Chapter 18 - Laboratory diagnosis of Niemann–Pick disease type C: The filipin staining test

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Abstract

Niemann–Pick disease type C (NPC) is an atypical neurovisceral lysosomal storage disorder resulting from mutations in either the NPC1 or the NPC2 gene, currently conceived as a lipid trafficking disorder. Impaired egress of cholesterol from the late endosomal/lysosomal (LE/L) compartment is a key element of the pathogenesis. The resulting accumulation of unesterified cholesterol in the LE/L compartment can be visualized by fluorescence microscopy after staining with filipin. The “filipin test,” performed on cultured fibroblasts, is the historical gold standard method to establish the diagnosis in patients. The authors provide methodological details of the protocol developed and used in their laboratory since 1988, in which two sources of low-density lipoproteins (LDL) (total serum and pure LDL) are used in parallel to facilitate the final interpretation. Methodological caveats and variability of patterns encountered in patients with proven Niemann–Pick C disease (typical “classic” or “intermediate,” atypical “variant”) are described. An overview of the past 5 years referrals (533 subjects tested, 57 NPC cases, but also 74 mildly/weakly positive tests not due to NPC) is discussed, leading to a proposed algorithm for interpretation of results in the filipin test. This tool takes into account the limits of the method. In up to 15% of all referrals, the filipin test was inconclusive in absence of molecular analysis. Patients diagnosed in the adult age preferentially showed an “intermediate” or “variant” pattern. Well conducted, the filipin test remains an efficient approach for diagnosing NPC, and it is a good functional test to study the pathogenicity of novel mutations.

Section snippets

Introduction and Rationale

Niemann–Pick disease type C (NPC) is an atypical lysosomal storage disorder with wide clinical heterogeneity, resulting from mutations in one of two genes, either NPC1 or NPC2 (Patterson et al., 2012, Vanier, 2010). Not an enzyme deficiency, it is currently conceived as a lipid trafficking disorder. Initial studies by Peter Pentchev and associates and further work from several laboratories (Patterson et al., 2001, Pentchev et al., 1994) demonstrated, in cultured skin fibroblasts of patients, a

Materials

  • 1.

    A cell culture unit with a CO2 cell culture incubator and an inverted microscope (if possible with phase contrast equipment).

  • 2.

    An epifluorescence-equipped microscope with an x20 or x25 (and if possible x40) fluo-objectives, and a UV-filter suitable to observe the fluorescence of filipin–cholesterol complexes (excitation 364 nm; emission 475 nm).

The authors have successively used a Leitz Ortholux with a B2 combined filter (excitation filter BP 350-410; Barrier filter LP 470); a Zeiss Axioscop 2 with

General Considerations

Filipin staining itself is a very straightforward procedure, but when the aim is to optimally diagnose NPC, all steps preceding the final staining are critical. Furthermore, fluorescence microscopic evaluation of the results must follow strict rules, since in a small subset of patients, results can overlap with those seen in NPC heterozygotes or patients with other conditions.

The protocol described below was established in the Lyon laboratory in 1988 to adapt the research method to a clinical

Less than optimal or inappropriate conditions for fluorescence microscopic examination

Selecting a proper and sufficiently specific filter is of course essential. This should be checked by examination of a filipin-stained slide from a known “classic” positive control. Other practical considerations related to the use of filipin have been discussed in a previous issue of Meth. Cell Biol. (Maxfield & Wüstner, 2012): an important fact is that filipin is rapidly photobleached with the UV light intensity of most fluorescence microscopes. We fully agree with these authors that

Concluding Remarks

Interpretation can be difficult in a subset (about 15%) of all NPC patients showing a “variant” filipin pattern. This profile is more common in adult onset patients, which are often clinically less typical. Mild alterations of intracellular cholesterol trafficking can also be seen in a variety of other pathological conditions, which further complicates the situation. These inconclusive results occur in about 15% of all referrals, and require complementary sequencing of the NPC1 and NPC2 genes.

Acknowledgments

The authors wish to acknowledge the unfailing expert technical assistance of Ms Marie-Christine Juge, Ms Heliane Cornot, and Ms Guenaelle Piguet-Lacroix throughout the years.

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