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 Emerging Infectious Diseases * Volume 3 * Number 1 * January-March 1997
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Synopses

Fluoroquinolone Resistance in Neisseria gonorrhoeae

Joan S. Knapp,* Kimberley K. Fox,* David L. Trees,* and William L.
Whittington†
*Centers for Disease Control and Prevention, Atlanta, Georgia, USA
†Center for AIDS and STD, University of Washington, Seattle, Washington,
USA
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      Fluoroquinolones and broad-spectrum cephalosporins are the
      most effective antimicrobial agents for the treatment of
      gonorrhea. However, clinically significant resistance to
      fluoroquinolones has emerged in Neisseria gonorrhoeae.
      Fluoroquinolone-resistant strains account for approximately
      10% of all gonococcal strains in Hong Kong and the Republic of
      the Philippines. As many as 50% of strains from some Far
      Eastern countries exhibit decreased susceptibility
      (intermediate resistance) to fluoroquinolones. Strains with
      intermediate resistance and clinically significant resistance
      are being isolated sporadically in North America, where
      resistant strains have been associated with an outbreak and
      with failure of infections to respond to treatment with doses
      of ciprofloxacin and ofloxacin recommended by the Centers for
      Disease Control and Prevention; strains exhibiting decreased
      susceptibility to these agents are endemic in at least one
      metropolitan area. Monitoring for fluoroquinolone resistance
      is now critical for ensuring adequate treatment of infections
      with resistant strains and for maximizing the time during
      which fluoroquinolones may be used to treat gonorrhea.

Gonorrhea is among the most prevalent sexually transmitted diseases
throughout much of the world. The emergence of resistance to antimicrobial
agents in Neisseria gonorrhoeae is a major obstacle in the control of
gonorrhea. In 1989 and 1993, in response to the increasing frequency of
isolation of penicillin-, tetracycline-, and spectinomycin-resistant
strains of N. gonorrhoeae in the United States, the Centers for Disease
Control and Prevention (CDC) recommended the use of broad-spectrum
cephalosporins or fluoroquinolones for the primary treatment of
uncomplicated gonorrhea (1,2). However, resistance to fluoroquinolones has
now emerged in N. gonorrhoeae (3-8). Because ciprofloxacin and ofloxacin
are more frequently used to treat gonorrhea than other fluoroquinolones,
this synopsis will focus on these agents.

Fluoroquinolone Therapeutic Regimens, Therapy Failure, and Susceptibility
Tests

In 1993, CDC recommended single-dose, oral therapy with ciprofloxacin (500
mg) or ofloxacin (400 mg) as two of the primary regimens for the treatment
of uncomplicated gonorrhea (2). Enoxacin (400 mg), lomefloxacin (400 mg),
and norfloxacin (800 mg) were recommended among alternative regimens (2).
In some countries, gonococcal infections have been treated with a single,
orally administered dose of 250 mg ciprofloxacin (8). The failure of
gonococcal infections to respond to treatment with 250 mg ciprofloxacin has
been reported in the United Kingdom since 1990 (8-11). The failure of
infections to respond to single-dose therapy with 500 mg ciprofloxacin or
400 mg ofloxacin has been reported in the United Kingdom, Australia,
Canada, Hong Kong, and the United States (3-7,12).

Different methods for determining in vitro antimicrobial susceptibilities
of N. gonorrhoeae have been developed in several countries. Differences
between these methods—the medium on which the susceptibilities are
determined, the concentrations of antimicrobial agents tested, the
concentration of antimicrobial agents in disks used to determine zone
inhibition diameters, or the inoculum size—complicate the interpretation of
susceptibility test results. For example, in the United Kingdom, Australia,
and Hong Kong, susceptibilities are usually determined on Isosensitest
medium (Oxoid, Basingstoke, United Kingdom) (3,8,13-15). In the United
States (where criteria for interpreting susceptibilities of N. gonorrhoeae
are established by the National Committee for Clinical Laboratory Standards
[NCCLS]) and Canada, susceptibilities are determined on a Difco or Becton
Dickinson base medium (Difco Laboratories, Detroit, MI; Becton Dickinson,
Cockeysville, MD) (16-19). Antimicrobial susceptibilities determined on
Oxoid base medium may be one concentration lower than those determined on
supplemented Difco or Becton Dickinson base media (15). Neither method is
right or wrong; nor is one method better than the other; they are
different. The method used in different countries is influenced by the
commercial availability of the base medium. Thus, criteria for interpreting
susceptibilities in the United States and Canada may differ slightly from
those used to interpret susceptibilities in the United Kingdom, Australia,
and Hong Kong, reflecting the difference in susceptibilities obtained on
different media. Similarly, when susceptibilities are measured on media
different from those described above it may be necessary to establish
"local" criteria using reference strains with known susceptibilities.

