猴表皮干细胞横向分化为角膜上皮细胞的研究

表皮干细胞可以作为角膜上皮细胞的替代物, 在自体眼表修复及组织工程生物角膜的构建中将产生不可估量的作用. 将体外分离培养的2 ~ 4代猴表皮干细胞和人角膜缘基质组织及角膜上皮细胞进行共培养(Transwell法), 于共培养前后使用流式细胞仪、RT-PCR和免疫组织 化学技术对其分化情况进行检测和鉴定. 并于第2, 4, 6, 8和10天进行免疫组织化学染色观察表皮干细胞转分化的比率. 实验采用条件培养基诱导法作为对照. 表皮干细胞在共培养前表达表皮干细胞标志, K15和整合素β1阳性, K3/K12阴性; 共培养后转为表达K3/K12, 从基因水平和蛋白质水平表现出角膜上皮细胞的特征, 但是条件培养基诱导法阳性率较低. 可见, 表皮干细胞具有可塑性, 在角膜缘基质组织及角膜上皮细胞的调控下, 可以横向分化为类角膜上皮细胞, 有可能重建角膜上皮, 进行自体生物角膜的构建.     

诱导胚胎干细胞向角膜上皮细胞分化的实验研究

探索胚胎干细胞在表层角膜缘基质诱导下向角膜上皮细胞分化的可能性. 体外培养带GFP标记的 ES-D3细胞, 并利用视黄酸进行预诱导, 然后将预诱导后的细胞接种在表层角膜缘基质上, 细胞融合形成单层后, 随机分为3组进行研究: 第1组传代后直接进行检测; 第2组在 气-液界面上培养10天, 然后植入裸鼠皮下以进行体内诱导; 第3组作为对照组, 不给予GFP-ES-D3细胞特殊诱导条件, 细胞自由分化. 诱导分化的细胞植入裸鼠皮下体2周后没有畸胎瘤形成. 诱导分化的细胞呈现上皮样外观, 体内诱导组和体外诱导组免疫组织化学染色均检测到CK3, P63和PCNA表达阳性, 电子显微镜检查可见两组细胞表面都有微绒毛和细胞间紧密连接形成. 实验对照组部分细胞脱落和死亡, 大部分表现神经样细胞的树突样外观, 小部分未死亡的贴壁细胞呈多态性, 这些结果表明胚胎干细胞在特定条件下经表层角膜基质诱导能够分化为角膜上皮细胞. 胚胎干细胞诱导分化有可能为眼表重建和组织工程化角膜的构建提供上皮种子细胞.     

诱导胚胎干细胞向角膜上皮细胞分化的实验研究

探索胚胎干细胞在表层角膜缘基质诱导下向角膜上皮细胞分化的可能性.体外培养带GFP标记的ES-D3细胞,并利用视黄酸进行预诱导,然后将预诱导后的细胞接种在表层角膜缘基质上,细胞融合形成单层后,随机分为3组进行研究:第1组传代后直接进行检测;第2组在气-液界面上培养10天,然后植入裸鼠皮下以进行体内诱导;第3组作为对照组,不给予GFP-ES-D3细胞特殊诱导条件,细胞自由分化.诱导分化的细胞植入裸鼠皮下体2周后没有畸胎瘤形成.诱导分化的细胞呈现上皮样外观,体内诱导组和体外诱导组免疫组织化学染色均检测到CK3,P63和PCNA表达阳性,电子显微镜检查可见两组细胞表面都有微绒毛和细胞间紧密连接形成.实验对照组部分细胞脱落和死亡,大部分表现神经样细胞的树突样外观,小部分未死亡的贴壁细胞呈多态性,这些结果表明胚胎干细胞在特定条件下经表层角膜基质诱导能够分化为角膜上皮细胞.胚胎干细胞诱导分化有可能为眼表重建和组织工程化角膜的构建提供上皮种子细胞.     

