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Antimicrobial Agents and Chemotherapy, April 1998, p. 833-839, Vol. 42, No. 4
0066-4804/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Unique Metabolism of a Novel Antiviral
L-Nucleoside Analog,
2'-Fluoro-5-Methyl-
-L-Arabinofuranosyluracil: a
Substrate for Both Thymidine Kinase and Deoxycytidine
Kinase
Shwu-Huey
Liu,
Kristie L.
Grove, and
Yung-Chi
Cheng*
Department of Pharmacology, Yale University
School of Medicine, New Haven, Connecticut 06510
Received 12 September 1997/Returned for modification 5 November
1997/Accepted 13 January 1998
 |
ABSTRACT |
2'-Fluoro-5-methyl-
-L-arabinofuranosyluracil
(L-FMAU) is the first L-nucleoside analog with
low cytotoxicity discovered to have potent antiviral activities against
both hepatitis B virus and Epstein-Barr virus but not human
immunodeficiency virus. This spectrum of activity is different from
those of the other L-nucleoside analogs examined.
L-FMAU enters cells through equilibrative-sensitive and
-insensitive nucleoside transport as well as through nonfacilitated passive diffusion. L-FMAU is phosphorylated stepwise in
cells to its mono-, di-, and triphosphate forms. In the present study the enzymes responsible for the first step of L-FMAU
phosphorylation were identified. This is the first thymidine analog
shown to be a substrate not only for cytosolic thymidine kinase and
mitochondrial deoxypyrimidine kinase but also for deoxycytidine kinase.
This finding suggests that the antiviral activity of L-FMAU
will not be limited by the loss or alteration of any of these
deoxynucleoside kinases.
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INTRODUCTION |
Hepatitis B virus (HBV) infection is
a major worldwide health problem. Infection with HBV not only causes
hepatitis but also has a strong association with hepatocellular
carcinoma (1, 24). A selective antiviral compound would be
useful for the treatment of hepatitis caused by HBV and may even
prevent or delay the onset of hepatocellular carcinoma associated with
HBV.
Currently, the only drug approved for the treatment of HBV hepatitis is
alpha interferon. However, only 25 to 50% of patients respond to this
therapy. Furthermore, there are side effects associated with this
treatment (19). A more selective anti-HBV drug is needed.
HBV is an incomplete double-stranded DNA virus. Its DNA replication
process is quite unique and includes the step of reverse transcription catalyzed by HBV-specified DNA polymerase
(23). The fact that HBV DNA polymerase is quite different
from human DNA polymerase raises the possibility of the discovery of
compounds that could selectively inhibit HBV DNA replication.
Deoxynucleoside analogs were previously shown to be active against HBV
and to have different degrees of toxicity (22). Their mechanism of antiviral action is suggested to be mediated through a unique interaction of the triphosphate metabolites with HBV DNA
polymerase. Although HBV DNA polymerase is essential for HBV DNA
replication and virus propagation, it is not required for HBV
supercoiled DNA or intergrated DNA synthesis. In order to be more
effective in the treatment of chronic HBV infection, treatment with
those anti-HBV nucleoside analogs which target HBV DNA polymerase will
need to be long term. This prolonged treatment not only will inhibit
HBV replication but also will deplete cells that harbor either
supercoiled or integrated HBV DNA through natural turnover of
virus-harboring cells. Thus, the safety of the drug upon long-term use
is an important issue.
Several of the toxicities of nucleoside analogs can be associated with
the incorporation of their triphosphate metabolites into nuclear DNA.
Upon long-term treatment, these drugs can also interfere with
mitochondrial DNA synthesis, resulting in delayed toxicity. In the
search for new antiviral compounds with fewer short- and long-term
toxicities, -L-2',3'-dideoxy-3'-thiacytidine (L-SddC; 3TC) was found to have potent activity against HBV
and human immunodeficiency virus (HIV) (3, 9). Nucleosides
are found in nature only in the -D configuration, and
this compound was the first nucleoside analog with the unnatural
-L configuration shown to have biological activity.
Subsequently, several other -L-deoxycytidine analogs
were found to have similar activities against HBV and HIV (10, 11,
16, 17, 29). However, none of these compounds is active against
Epstein-Barr virus (EBV).
