Stathmin 2 is a potential treatment target for TDP-43 proteinopathy in amyotrophic lateral sclerosis

IF 10.8 1区 医学 Q1 NEUROSCIENCES
Yunqing Liu, Dejun Yan, Lin Yang, Xian Chen, Chun Hu, Meilan Chen
{"title":"Stathmin 2 is a potential treatment target for TDP-43 proteinopathy in amyotrophic lateral sclerosis","authors":"Yunqing Liu, Dejun Yan, Lin Yang, Xian Chen, Chun Hu, Meilan Chen","doi":"10.1186/s40035-024-00413-0","DOIUrl":null,"url":null,"abstract":"<p>Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease characterized by the selective loss of motor neurons (MNs), resulting in progressive disability and mortality with a rapid course. Current approaches such as multidisciplinary care, disease-modifying therapies, pulmonary intervention, and dietary and nutritional intervention can only slow ALS progression [1]. It is imperative to dissect the underlying mechanisms and explore novel treatment targets.</p><p>Trans-reactive DNA binding protein 43 KD (TDP-43) is a main component of abnormal cytoplasmic protein deposits observed in ~ 97% of ALS patients, and its presence is considered a pathological hallmark of ALS regardless of the disease onset. Physiologically, TDP-43 is a multifunctional protein that predominantly localizes to the nucleus, where it binds to GU-rich sequences for selective splicing. It also shuttles to the cytoplasm to generate ribonucleoprotein transport/stress granules and control translation. However, abnormal modifications of TDP-43 reduce its functional level in the nucleus and promotes the formation of cytoplasmic inclusions in MNs, inducing neurotoxic effects known as TDP-43 proteinopathy.</p><p>Initial efforts were dedicated to analyzing the binding sites of TDP-43 in mouse and human brains, showing that TDP-43 could target approximately 1000 mRNAs, a large portion being glial RNAs, providing limited insights into neuronal targets. The following study established a method for inducing human embryonic stem cells to differentiate into human MNs (hMNs), providing a more reliable model for investigating disease stimuli and therapeutic strategies [2]. With induced hMNs, Klim et al. [3] revealed that the expression of stathmin-2 (STMN2) was significantly reduced upon TDP-43 depletion. Similar results have been observed in patient-derived MNs and postmortem patient spinal cords harboring TDP-43 mislocalization [4]. Mechanistically, functional TDP-43 binds directly to <i>STMN2</i> pre-mRNA to maintain normal splicing. Pathological TDP-43 drives premature polyadenylation and cryptic splicing in the first intron of <i>STMN2</i> pre-mRNA, leading to the production of a nonfunctional mRNA [4]. Reduction of TDP-43 or STMN2 in iPSC-derived MNs inhibited axonal regeneration after induced damage. Notably, restoration/stabilization of STMN2 rescued neurite outgrowth and axon regeneration in the absence of TDP-43 [3, 4].</p><p>STMN2 belongs to the conserved Stathmin family. It can depolymerize microtubules via unclear mechanisms and is specifically expressed in the nervous system for axonal development and maintenance (see details in [5]). A moderate level of STMN2 stimulates neurite outgrowth by modulating microtubule dynamics, whereas excessive or reduced levels of STMN2 cause growth cone collapse or suppress neurite outgrowth in neurons. In cultured sensory neurons from dorsal root ganglion (DRG) subjected to axotomy, Stmn2 was elevated in regenerating growth cones. Downregulation of Stmn2 accelerated axon fragmentation, whereas experimental rescue of the Stmn2 level delayed axonal degeneration [6]. Similarly, loss of <i>Stai</i>, a homolog of <i>STMN2</i> in <i>Drosophila</i>, leads to neuromuscular junction (NMJ) degeneration and motor axon retraction [7, 8]. Recently, Krus et al. generated both constitutive and conditional <i>Stmn2</i> knockout mice and reported that Stmn2 is required for motor and sensory system function [9]. Constitutive <i>Stmn2</i> knockout (<i>Stmn2</i><sup>−/−</sup>) induces severe motor and sensory neuropathy, including decreased compound muscle action potentials, NMJ denervation, and reduced nerve fiber density. Importantly, <i>Stmn2</i><sup>−/−</sup> mice predominantly exhibit degeneration of fast-fatigable motor units, similar to that observed in ALS patients. Loss of Stmn2 specifically in MNs recapitulates the NMJ pathology found in <i>Stmn2</i><sup>−/−</sup> mice [9]. The authors further studied Stmn2<sup>+/−</sup> mice, which mimic the partial loss of STMN2 in ALS patients and exhibit selective motor neuropathy. Like <i>Stmn2</i><sup>−/−</sup> mice, the <i>Stmn2</i><sup>+/−</sup> heterozygous mice behave normally as young adults but show motor weakness by 1 year of age [9]. This progressive motor neuropathy is also a typical clinical symptom of ALS patients. Moreover, adult mice with absence of Stmn-2 exhibit phenotypes comparable to those of ALS patients [10], suggesting that STMN2 is involved in ALS pathology.