Your search keyword '"Hoekman, Marco F.M."' showing total 11 results

1. Homeobox gene expression in adult dorsal root ganglia during sciatic nerve regeneration: is regeneration a recapitulation of development?

Author

Vogelaar, Christina F., Hoekman, Marco F.M., Gispen, Willem Hendrik, and Burbach, Peter H. J.

Published

2003

2. FoxK2 is Required for Cellular Proliferation and Survival.

Author

van der Heide, Lars P, Wijchers, Patrick J.E.C, von Oerthel, Lars, Burbach, J. Peter H, Hoekman, Marco F.M, and Smidt, Marten P

Subjects

CELL proliferation, TRANSCRIPTION factors, CENTRAL nervous system, GROWTH factors, MTOR protein, CELL death

Abstract

FoxK2 is a forkhead transcription factor expressed ubiquitously in the developing murine central nervous system. Here we investigated the role of FoxK2 in vitro and focused on proliferation and cellular survival. Knockdown of FoxK2 results in a decrease in BrdU incorporation and H3 phosphorylation, suggesting attenuation of proliferation. In the absence of growth factors, FoxK2 knockdown results in a dramatic increase in caspase 3 activity and propidium iodide positive cells, indicative of cell death. Additionally, knockdown of FoxK2 results in an increase in the mRNA of Gadd45α, Gadd45γ, as well as an increase in the phosphorylation of the mTOR dependent kinase p70S6K. Rapamycin treatment completely blocked the increase in p70S6K and synergistically potentiated the decrease in H3 phosphorylation upon FoxK2 knockdown. To gain more insight into the proapoptotic effects upon FoxK2 knockdown we screened for changes in Bcl2 genes. Upon FoxK2 knockdown both Puma and Noxa were significantly upregulated. Both genes were not inhibited by rapamycin treatment, instead rapamycin increased Noxa mRNA. FoxK2 requirement in cellular survival is further emphasized by the fact that resistance to TGFβ-induced cell death was greatly diminished after FoxK2 knockdown. Overall our data suggest FoxK2 is required for proliferation and survival, that mTOR is part of a feedback loop partly compensating for FoxK2 loss, possibly by upregulating Gadd45s, whereas cell death upon FoxK2 loss is induced in a Bcl2 dependent manner via Puma and Noxa. J. Cell. Physiol. 230: 1013-1023, 2015. © 2014 Wiley Periodicals, Inc., A Wiley Company [ABSTRACT FROM AUTHOR]

Published

2015

3. Identification of forkhead transcription factors in cortical and dopaminergic areas of the adult murine brain

Author

Wijchers, Patrick J.E.C., Hoekman, Marco F.M., Burbach, J. Peter H., and Smidt, Marten P.

Subjects

*BRAIN research, *TRANSCRIPTION factors, *EMBRYOLOGY, *CELL proliferation, *GENE expression, *GENES

Abstract

Abstract: The murine forkhead family of transcription factors consists of over 30 members, the vast majority of which is important in embryonic development. Implicated in processes such as proliferation, differentiation and survival, forkhead factors show highly restricted expression patterns. In search for forkhead genes expressed in specific neural systems, we identified multiple family members. We performed a detailed expression analysis for Foxj2, Foxk1 and the murine orthologue of the human ILF1 gene, which show a remarkable preference for complex cortical structures. In addition, a comprehensive examination of forkhead gene expression in dopamine neurons of the ventral tegmental area and substantia nigra pars compacta, revealed Ilf1 as a novel transcriptional regulator in midbrain dopamine neurons. These forkhead transcription factors may play a role in maintenance and survival of developing and adult neurons. [Copyright &y& Elsevier]

Published

2006

4. Spatial and temporal expression of FoxO transcription factors in the developing and adult murine brain

Author

Hoekman, Marco F.M., Jacobs, Frank M.J., Smidt, Marten P., and Burbach, J. Peter H.

