Maspin increases extracellular plasminogen activator activity associated with corneal fibroblasts and myofibroblasts

Maspin, an inhibitor of cell migration and a stimulator of adhesion of cells to the ECM, is synthesized and released by corneal keratocytes into the extracellular matrix. When the cornea is wounded, the quiescent stromal keratocytes underlying the wound undergo apoptosis and cells adjacent to this apoptotic area convert to fibroblasts or myofibroblasts. This study explores the effect of extracellular maspin on the plasminogen–plasminogen activator system of corneal stromal cells following wounding. Treatment of corneal fibroblasts and myofibroblasts with r-maspin increased extracellular but not cell-associated tissue-type plasminogen activator (tPA), urinary-type plasminogen activator (uPA) or plasminogen activator inhibitor-1 (PAI-1). Despite the extracellular increase in PAI-1, the net effect of maspin treatment was an increase in plasminogen activation. At physiological levels, maspin did not alter uPA or tPA mRNA levels, in these cells. The increase in pro and active uPA was due to decreased clearance in the presence of maspin for myofibroblasts but not for fibroblasts. The clearance of pro and active tPA was normal in fibroblasts indicating different mechanisms for the increase of these homologous enzymes in the two cell types. Increased generation of plasmin by maspin treated corneal stromal fibroblasts and myofibroblasts led to conversion of plasminogen to active plasmin degradation products and angiostatin-like molecules. This study suggests that extracellular maspin increased pro and active uPA and tPA released by corneal fibroblasts and myofibroblasts on the short time scale of 1–4 h, but by 24 h there was no increase over the levels produced without maspin. This augmentation of plasminogen activator activity increases plasmin activation and angiostatin generation. It further indicates that the effect of maspin on uPA and tPA levels is cell type dependent.     

Loss of alpha3(IV) collagen expression associated with corneal keratocyte activation

PURPOSE: To determine whether changes in the expression of type IV alpha1, alpha2, or alpha3 collagen isoforms are stringently associated with corneal stromal cell activation. METHODS: Keratocytes isolated from rabbit corneal stroma by collagenase digestion were plated in serum-free or insulin-, bFGF/heparin sulfate (HS)-, TGF-beta1-, or fetal bovine serum (FBS)-supplemented DMEM/F12 medium. Expression of type IV collagen isoforms and keratan sulfate proteoglycans (KSPGs) was evaluated by immunocytochemical analysis, Western blot analysis, or both. Concentrations of mRNAs were estimated by quantitative RT-PCR using SYBR Green RT-PCR reagents. RESULTS: Immunohistochemical analysis indicated that type IV alpha1, alpha2, and alpha3 collagens were expressed in normal rabbit corneal stroma and in keratocytes cultured in serum-free and insulin-supplemented media. However, alpha3(IV) collagen was not detectable in the regenerating stroma after photorefractive keratectomy (PRK) in rabbit or in corneal stromal cells cultured in media supplemented with FBS, bFGF/HS, or TGF-beta1. alpha3(IV) collagen mRNA levels were also diminished in the stromal cells cultured in these growth factor-supplemented media. KSPGs (lumican and keratocan) were expressed and secreted in serum-free medium. Although the expression of KSPGs was promoted by insulin, the expression and intracellular levels of lumican and keratocan mRNAs were downregulated by TGF-beta1 and FBS. bFGF/HS promoted the downregulation of intracellular keratocan but not lumican mRNA levels. CONCLUSIONS: The loss in the expression of alpha3(IV) collagen is a stringent phenotypic change associated with activation of keratocytes in vivo and in vitro. This phenotypic change in activated corneal stromal cells is induced by bFGF/HS and by TGF-beta1, and it accompanies the downregulation of keratocan expression.     

Preservation and expansion of the primate keratocyte phenotype by downregulating TGF-beta signaling in a low-calcium, serum-free medium

