Antimicrobial Agents and Chemotherapy, May 2004, p . 1865-1868, Vol . 48, No . 5

Natural Polymorphism of Cytomegalovirus DNA Polymerase Lies in Two Nonconserved Regions Located between Domains Delta-C and II and between Domains III and I

Anne-Marie Fillet,^1* Laetitia Auray,¹ Sophie Alain,² Karine Gourlain,¹ Berthe Marie Imbert,³ Fatiha Najioullah,⁴ Gael Champier,² Stéphanie Gouarin,⁵ Jocelyne Carquin,⁶ Nadhira Houhou,⁷ Isabelle Garrigue,⁸ Alexandra Ducancelle,⁹ Danielle Thouvenot,⁴ and Marie-Christine Mazeron⁹

Virology Laboratories, Hospital AP-HP Pitié-Salpêtrière and University Paris VI,¹ Hospital AP-HP Bichat-Claude Bernard,⁷ Hospital AP-HP Lariboisière, Paris,⁹ Teaching hospital, Limoges,² Teaching hospital, Nantes,³ Domaine Rockefeller, Lyon,⁴ Hospital Clemenceau, Caen,⁵ Hospital Robert Debré, Reims,⁶ Hospital Pellegrin, Bordeaux, France⁸

Received 6 October 2003/ Returned for modification 13 November 2003/ Accepted 8 January 2004

Ganciclovir resistance results mostly from changes in the UL97 phosphotransferase (7, 30) responsible for the primary phosphorylation of ganciclovir . Mutations in the UL 54 polymerase gene appear after prolonged ganciclovir therapy . They contribute to a high level of resistance to ganciclovir and induce cross-resistance to cidofovir (23, 29) . All foscarnet- and cidofovir-resistance mutations map to the UL 54 gene . Resistance mutations are mainly located in the conserved domains of the polymerase, and their location can often predict the resistance patterns of the strains (15, 20) .

As CMV resistance to antiviral drugs is a factor in therapeutic failure and disease progression (1, 3, 24), accurate and early resistance detection is needed . Phenotypic susceptibility assays require a long turnaround time in order to identify drug-resistant CMV isolates . The most convenient means of laboratory diagnosis of a drug-resistant virus is genotypic testing which shortens the delay of results, avoids bias by cell culture selection, and detects the resistance earlier (17, 19, 21, 22) . The interpretation of genetic assays requires that resistance-associated mutations to natural variation be distinguished . Some of the DNA polymerase changes have been validated as resistance markers by a process of marker transfer (2, 8, 9, 11, 12, 13, 14, 15, 18, 29), but others have not . In the latter situation the role of such changes in inducing resistance is questionable .

To date, only one study which listed changes in 40 ganciclovir- and foscarnet-susceptible CMV isolates from the United States has been performed to define natural variations (10) .

The aim of the multicenter study in France was to describe DNA polymerase polymorphisms in the region spanning domain IV to domain V .

Forty-two unrelated patients who had not received prior anti-CMV treatment (29 infants with congenital infection, 11 transplant recipients, and 2 human immunodeficiency virus-infected patients) were included . The following were collected: 13 amniotic fluid samples, 15 urine samples, 12 peripheral blood leukocyte samples, 1 bronchoalveolar fluid sample, and 1 lung biopsy sample . Also studied were four reference CMV strains, AD169, Towne, Davis (ATCC strains VR-538, VR-977, and VR-807, respectively), and Toledo (kindly provided by S . Michelson) .

Phenotypic susceptibility of the isolates to ganciclovir, foscarnet, and cidofovir was verified by measuring the drug concentration required to reduce the number of plaques by 50% (50% inhibitory concentration [IC₅₀]) compared to controls according to the Agence Nationale de Recherches sur le SIDA consensus method (16) . An isolate was considered sensitive if the ganciclovir sensitivity index (IC₅₀ of the isolate/IC₅₀ of strain AD169) was <3, the foscarnet IC₅₀ was <400 µM, and the cidofovir IC₅₀ was <2 µM . According to these criteria, all the isolates were susceptible to the three drugs .

