Background
Diabetes, especially Type 2, has become a world health problem, usually resulting from excessive weight and increased visceral fat. However, other less common forms of diabetes occur, some because of specific genetic alterations. Congenital generalized lipodystrophy (CGL) was first described in Brazil in 1954 by Waldemar Berardinelli in two children [
1], and 5 years later Martin Seip in Norway also described three other similar cases [
2]. Berardinelli-Seip congenital lipodystrophy (BSCL) is clinically characterized by hepatosplenomegaly, fatty liver, altered carbohydrate metabolism, severe insulin resistance, hyperinsulinemia, acromegaloid habitus, and dyslipidemia.
BSCL clinical characteristics and outcome are relatively well known, and new mutations recently described have allowed a better understanding of the disease’s pathophysiology. Currently, the disease is classified into four types according to clinical characteristics and the type of mutations. Genes involved in the pathophysiology of BSCL are responsible for adipogenesis and lipogenesis, including synthesis of triacylglycerol [
3], fusion of lipid droplets [
4], development and maturation of adipocytes [
5].
The BSCL is an autosomal recessive syndrome with around 500 cases reported in the world [
6,
7]. In Brazil, in the State of Rio Grande do Norte, we have diagnosed, treated, and followed 54 cases of BSCL in the past 17 years. The aim of this study was to describe the clinical and laboratory characteristics of a large series of patients with BSCL, correlating the findings with the pathophysiology of the disease.
Discussion
We report a series of patients with BSCL. This is a rare syndrome and case series reported in the literature are usually gathered from patients of several hospitals/clinics [
12,
13]. Our patients are accompanied in a single setting, the endocrinology clinic of the University Hospital Onofre Lopes, in Natal/RN, Brazil. Over the past 17 years, approximately 54 patients were diagnosed and monitored in this hospital. As consanguineous relationships exist in certain regions of our state, every year we still do some new diagnosis of this syndrome. In some cases, this diagnosis is as early as the first year of life, but in others, it may be much later, with the patient already presenting chronic complications of diabetes. We present here an overview of the clinical and laboratory findings of one of the largest series of patients followed in a single medical center, by the same medical team.
Since the phenotype of BSCL is typical (acromegaloid facies, muscle hypertrophy, acanthosis nigricans, decreased body fat, mild enophthalmos, among others), the clinical diagnosis of BSCL is relatively easy but requires a clinical suspicion (Fig.
1). Quite often, parents report that since birth or early in life the child had a different appearance, however, diagnosis is usually delayed. After our first cases, the identification of other cases was easier, since the medical staff became more aware of the potential cases. In addition, families have become pro-active, further facilitating early diagnosis.
Consanguineous marriages are not rare, occurring in about 10 % of the world population [
14]. This significantly increases the risk of developing genetic diseases, like BSCL. In fact, this is one of the most important risk factors in our study. More than two-thirds of our patients (72.4 %) reported consanguinity between parents and more than half (61.4 %) had, at least, one relative affected by the syndrome. The consanguinity rate can be even bigger; one patient only discovered the family relationship of her parents when she searched it until the fourth generation.
The majority of our patients were BSCL Type 2. This could help to explain the low average age of the patients (21 years) since this type is more severe and has a greater predisposition to premature death. AGPAT2 gene is essential in lipogenesis, while BSCL2 is also involved in the differentiation of pre-adipocytes and adipocyte maturation. In this setting, BSCL Type 2 has the most severely affected phenotype, with an almost complete lack of body fat [
15,
16]. We can divide the adipose tissue into metabolic (subcutaneous, intermuscular, intra-abdominal, intrathoracic, bone marrow, etc.) and mechanical (palms, soles, orbits, periarticular). Both (metabolic and mechanical) are decreased in Type 2, while mechanical fat is commonly preserved in Type 1 [
6,
15].
Recently, seipin has been described with functions beyond those in adipose tissue. It seems to be an important protein in spermatogenesis as well as in the nervous system [
17]. Seipin knockout rats have reduced brain weight and infertility with azoospermia [
17]. Some studies have linked seipin defects with motor neuron disease [
18]. Seipin is expressed in the cerebellar cortex, cerebellum, and hypothalamus, and have a significant action on neurotransmission, regulating excitatory synaptic transmission [
16,
19]. There is a tendency for a reduction in brain volume in patients with BSCL2 mutations, but that does not seem to be due to brain atrophy [
17]. In the literature, when evaluated using specific questionnaires, intellectual impairment was more frequent in Type 2 than in Type 1 (78 vs. 10 %) [
20]. We did not assess cognitive function, but it is easy to see during the anamnesis that most BSCL type 2 have this difficulty.
We only had patients with Type 1 or Type 2 BSCL. Due to the small number of Type 1 patients (AGPAT2 gene mutation), the comparison between these types was not possible. Some clinical features can help to differentiate these types. The extreme lack of body fat together with an intellectual deficit favors the clinical diagnosis of Type 2 BSCL. Acanthosis nigricans, acromegaloid facies, prognathism, atrophic cheeks (loss of Bichat’s fat ball), abdominal distension with protruding navel, phlebomegaly, and muscle hypertrophy are other common clinical findings (Fig.
1). Acrochordon, a marker of insulin resistance, is not usual in our patients, perhaps because it is more frequent in patients with higher BMI [
21] and also because adipocytes (lacking in BSCL) are usually seen in the histopathological examination of this lesion. Eruptive xanthomas are not frequent.