PURPOSE: To demonstrate whether the original keratocyte phenotype is maintained with proliferative activity by suppressing TGF-beta signaling in rhesus monkey keratocytes expanded in a serum-free and low-[Ca2+] medium. METHODS: Rhesus monkey keratocytes were isolated from central corneal buttons by collagenase digestion for 16 hours, seeded on plastic in Dulbecco's modified Eagle's medium (DMEM) containing insulin-transferrin-sodium selenite (ITS) supplement (DMEM/ITS) or 10% fetal bovine serum (DMEM/10% FBS), or in a defined keratinocyte serum-free medium (KSFM). After confluence, cells in KSFM were continuously subcultured at a 1-to-3 split. Cellular proliferation was analyzed by immunostaining for Ki67 and the MTT assay. The cellular phenotype was determined by immunostaining for aldehyde dehydrogenase (ALDH), keratocan, and CD34 and by the expression of keratocan promoter-driven enhanced cyan fluorescent protein (ECFP). The stability of the keratocyte phenotype was examined by switching KSFM to DMEM/ITS and DMEM/10% FBS. TGF-beta signaling was monitored by measuring the promoter activity of TGF-beta1, -beta2, and -beta RII after transient adenoviral transfection, and cytolocalization of Smad2 and Smad4. RESULTS: In KSFM, monkey keratocytes proliferated while maintaining the expression of keratocan, CD34, and ALDH proteins and keratocan promoter-driven ECFP for at least 15 passages. The nuclear accumulation of Smad2 and Smad4 and the promoter activities of TGF-beta1 and -beta RII were significantly downregulated in KSFM compared with DMEM/10% FBS. In KSFM, an increase of [Ca2+] to 1.8 mM and addition of 10% FBS synergistically downregulated the keratocan promoter activity, facilitated Smad2 and Smad4 nuclear translocation, and upregulated TGF-beta1 and -beta RII promoter activities. CONCLUSIONS: The normal monkey keratocyte phenotype can be maintained in a low-calcium, serum-free medium by downregulating Smad-mediated TGF-beta signaling.     

Sphere formation from corneal keratocytes and phenotype specific markers

The keratocytes are specialized mesenchymal cells that produce and maintain the extracellular matrix of the corneal stroma. With a typical dendritic and flattened appearance, these cells can morph into fibroblasts and myofibroblasts upon injury, and produce abnormal or fibrotic extracellular matrices detrimental to corneal transparency. Insights into mechanisms that regulate these phenotypic switches and optimal culture conditions that preserve the keratocyte phenotype are important for tissue engineering of the corneal stroma. Like other cell types with self-renewing capacity, keratocytes can form spheres in culture. Here we investigated human and bovine keratocytes with respect to their sphere forming capabilities, and sought to identify potentially distinguishing markers for the keratocyte and fibroblast phenotypes. Keratocytes, isolated from bovine and human corneas, cultured in serum-free medium supplemented with insulin, selenium and transferrin, assumed typical keratocyte morphology, converted to fibroblasts in serum-containing medium and reverted to keratocytes after serum-deprivation. The bovine keratocytes produced spheres under adherent or low attachment conditions, while the human keratocytes produced spheres under low attachment conditions only. The primary keratocytes and fibroblasts expressed vimentin, confirming their mesenchymal origin. Keratocan, considered to be a marker for keratocytes, was also detected in early passage bovine fibroblasts. BMP3 was expressed in keratocytes and keratocyte-derived spheres, while cadherin 5 in keratocytes only, suggesting these as potential keratocyte markers.     

Differential regulation of fibronectin synthesis in three different types of corneal cells

The production of fibronectin (FN) and its response to serum or epidermal growth factor (EGF) were investigated in three different types of rabbit corneal cells cultured in vitro. The corneal epithelial cells, stromal fibroblasts (keratocytes) and endothelial cells were separately cultured in different media: basic medium containing minimal serum (0.5%), basic medium with supplementary serum at a final concentration of 10% and basic medium with 100 ng/ml EGF, respectively. FN production by each type of cell was examined either by the immunofluorescent staining method or by the metabolic labeling method followed by immunoprecipitation of FN in the culture medium. Each type of corneal cell produced and secreted FN. FN secretion into the culture medium by keratocytes and by endothelial cells was enhanced by the addition of EGF. However, FN secretion by epithelial cells was lowered by the additional serum or EGF. Furthermore, when the epithelial cells were cultured in the basic medium, DNA synthesis was low but FN secretion was high. These results suggest that the control mechanism of FN production differs between epithelial cells and keratocytes or endothelial cells.     

Maspin: synthesis by human cornea and regulation of in vitro stromal cell adhesion to extracellular matrix.

PURPOSE: Maspin, a tumor-suppressor protein that regulates cell migration, invasion, and adhesion, is synthesized by many normal epithelial cells, but downregulated in invasive epithelial tumor cells. The purpose of this study was to determine whether cells in the normal human cornea express maspin and whether maspin affects corneal stromal cell adhesion to extracellular matrix molecules. METHODS: Maspin expression was analyzed by immunodot blot, Western blot, and RT-PCR analyses in cells obtained directly from human corneas in situ. Maspin protein and mRNA were also studied in primary and passaged cultures of corneal stromal cells using Western blot analysis, RT-PCR, and immunofluorescence microscopy. Maspin cDNA was cloned and sequenced from human corneal epithelial cells and expressed in a yeast system. The recombinant maspin was used to study attachment of cultured human corneal stromal cells to extracellular matrices. RESULTS: Maspin mRNA and micromolar amounts of the protein were found in all three layers of the human cornea in situ, including the stroma. Maspin was also detected in primary and first-passage corneal stromal cells, but its expression was downregulated in subsequent passages. Late-passage stromal cells, which did not produce maspin, responded to exogenous recombinant maspin as measured by increased cell adhesion not only to fibronectin, similar to mammary gland tumor epithelial cells, but also to type I collagen, type IV collagen, and laminin. CONCLUSIONS: The corneal stromal cell is the first nonepithelial cell type shown to synthesize maspin. Loss of maspin expression in late-passage corneal stromal cells in culture and their biological response to exogenous maspin suggests a role for maspin on the stromal cells in the cornea. Maspin may function within the cornea to regulate cell adhesion to extracellular matrix molecules and perhaps to regulate the migration of activated fibroblasts during corneal stromal wound healing.     