兔角膜缘干细胞体外分离、培养和生物学鉴定的实验研究

通过体外培养兔角膜缘干细胞,观察其生物学特性,建立兔角膜缘干细胞的体外培养方法。方法0．25%胰蛋白酶消化角膜缘组织,用含15%胎牛血清的DMEM和F12(1:1)的培养液(DF)对兔角膜缘干细胞进行体外培养,形态学观察,培养的细胞早期使用AEl/AE3、晚期使用AE5角蛋白特异的单克隆抗体)作细胞免疫化学鉴定。结果:原代培养细胞48h后开始贴壁,部分细胞由圆形变为卵圆形或长梭形;10～14d形成单层,细胞呈圆形、卵圆形,类角膜上皮细胞;细胞传到第5代左右开始出现老化状态;免疫细胞化学染色:培养的细胞早期AEl/AE3呈阳性而少部分细胞AE5呈阳性,培养的细胞晚期AE5呈阳性。结论:本实验初步建立了一套兔角膜缘干细胞的体外培养方法。     

兔角膜缘干细胞的研究进展

目前,角膜移植是临床上治疗角膜疾患的最有效途径,但供体角膜非常有限。新近兴起的干细胞技术,为组织工程角膜的研制和应用提供了契机。对于以角膜缘干细胞缺乏或功能障碍为特征的疾病也有治疗效果。采取角膜缘干细胞移植应是一种合理有效的治疗手段。本文主要介绍了兔角膜缘干细胞的体外分离、培养、鉴定及一些生长因子对其增殖的影响。     

小鼠角膜上皮祖细胞系TKE2的表型研究

目的：观察小鼠角膜上皮祖细胞系TKE2在扩增以及分化状态下的角蛋白及干细胞标志物的表达情况。方法小鼠角膜上皮祖细胞系TKE2在无血清培养基Keratinocyte-SFM （KSFM）以及含10﹪胎牛血清（FBS）的DMEM培养基中培养,约70﹪融合时进行角蛋白10、12、14、15、16（K10、K12、K14、K15、K16）以及Connexin43、ABCG2的免疫荧光染色,以及Ki67、P63、PCNA的免疫细胞化学染色。结果无血清培养状态下的TKE2细胞呈克隆样生长,克隆内所有细胞呈ABCG2、K14、Ki67、PCNA以及P63阳性,K15阳性细胞散在分布,K16阳性细胞呈片状分布于克隆中央区,K10、K12以及Connexin43染色为阴性。在含有10﹪胎牛血清的DMEM中培养2 d后,细胞明显增大, ABCG2、K15、P63、Ki67以及PCNA转为阴性,克隆内只有少量细胞呈K16、K14阳性染色, K10、K12、Connexin43仍为阴性。结论 TKE2细胞具有角膜上皮干细胞特性,可以作为角膜缘上皮干细胞表型维持和分化诱导研究的良好工具。     

翼状胬肉切除联合自体角膜缘干细胞移植术治疗翼状胬肉的临床疗效分析

目的:研究翼状胬肉切除术联合自体角膜缘干细胞移植治疗翼状胬肉的临床效果。方法:将2010年3月-2015年3月本院收治的105例翼状胬肉患者随机分为观察组和对照组。观察组患者53例,行翼状胬肉切除术联合自体角膜缘干细胞移植;对照组患者50例,行单纯翼状胬肉切除术。比较两组患者手术一般资料、手术前后视力水平、散光程度以及术后3个月和6个月的复发率。结果:术后,观察组角膜上皮修复时间、不适症状持续时间、住院时间均短于对照组;术后视力恢复情况、散光改善程度优于对照组;术后3个月和6个月治愈率显著高于对照组;而观察组术后并发率低于对照组,差异均有统计学意义(P0.05)。结论:翼状胬肉切除术联合自体角膜缘干细胞移植疗效显著、术后复发率低。     

