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CD8 T cell-neuron cross-talk: a hallmark of axonal regenerative decline Author︱Luming Zhou and Simone Di Giovanni (Department of Brain Sciences, Imperial College London, Division of Neuroscience, London, United Kingdom) Editor-in-Chief︱Sizhen WangAssociate Editor︱Yi LuEditor︱Jiaxue Zha Aging has been linked to an increased prevalence of axonal injuries, which are characterized by inadequate regeneration and significant impairment [1-
However, the cellular and molecular understanding of the age-dependent regenerative decline is very spar.
Previous studies showed that an age-related impairment in de-differentiation and activation of Schwann cells (SCs) limits axonal regrowth in the injured nervous peripheral system (PNS), impairing sensory and motor recovery [5,
In the central nervous system, following spinal cord injury,deletion of PTEN with an increase in mTOR signaling can only partially limit the aging-dependent axonal regenerative decay of corticospinal tracts [
These studies addressed some of the molecular mechanisms underpinning the aging-dependent molecular changes following an injury while aging in itself leads to profound modifications in cell signaling, metabolism, immunity, gene regulation, and protein translation in every tissue affecting homeostasis and predisposing to disease [8-1
Recently, Zhou et .
from Professor Simone Di Giovanni's lab in Imperial College London discovered that the inflammatory cytokine lymphotoxin activates NFκB, which induces the neuronal expression of the chemoattractive protein CXC motif chemokine ligand 13 (CXCL13) that in turn recruits CXCR5+ CD8+ T cells in proximity of aged DRG neurons expressing MHC.
CD8 T cells repress axonal regeneration of sensory DRG neurons by inhibiting the regenerative signals pAKT and pS6 via caspase 3 activati.
Remarkably, CXCL13 neutralization with monoclonal antibodies prevents CXCR5+ CD8+ T cell recruitment to the DRG and reverses aging-dependent regenerative decline promoting neurological recovery following sciatic nerve injury (SN.
These data propose a novel aging-dependent mechanism restricting the axonal regenerative ability and offer a clinically suitable antibody-based manipulation of neuron-immune cell communication to promote repa.
This work was published in Science on 13th May 202
In order to identify the aging-dependent gene expression profile,the authors initially performed RNA sequencing from sciatic DRG from 8-10 weeks (young) versus 20-22 months old mice (aged) both preceding (sham) or following asciatic nerve injury (SN.
Gene Ontology (GO), KEGG pathway and STRING analysis using significantly differentially expressed (DE) genes (FDR<05) suggested a very significant enrichment in the adaptive immune response including in T and B cell signaling and increased chemotaxis of T and B cells in aged DRG, both preceding and following SNI ( F.
1A-.
This implies an increased activation of specific subtypes of lymphocytes that might be recruited to aged DRG by the induction of chemo-/cytokines including after nerve inju.
This implication further led to identify CXCL13 as by far the most prominently upregulated gene as well as its receptor CXCR5,suggesting the presence of a CXCL13/CXCR5 signaling axis (F.
1.
F.
Aging induces enrichment in genes associated with chemokine and cytokine expression and adaptive immunity in dorsal root ganglia, including after S.
(Zhou et .
, Science , 2022) In addition to observing the neuronal enrichment of CXCL13 and its significant increase in aged DRG before and 3 days after sciatic nerve where crush regeneration was reduced in the aged mice (F.
1D-I), the authors identified a robust accumulation of B and T cells including CXCR5+ B and T cells in aged D.
Interestingly, a considerable number of CD8+ and CXCR5+ CD8+ T cells were CD44+CD69+CD62L–, indicating effector memory T cells (F.
2.
F.
Characterization of B and T cells in D.
(Zhou et .
, Science, 2022) subsequently,to address whether in vivo neuronal expression of CXCL13 would attract CXCR5+ B and T cells, CXCL13 was overexpressed in DRG neurons by infecting sciatic nerves of young mice with AAV-GFP or AAV-CXCL13-G.
Strickingly, both CXCR5+ B and CD8+ T cells were significantly increased in CXCL13 overexpressing DRG compared to GFP control (F.
3A-.
