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vol. 54
 
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Original paper

Application of molecular imaging combined with genetic screening in diagnosing MELAS, diabetes and recurrent pancreatitis

Wang Zhiping
,
Li Quwen
,
Zhou Hai
,
Zhou Jian
,
Gao Peiyi

Folia Neuropathol 2016; 54 (1): 66-71
Online publish date: 2016/03/31
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Introduction

Mitochondrial myopathy, encephalopathy, lactic acidosis, and stroke-like episodes syndrome (MELAS) are established phenotypes of mitochondrial encephalomyopathy. MELAS has been reported worldwide in recent decades [10,20,22]. It has been confirmed that a mitochondrial DNA (mtDNA) 3243A>G transition was associated with MELAS in most of these patients and that mutations in mtDNA could be useful for revealing the nature of MELAS. However, reports of MELAS combined with pancreatitis are uncommon and its pathogenesis remains unclear. In addition, a misdiagnosis or a missed diagnosis of pancreatitis combined with MELAS could be fatal [1,5]. In this paper, we report on a Chinese family afflicted by MELAS combined with diabetes and recurrent pancreatitis.
MELAS, which forms a major clinical subgroup of the mitochondrial encephalomyopathies, is caused by any of several different single base replacements in the mt tRNALeu(UUR) gene, which is responsible for the translation of UUR (R = A or G) leucine codons in mitochondrial genes [1-5]. It has been reported that 15% of patients with mitochondriopathies have symptoms of digestive disorders [3,7,14]. In contrast, mitochondrial dysfunction in the pancreas frequently results in diabetes mellitus and exocrine insufficiency, but only rarely leads to acute or chronic pancreatitis. Therefore, it was necessary to study the differences between the patients from this pedigree, particularly with regard to the differential diagnosis of pancreatitis.
In recent years, scientific advances have provided us with more comprehensive and objective insights into the pathophysiology of pancreatitis. Since the first discovery of the trypsinogen gene (PRSS1) mutations in hereditary pancreatitis, a variety of gene defects associated with pancreatitis have been reported. Mutations that lead to the generation of more trypsin, or reduce the activity of trypsin inhibitors or trypsin degradation, have been reported to be associated with pancreatitis, either alone or in epistasis. This has broadened the horizon to understand the mechanisms of the disease, and has helped to identify those who are at risk of developing pancreatitis. For many years, inappropriate intra-acinar trypsinogen activation has prevailed as a key initiator of pancreatitis, although the evidence is not direct or concrete [13,17]. Continued experimental studies are necessary to determine the specific relations of trypsin-antitrypsin imbalance and genetic heterogeneity in MELAS.

Material and methods

Patients

This study was approved by the Capital Medical University Committee and Fujian Central for Disease and Prevention Committee and all study participants gave informed consent to DNA analyses. Clinical information for the proband and 4 other family members was obtained by personal interviews using a structured questionnaire and/or clinical trials.

Materials

Mutant loads from the female carriers were assessed using peripheral blood samples and, if possible, urine and/or oral mucosa samples. In addition, hair follicles and muscle tissue were taken from the proband and his mother.

Clinical data

A total of 5 members from the maternal pedigree were included in this survey (Fig. 1): 2 males (II3, III1) and 3 females (I2, II2, II5). We recorded age, height, body weight, and other physiological conditions for the maternal pedigree. Any history of seizures and stroke-like episodes were recorded. Subjects took a Mini-Mental State Examination (MMSE) to evaluate their cognitive function. A standard vision chart, and pure tone and audiometry were used to determine vision and hearing conditions. We also tested ECG, EEG, and EMG. All family members also had tests for plasma lactate while in a resting state and at 15 minutes after a stepping exercise.

DNA extraction and molecular genetic analysis

Genomic DNA was extracted from peripheral blood and other tissue specimens using a QIAamp DNA mini kit (Qiagen, Germany). Three genes involved in pancreatitis – PRSS1, SPINK1, and CFTR – were sequenced according to references [11,12,18]. The mtDNA3243 A>G and PRSS1 c.410 C>T mutations (p.Thr 137 Met) were examined by polymerase chain reaction (PCR) and direct sequencing. For sequencing, a Perkin Elmer Big Dye Sequencing kit (Perkin-Elmer, Shelton, CT, USA) and an ABI PRISM7700 sequencer (Perkin-Elmer ABI, Foster City, CA) were used.

Results

Clinical data and ancillary test

Patient III1, a man born in 1992, had non-insulin-dependent (type 2) diabetes mellitus that began at the age of 16 and pancreatitis that first time occurred at the age of 10. Recent hospitalization was because of paroxysmal unconsciousness, convulsions limbs for 9 days and repeated vomiting for 7 days. The patient was diagnosed with emaciation, memory, computing and understanding power decreased significantly, tendon reflexes slowly and meningeal irritation-positive. CSF pressure was 80 mm H2O, lactic acid was 3.5 mmol/l (normal < 2.1 mmol/l) and sugar, protein and Cl– were normal. Plasma lactate (L) was 3.18 µmol/l, pyruvate (P) was 0.154 µmol/l and the ratio of L/P is 20.60, serum amylase fluctuations were 258-602 U/l. The proband was given control of epilepsy, gastrointestinal decompression and parenteral nutrition and high doses of coenzyme Q and symptoms were improved after treatment. The man strictly follows doctor’s orders and is followed up every 3 months and acquisition of peripheral blood, hair follicle and urine sediment samples from the patients was under the approval of Fujian Medical Ethics Committee.
PCR-RFLP and molecular genetic analysis results are shown in Figure 2 and 3. Heteroplasmy for the A3243G mutation in mtDNA was found in all samples from the affected patients (II2, II3, II5, III1). The proportion of mutated mtDNA varied from 36 to 73%, depending on the tissue analyzed. In selected patients of non-disease state, there were no significant differences in heteroplasmy for the A3243G mutation in mtDNA. In addition, in the affected patients, no mutations were found in the genes coding for PRSS1, SPINK1, and CFTR.

