Your search keyword '"Rickhag, Mattias"' showing total 5 results

1. Genetic tools to study complexity of striatal function.

Author

Ciriachi, Chiara, Svane‐Petersen, David, and Rickhag, Mattias

Published

2019

2. Preserved dopaminergic homeostasis and dopamine-related behaviour in hemizygous TH-Cre mice.

Author

Runegaard, Annika H., Jensen, Kathrine L., Fitzpatrick, Ciarán M., Dencker, Ditte, Weikop, Pia, Gether, Ulrik, Rickhag, Mattias, and Bolam, Paul

Subjects

DOPAMINERGIC mechanisms, DOPAMINE, RECOMBINASES, TRANSGENE expression, LABORATORY mice

Abstract

Cre-driver mouse lines have been extensively used as genetic tools to target and manipulate genetically defined neuronal populations by expression of Cre recombinase under selected gene promoters. This approach has greatly advanced neuroscience but interpretations are hampered by the fact that most Cre-driver lines have not been thoroughly characterized. Thus, a phenotypic characterization is of major importance to reveal potential aberrant phenotypes prior to implementation and usage to selectively inactivate or induce transgene expression. Here, we present a biochemical and behavioural assessment of the dopaminergic system in hemizygous tyrosine hydroxylase ( TH)-Cre mice in comparison to wild-type ( WT) controls. Our data show that TH-Cre mice display preserved dopaminergic homeostasis with unaltered levels of TH and dopamine as well as unaffected dopamine turnover in striatum. TH-Cre mice also show preserved dopamine transporter expression and function supporting sustained dopaminergic transmission. In addition, TH-Cre mice demonstrate normal responses in basic behavioural paradigms related to dopaminergic signalling including locomotor activity, reward preference and anxiolytic behaviour. Our results suggest that TH-Cre mice represent a valid tool to study the dopamine system, though careful characterization must always be performed to prevent false interpretations following Cre-dependent transgene expression and manipulation of selected neuronal pathways. [ABSTRACT FROM AUTHOR]

Published

2017

3. A novel dopamine transporter transgenic mouse line for identification and purification of midbrain dopaminergic neurons reveals midbrain heterogeneity.

Author

Apuschkin, Mia, Stilling, Sara, Rahbek‐Clemmensen, Troels, Sørensen, Gunnar, Fortin, Guillaume, Herborg Hansen, Freja, Eriksen, Jacob, Trudeau, Louis‐Eric, Egerod, Kristoffer, Gether, Ulrik, Rickhag, Mattias, and Roeper, Jochen

Subjects

DOPAMINE, DOPAMINERGIC neurons, LABORATORY mice, MESENCEPHALON, GENE expression, HETEROGENEITY, THERAPEUTICS

Abstract

Midbrain dopaminergic ( DAergic) neurons are a heterogeneous cell group, composed of functionally distinct cell populations projecting to the basal ganglia, prefrontal cortex and limbic system. Despite their functional significance, the midbrain population of DAergic neurons is sparse, constituting only 20 000-30 000 neurons in mice, and development of novel tools to identify these cells is warranted. Here, a bacterial artificial chromosome mouse line [ Dat1-enhanced green fluorescent protein ( eGFP)] from the Gene Expression Nervous System Atlas ( GENSAT) that expresses eGFP under control of the dopamine transporter ( DAT) promoter was characterized. Confocal microscopy analysis of brain sections showed strong e GFP signal reporter in midbrain regions and striatal terminals that co-localized with the DAergic markers DAT and tyrosine hydroxylase ( TH). Thorough quantification of co-localization of the e GFP reporter signal with DAT and TH in the ventral midbrain showed that a vast majority of e GFP-expressing neurons are DAergic. Importantly, expression profiles also revealed DAergic heterogeneity when comparing substantia nigra and ventral tegmental area. Dat1-e GFP mice showed neither change in synaptosomal DA uptake nor altered levels of DAT and TH in both striatum and midbrain. No behavioural difference between Dat1- eGFP and wild-type was found, suggesting that the strain is not aberrant. Finally, cell populations highly enriched in DAergic neurons can be obtained from postnatal mice by fluorescence-activated cell sorting and the sorted neurons can be cultured in vitro. The current investigation demonstrates that e GFP expression in this mouse line is selective for DAergic neurons, suggesting that the Dat1-e GFP mouse strain constitutes a promising tool for delineating new aspects of DA biology. [ABSTRACT FROM AUTHOR]