Although the number of migratory CXCR5+ CD4+ T cells in DRG was significantly increased, the percentage with respect to total T cells did not change (F.
3E- .
Importantly, sciatic nerve regeneration after AAV-CXCL13 overexpression to find a significant reduction in axonal regeneration with respect to AAV-GFP injected mice (F.
3G-.
These data indicate that DRG neuronal overexpression of CXCL13 recruits CXCR5+ B and T cells and it inhibits axonal regeneration partially phenocopying the aging phenoty.
F.
Overexpression of CXCL13 in DRG neurons in young mice facilitates the recruitment of CXCR5+ B and T cells to the DRG and reduces sciatic nerve regenerati.
(Zhou et .
, Science, 2022) To explore CXCL13 expression signaling, the transcription factors (TFs) putatively involved in driving aging-dependent CXCL13 expression were analyzed in the RNAseq dataset and only Nfkb2 was significantly upregulated in aged DRG becoming a natural candidate for further investigation (F.
4.
Several cytokines stimulating NFκB signaling including TNFα, Il1β and lymphotoxin beta subunit (LTα1β2) [13] were screened in primary DRG cell culture and only LTα1β2 significantly enhanced the expression of both Nfkb2 and Cxcl13, which could be attenuated by selective inhibition of the NFκB kinase IKK by using the IKK inhibitor PS1145 (F.
4B-.
Both expression and NFκB2 phosphorylation were also induced in aged DRG in vi.
When PS1145 inhibited the phosphorylation of NFkB2, the increase of CXCL13 expression was block.
These data suggest that aging-related CXCL13 expression is driven by lymphotoxin beta-triggered NFkB2 signaling (F.
4D-.
F.
CXCL13 expression is modulated by lymphotoxin-beta induced NFkB2 signaling in D.
(Zhou et .
, Science, 2022) Are CD8, CD4 T and/or B cells required to impair axonal regeneration of aged sciatic DRG neurons? To address this question, specifically antibody-mediated cell depletion against CD8, CD4 T or B cells respectively was performed in aged mice followed by a sciatic nerve crush for 3 da.
Interestingly,CD8 monoclonal antibody promoted nerve regeneration while depletion of CD4+ T cells or B cells did not alter the aging-dependent regenerative decline following sciatic nerve injury (F.
5A-.
F.
CD8+ T cells and neuronal MHC I are required for age-dependent regenerative decline after SNI through pAKT and pS (Zhou et .
, Science, 2022) MHC-I is expressed by antigen-presenting cells (APCs) to present antigenic peptides on the cell membrane to activate CD8+ T cells after engaging with T cell receptors (TCRs) [1
Given the increased expression and membrane localization of MHC-I in aged DRG neurons (F.
5D-F), the authors hypothesized the requirement of MHC-I expression for the activation of CD8+ T cells to limit nerve regeneration after inju.
Thus, an AAV-based approach was applied to express the virally encoded peptide sequence GAr,which inhibits MHC-I antigen presentation evading CD8+ T cell immune responses [15], in sciatic DRG of aged mi.
GAr was linked to a reverse tetracycline transactivator (rtTA) responsive to tetracycline/doxycycline inducible expression with a luciferase reporter [16-18.
Following viral infection in sciatic DRG and a sciatic nerve injury for 3 days in aged mice, MHC-I and cleaved caspase 3 expression were significantly reduced and sciatic axonal regeneration was enhanced upon AAV-GAr-rtTA infection (F.
5G-J.
Together, these data suggest that CD8+ T cells and neuronal MHC-I are required for aging-dependent regenerative decline following S.
Based upon the evidence of enhanced sciatic nerve regeneration when caspase 3 was inactivated in GAr-expressed DRG neurons where MHC- I was disrupted,the authors further discovered a significant induction of cleaved caspase 3 in aged DRG neurons after nerve injury (F.
5K-.
Strikingly, the phosphorylation of two outstanding regeneration-associated regulators, AKT and S6, was decreased in aged DRG which was significantly reversed by depletion of CD8+ T cells (F.
5M-.
