Primary hypocholesterolaemia is a rare disorder of lipoprotein metabolism that may be due to a polygenic predisposition or a monogenic disease.1,2 We present a case of hypocholesterolaemia that was presented at the XVIII National Meeting on Hypertriglyceridaemia and VIII Meeting of the Lipid Units of the SEA (Toledo), in a closed case format.

A 33-year-old woman referred to the lipid unit for hypocholesterolaemia (LDL<50 mg/dl cholesterol). No personal history of allergies, toxic habits, or surgical interventions. Diagnosed with asthma on treatment with formoterol/budesonide on demand. Her family history included only her father with obesity, diabetes, hypertension, and primary polycythaemia, treated with hydroxyurea, atorvastatin 20 mg, metformin 850 mg/12 h, enalapril 20, bisoprolol 10, and trifusal 1 tablet/day. In the anamnesis, the patient was asymptomatic, without diarrhoea or other gastrointestinal symptoms. On examination, she weighed 58 kg, height 1.51 m, waist circumference 79 cm, blood pressure 130/75 mmHg, no xanthelasmas or xanthomas were found. Neck with good carotid pulses, no murmurs. Cardiac and pulmonary auscultation without abnormalities. Abdomen at the same level as the thorax, soft and depressible, no palpable megalias. Extremities with preserved pulses.

The lipid profile of the patient and her relatives is shown in Table 1; neither the index case nor her relatives showed abnormalities of the liver, thyroid, or renal profile.

An abdominal ultrasound was performed and reported as a normal sized liver with homogeneous echogenicity with no data indicative of hepatic steatosis. The rest of the examination showed no abnormalities.

A diagnostic test was performed.

Based on the information available to us, this would appear to be a case of hypobetalipoproteinaemia, which is defined by the presence of plasma ApoB levels below the 5th percentile for age and sex.3 These analytical disturbances may be secondary or primary. Secondary disturbances include very strict vegetarian diets, chronic alcoholism, or various diseases, such as intestinal malabsorption, liver disease, malnutrition, or hyperthyroidism, and can be secondary to hypolipidemic treatment.4 None of these situations is present in our case, it seems reasonable, therefore, to rule them out.

Primary monogenic causes include abetalipoproteinaemia, familial hypobetalipoproteinaemia, chylomicron retention disease, familial combined hypolipidaemia, and hypobetalipoproteinaemia due to loss of PCSK9 function.2 Among these, a distinction is made between symptomatic and asymptomatic primary hypobetalipoproteinaemia.

Abetalipoproteinaemia is among the symptomatic causes, an autosomal recessive hypolipidaemia (AR) caused by variants of the MTTP gene with very low or almost absent plasma lipid levels and deficiency of fat-soluble vitamins. It is characterised by the presence from the neonatal period of a fat malabsorption syndrome, with steatorrhoea, vomiting, growth retardation, as well as retinitis, severe ataxia, liver disease may develop and acanthocytosis is characteristic. AR inherited chylomicron retention disease caused by mutations in the SAR1B gene and autosomal dominant (AD) homozygous or compound heterozygous familial hypobetalipoproteinaemia caused by mutation of the APOB gene are two diseases that are clinically and biochemically virtually indistinguishable from abetalipoproteinaemia - except for the normal triglyceride (TG) levels of chylomicron retention disease. Therefore, diagnosis of these hypobetalipoproteinaemias would require a genetic study.1,5 In any case, these 3 diseases can reasonably be ruled out in the index case because the patient is asymptomatic.

