Technical articles

Lipid Regulatory Mechanisms in Inflammation and Immune Responses

Lipids in inflammation and immune responses do not merely serve structural roles in membrane assembly and energy storage, but instead constitute a critical regulatory layer spanning the entire course of inflammatory initiation, signal amplification, immune cell differentiation, effector execution, and inflammatory resolution. Fatty acids, phospholipids, cholesterol, sphingolipids, and their derived lipid mediators collectively form a dynamically changing lipid network. Through regulation of membrane microdomain organization, lipid mediator biosynthesis, organelle interactions, and metabolic program reconfiguration, this network continuously shapes the activation threshold, migratory capacity, phagocytic efficiency, and inflammatory output intensity of immune cells.

 

Keywords: lipid metabolism; inflammatory response; immune regulation; arachidonic acid; prostaglandins; leukotrienes; cholesterol; sphingolipids; lipid droplets; inflammation resolution

 

I. Why Lipids Have Become a Critical Layer in Inflammation and Immune Regulation

1.1 Lipids are not merely structural molecules

(1) Membrane lipids determine the spatial organization of immune receptors

The initiation of inflammatory and immune responses generally begins with the recognition of pathogen-associated molecules, damage-associated molecules, or cytokines by membrane receptors. Whether receptors can efficiently cluster, internalize, and sustain signal transduction depends not only on receptor expression levels, but also on the membrane microenvironment in which they reside. Phospholipids, cholesterol, and sphingolipids together determine membrane fluidity, membrane curvature, and membrane microdomain stability, thereby influencing the signaling efficiency of Toll-like receptors, T-cell receptors, B-cell receptors, Fc receptors, and various adhesion molecules.

(2) Lipid metabolism is an essential basis for immune cell functional remodeling

Following immune cell activation, fatty acid uptake, lipid synthesis, cholesterol flux, and lipid droplet formation are often rapidly reprogrammed. This process is not solely intended to meet the demands of membrane expansion or energy supply, but rather to support inflammatory mediator generation, cell migration, phagocytosis, antigen presentation, and effector differentiation. Accordingly, changes in lipid metabolism themselves constitute an integral component of immune cell functional conversion.

 

1.2 Lipid regulation exhibits pronounced temporal phasing

(1) The initiation phase of inflammation is dominated by pro-inflammatory lipids

After tissue injury or infection occurs, polyunsaturated fatty acids in membrane phospholipids are rapidly mobilized, particularly with increased release of arachidonic acid, which is subsequently metabolized through multiple pathways into prostaglandins, leukotrienes, thromboxanes, and other pro-inflammatory lipid mediators. These molecules promote vasodilation, increased vascular permeability, leukocyte recruitment, and amplification of local inflammatory signaling.

(2) The resolution phase of inflammation requires a switch in lipid programs

Inflammation does not terminate automatically, but instead depends on an active resolution program. As the response progresses, the lipid mediator profile must gradually shift from a pro-inflammatory pattern to a pro-resolving pattern, generating lipoxins, resolvins, protectins, maresins, and other specialized pro-resolving mediators, thereby promoting neutrophil clearance, macrophage engulfment of apoptotic cells, and tissue repair. If this switch fails, inflammation is more likely to persist and develop into a chronic pathological state.

 

II. Key Enzymes Related to Lipid Regulation Constitute the Enzymatic Basis of the Inflammatory Response

2.1 Lipid regulation is not determined by a single enzyme

(1) From substrate release to lipid mediator generation, all steps depend on multistage enzymatic reactions

The generation of lipid signals during inflammation usually begins with membrane phospholipid cleavage, followed by oxidation, transfer, re-esterification, degradation, and reutilization. Different enzymes vary in temporal sequence, substrate preference, and cellular localization. Therefore, lipid regulation is fundamentally a multienzyme system composed of serial and branching coupling reactions.

(2) The same lipid substrate can enter distinct fate pathways

For example, arachidonic acid can enter the cyclooxygenase pathway to generate prostaglandins, the lipoxygenase pathway to produce leukotrienes or lipoxins, or cytochrome P450-related pathways to form other oxidized lipids. Thus, the key determinant of inflammatory direction is not merely whether the substrate is present, but rather which set of enzymes preferentially utilizes it.

(3) Different phospholipid cleavage sites alter downstream signaling trajectories

During the initial stage of membrane phospholipid mobilization, phospholipase A1, phospholipase A2, phospholipase C, and phospholipase D act on different bonds and generate different classes of lipid intermediates. For this reason, membrane phospholipid cleavage is not a singular process of arachidonic acid release, but rather a branching node that determines lysophospholipid profiles, second messenger generation, and subsequent directions of lipid remodeling.

