Pulmonary Tuberculosis Clinical Trial
Official title:
Relationship Between TLR2 Polymorphism and Pulmonary Tuberculosis
Infection with Mycobacterium tuberculosis remains at epidemic levels globally. Innate and
adaptive immune responses evolve as protective mechanisms against mycobacterial infection in
humans. Toll-like receptors (TLRs) are transmembrane proteins characterized by an
extracellular leucine-rich domain that participates in ligand recognition and an
intracellular tail. TLRs are the first defense system to detect potential pathogens,
initiate immune responses and form the crucial link between innate and adaptive immune
systems. Stimulation of TLR initiates a signaling cascade that involves a number of
proteins, such as MyD88 and IL-1 receptor-associated kinase. This signal cascade leads to
NF-κB activation, which induce the secretion of pro-inflammatory cytokines.
TLR2 is a family of TLR family and has been reported to be the principle mediator of
macrophage activation in response to mycobacterium. Growing amounts of data suggest that the
ability of certain individuals to respond properly to TLR ligands may be impaired by single
nucleotide polymorphisms (SNPs) within TLR genes, resulting in an altered susceptibility to,
or course of, infectious disease. The genetic polymorphism of TLR2 (arginine to glutamine
substitution at residue 753 (Arg753Gln)) has been associated with a negative influence on
TLR2 function, which may, in turn, determine the innate host response to mycobacteria. In
addition, another polymorphism (Arg677Trp) of the TLR2 was reported to be associated with
susceptibility to tuberculosis in Tunisian patients. Moreover, in Mycobacterium leprosy
patients with TLR2 mutation (Arg677Trp), production of IL-2, IL-12, IFN-gamma, and TNF-alpha
by M. leprae-stimulated peripheral blood mononuclear cell were decreased compared with that
in groups with wild-type TLR2.
To date, there have been no studies of the association of SNPs of TLR2 with cytokine
profiles and clinical outcomes on M. tuberculosis. We hypothesize that polymorphisms in the
TLR2 are associated with :
1. increased prevalence of active pulmonary TB infection,
2. altered levels of pro-inflammatory and anti-inflammatory cytokines in serum,
3. clinical outcomes and presentations. We thus design a prospective case-control study to
test this hypothesis. The frequency of TLR2 polymorphisms in both pulmonary TB patients
and healthy controls will be determined by polymerase chain reaction-restriction
fragment length polymorphism. Serial serum levels of IL-12, IFN-γ, and IL-10 in
pulmonary TB patients with or without TLR2 polymorphisms will be measured by enzyme
linked immunosorbent assay. Relationships between TLR2 polymorphisms and serum
cytokines dynamics or clinical outcomes will be analyzed.
Infection with Mycobacterium tuberculosis (TB) remains at epidemic levels globally. One
third of the word's population is infected with this organism, making tuberculosis the most
prevalent infectious disease. Annually, 8 million people contract the disease, and there are
2 million deaths worldwide each year, with increasing prevalence predicted over the next
several decades.(1) In Taiwan, there are 24,161 reporting cases registered in the national
tuberculosis database, and 17,660 were diagnosed as confirmed TB cases in 2004. The annual
incidence rate of newly TB cases is 74.11 per 100,000 people.
Immunity Against Mycobacteria M. tuberculosis is a unique pathogen in that once infection
occurs, even in the face of in intact host immune system it is not eradicated but
establishes a chronically persistent, or latent, state. Viable organisms remain sequestered
by the host's immune system, though they fail to progressively replicate. Subsequently, in
approximately 15 % of those latently infected, the infection may reactivate with the
development of overt, progressive, pulmonary disease. Impairments in the immune system may
linked to reactivation, but much remains to be discovered about control of infection by M.
tuberculosis.