Gonococcal strains associated with therapy failure to 250 mg ciprofloxacin
have had minimum inhibitory concentrations (MICs) of  >= 0.06 to 0.25 µg/ml
of ciprofloxacin (8,11); posttreatment strains from infections that failed
to respond to treatment with 500 mg ciprofloxacin or 400 mg ofloxacin have
had MICs  >= 1.0 µg/ml and  >= 2.0 µg/ml, respectively (4-6,12,15).

Criteria for Interpreting Fluoroquinolone Resistance

Before the emergence of fluoroquinolone resistance in N. gonorrhoeae, NCCLS
established interpretive criteria to differentiate between susceptible
strains and those exhibiting decreased susceptibility to selected
fluoroquinolones including ciprofloxacin, ofloxacin, lomefloxacin, and
enoxacin (16,17). Criteria for the interpretation of clinically significant
resistance of gonococcal strains to 500 mg ciprofloxacin and 400 mg
ofloxacin have been proposed (6,18).

Criteria for interpreting susceptibilities of N. gonorrhoeae to
antimicrobial agents should be based on treatment outcome and strain
susceptibility data. However, because many infections caused by
fluoroquinolone-resistant strains were treated with broad-spectrum
cephalosporins and few observations linked fluoroquinolone therapy outcome
and antimicrobial susceptibilities (MICs), CDC proposed criteria for
interpreting fluoroquinolone resistance in N. gonorrhoeae that were based
on theoretical predictions of the MICs at which gonococcal infections may
fail to respond to CDC-recommended doses of selected fluoroquinolones (18).
On the basis of the therapeutic index (calculated by dividing the peak
level of the agent in serum by the MIC of the infecting strain), CDC
proposed criteria for interpreting susceptibilities to selected
fluoroquinolones (Table) (18,20). These criteria were consistent with the
MICs of isolates from the observed treatment failures to 500 mg
ciprofloxacin and 400 mg ofloxacin documented at the time of the study
(4,5,12). Recently, Kam et al. proposed interpretive criteria based on the
susceptibilities of many strains that did not respond to treatment with
ofloxacin in Hong Kong (Table) (6). CDC and Kam et al. proposed identical
MICs for interpreting resistance to ciprofloxacin and ofloxacin: MICs of
 >= 2.0 µg/ml and  >= 1.0 µg/ml of ofloxacin and ciprofloxacin,
respectively. These criteria have also been adopted in Australia (15).

 Table. Criteria for interpreting susceptibilities of Neisseria gonorrhoeae
 strains to the fluoroquinolones ciprofloxacin, ofloxacin, enoxacin,
 lomefloxacin, and norfloxacina,b

 --------------------------------------------------------------------------------
  Therapeutic    Agent    Zone Inhibition    Equivalent MICc (mg/ml)   Reference
     agent,     Tested,      Diametersc
      Dose       Disk     nearest whole mm
               Content
                 (µg)      R     I     S       R        I        S
 --------------------------------------------------------------------------------
 Ciprofloxacin,          <= 24               >= 0.03
 250 mg        Cip, 1                                                  8
 Ciprofloxacin,          <= 29        >= 36  >= 1.0           <= 0.06
 500 mg        Cip, 5          30-35                0.13-0.5           18

               Cip, 5    <= 22               >= 1.0                    6

 Ofloxacin, 400          <= 24        >= 31  >= 2.0           <= 0.25
 mg            Ofx, 5          25-30                0.5-1.0            18