Together these data indicate that CD8+ T cell-dependent activation of caspase 3 is required to inhibit pAKT and pS6 in aged DRG neurons after SNI and that inhibition of caspase 3 activation promotes axonal regenerati.
F.
CXCR5+CD8+ T cells cause aging-dependent regenerative decline after S.
(Zhou et .
, Science, 2022) To determine whether CXCR5+ CD8+ T cells are directly responsible for axonal regenerative decline after sciatic nerve injury,WT or CXCR5-/- CD8+ T cells were isolated and adoptively transferred to the young and aged OT-I Rag-/- mice, which are B/T cell deficient, and mice were sacrificed 3 days after nerve inju.
The results showed a robust infiltration of adoptively transferred CXCR5+ CD8+ T cells in aged DRG, however these cells were barely detectable in the young recipients (F.
6A-.
On the contrary, transferred CXCR5+ CD8+ T cells accumulated more abundantly in the young spleen versus the old (F.
5A-.
These migratory patterns of CXCR5+ CD8+ T cells were in line with the differential CXCL13 levels in the young versus aged DRG and spleen tissues (F.
6.
Additionally,Adoptive transfer of CXCR5+ CD8+ T cells led to a significantly reduced sciatic nerve regeneration after injury only in aged mice where significantly increased perforin and decreased pS6 were observed in DRG neurons (F.
6D-.
It suggests that CXCR5+ CD8+ T cells drive aging -dependent axonal regenerative decline after sciatic nerve inju.
F.
CXCL13 neutralization enhances axonal regeneration, epidermal reinnervation, and sensory functional recovery after SNI in aged mi.
(Zhou et .
, Science, 2022)Lastly, the authors investigated whether blocking CXCL13-dependent pathway could offer a therapeutic opportunity to rejuvenate the sciatic nerve regenerative capaci.
Compared to control IgG,they observed that injection of monoclonal antibody against CXCL13 prevented the recruitment of CXCR5+ CD8+ T cells and significantly promoted sciatic nerve regeneration at acute phase after injury and chronically sensory recovery only in aged mice (F.
F.
Aging-dependent regenerative failure in injured sensory neuro.
(Zhou et .
, Science, 2022) Conclusion & Discussion, Inspiration & ExpectationIn summary, this work unveils a novel concept that aging primes DRG neurons for regenerative failure following axonal injury by a CXCL13-dependent mechanism that regulates CXCR5+ CD8+ T cells entry into the DRG (F.
Regenerative failure is a consequence of the CXCL13-dependent DRG recruitment of CXCR5+ CD8+ T cells that communicate with DRG neurons via MHC-I on the neuronal cell surface to drive regenerative inhibitory signalin.
While the nature of the aging and injury-dependent antigens remain elusive and deserves further investigation, it is intriguing to speculate that the combination of injury-dependent antigens with viral peptides accumulated and processed during the lifespan could lead to T cell-dependent neuronal MHC- I recognition and inhibition of axonal regeneration after inju.
More interestingly, an inverse relationship in the expression levels of CXCL13 between spleen and DRG tissues in young and aged mice with corresponding opposite tissue accumulation of CXCR5+ CD8+ T cel.
This might not only underpin the mechanism by which these cells accumulate in peripheral tissues, but it might also contribute to a CXCL13-dependent deterioration of immune defense in secondary lymphoid organs that is concomitant with an increase in immune-mediated neuronal dama.
Whether this underlines a general phenomenon that goes beyond the peripheral nervous system remains to be determin.
CXCL13 neutralization effectively promoted axonal regeneration and neurological recovery in aged mice while systemic delivery of anti-CXCL13 antibody might affect CXCR5+ T an B cell homing in the secondary lymph tissues, with a risk of increased susceptibility to viral infection and neoplas.
The best timing and route of antibody delivery will be considered for future targeted interventio.
Article: Zhou L, Kong G, Palmisano I, et .
, Reversible CD8 T cell- neuron cross-talk causes aging-dependent neuronal regenerative decli.
Scien.
2022 May 13;376(6594):eabd592 doi: 11126/scien.
abd592The first author-.
Luming Zhou (left); The co-first author -.
