Sylwia M. Gresner

Earlier Onset of Alzheimer's Disease: Risk Polymorphisms Within PRNP, PRND, CYP46, and APOE Genes

We studied eight polymorphisms within APOE, PRNP, PRND, and CYP46 genes in 213 Polish late-onset patients with Alzheimers disease (AD) and 171 non-demented elderly controls. A latent classification approach, grade-of-membership analysis, was taken to identify three extreme pure type risk sets defined by the probabilities of being affected with AD and for genotypes found at the examined genes. Sets I and II represented high intrinsic risk, having a higher density of various genotypes compared to set III, at low intrinsic risk. A gradient of onset age depending on membership in the risk sets was also observed. Logistic regression analysis showed that the highest risk for AD was found for individuals who co-inherited APOE epsilon4 allele, PRNP codon 129 homozygosity, PRND codon 174 Thr allele, and CYP46 rs754203 g allele. AD can be influenced by genetic profiles leading to appearance of the disease, composed of genes which separately evoke a little or unnoticeable effect. Moreover, there may be multiple sufficient risk sets for AD. Looking at multiple genes together rather than analyzing them individually, may improve identification of risk alleles.

Selection of reference genes for gene expression studies in astrocytomas

This study was aimed to test a panel of six housekeeping genes (GAPDH, HPRT1, POLR2A, RPLP0, ACTB, and H3F) so as to identify and validate the most suitable reference genes for expression studies in astrocytomas. GAPDH was the most stable and HPRT1 was the least stable reference gene. The effect of reference gene selection on quantitative real-time polymerase chain reaction data interpretation was demonstrated, normalizing the expression data of a selected gene of interest. Thus, GAPDH may be recommended for data normalization in gene expression studies in astrocytomas. Nevertheless, a preliminary validation of reference gene stability is required prior to every study.

Neuronal and astrocytic cells, obtained after differentiation of human neural GFAP-positive progenitors, present heterogeneous expression of PrPc

PrP(c) is a cellular isoform of the prion protein with an unknown normal function. One of the putative physiological roles of this protein is its involvement in cell differentiation. Recently, in vitro and in vivo studies showed that GFAP-positive cells have characteristics of stem/progenitor cells that generate neurons and glia. We used an in vitro model of human neurogenesis from GFAP-positive progenitor cells to study the expression of PrP(c) during neural differentiation. Semi-quantitative multiplex-PCR assay and Western blot analysis revealed a significant increase of PRNP expression level in differentiated cells compared to undifferentiated cell population. As determined by immunocytochemistry followed by a quantitative image analysis, the PrP(c) level increased significantly in neuronal cells and did not increase significantly in glial cells. Of note, glial and neuronal cells showed a very large heterogeneity of PrP(c) expression. Our results provide the basis for studying the role of PrP(c) in cell differentiation and neurogenesis from human GFAP-positive progenitor cells.

Successful elimination of non-neural cells and unachievable elimination of glial cells by means of commonly used cell culture manipulations during differentiation of GFAP and SOX2 positive neural progenitors (NHA) to neuronal cells

BackgroundAlthough extensive research has been performed to control differentiation of neural stem cells – still, the response of those cells to diverse cell culture conditions often appears to be random and difficult to predict. To this end, we strived to obtain stabilized protocol of NHA cells differentiation – allowing for an increase in percentage yield of neuronal cells.ResultsUncommitted GFAP and SOX2 positive neural progenitors – so-called, Normal Human Astrocytes (NHA) were differentiated in different environmental conditions to: only neural cells consisted of neuronal [MAP2+, GFAP-] and glial [GFAP+, MAP2-] population, non-neural cells [CD44+, VIMENTIN+, FIBRONECTIN+, MAP2-, GFAP-, S100β-, SOX2-], or mixture of neural and non-neural cells.In spite of successfully increasing the percentage yield of glial and neuronal vs. non-neural cells by means of environmental changes, we were not able to increase significantly the percentage of neuronal (GABA-ergic and catecholaminergic) over glial cells under several different cell culture testing conditions. Supplementing serum-free medium with several growth factors (SHH, bFGF, GDNF) did not radically change the ratio between neuronal and glial cells – i.e., 1,1:1 in medium without growth factors and 1,4:1 in medium with GDNF, respectively.ConclusionWe suggest that biotechnologists attempting to enrich in vitro neural cell cultures in one type of cells – such as that required for transplantology purposes, should consider the strong limiting influence of intrinsic factors upon extracellular factors commonly tested in cell culture conditions.

