Comparison of Mass Spectrometric Analysis and TRUGENE™ HBV Genotyping for Monitoring Lamivudine Resistance in Chronic Hepatitis B Patients

Background

There is an increasing need for the early detection of emerging mutations in the tyrosine-methionine-aspartate-aspartate (YMDD) motif of hepatitis B virus (HBV) DNA polymerase with using sensitive molecular methods.

Methods

We evaluated the usefulness of monitoring lamivudine resistance using a matrix-assisted laser desorption/ionization time-of-flight mass spectrometry-based assay (the restriction fragment mass polymorphism; RFMP) in comparison with the direct sequencing assay, the TRUGENE™ HBV genotyping kit. We also investigated the treatment responses in relation to the presence of YMDD mutants. The sera from 50 chronic HBVs patients were analysed for the presence of YMDD mutants by performing RFMP and TRUGENE. The results at codons 180 and 204 were compared for 46 patients.

Results

The concordance rate between the two assays was 65.2% (30/46). All the discordance corresponded to the detection of additional virus populations by RFMP. Early detection of mutants before viral breakthrough was accomplished by RFMP in two patients. Persistence of very low viraemia was observed in five patients who harboured mutant virus populations. Additional information was provided by TRUGENE in eight patients.

Conclusions

RFMP showed a superior ability for detecting minor mutant virus populations compared with TRUGENE. However, the results of highly sensitive RFMP should be interpreted carefully because lamivudine could be effective despite the presence of mutants. RFMP could be a practical tool in conjuction with regular measurements of the HBV viral load for the early detection of lamivudine resistance and the timely introduction of new antiviral drugs.

Quantitative Subtyping of Hepatitis B Virus Reveals Complex Dynamics of Ymdd Motif Mutants Development during Long-Term Lamivudine Therapy

Background/aims

Treatment of chronic hepatitis B (CHB) with lamivudine (3TC) is limited by development of drug-resistant mutants at the YMDD motif. We aimed to validate the use of mass spectrometry to detect YMDD mutants and quantify viral subpopulations.

Methods

A total of 21 Chinese patients with severe acute exacerbation of CHB treated with 3TC were studied. Serial serum samples were tested for wild-type and YMDD mutants using matrix assisted laser desorption/ionization time-of-flight mass spectrometry. INNO-LiPA assay was performed for comparison.

Results

At a median follow-up of 192 weeks, 11 patients developed YMDD mutants (six had YIDD, four had YVDD and one had YV/IDD). Mass spectrometry was concordant with INNO-LiPA in all but one patient, in which INNO-LiPA detected coexistence of YIDD and YVDD but mass spectrometry and direct sequencing detected YVDD only. Mass spectrometry was able to reliably detect a minor hepatitis B virus (HBV) subtype at 5% or above. By serial quantitative measurement, several patterns of viral dynamics were observed. In some cases, YMDD mutants dominated the whole viral population. In other cases, the proportion of YMDD mutants fluctuated with time. When more than one mutant was present (that is, YIDD and YVDD), the different mutants might dominate during different time periods.

Conclusions

Mass spectrometry is an accurate and cheap method for the detection of YMDD mutants, even in the presence of overwhelming wild-type HBV. We observed some intriguing mutant viral dynamics during 3TC treatment. Further studies are needed to clarify whether they have any clinical significance.