Deep imaging of LepR+ stromal cells in optically cleared murine bone hemisections

Yuehan Ni , Jiamiao Wu , Fengqi Liu , Yating Yi , Xiangjiao Meng , Xiang Gao , Luyi Xiao , Weiwei Zhou , Zexi Chen , Peng Chu , Dan Xing , Ye Yuan , Donghui Ding , Ge Shen , Min Yang , Ronjie Wu , Ling Wang , Luiza Martins Nascentes Melo , Sien Lin , Xiaoguang Cheng , Gang Li , Alpaslan Tasdogan , Jessalyn M. Ubellacker , Hu Zhao , Shentong Fang , Bo Shen

Bone Research ›› 2025, Vol. 13 ›› Issue (1) : 6

PDF
Bone Research ›› 2025, Vol. 13 ›› Issue (1) : 6 DOI: 10.1038/s41413-024-00387-9
Article

Deep imaging of LepR+ stromal cells in optically cleared murine bone hemisections

Author information +
History +
PDF

Abstract

Tissue clearing combined with high-resolution confocal imaging is a cutting-edge approach for dissecting the three-dimensional (3D) architecture of tissues and deciphering cellular spatial interactions under physiological and pathological conditions. Deciphering the spatial interaction of leptin receptor-expressing (LepR+) stromal cells with other compartments in the bone marrow is crucial for a deeper understanding of the stem cell niche and the skeletal tissue. In this study, we introduce an optimized protocol for the 3D analysis of skeletal tissues, enabling the visualization of hematopoietic and stromal cells, especially LepR+ stromal cells, within optically cleared bone hemisections. Our method preserves the 3D tissue architecture and is extendable to other hematopoietic sites such as calvaria and vertebrae. The protocol entails tissue fixation, decalcification, and cryosectioning to reveal the marrow cavity. Completed within approximately 12 days, this process yields highly transparent tissues that maintain genetically encoded or antibody-stained fluorescent signals. The bone hemisections are compatible with diverse antibody labeling strategies. Confocal microscopy of these transparent samples allows for qualitative and quantitative image analysis using Aivia or Bitplane Imaris software, assessing a spectrum of parameters. With proper storage, the fluorescent signal in the stained and cleared bone hemisections remains intact for at least 2–3 months. This protocol is robust, straightforward to implement, and highly reproducible, offering a valuable tool for tissue architecture and cellular interaction studies.

Cite this article

Download citation ▾
Yuehan Ni, Jiamiao Wu, Fengqi Liu, Yating Yi, Xiangjiao Meng, Xiang Gao, Luyi Xiao, Weiwei Zhou, Zexi Chen, Peng Chu, Dan Xing, Ye Yuan, Donghui Ding, Ge Shen, Min Yang, Ronjie Wu, Ling Wang, Luiza Martins Nascentes Melo, Sien Lin, Xiaoguang Cheng, Gang Li, Alpaslan Tasdogan, Jessalyn M. Ubellacker, Hu Zhao, Shentong Fang, Bo Shen. Deep imaging of LepR+ stromal cells in optically cleared murine bone hemisections. Bone Research, 2025, 13(1): 6 DOI:10.1038/s41413-024-00387-9

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Ding L, Saunders TL, Enikolopov G, Morrison SJ. Endothelial and perivascular cells maintain haematopoietic stem cells Nature, 2012, 481: 457-462.

[2]

Himburg HA, et al.. Distinct bone marrow sources of pleiotrophin control hematopoietic stem cell maintenance and regeneration Cell Stem cell, 2018, 23: 370-381.e375.

[3]

Ding L, Morrison SJ. Haematopoietic stem cells and early lymphoid progenitors occupy distinct bone marrow niches Nature, 2013, 495: 231-235.

[4]

Shen B, et al.. A mechanosensitive peri-arteriolar niche for osteogenesis and lymphopoiesis Nature, 2021, 591: 438-444.

