Allergic airways disease Mouse bone marrow
mast cells and human
eosinophils exhibit in vitro
chemotaxis responses to 12-HHT. Since both cell types are implicated in allergic reactions, this suggests that BLT2 receptors could contribute to allergic responses in mice and humans. However, in a mouse model of ovalbumin-induced allergic airway disease:
a) 12-HHT and its companion cyclooxygenase metabolites,
Prostaglandin E2 and
Prostaglandin D2, but not 12 other lipoxygenase or cyclooxygenase metabolites showed a statistically significantly increase in bronchoalveolar lavage fluid levels after intratracheal ovalbumin challenge;
b) only 12-HHT, among the monitored BLT2 receptor-activating ligands (i.e. LTB4, the 12(
S) stereoisomer of
12-HETE, and 15(
S)-HETE) rose to a level capable of activating BLT2 receptors; and
c) BLT2
knockout mice exhibited a greatly
enhanced response to ovalbumin challenge. This study also found that the expression of BLT2 receptors was significantly reduced in
CD4+ T cells (which are known to mediate allergy-reactions) taken from asthmatic compared to non-asthmatic human controls. Thus, BLT2 receptors suppress allergic airways disease in mice and may function similarly in humans. These studies also allow that BLT2 receptors play suppressive functions in other allergic diseases.
Inflammation The high affinity BLT2 receptor agonist, 12-HHT, stimulates in vitro chemotactic responses in human
neutrophils, Other studies, however, indicate that the role of BLT2 receptors in inflammation is directed toward other cell types than neutrophils and differs very much from that of BLT1 receptors. Immortalized human skin
keratinocyte HaCaT cells respond to
ultraviolet B (UVB) radiation by generating toxic
reactive oxygen species which in turn trigger the cells to become
apoptotic and eventually die. This response is BLT2 receptor-dependent since
a) topical treatment of mouse skin with a BLT2 receptor antagonist, LY255283, protects against UVB radiation-induced apoptosis;
b) BLT2-overexpressing transgenic mice exhibit more extensive skin apoptosis in response to UVB irradiation that
wild type mice; and
c) 12-HHT inhibits HaCaT cells from synthesizing the pro-inflammation mediator,
interleukin-6 (IL-6), in response to UVB radiation. Furthermore, BLT2 receptor knock-out mice mount of more severe intestinal inflammation response to dextran sodium sulfate than either wild type or BLT1 receptor knockout mice (see Knockout studies). Thus, BLT2 receptors appear responsible for suppressing UVB-induced skin inflammation and, in contrast to BLT1 receptors, oppose the development and thereby dampen the severity of experimental colitis in mice.
Cancer The
Ras subfamily of
small GTPases function as
Signal transduction proteins by transmitting the presence of extracellular stimuli into inducing the expression of genes which regulate cellular survival, proliferation, differentiation, adherence to
extracellular matrix, and motility as well as factors that are released to promote new blood vessel formation (i.e.
Neovascularization) and to alter the extracellular matrix; the three members of this subfamily,
KRAS, NRAS (i.e.