Thy-1 distinguishes human corneal fibroblasts and myofibroblasts from keratocytes

After corneal injury, keratocytes become activated and transform into repair phenotypes-corneal fibroblasts or myofibroblasts, however, these important cells are difficult to identify histologically, compromising studies of stromal wound healing. Recent studies indicate that expression of the cell surface protein, Thy-1, is induced in fibroblast populations associated with wound healing and fibrosis in other tissues. We investigated whether keratocyte transformation to either repair-associated phenotype induced Thy-1 expression. Human corneal keratocytes were isolated by collagenase digestion. The cells were either processed immediately (i.e. freshly isolated keratocytes) or were cultured in the presence of 10% fetal bovine serum or transforming growth factor-beta to induce transformation to the corneal fibroblast and myofibroblast phenotypes, respectively. Thy-1 mRNA and protein expression by freshly isolated keratocytes and corneal fibroblasts were assessed by RT-PCR and Western blotting. mRNA also was extracted from the whole intact stroma and assessed by RT-PCR. Thy-1 was localised immunocytochemically in cultured human corneal fibroblasts, myofibroblasts, and in keratocytes in normal human corneal tissue sections. Thy-1 mRNA and protein were detectable in cultured human corneal fibroblasts, but not freshly isolated keratocytes. Whole uninjured stroma showed no detectable Thy-1 mRNA expression. Cultured human corneal fibroblasts and myofibroblasts both labelled for Thy-1, but keratocytes in the stroma of normal human cornea did not. We conclude that Thy-1 expression is induced by transformation of keratocytes to corneal fibroblasts and myofibroblasts, suggesting a potential functional role for Thy-1 in stromal wound healing and providing a surface marker to distinguish the normal keratocyte from its repair phenotypes.     

Characterization of corneal keratocyte morphology and mechanical activity within 3-D collagen matrices

The purpose of this study was to assess quantitatively the differences in morphology, cytoskeletal organization and mechanical behavior between quiescent corneal keratocytes and activated fibroblasts in a 3-D culture model. Primary cultures of rabbit corneal keratocytes and fibroblasts were plated inside type I collagen matrices in serum-free media or 10% FBS, and allowed to spread for 1-5 days. Following F-actin labeling using phalloidin, and immunolabeling of tubulin, α-smooth muscle actin or connexin 43, fluorescent and reflected light (for collagen fibrils) 3-D optical section images were acquired using laser confocal microscopy. In other experiments, dynamic imaging was performed using differential interference contrast microscopy, and finite element modeling was used to map ECM deformations. Corneal keratocytes developed a stellate morphology with numerous cell processes that ran a tortuous path between and along collagen fibrils without any apparent impact on their alignment. Fibroblasts on the other hand, had a more bipolar morphology with pseudopodial processes (P ≤ 0.001). Time-lapse imaging of keratocytes revealed occasional extension and retraction of dendritic processes with only transient displacements of collagen fibrils, whereas fibroblasts exerted stronger myosin II-dependent contractile forces (P < 0.01), causing increased compaction and alignment of collagen at the ends of the pseudopodia (P < 0.001). At high cell density, both keratocytes and fibroblasts appeared to form a 3-D network connected via gap junctions. Overall, this experimental model provides a unique platform for quantitative investigation of the morphological, cytoskeletal and contractile behavior of corneal keratocytes (i.e. their mechanical phenotype) in a 3-D microenvironment.     

