Computational Analysis of the Effects of Antineoplastic Agents on Axonal Transport

Goshima, Yoshio; Usui, Hiroshi; Shiozawa, Takahito; Hida, Tomonobu; Kuraoka, Satoshi; Takeshita, Sayumi; Yamashita, Naoya; Ichikawa, Yasushi; Kamiya, Yoshinori; Gotoh, Takahisa; Gotoh, Toshiyuki

doi:10.1254/jphs.09352fp

Cited by 15 publications

(22 citation statements)

References 27 publications

(31 reference statements)

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“…Recently, similar attempts have been reported independently to detect and track vesicles along neuronal axons [4,29,30]. The time-sequence images of moving vesicles, which are observed by fluorescence microscopy with probes, such as fluorescence recovery after FRAP, GFP, and CM-DiI, are used for analyzing axonal transport as inputs.…”

Section: Physiological Functions Of Axonal Transportmentioning

confidence: 99%

“…The time-sequence images of moving vesicles, which are observed by fluorescence microscopy with probes, such as fluorescence recovery after FRAP, GFP, and CM-DiI, are used for analyzing axonal transport as inputs. The methods are classified into two approaches: the particle tracking in time-sequence image frames [4,29,30] and analysis using a kymograph image [29–31]. We will briefly introduce these methods in this section.…”

Section: Physiological Functions Of Axonal Transportmentioning

confidence: 99%

“…As discussed in the following section, in order to differentiate between those vesicles with different velocities and directions in a narrow passageway, strategies have been explored, such as use of Bayesian estimation [30], particle movement diagram [4] and kymograph image [29,31]. …”

Section: Physiological Functions Of Axonal Transportmentioning

confidence: 99%

“…This transport machinery depends on two families of motor proteins to transport molecules along microtubules, kinesin and dynein [1,3]. Defects in axonal transport reportedly can lead to neurodegenerative pathology and related disorders, such as Schizophrenia, Alzheimer’s (AD), Parkinson’s, other motor neuron diseases and drug-induced neuropathies [4–6], highlighting the importance of understanding the mechanisms of axonal transport.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, the development of a simple and objective assay system to evaluate axonal transport has long been awaited. We have recently developed a computer-assisted monitoring system for axonal transport [4]. In this review, we will just briefly summarize the physiology and pathophysiology of axonal transport, and discuss about the validity and general versatility of this method, and our tasks for the future.…”

Section: Introductionmentioning

confidence: 99%

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Computational Analysis of Axonal Transport: A Novel Assessment of Neurotoxicity, Neuronal Development and Functions

Goshima

Hida

Gotoh

2012

IJMS

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Axonal transport plays a crucial role in neuronal morphogenesis, survival and function. Despite its importance, however, the molecular mechanisms of axonal transport remain mostly unknown because a simple and quantitative assay system for monitoring this cellular process has been lacking. In order to better characterize the mechanisms involved in axonal transport, we formulate a novel computer-assisted monitoring system of axonal transport. Potential uses of this system and implications for future studies will be discussed.

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Section: Physiological Functions Of Axonal Transportmentioning

confidence: 99%

Section: Physiological Functions Of Axonal Transportmentioning

confidence: 99%

Section: Physiological Functions Of Axonal Transportmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Computational Analysis of Axonal Transport: A Novel Assessment of Neurotoxicity, Neuronal Development and Functions

Goshima

Hida

Gotoh

2012

IJMS

Self Cite

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Neuroprotective Role of Selected Antioxidant Agents in Preventing Cisplatin-Induced Damage of Human Neurons In Vitro

et al. 2019

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Chemotherapy-induced peripheral neuropathy (CIPN) is a side effect of platinum-based chemotherapy and decreases the quality of life of cancer patients. We compared neuroprotective properties of several agents using an in vitro model of terminally differentiated human cells NT2-N derived from cell line NT2/D1. Sodium azide and an active metabolite of amifostine (WR1065) increase cell viability in simultaneous treatment with cisplatin. In addition, WR1065 protects the non-dividing neurons by decreasing cisplatin caused oxidative stress and apoptosis. Accumulation of Pt in cisplatin-treated cells was heterogeneous, but the frequency and concentration of Pt in cells were lowered in the presence of WR1065 as shown by X-ray fluorescence microscopy (XFM). Transition metals accumulation accompanied Pt increase in cells; this effect was equally diminished in the presence of WR1065. To analyze possible chemical modulation of Pt-DNA bonds, we examined the platinum L III near edge spectrum by X-ray absorption spectroscopy. The spectrum found in cisplatin-DNA samples is altered differently by the addition of either WR1065 or sodium azide. Importantly, a similar change in Pt edge spectra was noted in cells treated with cisplatin and WR1065. Therefore, amifostine should be reconsidered as a candidate for treatments that reduce or prevent CIPN. Electronic supplementary material The online version of this article (10.1007/s10571-019-00667-7) contains supplementary material, which is available to authorized users.

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Depletion of Mitofusin-2 Causes Mitochondrial Damage in Cisplatin-Induced Neuropathy

et al. 2017

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Sensory neuropathy is a relevant side effect of the antineoplastic agent cisplatin. Mitochondrial damage is assumed to play a critical role in cisplatin-induced peripheral neuropathy, but the pathomechanisms underlying cisplatin-induced mitotoxicity and neurodegeneration are incompletely understood. In an animal model of cisplatin-induced neuropathy, we determined in detail the extent and spatial distribution of mitochondrial damage during cisplatin treatment. Changes in the total number of axonal mitochondria during cisplatin treatment were assessed in intercostal nerves from transgenic mice that express cyan fluorescent protein. Further, we explored the impact of cisplatin on the expression of nuclear encoded molecules of mitochondrial fusion and fission, including mitofusin-2 (MFN2), optic atrophy 1 (OPA1), and dynamin-related protein 1 (DRP1). Cisplatin treatment resulted in a loss of total mitochondrial mass in axons and in an abnormal mitochondrial morphology including atypical enlargement, increased vacuolization, and loss of cristae. These changes were observed in distal and proximal nerve segments and were more prominent in axons than in Schwann cells. Transcripts of fusion and fission proteins were reduced in distal nerve segments. Significant reduced expression levels of the fusion protein MFN2 was detected in nerves of cisplatin-exposed animals. In summary, we provide for the first time an evidence that cisplatin alters mitochondrial dynamics in peripheral nerves. Loss of MFN2, previously implicated in the pathogenesis of other neurodegenerative diseases, also contributes to the pathogenesis in cisplatin-induced neuropathy.

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Computational Analysis of the Effects of Antineoplastic Agents on Axonal Transport

Cited by 15 publications

References 27 publications

Computational Analysis of Axonal Transport: A Novel Assessment of Neurotoxicity, Neuronal Development and Functions

Computational Analysis of Axonal Transport: A Novel Assessment of Neurotoxicity, Neuronal Development and Functions

Neuroprotective Role of Selected Antioxidant Agents in Preventing Cisplatin-Induced Damage of Human Neurons In Vitro

Depletion of Mitofusin-2 Causes Mitochondrial Damage in Cisplatin-Induced Neuropathy

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