathogenicity of acyclovir resistant herpes simplex virus type 1 from an immunodeficient child. J. Infect. Dis. 146:673-682.[Medline]
37. Standberry, L. S., D. M. Jorgensen, and A. J. Nahmias. 1997. Herpes simplex virus 1 and 2, p. 419-454. In A. S. Evan and R. A. Kaslow (ed.). Viral infections of humans, 4th ed. Plenum Medical Book Company, New York, N.Y.
38. Swetter, S. M., E. L. Hill, E. R. Kern, D. M. Koelle, C. M. Posaved, W. Lawrence, and S. Safrin. 1998. Chronic vulvar ulceration in an immunocompetent woman due to acyclovir resistant, thymidine kinase deficient herpes simplex virus. J. Infect. Dis. 177:543-550.[Medline]
39. Swierkosz, E. M., D. R. Scholl, J. L. Brown, J. D. Jollick, and C. A. Gleaves. 1987. Improved DNA hybridization method for detection of acyclovir-resistant herpes simplex virus. Antimicrob. Agents Chemother. 31:1465-1469.[Abstract/Free Full Text]
40. Vyse, A., N. Gay, M. Slomka, et al. 2000. The burden of infection with HSV1 and HSV2 in England and Wales: implication for the changing epidemiology of genital herpes. Sex Transm. Infect. 76:183-187.[Abstract/Free Full Text]

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