Relationships between eye factors and lens-forming transformations in the cornea and pericorneal epidermis of larval Xenopus laevis

Larval Xenopus laevis at stage 56 (Nieuwkoop and Faber, '56) were subjected to various types of lentectomy: (1) simple lentectomy, from the pupillary space after incision of outer and inner cornea; (2) lentectomy from the dorsal region of the eye; (3) lentectomy from the dorsal region of the eye and simultaneous incision of the outer cornea; (4) lentectomy from the dorsal region of the eye and simultaneous incision of the outer and inner cornea. The results obtained show that the outer cornea underwent lens-forming transformations only when the inner cornea had been incised, thus permitting outer cornea (Experiments I-IV). No lens regeneration occurred when the inner cornea was left intact (Experiments II, III). It was concluded that the factor(s) allowing the lens-forming transformations of the outer cornea is not an aspecific nutritional factor(s) but a more specific factor(s) that cannot reach the outer cornea when the inner cornea is intact. Therefore, the absence of the lens and sufficient nutrient available to the outer cornea are not enough to allow lens regeneration from the outer cornea. When lens removal was carried out through the dorsal part of the eye (Experiments III-IV) the lens regenerated from the pericorneal epidermis of this region in a large number of cases.     

The transparent lens and cornea in the mouse and zebra fish eye

The lens and cornea combine to form a single optical element in which transparency and refraction are the fundamental biophysical characteristics required for a functional visual system. Although lens and cornea have different cellular and extracellular specializations that contribute to transparency and refraction, their development is closely related. In the embryonic mouse, the developing cornea and lens separate early. In contrast, zebra fish lens and cornea remain connected during early development and the optical properties of the cornea and lens observed by slit lamp and quasielastic laser light scattering spectroscopy (QLS) are more similar in the zebra fish eye than in the mouse eye. Optical similarities between cornea and lens of zebra fish may be the result of similarities in the cellular development of the cornea and lens.     

Deeper in the human cornea proteome using nanoLC-Orbitrap MS/MS: An improvement for future studies on cornea homeostasis and pathophysiology

The cornea is a transparent, avascular, and highly specialized connective tissue that provides the majority of light refraction in the optical system of the eye. The human cornea is composed of several layers interacting in a complex manner and possessing specific functions, like eye protection and optical clearness. Only few proteomic studies of mammalian cornea have been performed leading to the identification of less than 200 proteins in human corneas. The present study explores the proteome of the intact normal human cornea using a shot-gun nanoLC-MS/MS strategy and an LTQ Orbitrap mass spectrometer. A total of 2070 distinct corneal proteins were identified from five human cornea samples, which represents a 14-fold improvement in the number of proteins identified so far for human cornea. This enlarged dataset of human corneal proteins represents a valuable reference library for further studies on cornea homeostasis and pathophysiology. Network and gene ontology analyses were used to determine biological pathways specific of the human cornea. They allowed the identification of subnetworks of putative importance for corneal diseases, like a redox regulation and oxidative stress network constituted of aldehyde and alcohol dehydrogenases, most of them being described for the first time in human cornea.     

Relationships between Presence of the Eye Cup and Maintenance of Lens-Forming Capacity in Larval Xenopus laevis

The lentectomized eye of larval Xenopus laevis can regenerate a lens by a process of lens-transdifferentiation of the cornea and pericorneal epidermis. These tissues can form the lens only when they become in direct communication with the environment of the vitreous chamber (neural retina) indicating that the eye cup plays a fundamental role in this process.
In this work the role of the eye cup in the maintainance of the lens-forming capacity of the cornea and pericorneal epidermis was studied by allowing these tissues to cover the enucleated orbit for different periods, and then implanting them into the vitreous chamber of the contralateral eye. Under these experimental conditions the maintainance of the lens-forming capacity of the cornea and pericorneal epidermis showed no significant correlation with the time from enucleation to implantation.     

Transdifferentiation of ocular tissues in larval Xenopus laevis

Transdifferentiation phenomena offer a useful opportunity to study experimentally the mechanisms on which cell phenotypic stability depends. The capacities of vertebrate eye tissues to reprogram cell differentiation are well known in avian and mammalian embryos, and in larval and adult newt. From research into the capacity of anuran eye tissues to reprogram differentiation into a new pathway, considerable data have accumulated concerning the transdifferentiative capacities of eye tissues in larval Xenopus laevis. This work reviews the data concerning the transdifferentiative phenomena of eye tissues in that species and, based on these, aims to establish the extent of our knowledge about the mechanism controlling these processes. In larval Xenopus laevis the outer cornea can regenerate a lens by a lens-transdifferentiation process triggered and substained by a factor(s), probably of a protein nature, produced by the neural retina. In a normal eye phenotypic stability of the outer cornea is guaranteed by the presence of the inner cornea and lens, which prevent the spread of retinal factor(s). The stimulus for lens transdifferentiation of the outer cornea can be supplied by other tissues as well, but this capacity is not widely distributed. The iris and retinal pigmented epithelium can transdifferentiate into neural retina if isolated from the surrounding tissues and implanted in the vitreous chamber. As for lens transdifferentiation of the outer cornea, retinal transdifferentiation of the iris can be stimulated by certain nonocular tissues as well.     