Human keratocytes cultured on amniotic membrane stroma preserve morphology and express keratocan

PURPOSE: To develop a new method of expanding human corneal keratocytes in serum while maintaining their characteristic morphology and keratocan expression. METHODS: Human keratocytes were isolated from central corneal buttons by digestion in 1 mg/mL of collagenase A in DMEM and seeded on plastic or the stromal matrix of human amniotic membrane (AM) in DMEM with different concentrations of FBS. On confluence, cells on AM were continuously subcultured for six passages on AM or plastic. In parallel, cells cultured on plastic at passages 3 and 11 were reseeded on AM. Cellular morphology and cell-cell networks were assessed by phase-contrast microscopy and a cell viability assay, respectively. Expression of keratocan was determined by RT-PCR and Western blot analysis. RESULTS: Trephined stroma yielded 91,600 +/- 26,300 cells (ranging from 67,000 to 128,000 cells per corneal button). Twenty-four hours after seeding, cells appeared dendritic on AM, even in 10% FBS but fibroblastic on plastic. Such a difference in morphology correlated with expression of keratocan assessed by RT-PCR and Western blot, which was high and continued at least to passage 6 on AM, even in 10% FBS, but was rapidly lost each time when cells on AM were passaged on plastic. Fibroblasts continuously cultured on plastic to passages 3 and 11 did not reverse their morphology or synthesize keratocan when reseeded on plastic in 1% FBS or on AM. CONCLUSIONS: Human keratocytes maintain their characteristic morphology and keratocan expression when subcultured on AM stromal matrix even in the presence of high serum concentrations. This method can be used to engineer a new corneal stroma.     

microRNA-127抑制葡萄膜黑色素瘤细胞增殖的表观遗传调控研究

目的：研究microRNA-127（miR-127）在人葡萄膜黑色素瘤细胞中的表达水平及其对细胞增殖的影响。方法：实验研究。通过实时荧光定量PCR（RT-qPCR）法检测miR-127在葡萄膜黑色素瘤细胞M23和SP6.5与正常葡萄膜黑色素细胞UM95中的表达水平。细胞实验通过阳离子脂质体介导的方法将miR-127和阴性对照（NC）转染入M23和SP6.5中,并应用细胞增殖实验法（MTS法）和流式细胞技术分别检测细胞增殖能力和细胞周期,采用Western Blot法检测转染miR-127后细胞周期相关蛋白的表达。另外,通过RT-qPCR检测用表观药物5-氮杂-2-脱氧胞苷（5-Aza-dC）和（或）曲古抑菌素A（TSA）处理后的M23和SP6.5细胞内miR-127的表达水平。MiR-127的表达量及细胞实验各参数在2组间比较采用独立样本t检验。结果：miR-127在M23和SP6.5中的表达水平低于UM95（t=72.2、591.5,P<0.001）。MTS结果显示,在M23和SP6.5细胞中,转染miR-127组相对细胞数目较NC组的100%分别减少至（62.3±4.2）%和（65.4±2.3）%,差异具有统计学意义（t=12.7、21.6,P<0.001）。流式细胞技术分析显示,转染miR-127组处于G0/G1期的M23和SP6.5细胞数量比例明显高于NC组（t=-6.7,P=0.003;t=-9.9,P<0.001）,同时处于S期的M23和SP6.5细胞数量比例明显低于NC组（t=8.6,P=0.001;t=12.7,P<0.001）。Western Blot结果表明miR-127可明显降低M23和SP6.5细胞内磷酸化Rb 蛋白的表达水平（t=22.2、15.6,P<0.001）。此外,miR-127在M23和SP6.5细胞中的表达可被5-Aza-dC和TSA诱导上调（P<0.05）。结论：miR-127通过抑制细胞周期而抑制人葡萄膜黑色素瘤细胞的增殖,并可被DNA甲基化和组蛋白乙酰化表观遗传机制调控。     

Tropoelastin biosynthesis by corneal cells. Epithelial inhibition of keratocyte tropoelastin biosynthesis

The vertebrate cornea is an avascular tissue and does not contain elastic fibers. We tested the capacity of corneal epithelial cells and stromal keratocytes to synthesize tropoelastin. Explant cultures and cell cultures were obtained from these two cell types in standard culture conditions. Their elastin-synthetic activity was compared to skin explant cultures and to dermal fibroblast cell cultures. Both corneal cell types synthesized tropoelastin as shown by the incorporation of a radioactive precursor followed by immunoprecipitation of tropoelastin. When serial cultures of keratocytes were tested, tropoelastin biosynthesis strongly increased after the 3rd passage and was at the 9th passage more than the double of that of the first passage. When cocultures were studied with or without cell contact, epithelial cells partially inhibited tropoelastin biosynthesis by keratocytes. This inhibition was somewhat stronger (-36%, p < 0.005) with cell-to-cell contact than keeping separate epithelial cells and keratocytes bathing in the same medium (-18%, p < 0.005). When human skin fibroblasts were substituted for keratocytes with cell-to-cell contact, their tropoelastin biosynthesis was also inhibited by corneal epithelial cells (-42%, p < 0.005), to the same extent as for keratocytes. In Transwell culture, this inhibition was again somewhat lower (-36%, p < 0.005). Some diffusible factor produced by epithelial cells is apparently involved. The epithelial inhibition of tropoelastin biosynthesis by stromal keratocytes might represent one of the mechanisms keeping corneal stroma exempt of elastin fibers.     