 

2.2 Key enzymes related to lipid regulation and their functional positioning

 

Enzyme/Protein

Major substrate or pathway

Major product or function

Functional positioning in inflammation and immunity

Phospholipase A1 (PLA1/PLA1A)

Membrane phospholipids, especially selected substrates such as phosphatidylserine

2-acyl lysophospholipids, free fatty acids

Participates in membrane phospholipid remodeling, lysophospholipid generation, and regulation of specific immune-inflammatory signaling

Phospholipase A2 (PLA2)

Membrane phospholipids

Arachidonic acid, lysophospholipids

Initiates lipid mediator generation and serves as a key upstream enzyme in pro-inflammatory lipid pathways

Cyclooxygenase-1/2 (COX-1/COX-2)

Arachidonic acid

Prostaglandins, thromboxane precursors

Regulates fever, pain, vascular responses, and inflammatory amplification

5-Lipoxygenase (5-LOX)

Arachidonic acid

Leukotriene precursors

Promotes granulocyte recruitment, airway inflammation, and acute inflammatory responses

12/15-Lipoxygenase (12/15-LOX)

Polyunsaturated fatty acids

Lipoxins, precursors of selected pro-resolving mediators

Participates in inflammation resolution and tissue repair-associated lipid generation

Leukotriene A4 hydrolase (LTA4H)

LTA4

LTB4

Promotes neutrophil chemotaxis and inflammatory amplification

Leukotriene C4 synthase (LTC4S)

LTA4

LTC4

Participates in allergic inflammation, vascular permeability changes, and airway responses

Prostaglandin E synthase (PTGES)

PGH2

PGE2

Regulates fever, pain, blood flow, and immune cell function

Soluble epoxide hydrolase (EPHX2)

Epoxy lipids

Dihydroxylated lipids

Regulates the duration of inflammatory lipid activity and vascular responses

Fatty acid synthase (FASN)

Acetyl-CoA, malonyl-CoA

Long-chain fatty acids

Supports membrane biogenesis and metabolic reprogramming in inflammatory cells

Acetyl-CoA carboxylase (ACC)

Acetyl-CoA

Malonyl-CoA

Controls de novo fatty acid synthesis and the direction of lipid metabolism

Carnitine palmitoyltransferase 1A (CPT1A)

Long-chain acyl-CoA

Promotes mitochondrial fatty acid oxidation

Influences immune cell energy metabolism and functional differentiation

Long-chain acyl-CoA synthetase family (ACSL)

Long-chain fatty acids

Acyl-CoA

Determines whether fatty acids enter synthesis, oxidation, or remodeling pathways

Diacylglycerol acyltransferase (DGAT1/2)

Diacylglycerol

Triglycerides, lipid droplet formation

Regulates lipid droplet biogenesis and storage of inflammatory lipids

Adipose triglyceride lipase (ATGL)

Triglycerides

Free fatty acids

Mobilizes lipid droplet lipids and affects inflammatory substrate supply

Sphingomyelinase (SMase)

Sphingomyelin

Ceramide

Participates in stress responses, inflammasome activation, and cell death-related processes

Sphingosine kinase 1/2 (SPHK1/2)

Sphingosine

S1P

Regulates migration, barrier function, and immune cell distribution

S1P lyase (SGPL1)

S1P

Terminal degradation products

Terminates S1P signaling and affects lymphocyte circulation

Serine palmitoyltransferase (SPT)

Serine, palmitoyl-CoA

Initial products of sphingolipid synthesis

Determines sphingolipid biosynthetic flux

SOAT1/ACAT1

Cholesterol

Cholesteryl esters

Regulates cholesterol storage, foam cell formation, and inflammatory states

Neutral cholesterol ester hydrolase (NCEH1)

Cholesteryl esters

Free cholesterol

Affects cholesterol mobilization and lipid homeostasis in macrophages

Cholesterol 25-hydroxylase (CH25H)

Cholesterol

25-hydroxycholesterol

Links interferon responses, cholesterol metabolism, and anti-infective regulation

Phosphatidylinositol 3-kinase (PI3K)

Phosphatidylinositol lipids

PIP3 and related signaling lipids

Regulates phagocytosis, migration, survival, and inflammatory signaling pathways

Phospholipase C (PLC)

PIP2

DAG, IP3

Participates in receptor signal transduction and Ca2+ mobilization

Diacylglycerol kinase (DGK)

DAG

Phosphatidic acid

Controls receptor signal duration and the balance of lipid second messengers

 

III. The Arachidonic Acid Metabolic Network Constitutes the Central Axis of the Transition Between Pro-Inflammatory and Resolving States

3.1 Arachidonic acid release is the starting point of inflammatory lipid generation

(1) Membrane phospholipid mobilization determines response intensity

In most inflammatory cells, activation of PLA2 rapidly cleaves membrane phospholipids and releases arachidonic acid. This step determines not only the initial rate of lipid mediator production, but also whether downstream metabolism proceeds toward prostaglandin pathways, leukotriene pathways, or resolution-associated pathways. Therefore, PLA2 is not simply an upstream enzyme, but a major branching node in temporal control of inflammation.

(2) Different cellular sources influence metabolic direction

Neutrophils, macrophages, mast cells, and epithelial cells differ in their metabolic preference for arachidonic acid. Some cells preferentially generate leukotrienes, whereas others more readily form prostaglandins or pro-resolving lipids. As a result, the lipid profile within inflammatory microenvironments exhibits pronounced dependence on cellular origin.

 

3.2 Prostaglandins and leukotrienes jointly amplify acute inflammation

(1) Prostaglandins participate in regulation of blood flow and inflammatory thresholds

Prostaglandins are not a uniform group of molecules, but rather comprise different family members with distinct roles in vasodilation, pain sensitization, fever, and immune regulation. PGE2 is particularly complex, as it can both enhance selected inflammatory processes and, at specific stages, limit excessive immune activation.