</p><p>Nevertheless, there is emerging evidence of aberrant STMN2 in ALS patients. A noncoding CA repeat in <i>STMN2</i> that may affect mRNA processing has been reported to be associated with sporadic ALS in a North American cohort [11]. Moreover, two independent groups detected cryptic exons of <i>STMN2</i> in postmortem brain tissues from patients with TDP-43-associated Alzheimer’s disease [12] and C9ORF72 patients who were susceptible to TDP-43 pathology [13]. Consistently, in an unbiased study of single-cell protein expression profiles with human spinal MNs directly sampled from TDP-43 ALS patients, a lower frequency of the STMN2 protein was detected [14]. Via in situ hybridization, they detected a robust decrease in the <i>STMN2</i> RNA level in ALS MNs [14]. Importantly, cryptic splicing of <i>STMN2</i> was confirmed in TDP-43-depleted human iPSC-derived MNs [15] and iPSC MNs from postmortem sporadic TDP-43 ALS patients [16]. Thus, these findings reveal a strong link between aberrant <i>STMN2</i> expression and MN degeneration in ALS and imply that restoring STMN2 levels is a promising therapeutic approach for TDP-43-dependent ALS.</p><p>To test the effect of correcting <i>STMN2</i> pre-mRNA metabolism against TDP-43 proteinopathy, Baughn et al. pioneered this study to elucidate the detailed mechanism by which TDP-43 modulates STMN2 expression. They used CRISPR-Cas9 to clarify that TDP-43 binding to the exon 2a (a region containing a 24-base GU-rich segment between the cryptic splicing site and polyadenylation site in the first intron) of <i>STMN2</i> prevents misprocessing by blocking the recognition of cryptic RNA elements [17]. They subsequently substituted the 24-base GU-rich domain with a 19-base segment encoding the bacteriophage MS2 aptamer sequence, an RNA stem-loop structure that can be bound by the MS2 coat protein, thus preventing direct TDP-43 interaction. This substitution resulted in constitutive misprocessing of STMN2 pre-mRNA. Further genome editing analysis revealed that instead of the cryptic polyadenylation site, the cryptic 3’ splice acceptor is essential for initiating <i>STMN2</i> pre-mRNA misprocessing. Based on this critical finding, they attempted to suppress cryptic splicing of <i>STMN2</i> pre-mRNA by use of dCasRx (the “nuclease-dead” variant of the CRISPR effector RfxCas13d, which retains RNA-binding capability without enzymatic activity) or antisense oligonucleotides (ASOs), which restored STMN2 levels and axonal regeneration in TDP-43-deficient human MNs. Critically, ASOs injected into the cerebral spinal fluid of mice containing humanized STMN2 with cryptic splice-polyadenylation sequences could restore Stmn2 protein level and axonal regrowth [17] (Fig. 1).</p>\n<figure><figcaption><b data-test=\"figure-caption-text\">Fig. 1</b></figcaption><picture><source srcset=\"//media.springernature.com/lw685/springer-static/image/art%3A10.1186%2Fs40035-024-00413-0/MediaObjects/40035_2024_413_Fig1_HTML.png?as=webp\" type=\"image/webp\"/><img alt=\"figure 1\" aria-describedby=\"Fig1\" height=\"380\" loading=\"lazy\" src=\"//media.springernature.com/lw685/springer-static/image/art%3A10.1186%2Fs40035-024-00413-0/MediaObjects/40035_2024_413_Fig1_HTML.png\" width=\"685\"/></picture><p>TDP-43 binds directly to <i>STMN2</i> pre-mRNA to guarantee normal splicing of <i>STMN2</i> mRNA. Pathogenic (reduced) TDP-43 drives premature polyadenylation and aberrant splicing by steric inhibition in the first intron of the STMN2 pre-mRNA, producing a non-functional mRNA. Using dCasRx or antisense oligonucleotides (ASOs) to target the first intron of the <i>STMN2</i> pre-mRNA can efficiently restore STMN2 level and axonal regeneration in TDP-43 proteinopathy. Although current studies have provided promising results, animal models are required to confirm the efficiency and safety before clinic trials</p><span>Full size image</span><svg aria-hidden=\"true\" focusable=\"false\" height=\"16\" role=\"img\" width=\"16\"><use xlink:href=\"#icon-eds-i-chevron-right-small\" xmlns:xlink=\"http://www.w3.org/1999/xlink\"></use></svg></figure><p>Collectively, these studies indicate that a reduction in STMN2 is a critical biomarker for TDP-43 proteinopathy. Approaches that can restore STMN2 protein level are likely efficient in promoting MN regeneration. However, all current studies lack in vivo examination of functional/behavioral outcomes. Another core issue is how to maintain moderate levels of STMN2 since increased or decreased expression of STMN2 could be a barrier to axonal outgrowth/regeneration during patient treatment. Despite the gap from bench to bedside, STMN2 is a potential therapeutic target for TDP-43 proteinopathy.