Anees Fatima

MicroRNA-184 antagonizes microRNA-205 to maintain SHIP2 levels in epithelia.

Despite their potential to regulate approximately one-third of the whole genome, relatively few microRNA (miRNA) targets have been experimentally validated, particularly in stratified squamous epithelia. Here we demonstrate not only that the lipid phosphatase SHIP2 is a target of miRNA-205 (miR-205) in epithelial cells, but, more importantly, that the corneal epithelial-specific miR-184 can interfere with the ability of miR-205 to suppress SHIP2 levels. This is the first example of a miRNA negatively regulating another to maintain levels of a target protein. Interfering with miR-205 function by using a synthetic antagomir, or by the ectopic expression of miR-184, leads to a coordinated damping of the Akt signaling pathway via SHIP2 induction. This was associated with a marked increase in keratinocyte apoptosis and cell death. Aggressive squamous cell carcinoma (SCC) cells exhibited elevated levels of miR-205. This was associated with a concomitant reduction in SHIP2 levels. Partial knockdown of endogenous miR-205 in SCCs markedly decreased phosphorylated Akt and phosphorylated BAD levels and increased apoptosis. We were able to increase SHIP2 levels in SCC cells after inhibition of miR-205. Therefore, miR-205 might have diagnostic value in determining the aggressivity of SCCs. Blockage of miR-205 activity with an antagomir or via ectopic expression of miR-184 could be novel therapeutic approaches for treating aggressive SCCs.

MicroRNA-205 promotes keratinocyte migration via the lipid phosphatase SHIP2

microRNA‐205 (miR‐205) and miR‐184 coordinately regulate the lipid phosphatase SHIP2 for Akt survival signaling in keratinocytes. As the PI3K‐Akt pathway has also been implicated in regulating the actin cytoskeleton and cell motility, we investigated the role that these 2 miRNAs play in keratinocyte migration. We used antagomirs (antago) to reduce the levels of miR‐205 and miR‐184 in primary human epidermal keratinocytes (HEKs) and corneal epithelial keratinocytes (HCEKs) as well as direct SHIP2 silencing using siRNA oligos. Treatment of HEKs and HCEKs with antago‐205 increased SHIP2 levels and impaired the ability of these cells to seal linear scratch wounds compared with untreated or irrelevant‐antago treatments. In contrast, AKT signaling was enhanced and wounds sealed faster in HCEKs where miR‐184 was suppressed, enabling miR‐205 to inhibit SHIP2. Similar increases in migration were observed following direct SHIP2 silencing in HEKs. Furthermore, down‐regulation of miR‐205 resulted in an increase in Rho‐ROCKI activity, phosphorylation of the actin severing protein cofilin, and a corresponding diminution of filamentous actin. The connection among miR‐205, RhoA‐ROCKI‐cofilin inactivation, and the actin cytoskeleton represents a novel post‐translational mechanism for the regulation of normal human keratinocyte migration.—Yu, J., Peng, H., Ruan, Q., Fatima, A., Getsios, S., Lavker, R. M. MicroRNA‐205 promotes keratinocyte migration via the lipid phosphatase SHIP2. FASEB J. 24, 3950–3959 (2010). www.fasebj.org

In vitro culture and expansion of human limbal epithelial cells

Limbal stem cells (LSCs) have an important role in the maintenance of the corneal surface epithelium, and autologous cultured limbal epithelial cell transplantations have contributed substantially to the treatment of the visually disabling condition known as LSC deficiency. In this protocol, we describe a method of establishing human limbal epithelial cell cultures by a feeder-free explant culture technique using a small limbal biopsy specimen and human amniotic membrane (hAM) as the culture substrate. This protocol is free of animal-derived products and involves the use of human recombinant growth factors. In addition, the recombinant cell dissociation enzyme TrypLE is used to replace trypsin and autologous serum replaces FBS. It takes ∼2 weeks to establish a confluent monolayer from which ∼3 × 106 cells can be harvested. This procedure can be adopted for both basic research purposes and clinical applications.