(2) Leukotrienes are more strongly associated with cell recruitment and local effector enhancement

LTB4 is a potent chemotactic lipid that promotes neutrophil migration and activation, whereas cysteinyl leukotrienes are more deeply involved in changes in vascular permeability, mucosal edema, and airway hyperresponsiveness. Accordingly, leukotriene pathways have particularly prominent pathological significance in acute inflammation, allergy, and airway inflammation.

 

3.3 Inflammation resolution depends on a switch in lipid mediator classes

(1) Resolution is not a natural passive decline of inflammation

The resolution of inflammation requires an active switch in lipid mediators from pro-inflammatory to pro-resolving classes. Enzymes such as 12/15-LOX are especially important in this process, as they promote the generation of lipoxins and other resolution-associated molecules.

(2) Pro-resolving lipids promote clearance and repair

Lipoxins, resolvins, protectins, maresins, and related molecules suppress excessive granulocyte infiltration, promote macrophage engulfment of apoptotic cells, and support tissue repair. If this system is insufficient, inflammation may remain in a state of persistent low-grade activation even when its intensity has declined.

 

IV. Membrane Lipid Remodeling and Phospholipid Signaling Determine the Efficiency of Immune Receptor Activation

4.1 Membrane lipid composition alters receptor nanostructure

(1) Lipid rafts and microdomain organization influence signal clustering

Cholesterol- and sphingolipid-enriched regions can form relatively ordered membrane microdomains, allowing specific receptors and downstream signaling proteins to cluster more efficiently. Following inflammatory stimulation, whether receptors can rapidly form high-density signaling clusters often determines whether downstream signaling is transiently triggered or persistently amplified.

(2) Membrane curvature and membrane tension affect phagocytosis and endocytosis

During phagocytosis, migration, and immune synapse formation, immune cells require extensive membrane remodeling. Phospholipid classes, fatty acid saturation, and local lipid compositional changes influence membrane extensibility and bending capacity, thereby determining the efficiency of phagosome formation, endosome maturation, and vesicular trafficking.

 

4.2 The phosphatidylinositol signaling pathway is a central hub of membrane dynamic control

(1) Different phosphatidylinositol species represent distinct membrane identities

PI, PI4P, PI(4,5)P2, and PI(3,4,5)P3 are not merely metabolic intermediates, but important signaling lipids that define the functional identity of membrane compartments. Different molecular species recruit different effector proteins and thereby regulate cell polarity, receptor endocytosis, and cytoskeletal rearrangement.

(2) Migration, phagocytosis, and inflammasome activation all depend on PI signaling

Directed migration of neutrophils, phagocytosis by macrophages, antigen uptake by dendritic cells, and selected inflammasome-related events all require rapid local remodeling of PI signaling. Thus, phosphatidylinositol metabolism is a major pathway through which external inflammatory stimuli are converted into membrane dynamic responses.

 

V. Cholesterol and Oxysterols Determine the Activation Threshold of Immune Cells

5.1 Cholesterol homeostasis is not merely a metabolic issue

(1) Cholesterol influences the stability of receptor signaling platforms

Cholesterol enhances membrane order and promotes the clustering efficiency of selected receptors and signaling proteins on the membrane. When cholesterol content becomes abnormal, receptor activation thresholds change, such that stimuli of equivalent strength can induce different degrees of inflammatory output.

(2) Cholesterol imbalance can drive chronic inflammation

When macrophage cholesterol uptake increases, cholesterol efflux becomes insufficient, or cholesterol esterification becomes abnormal, foam cell-like phenotypes readily develop. This process is not merely lipid deposition, but also feeds back to amplify inflammatory transcriptional programs and tissue injury responses, especially in chronic inflammatory diseases such as atherosclerosis.

 

5.2 Intermediates of cholesterol metabolism possess immunoregulatory functions

(1) Oxysterols are not passive by-products

Oxysterols such as 25-hydroxycholesterol can directly participate in anti-infective and immunoregulatory processes, influencing membrane cholesterol distribution, viral entry, receptor signaling, and inflammatory gene expression.

(2) Cholesterol flux is linked to antigen presentation and phagocytic clearance

The movement of cholesterol among lysosomes, the endoplasmic reticulum, and the plasma membrane directly affects post-phagocytic membrane recycling, antigen processing, and organelle stress levels. Therefore, cholesterol homeostasis is deeply embedded in the structural and functional logic of immune cells.

 

VI. The Sphingolipid System Plays Bidirectional Roles in Inflammatory Amplification and Immune Homeostasis

6.1 Ceramide and S1P form a functionally antagonistic axis

(1) Ceramide is more strongly associated with stress responses and inflammatory amplification

Ceramide is generated following sphingomyelin cleavage by sphingomyelinases. Ceramide promotes membrane platform reorganization, cell death-associated programs, inflammasome activation, and enhancement of stress signaling, and is therefore commonly associated with tissue injury and inflammatory expansion.

(2) S1P is more strongly associated with migration, survival, and barrier regulation

S1P is generated by phosphorylation of sphingosine through SPHK1/2. Through receptor-mediated pathways, S1P regulates lymphocyte egress, vascular endothelial barrier stability, and inflammatory cell distribution, making it an important molecule linking local inflammation with systemic immune circulation.

 

6.2 The balance of sphingolipid metabolism determines inflammatory direction

(1) Upstream synthesis and downstream degradation jointly determine output

Multiple enzymes, including SPT, SMase, SPHK, and S1P lyase, collectively determine sphingolipid profiles. What truly determines whether a cell is biased toward stress-associated death, migratory survival, or maintenance of homeostasis is not the concentration of a single molecule, but rather the balance of the entire sphingolipid metabolic axis.