Proteoglycan synthesis by bovine keratocytes and corneal fibroblasts: maintenance of the keratocyte phenotype in culture.

PURPOSE: To determine the effect of serum on morphology, growth, and proteoglycan synthesis by primary cultures of collagenase-isolated bovine keratocytes. METHODS: Keratocytes were isolated from bovine corneas using sequential collagenase digestion and cultured in Dulbecco's modified Eagle's medium (DMEM), with and without fetal bovine serum (FBS). Proteoglycans synthesized by the cells in culture and by keratocytes in intact cornea culture were metabolically radiolabeled with 35SO4. The proteoglycans were characterized by their sensitivity to keratanase, chondroitinase ABC, and heparatinase and by their size on Superose 6 HR. Cell number was determined by measuring DNA content of the culture dishes. RESULTS: Keratocytes cultured in 10% FBS proliferated, appeared fibroblastic, and synthesized only 9% of the total glycosaminoglycan as keratan sulfate (KS), whereas cells in serum-free media were quiescent, appeared dendritic, and synthesized 47% KS, a value similar to the 45% KS for corneas radiolabeled overnight in organ culture. This increased proportion of KS synthesis in serum-free media was caused by a moderate increase in KS synthesis combined with a substantial decrease in chondroitin sulfate (CS) synthesis. Fractionation on Superose 6 High Resolution showed the size and relative amounts of the CS- and KS-containing proteoglycans synthesized by keratocytes in serum-free media also more closely resembled that of keratocytes in corneas in organ culture than keratocytes in media containing serum. CONCLUSIONS: A comparison of proteoglycan synthesis and cell morphology between keratocytes in corneas in organ culture and in cell culture indicates that keratocytes maintain a more native biosynthetic phenotype and appearance when cultured in serum-free media. These results also suggest that culturing in the presence of serum fundamentally alters the keratocyte phenotype to an activated cell, mimicking certain changes observed during wound healing.     

CD-34 expression by cultured human keratocytes is downregulated during myofibroblast differentiation induced by TGF-beta1

PURPOSE: To establish CD34 as a cell surface marker for human keratocytes and to demonstrate its downregulation during TGF-beta1-induced myofibroblast differentiation. METHODS: Collagenase-isolated keratocytes were seeded and subcultured on plastic or amniotic membrane matrix (AM) in DMEM, with or without 10% FBS, in serum-free DMEM containing insulin-transferrin-sodium selenite (ITS) with 10, 100, and 1000 pg/mL TGF-beta1 or in DMEM with 1% FBS and 10 ng/mL TGF-beta1. Protein expression of CD34 and alpha-smooth muscle actin (alpha-SMA) was measured by Western blot and immunostaining. RESULTS: Keratocytes, expressing CD34 in normal human corneas, continued to express CD34 when cultured on AM in serum-containing medium and on plastic in serum-free medium, but expression was lost on plastic in serum-containing medium. In serum-containing medium, expression of CD34, but not alpha-SMA, was maintained by cells continuously passaged on AM. In contrast, cells expressed alpha-SMA without CD34 when continuously passaged on plastic. Expression of alpha-SMA by cells on plastic was downregulated without CD34 when subcultured on AM. CD34 expression by cells on AM was downregulated, whereas alpha-SMA expression was upregulated when cells were subcultured on plastic. In serum-free medium, CD34 expression was maintained by cells treated with 10 pg/mL TGF-beta1, but was lost when treated with a higher concentration on plastic for 5 days. In 1% FBS, AM-expanded keratocytes rapidly became alpha-SMA-expressing myofibroblasts if subpassaged on plastic and treated with 10 ng/mL TGF-beta1, but failed to do so if cultured on AM, even for 7 days. CONCLUSIONS: These findings indicate that CD34 is expressed by human keratocytes in vivo and in vitro. Myofibroblast differentiation promoted by TGF-beta1 downregulates CD34 expression. Maintenance of CD34 expression by AM is consistent with a reported effect of AM on suppressing TGF-beta signaling.     