《自然》：标记、修复及培养角膜缘干细胞或有新方法

英国《自然》杂志上，美国科学家发表的最新研究指明了一种生物标记物。其能够用来分离进而修复受损眼睛的干细胞。这些干细胞位于角膜和眼白交界处的角膜缘上。与此同时，另一篇发表在《自然》杂志上的论文。描述了一种培养角膜缘干细胞的方法。这些研究结果都将有助于改善角膜疾病的治疗。     

表皮生长因子受体在正常大鼠眼组织中的表达

采用免疫组织化学方法观察了表皮生长因子受体在正常大鼠眼组织的表达。结果发现：角膜上皮的深层细胞和角膜缘上皮细胞、部分结膜上皮细胞和结膜下结缔组织内成纤维细胞均强烈表达表皮生长因子受体。结果显示：表皮生长因子受体阳性细胞主要分布于眼表层组织。这些细胞不仅是眼组织损伤后修复、而且是多种手术能否成功和某些疾病形成中起重要作用的细胞     

骨髓间充质干细胞向角膜上皮细胞分化及其免疫调节作用

目的：探讨大鼠骨髓间充质干细胞（rBMMSCs）转分化为角膜上皮的潜能,并在体外共培养体系中研究rBMMSCs对促炎细胞因子干扰素-γ（IFN-γ）和肿瘤坏死因子-α（TNF-α）刺激下的人角膜上皮细胞（hCECs）的免疫调节作用。方法采用聚蔗糖梯密度离心法获得rBMMSCs,并通过上皮细胞培养微环境来诱导rBMMSCs分化为上皮样细胞。通过免疫组织化学方法鉴定CD29、CD34、CK5＆8和ZO-1等标记物在rBMMSCs及诱导的上皮样细胞中的表达。流式细胞术用来分析CD29/CD34的表达及细胞分化过程中表达量的变化。hCECs单独培养或与rBMMSCs共培养,并采用IFN-γ/TNF-α刺激24或48 h。通过流式细胞术来分析细胞间黏附分子-1（ICAM-1）于IFN-γ/TNF-α刺激前后在hCECs上的表达,并通过黏附分析实验验证rBMMSC条件培养基对单核细胞黏附于IFN-γ/TNF-α刺激后的hCECs的作用。多组间比较采用单因素方差分析（ANOVA）,两组间比较采用双侧t检验。结果成功分离rBMMSCs,细胞表达CD29,但不表达CD34。在上皮细胞培养条件中培养5 d,大约4﹪的rBMMSCs可分化为上皮样细胞。此类细胞失去了CD29的标志,转为表达CK5＆8和ZO-1。IFN-γ/TNF-α能显著上调hCECs中ICAM-1的表达,在IFN-γ/TNF-α处理24 h和48 h后,ICAM-1分别呈现10倍和8倍的升高,分别达到4524±554.2和3107±329.6（P=0.0025,0.0014）。但与MSC共同培养时,上调作用被显著抑制,ICAM-1平均值为1356±325.6（24 h）与1323±106.6（48 h）（P=0.0079,0.0024）。MSC条件培养基可显著抑制单核细胞对hCECs的黏附作用,黏附细胞数从（10.01±3.01）×10^3/ml细胞降至（2.21±0.19）×10^3/ml细胞（P=0.0271）。结论rBMMSCs可转分化为角膜上皮样细胞,并抑制由促炎细胞因子诱导的ICAM-1在hCECs上的表达,同时对促炎细胞因子诱导的单核细胞的黏附性具有抑制作用,提示BMMSCs具有在角膜炎症疾病和损伤修复中的治疗潜能。     