[5]

Emoto T, et al.. Colony stimulating factor-1 producing endothelial cells and mesenchymal stromal cells maintain monocytes within a perivascular bone marrow niche Immunity, 2022, 55: 862-878 e868.

[6]

Zhong L, et al.. Csf1 from marrow adipogenic precursors is required for osteoclast formation and hematopoiesis in bone eLife, 2023, 12: e82112.

[7]

Greenbaum A, et al.. CXCL12 in early mesenchymal progenitors is required for haematopoietic stem-cell maintenance Nature, 2013, 495: 227-230.

[8]

Wu L, et al.. LepR+ niche cell-derived AREG compromises hematopoietic stem cell maintenance under conditions of DNA repair deficiency and aging Blood, 2023, 142: 1529-1542.

[9]

Gao X, et al.. Leptin receptor(+) cells promote bone marrow innervation and regeneration by synthesizing nerve growth factor Nat. Cell Biol., 2023, 25: 1746-1757.

[10]

Meacham CE, et al.. Adiponectin receptors sustain haematopoietic stem cells throughout adulthood by protecting them from inflammation Nat. Cell Biol., 2022, 24: 697-707.

[11]

Zhou BO, Yue R, Murphy MM, Peyer JG, Morrison SJ. Leptin-receptor-expressing mesenchymal stromal cells represent the main source of bone formed by adult bone marrow Cell Stem Cell, 2014, 15: 154-168.

[12]

Shu HS, et al.. Tracing the skeletal progenitor transition during postnatal bone formation Cell Stem Cell, 2021, 28: 2122-2136.e2123.

[13]

Jeffery EC, Mann TLA, Pool JA, Zhao Z, Morrison SJ. Bone marrow and periosteal skeletal stem/progenitor cells make distinct contributions to bone maintenance and repair Cell Stem Cell, 2022, 29: 1547-1561.e1546.

[14]

Baccin C, et al.. Combined single-cell and spatial transcriptomics reveal the molecular, cellular and spatial bone marrow niche organization Nat. Cell Biol., 2020, 22: 38-48.

[15]

Baryawno N, et al.. A cellular taxonomy of the bone marrow stroma in homeostasis and leukemia Cell, 2019, 177: 1915-1932.e1916.

[16]

Fang S, et al.. VEGF-C protects the integrity of the bone marrow perivascular niche in mice Blood, 2020, 136: 1871-1883.

[17]

Tikhonova AN, et al.. The bone marrow microenvironment at single-cell resolution Nature, 2019, 569: 222-228.

[18]

Wolock SL, et al.. Mapping distinct bone marrow niche populations and their differentiation paths Cell Rep., 2019, 28: 302-311.e305.

[19]

Matsushita Y, et al.. A Wnt-mediated transformation of the bone marrow stromal cell identity orchestrates skeletal regeneration Nat. Commun., 2020, 11. 332
[20]

Zhong L, et al.. Single cell transcriptomics identifies a unique adipose lineage cell population that regulates bone marrow environment eLife, 2020, 9: e54695.

[21]

Zhou BO, et al.. Bone marrow adipocytes promote the regeneration of stem cells and haematopoiesis by secreting SCF Nat. Cell Biol., 2017, 19: 891-903.

[22]

Shi Y, et al.. Gli1 identifies osteogenic progenitors for bone formation and fracture repair Nat. Commun., 2017, 8. 2043
[23]

Mo C, et al.. Single-cell transcriptomics of LepR-positive skeletal cells reveals heterogeneous stress-dependent stem and progenitor pools EMBO J., 2022, 41. e108415
[24]

Bandyopadhyay S, et al.. Mapping the cellular biogeography of human bone marrow niches using single-cell transcriptomics and proteomic imaging Cell, 2024, 187: 3120-3140.e3129.

[25]

Comazzetto S, Shen B, Morrison SJ. Niches that regulate stem cells and hematopoiesis in adult bone marrow Dev. Cell, 2021, 56: 1848-1860.

[26]

Morrison SJ, Scadden DT. The bone marrow niche for haematopoietic stem cells Nature, 2014, 505: 327-334.