               Ofx, 5    <= 24               >= 1.0                    6

 Enoxacin, 400           <= 31        >= 32  >= 1.0           <= 0.25
 mg            Enx, 10                              0.5                18
 Lomefloxacin,           <= 26        >= 36  >= 2.0           <= 0.125
 400 mg        Lom, 10         27-35                0.25-1.0           18
 Norfloxacin,            <= 32        >= 36  >= 1.0           <= 0.25
 800 mg        Nor, 5          33-35                0.5                18
 --------------------------------------------------------------------------------
 aThese criteria have not been recommended by the National Committee for
 Clinical Laboratory Standards (NCCLS); they are provided to guide
 interpretation of susceptibilities until the NCCLS establishes criteria.
 bAbbreviations: MIC, minimal inhibitory concentration (µg/ml); R, resistant; I,
 intermediate resistance; S, susceptible; Cip, ciprofloxacin; Ofx, ofoxacin;
 Enx, enoxacin; Lom, lomefloxacin; Nor, norfloxacin.
 cWith the exception of norfloxacin, criteria for the susceptible categories are
 those designated by the NCCLS (16,17); criteria for the interpretation of the
 susceptible category for norfloxacin were proposed by CDC (18).

In the United Kingdom, where 250 mg ciprofloxacin has been used to treat
gonorrhea, strains with MICs of 0.06 to 0.25 µg/ml have been isolated from
infections that did not respond to treatment (8,11). Ciprofloxacin in a
250-mg dose produces a peak serum level of approximately 1.2 µg/ml; thus,
strains with MICs of  >= 0.25 to 0.5 µg/ml would produce therapeutic
indices of 4.8:1 and 2.4:1, respectively. These calculated MICs suggest
that strains with MICs >= 0.25 µg/ml should be considered resistant to
treatment with 250 mg ciprofloxacin. Criteria for interpreting
susceptibilities of gonococcal strains to treatment with 250 mg
ciprofloxacin have been determined to ciprofloxacin (1 µg disks) or
nalidixic acid (30 µg disks) (10,21). Measurement of nalidixic acid
resistance may be useful for detecting strains causing infections that may
not respond to treatment with 250 mg ciprofloxacin. However, because
naladixic acid-resistance indicates decreased susceptibility to
ciprofloxacin and ofloxacin, this test does not differentiate between
strains with intermediate resistance and clinically significant resistance
to treatment with 500 mg ciprofloxacin or 400 mg ofloxacin (18).

Geographic Distribution, Frequency, and Diversity of
Fluoroquinolone-resistant N. gonorrhoeae

Strains exhibiting intermediate resistance (MICs 0.125 to 0.5 µg/ml of
ciprofloxacin; MICs 0.5-1.0 µg/ml of ofloxacin) have been reported from
many geographic areas including Australia, Canada, the Canary Islands, Hong
Kong, Japan, the Republic of the Philippines, mainland Spain, Thailand, the
United Kingdom, the United States, and the West Indies (4,7,9-15,21-32).
Fluoroquinolone resistance (MICs of  >= 1.0 µg/ml or  >= 2.0 µg/ml of
ciprofloxacin or ofloxacin, respectively) has been reported most frequently
from the Far East, Republic of the Philippines, Hong Kong, Japan) and less
frequently from Australia, Canada, Spain, Thailand, United Kingdom, and the
United States (3,4,6,7,9,12,15,22-32). Ofloxacin- and
ciprofloxacin-resistant strains had been isolated sporadically in Hong
Kong, the Republic of the Philippines, and Thailand for some years (22-24).
The frequency of fluoroquinolone-resistant strains has increased
dramatically since the early 1990s. For example, in Hong Kong,
fluoroquinolone-resistant strains were isolated intermittently during 1990
to 1992 (13) but have increased dramatically from an estimated 0.5% in late
1992 to 10.4% in late 1994 (14).

From 1994 to 1995, strains exhibiting decreased susceptibility to
ciprofloxacin and ofloxacin accounted for approximately 36%, 54%, and 22%
of strains in Hong Kong, the Republic of the Philippines, and Thailand,
respectively (13,14,29,31,32). During the same period,
fluoroquinolone-resistant strains accounted for approximately 10%, 12%, and
1% of all strains in Hong Kong, the Republic of the Philippines, and
Thailand, respectively (13,14,29,31,32). Strains with ciprofloxacin MICs of
 >= 8.0 µg/ml were first isolated in 1994 (10,12,29,31).

