Changes in synaptic inputs to dI3 INs and MNs after complete transection in adult mice.

IF 3.4 3区 医学 Q2 NEUROSCIENCES Frontiers in Neural Circuits Pub Date : 2023-01-01 DOI:10.3389/fncir.2023.1176310
Sara Goltash, Shannon J Stevens, Emine Topcu, Tuan V Bui
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Abstract

Introduction: Spinal cord injury (SCI) is a debilitating condition that disrupts the communication between the brain and the spinal cord. Several studies have sought to determine how to revive dormant spinal circuits caudal to the lesion to restore movements in paralyzed patients. So far, recovery levels in human patients have been modest at best. In contrast, animal models of SCI exhibit more recovery of lost function. Previous work from our lab has identified dI3 interneurons as a spinal neuron population central to the recovery of locomotor function in spinalized mice. We seek to determine the changes in the circuitry of dI3 interneurons and motoneurons following SCI in adult mice.

Methods: After a complete transection of the spinal cord at T9-T11 level in transgenic Isl1:YFP mice and subsequent treadmill training at various time points of recovery following surgery, we examined changes in three key circuits involving dI3 interneurons and motoneurons: (1) Sensory inputs from proprioceptive and cutaneous afferents, (2) Presynaptic inhibition of sensory inputs, and (3) Central excitatory glutamatergic synapses from spinal neurons onto dI3 INs and motoneurons. Furthermore, we examined the possible role of treadmill training on changes in synaptic connectivity to dI3 interneurons and motoneurons.

Results: Our data suggests that VGLUT1+ inputs to dI3 interneurons decrease transiently or only at later stages after injury, whereas levels of VGLUT1+ remain the same for motoneurons after injury. Levels of VGLUT2+ inputs to dI3 INs and MNs may show transient increases but fall below levels seen in sham-operated mice after a period of time. Levels of presynaptic inhibition to VGLUT1+ inputs to dI3 INs and MNs can rise shortly after SCI, but those increases do not persist. However, levels of presynaptic inhibition to VGLUT1+ inputs never fell below levels observed in sham-operated mice. For some synaptic inputs studied, levels were higher in spinal cord-injured animals that received treadmill training, but these increases were observed only at some time points.

Discussion: These results suggest remodeling of spinal circuits involving spinal interneurons that have previously been implicated in the recovery of locomotor function after spinal cord injury in mice.

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成年小鼠完全横断后突触输入di3ins和MNs的变化。
简介:脊髓损伤(SCI)是一种使人衰弱的疾病,它破坏了大脑和脊髓之间的交流。一些研究试图确定如何恢复病变尾侧的休眠脊髓回路,以恢复瘫痪患者的运动。到目前为止,人类患者的恢复水平充其量只是适度的。相比之下,脊髓损伤动物模型表现出更多的功能恢复。我们实验室之前的工作已经确定dI3中间神经元是脊髓化小鼠运动功能恢复的核心脊髓神经元群。我们试图确定成年小鼠脊髓损伤后dI3中间神经元和运动神经元电路的变化。方法:对转基因Isl1:YFP小鼠进行T9-T11水平的脊髓完全横断,并在术后恢复的不同时间点进行跑步机训练后,我们检测了涉及dI3中间神经元和运动神经元的三个关键回路的变化:(1)本体感觉和皮肤传入的感觉输入,(2)突触前感觉输入的抑制,以及(3)脊髓神经元到dI3 INs和运动神经元的中枢兴奋性谷氨酸突触。此外,我们研究了跑步机训练对dI3中间神经元和运动神经元突触连通性变化的可能作用。结果:我们的数据表明,损伤后dI3中间神经元的VGLUT1+输入短暂或仅在后期减少,而运动神经元的VGLUT1+水平在损伤后保持不变。VGLUT2+输入dI3 INs和MNs的水平可能会出现短暂的增加,但在一段时间后会低于假手术小鼠的水平。脊髓损伤后,对VGLUT1+输入dI3 INs和MNs的突触前抑制水平可在短时间内升高,但这种升高不会持续。然而,对VGLUT1+输入的突触前抑制水平从未低于假手术小鼠中观察到的水平。在研究的一些突触输入中,接受跑步机训练的脊髓损伤动物的突触输入水平更高,但这些增加仅在某些时间点被观察到。讨论:这些结果表明,涉及脊髓中间神经元的脊髓回路重塑先前与小鼠脊髓损伤后运动功能的恢复有关。
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来源期刊
CiteScore
6.00
自引率
5.70%
发文量
135
审稿时长
4-8 weeks
期刊介绍: Frontiers in Neural Circuits publishes rigorously peer-reviewed research on the emergent properties of neural circuits - the elementary modules of the brain. Specialty Chief Editors Takao K. Hensch and Edward Ruthazer at Harvard University and McGill University respectively, are supported by an outstanding Editorial Board of international experts. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics and the public worldwide. Frontiers in Neural Circuits launched in 2011 with great success and remains a "central watering hole" for research in neural circuits, serving the community worldwide to share data, ideas and inspiration. Articles revealing the anatomy, physiology, development or function of any neural circuitry in any species (from sponges to humans) are welcome. Our common thread seeks the computational strategies used by different circuits to link their structure with function (perceptual, motor, or internal), the general rules by which they operate, and how their particular designs lead to the emergence of complex properties and behaviors. Submissions focused on synaptic, cellular and connectivity principles in neural microcircuits using multidisciplinary approaches, especially newer molecular, developmental and genetic tools, are encouraged. Studies with an evolutionary perspective to better understand how circuit design and capabilities evolved to produce progressively more complex properties and behaviors are especially welcome. The journal is further interested in research revealing how plasticity shapes the structural and functional architecture of neural circuits.
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