L-SddC exerts its antiviral activity through the
interaction of its triphosphate metabolite with HIV reverse
transcriptase and HBV DNA polymerase. Unlike most previously
studied antiviral dideoxynucleoside analogs including the
anti-HBV compounds 2'-fluoro-5-methyl--D-arabinofuranosyluracil (D-FMAU)
and
1-(2'-deoxy-2'-fluoro--D-arabinofuranosyl)-5-iodouracil (D-FIAU), L-SddC does not interfere with
mitochondrial function. L-SddC has already been approved
for use for the treatment of patients with AIDS in combination with
zidovudine. In addition, L-SddC is currently showing
impressive results in clinical trials for the treatment of chronic HBV
infection (18, 25).
A problem with the use of L-SddC for anti-HIV therapy is
the development of resistance mediated by mutations in the HIV reverse transcriptase. Although L-SddC-resistant viruses are likely
to be cross-resistant to other deoxycytidine (dCyd) analogs, they may
not be resistant to analogs with different base. In addition, the
spectrums of toxicity and activity of these analogs might be different
from those of analogs with a cytidine base. Therefore, several
L-nucleoside analogs with different bases were synthesized and examined for antiviral activity. One of these compounds,
2'-fluoro-5-methyl--L-arabinofuranosyluracil (L-FMAU), was found to be active against HBV in 2.2.15 cells, with a 50% effective concentration of 0.1 µM. Unlike
the -L-dideoxycytidine (-L-ddC) analogs,
this compound was inactive against HIV. Interestingly, it was also
active against EBV, with a 90% effective concentration of 5 µM
(7, 21). This is the first example of an
L-thymidine analog with potent antiviral activity.
Although its spectrum of activity is different from those of
other -L-nucleoside analogs, it shares their
favorable toxicity profiles. Unlike its D analog,
L-FMAU triphosphate (L-FMAUTP) could not
be incorporated into nuclear DNA on the basis of cell culture studies
and experiments done with purified human DNA polymerases (21). In addition, treatment with L-FMAU did not
deplete cells of mitochondrial DNA. Therefore, delayed toxicities
upon long-term treatments should not be a problem with this
compound. Indeed, no toxicity was observed in mice after 30 days of
continuous treatment with L-FMAU at 50 mg/kg of body
weight. In vivo, L-FMAU was shown to have potent antiviral
activity against duck HBV when it was administered at an oral dosage of
10 mg/kg for 5 days (30). These results demonstrate the
potential use of L-FMAU for the treatment of human HBV
infection.
Like other nucleoside analogs, L-FMAU could be
phosphorylated in cells to its mono-, di-, and triphosphate
metabolites. L-FMAUTP is the major metabolite in most cell
lines examined except H1 cells, in which L-FMAU
monophosphate (L-FMAUMP) is the major metabolite (27,
28). This unique metabolic feature of L-FMAU in H1
cells could be due to the presence of EBV thymidine (dThd) kinase in cells. The metabolism of L-FMAU in 2.2.15 cells was no
different from its metabolism in HepG2 cells, suggesting that the
activation of L-FMAU is most likely carried out by cellular
enzymes (21). Given the unique structure of
L-FMAU, it was not clear which enzymes in human cells could
be important in its metabolism. This report describes the results of
our studies with respect to the enzymes with key roles in the
phosphorylation of L-FMAU to L-FMAUTP.
| |
MATERIALS AND METHODS |
Chemicals.
L-FMAU was synthesized by C. K. Chu, Department of Chemistry, University of Georgia.
[methyl-3H(N)]L-FMAU (76 Ci/mmol),
[5'-3H]L-FMAU (29.8 Ci/mmol),
[methyl-14C]thymidine (54 mCi/mmol),
[2-14C]2'-deoxycytidine (56 mCi/mmol), and
[2',3'-3H]dideoxyinosine (42 Ci/mmol) were
purchased from Moravek Biochemicals, Inc., Brea, Calif. Both
L-FMAU and [3H]L-FMAU were
further purified by high-performance liquid chromatography (HPLC) on
an RP-C18 column (Alltech Associates, Inc., Deerfield, Ill.) and
eluted with 20 mM KH2PO4 (pH 5.5).
L-FMAUTP was synthesized by a previously
described procedure (3).