A lymphatic defect causes ocular hypertension and glaucoma in mice

Glaucoma is a leading cause of blindness, afflicting more than 60 million people worldwide. Increased intraocular pressure (IOP) due to impaired aqueous humor drainage is a major risk factor for the development of glaucoma. Here, we demonstrated that genetic disruption of the angiopoietin/TIE2 (ANGPT/TIE2) signaling pathway results in high IOP, buphthalmos, and classic features of glaucoma, including retinal ganglion degeneration and vision loss. Eyes from mice with induced deletion of Angpt1 and Angpt2 (A1A2Flox(WB) mice) lacked drainage pathways in the corneal limbus, including Schlemms canal and lymphatic capillaries, which share expression of the PROX1, VEGFR3, and FOXC family of transcription factors. VEGFR3 and FOXCs have been linked to lymphatic disorders in patients, and FOXC1 has been linked to glaucoma. In contrast to blood endothelium, in which ANGPT2 is an antagonist of ANGPT1, we have shown that both ligands cooperate to regulate TIE2 in the lymphatic network of the eye. While A1A2Flox(WB) mice developed high IOP and glaucoma, expression of ANGPT1 or ANGPT2 alone was sufficient for ocular drainage. Furthermore, we demonstrated that loss of FOXC2 from lymphatics results in TIE2 downregulation, suggesting a mechanism for ocular defects in patients with FOXC mutations. These data reveal a pathogenetic and molecular basis for glaucoma and demonstrate the importance of angiopoietin ligand cooperation in the lymphatic endothelium.

Forkhead box transcription factor FoxC1 preserves corneal transparency by regulating vascular growth

Normal vision requires the precise control of vascular growth to maintain corneal transparency. Here we provide evidence for a unique mechanism by which the Forkhead box transcription factor FoxC1 regulates corneal vascular development. Murine Foxc1 is essential for development of the ocular anterior segment, and in humans, mutations have been identified in Axenfeld–Rieger syndrome, a disorder characterized by anterior segment dysgenesis. We show that FOXC1 mutations also lead to corneal angiogenesis, and that mice homozygous for either a global (Foxc1−/−) or neural crest (NC)-specific (NC-Foxc1−/−) null mutation display excessive growth of corneal blood and lymphatic vessels. This is associated with disorganization of the extracellular matrix and increased expression of multiple matrix metalloproteinases. Heterozygous mutants (Foxc1+/− and NC-Foxc1+/−) exhibit milder phenotypes, such as disrupted limbal vasculature. Moreover, environmental exposure to corneal injury significantly increases growth of both blood and lymphatic vessels in both Foxc1+/− and NC-Foxc1+/− mice compared with controls. Notably, this amplification of the angiogenic response is abolished by inhibition of VEGF receptor 2. Collectively, these findings identify a role for FoxC1 in inhibiting corneal angiogenesis, thereby maintaining corneal transparency by regulating VEGF signaling.

Ocular surface changes in limbal stem cell deficiency caused by chemical injury : a histologic study of excised pannus from recipients of cultured corneal epithelium

PurposeTo report histopathologic changes of the ocular surface pannus in patients with severe limbal stem cell deficiency (LSCD).MethodsCorneal and conjunctival pannus tissues from 29 patients undergoing ocular reconstruction with cultured limbal cell transplantation were included. The medical records of these patients were reviewed for demographics, aetiologic diagnosis, type of injury, interval between the initial insult and excision of pannus, and medical history involving human amniotic membrane (HAM) or limbal transplantation. The paraffin-embedded tissues were reviewed for epithelial changes, type–degree of fibrosis, degenerative changes, vascular changes, conjunctivalization of corneal surface, and evidence of residual HAM. We attempted a clinicopathologic correlation to understand the pathogenesis of pannus formation in LSCD.ResultsThe 29 tissues were from 29 eyes of patients with primary aetiology of chemical burn in 89.6% (undetermined in 10.4%) of cases. The pannus showed epithelial hyperplasia in 62%, active fibrosis in 66%, severe inflammation in 21%, giant cell reaction in 28%, and stromal calcification in 14% cases. Goblet cells were seen over the cornea in 64% cases; their absence was associated with squamous metaplasia of the conjunctiva and with long duration of insult. Evidence of residual HAM was noted in 42% cases.ConclusionsThe commonest cause of severe LSCD is alkali-induced injury. Goblet cells over the cornea were seen in 60% of cases. HAM used for ocular surface reconstruction could persist for long periods within the corneal pannus, thus raising the need for further studies with long-term follow-up.

EphA2/Ephrin-A1 signaling complexes restrict corneal epithelial cell migration.

PURPOSE Eph/ephrin signaling proteins are present in the corneal epithelium, where their function remains unknown. The authors examined the role of the EphA2 receptor and ephrin-A1 ligand in human corneal epithelial cell migration. METHODS Immunohistochemical analysis of EphA2 and ephrin-A1 in healthy and diabetic corneas was performed in concert with linear scratch wound healing studies in primary and telomerase-immortalized human corneal epithelial cells. Corneal epithelial cells were exposed to a soluble ephrin-A1-Fc peptide mimetic that targets EphA2 to trigger receptor phosphorylation and subsequent downregulation. Genetic modulation of EphA2 and ephrin-A1 levels was combined with manipulation of Erk1/2 or Akt signaling during wound healing. RESULTS EphA2 was immunolocalized to human corneal epithelial cells in vivo and in vitro. Ephrin-A1 ligand targeting of EphA2 restricted the ability of corneal epithelial cells to seal linear scratch wounds in a manner that was associated with a transient reduction in Erk1/2 and Akt activation state. Ephrin-A1-Fc treatment delayed wound healing independently of Mek-Erk1/2 signaling but was no longer capable of restricting migration after pharmacologic blockade of the PI3K-Akt pathway. Interestingly, ephrin-A1 immunoreactivity was increased in the corneal epithelia of diabetic individuals, mice maintained on a high-fat diet, or cultured corneal epithelial cells exposed to high glucose, which exhibit impaired Akt signaling and slower wound healing responses. CONCLUSIONS EphA2 attenuates corneal epithelial cell migration when stimulated by ephrin-A1 ligand in a manner that involves the suppression of Akt. Elevated levels of ephrin-A1 may contribute to diabetic keratopathies by persistently engaging EphA2 and prohibiting Akt-dependent corneal epithelial repair processes.

