Molecular Basis of Familial and Sporadic Alzheimer's Disease.

Alzheimer's disease (AD) is a multifactorial disease with genetic (70%) and environmental (30%) causes. Among the genetic factors are genes associated with a family history of the disease (familial AD, FAD) and sporadic AD (SAD). The genes: APP (amyloid precursor protein), PSEN1 (Presenilin 1) and PSEN2 (Presenilin 2) are responsible for the presence of FAD. The APOE gene is responsible for the sporadic form of the disease. Other molecular factors related to the immunological cause (TREM2) of the disease are a disorder of the lipid (ABCA1, ABCA7) or biothiol (MTHFD1) metabolism and of the transport of metabolites (BIN1). Currently, it is believed that APOE is a risk factor for both SAD and late-onset FAD. The pathomechanism of AD is most commonly explained as based on the amyloid cascade theory. This theory is related to the FAD, although there are reports indicating the probability of its occurrence in the SAD. It seems that the excessive deposition of ß-amyloid (Aß) peptides and intracellular neurofibrillary tangles of tau protein hyperphosphorylated forms contribute to the damage of both DNA and RNA. Furthermore, it is believed that RNA-interference can affect both the level of pathological proteins (Aß, tau protein) and the onset and progress of AD. It seems that a complete understanding of both FAD and SAD pathogenesis may contribute to the search for earlier clinical diagnosis and to an understanding of later occurrence of the disease, which may help modify its course and affect more effective therapy of this incurable neurological disease.

Analysis of PRKN Variants and Clinical Features in Polish Patients with Parkinson's Disease.

The etiology of Parkinson's disease (PD) is still unclear, but mutations in PRKN have provided some biological insights. The role of PRKN mutations and other genetic variation in determining the clinical features of PD remains unresolved. The aim of the study was to analyze PRKN mutations in PD and controls in the Polish population and to try to correlate between the presence of genetic variants and clinical features. We screened for PRKN mutations in 90 PD patients and 113 controls and evaluated clinical features in these patients. We showed that in the Polish population 4% of PD patients had PRKN mutations (single or with additional polymorphism) while single heterozygous polymorphisms (S167N, E310D, D394N) of PRKN were present in 21% of sporadic PD. Moreover, 5% PD patients had more than one PRKN change (polymorphisms and mutations). Detected PRKN variants moderately correlated with PD course and response to L-dopa. It also showed that other PARK genes (SNCA, HTRA2, SPR) mutations probably may additionally influence PD risk and clinical features. PRKN variants are relatively common in our Polish series of patients with PD. Analysis of the PRKN gene may be useful in determining clinical phenotype, and helping with diagnostic and prognostic procedures in the future.

[Alpha-synuclein in Parkinson's disease]. / Alfa-synukleina w chorobie Parkinsona.

Parkinson's disease (PD) is a degenerative disease of the central nervous system, of which patomechanizm entirely is not clear. In the picture neuropathologically there is observed degeneration and loss of dopaminergic neurons, but also noradrenergic, serotonergic and cholinergic neurons in patients with PD. It is believed, that causes of PD are both environmental and genetic factors, associated mainly with mutations in the SNCA and PRKN genes, which may lead to changes in the structure of proteins such as alpha-synuclein (ASN) and Parkin. In neurons, disorders of the protein structure can lead to its aggregation and formation of soluble oligomers and insoluble filaments in the form of Lewy bodies and Lewy neuritis. In PD aggregation of ASN can be modulated by many factors like: oxidative stress, other neuronal proteins, Parkin, catecholamines especially dopamine, and mutations of SNCA gene. It also appears that some impact on the aggregation of ASN may have destabilizing factors of ASN tetramers. That, does ASN may become a new point for pharmacotherapy in PD.

Mutations in the exon 7 of Trp53 gene and the level of p53 protein in double transgenic mouse model of Alzheimer's disease.