3-[(3-Cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS),
streptomycin sulfate, dipyridamole (DPM), and
b-[(4-nitrobenzyl)thio]-9--D-ribofuranosyl purine (NBMPR) were purchased from Sigma Chemical Co., St. Louis, Mo.
Purification of cytosolic dThd kinase and mitochondrial dPyd
kinase.
The purification procedures were the same as those
described previously, with some modifications (15). Human
chronic lymphocytic leukemia cells were extracted with 3 volumes of
buffer containing 10 mM Tris-HCl (pH 7.5), 1.5 mM MgCl2, 3 mM dithiothreitol (DTT), and 10 µM dThd. After 0.5% streptomycin
sulfate precipitation and 55% ammonium sulfate precipitation, followed
by dialysis, the crude cell extract was purified with a dThd affinity
column (13) (0.5 by 5 cm). 5-Bromovinyl-deoxyuridine
inhibited mitochondrial deoxypyrimidine (dPyd) kinase activity
(Ki = 0.83 ± 0.12 µM) but had no effect on that of
cytosolic dThd kinase (Ki > 100 µM) (5). CHAPS (0.5 mM) was added to each fraction to stabilize the enzymes (20). Due to the low protein concentration of purified
enzyme, the specific activity of cytosolic dThd kinase was estimated to be higher than 37 U/mg, while that of mitochondrial dPyd kinase was
higher than 6 U/mg. The unit of specific activity is defined as the
amount of enzyme which converts 1 nmol of dThd in 1 min at 37°C under
our assay conditions.
Purification of dCyd kinase.
dCyd kinase was purified from
BL21 (de3) bacteria containing the PET-3d expression vector into which
the cDNA of the human dCK gene cloned from KB cells has been inserted.
The bacterial pellet was extracted with buffer containing 25 mM
Tris-HCl (pH 7.5), 2 mM DTT, 10% glycerol, and 40 µM
ATP-MgCl2 and was lysed by treatment with 10 µg of
lysozyme per ml and sonicated. After centrifugation to remove the
insoluble fraction, the supernatant was fractionated with 20 to 55%
ammonium sulfate. The ammonium sulfate was then removed by dialysis
against buffer containing 25 mM Tris-HCl (pH 7.5), 2 mM DTT, 10%
glycerol, and 40 µM ATP-MgCl2. The protein was then
loaded onto a DE-52 anion-exchange column and eluted with a linear
gradient of the same buffer containing 0 to 1 M NaCl (4).
The partially purified protein was then loaded onto a hydroxyapatite
column and was eluted with a linear gradient of 0 to 1.0 mM
ATP-MgCl2. The dCyd kinase was further purified by fast
performance liquid chromatography with an anion-exchange mono-Q column
and had a final specific activity of 13 U/mg. The unit of specific
activity is defined as the amount of enzyme which converts 1 nmol of
dCyd in 1 min at 37°C. Bovine serum albumin (1 mg/ml) was added to
stabilize the purified dCyd kinase. No contamination of dThd kinase was
found in the dCyd kinase preparation.
dThd kinase and dCyd kinase activity assay.
dThd kinase
(0.004 U for cytosolic dThd kinase or 0.0006 U for mitochondrial dThd
kinase) or dCyd kinase (0.01 U) was incubated at 37°C for 1 h
with the kinase mixture which was described previously (4,
26), but with the following modifications: 0.14 M Tris-HCl (pH
7.5), 1.7 mM DTT, 8 mM NaF, 2 mM ATP-MgCl2, and 0.1 mM
[14C]dThd (11.8 mCi/mmol) or 0.1 mM
[14C]dCyd (11.8 mCi/mmol). The same procedures were used
for the kinetic studies, with the exception that the reaction mixtures contained different concentrations of dThd, ranging from 2 to 20 µM,
or dCyd, ranging from 1.25 to 40 µM (with radiospecificities of 19.9 mCi/mmol for both substrates).
L-FMAU kinase activity assay.
The reaction
conditions of the L-FMAU kinase activity assay were similar
to those of dThd kinase assays except that 0.1 mM [3H]L-FMAU (1,000 µCi/µmol) was used as a
substrate. Sometimes, UTP was used to replace ATP for dCyd kinase
catalysis. After the reaction, 50 µl of each reaction mixture was
applied to a Whatman DE-81 disc, and then the disc was washed three
times with 1 mM ammonium formate and once with ethanol. The discs were
dried and 1 ml of 0.2 N HCl-2 M NaCl was added to elute the
radioactive product from the disc. Radioactivities were quantified by
scintillation counting. For the kinetic studies with dThd kinase,
L-FMAU concentrations ranging from 5 to 40 µM were used.