Guiping Kong (middle); The corresponding author-Pr.
Simone Di Giovanni (righ.
(Photo credit: Di Giovanni's lab) Job opportunity: Exceptionally motivated individual at the PhD or post-doctoral level are invited to apply to Di Giovanni's lab, email:.
digiovanni@imperi.
.
uk, to study the fundamental mechanisms and translational potential of cell-cell communication for repair in the nervous system across the lifesp.
Homepage of Di Giovanni's lab: https:// Talent Recruitment [1] "Logical Neuroscience" is looking for an associate editor/editor/operation position (online office) Selected articles from previous issues [1] NeuroImage︱Luo Yuejia's research group reveals the forehead control system for social information regulation risk decision-making [ 2] Nat Neurosci | Neonatal oligodendrocytes have stronger remyelination ability after demyelination [3] Biol Psychiatry︱ Tianming Gao's team revealed that astrocytes regulate adult hippocampal neurogenesis and memory through acetylcholine receptor M1 Role【4】Curr Biol︱Chen Nannan et .
Reveal the asymmetric distribution of CaMKII protein caused by the translation of synaptic region, and its role in memory formation 【5】Review of Front Aging Neurosci︱Fan Dongsheng’s team focused on the periphery and the center of amyotrophic lateral sclerosis Interaction of the immune system【6】NPP︱Wei Lu’s team revealed a new mechanism of GABAA receptor auxiliary subunit phosphorylation to regulate neural behavior 【7】Cereb Cortex︱Pattern rigidity, temporal dynamics of ventromedial prefrontal cortex affect rumination and rumination The role of depression 【8】Front Aging Neurosci︱PTAFR as a novel biomarker to help the diagnosis and treatment of Alzheimer’s disease 【9】PNAS︱Feng Guoping’s lab reveals the important role of front thalamic circuits in working memory 【10 ]Mol Psychiatry︱ Keqiang Ye's research group revealed that inflammation-activated C/EBPβ/AEP signaling pathway mediates high-fat diet-induced diabetes and Alzheimer's disease high-quality scientific research training course recommendation [1] Academic paper writing practical training course (Live: 202
21~22) [2] Symposium on Single-Cell Sequencing and Spatial Transcriptomic Data Analysis (Tencent Online Meeting on June 11-12) [3] Seminar on Patch Clamp and Optogenetics and Calcium Imaging Technology May 21- References of Tencent Conference on the 22nd (swipe up and down to read) Verdú,.
, et .
, Influence of aging on peripheral nerve function and regenerati.
Journal of the Peripheral Nervous System, 200 5(4):.
191- 20 Vaughan, DW,Effects of advancing age on peripheral nerve regenerati.
Journal of Comparative Neurology, 199 323(2):.
219-23 Pestronk,.
, DB Drachman, and JW Griffin, Effects of aging on nerve sprouting and regenerati.
Experimental neurology , 198 70(1):.
65-8 DeVivo, MJ and.
Chen, Trends in new injuries, prevalent cases, and aging with spinal cord inju.
Archives of physical medicine and rehabilitation, 201 92(3) :.
332-33 Painter, MW, et .
, Diminished Schwann cell repair responses underlie age-associated impaired axonal regenerati.
Neuron, 201 83(2):.
331-34 Kang,.
and JW Lichtman , Motor axon regeneration and muscle reinnervation in young adult and aged anima.
Journal of Neuroscience, 201 33(50):.
19480-1949Geoffroy, CG, et .
,Evidence for an age-dependent decline in axon regeneration in the adult mammalian central nervous syst.
Cell reports, 201 15(2):.
238-24 Pomatto, LC and KJ Davies, The role of declining adaptive homeostasis in agei.
The Journal of physiology, 201 595(24):.
7275-730 Barzilai,.
, et .
, The critical role of metabolic pathways in agi.
Diabetes, 201 61(6):.
1315-1321
Weiskopf,.
,.
Weinberger, and.
Grubeck‐Loebenstein, The aging of the immune syst.
Transplant international, 200 22(11):.
1041-1051Lardenoije,.
, et .
, The Epigenetics of aging and neurodegenerati.