The asymptomatic hypobetalipoproteinaemias include heterozygous familial hypobetaliproteinaemia,4 inherited by AD due to pathogenic variants in the APOB gene that give rise to truncated proteins. Carrier patients are generally asymptomatic, but may develop liver disease of a steatotic nature with hypertransaminasaemia, low but not undetectable LDL-C, usually below 89 mg/dl, with normal TG concentrations. When the APOB variant is shorter than apoB48, fat absorption is compromised.6 Familial combined hypolipidaemia7 is also asymptomatic, with AD inheritance due to variants in the ANGPTL3 gene. Homozygous cases have very low LDL-C, HDL-C, and TG levels, and heterozygotes have a reduction of approximately 50% in TC, LDL-C, and TG levels, with relatively normal HDL-C. Finally, asymptomatic forms also include familial hypobetaliproteinaemia caused by autosomal dominantly-inherited loss-of-function variants in PCSK9,8 with low but detectable LDL-C levels (21%–40% lower than normal). These 3 asymptomatic hypolipidaemias appear to be associated with decreased cardiovascular risk.

Based on the above, in the case presented, we would rule out familial combined hypolipidaemia because she does not have very low TG concentrations. Furthermore, the homozygous form would have much lower concentrations of TC and LDL-C. Regarding heterozygous familial hypobetalipoproteinaemia, although patients are usually asymptomatic, they may also have liver disease, which seems to be ruled out in the patient and relatives. Therefore, our suspected diagnosis is heterozygous hypobetalipoproteinaemia due to loss-of-function variants in PCSK9.

The diagnostic test was massively parallel sequencing (Genológica, Málaga, Spain) which showed the presence of a reading frameshift variant in exon 9 of PCSK9: c.1378delG; p.Val460Tyrfs (rs749090549), not previously described in the literature and with an allelic frequency <.001. According to the criteria of the American College of Genetic and Genomic Medicine (ACMG), this variant is classified as a variant of uncertain significance as it has a single pathogenicity criterion, due to the reading frameshift produced, and has been found in healthy subjects (https://varsome.com/variant/hg38/rs749090549?annotation-mode=germline). To check whether this variant segregates in the family, samples were taken from the index case, the parents, and a sibling, and were analysed by the High-Resolution Melt (HMR) analysis technique,9 at the Lipids and Arteriosclerosis Laboratory (CIMES, University of Malaga). This methodology made it possible to identify the presence of the variant in the mother and in the sibling analysed, and confirm it in the index case (Fig. 1). The concentration of circulating PCSK9 protein was measured by enzyme-linked immunosorbent assay (Human Protein Convertase 9/PCSK9 Quantikine ELISA Kit [DPC900], R&D Systems®, Inc., Minneapolis, USA). Optical density was read at a wavelength of 450 nm using the SPECTROstar Nano microplate reader (BMG Labtech, gmbh, Offemburg, Germany). Sample concentrations were determined by interpolation from the standard curve generated with the standard samples supplied by the manufacturer with a 1:20 dilution of the serum samples (BiosferTeslab Laboratory, Reus, Tarragona, Spain). The results show that the carriers of the identified variant had lower concentrations than usual, given that, with the assay used, the normal values are 313 ± 71.5 ng/mL.

Figure 1.

Genealogical tree of the family studied. Black shading indicates the presence of the PCSK9 loss-of-function variant in heterozygosis. Circulating levels of LDL cholesterol (Co) (mg/dl) and PCSK9 (ng/mL) are shown.

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The following comments are pertinent to the present case. Familial hypobetalipoproteinaemia is rare but cannot be considered a rare disease. Recent data from the UK Biobank and the American NHBLI, on a total of 209,537 samples, indicate that 0.4% of these correspond to patients with variants that produce truncated proteins in apolipoprotein B or PCSK9, the latter being more frequent than the former.10 Finally, in terms of vascular risk, the presence of familial hypobetalipoproteinaemia reduces the risk significantly, by 80% and 50%,8,10 therefore prevention strategies should be maintained in these patients.

In summary, we present a case of asymptomatic familial hypobetalipoproteinaemia due to a loss-of-function variant in the PCSK9 gene.

The group's own funds (CTS-159) from the Andalusian Plan for Research, Development and Innovation (PAIDI).

The University of Málaga/CBUA funded the open publication of this article.

The authors have no conflict of interests to declare.