Endotoxin contamination is a common problem with recombinant proteins and nucleic acids purified from gram-negative bacteria such as E. coli. Endotoxins are lipopolysaccharides (LPS), which are heat-stable molecules associated with the outer membranes of certain gram-negative bacteria. When bacterial cells are actively growing or when their membranes disintegrate upon death, the essential LPS components of the cell wall are released into the surrounding environment. Lipopolysaccharides are large molecules ranging in size from 3–4 kDa, consisting of a hydrophobic lipid group covalently bound to a long complex polysaccharide tail (Figure 1). Endotoxin contamination is dangerous and can trigger endotoxic shock, inflammation, or sepsis in animals, and tissue culture.
Figure 1. Structure of bacterial endotoxin. Endotoxins are complex lipopolysaccharides and are biologically active structural components of the outer cell membrane of gram-negative bacteria. They consist of a core oligosaccharide chain, O-specific polysaccharide side chain (O-antigen), and a lipid component, lipid A, which is responsible for the toxic effects. In the early 1950s, Frederick Bang discovered that the blood cells (amebocytes) of the horseshoe crab clot in the presence of low levels of endotoxins. The gel-clot method established from this observation is an economical, specific, and sensitive method to detect endotoxins. The use of the amebocyte lysate has become the industry standard for endotoxin detection in the pharmaceutical and food industries as well as life science and medical research.
Product | Parameter | Detection method | Assay time | Sensitivity range (EU/mL) |
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Pierce LAL Chromogenic Endotoxin Quantitation Kit | Quantitative | Colorimetric (405 nm) | 10—14 min (0.1-1.0 EU/mL sensitivity) ~30 min (.01—0.1 EU/mL sensitivity) | 0.01—1 |
Pierce Rapid Gel Clot Endotoxin Assay Kit | Qualitative | Visual (clot) | 15—25 min | 0.03—0.5 |
Pierce High-Capacity Endotoxin Removal Resin | Quantitative | N/A | ≥ 1 hr | ≤ 5 |
Invitrogen Qubit Endotoxin Assay Kit | Quantitative | Fluorometric | 17—27 min | 0.001—10.0 |
Invitrogen Quant-iT Endotoxin Assay Kit | Quantitative | Fluorometric | 17—27 min | 0.001—10.0 |
Thermo Scientific Pierce Rapid Gel Clot Endotoxin Assay kits provide rapid and easy-to-read qualitative results indicating the presence or absence of gram-negative bacterial endotoxin in a sample. The kits are used for in vitro end-point endotoxin tests and do not require sophisticated equipment or software. They are best suited for samples that are colored and are available in a variety of sensitivities: 0.03 EU/mL, 0.125 EU/mL, 0.25 EU/mL, and 0.5 EU/mL.
Figure 2. The New Pierce Rapid Gel Clot Endotoxin Assay Kit
Pierce Rapid Gel Clot Endotoxin Assay kits use amebocyte lysates derived from the Limulus horseshoe crab hemolymph to detect endotoxin levels in samples. Limulus amebocyte lysate (LAL) is widely used as a simple and sensitive assay for detection of endotoxin lipopolysaccharide from the membranes of gram-negative bacteria. When endotoxin encounters the amebocyte lysate, a series of enzymatic reactions form a gel-like clot. In a positive test, a clot will form in the sample tube, indicating that the amount of endotoxin in the sample is greater than or equal to the listed sensitivity (in EU/mL) of the kit. A lack of gel clot formation in the tube is considered a negative result indicative of an endotoxin concentration in the test tube below the kit’s sensitivity (Figure 3).
Figure 3. Endotoxin gel clot reaction. LAL clots in the presence of endotoxin-containing sample via an enzymatic cascade reaction. If endotoxin is not present in the sample, no clotting occurs.
The Thermo Scientific Pierce Chromogenic Endotoxin Quantitation Kit accurately measures endotoxins at levels as low as 0.01 EU/mL in samples. This kit is an endpoint amebocyte lysate assay that accurately detects and quantitates endotoxins (lipopolysaccharides) in a variety of sample types, including proteins, peptides, nucleic acids, and antibodies.
The principle of the assay is based on the activation of factor C, factor B, and pro–clotting enzyme in the amebocyte lysate in the presence of endotoxin. The amount of endotoxin is quantitated by the addition of a chromogenic substrate, Ac-Ile-Glu-Ala-Arg-pNA. The endotoxin-activated pro–clotting enzyme catalyzes the release of p-nitroaniline (pNA) to produce a yellow color (Figure 4).
Figure 4. Coagulation cascade in horseshoe crab blood. LPS (endotoxin) activates plasma membrane–bound factor C. The activated factor C activates factor B, which activates the clotting enzyme that triggers the exocytotic release of the clotting cascade. Upon addition of a chromogenic substrate, Ac-Ile-Glu-Ala-Arg-pNA, the activated protease, clotting enzyme, catalyzes the release of p-nitroaniline (pNA), resulting in a yellow color that can be quantitated by measuring the absorbance at 405 nm and extrapolating from a standard curve.