Alzheimer's disease (AD) leads to generation of ß-amyloid (Aß) in the brain. Alzheimer's disease model PS/APP mice show a markedly accelerated accumulation of Aß, which may lead to apoptosis induction e.g. in cells expressing wild-type p53. The TP53 gene is found to be the most frequently mutated gene in human tumour cells. There is accumulating evidence pointing out to the contribution of oxidative stress and chronic inflammation in both AD and cancer. The purpose of this study was to analyze exon 7 mutations of the murine Trp53 gene and Aß/A4 and p53 protein levels in PS/APP and control mice. The studies were performed on female double transgenic PS/APP mice and young adults (8-12 weeks old) and age-matched control mice. The Trp53 mutation analysis was carried out with the use of PCR and DNA sequencing. The Aß/A4 and p53 levels were analyzed by Western blotting. The frequency of mutations was almost quadrupled in PS/APP mice (44%), compared to controls (14%). PS/APP mice with the A929T and A857G mutations had a similar p53 level. In cerebral gray matter of PS/APP mice the level of p53 positive correlated with the level of Aß protein (RS = +0.700, p < 0.05). In younger control animals, the T854G mutation was related to p53 down-regulation, while in aging ones, G859A substitution was most likely associated with over-expression of p53. In silico protein analysis revealed a possibly substantial impact of all four mutations on p53 activity. Three mutations were in close proximity to zinc-coordinating cysteine residues. It seems that in PS/APP mice missense Trp53 exon 7 mutations may be associated with the degenerative process by changes of p53 protein function.

Serum homocysteine levels are decreased in levothyroxine-treated women with autoimmune thyroiditis.

BACKGROUND: Hyperhomocysteinemia is a well-known cardiovascular risk factor and its elevation is established in overt hypothyroidism. Since some authors suggest that chronic autoimmune thyroiditis per se may be considered as a novel risk factor of atherosclerosis independent of thyroid function, the analysis of classical cardiovascular risk factors might be helpful in evaluation the causative relationship. Data concerning the impact of thyroid autoimmunity in euthyroid state on homocysteine (Hcy) level is lacking. The aim of this study was to evaluate Hcy level in context of anti-thyroperoxidase antibodies (TPOAbs) in euthyroidism. METHODS: It is a case-control study. 31 euthyroid women treated with levothyroxine (L-T4) due to Hashimoto thyroiditis (HT) and 26 females in euthyroidism without L-T4 replacement therapy were enrolled in the study. All women with HT had positive TPOAbs. Forty healthy females negative for TPOAbs comparable for age and body mass index (BMI) participated in the study as controls. Exclusion criteria were a history of any acute or chronic disease, use of any medications (including oral contraceptives and vitamin supplements), smoking, alcoholism. RESULTS: TPOAbs titers were higher in both groups of HT patients versus the healthy controls. Hcy levels were found to be significantly lower in treated HT patients (Me 11 µmol; IQR 4.2 µmol) as compared with healthy controls (Me 13.35 µmol; IQR 6.34 µmol; p = 0.0179). In contrast, no significant difference was found between non treated HT and control group in Hcy level. The study groups and the controls did not differ in age and BMI. Furthermore, levels of TSH, FT4, TC, LDL, HDL and TAG did not differ between the study group and the control group. CONCLUSION: The main finding of the study is a decrease in Hcy level in treated HT as compared with healthy controls. Based on our observations one can also assume that correct L-T4 replacement was associated here with a decrease of Hcy. Furthermore, it seems that non treated HT in euthyroidism is not associated with Hcy increase, in contrast to overt hypothyroidism. This may be just another argument against the concepts about the role of "euthyroid HT" in the development of atherosclerosis.

Genetic variants in diseases of the extrapyramidal system.