CMV DNA was extracted from clinical samples or infected fibroblasts (isolates and reference strains) by means of a Qia-Amp DNA blood kit (QIAGEN, Hilden, Germany) . The 2,019-bp region from codon 349 to codon 1022 of the UL 54 gene was amplified by using a high fidelity polymerase (LA PCR kit; Takara, Shiga, Japan) and the forward primer 5'-ATC TCT TTA CGA TCG GCA CC-3' and reverse primer 5'-ATC CTC AAA GAG CAG GGA GAG-3' . Sequences were determined either directly from initial samples (18 cases) or from isolates (24 cases) if amplification from the initial sample failed . PCR products were sequenced in forward and reverse directions by using internal primers that produced overlapping sequences (1,810 bps, codons 370 to 990), encompassing the conserved domains . Sequencing reactions were performed by Big Dye assay (Applied Biosystems, Warrington, United Kingdom) and analyzed with an automated sequencer (ABI 3100 Genetic Analyser; Applied Biosystems) . Nucleotide and amino acid sequences were compared to the AD169 sequences with AutoAssembler and sequence navigator software . All interstrain changes including single-amino-acid substitutions and an eight-amino-acid deletion were clustered in two nonconserved regions located between domains delta-C and II and between domains III and I, respectively (Fig . 1) .

 
Phylogenetic analysis was performed by using CLUSTAL W version 6.1 and PHYLIP software programs . The alignment of sequences showed 98% nucleotide homology . A phylogenetic tree, including the sequences of our 42 CMV strains, 19 strains from the United States published by Chou et al . (10), and reference strains AD169, Towne, Davis, and Toledo, was constructed by the neighbor-joining method and was generated with 100 bootstrap values . It showed no distinctive clustering based on geographical origin .

These results confirm the very weak variability of the CMV DNA polymerase gene as reported previously (10) . All the previously reported polymorphisms, except two changes located between domains IV and delta-C and one in the conserved domain II (10), were located in the regions between domains delta-C and II and between domains III and I (29, 33, 35) . Amino acid alignments of the human herpes virus polymerases, the human polymerase (6), and the polymerases of bacteriophages RB69 (32) and T4 (31) showed the following features: (i) the counterparts of the region between domains delta-C and II were either absent or significantly shorter in the other polymerases, and (ii) when present, they were highly divergent . The whole region between domains delta-C and II was rich in glycine (G) and serine (S), amino acids known to be present in flexible regions of proteins, as was a short segment close to domain I (Fig . 2) between domains III and I, where most of interstrain changes were located . Indeed, the region between domains delta-C and II of herpes simplex DNA polymerase was also likely to be flexible, according to proteolytic studies (34) . The combination of these characteristics suggests that these specific residues are not involved in the enzymatic functions .

 
The five most frequent changes from the AD169 sequence (A885T, N898D, S655L, N685S, S897L) in our study were also detected by Chou et al . (10) . As summarized in Table 1, T885 was rarely present either in field isolates or in the other reference strains . The four other mutations were hot spot sites of polymorphism as already described (29, 33, 35) . Each of the four reference strains had a specific pattern concerning these five positions . AD169 is a good reference strain because, on the one hand, it is the reference for IC₅₀ determination and, on the other hand, its sequence is well known .

 
In conclusion, although the natural polymorphism of CMV DNA polymerase is weak, knowledge of the polymorphism improves the interpretation of the sequencing results in patients with antiviral treatment failure . Indeed, the location of the mutations in the regions between domains delta-C and II and between domains III and I argues strongly in favor of a natural polymorphism . However, wild isolates should be further studied in order to draw a precise map of a polymorphism and, in particular, the location of a rare mutation .

Nucleotide sequence accession numbers. Sequences determined in this study have been deposited in the GenBank database under accession numbers AY422355 through AY422377 .

We thank Benoit Barrou for providing clinical information concerning kidney transplant recipients and Nathalie Dhédin for information concerning bone marrow recipients . We appreciate the advice provided by Constance Delaugerrre on phylogenetic studies and by Stephane Duquerroy on sequence alignment .

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