(2) Sphingolipid abnormalities are associated with multiple immune diseases

Rearrangement of sphingolipid profiles has been observed in infection, autoimmunity, metabolic inflammation, allergy, and tumor microenvironments. This indicates that sphingolipid pathways can serve not only as pathological marker layers, but also as interventional target layers.

 

VII. Fatty Acid Metabolic Reprogramming Determines Immune Cell Functional States

7.1 Fatty acid synthesis and oxidation shape distinct immune programs

(1) Pro-inflammatory states are often accompanied by enhanced lipogenesis

Activated macrophages, dendritic cells, and effector T cells frequently enhance fatty acid synthesis in order to support membrane expansion, organelle remodeling, and inflammatory mediator synthesis. Under these conditions, enzymes such as ACC, FASN, and ACSL play major roles in metabolic reprogramming.

(2) Fatty acid oxidation is often associated with persistent survival and reparative phenotypes

Certain regulatory T cells, memory T cells, and reparative macrophages rely more strongly on fatty acid oxidation to maintain long-term survival and sustained functional activity. Enzymes such as CPT1A have important regulatory significance in this direction. However, this relationship is not absolute, as different tissues and microenvironments can shift this pattern.

 

7.2 Lipids in immunometabolism do not operate independently

(1) Lipid metabolism is coupled with glucose metabolism and amino acid metabolism

Metabolic reprogramming of inflammatory cells is generally the result of coordinated changes across multiple pathways. Enhanced fatty acid synthesis often coincides with active glycolysis, whereas increased fatty acid oxidation is frequently associated with maintenance of mitochondrial function and oxidative metabolism.

(2) Metabolic reprogramming fundamentally alters cellular decision-making logic

Immune cells do not first determine function and then alter metabolism; rather, the metabolic program itself participates in determining effector differentiation, survival duration, and the type of inflammatory output.

 

VIII. Lipid Droplets Have Transitioned From Lipid Storage Structures to Inflammatory Effector Platforms

8.1 Lipid droplets are active organelles in inflammation

(1) Lipid droplets are not static lipid storage depots

In inflammatory cells, lipid droplets can recruit multiple lipid metabolic enzymes and inflammation-associated proteins, thereby serving as important platforms for lipid mediator synthesis and substrate buffering. Their formation generally indicates that the cell has entered a highly reprogrammed lipid metabolic state.

(2) Lipid droplets participate in substrate storage and toxicity buffering

When free fatty acid and cholesterol loads become excessive, lipid droplets can temporarily sequester them, thereby reducing lipotoxicity and membrane injury. However, this buffering function is not universally beneficial. Persistent lipid droplet accumulation can also provide a substrate basis for lipid mediator production and maintenance of chronic inflammation.

 

8.2 Lipid droplets are directly linked to immune cell function

(1) Lipid droplet burden in macrophages affects inflammatory transcriptional states

Macrophages with increased lipid droplets are often accompanied by abnormal cholesterol handling, enhanced generation of pro-inflammatory lipid mediators, and increased metabolic burden after phagocytosis. Their functional state may therefore shift from clearance and repair toward maintenance of inflammation.

(2) Lipid droplets are also important in dendritic cells and granulocytes

Changes in lipid droplets can affect the cross-presentation capacity of dendritic cells and also influence lipid mediator release and local response intensity in neutrophils. Thus, lipid droplets should be regarded as immunoregulatory platforms rather than simple metabolic by-products.

 

IX. How Lipid Imbalance Drives Chronic Inflammation and Immune Disease

9.1 Chronic inflammation is frequently accompanied by misaligned lipid programs

(1) Persistent presence of pro-inflammatory lipids with insufficient pro-resolving lipids

In chronic airway inflammation, atherosclerosis, autoimmune diseases, and metabolic inflammation, sustained elevation of pro-inflammatory lipid mediators is often observed together with insufficient generation of resolution-associated lipids. This indicates that disease involves not only increased inflammatory intensity, but also failure to correctly establish inflammatory termination programs.

(2) Cholesterol, sphingolipid, and lipid droplet abnormalities jointly drive disease persistence

Imbalanced cholesterol flux, shifted sphingolipid metabolism, and abnormal lipid droplet accumulation can each amplify inflammation from the levels of membrane signaling, cell fate control, and metabolic buffering, ultimately forming a stable pathological lipid microenvironment.

 

9.2 Lipid-targeted intervention cannot remain at the level of simple inhibition

(1) Cell specificity and stage specificity must be considered

The same lipid pathway does not have the same biological meaning during the initiation, amplification, and resolution phases of inflammation. Therapeutic strategies should not simply suppress all lipid signaling, but instead should precisely regulate lipid mediator classes, cholesterol flux, or sphingolipid balance according to disease stage and cell type.

(2) Lipidomics and functional stratification will become key tools

Measurement of cholesterol, triglycerides, or total fatty acid content alone is insufficient to explain the true immune-lipid state. More informative future strategies will integrate lipidomics approaches with molecular-species resolution, cell-subset resolution, and spatial-distribution resolution to establish higher-resolution inflammatory lipid maps.

 

X. Aladdin-Related Products

10.1 Phospholipase-Related Products

 

Product Type

Catalog No.