Matrices containing glycosaminoglycans in the developing anterior chambers of chick and Xenopus embryonic eyes.

The fibrous matrix present in the anterior chamber of the chick eye on the 4th day of development has been shown by autoradiography and histochemistry to contain chondroitin sulfate, protein, neutral polysaccharides, and possibly hyaluronic acid (HA). Its synthesis, probably by the mesenchyme of the angle of the eye, is completed by around 10 days of development. In the scanning electron microscope (SEM) it can be seen that, although the matrix thins as the eye grows, it does not disappear until the 15th day. The development of the Xenopus cornea is described; this animal has a matrix in its anterior chamber from soon after the formation of the inner cornea (stage 41) until metamorphosis 7 weeks later. In the SEM, this material appears as a dense, featureless aggregate rather than as a matrix of thick fibres; in the transmission electron microscope, it is seen to be a network of fine filaments containing small dark-staining granules. Histochemistry shows that it contains HA, protein, and neutral polysaccharides. The morphological evidence is compatible with the matrix being made by the inner cornea. The probable major role of the matrix is to separate lens from cornea in establishing the anterior chamber. In the chick embryo, at least, the matrix is also likely to help stabilise the endothelium during its formation.     

A lattice model for computing the transmissivity of the cornea and sclera.

The method of photonic band structure is used to calculate the frequencies of light that propagate in lattice models of the cornea and sclera of the mammalian eye, providing an explanation for transparency in the cornea that first properly accounts for multiple scattering of light. Each eye tissue is modeled as an ordered array of collagen rods, and photonic band structure methods are used to solve Maxwell's equations exactly for these models, a procedure that automatically effectively includes all orders of multiple scattering. These calculations show that the dispersion relation for the cornea is linear in the visible range, implying that the cornea is transparent. We show that the transmissivity is approximately 97% by using an effective medium approximation derived from the photonic band structure results and applicable in the visible region. In contrast, the dispersion relation for the model in the sclera is not linear in the visible region, and there are band gaps in this region that could play an important role in the transmission of light in the sclera.     

虻复眼感杆光导的模式与适应状态的关系

利用逆向照明方法,不经角膜中和,通过光学显佩镜快速观察和记录了暗适应,短时间明适应和长时间明适应状态下,虻(Atylotus miser Szilady)复眼感杆光导的模式。同时与角膜中和的实验结果作了比较。本文还讨论了憎黄虻复眼角膜透镜的作用以及该复眼对视觉信憎黄息抽样方式与适应状态的关系。     

Contribution of the cornea to cytokine levels in the whole eye induced during the early phase of Pseudomonas aeruginosa challenge

Pseudomonas aeruginosa keratitis is one of the most destructive diseases of the cornea. The host response to this infection is critical to the outcome, and is regulated by cytokines produced in the ocular tissue. In this study, we assessed the relative contribution of the cytokines produced in the cornea to the inflammatory response of the whole eye to gain a better understanding of the inflammatory and regulatory processes in the ocular environment during localized corneal infection. C57BL/6 mice were challenged by topical application of P. aeruginosa to wounded corneas. Corneas and whole eyes were harvested 24 h post-challenge and bacterial numbers, myeloperoxidase levels and the levels of cytokines known to be important in keratitis were determined. The site of production of IL-6 and KC in the retina was determined by in situ hybridization. Before infection, 90% of macrophage inflammatory protein (MIP)-2 and approximately 80% of all IFN-gamma and IL-10 produced constitutively in the eye was found outside the cornea. Twenty-four hours after infection, bacterial numbers, levels of myeloperoxidase, and levels of MIP-2 and IL-1 were not different, whether measured in cornea or whole eye. However, expression of IL-6, KC, IFN-gamma and IL-10 was significantly greater in whole eyes than in the corneas of infected eyes. The cells expressing IL-6 and KC in the retina were identified by in situ hybridization. This study indicates that during corneal inflammation, the response of the whole eye as well as the cornea needs to be considered.     

Enhancement of RNA labeling in iris and lens by wounding cornea

Lentectomy of the newt eye leads to formation of the lens from the iris. The initial event which occurs in the iris after lentectomy is enhancement of uridine incorporation into RNA. The present data demonstrate that surgery on the cornea without lentectomy enhances uridine incorporation into iris RNA. However, the profile of incorporation after cornea surgery is different from that after lentectomy. Furthermore, cornea surgery fails to cause the high level of incorporation of thymidine into iris which occurs after lentectomy. Cornea surgery also causes enhancement of uridine incorporation into lens RNA with a profile different from that in iris RNA.     