For the kinetic studies with dCyd kinase, the concentration of
L-FMAU ranged from 50 to 800 µM. In examining the
inhibitory effect of natural nucleosides, 588 µM nucleoside was used
with 100 µM [3H]L-FMAU as a substrate.
5'-Nucleotidase activity assay.
The 5'-nucleotidase activity
assay proctols were modified from the procedures reported by Johnson
and Fridland (12). The 5'-nucleotidase reaction mixture
contained 0.1 M Tris-HCl (pH 7.5), 5 mM MgCl2, 3 mM DTT,
0.5 M KCl, 10 µM dideoxyinosine (ddI), 1 µCi of
[3H]ddI, 2 mM IMP, and dialyzed cell extract. The
reaction mixture was incubated at 37°C for 2 h in a final volume
of 100 µl. The resulting products were detected by the procedures
described above.
Drug metabolism analysis.
The cells (3 × 107) were incubated with 1 µM
[3H]L-FMAU (14.5 µCi/mmol) at 37°C for
specific periods of the time in the presence or absence of dCyd
(20 µM) and/or dThd (20 µM) as a competitor. The metabolites were
extracted with perchloric acid and analyzed by HPLC by previously
described procedures (27). The intracellular nucleotide
concentration was normalized with the cell number and an internal
standard, acyclovir triphosphate.
Drug transport.
The inhibitor stop method was used in
transport studies (8, 14). A total of 4 × 105 2.2.15, HepG2, HeLa, or DU-145 cells were seeded per
35-mm dish, and the dishes were incubated for 48 h. The cells were
incubated with either NBMPR (0.3 nM to 20 µM), DPM (30 nM to 20 µM), or adenine (0.5 mM) at 37°C for 15 min prior to the transport
assays. [14C]dThd (53 mCi/mmol) was added to the cells
for times ranging from 2 to 30 s, and
5'-[3H]L-FMAU (200 mCi/mmol) was added for
times ranging from 2 s to 30 min. Transport was terminated by the
addition of ice-cold phosphate-buffered saline containing 20 µM DPM
and placing the dish on ice. The cells were then washed five times with
cold phosphate-buffered saline containing 20 µM DPM and were
solubilized with 1% Sarkosyl. The radioactivities were
determined in a liquid scintillation counter.
| |
RESULTS |
Inhibition of L-FMAU phosphorylation by natural
nucleosides.
In order to identify which nucleoside kinase could
potentially be responsible for the first step of phosphorylation of
L-FMAU, the effects of different natural nucleosides on
[3H]L-FMAU phosphorylation catalyzed by a
dialyzed crude HepG2 cell extract were examined. The fact that these
natural nucleosides could compete with
[3H]L-FMAU for phosphorylation indicated that
a unique kinase was used. As indicated in Fig.
1, dThd, a substrate of cytosolic dThd kinase and mitochondrial dPyd kinase, inhibited about 90% of
L-FMAU phosphorylation, while dCyd, a substrate of
cytosolic dCyd kinase and mitochondrial dPyd kinase, inhibited 60% of
L-FMAU phosphorylation. These data suggest that cytosolic
dThd kinase, cytosolic dCyd kinase, and mitochondrial dPyd kinase all
may play a role in the phosphorylation of L-FMAU. Although
deoxyadenosine (dAdo) and deoxyguanosine (dGuo) are substrates of
cytosolic dCyd kinase, L-FMAU phosphorylation was not
affected significantly by dAdo or dGuo. This observation could be due
to the poor binding affinity of dAdo and dGuo for cytosolic dCyd
kinase, the lack of action of dAdo and dGuo against mitochondrial dPyd
kinase, or the higher rate of catabolism of dAdo and dGuo by adenosine
deaminase and purine nucleoside phosphorylase, respectively, in the
crude HepG2 cell extract. Furthermore, the major enzyme for
L-FMAU phosphorylation in this crude extract is likely to
be cytosolic dThd kinase since dThd can inhibit most L-FMAU
phosphorylation.