Neuroblastoma RAS viral oncogene homolog), and
HRAS, develop
point mutations to become
oncogenes that drive the growth and spread of some 20% of all human cancers. The highest levels of Ras mutations are found in adenocarcinoma of the pancreas (90%), colon (50%), and lung (30%) Bos, 1989). Ras oncogenes can stimulate arachidonic acid metabolism:
a) HRAS, in a rat intestinal epithelial cell line, and KRAS, in a rat lung epithelial cell line, up-regulate COX2 expression and prostaglandin synthesis;
b) HRAS induces 12-lipoxygenase in the human epidermoid carcinoma
A431 cells; and
c) HRAS stimulates the expression of 5-lipoxygenase,
5-lipoxygenase-activating protein, LTB4, and BLT2 receptors Rat2 and a rat
fibroblast cell lines thereby increasing the tumor-forming ability the latter cell line in athymic mice. These studies suggest that the metabolites of cyclooxygenase, 5-lipoxygenase, and 12-lipoxygenase, i.e. 12-HHT, LTB4, and 12-HTE, respectively, may act through BLT2 receptors to contribute to the growth and spread of cancers initiated and/or oncogenic Ras and possibly other oncogenes. This is supported by findings that BLT2 is abnormally expressed in many human cancers that concurrently overexpress these arachidonic acid metabolizing pathways viz., follicular
thyroid adenoma,
renal cell carcinoma, urinary bladder
transitional cell carcinoma, esophagus
squamous cell carcinoma,
colon adenocarcinoma, the
serous cystadenocarcinoma type of
ovarian cancer, and uterine
cervical carcinoma. When detached from surfaces, cultured non-malignant PWR-1E and PC3 prostate cancer cells die by engaging suicidal
apoptosis pathways, a reaction termed
anoikis. This is accompanied by increased expression of BLT2 receptors, activation of
NADPH oxidase (NOX), increases in NOX-mediated production of
reactive oxygen species (ROS), and ROS-induced activation of the pro-survival transcription factor,
NF-κB. Ectopic expression and stimulation of BLT2 receptors by 12(
S)-HETE or a synthetic BLT2 receptor agonist, CAY-10583, inhibits whereas
Gene knockdown by
mRNA interference or pharmacological inhibition by LY255283 enhances these cells' anoikis response to surface detachment. 12-HETE also increases the survival of PC-3 cells by helping to maintain high levels of phosphorylated Rb
retinoblastoma protein, an effect which reduces the ability of retinoblastoma protein to inhibit the synthesis of DNA and thereby cell division. Finally, 12-lipoxygenase is overexpressed and the mass of 12-HETE is far higher in human prostate cancer than nearby normal prostate tissue; These findings suggest that BLT2 receptors operate to promote the survival, growth, and spread of human prostate cancer It remains unclear which if any of its 12-HHT, LTB4, and/or 12-HETE ligands mediate BLT2 receptor activation in the human disease.
Urinary bladder cancer LTB4 and 12(
S)-HETE stimulate the invasiveness in an in vitro Matrigel invasion assay of highly malignant human 253 J-BV urinary bladder cancer cell; their activity in this assay is completely inhibited by a pharmacological inhibition or siRNA knockdown of BLT2 receptors. The expression of 5-lipoxygenase,
5-lipoxygenase-activating protein, 12-lipoxygenase (enzymes synthesizing LTB4 and 12(
S)-HETE, respectively) as wells as LTB4 and 12(
S)-HETE were substantially elevated in these cells. Pretreatment of these cells with an inhibitor of BLT2 receptors, reduced their tumor forming ability after injection into mice; intraperitoneal injections of LY255283 into the mice also decreased the metastasis-forming ability of the cells after injection in the urinary bladder. Finally, BLT2 receptor protein was over expressed by the malignant tissues of human urinary bladder cancer and this expression was positively associated with the severity of this cancer. The action of BLT2 receptors, similar to their actions on prostate cancer cells, appeared to involve the receptors activation of the NOX, reactive species of oxygen, NK-κB pathway. These results suggest that BLT2 receptors contribute to the aggressiveness and progression of human urinary bladder cancer.
Breast cancer Compared to non-malignant
IMR-90 and immortalized but non-malignant
MCF-10A human breast cancer cell lines,
MCF-7,
ZR-75-1,
T47-D,
MDA-MB-231,
MDA-MB-468,
MDA-MB-453, and
SK-BR-3 human breast cancer cell lines (see
list of breast cancer cell lines) overexpress BLT2 mRNA and protein but show relatively little expression of BLT1 mRNA; treatment of the malignant but not non-malignant cells with a BLT2 antagonist, LY255283, but not a BLT1 antagonist, U75302, blocked proliferation of the cells in culture. LY255283 concurrently caused apoptosis in
estrogen receptor negative MDA-MB-468 and
MDA-MB-453 but not
estrogen receptor positive MCF-7 and
T47-D malignant cells. Since LY255283 also inhibits the BLT1 receptor, the apoptosis-inhibiting action of BLT2 receptors was also demonstrated by showing that
siRNA-induced transient
gene knockdown of BLT2 receptors caused apoptosis in the
MDA-MB-468 cell line. BLT2 receptors link to the activation of the
NADPH oxidase,
NOX1 (a synthesizer of the
superoxide anion which is a
reactive oxygen species that, when inappropriately overproduced, causes cell death and tissue injury); the attendant increased production of
reactive oxygen species and activation of
NF-κB appeared responsible for these BLT-2 receptor dependent effects.