APBB2 genetic polymorphisms are associated with severe cognitive impairment in centenarians

APBB2 gene encodes for β-amyloid precursor protein-binding family B member 2, (APBB2, FE65-like, FE65L1), an adaptor protein binding to the cytoplasmatic domain of β-amyloid precursor protein (βAPP). Over-expression of APBB2 promotes formation of β-amyloid (Aβ), the main constituent of senile plaques. Polymorphisms within APBB2 gene have been proposed as candidate risk factors for Alzheimers disease. However, their association with longevity has never been investigated. Here we present the first attempt to analyze APBB2 polymorphisms in centenarians. We used a PCR-RFLP method to analyze two intronic nucleotide substitutions: hCV1558625 (rs17443013) and rs13133980. We found no differences in genotype or allele distribution between centenarians and young controls. After stratification of centenarians upon their cognitive performance, the APBB2 rs13133980 G allele was over-represented in centenarians with severe cognitive impairment compared to individuals without this disability. Also the hCV1558625-rs13133980 AG haplotype increased relative risk for severe cognitive impairment in centenarians. Our results support the concept of APBB2 polymorphism association with cognitive performance in the oldest age.

Molecular alterations in meningiomas: association with clinical data.

The aim of our study was to evaluate the frequency of deletions on chromosomes 1, 9, 10, 14, 18 and 22 in 75 benign and 15 atypical meningiomas and correlate them with clinical findings. Paired normal and tumor DNA samples were analyzed for loss of heterozygosity (LOH), using 24 microsatellite markers and PCR techniques. Statistical analysis showed that deletions on chromosomes 14 and 18 were significantly associated with tumor grade of meningiomas (p = 0.048 and p = 0.03, respectively). In addition, we found a marginally increased frequency of LOH on chromosome 9 in atypical meningiomas (p = 0.06). Interestingly, LOH on chromosome 14 was significantly associated with tumor size (p = 0.049), as the risk of developing a tumor of more than 4 cm in diameter was 6-times the risk of developing tumor with diameter below 4 cm. The most frequent genetic abnormality in meningiomas is 22 LOH, which seems to be confirmed by the present study in which high frequency of such abnormality was observed (67%). We found associations between chromosome 22 status and histological subtype. LOH on chromosome 22 was more frequent in fibrous meningiomas than in the meningothelial variant (p = 0.001). Besides that, we found a relationship between 22 LOH status and tumor localization: the frequency of LOH in skull base-localized tumors was significantly lower compared to parasagittal meningiomas (p = 0.0004). Our results indicated that allelic loss on chromosomes 9, 10, 14, 18 and 22 may be associated with meningioma pathogenesis and progression.

Analysis of APBB2 gene polymorphisms in sporadic Alzheimer's disease.

The accumulation of beta-amyloid (Abeta) in the brain plays a central role in the pathogenesis of Alzheimers disease (AD). The processing of Abeta precursor protein to Abeta is modulated by binding proteins including APBB2 [amyloid beta precursor protein-binding family B member 2, FE65-like, FE65L1]. We investigated two intronic SNPs within the APBB2 gene: rs13133980 and hCV1558625 (rs17443013), among Polish AD patients and healthy controls (n=213, 171). The frequencies of rs13133980 alleles and genotypes did not differ between cases and controls, irrespective of age of onset or APOE epsilon4 carrier status. The hCV1558625 G allele was over-represented in patients with onset under age 70 compared to controls in the same age range (57% vs. 43%, p=0.03). The association between the hCV1558625 G allele and susceptibility for AD at relatively young ages needs to be confirmed in other samples.

The prion protein M129V polymorphism Longevity and cognitive impairment among Polish centenarians

The PRNP gene encodes the cellular isoform of prion protein (PrPc). The M129V polymorphism influences the risk of prion diseases and may modulate the rate of neurodegeneration with age. We present the first study of the polymorphism among Polish centenarians. In the control group (n = 165, ages 18 to 56 years) the observed M129V genotype frequencies agreed with those expected according to the Hardy-Weinberg equilibrium (MM, MV, VV): 43%, 44%, 13% (HWE p > 0.05). Among centenarians (n = 150, ages 100 to 107) both homozygotes were more common than expected and HWE was rejected: 46%, 37%, 17% (expected 42%, 46%, 13%; HWE p = 0.025). This finding is consistent with a higher mortality rate among heterozygotes. However, the observed allele and genotype frequencies did not differ significantly between the oldest-old and the young controls. The genotypic frequencies were not related to severe cognitive impairment among the centenarians.