</p><p>Not applicable.</p><dl><dt style=\"min-width:50px;\"><dfn>ALS:</dfn></dt><dd>\n<p>Amyotrophic lateral sclerosis</p>\n</dd><dt style=\"min-width:50px;\"><dfn>ASO:</dfn></dt><dd>\n<p>Antisense oligonucleotide</p>\n</dd><dt style=\"min-width:50px;\"><dfn>hMN:</dfn></dt><dd>\n<p>Human motor neuron</p>\n</dd><dt style=\"min-width:50px;\"><dfn>MN:</dfn></dt><dd>\n<p>Motor neuron</p>\n</dd><dt style=\"min-width:50px;\"><dfn>NMJ:</dfn></dt><dd>\n<p>Neuromuscular junction</p>\n</dd><dt style=\"min-width:50px;\"><dfn>TDP-43:</dfn></dt><dd>\n<p>Trans-reactive DNA binding protein 43 KD</p>\n</dd><dt style=\"min-width:50px;\"><dfn>STMN2:</dfn></dt><dd>\n<p>Stathmin 2</p>\n</dd></dl><ol data-track-component=\"outbound reference\"><li data-counter=\"1.\"><p>Ilieva H, Vullaganti M, Kwan J. Advances in molecular pathology, diagnosis, and treatment of amyotrophic lateral sclerosis. 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Science. 2023;379:1140–9.</p><p>Article CAS PubMed PubMed Central Google Scholar </p></li></ol><p>Download references<svg aria-hidden=\"true\" focusable=\"false\" height=\"16\" role=\"img\" width=\"16\"><use xlink:href=\"#icon-eds-i-download-medium\" xmlns:xlink=\"http://www.w3.org/1999/xlink\"></use></svg></p><p>We would like to apologize to colleagues whose work could not be cited here due to space restrictions.</p><p>This work was supported by grants from Guangdong Basic and Applied Basic Research Foundation (2023A1515010477), the National Natural Science Foundation of China (32000690), the Key-Area Research and Development Program of Guangdong Province, China (2019B030335001), and the Key Medical and Health Projects of Panyu District Science and Technology Plan, Guangzhou, China (2023-Z04-103).</p><span>Author notes</span><ol><li><p>Yunqing Liu, Dejun Yan and Lin Yang contributed equally to this work.</p></li></ol><h3>Authors and Affiliations</h3><ol><li><p>Key Laboratory of Brain, Cognition and Education Sciences, South China Normal University, Ministry of Education, Guangzhou, China</p><p>Yunqing Liu, Dejun Yan, Xian Chen &amp; Chun Hu</p></li><li><p>Institute for Brain Research and Rehabilitation, South China Normal University, Guangzhou, 510631, China</p><p>Yunqing Liu, Dejun Yan, Xian Chen &amp; Chun Hu</p></li><li><p>Guangdong Second Provincial General Hospital, Guangzhou, 510317, China</p><p>Chun Hu &amp; Meilan Chen</p></li><li><p>Department of Anesthesiology, the Affiliated Panyu Central Hospital of Guangzhou Medical University, Guangzhou, China</p><p>Lin Yang</p></li><li><p>Rehabilitation Medicine Institute of Panyu District, Guangzhou, 511499, China</p><p>Lin Yang</p></li></ol><span>Authors</span><ol><li><span>Yunqing Liu</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li><li><span>Dejun Yan</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li><li><span>Lin Yang</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li><li><span>Xian Chen</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li><li><span>Chun Hu</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li><li><span>Meilan Chen</span>View author publications<p>You can also search for this author in <span>PubMed<span> </span>Google Scholar</span></p></li></ol><h3>Contributions</h3><p>C.H. and M.L.C. conceived the idea. Y.Q.L., D.J.Y. and L.Y. wrote the draft and prepared the Figure. X.C. helped collect and review the references. M.L.C revised the manuscript with input from all authors.</p><h3>Corresponding authors</h3><p>Correspondence to Chun Hu or Meilan Chen.</p><h3>Ethics approval and consent to participate</h3>\n<p>Not applicable.</p>\n<h3>Consent for publication</h3>\n<p>Not applicable.</p>\n<h3>Competing interests</h3>\n<p>None.</p><p><b>Open Access</b> This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data.</p>\n<p>Reprints and permissions</p><img alt=\"Check for updates. 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Abstract

Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease characterized by the selective loss of motor neurons (MNs), resulting in progressive disability and mortality with a rapid course. Current approaches such as multidisciplinary care, disease-modifying therapies, pulmonary intervention, and dietary and nutritional intervention can only slow ALS progression [1]. It is imperative to dissect the underlying mechanisms and explore novel treatment targets.

Trans-reactive DNA binding protein 43 KD (TDP-43) is a main component of abnormal cytoplasmic protein deposits observed in ~ 97% of ALS patients, and its presence is considered a pathological hallmark of ALS regardless of the disease onset. Physiologically, TDP-43 is a multifunctional protein that predominantly localizes to the nucleus, where it binds to GU-rich sequences for selective splicing. It also shuttles to the cytoplasm to generate ribonucleoprotein transport/stress granules and control translation. However, abnormal modifications of TDP-43 reduce its functional level in the nucleus and promotes the formation of cytoplasmic inclusions in MNs, inducing neurotoxic effects known as TDP-43 proteinopathy.

Initial efforts were dedicated to analyzing the binding sites of TDP-43 in mouse and human brains, showing that TDP-43 could target approximately 1000 mRNAs, a large portion being glial RNAs, providing limited insights into neuronal targets. The following study established a method for inducing human embryonic stem cells to differentiate into human MNs (hMNs), providing a more reliable model for investigating disease stimuli and therapeutic strategies [2]. With induced hMNs, Klim et al. [3] revealed that the expression of stathmin-2 (STMN2) was significantly reduced upon TDP-43 depletion. Similar results have been observed in patient-derived MNs and postmortem patient spinal cords harboring TDP-43 mislocalization [4]. Mechanistically, functional TDP-43 binds directly to STMN2 pre-mRNA to maintain normal splicing. Pathological TDP-43 drives premature polyadenylation and cryptic splicing in the first intron of STMN2 pre-mRNA, leading to the production of a nonfunctional mRNA [4]. Reduction of TDP-43 or STMN2 in iPSC-derived MNs inhibited axonal regeneration after induced damage. Notably, restoration/stabilization of STMN2 rescued neurite outgrowth and axon regeneration in the absence of TDP-43 [3, 4].