Progress in neurobiology, 201 131:.
21-61 Taylor, RC and.
Dillin, Aging as an event of proteostasis collap.
Cold Spring Harbor perspectives in biology, 201 3(5):.
a004441 Xiao,.
, et .
,Lymphotoxin β receptor-mediated NFκB signaling promotes glial lineage differentiation and inhibits neuronal lineage differentiation in mouse brain neural stem/progenitor cel.
Journal of neuroinflammation, 201 15(1):.
41 Zinkernagel, RM, On cross-priming of MHC class I‐specific CTL: rule or exception? European journal of immunology, 200 32(9):.
2385-2391 Zaldumbide,.
and.
Hoeben, How not to be seen: immune-evasion strategies in gene therap.
Gene therapy, 200 15(4):.
239-241 Zaldumbide,.
, et .
, A potentially immunologically inert derivative of the reverse tetracycline-controlled transactivat.
Biotechnology letters, 201 32(6): p 749-751 Hoyng, SA, et .
, Developing a potentially immunologically inert tetracycline-regulatable viral vector for gene therapy in the peripheral ner.
Gene therapy, 201 21(6).
549-551 Burnside, ER, et .
, Immune-evasive gene switch enables regulated delivery of chondroitinase after spinal cord inju.
Brain, 201 141(8):.
2362-238 End of this paper
However, the cellular and molecular understanding of the age-dependent regenerative decline is very spar.
Previous studies showed that an age-related impairment in de-differentiation and activation of Schwann cells (SCs) limits axonal regrowth in the injured nervous peripheral system (PNS), impairing sensory and motor recovery [5,
In the central nervous system, following spinal cord injury,deletion of PTEN with an increase in mTOR signaling can only partially limit the aging-dependent axonal regenerative decay of corticospinal tracts [
These studies addressed some of the molecular mechanisms underpinning the aging-dependent molecular changes following an injury while aging in itself leads to profound modifications in cell signaling, metabolism, immunity, gene regulation, and protein translation in every tissue affecting homeostasis and predisposing to disease [8-1
Recently, Zhou et .
from Professor Simone Di Giovanni's lab in Imperial College London discovered that the inflammatory cytokine lymphotoxin activates NFκB, which induces the neuronal expression of the chemoattractive protein CXC motif chemokine ligand 13 (CXCL13) that in turn recruits CXCR5+ CD8+ T cells in proximity of aged DRG neurons expressing MHC.
CD8 T cells repress axonal regeneration of sensory DRG neurons by inhibiting the regenerative signals pAKT and pS6 via caspase 3 activati.
Remarkably, CXCL13 neutralization with monoclonal antibodies prevents CXCR5+ CD8+ T cell recruitment to the DRG and reverses aging-dependent regenerative decline promoting neurological recovery following sciatic nerve injury (SN.
These data propose a novel aging-dependent mechanism restricting the axonal regenerative ability and offer a clinically suitable antibody-based manipulation of neuron-immune cell communication to promote repa.
This work was published in Science on 13th May 202
In order to identify the aging-dependent gene expression profile,the authors initially performed RNA sequencing from sciatic DRG from 8-10 weeks (young) versus 20-22 months old mice (aged) both preceding (sham) or following asciatic nerve injury (SN.
Gene Ontology (GO), KEGG pathway and STRING analysis using significantly differentially expressed (DE) genes (FDR<05) suggested a very significant enrichment in the adaptive immune response including in T and B cell signaling and increased chemotaxis of T and B cells in aged DRG, both preceding and following SNI ( F.
1A-.
This implies an increased activation of specific subtypes of lymphocytes that might be recruited to aged DRG by the induction of chemo-/cytokines including after nerve inju.
This implication further led to identify CXCL13 as by far the most prominently upregulated gene as well as its receptor CXCR5,suggesting the presence of a CXCL13/CXCR5 signaling axis (F.
1.
F.
Aging induces enrichment in genes associated with chemokine and cytokine expression and adaptive immunity in dorsal root ganglia, including after S.
(Zhou et .