Innate and adaptive immune responses evolve as protective mechanisms against infectious
organisms in humans. Phagocytosis of relatively small numbers of organisms initiated the
host response in the alveolar cells.CD14 and toll-like receptors (TLRs) are examples of
pattern recognition receptors that detect antigenic molecules on the surface of bacteria and
mycobacteria.(2) The family of TLRs is capable of recognizing conserved microbial patterns
including components of bacterial cell wall, microbial nucleic acids, and bacterial
motility. TLRs are the first defense system to detect potential pathogens, initiate immune
responses and form the crucial link between innate and adaptive immune systems. TLRs also
play an import role in the pathophysiology of infectious diseases, inflammatory diseases
such as Crohn's disease and atherosclerosis, possibly play a role in autoimmune disease.( 3)
TLRs are transmembrane proteins characterized by an extracellular leucine-rich domain that
participates in ligand recognition and an intracellular tail that contains a conserved
region called the Toll interleukin 1 receptor (IL-1R) homology domain.(4) Stimulation of TLR
initiates a signaling cascade that involves a number of proteins, such as MyD88 and IL-1
receptor-associated kinase.(5) This signal cascade leads to NF-κB activation, which induce
the secretion of pro-inflammatory cytokines. TLR2 has been reported to be the principle
mediator of macrophage activation in response to mycobacteria. TLR2 expression is found
primarily on alveolar macrophages and epithelial cells type Ⅱwithin tuberculous granulomas.
Due to its ability to recognize Mycobacterium tuberculosis and its components, the
expression of TLR2 at the site of disease is critical. (6, 7)
Single nucleotide polymorphisms of Toll-like receptors and susceptibility to pulmonary
tuberculosis Growing amounts of data suggest that the ability of certain individuals to
respond properly to TLR ligands may be impaired by single nucleotide polymorphisms (SNPs)
within TLR genes, resulting in an altered susceptibility to, or course of, infectious
disease.TLR2 is a member of the TLR family.(8) Animal studies have shown that TLR2-knockout
mice are more susceptible to septicemia due to Staphylococcus and Listeria monocytogenes,
meningitis due to Streptococcus pneumoniae, and infection with Mycobacterium tuberculosis,
suggesting the functional TLR2 polymorphisms may impair host response to a certain spectrum
of microbial pathogens.(9) Mycobacterium tuberculosis infects 2 billion people globally, yet
only 10 % develop clinical disease. The identification of factors that predispose to disease
could aid the development of new therapies and vaccines.
The genetic polymorphism of TLR2 (arginine to glutamine substitution at residue 753
(Arg753Gln)) has been associated with a negative influence on TLR2 function, which may, in
turn, determine the innate host response to mycobacteria. In a recent cohort study, this
polymorphism was demonstrated to influence the risk of developing tuberculosis in Turkey
patients.(10) In addition, another polymorphism (Arg677Trp) of the TLR2 was reported to be
associated with susceptibility to tuberculosis in Tunisian patients (11), as well as
lepromatous leprosy(12). More recently, polymorphisms in CD 14 and TLR2 are demonstrated to
be associated with increased prevalence of infection in critical ill adults (13). TLR2 gene
Arg753Lin polymorphism is also strongly associated with rheumatic fever in children.