[27]

Zhang J, et al.. In situ mapping identifies distinct vascular niches for myelopoiesis Nature, 2021, 590: 457-462.

[28]

Wu Q, et al.. Resilient anatomy and local plasticity of naive and stress haematopoiesis Nature, 2024, 627: 839-846.

[29]

Acar M, et al.. Deep imaging of bone marrow shows non-dividing stem cells are mainly perisinusoidal Nature, 2015, 526: 126-130.

[30]

Yue R, Shen B, Morrison SJ. Clec11a/osteolectin is an osteogenic growth factor that promotes the maintenance of the adult skeleton eLife, 2016, 5: e18782.

[31]

Shen B, et al.. Integrin alpha11 is an Osteolectin receptor and is required for the maintenance of adult skeletal bone mass eLife, 2019, 8. e42274
[32]

Zhang J, et al.. The effect of parathyroid hormone on osteogenesis is mediated partly by osteolectin Proc. Natl. Acad. Sci. USA, 2021, 118: e2026176118.

[33]

Zhang J, et al.. Bone marrow dendritic cells regulate hematopoietic stem/progenitor cell trafficking J. Clin. Invest, 2019, 129: 2920-2931.

[34]

Zhao YC, et al.. A novel computational biomechanics framework to model vascular mechanopropagation in deep bone marrow Adv. Health. Mater., 2023, 12. e2201830
[35]

Chen JY, et al.. Hoxb5 marks long-term haematopoietic stem cells and reveals a homogenous perivascular niche Nature, 2016, 530: 223-227.

[36]

Kokkaliaris KD, et al.. Adult blood stem cell localization reflects the abundance of reported bone marrow niche cell types and their combinations Blood, 2020, 136: 2296-2307.

[37]

Christodoulou C, et al.. Live-animal imaging of native haematopoietic stem and progenitor cells Nature, 2020, 578: 278-283.

[38]

Jacob L, et al.. Anatomy and function of the vertebral column lymphatic network in mice Nat. Commun., 2019, 10. 4594
[39]

Kiel MJ, et al.. SLAM family receptors distinguish hematopoietic stem and progenitor cells and reveal endothelial niches for stem cells Cell, 2005, 121: 1109-1121.

[40]

Zhu J, et al.. Osteoblasts support B-lymphocyte commitment and differentiation from hematopoietic stem cells Blood, 2007, 109: 3706-3712.

[41]

Wu JY, et al.. Osteoblastic regulation of B lymphopoiesis is mediated by Gsalpha-dependent signaling pathways Proc. Natl. Acad. Sci. USA, 2008, 105: 16976-16981.

[42]

Katayama Y, et al.. Signals from the sympathetic nervous system regulate hematopoietic stem cell egress from bone marrow Cell, 2006, 124: 407-421.

[43]

Zhang S, et al.. Bone marrow adipocytes fuel emergency hematopoiesis after myocardial infarction Nat. Cardiovasc Res., 2023, 2: 1277-1290.

[44]

Maryanovich M, et al.. Adrenergic nerve degeneration in bone marrow drives aging of the hematopoietic stem cell niche Nat. Med, 2018, 24: 782-791.

[45]

Fielding C, et al.. Cholinergic signals preserve haematopoietic stem cell quiescence during regenerative haematopoiesis Nat. Commun., 2022, 13. 543
[46]

Gadomski S, et al.. A cholinergic neuroskeletal interface promotes bone formation during postnatal growth and exercise Cell Stem Cell, 2022, 29: 528-544.

[47]

Gao X, et al.. Nociceptive nerves regulate haematopoietic stem cell mobilization Nature, 2020, 589: 591-596.

[48]

Sarkaria SM, et al.. Systematic dissection of coordinated stromal remodeling identifies Sox10(+) glial cells as a therapeutic target in myelofibrosis Cell Stem Cell, 2023, 30: 832-850.e836.