Product Name

Grade and Purity

Applicable Research Direction / Use

Inhibitor

M304853

ML348

≥98%

Lysophospholipid metabolism and membrane phospholipid remodeling studies

ELISA Kit

EJ1514434

Human Phospholipase A1 (PL-A1) ELISA Kit

BioReagent

PLA1 expression analysis; membrane lipid remodeling studies

Enzyme

P757681

Phospholipase A1

EnzymoPure™, 75 PLA-L/g

Phospholipid hydrolysis studies; PLA1 enzymology analysis

Enzyme

P299005

Phospholipase A1 from Aspergillus oryzae

EnzymoPure™, ≥10 KLU/G

Phospholipase A1 enzymology; membrane lipid degradation studies

Inhibitor

A286909

ASB 14780

≥98%(HPLC)

Upstream regulation of arachidonic acid release; studies of pro-inflammatory lipid generation

Inhibitor

M288686

ML 349

≥98%

Regulation of lysophospholipid metabolism; membrane lipid turnover studies

Inhibitor

O288799

OBAA

≥98%

PLA2 inhibition; studies of inflammatory lipid precursor release

Inhibitor

O275137

ONO-RS-082

≥98%

PLA2 pathway inhibition; membrane phospholipid mobilization studies

Inhibitor

Y288422

YM 26734

≥95%(HPLC)

Studies of secretory PLA2-related inflammatory pathways

ELISA Kit

EJ1513719

Human Phospholipase A2, Group IID (PLA2G2D) ELISA Kit

BioReagent

PLA2 subtype expression analysis; stratification of inflammatory models

ELISA Kit

EJ1513733

Human Calcium-dependent Phospholipase A2 (PLA2G5) ELISA Kit

BioReagent

PLA2 subtype expression analysis; lipid signaling profiling

ELISA Kit

EJ1513734

Human Phospholipase A2, Group X (PLA2G10) ELISA Kit

BioReagent

PLA2 subtype expression analysis; studies of inflammatory lipid release

ELISA Kit

EJ1514436

Human Phospholipase A2, Membrane Associated (PLA2G2A) ELISA Kit

BioReagent

Evaluation of pro-inflammatory PLA2 expression; acute inflammation studies

ELISA Kit

EJ1514755

Human Phospholipase A2, LipoProtein Associated (LpPLA2) ELISA Kit

BioReagent

Evaluation of lipoprotein-associated inflammatory phospholipid metabolism

ELISA Kit

H1509864

Human Lp-PLA2 ELISA Kit

BioReagent

Lp-PLA2 level determination; lipid-inflammatory risk assessment

ELISA Kit

EJ1511943

Rat Phospholipase A2, Membrane Associated (PLA2G2A) ELISA Kit

BioReagent

PLA2 expression analysis in rat inflammatory models

ELISA Kit

EJ1512283

Rat Phospholipase A2, LipoProtein Associated (LpPLA2) ELISA Kit

BioReagent

Evaluation of lipoprotein inflammatory pathways in rats

ELISA Kit

EJ1512597

Mouse Phospholipase A2, Membrane Associated (PLA2G2A) ELISA Kit

BioReagent

PLA2 expression analysis in mouse inflammatory models

ELISA Kit

EJ1513140

Mouse Phospholipase A2, LipoProtein Associated (LpPLA2) ELISA Kit

BioReagent

Studies of Lp-PLA2-related inflammation in mice

Enzyme

P1501339

Phospholipase A2 (PLA2) from Porcine pancreas

ActiBioPure™, Bioactive, High Performance, EnzymoPure™, ≥200LeU/mg powder

Phospholipase A2 enzymology; construction of arachidonic acid release models

Inhibitor

U302223

U73122

Moligand™, ≥97%

PLC signaling inhibition; receptor-mediated phospholipid signaling studies

Activator

M287045

m-3M3FBS

Moligand™, ≥98%

PLC activation; studies of Ca2+ mobilization and receptor signaling

Enzyme

P757679

Phospholipase C

EnzymoPure™, ≥5000 PLC-S/g

Phospholipase C enzymology; membrane phospholipid cleavage studies

Enzyme

P1434805

Phosphatidylinositol phosphodiesterase

 

PI-specific phospholipid cleavage; membrane signal transduction studies

Inhibitor

F288161

FIPI

≥98%(HPLC)

Phospholipase D inhibition; membrane lipid remodeling and vesicular signaling studies

 

10.2 Arachidonic Acid Metabolism-Related Products

 

Product Type

Catalog No.

Product Name

Grade and Purity

Applicable Research Direction / Use

Inhibitor

C336912

COX-1 Inhibitor II

≥95%

COX-1 pathway inhibition; studies of basal prostaglandin generation

Inhibitor

C135780

SC-560

Moligand™, ≥98%(HPLC)

Selective COX-1 inhibition; studies of cyclooxygenase functional division

ELISA Kit

EJ1514286

Human Cyclooxygenase 1 (COX-1) ELISA Kit

BioReagent

COX-1 expression analysis; evaluation of prostaglandin synthesis pathways

ELISA Kit

EJ1512116

Rat Cyclooxygenase 1 (COX-1) ELISA Kit

BioReagent

Rat COX-1 expression analysis; inflammatory model studies

ELISA Kit

EJ1512869

Mouse Cyclooxygenase 1 (COX-1) ELISA Kit

BioReagent

Mouse COX-1 expression analysis; evaluation of arachidonic acid metabolism

Inhibitor

D287247

DuP 697

≥98%

COX-2 inhibition; studies of inflammation-amplifying pathways

Inhibitor

F287097

FK 3311

≥98%(HPLC)