Subjects

*CELLULAR signal transduction, *GENE expression, *TRANSCRIPTION factors, *IN situ hybridization, *HIPPOCAMPUS (Brain), *NUCLEUS accumbens

Abstract

Abstract: In order to obtain leads to molecular mechanisms of signal transduction pathways and controled gene expression in neuronal development we have screened the adult mouse brain for expressed forkhead transcription factors using a degenerate RT-PCR approach. Here, we focus on three FoxO genes found to be expressed in the brain: FoxO1, FoxO3 and FoxO6. The FoxO subfamily of forkhead transcription family is emerging as a central keypoint in an array of cellular functions, such as metabolism, differentiation and transformation. In situ hybridization experiments on adult and embryonic mouse brain showed differential expression patterns for three FoxO members. FoxO1 was strongly expressed in the striatum and neuronal subsets of the hippocampus (dentate gyrus and the ventral/posterior part of the CA regions), whereas FoxO3 was more diffusely expressed throughout the brain including all hippocampal areas, cortex and cerebellum. FoxO6 expression was eminent in various parts of the adult mouse brain, including the entire hippocampus, the amygdalohippocampal area and the shell of the nucleus accumbens. Remarkably, all three FoxO transcription factors were expressed relatively late in the developing murine brain, starting between E12.5 and E14. In summary, the presented data show FoxO factors to be expressed in the adult and developing mouse brain, in a spatially end temporally restricted manner. [Copyright &y& Elsevier]

Published

2006

5. Cloning and analysis of the murine Foxi2 transcription factor

Author

Wijchers, Patrick J.E.C., Hoekman, Marco F.M., Burbach, J. Peter H., and Smidt, Marten P.

Subjects

*TRANSCRIPTION factors, *COMPARISON (Psychology), *AMINO acids, *RODENTS

Abstract

Abstract: Forkhead transcription factors comprise a large family of key regulators of embryonic development. Here, we describe the cloning and analysis of the murine Foxi2 gene, coding for a putative 311 amino acid protein resembling Foxi subfamily members in mice and other species. Expression analysis during the final stages of embryonic development revealed that Foxi2 expression is mainly confined to subsets of cells in epithelial structures and particular ducts, in addition to the developing forebrain and neural retina. Since FoxI factors are thought to be implicated in the regulation of cell fate, the highly restricted expression pattern of Foxi2 suggestive of a possible role in controlling cellular identity. [Copyright &y& Elsevier]

Published

2005

6. Structural aspect of bile acids involved in the regulation of cholesterol 7α-hydroxylase and sterol 27-hydroxylase.

Author

Twisk, Jaap, Hoekman, Marco F.M., Muller, Linda M., Iida, Takashi, Tamaru, Tamaaki, Ijzerman, Ad, Mager, Willem H., and Princen, Hans M.G.

Subjects

*BILE acids, *CHOLESTEROL hydroxylase, *STEROLS, *LIVER cells, *BILE, *CHOLIC acid

Abstract

Studies the structural aspects of bile acids involved in the regulation of cholesterol 7α-hydroxylase and sterol 27-hydroxylase. Culture medium of hepatocytes; Reduction of transcriptional activity by cholate; Assessment of the effects of a large group of different bile acids.

Published

1995

7. Analysis of upstream activation sites of yeast ribosomal protein genes.

Author

Woudt, Lambertus P., Mager, Willem H., M.Nieuwint, René T., Wassenaar, Gertrude M., van der Kuyl, Antoinette C., Murre, Jan J., Hoekman, Marco F.M., Brockhoff, Paul G.M., and Planta, Rudi J.

Published

1987

8. The circadian clock in adult neural stem cell maintenance.

Author

Draijer, Swip, Chaves, Inês, and Hoekman, Marco F.M.

Subjects

*NEURAL stem cells, *CELL populations, *CELL cycle, *CELL physiology, *TRANSCRIPTION factors

Abstract

Highlights • The circadian clock regulates maintenance of neural stem cells. • Metabolism modulates both neural stem cell fates and circadian clock machinery. • Disruption of the circadian clock causes loss of quiescence resulting indepletion of the neural stem cell population. • We propose that the NAD+-dependent deacetylase SIRT1 mediates neural stem cell fates by modulating the circadian clock. Abstract Neural stem cells persist in the adult central nervous system as a continuing source of astrocytes, oligodendrocytes and neurons. Various signalling pathways and transcription factors actively maintain this population by regulating cell cycle entry and exit. Similarly, the circadian clock is interconnected with the cell cycle and actively maintains stem cell populations in various tissues. Here, we discuss emerging evidence for an important role of the circadian clock in neural stem cell maintenance. We propose that the NAD+-dependent deacetylase SIRT1 exerts control over the circadian clock in adult neural stem cell function to limit exhaustion of their population. Conversely, disruption of the circadian clock may compromise neural stem cell quiescence resulting in a premature decline of the neural stem cell population. As such, energy metabolism and the circadian clock converge in adult neural stem cell maintenance. [ABSTRACT FROM AUTHOR]

Published

2019

9. Sciatic nerve regeneration in mice and rats: recovery of sensory innervation is followed by a slowly retreating neuropathic pain-like syndrome

Author

Vogelaar, Christina F., Vrinten, Dorien H., Hoekman, Marco F.M., Brakkee, Jan H., Burbach, J. Peter H., and Hamers, Frank P.T.