Myofibroblast differentiation of normal human keratocytes and hTERT,extended-life human corneal fibroblasts

PURPOSE: The purpose of this study was to determine whether TGFbeta induces myofibroblast differentiation in cultured human keratocytes and in telomerase (hTERT)-immortalized human corneal fibroblast cell lines. METHODS: Normal human corneal keratocytes were isolated from donor corneas of various ages and grown under serum-free (cultured keratocytes) or serum-added (corneal fibroblasts) conditions. Corneal fibroblasts were infected with the MPSV-hTERT retroviral vector, and selected clones were isolated and characterized by chromosomal karyotyping. The responses of normal cultured keratocytes and serum-starved corneal fibroblasts to TGFbeta in the presence or absence of Arg-Gly-Asp (RGD)-containing peptides and neutralizing antibodies to platelet-derived growth factor (PDGF) were characterized by immunocytochemistry, Western blot analysis, and real-time PCR, to identify assembly of actin filaments, formation of focal adhesions, and expression of alpha-smooth muscle actin (alpha-SMA). RESULTS: Treatment of cultured keratocytes with TGFbeta (1 ng/mL) induced cell spreading, assembly of actin filaments, formation of focal adhesions, and expression of alpha-SMA, which was blocked by the addition of RGD-containing peptides (100 microM). A similar response was identified in hTERT-expressing human corneal fibroblast cell lines, showing a 69-fold increase in alpha-SMA message. Furthermore, treatment of hTERT corneal fibroblasts with RGD or anti-PDGF inhibited myofibroblast differentiation. Karyotype analysis of hTERT corneal fibroblasts identified age-dependent chromosomal aberrations in cells of older donors but not in those of a 10-year-old donor. CONCLUSIONS: Induction of myofibroblast differentiation by TGFbeta in cultured human keratocytes and hTERT corneal fibroblasts occurs through a similar signal transduction pathway to that previously identified in the rabbit, which involves an autocrine PDGF feedback loop.     

小鼠角膜基质细胞的KSFM培养基培养法

目的研究使用KSFM培养基能否获取具有增殖能力且保持生物学特性不变的小鼠角膜基质细胞（CSCs）。方法实验研究。将中央区角膜置于EDTA液（20mmol／L）内孵育45min后,用手术显微镊小心剥离角膜上皮层以及内皮层,并将获取的角膜基质置于含300U／mlⅠ型胶原酶的溶液中消化4h。离心后采用DMEM基础培养基、DMEM完全培养基（含10％FBS）以及KSFM培养基重悬细胞常规培养,并以含1U／m1分散酶的EDTA液消化传代细胞。同时,观察细胞并绘制细胞生长曲线;采用逆转录聚合酶链式反应（RT．PCR）检测细胞角膜蛋白多糖（keratocan）mRNA和乙醛脱氢酶（ALDH）mRNA表达情况;采用细胞免疫荧光染色以及蛋白质印迹方法检测细胞keratocan蛋白的表达情况。采用独立样本≠检验对数据进行统计学分析。结果通过胶原酶消化的方法可以从每只小鼠的角膜基质获取约l×l04个单个细胞。RT-PCR结果显示,原代细胞表达CSCs标记物keratocan和ALDH;免疫荧光染色和蛋白质印迹结果显示：原代细胞表达keratocan蛋白。培养于DMEM基础培养基内的原代CSCs无法增殖。培养于DMEM完全培养基内的CSCs可增殖,但第3代细胞不表达keratocan mRNA和ALDH mRNA以及keratocan蛋白。培养于KSFM培养基内的CSCs也可增殖,第3代细胞仍表达keratocan mRNA和ALDH mRNA以及keratocan蛋白,且与原代细胞相比,表达强度差异无统计学意义。结论KSFM培养基不仅能维持小鼠CSCs的生物学特性不变,还能有效促进细胞增殖。     

Partial restoration of the keratocyte phenotype to bovine keratocytes made fibroblastic by serum

PURPOSE: To determine whether keratocytes made fibroblastic in vitro by addition of fetal bovine serum to the medium regain the keratocyte phenotype after culture in serum-free medium. METHODS: Collagenase-isolated keratocytes from bovine corneas were plated in DMEM/F-12 containing 1% horse plasma, to allow cell attachment, and then cultured until day 4 in either DMEM/F-12 alone, to retain the keratocyte phenotype, or in DMEM containing 10% fetal bovine serum, to cause the keratocytes to become fibroblastic. Medium for the fibroblastic cells was replaced on day 4 with serum-free medium, and cells were cultured until day 12. Cell phenotypes were determined on days 4 to 5 and 11 to 12 of culture as follows: (1) by the morphologic appearance on phase-contrast microscopy; (2) by the levels of aldehyde dehydrogenase in the cells, determined by SDS-PAGE and Coomassie blue staining; (3) by the relative synthesis of collagen types I and V, determined by (14)C-proline radiolabeling; (4) by pepsin digestion and analysis of collagen types by SDS-PAGE autoradiography; (5) by relative synthesis of cornea-specific proteoglycan core proteins determined by analysis of chondroitinase- or endo-beta-galactosidase-generated radiolabeled core proteins by SDS-PAGE autoradiography; and (6) by the relative synthesis of keratan sulfate and chondroitin sulfate determined by (35)SO(4) radiolabeling and measuring the sensitivity to endo-beta-galactosidase and chondroitinase ABC. RESULTS: Keratocytes cultured in serum-free medium appeared dendritic and became fibroblastic in appearance when exposed to medium containing serum. Keratocytes and fibroblasts synthesized a similar proportion of collagen types I and V. However, compared with the keratocytes, the fibroblasts possessed no aldehyde dehydrogenase and synthesized significantly higher levels of decorin and significantly lower levels of prostaglandin D synthase (PGDS) and keratan sulfate. Subsequent culture of the fibroblasts in serum-free medium did not restore aldehyde dehydrogenase to keratocyte levels but did restore the cell morphology to a more dendritic appearance and returned the synthesis of decorin, PGDS, and keratan sulfate to keratocyte levels. CONCLUSIONS: The results of these studies indicate that primary cultures of keratocytes made fibroblastic by exposure to serum can return to their keratocyte phenotype in synthesizing extracellular matrix. These results also indicate that the differences in the organization of the collagenous matrix produced by keratocytes and fibroblasts may be related more to the different proteoglycan types than to the collagen types produced.     