STMN2 belongs to the conserved Stathmin family. It can depolymerize microtubules via unclear mechanisms and is specifically expressed in the nervous system for axonal development and maintenance (see details in [5]). A moderate level of STMN2 stimulates neurite outgrowth by modulating microtubule dynamics, whereas excessive or reduced levels of STMN2 cause growth cone collapse or suppress neurite outgrowth in neurons. In cultured sensory neurons from dorsal root ganglion (DRG) subjected to axotomy, Stmn2 was elevated in regenerating growth cones. Downregulation of Stmn2 accelerated axon fragmentation, whereas experimental rescue of the Stmn2 level delayed axonal degeneration [6]. Similarly, loss of Stai, a homolog of STMN2 in Drosophila, leads to neuromuscular junction (NMJ) degeneration and motor axon retraction [7, 8]. Recently, Krus et al. generated both constitutive and conditional Stmn2 knockout mice and reported that Stmn2 is required for motor and sensory system function [9]. Constitutive Stmn2 knockout (Stmn2−/−) induces severe motor and sensory neuropathy, including decreased compound muscle action potentials, NMJ denervation, and reduced nerve fiber density. Importantly, Stmn2−/− mice predominantly exhibit degeneration of fast-fatigable motor units, similar to that observed in ALS patients. Loss of Stmn2 specifically in MNs recapitulates the NMJ pathology found in Stmn2−/− mice [9]. The authors further studied Stmn2+/− mice, which mimic the partial loss of STMN2 in ALS patients and exhibit selective motor neuropathy. Like Stmn2−/− mice, the Stmn2+/− heterozygous mice behave normally as young adults but show motor weakness by 1 year of age [9]. This progressive motor neuropathy is also a typical clinical symptom of ALS patients. Moreover, adult mice with absence of Stmn-2 exhibit phenotypes comparable to those of ALS patients [10], suggesting that STMN2 is involved in ALS pathology.

Nevertheless, there is emerging evidence of aberrant STMN2 in ALS patients. A noncoding CA repeat in STMN2 that may affect mRNA processing has been reported to be associated with sporadic ALS in a North American cohort [11]. Moreover, two independent groups detected cryptic exons of STMN2 in postmortem brain tissues from patients with TDP-43-associated Alzheimer’s disease [12] and C9ORF72 patients who were susceptible to TDP-43 pathology [13]. Consistently, in an unbiased study of single-cell protein expression profiles with human spinal MNs directly sampled from TDP-43 ALS patients, a lower frequency of the STMN2 protein was detected [14]. Via in situ hybridization, they detected a robust decrease in the STMN2 RNA level in ALS MNs [14]. Importantly, cryptic splicing of STMN2 was confirmed in TDP-43-depleted human iPSC-derived MNs [15] and iPSC MNs from postmortem sporadic TDP-43 ALS patients [16]. Thus, these findings reveal a strong link between aberrant STMN2 expression and MN degeneration in ALS and imply that restoring STMN2 levels is a promising therapeutic approach for TDP-43-dependent ALS.

To test the effect of correcting STMN2 pre-mRNA metabolism against TDP-43 proteinopathy, Baughn et al. pioneered this study to elucidate the detailed mechanism by which TDP-43 modulates STMN2 expression. They used CRISPR-Cas9 to clarify that TDP-43 binding to the exon 2a (a region containing a 24-base GU-rich segment between the cryptic splicing site and polyadenylation site in the first intron) of STMN2 prevents misprocessing by blocking the recognition of cryptic RNA elements [17]. They subsequently substituted the 24-base GU-rich domain with a 19-base segment encoding the bacteriophage MS2 aptamer sequence, an RNA stem-loop structure that can be bound by the MS2 coat protein, thus preventing direct TDP-43 interaction. This substitution resulted in constitutive misprocessing of STMN2 pre-mRNA. Further genome editing analysis revealed that instead of the cryptic polyadenylation site, the cryptic 3’ splice acceptor is essential for initiating STMN2 pre-mRNA misprocessing. Based on this critical finding, they attempted to suppress cryptic splicing of STMN2 pre-mRNA by use of dCasRx (the “nuclease-dead” variant of the CRISPR effector RfxCas13d, which retains RNA-binding capability without enzymatic activity) or antisense oligonucleotides (ASOs), which restored STMN2 levels and axonal regeneration in TDP-43-deficient human MNs. Critically, ASOs injected into the cerebral spinal fluid of mice containing humanized STMN2 with cryptic splice-polyadenylation sequences could restore Stmn2 protein level and axonal regrowth [17] (Fig. 1).