Selenoprotein P Controls Oxidative Stress in Cornea

The ocular surface is always attacked by oxidative stress, and cornea epithelial cells are supposed to have their own recovery system against oxidative stress. Therefore we hypothesized that tears supply key molecules for preventing oxidative stress in cornea. The potential target key molecule we focused is selenoprotein P (SeP). SeP is a carrier of selenium, which is an essential trace element for many animals, for oxidative stress metabolism in the organism, and was extremely expressed in lacrimal gland. An experiment was performed with SeP eye drops in a rat dry eye model, prepared by removing the lacrimal glands. The anticipated improvement in corneal dry eye index and the suppression of oxidative stress markers were observed in SeP eye drop group. Furthermore, the concentration of SeP was significantly higher in dry eye patients compared with normal volunteers. Collectively, we concluded that tear SeP is a key molecule to protect the ocular surface cells against environmental oxidative stress.     

Toll-like receptors and corneal innate immunity

The ocular surface is constantly exposed to a wide array of microorganisms. The ability of the cornea to recognize pathogens as foreign and eliminate them is critical to retain its transparency, hence preservation of sight. In the eye, as in other parts of the body, the early response against invading pathogens is provided by innate immunity. Corneal innate immune system uses a series of pattern recognition receptors to detect the presence of pathogens thus allowing for rapid host defense responses to invading microbes. A key component of such receptors is the "Toll-like receptors" (TLRs), which have come to occupy the center stage in innate immunity against invading pathogens. An increasing number of studies have shown that TLRs are expressed by a variety of tissues and cells of the eye and play an important role in ocular defense against microbial infection. Here in this review we summarize the current knowledge about TLR expression in human eye with main emphasis on the cornea, and discuss the future directions of the field.     

Calcium desorption from the cornea while using complex-forming substances

The time course of calcium desorption from the eye cornea and the efficacy of the use of complex-forming substances during desorption were examined. Experiments with labeled calcium showed an active absorption of the ions by the normal cornea thereby making it turbid. The removal of labeled calcium from an isolated eye and from corneal pieces while using a combination of complex-forming substances and diffusion facilitating-papain was accompanied by the lowering of tissue turbidity. Application of such combinations might eliminate, in some cases, the necessity of surgical operations on the cornea.     

Screening pigment migration in a sphingid moth is triggered by light near the cornea

Summary It is possible to project a horizontal line of light onto a moth's cornea and simultaneously a vertical line onto the retina (Fig. 1). In the dark adapted eye of a sphingid moth (Theretra latreilli) this resulted in the appearance of a horizontal line of pigment across the eye (Fig. 2). This proves that the trigger for pigment migration is near the cornea, presumably in the pigment cells themselves, and not in the receptors.     

Multi-physics modeling and finite element formulation of corneal UV cross-linking

Biomechanics and Modeling in Mechanobiology - The UV cross-linking technique applied to the cornea is a popular and effective therapy for eye diseases such as keratoconus and ectatic disorders. The...     

Corneal transduction by intra-stromal injection of AAV vectors in vivo in the mouse and ex vivo in human explants

The cornea is a transparent, avascular tissue that acts as the major refractive surface of the eye. Corneal transparency, assured by the inner stroma, is vital for this role. Disruption in stromal transparency can occur in some inherited or acquired diseases. As a consequence, light entering the eye is blocked or distorted, leading to decreased visual acuity. Possible treatment for restoring transparency could be via viral-based gene therapy. The stroma is particularly amenable to this strategy due to its immunoprivileged nature and low turnover rate. We assayed the potential of AAV vectors to transduce keratocytes following intra-stromal injection in vivo in the mouse cornea and ex vivo in human explants. In murine and human corneas, we transduced the entire stroma using a single injection, preferentially targeted keratocytes and achieved long-term gene transfer (up to 17 months in vivo in mice). Of the serotypes tested, AAV2/8 was the most promising for gene transfer in both mouse and man. Furthermore, transgene expression could be transiently increased following aggression to the cornea.     

胭脂鱼眼早期形态发生研究

采用组织学方法观察了胭脂鱼(Myxocyprinus asiaticus) 眼的发生过程, 结果显示: 胭脂鱼眼的发育经历了眼原基形成期、眼囊形成期、视杯形成期、晶体板形成期、晶体囊形成期、角膜原基形成期、角膜上皮形成期、视网膜细胞增殖期、晶状体成熟期、眼色素形成期以及眼成型期等11个时期。视网膜发育最早, 起始于眼原基的形成, 直至眼成型期分化完成, 形成了厚度不一的8层细胞, 由内向外依次为神经纤维层、神经细胞层、内网层、内核层、外网层、外核层、视杆视锥层和色素上皮层, 且发育历时最长, 约264h。晶状体的发育在视网膜之后, 始于晶体板的形成, 于出膜前期成熟, 发育历时最短, 约74h。角膜发育最晚, 始于角膜原基的形成, 出膜1 d分化为透明的成熟角膜, 发育历时约96h。出膜4 d仔鱼眼色素沉积明显, 视网膜各层分化明显, 晶状体内部完全纤维化, 眼的形态结构基本发育完全。