Olga Labudova

Homocysteine Increases Cyclin-Dependent Kinase in Aortic Rat Tissue

BACKGROUND Hyperhomocyst(e)inemia is strongly associated with occlusive arterial disease. A direct effect of homocysteine on the proliferation of smooth muscle cells was proposed recently. This observation led us to examine the effect of homocysteine on cyclin-dependent kinase, the starter of mitosis and reflecting proliferation. METHODS AND RESULTS Seventy Him:OFA rats were divided into seven groups. For 12 weeks, 10 rats were fed homocysteine 25 mg/kg body weight per day, 10 were fed 50 mg/kg body wt per day, and 10 were fed 100 mg/kg body weight per day; 10 were given homocysteic acid 100 mg/kg body weight per day, 10 were administered cysteine 100 mg/kg body weight per day, and 10 were given ascorbic acid 270 mg/kg body weight per day. Ten remained untreated and served as controls. Aortic cyclin-dependent kinase was determined at the transcriptional (mRNA) and protein levels. Phosphokinase C and aortic homocyst(e)ine also were evaluated in aortic tissue. Aortic cyclin-dependent kinase protein was significantly (P = .0001) elevated in the three homocysteine-treated groups, and mRNA cyclin-dependent kinase levels were significantly elevated in the rats given the 50 and 100 mg/kg body weight per day protocol. Endothelial damage was shown at higher homocysteine doses as reflected by circulating ACE and von Willebrand factor changes. Proliferation of cells of the aortic wall by bromodeoxyuridine incorporation could be shown in the high-dose homocysteine group only. CONCLUSIONS Our findings indicate that homocysteine specifically stimulates aortic cyclin-dependent kinase at the transcriptional level, with the possible consequence of proliferation of aortic cells as revealed by incorporation of bromodeoxyuridine in the aortic wall.

Increased glyceraldehyde 3-phosphate dehydrogenase levels in the brain of patients with Down's syndrome

Impaired glucose metabolism in Downs syndrome (DS) has been well-documented in vivo, although information on the underlying biochemical defect is limited and no biochemical studies on glucose handling enzymes have been carried out in the brain. In a previous study, we found by gene hunting in DS brain an overexpressed sequence homologous to the glyceraldehyde 3-phosphate dehydrogenase (G3PD) gene. Here we studied G3PD activity and expression levels, using two-dimensional gel analysis, in five brain regions of patients with DS and Alzheimers disease (AD). The protein expression levels in four brain areas were approximately 1.5-fold higher in patients with DS in comparison with the controls. G3PD activity was significantly elevated in the frontal, parietal, occipital and temporal lobe of DS as well, but not in the corresponding AD brain regions. We conclude that our biochemical findings complement previously published data of impaired brain glucose metabolism in DS evaluated by positron emission tomography in clinical studies.

Expression of DNA excision-repair-cross-complementing proteins p80 and p89 in brain of patients with Down Syndrome and Alzheimer's disease

Although deficient DNA repair was proposed for neurodegenerative disorders including Down syndrome (DS), repair proteins for nucleotide excision repair have not been studied in brain yet. As one of the hypotheses for the pathogenesis of brain damage in DS and Alzheimers disease (AD), is oxidative stress, and cells of patients with DS were shown to be more susceptible to ionizing irradiation. We decided to study expression of excision repair-cross-complementing (ERCC) gene products, proteins 80 and 89, representatives of repair genes known to be involved in the repair of different types of DNA damage. ERCC2-protein 80 kDa and ERCC3-protein p89 were determined in five individual brain regions of controls, aged DS and AD patients. Although different in the individual regions, DNA repair proteins were consistently higher in temporal and frontal lobes of patients with DS and higher in all brain regions of patients with AD. Our results are the first to describe DNA repair gene protein patterns in human brain regions providing the basis for further studies in this area. We showed that DNA repair genes ERCC2 and ERCC3 (excision-repair-cross-complementing) for nucleotide excision repair were increased at the protein level with the possible biological meaning that this increase may be compatible with and indicate ongoing (oxidative?) DNA damage.

mRNA levels of the hypoxia inducible factor (HIF-1) and DNA repair genes in perinatal asphyxia of the rat.