Fig. 1
Abstract Image

TDP-43 binds directly to STMN2 pre-mRNA to guarantee normal splicing of STMN2 mRNA. Pathogenic (reduced) TDP-43 drives premature polyadenylation and aberrant splicing by steric inhibition in the first intron of the STMN2 pre-mRNA, producing a non-functional mRNA. Using dCasRx or antisense oligonucleotides (ASOs) to target the first intron of the STMN2 pre-mRNA can efficiently restore STMN2 level and axonal regeneration in TDP-43 proteinopathy. Although current studies have provided promising results, animal models are required to confirm the efficiency and safety before clinic trials

Full size image

Collectively, these studies indicate that a reduction in STMN2 is a critical biomarker for TDP-43 proteinopathy. Approaches that can restore STMN2 protein level are likely efficient in promoting MN regeneration. However, all current studies lack in vivo examination of functional/behavioral outcomes. Another core issue is how to maintain moderate levels of STMN2 since increased or decreased expression of STMN2 could be a barrier to axonal outgrowth/regeneration during patient treatment. Despite the gap from bench to bedside, STMN2 is a potential therapeutic target for TDP-43 proteinopathy.

Not applicable.

ALS:

Amyotrophic lateral sclerosis

ASO:

Antisense oligonucleotide

hMN:

Human motor neuron

MN:

Motor neuron

NMJ:

Neuromuscular junction

TDP-43:

Trans-reactive DNA binding protein 43 KD

STMN2:

Stathmin 2

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We would like to apologize to colleagues whose work could not be cited here due to space restrictions.

This work was supported by grants from Guangdong Basic and Applied Basic Research Foundation (2023A1515010477), the National Natural Science Foundation of China (32000690), the Key-Area Research and Development Program of Guangdong Province, China (2019B030335001), and the Key Medical and Health Projects of Panyu District Science and Technology Plan, Guangzhou, China (2023-Z04-103).

Author notes
  1. Yunqing Liu, Dejun Yan and Lin Yang contributed equally to this work.

Authors and Affiliations

  1. Key Laboratory of Brain, Cognition and Education Sciences, South China Normal University, Ministry of Education, Guangzhou, China

    Yunqing Liu, Dejun Yan, Xian Chen & Chun Hu

  2. Institute for Brain Research and Rehabilitation, South China Normal University, Guangzhou, 510631, China

    Yunqing Liu, Dejun Yan, Xian Chen & Chun Hu

  3. Guangdong Second Provincial General Hospital, Guangzhou, 510317, China

    Chun Hu & Meilan Chen

  4. Department of Anesthesiology, the Affiliated Panyu Central Hospital of Guangzhou Medical University, Guangzhou, China

    Lin Yang

  5. Rehabilitation Medicine Institute of Panyu District, Guangzhou, 511499, China

    Lin Yang

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Contributions

C.H. and M.L.C. conceived the idea. Y.Q.L., D.J.Y. and L.Y. wrote the draft and prepared the Figure. X.C. helped collect and review the references. M.L.C revised the manuscript with input from all authors.

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Correspondence to Chun Hu or Meilan Chen.

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Liu, Y., Yan, D., Yang, L. et al. Stathmin 2 is a potential treatment target for TDP-43 proteinopathy in amyotrophic lateral sclerosis. Transl Neurodegener 13, 20 (2024). https://doi.org/10.1186/s40035-024-00413-0