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FIG. 1.
Effects of nucleosides on L-FMAU
phosphorylation by HepG2 cell extracts.
[3H]L-FMAU (100 µM) was phosphorylated with
dialyzed HepG2 cell extracts in the presence or absence of nucleosides
at 588 µM. The values are means ± standard deviations of three
determinations. Ado, adenosine; Cyd, cytidine; Guo, guanosine; Urd,
uridine; dAdo, deoxyadenosine; dGuo, deoxyguanosine; dUrd,
deoxyuridine.
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Behavior of L-FMAU toward cytosolic dThd kinase and
cytosolic dCyd kinase.
Both cytosolic dThd kinase and cytosolic
dCyd kinase were prepared as described above. The behavior of
L-FMAU as a substrate for those two enzymes was examined.
The results are depicted in Table 1. The
Km value of L-FMAU for cytosolic
dThd kinase was 18.3 µM, which is threefold greater than that of dThd
(Km = 6 µM). However, the
Vmax of L-FMAU was similar to that
of dThd. Therefore, the relative ratio of
Vmax/Km, which is often
used to indicate enzyme efficiency when the concentration of the
substrate used is relatively low in comparison with the
Km, for L-FMAU phosphorylation by
cytosolic dThd kinase was one-third that for dThd. To ensure that the
reaction studied was carried out by cytosolic dThd kinase and not by
some contaminating activity, the effects of dThd, a substrate, and
dTTP, an inhibitor of cytosolic dThd kinase, were examined. dThd was
found to be a competitive inhibitor of L-FMAU phosphorylation, with a Ki of 7 µM, while TTP
served as an inhibitor of L-FMAU phosphorylation,
with 50% inhibition occurring with L-FMAU at 4 µM
(Table 2).
The discovery that dCyd could inhibit
L-FMAU
phosphorylation in crude cell extracts suggested that dCyd kinase might
also
be able to phosphorylate
L-FMAU. The behavior of
L-FMAU as a substrate
for cytosolic dCyd kinase was
studied.
L-FMAU was phosphorylated
by cytosolic dCyd kinase
with a
Km of 1.1 mM, which is much higher
than
that of dCyd in the presence of ATP. However, the
Vmax of
L-FMAU was 12.5-fold higher
than that of dCyd. The
Vmax/
Km of
L-FMAU as a substrate for dCyd kinase was 14-fold lower
than that
of dCyd in the presence of ATP (Table
1). UTP has been shown
to be a good phosphate donor of cytosolic dCyd kinase. The
Km of
L-FMAU was determined to be
0.25 mM, and the
Vmax was determined
to be
8-fold that of dCyd when UTP was the phosphate donor. The
Vmax/
Km for
L-FMAU phosphorylation with UTP as a phosphate donor
was
4.7-fold lower than that for dCyd. In addition, the effects
of dCyd and
dCTP as inhibitors of
L-FMAU phosphorylation catalyzed
by
this enzyme were examined. dCyd was found to be an effective
competitive inhibitor of
L-FMAU phosphorylation, with a
Ki value
of 1.2 µM, while dCTP showed 50%
inhibition at 0.8 µM, as indicated
in Table
2.
Behavior of L-FMAU toward mitochondrial dPyd
kinase.
L-FMAU was also found to be a substrate for
mitochondrial dPyd kinase, with a Km value
higher than that of either dCyd or dThd (Km
values, 61, 33, and 7 µM, respectively). The relative Vmax of L-FMAU was also higher than
that of dCyd or dThd, as indicated in Table 1. Therefore, the
Vmax/Km for
L-FMAU phosphorylation by mitochondrial dPyd kinase was
about the same as that for dCyd and lower than that for dThd. dThd was
also shown to be a competitive inhibitor of L-FMAU
phosphorylation catalyzed by mitochondrial dPyd kinase, with a
Ki of 10.8 µM, while dCyd was a poor
inhibitor, with a Ki of >100 µM. Both TTP and
dCTP proved to be potent inhibitors of L-FMAU
phosphorylation, with 50% inhibitory concentrations of 12 and 6 µM,
respectively (Table 2).
Behavior of L-FMAU toward 5'-nucleotidase.