, Science , 2022) In addition to observing the neuronal enrichment of CXCL13 and its significant increase in aged DRG before and 3 days after sciatic nerve where crush regeneration was reduced in the aged mice (F.
1D-I), the authors identified a robust accumulation of B and T cells including CXCR5+ B and T cells in aged D.
Interestingly, a considerable number of CD8+ and CXCR5+ CD8+ T cells were CD44+CD69+CD62L–, indicating effector memory T cells (F.
2.
F.
Characterization of B and T cells in D.
(Zhou et .
, Science, 2022) subsequently,to address whether in vivo neuronal expression of CXCL13 would attract CXCR5+ B and T cells, CXCL13 was overexpressed in DRG neurons by infecting sciatic nerves of young mice with AAV-GFP or AAV-CXCL13-G.
Strickingly, both CXCR5+ B and CD8+ T cells were significantly increased in CXCL13 overexpressing DRG compared to GFP control (F.
3A-.
Although the number of migratory CXCR5+ CD4+ T cells in DRG was significantly increased, the percentage with respect to total T cells did not change (F.
3E- .
Importantly, sciatic nerve regeneration after AAV-CXCL13 overexpression to find a significant reduction in axonal regeneration with respect to AAV-GFP injected mice (F.
3G-.
These data indicate that DRG neuronal overexpression of CXCL13 recruits CXCR5+ B and T cells and it inhibits axonal regeneration partially phenocopying the aging phenoty.
F.
Overexpression of CXCL13 in DRG neurons in young mice facilitates the recruitment of CXCR5+ B and T cells to the DRG and reduces sciatic nerve regenerati.
(Zhou et .
, Science, 2022) To explore CXCL13 expression signaling, the transcription factors (TFs) putatively involved in driving aging-dependent CXCL13 expression were analyzed in the RNAseq dataset and only Nfkb2 was significantly upregulated in aged DRG becoming a natural candidate for further investigation (F.
4.
Several cytokines stimulating NFκB signaling including TNFα, Il1β and lymphotoxin beta subunit (LTα1β2) [13] were screened in primary DRG cell culture and only LTα1β2 significantly enhanced the expression of both Nfkb2 and Cxcl13, which could be attenuated by selective inhibition of the NFκB kinase IKK by using the IKK inhibitor PS1145 (F.
4B-.
Both expression and NFκB2 phosphorylation were also induced in aged DRG in vi.
When PS1145 inhibited the phosphorylation of NFkB2, the increase of CXCL13 expression was block.
These data suggest that aging-related CXCL13 expression is driven by lymphotoxin beta-triggered NFkB2 signaling (F.
4D-.
F.
CXCL13 expression is modulated by lymphotoxin-beta induced NFkB2 signaling in D.
(Zhou et .
, Science, 2022) Are CD8, CD4 T and/or B cells required to impair axonal regeneration of aged sciatic DRG neurons? To address this question, specifically antibody-mediated cell depletion against CD8, CD4 T or B cells respectively was performed in aged mice followed by a sciatic nerve crush for 3 da.
Interestingly,CD8 monoclonal antibody promoted nerve regeneration while depletion of CD4+ T cells or B cells did not alter the aging-dependent regenerative decline following sciatic nerve injury (F.
5A-.
F.
CD8+ T cells and neuronal MHC I are required for age-dependent regenerative decline after SNI through pAKT and pS (Zhou et .
, Science, 2022) MHC-I is expressed by antigen-presenting cells (APCs) to present antigenic peptides on the cell membrane to activate CD8+ T cells after engaging with T cell receptors (TCRs) [1
Given the increased expression and membrane localization of MHC-I in aged DRG neurons (F.
5D-F), the authors hypothesized the requirement of MHC-I expression for the activation of CD8+ T cells to limit nerve regeneration after inju.
Thus, an AAV-based approach was applied to express the virally encoded peptide sequence GAr,which inhibits MHC-I antigen presentation evading CD8+ T cell immune responses [15], in sciatic DRG of aged mi.
GAr was linked to a reverse tetracycline transactivator (rtTA) responsive to tetracycline/doxycycline inducible expression with a luciferase reporter [16-18.