Selective COX-2 inhibition; studies of pro-inflammatory prostaglandin generation

Inhibitor

N274713

NS 398

Moligand™, ≥98%

COX-2 inhibition; studies of acute inflammation and fever-related pathways

Inhibitor

N288651

NCX 466

≥98%(HPLC)

Studies of combined COX inhibition and nitric oxide donor effects

ELISA Kit

EJ1514287

Human Cyclooxygenase-2 (COX-2) ELISA Kit

BioReagent

COX-2 expression analysis; evaluation of inflammatory severity

Inhibitor

B288165

BAY-X 1005

Moligand™, ≥98%(HPLC)

Upstream inhibition of the leukotriene pathway; studies of the 5-LOX accessory complex

Inhibitor

B288192

BW-B 70C

Moligand™, ≥98%(HPLC)

5-LOX inhibition; studies of leukotriene generation

Inhibitor

L607227

5-LOX inhibitor 2m

Moligand™

5-LOX inhibition; studies related to granulocyte recruitment

ELISA Kit

EJ1513404

Human 5-Lipoxygenase (5-LOX) ELISA Kit

BioReagent

5-LOX expression analysis; evaluation of leukotriene pathways

Inhibitor

T288932

2-TEDC

Moligand™, ≥99%(HPLC)

Multi-LOX pathway inhibition; studies of the switch between pro-inflammatory and pro-resolving programs

Inhibitor

C274883

CDC

Moligand™, ≥98%

LOX pathway inhibition; lipid oxidation metabolism studies

Inhibitor

M275434

MK886

Moligand™, ≥98%

Regulation studies of leukotriene-related LOX branches

Inhibitor

P287013

PD 146176

Moligand™, ≥98%(HPLC)

15-LOX inhibition; studies of pro-resolving precursor generation

Inhibitor

L1496742

15-LOX-1 inhibitor 1

Moligand™, 10 mM in DMSO

15-LOX-1 inhibition; studies of lipoxins and pro-resolving lipids

Inhibitor

L647840

15-LOX-1 inhibitor 1

≥98%

15-LOX-1 inhibition; analysis of resolution pathways

Inhibitor

H1440710

h15-LOX-2 inhibitor 2

 

15-LOX-2 inhibition; lipid oxidation branch studies

Inhibitor

H1440701

h15-LOX-2 inhibitor 3

 

15-LOX-2 inhibition; studies of resolution-related metabolism

ELISA Kit

EJ1514788

Human Arachidonate-12-Lipoxygenase (ALOX12) ELISA Kit

BioReagent

ALOX12 expression analysis; studies of the 12-LOX branch

ELISA Kit

EJ1513171

Mouse Arachidonate-12-Lipoxygenase (ALOX12) ELISA Kit

BioReagent

Mouse ALOX12 expression analysis; LOX pathway profiling

ELISA Kit

EJ1514333

Human Leukotriene A-4 Hydrolase (LTA4H) ELISA Kit

BioReagent

Detection of the LTB4-generating pathway; studies of neutrophil chemotaxis

ELISA Kit

EJ1512135

Rat Leukotriene A4 Hydrolase (LTA4H) ELISA Kit

BioReagent

Rat LTA4H expression analysis; evaluation of leukotriene pathways

Inhibitor

C287028

C3

Moligand™, ≥98%(HPLC)

Inhibition of downstream PGE2 synthesis; studies of the prostaglandin E pathway

Inhibitor

T287865

TPPU

≥98%(HPLC)

EPHX2/sEH inhibition; studies of epoxy-lipid homeostasis

Enzyme

E1429656

Epoxide hydrolase

 

Enzymology studies of epoxy-lipid metabolism; studies of oxidized lipid conversion

ELISA Kit

EJ1515603

Human Prostaglandin E2 (PGE2) ELISA Kit

BioReagent

PGE2 level determination; evaluation of inflammation-amplifying effects

ELISA Kit

EJ1515384

Rat Prostaglandin E2 (PGE2) ELISA Kit

BioReagent

Rat PGE2 determination; pharmacodynamic evaluation studies

ELISA Kit

EJ1515486

Mouse Prostaglandin E2 (PGE2) ELISA Kit

BioReagent

Mouse PGE2 determination; inflammatory model monitoring

ELISA Kit

EJ1515325

Lipoxin A4 (LXA4) ELISA Kit

BioReagent

Detection of pro-resolving lipids during inflammation resolution; evaluation of resolution programs

 

10.3 Cholesterol- and Sphingolipid Metabolism-Related Products

 

Product Type

Catalog No.

