Browsing by Author "Erbaba, Begün"

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    Caloric restriction reinforces the stem cell pool in the aged brain without affecting overall proliferation status
    (Elsevier BV, 2022-11-01) Erbaba, Begün; Macaroğlu, Duygu; Avcı, N. İlgim Ardıç; Ergül , Ayça Arslan; Adams, Michelle M.
    Overfeeding (OF) and obesity increase the risk for brain aging and neurodegenerative diseases due to increased oxidative stress and neuroinflammation, which likely contribute to cellular dysfunction. In contrast, caloric restriction (CR) is an intervention known for its effects on extending both life- and health-span. In the current study, the effects on the aging brain of two short-term feeding regimens, OF and CR, were investigated. We applied these diets for 12 weeks to both young and aged zebrafish. We performed protein and mRNA level analysis to examine diet-mediated effects on any potential age-related alterations in the brain. Markers implicated in the regulation of brain aging, cell cycle, proliferation, inflammation, and cytoskeleton were analyzed. The most prominent result observed was a downregulation in the expression levels of the stem cell marker, Sox2, in CR-fed animals as compared to OF-fed fish. Furthermore, our data highlighted significant age-related downregulations in Tp53, Myca, and L-plastin levels. The multivariate analyses of all datasets suggested that as opposed to OF, the adaptive mechanisms increasing lifespan via CR are likely exerting their effects by reinforcing the stem cell pool and downregulating inflammation. The data reveal important therapeutic targets with respect to the state of nutrient uptake for the slowing down of the detrimental effects of aging, resulting in a healthy and extended lifespan, as well as lowering the risk for neurodegenerative disease.
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    Effects of aging and short-term dietary restriction on neurogenesis and cellular senescence in the zebrafish (Danio Reio) brain
    (2016-09) Erbaba, Begün
    Currently we know from rodent and fish studies that adult neuron generation is reduced but still continues in old animals with a dynamic change throughout aging. This process occurs mainly in hippocampal region, which is thought to be analogous to a region in telencephalon of the zebrafish brain. Changes in this neuron turnover are thought to be one contributing factor to cognitive change occuring with advanced age. Since we know that external factors can affect the process of neurogenesis, and as previous studies showed, dietary restriction (DR) extends life span; here, we hypothesized that DR should also alleviate several age associated alterations. In order to test this, we applied a 10-week feeding regimen to young (8-9 months) and old (26-32.5 months) male and female fish. We had two dietary regimen groups, one fed Ad libitum and one fed with a DR that was a pattern of every-other-day feeding, which is a widely accepted method of DR. A total of 124 animals were used in this study. As a result, a significant loss of body weight in both young and old DR groups was observed without an effect on body lengths. To be able to label actively dividing cells we used Bromodeoxyuridine (BrdU), which is a thymidine analog. It is injected into the fish intraperitoneally prior to euthanasia. Four hours later the brains were dissected and fixed for sectioning. We obtained cross-sectional slices of 50 m thickness with a vibratome, performed immunostaining with antibodies against BrdU, NeuN (neuronal marker), HuC (neuronal marker); and visualized the brain sections with confocal microscopy forming 3D reconstructed pictures. We counted the BrdU positive cells in all brain slices, forming a regional map of the telencephalic region of zebrafish brain, in which we documented the specific regions where the adult neurogenesis dominates the most and least. Our results confirmed that there are more BrdU positive cells in young animals than olds, and that age is correlated with an increased senescence associated fi-galactosidase (SA-fi-gal) activity, along with shortened telomere lengths. The 10-week diet was not found to be creating a significant change in cell proliferation rates, cellular senescence, or the differentiation pattern of glial cells. However, it was demonstrated to have a shortening effect on telomere lengths. Our data suggest that the potential effects of DR could be related to telomere regulation. Therefore, in order to detect differentially expressed genes that could be related to this mechanism between the groups, we performed microarray analysis with differing DR regimens. Initial data indicated no significant effects of a 4-week diet on gene expression differences among aged fish. Further analysis of the different periods of DR will be performed. Taken together, the effects of age are more robust than a short-term DR.