Epithelial-stromal interactions: specific stimulation of corneal epithelial cell growth in vitro by a factor(s) from cultured stromal fibroblasts

By using a recently modified method of isolating and culturing rabbit corneal cells, this study investigated the presence of a diffusible substance(s) in stromal fibroblast conditioned medium that stimulated the growth of cultured corneal epithelial cells. The growth stimulation involved initiation of DNA synthesis (assayed by [3H]-thymidine incorporation) and enhanced cell proliferation (quantified by cell counting). Among the three corneal cell types, only fibroblasts (rabbit and human) released the stimulatory substance, which acted only on epithelial cells. The effect of this stromal fibroblast factor (SFF) was observed after an exposure period of less than 16 hr and persisted as long as it was present. Its action was concentration-dependent and was not a result of improvement in the survival of epithelial cells during culture. Both sparse and confluent epithelial cultures were susceptible to SFF. The release of SFF was correlated with the number of fibroblasts in the culture and appeared to be sensitive to the growth condition of the cells. Both the release and action of SFF did not depend on the presence of serum in the culture medium. The factor was heat resistant and insensitive to proteolytic enzymes. From ultrafiltration studies, the size of SFF was estimated to be in the approximate range of 50-1000 daltons. By direct comparison of the stimulatory effect with other previously studied growth promoting agents, it was concluded that SFF was not epidermal growth factor, fibroblast growth factor, putrescine, cyclic AMP, hydrocortisone or acetate. The implication of SFF in the regulation of epithelial growth by endogenous, intercellular mechanisms is discussed.     

低剂量TGF-β1维持三维培养模型中牛角膜基质细胞生长和缓解细胞外基质纤维化的作用

背景 转化生长因子(TGF)-β1在角膜损伤修复过程中发挥重要作用,不同剂量的TGF-β1对角膜细胞外基质(ECM)的合成具有不同影响,从而影响瘢痕形成的程度.既往研究多集中于高质量浓度TGF-β1对二维培养的角膜基质细胞的影响,而低质量浓度TGF-β1对角膜基质细胞ECM合成的影响鲜见研究.目的研究低质量浓度TGF-β1对体外三维培养的角膜基质细胞生长状况及ECM合成的影响. 方法 采用两步胶原酶消化法从新鲜牛眼中分离牛角膜基质细胞并置于含体积分数10％胎牛血清(FBS)的DMEM/F12培养基,利用Pellet体外三维培养模型对牛角膜基质细胞进行培养.将细胞分为0.25 ng/ml TGF-β1+5％ FBS组和0.50 ng/ml TGF-β1+5％ FBS组,分别于培养后48 h、1周、2周、3周观察Pellet培养模型的形态变化.于培养后3周采用苏木精-伊红染色法对Pellet培养模型进行常规组织形态学检查,采用钙黄绿素-AM/碘化丙啶法(Calcein-AM/PI法)于激光扫描共焦显微镜下检查角膜基质细胞的死亡率;采用实时荧光定量PCR及免疫荧光细胞化学法分别检测细胞中α-平滑肌肌动蛋白(α-SMA)、纤维连接蛋白(FN)、Ⅰ型胶原(Col Ⅰ)和ColⅢmRNA及其蛋白的相对表达量;采用实时荧光定量PCR法检测细胞中角膜蛋白(KERA)mRNA和基膜聚糖(LUM)mRNA的表达.结果 培养后48 h、1周、2周和3周Pellet细胞均成团生长.苏木精-伊红染色可见,Pellet球内均有大量红色淡染的胶原纤维以及大部分正常的成纤维细胞和少量坏死的成纤维细胞,坏死细胞可见细胞形态破坏,呈均质红染,且0.25 ng/ml TGF-β1+5％ FBS组和0.50 ng/ml TGF-β1+5％ FBS组培养细胞形态无明显差别.0.25 ng/ml TGF-β1+5％ FBS组和0.50 ng/ml TGF-β1+5％ FBS组细胞死亡率分别为(33.60±1.65)％和(30.90±0.78)％,差异无统计学意义(t=0.144,P=0.887).0.25 ng/ml TGF-β1+5％FBS组Pellet培养模型中α-SMA、FN、ColⅢ蛋白表达量均低于0.50 ng/ml TGF-β1+5％ FBS组,差异均有统计学意义(tα-SMA=4.622,P=0.010;tFN=2.973,P=0.040;tCol Ⅲ=7.845,P＜0.001),0.25 ng/ml TGF-β1 +5％ FBS组Col Ⅰ的表达量明显高于0.50 ng/ml TGF-β1+5％ FBS组,差异有统计学意义(tColⅠ=4.022,P=O.016).在转录水平和蛋白表达水平,0.25 ng/ml TGF-β1 +5％ FBS组ColⅢ/Col Ⅰ比值均低于0.50 ng/ml TGF-β1+5％FBS组,差异均有统计学意义(tmRNA=-3.039,P=0.038;t蛋白=3.215,P=0.032).培养后48 h、1周、2周Pellet培养模型中KERA mRNA和LUM mRNA均呈阳性表达,0.25 ng/ml TGF-β1+5％ FBS组LUM mRNA相对表达量随培养时间延长而逐渐增加;0.50 ng/ml TGF-β1 +5％ FBS组LUM mRNA相对表达量于培养后1周时达峰值.2个组Pellet培养模型中KERA mRNA相对表达量均在培养后1周达峰值. 结论 低剂量的TGF-β1既能够维持Pellet体外三维培养模型中角膜基质细胞的生长并合成ECM,也使ECM组成成分的合成倾向于正常状态,以减少瘢痕化修复的趋势.     