Product Name

Grade and Purity

Applicable Research Direction / Use

Inhibitor

A129742

Avasimibe

≥98%

Inhibition of cholesterol esterification; studies of foam cell formation

Inhibitor

C276393

CI 976 (PD 128042)

≥98%

Inhibition of the ACAT/SOAT pathway; studies of cholesterol storage

Inhibitor

T275108

TMP-153

≥95%

Inhibition of cholesterol ester formation; cholesterol homeostasis studies

Inhibitor

V286658

VULM 1457

≥98%

Regulation of cholesterol esterification; studies of inflammatory lipid accumulation

Inhibitor

Y287168

YM 750

≥98%(HPLC)

ACAT inhibition; studies related to cholesterol loading

siRNA

S1476297

SOAT1 Human Pre-designed siRNA Set A

 

SOAT1 gene silencing; functional validation of cholesterol esterification

siRNA

N1482130

NCEH1 Human Pre-designed siRNA Set A

 

NCEH1 gene silencing; studies of cholesteryl ester hydrolysis

siRNA

C1488055

CH25H Human Pre-designed siRNA Set A

 

CH25H gene silencing; studies of oxysterols and anti-infective regulation

Detection Kit

T1505557

Total Cholesterol (TC) Content Assay Kit (Single-Reagent COD-PAP, Micro Method)

BioReagent

Quantification of total cholesterol in cells/tissues

Detection Kit

T1505558

Total Cholesterol (TC) Content Assay Kit (Double-Reagent COD-PAP, Micro Method)

BioReagent

Total cholesterol determination; evaluation of cholesterol homeostasis

Detection Kit

T1515864

Total Cholesterol (TC) Content Assay Kit (Single-Reagent COD-PAP, Colorimetric Method)

BioReagent

Measurement of cholesterol loading; cholesterol metabolism studies

Detection Kit

F1505559

Free Cholesterol (FC) Content Assay Kit (COD-PAP, Micro Method)

BioReagent

Quantification of free cholesterol; cholesterol flux analysis

Detection Kit

F1515865

Free Cholesterol (FC) Content Assay Kit (Single Reagent COD-PAP, Colorimetric Method)

BioReagent

Free cholesterol determination; analysis of esterification/de-esterification balance

Detection Kit

F1515866

Free Cholesterol (FC) Content Assay Kit (Dual Reagent COD-PAP, Colorimetric Method)

BioReagent

Studies of cholesterol flux and mobilization

ELISA Kit

EJ1511959

Rat Sphingomyelin Phosphodiesterase 2 (NSMASE) ELISA Kit

BioReagent

Detection of the sphingomyelin-ceramide axis; rat model studies

ELISA Kit

EJ1512612

Mouse Sphingomyelin Phosphodiesterase 2 (NSMASE) ELISA Kit

BioReagent

nSMase expression analysis; studies of sphingolipid metabolism in mice

Inhibitor

D286815

DPTIP

≥98%(HPLC)

nSMase2 inhibition; studies of ceramide generation

Inhibitor

N1441174

nSMase2-IN-1

≥98%

Inhibition of neutral sphingomyelinase 2; studies of sphingolipid stress pathways

Inhibitor

S129855

SKI II

Moligand™, ≥98%

SPHK1/2 inhibition; studies of S1P generation

Inhibitor

S275155

SKI-I

≥90%

Sphingosine kinase inhibition; studies of migration and barrier signaling

Inhibitor

C276256

CAY10621 (SKI 5C)

≥98%

Selective SPHK1 inhibition; studies of S1P signaling regulation

Inhibitor

M288047

MP A08

Moligand™, ≥97%

Dual SPHK1/2 inhibition; studies of sphingolipid homeostasis

siRNA

S1490203

SGPL1 Human Pre-designed siRNA Set A

 

SGPL1 gene silencing; studies of terminal S1P degradation

Substrate

S1452349

SGPL1 fluorogenic substrate

 

SGPL1 activity assay; functional analysis of S1P lyase

ELISA Kit

EJ1513355

Mouse Sphingosine 1 Phosphate Lyase 1 (SGPL1) ELISA Kit

BioReagent

Mouse SGPL1 expression analysis; evaluation of S1P metabolism

 

10.4 Fatty Acid Metabolism, Lipid Droplet, and Phospholipid Signaling-Related Products

 

Product Type

Catalog No.

Product Name

Grade and Purity

Applicable Research Direction / Use

ELISA Kit

EJ1514752

Human Fatty Acid Synthase (FASN) ELISA Kit

BioReagent

FASN expression analysis; fatty acid synthesis studies

ELISA Kit

EJ1513138

Mouse Fatty Acid Synthase (FASN) ELISA Kit

BioReagent

Mouse FASN expression analysis; immune metabolic reprogramming studies

Activity Assay Kit

F1516011

Fatty Acid Synthase (FAS) Activity Assay Kit (UV Micro Method)

BioReagent

FASN activity assay; evaluation of lipid synthesis capacity

Activity Assay Kit

F1516012

Fatty Acid Synthase (FAS) Activity Assay Kit (UV Colorimetric Method)

BioReagent

Assessment of fatty acid synthesis flux; pharmacodynamic studies

Inhibitor

A1440171

ACC1-IN-2

 

ACC1 inhibition; studies of fatty acid synthesis regulation

Inhibitor

A1440172

ACC1/2-IN-1

 

Dual ACC1/2 inhibition; studies of the balance between synthesis and oxidation

Inhibitor

A1440169

ACC1/2-IN-2

 

ACC1/2 inhibition; studies of lipid metabolic directionality control

Inhibitor

A275993

ACC2 Inhibitor

≥98%

ACC2 inhibition; studies favoring fatty acid oxidation

Inhibitor

P288592

PF 05175157

≥98%(HPLC)

ACC1/2 inhibition; immune metabolic reprogramming studies

Activity Assay Kit

A1515852

Acetyl CoA Carboxylase (ACC) Activity Assay Kit (AHM, Micro Method)