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    Effects of caloric restriction on the antagonistic and integrative hallmarks of aging
    (Elsevier, 2021) Erbaba, Begün; Arslan-Ergül, Ayça; Adams, Michelle M.
    Aging is a significant risk factor for cognitive decline associated with neurodegenerative diseases, which makes understanding what promotes ‘healthy brain aging’ very important. Studies suggest that caloric restriction (CR) is a non-genetic intervention that reliably extends life- and healthspan. Here, we review the CR literature related to both the subject of aging and alterations in cell cycle machinery, especially surrounding the regulation of the E2F/DP1 complex, to elucidate the cellular protection mechanisms in the brain induced via dietary applications. The alterations extending lifespan via CR appear to exert their effects by promoting survival of individual cells, downregulating cell proliferation, and inducing stem cell quiescence, which results in keeping the stem cell reserve for extreme needs. This survival instinct of cells is believed to cause some molecular adaptations for their maintenance of the system. Avoiding energy waste of proliferation machinery promotes the long term survival of the individual cells and this is due to adaptations to the limited nutrient supply in the environment. Such a protective mechanism induced by diet could be promoted via the downregulation of crucial cell cycle-related transcription activators. This review article aims to bring attention to the importance of molecular adaptations induced by diet that promote healthy brain aging. It will provide insights into alternative targets for new treatments or neuroprotective approaches against neurodegenerative pathophysiologies.
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    TERT distal promoter GC islands are critical for telomerase and together with DNMT3B silencing may serve as a senescence-inducing agent in gliomas
    (Taylor & Francis Inc., 2022-08-23) Şerifoğlu, Naz; Adams, Michelle; Erbaba, Begün; Arslan-Ergül, Ayça
    Telomerase is reactivated in the majority of cancers. For instance, in gliomas, it is common that the TERT promoter is mutated. Research on telomere promoter GC islands have been focused primarily on proximal TERT promoter but little is known about the distal promoter. Therefore, in this study, we investigated the proximal and distal TERT promoter, in terms of DNA methylation. We did bisulfite sequencing in zebrafish tissue samples for the distal tert promoter. In the zebrafish brain tissues, we identified a hypomethylation site in the tert promoter, and found that this hypomethylation was associated with aging and shortened telomeres. Through site directed mutagenesis in glioma cell lines, we changed 10 GC spots individually, cloned into a reporter vector, and measured promoter activity. Finally, we silenced DNMT3B and measured telomerase activity along with vidaza and adriamycin treatments. Site directed mutagenesis of glioma cell lines revealed that each of the 10 GC spots are critical for telomerase activity. Changing GC to AT abolished promoter activity in all spots when transfected into glioma cell lines. Then, through silencing of DNMT3B, we observed a reduction in hTERT expression levels, while hTR remained the same, and a major increase in senescence-associated beta-galactosidase activity. Finally, we propose a model regarding the efficacy of two chemotherapeutic drugs, adriamycin and azacytidine, on gliomas. Here, we show that distal TERT promoter is critical; changing even one GC to AT abolishes TERT promoter activity. DNMT3B, a de novo methyltransferase, together with GC islands in distal TERT promoter plays an important role in regulation of telomerase expression and senescence.