Since
cytosolic 5'-nucleotidase was shown to be responsible for the
intracellular phosphorylation of ddI, the ability of this enzyme to
phosphorylate L-FMAU was examined. Under the same reaction conditions, ddI was phosphorylated to ddIMP in the absence of ATP,
while no trace of L-FMAUMP formation was observed.
Therefore, it is unlikely that 5'-nucleotidase is able to phosphorylate
L-FMAU.
Inhibition of phosphorylation of L-FMAU by dThd and
dCyd in 2.2.15 cells.
The HBV-producing 2.2.15 cells were
incubated with 1 µM [3H]L-FMAU with and
without dCyd or dThd for 4 h. The metabolism of L-FMAU
was examined. With increasing dThd or dCyd concentrations, the
intracellular L-FMAU nucleotide concentrations dropped
sequentially. When a 20-fold excess of dCyd was added, the amount of
L-FMAU nucleotides dropped to ~60% of that of the
control. With a 20-fold excess of dThd present, the intracellular
L-FMAU nucleotide levels decreased to 40% of that of the
control, as indicated in Fig. 2. When
both dThd and dCyd were administered with
[3H]L-FMAU, the intracellular
L-FMAU nucleotide concentration decreased to 15% of that
of the control. The degree of inhibition with the combination of dCyd
and dThd is lower than that which is expected on the basis of the
enzyme studies. This could be due to some difference in enzyme behavior
in cells from that in the isolated form of the enzyme. These data are
consistent with the observation that both dCyd kinase and dThd kinase
could phosphorylate L-FMAU.
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FIG. 2.
L-FMAU metabolism in the presence of dThd,
dCyd, or both. Cells (3 × 107) were incubated with 1 µM [3H]L-FMAU (14.5 µCi/mmol) at 37°C
for 4 h in the absence or presence of 20 µM dThd, dCyd, or both.
The intracellular nucleotide concentrations were analyzed by HPLC as
described in Materials and Methods. CEM/dCK , cytosolic
dCyd kinase-deficient CEM cell line; HeLa Bu/TK,
cytosolic dThyd kinase-deficient HeLa cells;  , control; C,
deoxycytidine; T, thymidine; B, both.
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Phosphorylation of L-FMAU in cytosolic
CEM/dCK cells.
To ensure the role of dCyd kinase in
the phosphorylation of L-FMAU, CEM cells and CEM cytosolic
dCyd kinase-deficient (CEM/dCK) cells were compared with
respect to L-FMAU metabolism (Fig. 2). There was a decrease
in the amount of phosphorylated metabolites in CEM/dCK
cells in comparison with that in CEM cells. The phosphorylation of
L-FMAU in CEM/dCK cells could be due to
cytosolic dThd kinase and mitochondrial dPyd kinase in the cells. The
addition of dThd had a more pronounced effect on the inhibition of
L-FMAU phosphorylation in CEM/dCK cells.
Phosphorylation of L-FMAU in HeLa Bu cells.
The
metabolism of L-FMAU in the HeLa and the HeLa cytosolic
dThd kinase-deficient (HeLa Bu) cell lines was examined. The addition of dCyd had a more pronounced effect on the inhibition of
L-FMAU phosphorylation in HeLa Bu cells than in HeLa cells,
as indicated in Fig. 2. The phosphorylation of L-FMAU in
HeLa Bu cells could be due to the presence of cytosolic dCyd kinase and
mitochondrial dPyd kinase.
Transport behaviors of L-FMAU.
Since the
inhibition of L-FMAU phosphorylation by dThd or dCyd in
cells could partly be due to the competition with dThd and dCyd for
L-FMAU transport into cells, the transport of
L-FMAU into HepG2 cells was examined in the presence of the
nucleoside-facilitated diffusion inhibitors NBMPR and DPM.
[14C]dThd (56 mCi/mmol) was used to characterize the
nucleoside transport system in HepG2 cells. dThd transport was
inhibited by both DPM and NBMPR, with 50% inhibition occurring
at 1 and 20 nM, respectively, in a 30-s reaction (Fig.
3A). The transport of dThd was completely inhibited when DPM or NBMPR concentrations were higher than 1 µM.