Murine Notch1 is required for lymphatic vascular morphogenesis during development

BACKGROUND: The transmembrane receptor Notch1 is a critical regulator of arterial differentiation and blood vessel sprouting. Recent evidence shows that functional blockade of Notch1 and its ligand, Dll4, leads to postnatal lymphatic defects in mice. However, the precise role of the Notch signaling pathway in lymphatic vessel development has yet to be defined. Here we show the developmental role of Notch1 in lymphatic vascular morphogenesis by analyzing lymphatic endothelial cell (LEC)‐specific conditional Notch1 knockout mice crossed with an inducible Prox1CreERT2 driver. RESULTS: LEC‐specific Notch1 mutant embryos exhibited enlarged lymphatic vessels. The phenotype of lymphatic overgrowth accords with increased LEC sprouting from the lymph sacs and increased filopodia formation. Furthermore, cell death was significantly reduced in Notch1‐mutant LECs, whereas proliferation was increased. RNA‐seq analysis revealed that expression of cytokine/chemokine signaling molecules was upregulated in Notch1‐mutant LECs isolated from E15.5 dorsal skin, whereas VEGFR3, VEGFR2, VEGFC, and Gja4 (Connexin 37) were downregulated. CONCLUSIONS: The lymphatic phenotype of LEC‐specific conditional Notch1 mouse mutants indicates that Notch activity in LECs controls lymphatic sprouting and growth during development. These results provide evidence that similar to postnatal and pathological lymphatic vessel formation, the Notch signaling pathway plays a role in inhibiting developmental lymphangiogenesis. Developmental Dynamics 243:957–964, 2014.

Foxc1 and Foxc2 deletion causes abnormal lymphangiogenesis and correlates with ERK hyperactivation

The lymphatic vasculature is essential for maintaining interstitial fluid homeostasis, and dysfunctional lymphangiogenesis contributes to various pathological processes, including inflammatory disease and tumor metastasis. Mutations in FOXC2 are dominantly associated with late-onset lymphedema; however, the precise role of FOXC2 and a closely related factor, FOXC1, in the lymphatic system remains largely unknown. Here we identified a molecular cascade by which FOXC1 and FOXC2 regulate ERK signaling in lymphatic vessel growth. In mice, lymphatic endothelial cell-specific (LEC-specific) deletion of Foxc1, Foxc2, or both resulted in increased LEC proliferation, enlarged lymphatic vessels, and abnormal lymphatic vessel morphogenesis. Compared with LECs from control animals, LECs from mice lacking both Foxc1 and Foxc2 exhibited aberrant expression of Ras regulators, and embryos with LEC-specific deletion of Foxc1 and Foxc2, alone or in combination, exhibited ERK hyperactivation. Pharmacological ERK inhibition in utero abolished the abnormally enlarged lymphatic vessels in FOXC-deficient embryos. Together, these results identify FOXC1 and FOXC2 as essential regulators of lymphangiogenesis and indicate a new potential mechanistic basis for lymphatic-associated diseases.

Chapter 5 Limbal Stem Cells: Application in Ocular Biomedicine

Corneal opacification due to limbal stem cell deficiency (LSCD) is an important cause for ocular morbidity, resulting from a number of intrinsic and extrinsic factors. While the extrinsic factors include conditions such as chemical or thermal injuries, intrinsic include dysfunction, or reduction in the number of stem cells either due to pathological changes in autoimmune diseases or secondary to certain clinical conditions such as diabetes, dry eye disorders, or multiple previous eye surgeries. LSCD is characterized by a classic triad of signs -- conjunctivalization, neovascularization and decrease in vision. With the increasing knowledge of limbal stem cells, the treatment of this condition has evolved from simple debridement to use of biological materials, direct transplantation of the healthy limbal tissue from the contralateral eye, or allogenic source to the use of cultivated limbal epithelial sheets. This chapter provides an update on the disease pathology, various treatment methodologies, with specific emphasis on the fast developing field of cell therapy and tissue engineering.