Lipopolysaccharide (i.e.
endotoxin) stimulates
MDA-MB-231 and
MDA-MB-435 cells to increase their invasiveness as determined with in vitro Matrigel Invasion Chamber assays; this effect appears due to its ability to induce the overexpression of BLT2 receptors, the enzymes which produce LTB4 and 12(
S)-HETEs, and the key metabolites of these enzymes, LTB4 and 12(
S)-HETE; furthermore, the latter the binding of the latter metabolites to cells overexpressed BLT2 receptors leads to the activation of NF-κB. These results indicate that the 12-HETE/BLT2 interaction reduces the survival of cultured human breast cells by stimulating the production of reactive oxygen species and the activation of NF-κB.
Epithelial–mesenchymal transition, a process whereby epithelial cells assume a mesenchymal phenotype, is proposed to occur in a subset of cells in various cancer tissues to promote their movement from a tumor site into blood and lymphatic vessels and thereby form distant metastases. Human breast cancer often expresses and appears promoted by Ras proteins (see
carcinogenesis and the
Ras subfamily). The forced expression of oncogenic Ras in cultured human
MCF-10A breast cancer cells markedly up-regulates BLT2 receptors and this up-regulation appears essential for the epithelial–mesenchymal transition-promoting ability of
transforming growth factor beta in these cells; BLT2 receptors in these cells appear to stimulate the production of reactive oxygen species and activation of NF-κB and may thereby contribute to the metastatic ability of breast cancer. Since BLT2 receptors are significantly elevated in human breast cancer tissue compared to non-cancerous breast tissue, These studies indicate that the stimulation of BLT4 receptors by LTB4 and/or 12-HETE operate through a NOX4-reactive oxygen species-STAT-3-MMP2 pathway to promote the metastasis of SKOV-3 and CAOV-3 cancer cells in mice and may act similarly to promote metastases in human ovarian cancer.
Pancreatic cancer BLT2 receptor protein and mRNA was found to be markedly elevated in human advanced pancreatic intraepithelial
neoplasias in their primary pancreas sites as well as in
lymph node metastasis sites; mRNA for BLT1 was also elevated in these tissues but to a ~5-fold greater extent. Both receptors' mRNA were also expressed in a wide range of human pancreas cancer cell lines with BLT1 receptor mRNA ~2-fold greater than that for BLT2. The stable over expression of BLT2 in AsPC-1, Colo357, and
PANC-1 human pancreas cancer cell lines increased these cells' in vitro growth rates; specific BLT2 agonists also stimulated Colo367 and Panc-1 cell growth. BLT2 receptors mediated the in vitro migration of Panc-1 cells. These results allow that BLT2 receptors may contribute to the malignant growth and metastasis of human pancreas cancer.
Colon cancer The proliferation of
Caco-2 human epithelial colorectal adenocarcinoma cells in culture was stimulated by 12-HETE and inhibited by a somewhat selective inhibitor of 12-lipoxygenase,
baicalein; the stimulatory effect of 12-HETE appeared due to its interaction with BLT2 receptors based on the effects of pharmacological inhibitors.
Esophageal cancer Esophagus
squamous cell carcinoma overexpresses BLT2 receptors.
Other activities The BLT2 receptor mediates the itch scratching behavior induced by intradermal injection of 12-HETE in mice. == Antagonist ==