PNH results from the loss of GPI-anchored proteins, leading to complement-mediated destruction of blood cells that can be accurately detected by high-sensitivity flow cytometry.
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Paroxysmal Nocturnal Hemoglobinuria (PNH) is a rare disorder that causes the destruction of blood cells: red blood cells (erythrocytes), which are responsible for oxygen transport; white blood cells (leukocytes), cells of the immune system; and platelets (thrombocytes), cell fragments that play a role in blood clotting and tissue repair.
PNH is characterized, as its name suggests, by the presence of hemoglobin in the urine (hemoglobinuria) in an intermittent (paroxysmal) and nighttime (nocturnal) pattern; this hemoglobin comes from destroyed red blood cells (hemolysis).
Related conditions: The early destruction of healthy cells can lead to several disorders:
Cause and mechanism of the disease: Cell destruction occurs through activation of the complement system, an innate immune system. This system is based on certain circulating proteins that bind to a pathogen through different activation pathways; this triggers a cascade of multiple reactions involving proteins, convertase enzymes, and protein-derived fragments. The chain reaction culminates in the formation of a Membrane Attack Complex (MAC), composed of several linked fragments that perforate and destroy the target cell.
Fragments of the complement system’s proteins that bind to the target in order to eliminate it.
Certain proteins require a GPI anchor to bind to the membrane.
Glycosylphosphatidylinositol (GPI) is a glycolipid that acts as an anchor between a protein and the cell membrane. It is synthesised by a series of proteins encoded by PIG (phosphatidylinositol glycan) genes.
Some surface proteins are directly attached to the cell membrane via the protein’s own transmembrane domains; they do not rely on other anchoring mechanisms, such as GPI.
The Membrane Attack Complex is the final structure of the complement system, formed by the sequential assembly of its fragments. The purpose of this complex is to perforate the membrane, thereby causing cell lysis.
With the formation of the MAC, the lytic function of the complement system is completed, leading to membrane destruction and cell death.
In healthy cells, protective proteins are expressed against the alternative complement pathway (mediated by the C3 protein). CD55 inhibits the activity of C3 and C5 convertase enzymes; CD59 prevents the formation of the MAC. These and other proteins are attached to the cell membrane via a docking molecule called GPI (glycosylphosphatidylinositol). Proteins that depend on GPI for membrane attachment are called GPI-APs (GPI-anchored proteins); proteins that do not depend on this attachment are called transmembrane proteins, because they contain their own domains that enable direct membrane anchoring.
The synthesis of GPI is organized by several proteins encoded by PIG genes (phosphatidylinositol glycan). PNH is generally associated with a mutation in the class A PIG gene (PIGA), which prevents the formation of the molecule and therefore the attachment of GPI-APs to the cell. Without proteins that protect the cell from complement, it becomes vulnerable to attack, leading to PNH. During the night, blood acidification enhances the alternative complement pathway, increasing hemolysis (hence the disease’s paroxysmal nocturnal character).
There are other mutations that can also lead to PNH, such as a mutation in PIGT. In this case, the deficiency of GPI-APs is not due to the absence of GPI (which is still formed), but because PIGT mediates the binding between GPI and GPI-AP. Although the effects are similar, this form of PNH (PIGT-PNH) presents with autoinflammatory symptoms.
The gold standard diagnostic test for PNH is flow cytometry. This test is carried out once other possible causes of anaemia have been ruled out and following a negative result in the direct Coombs test (direct antiglobulin test or DAT), which detects the presence of antibodies on the surface of red blood cells in cases of haemolysis.
PNH clones that is, populations that test positive for the disease can be classified according to their symptoms:
Another possible classification relates to the level of GPI expression:
Finally, they can be classified according to the clone size analysed within a target population:
A diagnosis of PNH may refer to a combination of characteristics of the cells analysed, namely whether or not PNH clones are present, the size of the detected clone (the ratio of healthy to diseased cells) and the level of GPI expression in that clone.
The severity of the disease increases with a larger clone size (complete PNH+ or high partial PNH+) and a greater absence of GPI (Type III).
In erythrocytes, a GPI-independent marker is used for comprehensive identification; this is CD235a. CD59 (and/or CD55) is then used to assess the level of GPI expression. GPI deficiency may be complete or partial; therefore, erythrocytes are classified according to GPI-AP expression: Type I, Type II and Type III. (Figure 1, A).
Subsequently, the size of the PNH-positive clones (Type II and Type III) is assessed to determine the extent of the disease, i.e. whether all cells are diseased (complete PNH+) or whether some are healthy (partial PNH+), and what the ratio of diseased to healthy cells is. (Figure 1, B)
Figure 1. A) Identification of CD235a+ erythrocyte subtypes according to their level of CD59 expression. B) Analysis of the size of each cell type.
Fluorescein-Labelled Aerolysin is a fluorescently labelled bacterial toxin. This toxin binds specifically to GPI.
A carbohydrate found in abundance in neutrophils; although it is also present in monocytes and eosinophils, its expression is lower and it can be easily distinguished from neutrophils.
A transmembrane protein, GPI-independent, specific to the monocyte population.
GPI-AP which is present in myeloid cells.
A transmembrane protein present in all white blood cells (pan-leukocyte marker).
A pan-leukocyte marker, CD45, is used to detect leukocytes (Figure 2, A). The populations of interest are then separated using specific markers: CD15 for neutrophils (Figure 2, B) and CD64 for monocytes (Figure 2, C). These three markers are GPI-independent. PNH clones are identified using GPI-AP, CD157 (common to myeloid lineage cells, such as neutrophils and monocytes), and FLAER, a molecule that binds specifically to GPI. When used in combination, the clone size and the level of expression can be assessed.
The FLAER/CD157 analysis can yield several interpretations:
In leukocytes, analysis of the clone size is relevant; the level of expression is more easily analysed in erythrocytes, although it can also be carried out there.
Figure 2. Analysis of PNH clones in leukocytes. A) Separation of CD45+ leukocytes into two populations of interest: monocytes (CD64+/CD15-) and neutrophils (CD15+/CD64-). B) and C) Identification of neutrophils (B) and monocytes (C), depending on whether they are healthy cells (FLAER+/CD157+, DP) or pathological cells (FLAER-/CD157-, DN).
For all product codes, blue and red lasers are sufficient, with the exception of product codes PNHWBC-25T and LYOPNHWBC-25T; these product codes contain a CFBlue marker, which corresponds to the violet laser.
Freeze-drying or drying the reagents reduces the need for handling and improves reproducibility. A flow cytometer tube is supplied with the reagent mixture at the bottom, ready for the sample to be added and incubated, thereby avoiding variability caused by pipetting and handling the original vial.