Therapeutic use of limbal stem cells

Stem cells are defined as relatively undifferentiated cells that have the capacity to generate more differentiated daughter cells. Limbal stem cells are responsible for epithelial tissue repair and regeneration throughout the life. Limbal stem cells have been localized to the Palisades of Vogt in the limbal region. Limbal stem cells have a higher proliferative potential compared to the cells of peripheral and central cornea. Limbal stem cells have the capacity to maintain normal corneal homeostasis. However, in some pathological states, such as chemical and thermal burns, Stevens-Johnson syndrome, and ocular pemphigoid limbal stem cells fail to maintain the corneal epithelial integrity. In such situations, limbal stem cell transplantation has been required as a therapeutic option. In unilateral disorders, the usual source of stem cells is the contralateral eyes, but if the disease is bilateral stem cell allografts have to be dissected from family members or cadaver eyes. The advent of ex vivo expansion of limbal stem cells from a small biopsy specimen has reduced the risk of limbal deficiency in the donor eye. Concomitant immunosuppressive therapy promotes donor-derived epithelial cell viability, but some evidences suggest that donor-derived epithelial stem cell viability is not sustained indefinitely. Thus, long-term follow-up studies are required to ascertain whether donor limbal stem cell survival or promotion of recolonization by resident recipient stem cells occurs in restored recipient epithelium. However, this is not an easy task since a definitive limbal stem cell marker has not been identified yet. This review will discuss the therapeutic usage of limbal stem cells in the corneal epithelial disorders.     

Maintenance and Distribution of Epithelial Stem/Progenitor Cells after Corneal Reconstruction Using Oral Mucosal Epithelial Cell Sheets

We assessed the maintenance and distribution of epithelial stem/progenitor cells after corneal reconstruction using tissue-engineered oral mucosal cell sheets in a rat model. Oral mucosal biopsy specimens were excised from green fluorescent protein (GFP) rats and enzymatically treated with Dispase II. These cells were cultured on inserts with mitomycin C-treated NIH/3T3 cells, and the resulting cell sheets were harvested. These tissue-engineered cell sheets from GFP rats were transplanted onto the eyes of a nude rat limbal stem cell deficiency model. Eight weeks after surgery, ocular surfaces were completely covered by the epithelium with GFP-positive cells. Transplanted corneas expressed p63 in the basal layers and K14 in all epithelial layers. Epithelial cells harvested from the central and peripheral areas of reconstructed corneas were isolated for a colony-forming assay, which showed that the colony-forming efficiency of the peripheral epithelial cells was significantly higher than that of the central epithelial cells 8 weeks after corneal reconstruction. Thus, in this rat model, the peripheral cornea could maintain more stem/progenitor cells than the central cornea after corneal reconstruction using oral mucosal epithelial cell sheets.     

Reconstruction of corneal epithelium with cryopreserved corneal limbal stem cells in a goat model

We describe a procedure to construct an artificial corneal epithelium from cryopreserved limbal stem cells (LSCs) for corneal transplantation. The LSCs were separated from limbal tissue of male goats. The primary LSCs were identified by flow cytometry and were expanded. They were examined for stem cell-relevant properties and cryopreserved in liquid nitrogen. Cryopreserved LSCs were thawed and then transplanted onto human amniotic membrane, framed on a nitrocellulose sheet, to construct corneal epithelium sheets. The artificial corneal epithelium was transplanted into the right eye of pathological models of total limbal stem cell deficiency (LSCD). Then, the effects of reconstruction were evaluated by clinical observation and histological examination. Polymerase chain reaction analysis was used to detect the SRY gene. The data showed that transplantation of cryopreserved LSCs, like fresh LSCs, successfully reconstructed damaged goat corneal surface gradually, but the SRY gene expression from male goat cells could only be detected in the first 2 months after transplantation. The therapeutic effect of the transplantation may be associated with the inhibition of inflammation-related angiogenesis after transplantation of cryopreserved LSCs. This study provides the first line of evidence that cryopreserved LSCs can be used for reconstruction of damaged corneas, presenting a remarkable potential source for transplantation in the treatment of corneal disorders.     