Following viral infection in sciatic DRG and a sciatic nerve injury for 3 days in aged mice, MHC-I and cleaved caspase 3 expression were significantly reduced and sciatic axonal regeneration was enhanced upon AAV-GAr-rtTA infection (F.
5G-J.
Together, these data suggest that CD8+ T cells and neuronal MHC-I are required for aging-dependent regenerative decline following S.
Based upon the evidence of enhanced sciatic nerve regeneration when caspase 3 was inactivated in GAr-expressed DRG neurons where MHC- I was disrupted,the authors further discovered a significant induction of cleaved caspase 3 in aged DRG neurons after nerve injury (F.
5K-.
Strikingly, the phosphorylation of two outstanding regeneration-associated regulators, AKT and S6, was decreased in aged DRG which was significantly reversed by depletion of CD8+ T cells (F.
5M-.
Together these data indicate that CD8+ T cell-dependent activation of caspase 3 is required to inhibit pAKT and pS6 in aged DRG neurons after SNI and that inhibition of caspase 3 activation promotes axonal regenerati.
F.
CXCR5+CD8+ T cells cause aging-dependent regenerative decline after S.
(Zhou et .
, Science, 2022) To determine whether CXCR5+ CD8+ T cells are directly responsible for axonal regenerative decline after sciatic nerve injury,WT or CXCR5-/- CD8+ T cells were isolated and adoptively transferred to the young and aged OT-I Rag-/- mice, which are B/T cell deficient, and mice were sacrificed 3 days after nerve inju.
The results showed a robust infiltration of adoptively transferred CXCR5+ CD8+ T cells in aged DRG, however these cells were barely detectable in the young recipients (F.
6A-.
On the contrary, transferred CXCR5+ CD8+ T cells accumulated more abundantly in the young spleen versus the old (F.
5A-.
These migratory patterns of CXCR5+ CD8+ T cells were in line with the differential CXCL13 levels in the young versus aged DRG and spleen tissues (F.
6.
Additionally,Adoptive transfer of CXCR5+ CD8+ T cells led to a significantly reduced sciatic nerve regeneration after injury only in aged mice where significantly increased perforin and decreased pS6 were observed in DRG neurons (F.
6D-.
It suggests that CXCR5+ CD8+ T cells drive aging -dependent axonal regenerative decline after sciatic nerve inju.
F.
CXCL13 neutralization enhances axonal regeneration, epidermal reinnervation, and sensory functional recovery after SNI in aged mi.
(Zhou et .
, Science, 2022)Lastly, the authors investigated whether blocking CXCL13-dependent pathway could offer a therapeutic opportunity to rejuvenate the sciatic nerve regenerative capaci.
Compared to control IgG,they observed that injection of monoclonal antibody against CXCL13 prevented the recruitment of CXCR5+ CD8+ T cells and significantly promoted sciatic nerve regeneration at acute phase after injury and chronically sensory recovery only in aged mice (F.
F.
Aging-dependent regenerative failure in injured sensory neuro.
(Zhou et .
, Science, 2022) Conclusion & Discussion, Inspiration & ExpectationIn summary, this work unveils a novel concept that aging primes DRG neurons for regenerative failure following axonal injury by a CXCL13-dependent mechanism that regulates CXCR5+ CD8+ T cells entry into the DRG (F.
Regenerative failure is a consequence of the CXCL13-dependent DRG recruitment of CXCR5+ CD8+ T cells that communicate with DRG neurons via MHC-I on the neuronal cell surface to drive regenerative inhibitory signalin.
While the nature of the aging and injury-dependent antigens remain elusive and deserves further investigation, it is intriguing to speculate that the combination of injury-dependent antigens with viral peptides accumulated and processed during the lifespan could lead to T cell-dependent neuronal MHC- I recognition and inhibition of axonal regeneration after inju.
More interestingly, an inverse relationship in the expression levels of CXCL13 between spleen and DRG tissues in young and aged mice with corresponding opposite tissue accumulation of CXCR5+ CD8+ T cel.
This might not only underpin the mechanism by which these cells accumulate in peripheral tissues, but it might also contribute to a CXCL13-dependent deterioration of immune defense in secondary lymphoid organs that is concomitant with an increase in immune-mediated neuronal dama.