This observation suggested that the equilibrative-sensitive system was
the only nucleoside transport system present in HepG2 cells. The
transport of L-FMAU was much slower than that of dThd. The rate of L-FMAU uptake is 60-fold less than that
of dThd uptake. L-FMAU uptake was sensitive to
inhibition by NBMPR, with 50% inhibition at 0.1 nM, while higher
concentrations of DPM (0.1 µM) were required to achieve the same
degree of inhibition (Fig. 3B). These data indicate that the
equilibrative-sensitive nucleoside transport system could also be used
for L-FMAU uptake by HepG2 cells. It was noted that neither
inhibitor could inhibit L-FMAU uptake 100%. Ten percent of
L-FMAU was still transported into HepG2 cells in the
presence of 20 µM DPM or NBMPR, while no dThd was found. When the
L-FMAU uptake study was performed at 4°C, similar amount
of uptake occurred. These results suggest that a passive diffusion mechanism could also play a role in L-FMAU uptake. Since
HepG2 cells used only the equilibrative-sensitive nucleoside transport system, other transport systems were examined in other cell lines.
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FIG. 3.
Characterization of human cellular L-FMAU
uptake system. (A) HepG2 cells were preincubated with either DPM ( )
or NBMPR (+) before the transport assay. Then, 3 µM
[14C]dThd (53 mCi/mmol) was added to the cells for
30 s and the transport was terminated as described in Materials
and Methods. (B) [3H]L-FMAU (10 µM; 200 mCi/mmol) was transported into DPM- or NBMPR-treated HepG2 cells for 30 min. (C) Transport of 3 µM [14C]dThd into HeLa cells.
(D) Transport of 10 µM [3H]L-FMAU into HeLa
cells.
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HeLa cells were reported to have two classes of nucleoside transport
systems, the equilibrative-sensitive system with high
affinity to NBMPR
and the equalibritive-insensitive system with
low affinity to NBMPR
(
8,
14). By using dThd as a control,
the dThd transport was
inhibited 40% at an NBMPR concentration
of 1 nM. The remaining 60% of
the dThd uptake remained insensitive
to NBMPR until the concentration
of NBMPR was elevated 1,000-fold
(Fig.
3C). This suggests that the
transport of dThd is approximately
40% through the
equilibrative-sensitive system and 60% through
the
equilibrative-insensitive system. The inhibition of
L-FMAU
uptake by NBMPR and DPM is similar to that of dThd (Fig.
3D).
These
observations suggest that
L-FMAU could also be transported
into HeLa cells through the equilibrative-insensitive system.
The nucleoside analog carbovir was shown to be a substrate for the
nucleobase carrier, which is inhibited by adenine. Therefore,
the
ability of adenine to inhibit
L-FMAU transport was also
examined
in DU-145 cells. [
3H]fluorouracil
([
3H]FU; 100 mCi/mmol) was used as a control for
nucleobase transport.
The transport of FU was inhibited in the presence
of adenine.
When the concentration of adenine was as high as 0.5 mM,
85% of
FU transport was inhibited, while no inhibition of
L-FMAU transport
was found. These data suggested that
L-FMAU is not a substrate
for the nucleobase transporter.
| |
DISCUSSION |
L-FMAU is the first thymidine analog shown to
have potent anti-HBV and anti-EBV activity in cell culture. This
spectrum of activity is different from those of other biologically
active L-dideoxythymidine analogs (2).
L-FMAUTP acts as a potent inhibitor of HBV DNA
polymerase with a Ki of 0.12 µM
(calculated from previously published data [21]). It cannot be used as a substrate by human 
,
, 
, and 
DNA polymerases. This may explain its
selective antiviral activity against HBV and its lack of
toxicity. In this report the enzymes responsible for the first step in
the phosphorylation of L-FMAU were identified. Unlike other
dThd or dCyd analogs, L-FMAU could be phosphorylated by
cytosolic dThd kinase, cytosolic dCyd kinase, and mitochondrial dPyrd
kinase as a substrate. The phosphorylation of L-FMAU
by those enzymes was also subject to inhibition by their feedback
inhibitors. When the efficiency
(Vmax/Km) of
L-FMAU as a substrate for all three enzymes was examined,
it was found to be within the same order of magnitude as those of the
natural substrates. Chou et al. (6) reported that
D-FMAU is a competitive inhibitor for the incorporation of
dThd and dCyd into DNA in mouse leukemia p815 cells and dThd in
cytosine arabinoside (Ara-C)-resistant p815/Ara-C cells. Although this
could suggest that D-FMAU is a substrate for both dThd
kinase and dCyd kinase, several other mechanisms could be
responsible for the observation, such as the competition of
D-FMAUTP with dTTP or dCTP at the DNA polymerase level. It would be interesting to determine whether D-FMAU
could also serve as a substrate for both cytosolic kinase and cytosolic dCyd kinase. Therefore, to the best of our knowledge,
L-FMAU is the first pyrimidine nucleoside analog shown to
be a substrate for all three cellular deoxypyrimidine nucleoside
kinases.