After the reaction is stopped, the released pNA is photometrically measured at 405 nm (Figure 5). The developed color intensity is directly proportional to the amount of endotoxin present in the sample and is calculated using a standard curve.
Figure 5. Pierce Chromogenic Endotoxin Quantitation Kit assay principle. Sample endotoxin activates factor C, which leads to a signal cascade that results in activated protease catalyzing the release of chromogenic pNA. This produces a yellow color that can be measured by absorbance at 405 nm. A standard curve is plotted from the absorbance values generated from a set of diluted endotoxin samples.
Sensitive endotoxin testing is essential because of the sample limitations and low endotoxin levels required for cell culture and animal research. The Pierce Chromogenic Endotoxin Quant Kit offers high-sensitivity and reproducibility with two linear dynamic ranges of 0.01–0.1 EU/mL and 0.1–1.0 EU/mL (Figure 6). The test-to-test and operator-to-operator reproducibility of this endpoint amebocyte lysate assay resulted in a coefficient of variation (CV) of 3%. The lower sensitivity range permits higher dilution of samples that are limited in quantity or contain interfering substances, therefore helping to avoid potential false negatives or false positives in endotoxin quantitation.
Figure 6. Standard curves for the Pierce Chromogenic Endotoxin Quantitation Kit. The standard curves show exceptional linearity with r2 = 0.99. The Pierce Chromogenic Endotoxin Quant Kit has a lower-range standard curve of 0.01–0.1 EU/mL. The standard curve of 0.1–1.0 EU/mL represents a 14-minute incubation with endotoxin standards and amebocyte lysate, followed by a 6-minute incubation with the chromogenic substrate. For the lower range, a 30-minute incubation with endotoxin standards and amebocyte lysate was followed by a 6-minute incubation with the chromogenic substrate. Consistency and reproducibility (n = 17; CV = 3%) is shown for the low-range standards (0.01–0.1 EU/mL).
Amebocyte lysate assays can be affected by many factors that can cause inhibition or enhancement leading to false negatives or false positives. Factors that can lead to inhibition of the amebocyte lysate assay include reaction temperature, sample pH, ionic strength, and metal ions (e.g., magnesium and calcium). Serum proteins, nucleic and fatty acids, surfactants, and chelating reagents (e.g., EDTA and heparin) cause changes in molecular structure of endotoxin aggregates that can result in inaccurate or total inhibition of the amebocyte lysate assay. In addition, surfactants (e.g., Triton X-100, SDS, deoxycholate) used in various protein workflows alter the supramolecular structure of lipopolysaccharides and therefore can interfere with their detection and quantitation. If any of these interfering substances are present in test samples, the samples need to be diluted.
Table 1 summarizes compatibility levels of common reagents with the amebocyte lysate assay. To be considered free of interfering factors in the test, the measured concentration of endotoxin added to the sample must be within 50%–200% of the known added amount.
Table 1. Highest acceptable concentration of typical reagents for valid endotoxin spike recovery using the Pierce Chromogenic Endotoxin Quant Kit. Concentrations listed refer to the actual concentration in the sample that produced no decrease in quantitation values when spiked with 0.5 EU endotoxin. Dilutions are expressed in the form of a ratio, where 1:100 means a 100-fold dilution.
Another common interfering substance in the amebocyte lysate assay is (1,3)-β-D-glucan, a cell wall component of bacteria and fungi. Although β-glucan is not pyrogenic, it can activate factor G, which is able to trigger the coagulation cascade, producing false positives in the assay (Figure 7). The Pierce Chromogenic Endotoxin Quant Kit is compatible with β-glucans, and in samples containing ≤10 ng/mL of (1,3)-β-D-glucan, no enhancement is exhibited.
Figure 7. Activation of the clotting enzyme by (1,3)-β-D-glucan. The presence of β-glucans activates a pathway that is independent of the amebocyte lysate response to endotoxins resulting in false-positive determination of bacterial endotoxins in the sample. The Pierce Chromogenic Endotoxin Quant Kit is resistant to β-glucans. Red indicates inactive enzymes, and green indicates active enzymes.
Endotoxin-contaminated protein or antibody samples transfected into cells or injected into an animal host can initiate a strong immune response, resulting in systemic inflammatory response syndrome (SIRS) and/or sepsis. Elimination of endotoxins from samples produced from gram-negative bacteria prior to cell transfection or animal injection is a necessity. Ultrafiltration, polymixin B affinity resin, or resin- or membrane-based chromatography are the traditional methods of endotoxin removal. These methods have limitations in protein recovery or endotoxin binding capacity or have toxicity concerns.
The Pierce High Capacity Endotoxin Removal Resin is a modified ε-poly-L-lysine [poly (ε-lysine)] affinity resin (nontoxic polymer of the natural amino acid lysine) that displays both excellent endotoxin binding capacity and protein recovery. It is effective in eliminating endotoxins from samples containing proteins of various sources, sizes, and charges. The high binding capacity and low protein retention of this resin make it suitable for many protein sample types, including antibodies.
Figure 8 shows how the poly (ε-lysine) affinity ligands on the Pierce High Capacity Endotoxin Removal Resin bind endotoxins through both cationic and hydrophobic interactions.
