Browsing by Subject "Neurogenesis"

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Open Access
Age related alterations of adult neurogenesis and astrocytes in Zebrafish (Danio Rerio)
(2019-09) Ardıç, Narin Ilgım
Brain aging is marked by a decline in cognitive abilities and associated with neurodegenerative disorders. In order to identify appropriate interventions to change the course of brain aging and age-related neurological disorders, we should first understand the normal age-related changes. Previous studies claimed that there was a correlation between cognitive capacities and number of neurons. However, recent studies have shown no statistically significant change in total neuron number during healthy aging. Therefore, further studies are required to understand the reasons behind these changes in the brain. One possibility could be the age-related alterations in neuronal lineage and glial markers. Thus, this study aims to show the protein levels, distributions, and localizations of key neuronal lineage and glial markers, which include neural progenitor, early neuronal, immature neuron, and mature neuron and glial markers during healthy aging of the zebrafish brain. For this aim, we measured NeuN (Fox-3, Rbfox3, or Hexaribonucleotide Binding Protein-3), MAP-2 (Microtubule-associated protein 2), HuC (ELAV like neuron-specific RNA binding protein 3), DCAMKL-1 (Doublecortin-like kinase 1), and GFAP (Glial fibrillary acidic protein) with immunohistochemistry and western blot techniques. First, the immunohistochemistry technique was applied on two specific proliferation areas, pallium and optic tectum, to detect the changes in the number of neuronal lineages and glial marker. The results indicated no statistically significant changes between young and old groups. Secondly, we performed whole-brain immunohistochemistry of all markers and quantified every image by manually counting the positive signal. We found that aging did not have an effect on the distribution and expression of the markers, even in the whole brain. Finally, Western-blot was performed in whole brain lysates to compare neuron number and protein level changes. Western-blot results indicated an age-related statistically significant decline in immature neuron marker for specifically males and glial marker for specifically females. The protein level of neural progenitor marker showed the significant decline in males during aging but no change between two age groups. Results of the mature neuron antibody revealed that the protein levels were consistent through aging and did not show variation. Our results overall support the finding that the number of neurons and glia do not change during aging since the numbers of markers were not show statistically significant changes during the aging process in the proliferation areas of the zebrafish brain. However, protein levels showed changes between age and gender groups. Thus, this study shows that understanding changes in the number of cells need to count; protein level is not representative, and zebrafish is an appropriate model for brain aging studies.
Open Access
Age-dependent effects of short-term intermittent fasting and rapamycin treatment in Zebrafish (Danio Rerio) brain
(2020-05) Birand, Ergül Dilan Çelebi
World populations are rapidly aging, and there is an urgent need to develop interventions that prevent or reverse age-related deterioration of health. To date, several approaches have been developed to extend health span. Among these, non genetic interventions have a higher potential to be utilized in translational studies. Caloric restriction (CR) and its pharmacological mimetic rapamycin, are two applications that have been shown to reliably extend life and health span across species. Despite a growing body of knowledge on how CR and rapamycin show their beneficial effects, their molecular mechanisms in the brain are not completely understood. Furthermore, most studies applied life-long CR, which is not suitable for translational research. To fill this gap, we investigated whether short-term durations of a CR approach intermittent fasting (IF) or rapamycin altered cellular and molecular markers of critical processes in the brain as well as metabolic parameters in the body. To assess how the age of the subjects affect the outcome of the treatments, we included young (6-10 months old) and old (26-31 months) zebrafish, which has recently emerged as a suitable model for gerontological research. Our results demonstrated that IF decreased whole-body glucose and cortisol levels, and increased neural progenitor marker DCAMKL1 in young and old animals. While this proliferation-promoting effect was preceded by suppression of mTOR activity in young, the upregulation of foxm1 and reduced autophagic flux as measured by LC3 II/LC3-I ratio were observed in old animals. Rapamycin, on the other hand, did not alter the metabolic parameters and induced entirely different molecular profiles at young and old ages. The most notable changes in young animals were reduced mTOR activity, LC3-II/LC3-I ratio and expression levels of a global proliferation marker PCNA. In old animals, the marker of activated astrocytes (i.e. GFAP) was decreased, indicating lower neuroinflammation, whereas excitatory-inhibitory balance as measured by PSD-95/Gephyrin ratio was shifted towards a more excitatory state. These results suggested that IF and rapamycin induced distinct metabolic profiles in young and old animals. Furthermore, there was an age dependent reciprocal relationship between proliferation and autophagy, which might be partly due to differential regulation of mTOR activity. Interestingly, rapamycin treatment was more effective in suppressing mTOR activity in young animals, and compared to IF. Nevertheless, these results suggested that rapamycin crosses the blood-brain barrier in zebrafish, and that short-term durations of IF or rapamycin were sufficient to alter the expression levels of key proteins involved in critical mechanisms in the brain.
