December
9, 2004 - Scientists at Johnson & Johnson Pharmaceutical
Research and Development (J&JPRD) have
identified a novel anti-tuberculosis (TB)
compound that works better and faster than
the current standard of care in mouse models
of TB infection. Also, preliminary studies
in healthy human volunteers show that the
drug is safe. The findings are published
in the December 9 issue of Science Express,
the online version of the journal Science,
and will be published in the January 14
print edition. The studies are reported
by scientists at J&JPRD and colleagues
at the Swedish Institute for Infectious
Disease Control in Solna, Sweden, and Pitié-Salpêtrière
School of Medicine in Paris, France.
The compound, called R207910, belongs
to a new family of anti-TB agents called
diarylquinolines (DARQ) and appears to
have better, and more differentiated
antibiotic properties than currently
used drugs for TB, individually and in
combination. R207910 was better at clearing
infection from the lungs of mice than
the triple cocktail regimen currently
recommended by the World Health Organization
(WHO). Also, cocktail regimens containing
R207910 cleared infection in mice in
half the time than the currently used
regimen.
“The drug acts through a novel
mechanism of action, and is therefore
active against all multi-drug resistant
(MDR) strains of TB tested so far,” says
Dr. Koen Andries, D.V.M., Ph.D., Distinguished
Research Fellow, Antimicrobial Research
at J&JPRD. “A combination including
R207910 but excluding rifampin, one of
the current TB drugs, looks especially
promising. A combination excluding rifampin
would be compatible with anti-HIV drugs,
making it suitable for treating patients
co-infected with HIV and TB.”
The World Health Organization (WHO)
has declared TB a global health crisis.
TB now infects one-third of the world's
population and causes close to nine million
new cases of active TB and 2 million
deaths each year. Unfortunately, many
TB strains have become resistant to several
antibiotics used today to treat the disease.
More than 300,000 new cases of multi-drug-resistant
TB per year are detected, mainly in Eastern
Europe and Central Asia.
“For a long time, there has been
a move to find a drug that is safe and
effective and completely cures the patient
in a shorter time,” Andries says. “A new
drug that could shorten or simplify effective
treatment of TB would dramatically improve
TB control programs.”
No new anti-TB drugs have been brought
into the clinic in the past 40 years,
and although doctors have effective first-line
TB drugs that work, there have been difficulties
getting these medicines to the patients
who need them as well as effectively
treating patients with drug resistant
disease.
One out of three people in the world
are infected with latent TB. Even in
the developed world, one out of twenty
carry the TB bacillus. In some developing
countries, one in two people are infected.
A carrier of latent TB has a 10 percent
life-long risk to develop TB. However,
in HIV patients, that risk is 10 percent
per year.
“That is the main reason why there
is now such a resurgence of tuberculosis
in countries that were previously hit
by HIV,” Andries says. “The
HIV epidemic has worsened the TB epidemic
substantially.”
TB is currently treated with a cocktail
of antibiotics, including rifampin, isoniazid,
and pyrazinamide, which must be taken
for six to nine months. The TB symptoms
disappear after several weeks, and patients
begin to feel healthy. However, to completely
clear the infection, they must continue
therapy at least four more months. This
is often difficult, especially for people
living in remote areas in developing
countries, and discontinuing treatment
prematurely increases the risk of developing
resistant bacteria.
To ensure compliance, TB patients are
monitored under the DOT (Directly Observed
Treatment) program, with patients taking
their cocktail of medicines each day
under the supervision of a healthcare
worker.
R207910 Study Findings
“Our findings suggest that at
least in mice, R207910 seems to have
the desired properties of simplifying
and shortening the treatment duration,
and perhaps, more,” says Andries.
In bacterial cell cultures, R207910 was
effective against many different strains
of mycobacteria, including strains that
are resistant to other drugs. The drug
is bactericidal, meaning that it kills
the TB bacilli.
In mouse models, the studies showed
that a cocktail regimen containing this
compound reduced bacterial load after
one month to the same level as the currently
used regimen after two months of treatment,
shortening normal treatment time by 50
percent. After two months treatment with
the R207910 containing cocktail, no TB
bacilli could be isolated from the lungs
anymore, a finding that the French group
that did those studies called “unprecedented”.
The mouse studies also show that this
new compound quickly enters the bloodstream
and is actually concentrated in lung
cells—which harbour the TB bacilli—killing
the bacilli soon after they enter the
body. Also, R207910 lingers in the body
for days continuing to kill bacilli even
when administered only once a week in
mice.
R207910 is unique in the way it works.