Published

2015

4. Npas4, a novel helix–loop–helix PAS domain protein, is regulated in response to cerebral ischemia.

Author

Shamloo, Mehrdad, Soriano, Liza, Von Schack, David, Rickhag, Mattias, Chin, Daniel J., Gonzalez‐Zulueta, Mirella, Gido, Gunilla, Urfer, Roman, Wieloch, Tadeusz, and Nikolich, Karoly

Subjects

CEREBRAL anoxia, CEREBRAL ischemia, CEREBROVASCULAR disease, LABORATORY rats, CEREBRAL arteries, IN situ hybridization, IMMUNOHISTOCHEMISTRY

Abstract

Basic helix–loop–helix PAS domain proteins form a growing family of transcription factors. These proteins are involved in the process of adaptation to cellular stresses and environmental factors such as a change in oxygen concentration. We describe the identification and characterization of a recently cloned PAS domain protein termed Npas4 in ischemic rat brain. Using gene expression profiling following middle cerebral artery occlusion, we showed that the Npas4 mRNA is differentially expressed in ischemic tissue. The full-length gene was cloned from rat brain and its spatial and temporal expression characterized with in situ hybridization and Northern blotting. The Npas4 mRNA is specifically expressed in the brain and is highly up-regulated in ischemic tissues following both focal and global cerebral ischemic insults. Immunohistochemistry revealed a strong expression in the limbic system and thalamus, as well as in layers 3 and 5 in the cortex of the unchallenged brain. When overexpressed in HEK 293 cells, Npas4 appears as a protein of ∼ 100 kDa. In brain samples, however, in addition to the 100 kDa band a specific 200 kDa immunoreactive band was also detected. Ischemic challenge lead to a decrease in the 200 kDa form and a simultaneous increase in the 100 kDa immunoreactivity. This could indicate a novel regulatory mechanism for activation and/or deactivation of this protein in response to ischemic brain injury. [ABSTRACT FROM AUTHOR]

Published

2006

5. Comprehensive regional and temporal gene expression profiling of the rat brain during the first 24 h after experimental stroke identifies dynamic ischemia-induced gene expression patterns, and reveals a biphasic activation of genes in surviving tissue.

Author

Rickhag, Mattias, Wieloch, Tadeusz, Gid, Gunilla, Elmér, Eskil, Krogh, Morten, Murray, Joseph, Lohr, Scott, Bitter, Hans, Chin, Daniel J., von Schack, David, Shamloo, Mehrdad, and Nikolich, Karoly

Subjects

*BLOOD vessels, *LIPIDS, *CELL division, *CELLS, *CELL death, *GENETIC regulation, *BRAIN, *GENE expression

Abstract

In order to identify biological processes relevant for cell death and survival in the brain following stroke, the postischemic brain transcriptome was studied by a large-scale cDNA array analysis of three peri-infarct brain regions at eight time points during the first 24 h of reperfusion following middle cerebral artery occlusion in the rat. K-means cluster analysis revealed two distinct biphasic gene expression patterns that contained 44 genes (including 18 immediate early genes), involved in cell signaling and plasticity (i.e. MAP2K7, Sprouty2, Irs-2, Homer1, GPRC5B, Grasp). The first gene induction phase occurred at 0–3 h of reperfusion, and the second at 9–15 h, and was validated by in situ hybridization. Four gene clusters displayed a progressive increase in expression over time and included 50 genes linked to cell motility, lipid synthesis and trafficking (i.e. ApoD, NPC1, G3P-dehydrogenase1, and Choline kinase) or cell death-regulating genes such as mitochondrial CLIC. We conclude that a biphasic transcriptional up-regulation of the brain-derived neurotrophic factor (BDNF)–G-protein coupled receptor (GPCR)–mitogen-activated protein (MAP) kinase signaling pathways occurs in surviving tissue, concomitant with a progressive and persistent activation of cell proliferation signifying tissue regeneration, which provide the means for cell survival and postischemic brain plasticity. [ABSTRACT FROM AUTHOR]

Published

2006