Moreover, this polymorphism is a risk factor for coronary restenosis.(14)
Dynamics of cytokine generation by inflammatory cells and clinical outcomes TLRs mediate the
activation of cells of the innate immune system leading to dynamic functions including
direct anti-microbial activity, induction of cytokine secretion, triggering dendritic cell
maturation, and triggering apoptosis. Macrophage phagocytosis of M. tuberculosis is
accompanied by activation of the transcription factor NF-κB and secretion of inflammatory
mediators that play an important role in granuloma formation and immune protection. Once
antigen-presenting cells (alveolar macrophage or dendritic cell) have processed the engulfed
mycobacterial protein, they present the antigens in the context of major histocompatibility
complex (MHC) class Ⅱ surface molecules to naïve CD4+ lymphocytes. The antigen-presenting
cell produce IL-12 to bias the immune reaction to T helper 1 (Th1) and IL-1, which stimulate
the CD4+ lymphocytes to produce IL-2. The net result is the rapid clonal expansion of
specific CD4+ Th1 lymphocyte, which produce interferon gamma (IFNγ), a cytokine that
activate the macrophage that have engulfed mycobacteria to become mycobactericidal. It has
been demonstrated that a 19-kDa lipoprotein of M.tb triggered cells to activate NF-κB and
secret IL-2 in a TLR-2 dependent pathway(15).On the other hand, The Th2 cytokines may play
roles in mycobacterial inflammation as well. IL-10, produced by monocytes, macrophage, and
lymphocytes, is upregulated after mycobacterail infection, and downregulates IFN-γ
production. Secretion of IL-10 will favor the activation of a Th2 response which is
incapable of destroying intracellular pathogens. Activation of human monocyte derived
dendritic cells with M.tb 19 kDa lipoprotein results in the preferential secretion of IL-12
over IL-10 (16, 17).
The balance between IFN-γ and IL-10 production may determine wheather effective immunity is
established or anergy supervenes in any infected patient, and may influence clinical
outcome. Levels of IFN-γ are higher in moderate disease than advanced diaseses, whereas
advanced cases showed higher IL-12, and TNF-alpha compared with cases of moderate TB. In
most patients, decreased interferon-γ production by PBMC seems to be a transient response
because it is significantly increased in most active TB patients during and following
successful therapy. In the TB patients with a systemic reaction, both IL-12 and
IFN-γproduction by monocytes after challenge with a virulent M.tb strain were significantly
reduced compared to PPD reactor group. Bronchoalveolar lavarge fluid levels of IFN-γ was
also correlated with disease grading and decreased after anti-TB chemotherapy(18).However,
some patients remain anergic in vivo and in vitro after chemotherapy, and the underlying
biochemical mechanisms for T cell anergy in modulating protection or pathology in TB needs
further clarification.(19)
Toll-like receptor 2 mutation and the profiles of cytokines The production of IL-6 and IL-10
from dendritic cells in response to M.tuberculosis is principally dependent on TLR2 (20). On
the other hand, M. tuberculosis can induce IL-12 production in the absence of either TLR2 or
TLR4. In leprosy patients with TLR2 mutation (Arg677Trp), production of IL-2, IL-12,
IFN-gamma, and TNF-alpha by M. leprae-stimulated peripheral blood mononuclear cell were
decreased compared with that in groups with wild-type TLR2. However the cells from patients
with the TLR2 mutation showed significantly increased production of IL-10. These results
suggest that TLR2 signal pathway plays a critical role in the alteration of cytokine
profiles in PBMC from patients with mycobacterial infection. ( 21)
In summary, TLR2 polymorphisms have been shown to be associated with susceptibility to
tuberculosis in Turkey and Tunisian people. These polymorphisms have been demonstrated to
affect cytokine production by monocytes in vitro. To date, there have been no studies of the
association of SNPs of TLR2 with serum cytokine profiles and clinical outcomes on M.
tuberculosis infection. We hypothesize that polymorphisms in the TLR2 are associated with :
1. increased prevalence of active pulmonary TB infection,
2. altered levels of pro-inflammatory and anti-inflammatory cytokines in serum,
3. clinical outcomes and presentations. We thus design a prospective case control study to
test this hypothesis. The frequency of TLR2 polymorphisms in both pulmonary TB patients
and healthy controls will be determined and compared by polymerase chain
reaction-restriction fragment length polymorphism. Serial serum levels of IL-12, IFN-γ,
and IL-10 in pulmonary TB patients with or without TLR2 polymorphisms will be measured
by enzyme linked immunosorbent assay at initial presentation, 2months and 6 months
after anti-TB drugs treatment. Relationships between TLR2 polymorphisms and serum
cytokines dynamics or clinical outcomes will be analyzed.
;
Observational Model: Case Control, Time Perspective: Prospective
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