Hypoxia inducible factor 1 (HIF-1) is a transcription factor which is expressed, when mammalian cells are subjected to hypoxia, activating the transcription of genes encoding proteins thought important for maintaining oxygen hemostasis. The aim of the study was to evaluate HIF-1 mRNA levels in a non-invasive model of perinatal asphyxia (PA). Brain was taken for studies on HIF-1 alpha and beta 10 min following the asphyctic period. To rule out influences by the redox status we also determined antioxidant enzyme mRNA levels for superoxide dismutase, catalase, glutathion peroxidase and performed electron spin resonance studies. To study the link to protein phosphorylation as previously proposed, we evaluated mRNA levels for protein kinase C. As DNA breaks were reported to occur in PA, we determined mRNA levels of two genes representing DNA nucleotide excision repair, ERCC2 and ERCC3, and a DNA repair gene involved in the repair of oxidation mediated DNA damage, XRCC1. mRNAs for HIF-1 were not detectable following 5-20 minutes of asphyxia. The antioxidant enzymes did not show any changes during the asphyctic periods either and electron spin resonance failed to detect the presence of the hydroxyl radical. PKC significantly decreased with the length of the asphyctic period. ERCC2 and XRCC1 mRNAs were inducible during the acute phase of asphyxia indicating early repair phenomena. HIF-1 may not be relevant for periods of PA up to 20 minutes, the maximal survival time in our model. Neonatal factors may be responsible for that phenomenon although we cannot rule out that HIF-1 changes may occur at the protein level.

Thyroid stimulating hormone — Receptor overexpression in brain of patients with Down Syndrome and Alzheimer's disease

Thyroid hormone abnormalities are strongly associated with Down Syndrome (DS) with elevated thyroid stimulating hormone (TSH) levels as the most consistent finding. Using subtractive hybridization for gene hunting we found significant overexpression of mRNA levels for the TSH-receptor (TSH-R) in brain of a fetus with DS. Based upon this observation we determined TSH-R protein levels in five brain regions of patients with DS (n=8), Alzheimer disease (AD, n=8) and controls (C, n=8). Western blots revealed significantly elevated immunoreactive TSH-R protein(s) 40 kD and 61 kD in temporal and frontal cortex of patients with DS and, unexpectedly, in AD. Levels for the 40 kD protein in temporal cortex were 1.00+/-0.036 (arbitrary units+/-SD) in C, 1.35+/-0.143 in DS, 1.52+/-0.128 in AD; in frontal cortex: 1.00+/-0.046 in C, 1.10+/-0.03 in DS, 1.10+/-0.038 in AD. Levels for the 61 kD protein in temporal cortex were 1.01+/-0.015 in C, 1.47+/-0.013 in DS, 1.623+/-0.026 in AD; in frontal cortex: 1.02+/-0.020 in C, 1.18 +/-0.123 in DS, 1.48+/-0.020 in AD. These results show that elevated brain immunoreactive TSH-R is not specific for DS and maybe reflecting apoptosis, a hallmark of both neurodegenerative disorders, as it is well-documented that the thyroid hormone system is involved in the control of programmed cell death.

Decrease of heart protein kinase C and cyclin-dependent kinase precedes death in perinatal asphyxia of the rat.

Acidosis, energy depletion, overstimulation by excitatory amino acids, and free radical‐mediated reactions are the major current concepts for the explanation of damage and death resulting from asphyxia. Impaired phosphorylation by protein kinase C (PKC) represents another mechanism incriminated for cell death. We used an unsophisticated perinatal asphyxia model to study heart protein kinases PKC and cyclin dependent kinase (CDK). Tissue pH, ATP, the antioxidant enzymes superoxide dismutase, catalase, and glutathion peroxidase, lipid peroxidation products, carbonyls, and aromatic hydroxyiation were also tested. Electron spin resonance was applied to demonstrate the possible presence of radical adducts. An ELISA method was used to determine cell death. PKC activity and mRNA decreased with the length of the asphyctic periods and were paralleled by CDK and pH, whereas cell death gradually increased. No evidence was found for the involvement of active oxygen species or a radical adduct, and no energy depletion was observed. We conclude that impaired protein phosphorylation and/or acidosis may play a role in the pathobiochemistry of death from perinatal asphyxia in the rat.—Lubec, B., Marx, M., Herrera‐Marschitz, M., Labudova, O., Hoeger, H., Gille, L., Nohl, H., Mosgoeller, W., Lubec, G. Decrease of heart protein kinase C and cyclin‐dependent kinase precedes death in perinatal asphyxia of the rat FASEB J. 11, 482–492 (1997)