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Stathmin 2 是肌萎缩侧索硬化症 TDP-43 蛋白病变的潜在治疗靶点
肌萎缩性脊髓侧索硬化症(ALS)是一种神经退行性疾病,其特征是运动神经元(MN)的选择性丧失,导致进行性残疾和死亡,病程迅速。目前的方法,如多学科护理、疾病改变疗法、肺部干预、饮食和营养干预等,只能延缓 ALS 的进展[1]。反式反应 DNA 结合蛋白 43 KD(TDP-43)是在约 97% 的 ALS 患者中观察到的异常细胞质蛋白沉积的主要成分,无论发病与否,它的存在都被认为是 ALS 的病理标志。在生理学上,TDP-43 是一种多功能蛋白质,主要定位于细胞核,与富含 GU 的序列结合进行选择性剪接。它还能穿梭到细胞质中,生成核糖核蛋白转运/应激颗粒并控制翻译。最初的研究致力于分析 TDP-43 在小鼠和人脑中的结合位点,结果表明 TDP-43 可靶向约 1000 个 mRNA,其中很大一部分是神经胶质 RNA,但对神经元靶点的了解有限。随后的研究建立了一种诱导人类胚胎干细胞分化为人类 MNs(hMNs)的方法,为研究疾病刺激和治疗策略提供了更可靠的模型[2]。Klim 等人[3]利用诱导的 hMNs 发现,TDP-43 消耗后,stathmin-2(STMN2)的表达明显减少。在病人衍生的 MNs 和死后病人脊髓中也观察到了类似的 TDP-43 错定位结果[4]。从机制上讲,功能性 TDP-43 直接与 STMN2 前 mRNA 结合,以维持正常的剪接。病理 TDP-43 会促使 STMN2 前 mRNA 的第一个内含子过早发生多腺苷酸化和隐性剪接,导致产生无功能的 mRNA [4]。iPSC 衍生的中枢神经细胞中 TDP-43 或 STMN2 的减少抑制了诱导损伤后的轴突再生。值得注意的是,在没有 TDP-43 的情况下,STMN2 的恢复/稳定可挽救神经元的生长和轴突再生 [3,4]。STMN2 属于保守的 Stathmin 家族,它能通过不明确的机制解聚微管,并在神经系统中特异性表达,用于轴突的发育和维持(详见文献[5])。中等水平的 STMN2 可通过调节微管动力学刺激神经元的生长,而过高或过低水平的 STMN2 则会导致神经元生长锥塌陷或抑制神经元的生长。在接受轴突切断术的背根神经节(DRG)培养感觉神经元中,再生生长锥中的 Stmn2 升高。下调 Stmn2 会加速轴突碎裂,而通过实验挽救 Stmn2 水平会延缓轴突变性 [6]。同样,果蝇中 STMN2 的同源物 Stai 的缺失会导致神经肌肉接头(NMJ)退化和运动轴突回缩 [7,8]。最近,Krus 等人产生了组成型和条件型 Stmn2 基因敲除小鼠,并报告说 Stmn2 是运动和感觉系统功能所必需的 [9]。组成型 Stmn2 基因敲除(Stmn2-/-)会诱发严重的运动和感觉神经病,包括复合肌肉动作电位下降、NMJ 神经支配和神经纤维密度降低。重要的是,Stmn2-/- 小鼠主要表现出快速易疲劳运动单位的变性,这与 ALS 患者的表现类似。运动神经元中 Stmn2 的特异性缺失再现了在 Stmn2/-小鼠中发现的 NMJ 病理[9]。作者进一步研究了 Stmn2+/- 小鼠,这种小鼠模拟了 ALS 患者 STMN2 的部分缺失,表现出选择性运动神经病变。与 Stmn2-/- 小鼠一样,Stmn2+/- 杂合子小鼠在幼年时表现正常,但到 1 岁时会出现运动无力 [9]。这种进行性运动神经病变也是 ALS 患者的典型临床症状。此外,缺失 Stmn-2 的成年小鼠表现出与 ALS 患者相似的表型 [10],这表明 STMN2 参与了 ALS 的病理过程。据报道,在北美的一个队列中,STMN2 中一个可能影响 mRNA 处理的非编码 CA 重复与散发性 ALS 有关 [11]。此外,两个独立的研究小组在 TDP-43 相关阿尔茨海默病患者[12] 和易受 TDP-43 病变影响的 C9ORF72 患者的死后脑组织中检测到了 STMN2 的隐含外显子[13]。与此相一致的是,在一项直接从 TDP-43 ALS 患者脊髓 MNs 取样的单细胞蛋白表达谱的无偏见研究中,检测到 STMN2 蛋白的频率较低[14]。 文章 CAS PubMed PubMed Central Google Scholar Lépine S, Castellanos-Montiel MJ, Durcan TM.肌萎缩侧索硬化症中的 TDP-43 失调和神经肌肉接头破坏。Transl Neurodegener.2022;11:56.Article PubMed PubMed Central Google Scholar Krus KL, Strickland A, Yamada Y, Devault L, Schmidt RE, Bloom AJ, et al. Loss of Stathmin-2, a hallmark of TDP-43-associated ALS, causes motor neuropathy.Cell Rep. 2022;39:111001.Article CAS PubMed PubMed Central Google Scholar López-Erauskin J, Bravo-Hernandez M, Presa M, Baughn MW, Melamed Z, Beccari MS, et al. Stathmin-2 缺失导致神经丝依赖性轴突塌陷,驱动运动和感觉神经剥夺。Nat Neurosci.2023. https://doi.org/10.1038/s41593-023-01496-0.Theunissen F, Anderton RS, Mastaglia FL, Flynn LL, Winter SJ, James I, et al. Novel STMN2 variant linked to amyotrophic lateral sclerosis risk and clinical phenotype.Front Aging Neurosci.2021;13:658226.Agra Almeida Quadros AR, Li Z, Wang X, et al. Cryptic splicing of stathmin-2 and UNC13A mRNAs is a pathological hallmark of TDP-43-associated Alzheimer's disease.Acta