BioReagent

ACC activity assay; studies of precursor generation for fatty acid synthesis

Activity Assay Kit

A1515969

Acetyl-CoA Carboxylase (ACC) Activity Assay Kit (AHM, Colorimetric Method)

BioReagent

ACC activity assay; evaluation of pharmacological intervention

ELISA Kit

EJ1515058

Human Long-chain-fatty-acid—CoA Ligase 4 (ACSL4) ELISA Kit

BioReagent

ACSL4 expression analysis; studies of long-chain fatty acid activation

Enzyme

A774049

Acyl-CoA Synthetase (ACS)

Bioactive, ActiBioPure™, High Performance, EnzymoPure™, ≥85%(SDS-PAGE), ≥5 U/mg protein

Fatty acid activation; studies of acyl-CoA generation

Enzyme

R1506902

Acyl-CoA Synthetase (ACS)

Bioactive,Recombinant,ActiBioPure™,High Performance,EnzymoPure™,≥1 U/mg enzyme powder

Construction of recombinant fatty acid activation systems; metabolic pathway analysis

Inhibitor

A129800

A922500

≥98%

DGAT1 inhibition; studies of lipid droplet formation

Inhibitor

A286752

AZD 3988

≥98%(HPLC)

DGAT1 inhibition; studies of triglyceride synthesis

Inhibitor

A128057

AZD7687

Moligand™, ≥98%

DGAT1 inhibition; studies of lipid droplet burden regulation

Inhibitor

D649195

DGAT-1 inhibitor 2

≥95%

DGAT1 inhibition; studies of lipid droplet biogenesis

Inhibitor

D651790

DGAT1-IN-1

≥95%

DGAT1 inhibition; studies of lipid droplet storage

Inhibitor

D647241

DGAT1-IN-3

≥99%

DGAT1 inhibition; studies of triglyceride storage

Inhibitor

D1439626

DGAT2-IN-3

 

DGAT2 inhibition; studies of lipid droplet maturation and lipid storage

Inhibitor

J287704

JNJ DGAT2-A

≥98%

DGAT2 inhibition; studies of late-stage lipid droplet formation

Inhibitor

P286969

PF 06424439

≥98%(HPLC)

DGAT2 inhibition; studies of triglyceride synthesis

ELISA Kit

EJ1514750

Human Adipose Triglyceride Lipase (ATGL) ELISA Kit

BioReagent

ATGL expression analysis; studies of lipid droplet mobilization

Inhibitor

A129503

AS-252424

Moligand™, ≥98%

PI3Kγ inhibition; studies of migration and inflammatory membrane signaling

Inhibitor

A129517

AS-604850

Moligand™, ≥98%

PI3Kγ inhibition; studies of receptor-downstream phospholipid signaling

Inhibitor

A127765

AS-605240

Moligand™, ≥98%

Studies of PI3Kγ-dependent phagocytosis/migration pathways

Inhibitor

I126757

IC-87114

Moligand™, ≥98%

PI3Kδ inhibition; studies of immune cell signaling regulation

Inhibitor

S414119

Selective PI3Kδ Inhibitor 1 (compound 7n)

≥98%

Selective PI3Kδ inhibition; inflammatory signaling studies

Inhibitor

T127783

TG100-115

Moligand™, ≥98%

Dual PI3Kγ/δ inhibition; studies of membrane dynamics and migration

Inhibitor

G126357

GDC-0941

Moligand™, ≥98%

Broad PI3K pathway inhibition; studies of phagocytosis and survival signaling

Inhibitor

X129499

XL147

Moligand™, ≥98%

PI3K inhibition; studies of phosphatidylinositol signaling

Inhibitor

Z126804

ZSTK474

Moligand™, ≥98%

PI3K inhibition; studies of membrane identity and inflammatory signaling

Inhibitor

R288294

R 59-022

≥98%(HPLC)

DGK inhibition; studies of DAG/phosphatidic acid balance and receptor signaling

 

Lipid regulation in inflammation and immune responses is, in essence, a multilayered network jointly composed of membrane lipid remodeling, lipid mediator generation, metabolic program switching, and organelle interactions. Lipids participate not only in the initiation of inflammation, but also determine whether inflammation can be resolved in a timely manner; they not only shape the effector output of immune cells, but also define their metabolic boundaries and tissue adaptability. Only by understanding pro-inflammatory lipids, pro-resolving lipids, cholesterol flux, sphingolipid signaling, and lipid droplet dynamics within a unified framework can the true regulatory logic of inflammation and immune responses be more accurately captured, thereby providing a stronger theoretical foundation for subsequent mechanistic investigation and precision intervention.

 

For more related articles, please see below:

[1] How to Map the NF-κB Pathway and Choose Inhibitors: Bringing Inflammatory Transcriptional Output into a “Controllable Range” (Tables A–F)

Categories: Technical articles

Da — when not otherwise indicated, molecular weight units are daltons.   Mw — weight-average molecular weight.   Mn — number-average molecular weight.

Products are supplied for research and development use only. Not for use in humans, animals, diagnosis, or therapy.

Cite this article

Aladdin Scientific. "Lipid Regulatory Mechanisms in Inflammation and Immune Responses" Aladdin Knowledge Base, updated Mar 18, 2026. https://www.aladdinsci.com/us_en/faqs/lipid-regulatory-mechanisms-in-inflammation-and-immune-responses-en.html
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