Figure 8. The poly(ε-lysine) affinity ligand binds endotoxins through both ionic and hydrophobic interactions. The multiple ε-aminobutyl groups impart both a positive charge via the primary amines and a hydrophobic characteristic via the butyl spacer between primary amines. The hydrophilic nature of the porous cellulose base matrix is masked by thorough derivatization of its interior and exterior surfaces with the poly(ε-lysine) ligand.
The Pierce High Capacity Endotoxin Removal Resin has a 2,000,000 EU/mL binding capacity, enabling endotoxin levels to be reduced by 99% in samples containing initial endotoxin levels of 10,000 EU/mL. Typical protein samples processed with the Thermo Scientific Pierce High Capacity Endotoxin Removal Resin have a final endotoxin concentration below 5 EU/mL (Figure 9).
Figure 9. Efficient removal of endotoxins by the Pierce High Capacity Endotoxin Removal Resin. General workflow for endotoxin removal and quantitation. (B) Determination of final endotoxin concentrations in purified protein samples in preparation for downstream applications.
The Invitrogen Qubit Endotoxin Detection Assay Kit and the Invitrogen Quant‑iT Endotoxin Detection Assay Kit, designed for use with the Invitrogen Qubit Flex Fluorometer and fluorescence microplate readers, respectively, offer efficient, fluorescent endpoint assays that quantify endotoxins in various sample types using a streamlined workflow.
The Qubit Endotoxin Detection Assay, designed for use with Qubit Flex Fluorometers, is an efficient, fluorescent endpoint assay that uses amebocyte lysates to quantify endotoxin in various sample types such as protein, peptides, antibodies or nucleic acid samples. The assay can be run with variable sample volumes and offers a dynamic range from 0.01-10.0 EU/mL using a streamlined workflow (Figure 10).
Key features and benefits of the Qubit Endotoxin Detection Assay Kit include:
- High sensitivity and broad range - Detect as little as 0.01 EU/mL to 10.0 EU/mL
- Versatility – Suitable for a wide range of samples, including proteins, plasmid preparations, DNA and RNA
- Easy-to-use – When paired with the Qubit Flex Fluorometer, calculations are performed automatically, reducing the potential for error
NEW Invitrogen Qubit™ Endotoxin Detection Assay Kit | |
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Sensitivity range (EU/mL) | 0.01—10.0 |
Detection method | Fluorescent |
β-glucan interference | No |
No. of assays | 80 |
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Figure 10. The New Invitrogen™ Qubit™ Endotoxin Detection Assay Kit
NEW Invitrogen Quant-iT™ Endotoxin Detection Assay Kit
The Quant-iT Endotoxin Detection Assay, designed for use with fluorescence microplate readers, offers an efficient, fluorescent endpoint assay that uses amebocyte lysates to quantify endotoxin in various sample types such as protein, peptides, antibodies or nucleic acid samples. The assay can be performed on variable sample volumes, and offers a dynamic range of 0.01–10.0 EU/mL using a streamlined workflow (Figure 11).
NEW Invitrogen Quant-iT™ Endotoxin Detection Assay Kit | |
---|---|
Sensitivity range (EU/mL) | 0.01–10.0 |
Detection method | Fluorescent |
β-glucan interference | No |
No. of assays | 160 |
Order now |
Figure 11. The New Invitrogen™ Quant-iT™ Endotoxin Detection Assay Kit
- Levin J, Bang FB (1964) The role of endotoxin in the extracellular coagulation of limulus blood. Bull Johns Hopkins Hosp 115:265–274.
- Iwanaga S (1993) The limulus clotting reaction. Curr Opin Immunol 5(1):74–82.
- Nakamura T, Morita T, Iwanaga S (1986) Lipopolysaccharide-sensitive serine-protease zymogen (factor C) found in Limulus hemocytes. Isolation and characterization. Eur J Biochem 154(3):511–521.
- Iwanaga S, Morita T, Harada T et al. (1978) Chromogenic substrates for horseshoe crab clotting enzyme. Its application for the assay of bacterial endotoxins. Haemostasis 7(2-3):183–188.
- Muta T, Miyata T, Misumi Y et al. (1991) Limulus factor C. An endotoxin-sensitive serine protease zymogen with a mosaic structure of complement-like, epidermal growth factor-like, and lectin-like domains. J Biol Chem 266(10):6554–6561.
- Cooper JF, Levin J, Wagner HN Jr. (1971) Quantitative comparison of in vitro and in vivo methods for the detection of endotoxin. J Lab Clin Med 78:138–148.
- Seki N, Muta T, Oda T et al. (1994) Horseshoe crab (1,3)-beta-D-glucan-sensitive coagulation factor G. A serine protease zymogen heterodimer with similarities to beta-glucan-binding proteins. J Biol Chem 269:1370–1374.
- Nakamura T, Morita T, Iwanaga S (1985) Intracellular proclotting enzyme in limulus (Tachypleus tridentatus) hemocytes: its purification and properties. J Biochem 97:1561–1574.
For Research Use Only. Not for use in diagnostic procedures.