Single-cell RNA sequencing in cornea research: Insights into limbal stem cells and their niche regulation

The corneal epithelium is composed of stratified squamous epithelial cells on the outer surface of the eye, which acts as a protective barrier and is critical for clear and stable vision. Its continuous renewal or wound healing depends on the proliferation and differentiation of limbal stem cells (LSCs), a cell population that resides at the limbus in a highly regulated niche. Dysfunction of LSCs or their niche can cause limbal stem cell deficiency, a disease that is manifested by failed epithelial wound healing or even blindness. Nevertheless, compared to stem cells in other tissues, little is known about the LSCs and their niche. With the advent of single-cell RNA sequencing, our understanding of LSC characteristics and their microenvironment has grown considerably. In this review, we summarized the current findings from single-cell studies in the field of cornea research and focused on important advancements driven by this technology, including the heterogeneity of the LSC population, novel LSC markers and regulation of the LSC niche, which will provide a reference for clinical issues such as corneal epithelial wound healing, ocular surface reconstruction and interventions for related diseases.     

Culture of limbal stem cells on human amniotic membrane

Limbal stem cells (LSC) have an important role in the maintenance of the corneal surface epithelium, and autologous cultured limbal epithelial cell (HLECs) transplantations have contributed substantially to the treatment of the visually disabling condition known as LSC deficiency. A major challenge is the ability to identify LSC in vitro and in situ, and one of the major controversies in the field relates to reliable LSC markers. This study was carried out to evaluate the culture of a limbal biopsy on human amniotic membrane (HAM): directly on the chorionic side and on intact epithelium, and the expression of the stem cell associated markers: ABCG2, p63. HAM has been extensively used for ocular surface reconstruction and has properties which facilitate the growth of epithelial cells controlling inflammation and scarring.     

Stratified epithelial sheets engineered from a single adult murine corneal/limbal progenitor cell

The limbal region of the adult cornea contains stem cells which are ultimately responsible for regeneration of the corneal epithelium during wound repair. However, primarily-isolated murine corneal/limbal epithelial cells rapidly senesce on plastic in a serum-free low [Ca(2+)] medium, suggesting only transit amplifying cells are promoted. We developed a novel expansion method by seeding at a low cell density (<500 cells/cm(2)) and prolonging each culture time beyond the lifespan of transit amplifying cells (4 weeks). Expanded cells were uniformly small, negative to K12 keratin, but positive for p63 nuclear staining, and could be subcultured beyond 100 passages. After limiting dilution, one clone (TKE2) was selected that exhibited single cell clonal expansion with a doubling time of 34.2 hrs, and had normal karyotyping, but no anchorage-independent growth. A single cell could be continually expanded to a confluent monolayer on denuded amniotic membrane and became stratified by exposing to the air-medium interface. The resultant stratified epithelium expressed K14 keratin, involucrin, connexin 43 and p63, but not K12 keratin or Pax 6. However, expression of K12 could be up-regulated by increasing extracellular calcium concentration and addition of foetal bovine serum (FBS) at P12, but less so at P85. Therefore, this murine lim-bal/corneal epithelium-derived progenitor cell line still retained the plasticity for adopting corneal lineage differentiation, could be useful for investigating limbal niche cues that may promote corneal epithelial fate decision.     

PFN1 and integrin‐β1/mTOR axis involvement in cornea differentiation of fibroblast limbal stem cells

Ex vivo limbal stem cell transplantation is the main therapeutic approach to address a complete and functional re‐epithelialization in corneal blindness, the second most common eye disorder. Although important key points were defined, the molecular mechanisms involved in the epithelial phenotype determination are unclear. Our previous studies have demonstrated the pluripotency and immune‐modulatory of fibroblast limbal stem cells (f‐LSCs), isolated from the corneal limbus. We defined a proteomic profile especially enriched in wound healing and cytoskeleton‐remodelling proteins, including Profilin‐1 (PFN1). In this study we postulate that pfn‐1 knock down promotes epithelial lineage by inhibiting the integrin‐β1(CD29)/mTOR pathway and subsequent NANOG down‐expression. We showed that it is possible modulate pfn1 expression levels by treating f‐LSCs with Resveratrol (RSV), a natural compound: pfn1 decline is accompanied with up‐regulation of the specific differentiation epithelial genes pax6 (paired‐box 6), sox17 (sex determining region Y‐box 17) and ΔNp63‐α (p63 splice variant), consistent with drop‐down of the principle stem gene levels. These results contribute to understand the molecular biology of corneal epithelium development and suggest that pfn1 is a potential molecular target for the treatment of corneal blindness based on epithelial cell dysfunction.     