Knowledge on the genetics of movement disorders has advanced significantly in recent years. It is now recognized that disorders of the basal ganglia have genetic basis and it is suggested that molecular genetic data will provide clues to the pathophysiology of normal and abnormal motor control. Progress in molecular genetic studies, leading to the detection of genetic mutations and loci, has contributed to the understanding of mechanisms of neurodegeneration and has helped clarify the pathogenesis of some neurodegenerative diseases. Molecular studies have also found application in the diagnosis of neurodegenerative diseases, increasing the range of genetic counseling and enabling a more accurate diagno-sis. It seems that understanding pathogenic processes and the significant role of genetics has led to many experiments that may in the future will result in more effective treatment of such diseases as Parkinson's or Huntington's. Currently used molecular diagnostics based on DNA analysis can identify 9 neurodegenerative diseases, including spinal cerebellar ataxia inherited in an autosomal dominant manner, dentate-rubro-pallido-luysian atrophy, Friedreich's disease, ataxia with ocu-lomotorapraxia, Huntington's disease, dystonia type 1, Wilson's disease, and some cases of Parkinson's disease.

Mutations in PRKN and SNCA Genes Important for the Progress of Parkinson's Disease.

Although Parkinson's disease (PD) was first described almost 200 years ago, it remains an incurable disease with a cause that is not fully understood. Nowadays it is known that disturbances in the structure of pathological proteins in PD can be caused by more than environmental and genetic factors. Despite numerous debates and controversies in the literature about the role of mutations in the SNCA and PRKN genes in the pathogenesis of PD, it is evident that these genes play a key role in maintaining dopamine (DA) neuronal homeostasis and that the dysfunction of this homeostasis is relevant to both familial (FPD) and sporadic (SPD) PD with different onset. In recent years, the importance of alphasynuclein (ASN) in the process of neurodegeneration and neuroprotective function of the Parkin is becoming better understood. Moreover, there have been an increasing number of recent reports indicating the importance of the interaction between these proteins and their encoding genes. Among others interactions, it is suggested that even heterozygous substitution in the PRKN gene in the presence of the variants +2/+2 or +2/+3 of NACP-Rep1 in the SNCA promoter, may increase the risk of PD manifestation, which is probably due to ineffective elimination of over-expressed ASN by the mutated Parkin protein. Finally, it seems that genetic testing may be an important part of diagnostics in patients with PD and may improve the prognostic process in the course of PD. However, only full knowledge of the mechanism of the interaction between the genes associated with the pathogenesis of PD is likely to help explain the currently unknown pathways of selective damage to dopaminergic neurons in the course of PD.

Polymorphism of the COMT, MAO, DAT, NET and 5-HTT Genes, and Biogenic Amines in Parkinson's Disease.

Epinephrine (E) and sympathetic nerve stimulation were described by Thomas Renton Elliott in 1905 for the first time. Dopamine (DA), norepinephrine (NE), E, and serotonin (5-HT) belong to the classic biogenic amines (or monoamines). Parkinson's disease (PD) is among the diseases in which it has been established that catecholamines may account for the neurodegeneration of central and peripheral catecholamine neural systems. PD is a chronic and progressive neurological disorder characterized by resting tremor, rigidity, and bradykinesia, affecting 2% of individuals above the age of 65 years. This disorder is a result of degeneration of DA-producing neurons of the substantia nigra and a significant loss of noradrenergic neurons in the locus coeruleus. In PD and other related neurodegerative diseases, catecholamines play the role of endogenous neurotoxins. Catechol-O-methyltransferase (COMT) and/or monoamine oxidase (MAO) catalyze the metabolism of monoamines. However, the monoamine transporters for DA, NE, and 5-HT namely DAT, NET, and SERT, respectively regulate the monoamine concentration. The metabolism of catecholamines and 5-HT involves common factors. Monoamine transporters represent targets for many pharmacological agents that affect brain function, including psychostimulators and antidepressants. In PD, polymorphisms of the COMT, MAO, DAT, NET, and 5- HTT genes may change the levels of biogenic amines and their metabolic products. The currently available therapies for PD improve the symptoms but do not halt the progression of the disease. The most effective treatment for PD patients is therapy with L-dopa. Combined therapy for PD involves a DA agonist and decarboxylase, MAOs and COMT inhibitors, and is the current optimal form of PD treatment maintaining monoamine balance.