Subjects

*REFLEX testing, *PERIPHERAL nervous system, *GENE expression, *NERVOUS system regeneration

Abstract

Peripheral nerve regeneration has been studied extensively in the sciatic nerve crush model, at the level of both function and gene expression. The crush injury allows full recovery of sensory and motor function in about 3 weeks as assessed by the foot reflex withdrawal test and De Medinacelli walking patterns. We used the recently developed CatWalk paradigm to study walking patterns in more detail in mice and rats. We found that, following the recovery of sensory function, the animals developed a state of mechanical allodynia, which retreated slowly over time. The motor function, although fully recovered with the conventional methods, was revealed to be still impaired because the animals did not put weight on their previously injured paw. The development of neuropathic pain following successful sensory recovery has not been described before in crush-lesioned animals and may provide an important new parameter to assess full sensory recovery. [Copyright &y& Elsevier]

Published

2004

10. Insulin-FOXO3 Signaling Modulates Circadian Rhythms via Regulation of Clock Transcription.

Author

Chaves, Inês, van?der?Horst, Gijsbertus?T.J., Schellevis, Raymond, Nijman, Romana?M., Koerkamp, Marian?Groot, Holstege, Frank?C.P., Smidt, Marten?P., and Hoekman, Marco?F.M.

Subjects

*INSULIN, *CELLULAR signal transduction, *CIRCADIAN rhythms, *GENETIC regulation, *SUPRACHIASMATIC nucleus, *GENETIC transcription

Abstract

Summary: Circadian rhythms are responsive to external and internal cues, light and metabolism being among the most important. In mammals, the light signal is sensed by the retina and transmitted to the suprachiasmatic nucleus (SCN) master clock [1], where it is integrated into the molecular oscillator via regulation of clock gene transcription. The SCN synchronizes peripheral oscillators, an effect that can be overruled by incoming metabolic signals [2]. As a consequence, peripheral oscillators can be uncoupled from the master clock when light and metabolic signals are not in phase. The signaling pathways responsible for coupling metabolic cues to the molecular clock are being rapidly uncovered [3–5]. Here we show that insulin-phosphatidylinositol 3-kinase (PI3K)-Forkhead box class O3 (FOXO3) signaling is required for circadian rhythmicity in the liver via regulation of Clock. Knockdown of FoxO3 dampens circadian amplitude, an effect that is rescued by overexpression of Clock. Subsequently, we show binding of FOXO3 to two Daf-binding elements (DBEs) located in the Clock promoter area, implicating Clock as a transcriptional target of FOXO3. Transcriptional oscillation of both core clock and output genes in the liver of FOXO3-deficient mice is affected, indicating a disrupted hepatic circadian rhythmicity. Finally, we show that insulin, a major regulator of FOXO activity [6–9], regulates Clock levels in a PI3K- and FOXO3-dependent manner. Our data point to a key role of the insulin-FOXO3-Clock signaling pathway in the modulation of circadian rhythms. [Copyright &y& Elsevier]

Published

2014

11. FoxO6, a Novel Member of the FoxO Class of Transcription Factors with Distinct Shuttling Dynamics.

Author

Jacobs, Frank M.J., van der Heide, Lars P., Wijchers, Patrick J.E.C., Burbach, J. Peter H., Hoekman, Marco F.M., and Smidt, Marten P.

Subjects

*CLONING, *TRANSCRIPTION factors

Abstract

Describes the cloning and characterization of a novel forkhead domain gene from mouse that appeared to be related to the FoxO-group of transcription factors designated as FoxO6. Results of structure function analysis of Fox06 compared with its group members; Nuclear localization shown by Fox06 coupled to GFP after stimulation with growth factors.

Published

2003