Whether this underlines a general phenomenon that goes beyond the peripheral nervous system remains to be determin.
CXCL13 neutralization effectively promoted axonal regeneration and neurological recovery in aged mice while systemic delivery of anti-CXCL13 antibody might affect CXCR5+ T an B cell homing in the secondary lymph tissues, with a risk of increased susceptibility to viral infection and neoplas.
The best timing and route of antibody delivery will be considered for future targeted interventio.
Article: Zhou L, Kong G, Palmisano I, et .
, Reversible CD8 T cell- neuron cross-talk causes aging-dependent neuronal regenerative decli.
Scien.
2022 May 13;376(6594):eabd592 doi: 11126/scien.
abd592The first author-.
Luming Zhou (left); The co-first author -.
Guiping Kong (middle); The corresponding author-Pr.
Simone Di Giovanni (righ.
(Photo credit: Di Giovanni's lab) Job opportunity: Exceptionally motivated individual at the PhD or post-doctoral level are invited to apply to Di Giovanni's lab, email:.
digiovanni@imperi.
.
uk, to study the fundamental mechanisms and translational potential of cell-cell communication for repair in the nervous system across the lifesp.
Homepage of Di Giovanni's lab: https:// Talent Recruitment [1] "Logical Neuroscience" is looking for an associate editor/editor/operation position (online office) Selected articles from previous issues [1] NeuroImage︱Luo Yuejia's research group reveals the forehead control system for social information regulation risk decision-making [ 2] Nat Neurosci | Neonatal oligodendrocytes have stronger remyelination ability after demyelination [3] Biol Psychiatry︱ Tianming Gao's team revealed that astrocytes regulate adult hippocampal neurogenesis and memory through acetylcholine receptor M1 Role【4】Curr Biol︱Chen Nannan et .
Reveal the asymmetric distribution of CaMKII protein caused by the translation of synaptic region, and its role in memory formation 【5】Review of Front Aging Neurosci︱Fan Dongsheng’s team focused on the periphery and the center of amyotrophic lateral sclerosis Interaction of the immune system【6】NPP︱Wei Lu’s team revealed a new mechanism of GABAA receptor auxiliary subunit phosphorylation to regulate neural behavior 【7】Cereb Cortex︱Pattern rigidity, temporal dynamics of ventromedial prefrontal cortex affect rumination and rumination The role of depression 【8】Front Aging Neurosci︱PTAFR as a novel biomarker to help the diagnosis and treatment of Alzheimer’s disease 【9】PNAS︱Feng Guoping’s lab reveals the important role of front thalamic circuits in working memory 【10 ]Mol Psychiatry︱ Keqiang Ye's research group revealed that inflammation-activated C/EBPβ/AEP signaling pathway mediates high-fat diet-induced diabetes and Alzheimer's disease high-quality scientific research training course recommendation [1] Academic paper writing practical training course (Live: 202
21~22) [2] Symposium on Single-Cell Sequencing and Spatial Transcriptomic Data Analysis (Tencent Online Meeting on June 11-12) [3] Seminar on Patch Clamp and Optogenetics and Calcium Imaging Technology May 21- References of Tencent Conference on the 22nd (swipe up and down to read) Verdú,.
, et .
, Influence of aging on peripheral nerve function and regenerati.
Journal of the Peripheral Nervous System, 200 5(4):.
191- 20 Vaughan, DW,Effects of advancing age on peripheral nerve regenerati.
Journal of Comparative Neurology, 199 323(2):.
219-23 Pestronk,.
, DB Drachman, and JW Griffin, Effects of aging on nerve sprouting and regenerati.
Experimental neurology , 198 70(1):.
65-8 DeVivo, MJ and.
Chen, Trends in new injuries, prevalent cases, and aging with spinal cord inju.
Archives of physical medicine and rehabilitation, 201 92(3) :.
332-33 Painter, MW, et .
, Diminished Schwann cell repair responses underlie age-associated impaired axonal regenerati.
Neuron, 201 83(2):.
331-34 Kang,.
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