Neurite Branch Retraction Is Caused by a Threshold-Dependent Mechanical Impact

Franze, Kristian; Gerdelmann, Jens; Weick, Michael; Betz, Timo; Pawlizak, Steve; Lakadamyali, Melike; Bayer, Johannes; Rillich, Katja; Gögler, Michael; Lu, Yun-Bi; Reichenbach, Andreas; Janmey, Paul A.; Käs, Josef A.

doi:10.1016/j.bpj.2009.07.033

Cited by 154 publications

(155 citation statements)

References 48 publications

(75 reference statements)

Supporting

Mentioning

148

Contrasting

Unclassified

Order By: Relevance

“…Once a neurite is connected to its target, tension promotes its stabilization; at the same time, it causes retraction or elimination of collateral neurites (Anava et al, 2009). Thus, tension might serve as a signal for axonal and dendritic survival, and reduced tension might, therefore, contribute to branch pruning (Franze et al, 2009). Accordingly, the orientation of apical dendrites of pyramidal neurons in the cortex and the degree of their dendritic and axonal arborization depends on their location relative to the curvature of the tissue (Welker, 1990), and thus probably on local tension (Xu et al, 2010).…”

Section: Network Formationmentioning

confidence: 99%

“…The actin cytoskeleton is also coupled to the substrate via point contacts, which are made up of protein complexes containing integrins, vinculin, talin and many others (Renaudin et al, 1999). These point contacts form molecular 'clutches' (Suter and Forscher, 1998), which allow growth cones to transmit forces to their substrate, which may lead to its deformation (Franze et al, 2009;Betz et al, 2011;Koch et al, 2012). Accordingly, inhibition of actin polymerization leads to a reduction in the maximum force and velocity of growth cone protrusion, and a reduction in membrane stiffness results in larger forces and increased velocity (Amin et al, 2012).…”

Section: Growth Cone Motilitymentioning

confidence: 99%

“…Netrin 1, in turn, positively regulates traction forces via Pak1-mediated shootin1 phosphorylation, thus promoting actin-substrate coupling, force generation and axon outgrowth (Toriyama et al, 2013). Finally, calcium influx through mechanosensitive ion channels, which also may affect talin, is involved in the neuronal response to mechanical stimuli (Franze et al, 2009;Kerstein et al, 2013).It is likely that, similar to chemical signaling pathways, more than one mechanism is involved in cellular mechanotransduction. Furthermore, individual mechanical and chemical cues might activate similar or the same downstream signaling pathways and thus interact with each other.…”

mentioning

confidence: 99%

See 2 more Smart Citations

The mechanical control of nervous system development

2013

Self Cite

View full text Add to dashboard Cite

The development of the nervous system has so far, to a large extent, been considered in the context of biochemistry, molecular biology and genetics. However, there is growing evidence that many biological systems also integrate mechanical information when making decisions during differentiation, growth, proliferation, migration and general function. Based on recent findings, I hypothesize that several steps during nervous system development, including neural progenitor cell differentiation, neuronal migration, axon extension and the folding of the brain, rely on or are even driven by mechanical cues and forces.Key words: Mechanics, Mechanosensitivity, Mechanotaxis, Mechanotransduction, Stiffness, Force, Tension, Brain folding Introduction Many processes in development involve growth and motion on different length and time scales. All of these processes are driven by forces; the development of organisms and organ systems would not proceed without mechanics. For example, during neuronal development, neurons migrate and extend immature processes (neurites), which become axons and dendrites. Axons then grow in two different phases, both of which are distinguished by the nature of the forces that drive the growth. In the first phase, growth cones at the tips of axonal processes actively exert forces on their environment (Betz et al., 2011), thus pulling on the processes (Lamoureux et al., 1989). In a second phase, after connecting with their target tissue, axons may be passively pulled by the increasing distance between target and nervous tissue, resulting in considerable growth in length, a process referred to as stretch growth (Weiss, 1941). Once the final connectivity is established, tension may develop along neuronal axons, which may be involved in neuronal network formation and the folding of the brain. Apart from this direct requirement of forces for developmental processes, which has been studied to some degree in the past, the mechanical interaction of cells with their environment may add an additional level of control to several processes in the developing nervous system, including progenitor cell differentiation and cellular guidance.The idea of an important contribution of mechanics to the development of the nervous system has been around for more than a century. However, recent decades have seen only little progress in this field compared with other (e.g. electrophysiology, molecular biology or genetics-based) areas of neuroscience. Progress often depends on the availability of appropriate methodology. Only recently has the increasing involvement of physical and engineering approaches in interdisciplinary studies of biological systems led to the development of new techniques and conceptual approaches that can be used to quantitatively probe and control relevant mechanical parameters, such as cell and tissue stiffness, cellular forces, and tension. In recent years, such tissue mechanics-based studies have resulted in an increasing awareness of the importance of physical parameters, particularly in developm...