Molecular genetic analysis

Heteroplasmy for the A3243G mutation in mtDNA was found in all samples from the affected patients. The proportion of mutated mtDNA varied from 36 to 73%, depending on the tissue analyzed. In selected patients of non-disease state, there were no significant differences heteroplasmy for the A3243G mutation in mtDNA. In addition, in the affected patients, no mutations were found in the genes coding for PRSS1, SPINK1, and CFTR.

Imaging data

Imaging showed bilateral malacia limb internal capsule, surrounding hemosiderin deposition, symmetry of abnormal signal intensity in the bilateral caudate nucleus, brain atrophy, an inverted lactate peak could be seen in bilateral basal ganglia, bilateral dorsal thalamus and parietal white matter, and the NAA/Cho ratio was not reduced suggesting the local accumulation of lactic acid. His pancreas was fully formed and had a small amount of leakage around it. It had a dilated descending part, considered to be due to an obstruction.

Discussion

The A3243G transition in the MTTL1 mitochondrial gene is the most common pathogenetic mutation found in mtDNA [2,11,12,18]. This mutation is associated with a broad spectrum of clinical manifestations, including mitochondrial encephalomyopathy, lactic acidosis, stroke-like episodic syndrome (MELAS) and maternally inherited diabetes and deafness syndrome (MIDD) [4,8,15,21]. Diabetes mellitus and exocrine insufficiency are the most common pancreatic features of mitochondriopathy. In contrast, to date there have been only six reports of patients with acute or chronic pancreatitis associated with mtDNA mutations. Four of these cases involved the A3243G mutation. Therefore, clinicians should be aware of the possibility of a missed diagnosis or a misdiagnosis of MELAS accompanied by pancreatitis [9]. The molecular diagnostic accuracy of MELAS is directly related to the choice of samples as the mitochondrial mutation load is quite different in different tissues and the mutation load is usually low in peripheral blood [16]. This is because mitochondrial DNA is divided randomly among daughter cells during mitosis and the daughter cells have different proportions of mutant or wild-type mitochondrial DNA.
In this study, urinary sediment cells and oral epithelial cells were collected, which have good diagnostic performance and are convenient samples to be collected for non-invasive screening of the family members of patients. The hair follicle is also a sensitive tissue that has the A3243G point mutation in its mitochondrial DNA. During aging, this mutation will disappear in blood cells, while hair follicles will maintain this mutation and have the advantages of ease of collection and storage, and can also be used to screen asymptomatic family members for genetic counseling.
The diagnosis and differential diagnosis of MELAS should be based on clinical symptoms, molecular biology, iconography, and other comprehensive analyses. The standard for detection is the sequencing of nuclear gene mutations. However, in the field of molecular diagnostics for mitochondrial diseases, owing to the considerably high frequency of mtDNA polymorphisms, which often is the variation due to homogeneity, and the limitations of sequencing, it is considered that those cases with mutation rates of 0-20% or 80-100% can easily be mistaken as homogeneity. Therefore, for the screening of heterogeneous cases, the sequencing method should be used in conjunction with other methods, such as restriction enzyme digestion, PCR primer mismatch, and other methods that can, to some extent, compensate for the disadvantages of sequencing for predicating possible heterozygous mutations. In addition, the proportions of different genotypes can be obtained when using gel scanning technology.
In the clinical diagnosis of mitochondrial disease, because of a variety of internal and external factors, the functional status of mitochondria is enormously diverse and it is difficult to confirm a precise definition of encephalomyopathy from any single aspect of clinical symptoms, pathological or biochemical. MtDNA mutation testing is helpful for diagnosing mitochondrial diseases, but it is not the only means. In recent years, with the rapid development of molecular imaging technology (spectroscopy), the direct finding of a lactate peak (areas of lactic acid accumulation) in the pineal body region using computer integration of data has contributed to the diagnosis of MELAS [19].
Pancreatitis may also be explained by a similar mitochondrial energy defect or vascular dysfunction. Although there is no direct evidence for vascular involvement in the pancreas of patients with the A3243G mutation, it is known that this organ is susceptible to ischemic injury, and perturbations of the systemic and pancreatic micro-vascularization play a significant role in the pathogenesis of pancreatitis [6]. In addition, mitochondrial diseases, including MELAS, are associated with an excess production of reactive oxygen species (ROC), which mostly occurs in the mitochondria as byproducts of oxidative phosphorylation, and has been described as an important factor in the pathogenesis and progression of pancreatitis [23].
In patients with MELAS, non-specific gastrointestinal symptoms, including constipation, stomach upset, liver disease, recurrent vomiting or recurrent pancreatitis, are being increasingly recognized. Different diseases share the same point base mutation leading to an “overlap syndrome” and the same clinical phenotypes can be caused by mutations at multiple sites. This means that it remains unknown whether the clinical symptoms of mitochondrial diseases are caused by a single gene mutation or by the interaction of mutations at different sites and heterogeneity. Thus, there are many problems that remain to be explored.

Disclosure

Authors report no conflict of interest.

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Copyright: © 2016 Mossakowski Medical Research Centre Polish Academy of Sciences and the Polish Association of Neuropathologists. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
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