[49]

Yamazaki S, et al.. Nonmyelinating Schwann cells maintain hematopoietic stem cell hibernation in the bone marrow niche Cell, 2011, 147: 1146-1158.

[50]

Lucas D, et al.. Chemotherapy-induced bone marrow nerve injury impairs hematopoietic regeneration Nat. Med., 2013, 19: 695-703.

[51]

Fukuda T, et al.. Sema3A regulates bone-mass accrual through sensory innervations Nature, 2013, 497: 490-493.

[52]

Mahmoud AI, et al.. Nerves regulate cardiomyocyte proliferation and heart regeneration Dev. Cell, 2015, 34: 387-399.

[53]

Ambrosi TH, et al.. Aged skeletal stem cells generate an inflammatory degenerative niche Nature, 2021, 597: 256-262.

[54]

Young KA, et al.. Variation in mesenchymal KITL/SCF and IGF1 expression in middle age underlies steady-state hematopoietic stem cell aging Blood, 2024, 144: 378-391.

[55]

Mitchell CA, et al.. Stromal niche inflammation mediated by IL-1 signalling is a targetable driver of haematopoietic ageing Nat. Cell Biol., 2023, 25: 30-41.

[56]

Allocca G, Kusumbe AP, Ramasamy SK, Wang N. Confocal/two-photon microscopy in studying colonisation of cancer cells in bone using xenograft mouse models Bonekey Rep., 2016, 5: 851.

[57]

Chen J, et al.. High-resolution 3D imaging uncovers organ-specific vascular control of tissue aging Sci. Adv., 2021, 7: eabd7819.

[58]

Kusumbe AP, Ramasamy SK, Adams RH. Coupling of angiogenesis and osteogenesis by a specific vessel subtype in bone Nature, 2014, 507: 323-328.

[59]

Kusumbe AP, et al.. Age-dependent modulation of vascular niches for haematopoietic stem cells Nature, 2016, 532: 380-384.

[60]

Ramasamy SK, Kusumbe AP, Wang L, Adams RH. Endothelial Notch activity promotes angiogenesis and osteogenesis in bone Nature, 2014, 507: 376-380.

[61]

Gruneboom A, et al.. A network of trans-cortical capillaries as mainstay for blood circulation in long bones Nat. Metab., 2019, 1: 236-250.

[62]

He J, et al.. Dissecting human embryonic skeletal stem cell ontogeny by single-cell transcriptomic and functional analyses Cell Res, 2021, 31: 742-757.

[63]

Chan CKF, et al.. Identification of the human skeletal stem cell Cell, 2018, 175: 43-56.e21.

[64]

DeFalco J, et al.. Virus-assisted mapping of neural inputs to a feeding center in the hypothalamus Science, 2001, 291: 2608-2613.

[65]

Merz SF, et al.. Contemporaneous 3D characterization of acute and chronic myocardial I/R injury and response Nat. Commun., 2019, 10. 2312
[66]

Renier N, et al.. iDISCO: a simple, rapid method to immunolabel large tissue samples for volume imaging Cell, 2014, 159: 896-910.

[67]

Richardson DS, Lichtman JW. Clarifying tissue clearing Cell, 2015, 162: 246-257.

[68]

Tomer R, Ye L, Hsueh B, Deisseroth K. Advanced CLARITY for rapid and high-resolution imaging of intact tissues Nat. Protoc., 2014, 9: 1682-1697.

[69]

Yang B, et al.. Single-cell phenotyping within transparent intact tissue through whole-body clearing Cell, 2014, 158: 945-958.

[70]

Yao Y, Taub AB, LeSauter J, Silver R. Identification of the suprachiasmatic nucleus venous portal system in the mammalian brain Nat. Commun., 2021, 12. 5643
[71]

Inra CN, et al.. A perisinusoidal niche for extramedullary haematopoiesis in the spleen Nature, 2015, 527: 466-471.

[72]

Poulos MG, et al.. Complementary and inducible creER(T2) mouse models for functional evaluation of endothelial cell subtypes in the bone marrow Stem Cell Rev. Rep., 2024, 20: 1135-1149.

