Spino‐dendritic cross‐talk in rodent Purkinje neurons mediated by endogenous Ca<sup>2+</sup>‐binding proteins

Schmidt, Hartmut; Kunerth, Svenja; Wilms, Christian; Strotmann, Rainer; Eilers, Jens

doi:10.1113/jphysiol.2007.127860

Cited by 46 publications

(64 citation statements)

References 50 publications

(119 reference statements)

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“…In a model study, the spino-dendritic coupling in Purkinje cells and the role for dendritic Ca 2+ homeostasis and downstream signaling cascades was investigated using data obtained in PV-/-and CB-D28k-/-PV-/-mice [156]. CB-D28k is the more important "Ca 2+ transporter" than PV that, by buffered diffusion, also transiently increases [Ca 2+ ] i in dendritic shafts.…”

Section: B Schwallermentioning

confidence: 99%

The continuing disappearance of “pure” Ca2+ buffers

Schwaller

2008

Cell. Mol. Life Sci.

226

201

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Advances in the understanding of a class of Ca(2+)-binding proteins usually referred to as "Ca(2+) buffers" are reported. Proteins historically embraced within this group include parvalbumins (alpha and beta), calbindin-D9k, calbindin-D28k and calretinin. Within the last few years a wealth of data has accumulated that allow a better understanding of the functions of particular family members of the >240 identified EF-hand Ca(2+)-binding proteins encoded by the human genome. Studies often involving transgenic animal models have revealed that they exert their specific functions within an intricate network consisting of many proteins and cellular mechanisms involved in Ca(2+) signaling and Ca(2+) homeostasis, and are thus an essential part of the Ca(2+) homeostasome. Recent results indicate that calbindin-D28k, possibly also calretinin and oncomodulin, the mammalian beta parvalbumin, might have additional Ca(2+) sensor functions, leaving parvalbumin and calbindin-D9k as the only "pure" Ca(2+) buffers.

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Section: B Schwallermentioning

confidence: 99%

The continuing disappearance of “pure” Ca2+ buffers

Schwaller

2008

Cell. Mol. Life Sci.

226

201

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“…Specifically, CB is a good marker of Purkinje cells [Fortin et al, 1998;Schmidt et al, 2005Schmidt et al, , 2007, whereas CR is found mainly in other cell types as granular [Gall et al, 2003], unipolar, brush, and Lugaro cells Schiffmann et al, 1999], except in primates where some subpopulations of Purkinje cells are CRir [Fortin et al, 1998]. In all species of amphibians studied so far CB is present in Purkinje cells and some granule cells [Uray et al, 1998;Uray and Gona, 1999;Morona and González, 2009] and particularly in Rana but not in Xenopus laevis, and urodeles Purkinje cells contain CR [Necchi et al, 1999;Uray and Gona, 1999;Morona and González, 2009].…”

Section: Hindbrainmentioning

confidence: 99%

“…However, the dissimilarities in CB and CR sequence [Parmentier, 1990] reflect functional and evolutionary differences between the two proteins in terms of adaptation to different targets [Schwaller et al, 2002;Palczewska et al, 2003]. CR is considered a pure Ca 2+ buffer which acts as passive modulator of the cytosolic calcium levels [Schmidt et al, 2007], whereas CB acts as a sensor that regulates the degradation of inositol messengers in an activity-dependent manner [Schmidt et al, 2005] and has a neuroprotective capability to prevent degeneration [Wang et al, 2008]. Thus, each protein seems to play specific roles in different neuron subsets.…”

Section: Introductionmentioning

confidence: 99%

Localization of Calbindin-D28k and Calretinin in the Brain of Dermophis Mexicanus (Amphibia: Gymnophiona) and Its Bearing on the Interpretation of Newly Recognized Neuroanatomical Regions

Morona¹,

López²,

González³

2011

Brain Behav Evol

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The analysis of the distribution of the calbindin-D28k and calretinin immunoreactive (CBir and CRir) systems recently described in the brain of anuran and urodele amphibians was very useful for the interpretation of many otherwise indistinct brain regions and cell masses. In the present study we have followed a similar approach to investigate the distribution of CBir and CRir cell bodies and fibers in the brain of Dermophis mexicanus, a member of the much neglected third amphibian order of gymnophionans. The pattern of distribution obtained showed particular characteristics in Dermophis, such as the existence of abundant CRir elements in the olfactory bulbs and CBir and CRir cell populations in pallial areas. The distinct distribution of the two proteins allowed the tentative identification of currently described subregions, mainly in the amygdaloid complex and hypothalamic areas. The analysis of the diencephalon and brainstem distribution framed in the neuromeric model highlighted common traits with other amphibians but also specific features. Therefore, the immunohistochemical detection of calcium-binding proteins has served to discern cell populations and has helped to demonstrate neuronal heterogeneity. However, it should be pointed out that a straightforward comparison based only on the presence of these proteins should not be made due to the great variability observed in well-established homologous regions in the brain of different vertebrates, as evidenced within the class Amphibia.

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“…Thus, in a resting cell (e.g., muscle fibers, neurons), Ca 2þ buffers are mostly in the Ca 2þ -free form. It is the kinetics of various Ca 2þ buffers that strongly affect the spatiotemporal aspects of Ca 2þ signals, in particular, in excitable cells (Schmidt et al 2007b;Schmidt and Eilers 2009;Schwaller 2009 (Table 1). The ratio between high:intermediate affinity sites is either 3:1 or 2:2.…”

Section: Metal-binding Kineticsmentioning

confidence: 99%

“…This indicates that the slow diffusion of Ca 2þ ions in a resting cell ([Ca 2þ ] i % 50 nM) is caused by slowly mobile or immobile buffers "acting like velcro" for Ca 2þ ions, limiting the effective range of an unbuffered free Ca 2þ ion to %0.1 mm. Thus, the range of Ca 2þ can be increased by buffered diffusion, that is, mobile Ca 2þ buffers acting as shuttles transporting Ca 2þ through the "mesh of immobile buffers" (Schmidt et al 2007b). …”

Section: Mobility and Interaction With Ligandsmentioning

confidence: 99%

Cytosolic Ca2+ Buffers

Schwaller¹

2010

Cold Spring Harbor Perspectives in Biology

350

305

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Spino‐dendritic cross‐talk in rodent Purkinje neurons mediated by endogenous Ca²⁺‐binding proteins

Cited by 46 publications

References 50 publications

The continuing disappearance of “pure” Ca2+ buffers

The continuing disappearance of “pure” Ca2+ buffers

Localization of Calbindin-D28k and Calretinin in the Brain of Dermophis Mexicanus (Amphibia: Gymnophiona) and Its Bearing on the Interpretation of Newly Recognized Neuroanatomical Regions

Cytosolic Ca2+ Buffers

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Spino‐dendritic cross‐talk in rodent Purkinje neurons mediated by endogenous Ca2+‐binding proteins

Cited by 46 publications

References 50 publications

The continuing disappearance of “pure” Ca2+ buffers

The continuing disappearance of “pure” Ca2+ buffers

Localization of Calbindin-D28k and Calretinin in the Brain of Dermophis Mexicanus (Amphibia: Gymnophiona) and Its Bearing on the Interpretation of Newly Recognized Neuroanatomical Regions

Cytosolic Ca2+ Buffers

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Spino‐dendritic cross‐talk in rodent Purkinje neurons mediated by endogenous Ca²⁺‐binding proteins