LPS storage in the body The human body carries endogenous stores of LPS. The epithelial surfaces are colonized by a complex microbial flora (including Gram-negative bacteria). Gram-negative bacterial will shed endotoxins. This host-microbial interaction is a symbiotic relationship which plays a critical role in systemic immunologic homeostasis. When this is disrupted, it can lead to disease such as endotoxemia and endotoxic septic shock.
Immune response LPS acts as the prototypical endotoxin because it binds the
CD14/
TLR4/
MD2 receptor complex in many cell types, but especially in
monocytes,
dendritic cells,
macrophages and
B cells, which promotes the secretion of pro-
inflammatory cytokines,
nitric oxide, and
eicosanoids.
Bruce Beutler was awarded a portion of the 2011 Nobel Prize in Physiology or Medicine for his work demonstrating that
TLR4 is the LPS receptor. As part of the cellular
stress response,
superoxide is one of the major
reactive oxygen species induced by LPS in various cell types that express TLR (
toll-like receptor). LPS is also an exogenous
pyrogen (fever-inducing substance). and other animals as well (e.g., mice). A dose of 1 μg/kg induces shock in humans, but mice will tolerate a dose up to a thousand times higher. This may relate to differences in the level of circulating natural antibodies between the two species. It may also be linked to multiple immune tactics against pathogens, and part of a multi-faceted anti-microbial strategy that has been informed by human behavioral changes over our species' evolution (e.g., meat eating, agricultural practices, and smoking). Endotoxins are in large part responsible for the dramatic clinical manifestations of infections with pathogenic Gram-negative bacteria, such as
Neisseria meningitidis, the pathogens that causes
meningococcal disease, including
meningococcemia,
Waterhouse–Friderichsen syndrome, and
meningitis. Portions of the LPS from several bacterial strains have been shown to be chemically similar to human host cell surface molecules; the ability of some bacteria to present molecules on their surface which are chemically identical or similar to the surface molecules of some types of host cells is termed molecular
mimicry. For example, in
Neisseria meningitidis L2,3,5,7,9, the terminal tetrasaccharide portion of the oligosaccharide (lacto-N-neotetraose) is the same tetrasaccharide as that found in
paragloboside, a precursor for
ABH glycolipid antigens found on human
erythrocytes. Infection in mice using
S. typhimurium showed similar results, validating the experimental model also
in vivo.
Effect of variability on immune response s of the
innate immune system recognize LPS and trigger an
immune response. O-antigens (the outer carbohydrates) are the most variable portion of the LPS molecule, imparting antigenic specificity. In contrast, lipid A is the most conserved part. However, lipid A composition also may vary (e.g., in number and nature of
acyl chains even within or between genera). Some of these variations may impart antagonistic properties to these LPS. For example, diphosphoryl lipid A of
Rhodobacter sphaeroides (RsDPLA) is a potent antagonist of LPS in human cells, but is an agonist in hamster and equine cells. It has been speculated that conical lipid A (e.g., from
E. coli) is more agonistic, while less conical lipid A like that of
Porphyromonas gingivalis may activate a different signal (
TLR2 instead of TLR4), and completely cylindrical lipid A like that of
Rhodobacter sphaeroides is antagonistic to TLRs. In general, LPS gene clusters are highly variable between different strains, subspecies, species of bacterial pathogens of plants and animals. Normal human blood
serum contains anti-LOS antibodies that are bactericidal and patients that have infections caused by serotypically distinct strains possess anti-LOS antibodies that differ in their specificity compared with normal serum. These differences in humoral immune response to different LOS types can be attributed to the structure of the LOS molecule, primarily within the structure of the oligosaccharide portion of the LOS molecule. Taken together, these observations suggest that variations in bacterial surface molecules such as LOS can help the pathogen evade both the
humoral (antibody and complement-mediated) and the
cell-mediated (killing by neutrophils, for example) host immune defenses.
Non-canonical pathways of LPS recognition Recently, it was shown that in addition to
TLR4 mediated pathways, certain members of the family of the
transient receptor potential ion channels recognize LPS. LPS-mediated activation of
TRPA1 was shown in mice and
Drosophila melanogaster flies. At higher concentrations, LPS activates other members of the sensory
TRP channel family as well, such as
TRPV1,
TRPM3 and to some extent
TRPM8. LPS is recognized by
TRPV4 on epithelial cells. TRPV4 activation by LPS was necessary and sufficient to induce nitric oxide production with a bactericidal effect.
Testing Lipopolysaccharide is a significant factor that makes bacteria harmful, and it helps categorize them into different groups based on their structure and function. This makes LPS a useful marker for telling apart various Gram-negative bacteria. Swiftly identifying and understanding the types of pathogens involved is crucial for promptly managing and treating infections. Since LPS is the main trigger for the immune response in our cells, it acts as an early signal of an acute infection. Therefore, LPS testing is more specific and meaningful than many other serological tests. The current methods for testing LPS are quite sensitive, but many of them struggle to differentiate between different LPS groups. Additionally, the nature of LPS, which has both water-attracting and water-repelling properties (amphiphilic), makes it challenging to develop sensitive and user-friendly tests. The assay reacts specifically with the Lipid A moiety of LPS of Gram-negative bacteria and does not cross-react with cell wall constituents of Gram-positive bacteria and other microorganisms.
Pathophysiology LPS is a powerful toxin that, when in the body, triggers inflammation by binding to cell receptors. Excessive LPS in the blood, endotoxemia, may cause a highly lethal form of sepsis known as endotoxic septic shock. This condition includes symptoms that fall along a continuum of pathophysiologic states, starting with a systemic inflammatory response syndrome (SIRS) and ending in multiorgan dysfunction syndrome (MODS) before death. Early symptoms include rapid heart rate, quick breathing, temperature changes, and blood clotting issues, resulting in blood vessels widening and reduced blood volume, leading to cellular dysfunction. Recent research indicates that even small LPS exposure is associated with autoimmune diseases and allergies. High levels of LPS in the blood can lead to metabolic syndrome, increasing the risk of conditions like diabetes, heart disease, and liver problems. LPS also plays a crucial role in symptoms caused by infections from harmful bacteria, including severe conditions like Waterhouse-Friderichsen syndrome, meningococcemia, and meningitis. Certain bacteria can adapt their LPS to cause long-lasting infections in the respiratory and digestive systems. Recent studies have shown that LPS disrupts cell membrane lipids, affecting cholesterol and metabolism, potentially leading to high cholesterol, abnormal blood lipid levels, and non-alcoholic fatty liver disease. In some cases, LPS can interfere with toxin clearance, which may be linked to neurological issues. ==Health effects==