In other geographic areas, strains exhibiting intermediate resistance and
resistance have been isolated only sporadically, although with increasing
frequency. In Sydney, Australia, fluoroquinolone-resistant strains were
isolated infrequently in 1991 to 1994, but with dramatically increasing
frequency in early 1995 (15). The pattern of isolation of
fluoroquinolone-resistant strains in Australia, i.e., infrequent and
sporadic isolations for a number of years followed by increasing frequency
of isolation over a short period, may be anticipated in other countries
unless the fluoroquinolone-resistant strains are controlled in the Far
East, where they are now prevalent. In the CDC-sponsored Gonococcal Isolate
Surveillance Project in the United States, the frequency of strains with
intermediate resistance has increased significantly from 0.3% (17/5,238) in
1991 to 1.3% (65/4,996) in 1994 (p <= 0.001); however, resistant strains
accounted for only 0.04% (2/4,996) of strains in 1994 (33,34). In the
United States, the increase in strains with intermediate resistance is
associated largely, but not exclusively, with the persistence of such
strains in Cleveland, Ohio. First detected in 1992, these strains accounted
for 16% to 17.5% of isolates in Cleveland in 1994 (26,35). In addition, a
sustained outbreak caused by ciprofloxacin-resistant strains has been
reported from Seattle, Washington, in 1995; these strains had MICs of 8.0
µg/ml of ciprofloxacin and ofloxacin (5).

Many different strains, as defined by penicillin/tetracycline resistance
phenotype and auxotype/serovar (A/S) class, exhibit intermediate resistance
and resistance to fluoroquinolones (4,5,15,25,26,31,32,36). Fluoroquinolone
resistance has been identified frequently in strains that produce
ß-lactamase and strains exhibiting chromosomally mediated resistance to
penicillin and tetracycline and less frequently in strains that are
susceptible to penicillin and tetracycline (4,31,32). Fluoroquinolone
resistance has not been documented in strains possessing the
25.2-megadalton TetM-containing plasmid (TRNG) alone or in TRNG strains
possessing a ß-lactamase plasmid (31). It should not, however, be assumed
that these strains may not develop fluoroquinolone resistance, but rather
that resistant strains have not been detected at this time. Many strains,
as defined by A/S class, are associated with fluoroquinolone resistance;
fluoroquinolone resistance is not associated with the epidemic spread of
one or two strains (15,31,32). In Australia, strains exhibiting
intermediate resistance and resistance to fluoroquinolones have belonged to
27 different A/S classes; strains with MICs 8.0-16.0 µg/ml of ciprofloxacin
have belonged to 6 A/S classes (15). In the Republic of the Philippines,
strains belonging to 27 A/S classes exhibited decreased susceptibility to
ciprofloxacin; strains belonging to 10 A/S classes had MICs  >= 1.0 µg/ml
of ciprofloxacin (31). In Thailand, strains belonging to 13 A/S classes
exhibited decreased susceptibility to ciprofloxacin (32).

The Gonococcal Isolate Surveillance Project monitors the susceptibilities
of N. gonorrhoeae isolates to fluoroquinolones in the United States and
provides prototype reference strains for quality assurance of
susceptibility testing of these agents. Information about antimicrobial
resistance in N. gonorrhoeae in the United States is available on the
Internet at http://www.cdc.gov/ncidod/dastlr/gcdir/gono.html.

Mechanisms of Resistance to Fluoroquinolones

Fluoroquinolones inhibit the replication of DNA; they are believed to bind
to the GyrA region of DNA gyrase, which is attached to DNA, and inhibit the
enzyme from supercoiling the DNA (37). Resistance to fluoroquinolones in N.
gonorrhoeae is associated with mutations that result in amino acid changes
in the A subunit (GyrA) and the B subunit (GyrB) of the DNA gyrase, and in
the parC-encoded subunit of topoisomerase IV (37-40). Although mutations in
gyrB confer low-level resistance to naladixic acid, high-level quinolone
resistance is associated with mutations in the quinolone
resistance-determining region of gyrA (41). Topoisomerase IV, encoded by
parC and parE in Escherichia coli and believed to be located in the
cytoplasmic membrane, is involved in DNA replication but is not as
sensitive to fluoroquinolone inhibition as is DNA gyrase (37). No parE
analog has been detected in N. gonorrhoeae (37). Mutations in gyrA and parC
are most relevant when considering clinically significant levels of
fluoroquinolone resistance in N. gonorrhoeae (37,39,40). Similar results
have been obtained in studies of gyrA mutations in both laboratory-adapted
strains and clinical isolates (37,39,40): ciprofloxacin-susceptible strains
(MICs, <0.03 µg/ml) had no mutations in gyrA and strains with MICs, >= 0.5
µg/ml of ciprofloxacin may have changes in nucleotides 272 and 283 of gyrA.
In addition, strains with MICs  >= 2.0 had mutations in parC. Mutations in
parC were observed only in strains with at least one mutation in gyrA
(37,39) and appeared to be associated with an MIC higher than would be
expected with the gyrA mutation alone (39). Mutations in gyrA and parC may
be characterized by polymerase chain reaction and DNA sequencing (37,39).
The transfer of gyrA and parC mutations between gonococcal strains has been
demonstrated in vitro (37). The presence of transformation sequences just
downstream from the gyrA sequences suggests that transformation may play a
role in the spread of gyrA mutations between gonococcal strains in vivo
(37). The opportunity for transformation of genes between gonococcal
strains, which depends on concurrent infections with multiple strains, has
been documented for women and homosexual men (42,43).