Neuropathol.2024;147:9. https://doi.org/10.1007/s00401-023-02655-0.Gittings LM, Alsop EB, Antone J, Singer M, Whitsett TG, Sattler R, et al. Cryptic exon detection and transcriptomic changes revealed in single-nuclei RNA sequencing of C9ORF72 patients spanning the ALS-FTD spectrum.Acta Neuropathol (Berl).2023;146:433-50.Article CAS PubMed Google Scholar Guise AJ, Misal SA, Carson R, Boekweg H, Watt DVD, Truong T et al. TDP-43-stratified single-cell proteomic profiling of postmortem human spinal motor neurons reveals protein dynamics in amyotrophic lateral sclerosis.bioRxiv. https://doi.org/10.1101/2023.06.08.544233.Seddighi S, Qi YA, Brown AL, Wilkins OG, Bereda C, Belair C, et al.Sci Transl Med.2024;16(734):eadg7162.Article CAS PubMed Google Scholar Held A, Adler M, Marques C, Reyes CJ, Kavuturu AS, Quadros ARAA, et al. IPSC 运动神经元,而非其他衍生细胞类型,捕获了死后散发性 ALS 运动神经元的基因表达变化。Cell Rep. 2023;42:113046.Article CAS PubMed PubMed Central Google Scholar Baughn MW, Melamed Z, López-Erauskin J, Beccari MS, Ling K, Zuberi A, et al.科学。2023;379:1140-9.Article CAS PubMed PubMed Central Google Scholar 下载参考文献我们谨向因篇幅限制而无法在此引用其研究成果的同事表示歉意。本研究得到广东省基础与应用基础研究基金(2023A1515010477)、国家自然科学基金(32000690)、广东省重点研发计划(2019B030335001)和广州市番禺区科技计划医药卫生重点项目(2023-Z04-103)的资助。作者及工作单位华南师范大学脑科学、认知科学与教育科学教育部重点实验室,广州,中国刘云清,严德军,陈娴,胡春华南师范大学脑研究与康复学院,广州,510631,中国刘云清,严德军,陈娴,胡春广东省第二人民医院,广州,510317,中国胡春&amp;陈美兰广州医科大学附属番禺中心医院麻醉科 杨林广州市番禺区康复医学研究所 511499、中国杨林作者:刘云青查看作者发表论文您也可以在PubMed Google Scholar中搜索该作者严德军查看作者发表论文您也可以在PubMed Google Scholar中搜索该作者杨林查看作者发表论文您也可以在PubMed Google Scholar中搜索该作者ScholarXian ChenView 作者发表作品您也可以在 PubMed Google Scholar中搜索该作者Chun HuView 作者发表作品您也可以在 PubMed Google Scholar中搜索该作者Meilan ChenView 作者发表作品您也可以在 PubMed Google Scholar中搜索该作者ContributionsC.H.和M.L.C.构思了这一想法。Y.Q.L.、D.J.Y.和L.Y.撰写了草案并准备了图表。X.C. 帮助收集和审阅参考文献。通讯作者:胡春或陈美兰伦理批准和参与同意书不适用发表同意书不适用竞争利益无开放存取本文采用知识共享署名 4.0(Creative Commons Attribution 4.
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来源期刊
Translational Neurodegeneration
Translational Neurodegeneration Neuroscience-Cognitive Neuroscience
CiteScore
19.50
自引率
0.80%
发文量
44
审稿时长
10 weeks
期刊介绍: Translational Neurodegeneration, an open-access, peer-reviewed journal, addresses all aspects of neurodegenerative diseases. It serves as a prominent platform for research, therapeutics, and education, fostering discussions and insights across basic, translational, and clinical research domains. Covering Parkinson's disease, Alzheimer's disease, and other neurodegenerative conditions, it welcomes contributions on epidemiology, pathogenesis, diagnosis, prevention, drug development, rehabilitation, and drug delivery. Scientists, clinicians, and physician-scientists are encouraged to share their work in this specialized journal tailored to their fields.
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