In the literature, there are several reports of umbilical hernia in patients with BSCL [
12,
22]. None of our patients required surgery for umbilical hernia repair, and on physical examination, we did not detect any cases of hernia. In contrast, the absence of subcutaneous adipose tissue made the enlargement of the umbilicus very frequent, being present in almost all patients (Fig.
2a). Hepatomegaly may also contribute to the umbilical prominence. This umbilical protrusion can be confused with a hernia and perhaps this may have happened in some cases described in the literature, as we already published [
23].
Usually, in individuals without BSCL, lipids are stored during the feeding state, and this stock is mobilized during fasting. Together with other mechanisms (hypoleptinemia, insulin resistance, etc.), low body fat would explain the increased appetite commonly seen in these patients. Quite often, parents complain about the difficulty of controlling the appetite of their children.
Diagnosis confirmation can be done by searching for one of the known mutations. Of the 44 patients studied in our cohort, 29 were genotyped. Clinical features together with laboratory and imaging (DEXA) tests can help to increase the degree of clinical suspicion. Determination of body fat by DEXA scan is simple and inexpensive. Invariably and consistent with the diagnosis, all of our patients submitted to this test had very low body fat, rarely exceeding 7 %, even in those with higher BMI. Serum leptin measurement is available in many centers with an acceptable cost. Concordant with the very low body fat, serum leptin is usually very low. The combination of clinical features, low body fat measured by DEXA and very low serum leptin can make the diagnosis. Nevertheless, we still advise looking for the mutation, because of the clinical peculiarities of each type.
The majority of our patients were diabetics (67.4 %). This is expected because diabetes usually starts early in this syndrome (mean age 15 years), and the mean age of the group was 21 years. Diabetes was not detected in any affected children under the age of 10 years, and their serum insulin was lower than that of adults. Interestingly, even with higher values of serum insulin, adults develop diabetes. This may indicate that, unlike Type 2 diabetes where the failure to increase insulin secretion by the beta cells is an important factor to the onset of the disease [
24,
25], in patients with BSCL, the increasing insulin resistance appears to be the key determinant. We could hypothesize that with age and difficult to deposit fat in the adipocyte, the lipids are stored in the liver and muscles, reducing insulin sensitivity and requiring higher secretion of the beta cells [
22]. These cells continue to secrete too much insulin, but it does not seem to be enough, and the patient develops diabetes. Serum leptin did not differ between adults and children, being very low in both groups. This confirms that, as an autosomal recessive hereditary disease, BSCL has already started since birth, in contrast to insulin resistance that worsens with age.
The glycemic control of these patients was not good, but this is not a peculiarity of this syndrome. Worldwide and specifically in Brazil, only a small percentage of diabetic patients has good glycemic control. The analysis of a series of more than 5000 type 2 diabetic patients in Brazil showed that the mean HbA1c was 8.6 % and only 26 % had HbA1c <7 % [
26]. The data of our patients were very similar (mean HbA1c 8.3 % and only 30 % with HbA1c <7 %). In recent years, we have been diagnosing the BSCL earlier (some cases even before 1 year of age). We hope this will allow imposing actions that will delay the onset of diabetes, prevent its complications, and improve life expectation.
Hypertriglyceridemia was present in the great majority of patients (42 patients, 95.5 %), being higher in diabetics (330.0 [119.0–1121.0] vs. 190.5 [124.0–422.0] mg/dl, p < 0.05). This is the result of serum accumulation of chylomicron and VLDL as well as excessive hepatic production due to liver steatosis [
27]. The tissue uptake of triglycerides is defective due to the inability of adipocytes to store energy. Moreover, the lipolysis caused by endothelial lipase and stimulated by insulin is attenuated due to insulin resistance [
27]. Although hypertriglyceridemia is common and acute pancreatitis occurs in some patients, this is not a usual cause of death. On the other hand, hypercholesterolemia is not so frequent, and when present, it is mild. Less than one-fourth of patients (10 of 44, 22.7 %) had total cholesterol greater than 200 mg/dl. But we know that patients with hypertriglyceridemia have a higher concentration of small and dense LDL [
28] and, consequently, a higher cardiovascular risk. This can be confirmed in our patients who had a myocardial infarction and atherosclerotic leg ulcers at an early age. HDL cholesterol is always very low, as expected in patients with hypertriglyceridemia, and no patient had HDL higher than 45 mg/dl. Hypertriglyceridemia, low HDL, and small and dense LDL are essential parts of the atherogenic triad seen in metabolic syndrome and also in our patients [
28,
29]. Improvements in the lipid profile seen in patients using metreleptin (an analog of human leptin) confirm the important role of leptin in the treatment of dyslipidemia [
30]. The mechanisms by which leptin improves insulin resistance are not yet known [
22]. It seems that there is a reduction in fat deposition in the liver and muscles [
31]. None of our patients was on metreleptin. Despite its approval for BSCL in other countries, metreleptin is not yet available in Brazil.
Hepatic steatosis is part of the syndrome, but liver enzyme elevation was not frequent in our series. Two-thirds of the patients had liver enzymes within the normal range. We must remember that the aminotransferases are not reliable predictors of steatohepatitis and several patients with normal aminotransferases may have steatohepatitis when undergoing liver biopsy [
32].