In addition to mutations in gyrA and parC, reduced permeability of the
cytoplasmic membrane may contribute to low-level resistance to
fluoroquinolones in N. gonorrhoeae, e.g., increasing the MIC of one
recipient strain from  <= 0.002 to 0.06 µg/ml of ciprofloxacin (3,44). This
resistance may also be transferred between gonococcal strains by
transformation (3).

Guidance

Continued reports of the isolation of fluoroquinolone-resistant strains of
N. gonorrhoeae indicate the need for heightened awareness of the potential
for increasing prevalence of strains with clinically significant
fluoroquinolone resistance. In areas where a fluoroquinolone is used to
treat gonorrhea, the following steps are recommended to monitor and control
the spread of fluoroquinolone-resistant strains of N. gonorrhoeae.

  1. Susceptibility testing should be performed to detect fluoroquinolone
     resistant strains. In geographic areas where interpretive criteria
     have not been proposed, criteria should be developed for results
     obtained with local test procedures that use strains with known
     susceptibilities to ciprofloxacin or ofloxacin.
  2. Ideally, routine surveillance for emerging fluoroquinolone resistance
     should be performed in centers where fluoroquinolones are used widely
     to treat gonorrhea; e.g., a sample of approximately 20 to 50
     consecutive isolates should be tested periodically. If
     ciprofloxacin-resistant isolates are detected, the use of alternative
     therapies for gonorrhea should be considered; if isolates are
     ciprofloxacin-susceptible, ciprofloxacin or ofloxacin may be used to
     treat gonorrhea.
  3. Susceptibilities of isolates from individual patients whose infections
     did not respond to treatment with a fluoroquinolone should be
     determined.
  4. A cluster of infections unresponsive to fluoroquinolone therapy may
     indicate an outbreak caused by a resistant strain.
  5. If treating gonorrhea with a fluoroquinolone, e.g., ciprofloxacin or
     ofloxacin, never use less than the recommended dose. In the United
     States, 500 mg of ciprofloxacin or 400 mg ofloxacin should be used.
  6. Because gonococcal infections caused by fluoroquinolone-resistant
     strains have been acquired frequently in the Far East, clinicians may
     wish to treat infections possibly acquired in the Far East with 125 mg
     ceftriaxone, intramuscularly, or 400 mg cefixime, orally, the current
     CDC-recommended doses for treating gonococcal infections.

The importance of the emergence and spread of fluoroquinolone resistance in
N. gonorrhoeae cannot be overstated. Of antimicrobial agents available for
treating gonorrhea, broad-spectrum cephalosporins are the only agents to
which N. gonorrhoeae is not resistant, and exclusive use of these agents,
particularly the orally administered cephalosporins such as cefixime, may
result ultimately in the emergence of resistance to these agents. Thus, it
is critical to take measures to ensure that fluoroquinolones remain
effective for the treatment of uncomplicated gonorrhea for as long as
possible.

Dr. Knapp is chief, Gonorrhea, Chlamydia, and Chancroid Branch, Division of
AIDS, STD, and TB Laboratory Research, National Center for Infectious
Diseases, CDC. Her research interests are antimicrobial resistance in N.
gonorrhoeae, the molecular epidemiology of gonococcal strain populations,
and the taxonomy of Neisseria spp.

Address for correspondence: Joan S. Knapp, Ph.D., Centers for Disease
Control and Prevention, 1600 Clifton Road NE, MS G39, Atlanta, GA 30333,
USA; fax: 404-639-3976; e-mail: jsk2@cdc.gov.

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Emerging Infectious Diseases
National Center for Infectious Diseases
Centers for Disease Control and Prevention
Atlanta, GA