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    Transcriptomic alterations in the aged brain with and without dietary and dietary- mimetic manipulations
    (2021-12) Erbaba, Begün
    Aside from many genetic and environmental influences on the brain, aging itself is a significant risk factor for accelerated cognitive decline, making aging research crucial due to the increasing population age in our era. We aimed to discover gene expression differences in the aging zebrafish brain using three age groups in the first aim. We identified gjc2 (CX47) and alcamb (ALCAM) cell adhesion genes showing consistent downregulation with age across all experiments. ALCAM is also known to be associated with neuroinflammation, which has been implicated to be lowered using anti-aging, non-genetic nutrient interventions. In the second aim, we applied 12 weeks of two opposing nutrient interventions, caloric restriction (CR) and overfeeding (OF) in aging zebrafish, in order to be able to propose a reliable therapeutic approach for reversing age-related neurobiological changes. We measured protein and expression level differences of selected genes related to proliferation to inflammation with these diets. The results showed that sox2 gene expression was significantly upregulated following OF treatment than CR diet, and myca and tp53 mRNA levels were significantly downregulated with advanced age. Alcamb and tfdp1 expression levels were also marginally significantly lowered with CR compared to other groups. Meanwhile, we also conducted another transcriptomic approach using microarray to assess gene expression differences with CR compared to Ad-libitum (AL) feeding. Thus, lastly, in the third part, we found that CR causes changes in cell cycle regulation among several other functional regulatory pathways in zebrafish brains. We identified the tfdp1 gene, which showed downregulation with CR, as a possible CR regulator. Then, to create a CR mimic, we performed morpholino oligo (MO) injections to zebrafish embryos and adult brains to knock down tfdp1 gene expression levels. The injections were not successful in altering Tfdp1 protein levels in neither embryos and adults. However, 8ng tfdp1-MO injections in embryos significantly increased myca and tp53 expression levels, which are among the downstream targets of tfdp1. Our examinations shed light on healthy brain aging and possibly propose new drug targets.
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    Zebrafish aging models and possible interventions
    (InTechOpen Press, 2018) Birand, Dilan Ç.; Erbaba, Begün; Özdemir, Ahmet T.; Kafalıgönül, Hulusi; Adams, Michelle; Bozkurt, Y.
    Across the world, the aging population is expanding due to an increasing average life expectancy. The percentage of elderly over the age of 65 is expected to be more than 15% of the total world population by 2025. As the lifespan increases, there will be a need for maintaining a healthy state for these individuals. Our current knowledge on types and durations of potential anti-aging therapies is quite limited. Recently the zebrafish has emerged as a promising model for understanding the cognitive and neurobiological changes during aging, as well as its use with potential anti-aging interventions. Like humans this model organism ages gradually, displays similar behavioral properties and social characteristics, and in addition, there is a wealth of molecular and genetic tools to uncover the cellular mechanism that contribute to age-related cognitive declines. Drug effect and toxicity can be easily tested in the zebrafish. Therefore, this animal model can provide information about potential therapies that could be translated directly into human populations or provide a more focused treatment direction for testing in other mammalian animal models. The zebrafish will be a powerful tool for uncovering the mysteries of the aging brain.
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    Zebrafish brain RNA sequencing reveals that cell adhesion molecules are critical in brain aging
    (Elsevier, 2020) Erbaba, Begün; Burhan, Özge Pelin; Şerifoğlu, Naz; Muratoğlu, B.; Kahveci, Fatma; Adams, Michelle M.; Arslan-Ergül, A.
    Brain aging is a complex process, which involves multiple pathways including various components from cellular to molecular. This study aimed to investigate the gene expression changes in zebrafish brains through young-adult to adult, and adult to old age. RNA sequencing was performed on isolated neuronal cells from zebrafish brains. The cells were enriched in progenitor cell markers, which are known to diminish throughout the aging process. We found 176 statistically significant, differentially expressed genes among the groups, and identified a group of genes based on gene ontology descriptions, which were classified as cell adhesion molecules. The relevance of these genes was further tested in another set of zebrafish brains, human healthy, and Alzheimer’s disease brain samples, as well as in Allen Brain Atlas data. We observed that the expression change of 2 genes, GJC2 and ALCAM, during the aging process was consistent in all experimental sets. Our findings provide a new set of markers for healthy brain aging and suggest new targets for therapeutic approaches to neurodegenerative diseases.