Open Access
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.
Open Access
Effects of aging on gene expression levels of inflammatory, cytoskeletal and microglial markers in the brain using the zebrafish (Danio Rerio) model organism
(2021-01) Aydoğan, Hande Özge
Age-related cognitive decline burdens the elderly population, limiting their abil-ity to socialize and be independent. To be able to develop proper treatments, healthy aging should be examined. Previous studies focusing on healthy brain aging revealed that abnormal microglial activation was observed. Aging microglia exhibits 0partial loss of motility due to cytoskeletal changes, leading to decreases in their ability to respond to environmental cues. Thus, a more inﬂammatory phe-notype was observed in microglia. These disruptions of the previously established homeostasis in the brain could be the underlying reason for cognitive decline ex-perienced during aging. To understand these changes during aging in the brain, cytoskeletal, microglial, and inﬂammation-related markers were investigated by using both in silico and in vivo approaches. In silico analyses were performed on mice hippocampus and the whole brain revealed that the genes involved in the actin cytoskeleton reorganization (Arpc1b), neurogenesis (Erbb4), and proinﬂam-matory related pathways (Il1b, P2x7r, Elf2b) showed diﬀerential gene expression levels among diﬀerent age groups, genders, and tissue of origin. On the other hand, no diﬀerential expression was observed in microglial (Coro1a and Aif1) and anti-inﬂammatory markers (Tgfb1 and Il10). To further validate these re-sults in vivo, quantitative polymerase chain reaction (qPCR) was performed on young and old zebraﬁsh brains. According to the results, only two genes showed marginally signiﬁcant diﬀerences among young and old brains: arpc1b and p2x7r. These results collectively could mean 1) the overall microglia population does not change during aging, 2) the brain does not exhibit imbalances in terms of pro-and anti-inﬂammatory cytokines, and 3) neurogenesis. Furthermore, the signiﬁ-cant changes observed in arpc1b and p2x7r indicated the iii iv importance of the cytoskeleton and inﬂammation-related pathways in the correct functioning of the cells. Therefore, this study showed that in silico analysis are the reliable indica-tors of in vivo experiments, zebraﬁsh can be used as a gerontological model, and the importance of cytoskeleton in motile cells. However, to understand these de-scribed relations, further investigation on the protein level of these genes should be done.
Open Access
Gene expression changes in aging zebrafish (Danio rerio) brains are sexually dimorphic
(BioMed Central, 2014) Arslan-Ergül, Ayça; Adams, Michelle M.
Background: Brain aging is a multi-factorial process due to both genetic and environmental factors. The zebrafish has recently become a popular model organism for examining aging and age-related diseases because as in humans they age gradually and exhibit cognitive decline. Few studies have examined the biological changes in the aging brain that may contribute to these declines and none have examined them within individuals with respect to gender. Our aim was to identify the main genetic pathways associated with zebrafish brain aging across gender. We chose males and females from specific age groups (young, 7.5-8.5 months and old, 31-36 months) based on the progression of cognitive decline in zebrafish. RNA was isolated from individual brains and subjected to microarray and qPCR analysis. Statistical analyses were performed using a two-way ANOVA and the relevant post-hoc tests. Results: Our results demonstrated that in the brains of young and old male and female zebrafish there were over 500 differentially expressed genes associated with multiple pathways but most notably were those related to neurogenesis and cell differentiation, as well as brain and nervous system development. Conclusions: The gene expression of multiple pathways is altered with age and differentially expressed in males and females. Future studies will be aimed at determining the causal relationships of age-related changes in gene expression in individual male and female brains, as well as possible interventions that counteract these alterations.