The compound attacks an enzyme called
ATP synthase, the energy source for the
bacterium. Given its new mechanism of
action and apparent impact on drug resistant
strains of TB, according to Andries,
R207910 could lead to a shift in the
current treatment paradigm for tuberculosis. “Preliminary
data show R207910 has the desired properties
we need and holds a great deal of promise,” he
said.
However, Koen added, considerable work
needs to be done to fully determine this
compound’s clinical potential.
Since the compound seems to be safe and
well tolerated in Phase I studies with
healthy human volunteers, R207910 will
now be tested in humans with active pulmonary
TB.
Dr. Andries’ coauthors are Peter
Verhasselt, Hinrich Göhlmann, Jean-Marc
Neefs, Hans Winkler, Jef Van Gestel,
Philip Timmerman, and Didier de Chaffoy
at Johnson & Johnson Pharmaceutical
Research and Development, LLC in Beerse,
Belgium; Jerome Guillemont at Johnson & Johnson
Pharmaceutical Research and Development
in Val de Reuil, France; Min Zhu at Johnson & Johnson
Pharmaceutical Research and Development,
LLC in Raritan, NJ; Ennis Lee, and Peter
Williams at Johnson & Johnson Pharmaceutical
Research and Development, LLC in High
Wycome, UK; Emma Huitric and Sven Hoffner
at Swedish Institute for Infectious Disease
Control in Solna, Sweden; Emmanuelle
Cambau, Chantal Truffot-Pernot, Nacer
Lounis, and Vincent Jarlier at Pitié-Salpêtrière
School of Medicine in Paris, France.
Nacer Lounis is currently at Johns Hopkins
University School of Medicine in Baltimore,
MD.
The study was supported by Johnson & Johnson
Pharmaceutical Research and Development,
and animal work in Paris was also supported
by annual grants from Association Française
Raoul Follereau, INSERM and, Ministère
de l’Education Nationale et de
la Recherche.
About R207910
A French chemist from the Johnson & Johnson
pharmaceutical group synthesised the
substance; and the team in Beerse, Belgium
discovered its anti-TB action. The compound
has been transferred to its sister company,
Tibotec, whose lead compounds are for
HIV/AIDS, for clinical development.
About Johnson & Johnson Pharmaceutical
Research & Development
Johnson & Johnson Pharmaceutical
Research & Development, (J&JPRD)
is part of Johnson & Johnson, the
world's most broad-based producer of
healthcare products. J&JPRD, with
its headquarters in Raritan, New Jersey
(USA), has sites throughout Europe and
the United States. J&JPRD leverages
drug discovery, drug evaluation, and
drug development in a variety of therapeutic
areas to address unmet medical needs
worldwide. The company's major therapeutic
areas of focus include hematology, oncology,
infectious disease, obesity and metabolic
disorders, neurology and psychiatry,
pain and women's health.
About Janssen Pharmaceutica N.V.
Janssen Pharmaceutica is a worldwide
Center of Excellence of integrated
R&D, production, and general services
within the Johnson & Johnson group.
In Belgium the company has premises
in Beerse, Geel and Olen employing
a total of 4,386 staff. With more than
80 drugs to its credit the company
is one of the most innovative worldwide,
and its products are used the world
over in both human and animal health
and in material protection.
About Tibotec
Tibotec is a pharmaceutical research
and development company with headquarters
in Belgium and operating subsidiaries
in the United States and Ireland. The
company, like J&JPRD, is a subsidiary
of Johnson & Johnson. Tibotec's
lead development compounds are for
the treatment of HIV/AIDS and the pandemics
of TB and HIV/AIDS are closely intertwined.
Drug interactions between HIV/AIDS
drugs and TB drugs are particularly
problematic.
(This press release
contains "forward-looking
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Securities Litigation Reform Act of 1995.
These statements are based on current
expectations of future events. If underlying
assumptions prove inaccurate or unknown
risks or uncertainties materialize, actual
results could vary materially from the
Company's expectations and projections.
Risks and uncertainties include general
industry conditions and competition;
economic conditions, such as interest
rate and currency exchange rate fluctuations;
technological advances and patents attained
by competitors; challenges inherent in
new product development, including obtaining
regulatory approvals; domestic and foreign
health care reforms and governmental
laws and regulations; and trends toward
health care cost containment. A further
list and description of these risks,
uncertainties and other factors can be
found in Exhibit 99(b) of the Company's
Annual Report on Form 10-K for the fiscal
year ended December 28, 2003. Copies
of this Form 10-K are available online
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to update any forward-looking statements
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