[73]

Spalteholz, W. Uber das durchsichtigmachen von menschlichen und tierischen praparaten [About the transparency of human and animal preparations]. (1914).
[74]

Pan C, et al.. Shrinkage-mediated imaging of entire organs and organisms using uDISCO Nat. Methods, 2016, 13: 859-867.

[75]

Greenbaum A, et al.. Bone CLARITY: clearing, imaging, and computational analysis of osteoprogenitors within intact bone marrow Sci. Transl. Med, 2017, 9: eaah6518.

[76]

Dodt HU, et al.. Ultramicroscopy: three-dimensional visualization of neuronal networks in the whole mouse brain Nat. Methods, 2007, 4: 331-336.

[77]

Jing D, et al.. Tissue clearing of both hard and soft tissue organs with the PEGASOS method Cell Res., 2018, 28: 803-818.

[78]

Li Y, Xu J, Wan P, Yu T, Zhu D. Optimization of GFP fluorescence preservation by a modified uDISCO clearing protocol Front Neuroanat., 2018, 12: 67.

[79]

Yi Y, et al.. 3-dimensional visualization of implant-tissue interface with the polyethylene glycol associated solvent system tissue clearing method Cell Prolif., 2019, 52. e12578
[80]

Yi Y, et al.. Mapping of individual sensory nerve axons from digits to spinal cord with the transparent embedding solvent system Cell Res, 2024, 34: 124-139.

[81]

Wang Q, Liu K, Yang L, Wang H, Yang J. BoneClear: whole-tissue immunolabeling of the intact mouse bones for 3D imaging of neural anatomy and pathology Cell Res, 2019, 29: 870-872.

[82]

Dazzi M, Rowland EM, Mohri Z, Weinberg PD. 3D confocal microscope imaging of macromolecule uptake in the intact brachiocephalic artery Atherosclerosis, 2020, 310: 93-101.

[83]

Madisen L, et al.. A robust and high-throughput Cre reporting and characterization system for the whole mouse brain Nat. Neurosci., 2010, 13: 133-140.

[84]

Daigle TL, et al.. A suite of transgenic driver and reporter mouse lines with enhanced brain-cell-type targeting and functionality Cell, 2018, 174: 465-480.e422.

[85]

Kalajzic Z, et al.. Directing the expression of a green fluorescent protein transgene in differentiated osteoblasts: Comparison between rat type I collagen and rat osteocalcin promoters Bone, 2002, 31: 654-660.

[86]

Subach OM, Cranfill PJ, Davidson MW, Verkhusha VV. An enhanced monomeric blue fluorescent protein with the high chemical stability of the chromophore PloS one, 2011, 6: e28674.

[87]

Mansfield JR, Gossage KW, Hoyt CC, Levenson RM. Autofluorescence removal, multiplexing, and automated analysis methods for in-vivo fluorescence imaging J. Biomed. Opt., 2005, 10: 41207.

[88]

Foster DS, et al.. A clearing technique to enhance endogenous fluorophores in skin and soft tissue Sci. Rep., 2019, 9. 15791
[89]

Klingberg A, et al.. Fully automated evaluation of total glomerular number and capillary tuft size in nephritic kidneys using lightsheet microscopy J. Am. Soc. Nephrol., 2017, 28: 452-459.

[90]

Masselink W, et al.. Broad applicability of a streamlined ethyl cinnamate-based clearing procedure Development, 2019, 146: dev.166884.

[91]

Si Y, et al.. Multidimensional imaging provides evidence for down-regulation of T cell effector function by MDSC in human cancer tissue Sci. Immunol., 2019, 4: eaaw9159.

Funding

National Natural Science Foundation of China (National Science Foundation of China)(82272563)

National Science Foundation of China | National Natural Science Foundation of China-Yunnan Joint Fund (NSFC-Yunnan Joint Fund)(82203653)

RIGHTS & PERMISSIONS

The Author(s)

AI Summary AI Mindmap
PDF

252

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/