In order to further investigate whether L-FMAU could be
phosphorylated by cytosolic dCyd kinase or dThd kinase, we studied the
metabolism of L-FMAU in cells that lack these enzymes.
L-FMAU was phosphorylated less, but it was still
phosphorylated substantially in either enzyme-deficient cell line. dThd
and dCyd influenced the degree of L-FMAU phosphorylation in
those cell lines. The inhibition of L-FMAU phosphorylation
by dThd in cytosolic dCyd kinase-deficient cell lines than was more
pronounced than that in cells with all three enzymes. This is due to
the fact that cytosolic dThd kinase is the only major enzyme
responsible for L-FMAU phosphorylation in these cells.
Likewise, the phosphorylation of L-FMAU is much less
influenced by dCyd in HeLa cells than in HeLa Bu cells. This
observation is consistent with our enzyme studies in which the action
of dCyd and/or dThd on L-FMAU metabolism was studied in
HepG2 cells. Both dThd and dCyd could suppress L-FMAU
phosphorylation to some extent. However, the combination of dThd and
dCyd was the most effective.
Our concern in this cell culture study was that dThd or dCyd could
inhibit the transport of L-FMAU through the plasma cell membrane, resulting in the inhibition of L-FMAU
phosphorylation intracellularly if these compounds use the same
transport system. There are two facilitated transport systems,
equilibrative-sensitive and equilibrative-insensitive systems, for the
transport of nucleoside in culture cells. HepG2 cells have
predominately equilibrative-sensitive transporters, while
HeLa cells have 40% equilibrative-sensitive and 60%
equilibrative-insensitive transporters under the conditions used in
this study. We found that L-FMAU could use both
equilibrative-sensitive and equilibrative-insensitive facilitated
nucleoside transport systems. In addition, L-FMAU appears
to be able to enter cells via passive diffusion. Thus, the inhibition
of L-FMAU phosphorylation in HepG2 cells is the combined
effect of competition by dThd and/or dCyd for uptake as well as
competition for phosphorylation by cellular kinases.
In summary, as shown in Fig. 4,
L-FMAU is a unique nucleoside analog that can be recognized
as a substrate by all three nucleoside kinases. In vivo, it is likely
that cytosolic dCyd kinase is the major enzyme for phosphorylation in
the liver since the activities of both cytosolic dThd kinase and
mitochondrial dPyd kinase are low in comparison with the activity of
cytosolic dCyd kinase. It is not clear whether L-FMAU could
be taken into mitochondria to be phosphorylated, since this compound
does not interfere with mitochondrial function like its
D-FMAU enantiomer does. Thus, the ability of mitochondrial
dPyd nucleoside kinase to phosphorylate L-FMAU may not have
functional significance. This compound is in preclinical development
for the treatment of patients with HBV infection.
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|
FIG. 4.
Summary of L-FMAU metabolism in the cells.
ES, equilibrative-sensitive nucleoside transport system; EI,
equilibrative-insensitive nucleoside transport system; NB, nucleobase
transport system; Passive Diff., passive diffusion system; DP, DNA
polymerase. Arrows with solid line indicate the reactions that are
confirmed, while arrows with dashed lines indicate the reactions that
are unconfirmed.
|
|
| |
ACKNOWLEDGMENTS |
This work was supported by National Institutes of Health grants
AI33655 and AI 38204.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pharmacology, Yale University School of Medicine, Sterling Hall of
Medicine, 333 Cedar St., New Haven, CT 06510. Phone: (203) 785-7119. Fax: (203) 785-7129. E-mail: cheng.Lab{at}Yale.edu.
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Abstract
Introduction