Growth factor, cytokine and protease interactions during corneal wound healing

Healing of corneal injuries is an exceptionally complex process involving the integrated actions of multiple growth factors, cytokines, and proteases produced by epithelial cells, stromal keratocytes, inflammatory cells, and lacrimal gland cells. Following corneal injury, basal epithelial cells migrate and proliferate in response to chemotactic cytokines and mitogenic growth factors, including epidermal growth factor and keratinocyte growth factor. Simultaneously, keratocytes adjacent to the injured area undergo apoptosis under the Fas/Fas ligand system, while more distant keratocytes transform into activated fibroblasts and migrate into the wound, where they begin synthesizing new extracellular matrix components that form the scar tissue under the dominant influence of the TGFb/ CTGF system. Epithelial cells and activated stromal fibroblasts also secrete growth factors and cytokines that have paracrine and autocrine functions. Corneal repair proceeds for the next several weeks to months, during which time the gene expression profile slowly returns to the pre-injury pattern and the provisional scar matrix slowly remodels by actions of matrix metalloproteinases. While minor epithelial injuries heal by regeneration of normal architecture, large stromal injuries heal by repair with irregular scar tissue that impairs the optical properties of the cornea.Also, if the integrated regulation of the wound healing process is interrupted at any point, the wound fails to heal properly and a corneal ulcer develops. Better understanding of the cellular and molecular changes that occur during repair of corneal wounds will provide the opportunity to design agents that selectively modulate key phases of corneal wound healing, resulting in scars that more closely resemble normal corneal architecture.     

The effects of epithelial viability on stromal keratocyte apoptosis in porcine corneas stored in Optisol-GS

PURPOSE: To investigate the effect of corneal epithelium on the viability of corneal stromal keratocytes in Optisol-GS. METHODS: After sterilization, corneoscleral buttons were excised and stored in Optisol-GS for various time periods. Group 1 corneas (n = 40) underwent mechanical corneal epithelial debridement before storage while group 2 corneas (n = 40) were stored with intact epithelium. Changes in corneal thickness, keratocyte density, and keratocyte apoptosis were investigated immediately, at 4 hours, and on days 1, 2, 3, 5, 7, and 14 in the preservation medium. The differences between group 1 and 2 corneas were analyzed. RESULTS: Corneal thickness increased significantly in the second week of preservation in both groups, though more substantially in group 1. Significant corneal epithelial apoptosis was noticed in the first week in group 2 corneas. Corneal stromal keratocyte density decreased with prolonged preservation time. DNA laddering was detected by ligation-mediated polymerase chain reaction throughout the experiment periods in both groups, but the increase of keratocyte apoptosis was more significant after 5 days of preservation, especially in group 1. CONCLUSIONS: Stromal keratocytes underwent apoptosis in Optisol-GS. The absence of corneal epithelium during preservation further increased the stromal keratocyte apoptosis.