The corneal epithelial stem cell

The aim of this paper was to develop a GFP-expressing transgenic mouse model for the keratoepithelioplasty and to use this to follow the outcome of this form of graft, when placed on an inflamed corneal surface. Further aims were to characterize both the graft and the epithelial surface of the mouse and rat cornea using putative stem cell markers (P63 and Telomerase) and marker of cell differentiation (14-3-3 sigma). Keratepithelioplasty was carried out using a GFP transgenic mouse cornea as donor tissue. Fluorescent epithelial outgrowth from each keratepithelioplasty was scored and quantified. Donor corneal graft tissue was obtained from the paracentral region or the anatomical limbal region of murine corneas. Paracentral donor grafts (n = 20) consistently demonstrated a significant increase in proliferative potential compared to grafts obtained from the anatomical limbal region of the mouse cornea (n = 25) (P = 0.000, Mann-Whitney U). Correspondingly, P63 expression was maximal in the paracentral region of the mouse cornea, in keeping with the demonstrated increased proliferative potential of donor grafts harvested from this region of the cornea. The murine corneal epithelium demonstrated decreased rather than increased cellular layers at the limbal region, in contrast to that of the rat or human epithelium. In addition, as a general finding in all species tested, there was an apparent increase noted in P63 expression in basal corneal epithelial cells in regions that had increased cellular layers (limbus in humans and rats and the paracentral corneal region in the mouse). Epithelium, which had migrated from donor grafts onto recipient corneas, retained P63 expression for the period of time examined (up to 3 days postengraftment). In addition, the conjunctival surface of an injured conjunctivalized displayed an abnormal pattern of P63 expression. Telomerase expression was widespread throughout many layers of both the murine and rat corneal epithelium. In the mouse and rat corneal epithelium P63 expression was maximal in areas of increased proliferative potential. Its expression, however, was not confined to stem cells alone. Migrating cells from transplanted keratoepithelial grafts retained P63 expression at least in the early stages post-transplantation. Finally, damaged conjunctivalized corneas displayed an abnormal P63 expression pattern when compared to either normal conjunctiva or normal cornea.     

Aquaporin 1-positive stromal niche-like cells directly interact with N-cadherin-positive clusters in the basal limbal epithelium

Stem cells have a specialized microenvironment for maintaining self-renewal and multipotent capacities. It is believed that a cornea epithelial stem cell niche exists in the limbus. To characterize the niche of limbal epithelial stem cells, we observed the limbal basal epithelial layer by histological analysis.Cell clusters or cell suspensions from limbal tissue were prepared with collagenase or dispase II and fixed for cytospin sections. Adhesion assays were done to quantitate calcium-dependent cell adhesion. Limbal tissue and cytospin sections were analyzed by immunohistochemistry, transmission electron microscopy and confocal microscopy.AQP1 positive (AQP1⁺) cells were observed as non-epithelial cells in the subepithelial stroma. AQP1 expression did not co-localize with CD31, podoplanin, MART-1 positive cells, but were observed in vimentin positive stromal cells. When we made a thorough search of limbal basal cells by confocal microscopy, AQP1⁺ were observed in the proximity of N-cad, K15 and p63 positive limbal basal epithelial cells. Furthermore, electron microscope revealed stromal cells penetrating the epithelial basal membrane and forming calcium-dependent cellular adhesions with N-cad⁺ limbal basal epithelial cells.Although we could not clearly detect the expression of N-cad in the AQP1⁺ cells, AQP1⁺ cells immediately beneath the epithelial basement membrane may be stromal niche-like cells that directly interact with N-cad⁺ limbal basal epithelial progenitor cells.