Expression of Transcription Factors in the Brain of Rats with Perinatal Asphyxia

No information is available on transcription factors (TF), the main regulators of gene expression, in perinatal asphyxia (PA), and as pathomechanisms in PA are different, data on TFs from ischemia or hypoxia cannot be simply extrapolated to PA, and no studies have been reported to show an expressional pattern or the concerted action of TFs. We, therefore, used a gene-hunting technique, subtractive hybridization, to show sequences different in brains of normoxic and perinatally asphyxiated (10 and 20 min of asphyxia) rats. These subtracted sequences were identified by gene bank and assigned to individual genes. At 10 min of PA the TFs NFI/CAAT-binding protein, NF-kappa-B p65, N-myc, basic helix loop helix protein D82868, and c-myc intron binding protein were upregulated. At 20 min of PA the TFs SOX4 and neuronal death factor were upregulated, whereas the TFs c-maf, PEBP major transcription factor, brn-2, homeodomain protein Af004431, and zinc finger transcriptional factor M65008 were downregulated. The biological meaning of our findings is the demonstration of a pathophysiological pattern of TFs including POU, zinc finger, homeodomain, and basic helix-loop helix motifs in PA, proposing pathomechanisms for brain damage from PA, explaining transcriptional changes in general (as, e.g., NF-kappa-B p65, etc.) or in specific terms (as, e.g., neuronal death factor).

Decreased transcription factor junD in brains of patients with Down syndrome.

JunD is a member of the Jun family of transcription factors (TF), recently shown to negatively regulate cell growth and antagonizes transformation by the protooncogene ras: c-jun decreases while junD is accumulating when fibroblasts become quiescent. Furthermore, overexpression of junD resulted in slower growth and an increase in cells in G0/G1. Performing gene hunting on fetal Down syndrome (DS) brain we found a sequence downregulated and homologous to junD. This observation made us examine junD protein levels in adult brain specimens. Western blot experiments were carried out in five brain regions of aged patients with DS (n = 9), controls (n = 9) and patients with Alzheimers disease (AD, n = 9). We found that junD in AD brains were comparable to controls, whereas junD levels were significantly and remarkably reduced in frontal, temporal lobe and cerebellum of patients with DS. These findings may indicate a specific finding in DS and were not linked to the AD-like-neuropathological changes of plaques and tangles, observed in DS from the fourth decade, which is also suggested by the findings of downregulated junD at the mRNA level revealed by the gene hunting technique (subtractive hybridization) in fetal DS brain. We propose that junD plays a role for the impaired development and wiring of DS brain, maybe already early in life.

Increased steady state mRNA levels of DNA-repair genes XRCC1, ERCC2 and ERCC3 in brain of patients with Down syndrome.

Although deficient DNA-repair was proposed for neurodegenerative disorders including Down Syndrome (DS), repair genes for nucleotide excision repair or X-ray repair have not been studied in brain yet. As one of the hypotheses for the pathogenesis of brain damage in DS is oxidative stress and cells of patients with DS are more susceptible to ionizing irradiation, we decided to study ERCC2, ERCC3 and XRCC1, representatives of repair genes known to be involved in the repair of oxidative DNA-damage. mRNA steady state levels of ERCC2, ERCC3, XRCC1, a transcription activator (TAF-DBP) and an elongation factor (EF1A) were determined and normalized versus the housekeeping gene beta-actin in five individual brain regions of nine controls and nine DS patients. Although different in the individual regions, DNA-repair genes were consistently higher in temporal, parietal and occipital lobes of patients with DS accompanied by comparable changes of TFA-DBP and EF1A. Our results are the first to describe DNA-repair gene patterns in human brain regions providing the basis for further studies in this area. We showed that DNA-repair genes ERCC2 and ERCC3 (excision-repair-cross-complementing-) for nucleotide excision repair and XRCC1 (X-ray-repair-cross-complementing-) for X-ray-repair, were increased at the transcriptional level with the possible biological meaning that this increase may be compatible with permanent (oxidative?) DNA damage.

Reduced aldehyde dehydrogenase levels in the brain of patients with Down syndrome.

Aldehyde dehydrogenase (ALDH) is a key enzyme in fructose, acetaldehyde and oxalate metabolism and represents a major detoxification system for reactive carbonyls and aldehydes. In the brain, ALDH exerts a major function in the metabolism of biogenic aldehydes, norepinephrine, dopamine and diamines and gamma-aminobutyric acid. Subtractive hybridization studies in Down Syndrome (DS) fetal brain showed that mRNA for ALDH are downregulated. Here we studied the protein levels in the brain of adult patients. The proteins from five brain regions of 9 aged patients with DS and 9 controls were analyzed by two-dimensional (2-D) gel electrophoresis and identified by matrix-assisted laser desorption ionization mass spectrometry. ALDH levels were reduced in the brain regions of at least half of the patients with Down Syndrome, as compared to controls. The decreased ALDH levels in the DS brain may result in accumulation of aldehydes which can lead to the formation of plaques and tangles reflecting abnormally cross-linked, insoluble and modified proteins, found in aged DS brain. Furthermore, we constructed a 2-Dmap including approximately 120 identified human brain proteins.