show abstract

Section: Network Formationmentioning

confidence: 99%

Section: Growth Cone Motilitymentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

The mechanical control of nervous system development

2013

Self Cite

View full text Add to dashboard Cite

show abstract

“…The fragmentation can be related to growth cones pruning that occurs during the early development of the central nervous system, where an excessive outgrowth of projections need to be refined to achieve precise connectivity (Faulkner et al, 2007). The selective elimination of neuronal cell processes, or neurites, is an essential step during normal development and occurs through retraction, degeneration, or a combination of both (Franze et al, 2009). This phenomenon resembles the growth cone collapse induced by several factors like mercury (Leong et al, 2001), X-ray (Al-Jahdari et al, 2008) or semaphorin in the absence of growth factors (Tamagnone & Comoglio, 2004).…”

Section: Discussionmentioning

confidence: 99%

Characterization of Embryonic Stem (ES) Neuronal Differentiation Combining Atomic Force, Confocal and DIC Microscopy Imaging

Ruaro¹,

Ban²,

Torre³

2011

Embryonic Stem Cells - Differentiation and Pluripotent Alternatives

View full text Add to dashboard Cite

“…99,100 Excessive mechanical tension can also lead to neurite retraction due to deformations of mechano-sensitive ion channels. 101 Interestingly, it has also been proposed that mechanical tension and a critical neurite length (~10 µm longer than other neurites) can specify axonal fate, potentially establishing neurons with two axons (Note: usually neurons have only one axon). 7 The growing neurites can also form communication networks which increase the tensile forces on each neuron.…”

Section: Regulation Of Neurite Growthmentioning

confidence: 99%

Acute and Chronic Neural Stimulation via Mechano-Sensitive Ion Channels

Tay

2018

Springer Theses

View full text Add to dashboard Cite

Neural stimulation techniques for eliciting calcium influx can elucidate the physiological roles of specific neural populations. To overcome some of the limitations of existing techniques such as poor specificity and noxious effects of heat, I developed a technology for non-invasive control of neural activities using magnetic forces and magnetic nanoparticles (MNPs) which offer deep tissue penetration and controllable dosage. Extensive investigations with different neurotoxins and experimental conditions support that the mechanism of magnetic stimulation that involves membrane-bound MNPs transducing magnetic forces into mechanical stretching of the cell membrane to enhance the opening probability of mechano-sensitive N-type calcium ion channels to induce calcium influx.Making use of the ability of neural networks to actively regulate their ratio of excitatory to inhibitory ion channel/receptor, I also performed chronic magnetic stimulation on fragile X iii syndrome (FXS) model neural networks. We found that chronic magnetic stimulation reduced the density of N-type calcium ion channels whose expression is increased in FXS. This technique demonstrates the potential of using bio-magnetic/mechanical forces to modulate expressions of mechano-sensitive ion channels where they are over-expressed in diseases such as abnormal nociception.Nonetheless, there are still a few areas where the technique can be improved. Firstly, it is the use of MNPs with more uniform properties to have greater control on magnetic stimulations.Secondly, the technique needs to be useful for in vivo studies. Therefore, I started researching on magnetotactic bacteria (MTB) which produce biological MNPs with superior properties such as uniform sizes and highly homogenous magnetic properties with the goal of harvesting MNPs from them.MTB, however, grow extremely slowly and the number of MNPs produced/bacterium is low. One way to overcome this problem is to evolve MTB over-producers of MNPs but this strategy is constrained by the absence of a selection platform that is quantitative and offer high throughput. To overcome this problem, I combined random chemical mutagenesis and selection using a magnetic ratcheting platform to generate and isolate MTB over-producers that produce twice as many MNPs/bacterium after 5 rounds of mutation/selection. I next designed a magnetic microfluidic device and demonstrate as a proof of concept, that it can be coupled to a bioreactor for high throughput microfluidic selection of MTB over-producers.iv

show abstract

Neurite Branch Retraction Is Caused by a Threshold-Dependent Mechanical Impact

Cited by 154 publications

References 48 publications

The mechanical control of nervous system development

The mechanical control of nervous system development

Characterization of Embryonic Stem (ES) Neuronal Differentiation Combining Atomic Force, Confocal and DIC Microscopy Imaging

Acute and Chronic Neural Stimulation via Mechano-Sensitive Ion Channels

Contact Info

Product

Resources

About