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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

A critical appraisal of the etiology of adult human lenticular opacification and an investigation into the role of metabolic factors in its pathogenesis

Meyer, David 12 1900 (has links)
Thesis (PhD)--Stellenbosch University, 2001 / ENGLISH ABSTRACT: The eye is that biological instrument which conveys the light of the external world into the inner world of the mind, wherein we receive the miraculous gift of vision. So precious is this gift, that Science must search for ways to keep this portal clear for the flow of light. Indeed, Science is called upon to “make war upon the bloody tyrant, Time.” (Shakespeare W. Sonnet No. 16). For, in the course of ageing, the lens grows cloudy and cataractous. In this battle between Science and Time, we are fortunate to live in an era in which Science is uncovering the molecular basis for the various obstacles to vision. The question arises, whether or not, the ruinous hand of time can be stayed. Due to unrelenting, progressive lens opacification, most of the elderly are destined to be subjected to loss of vision and with passage of time, even blindness. Globally the cataract surgery rate is inadequate to keep pace with the ever growing demand on financial and human resources created by the cataract problem. An immense challenge therefore is directed to primary eye care: “Can cataract be prevented or can its onset at least be postponed?” This laudable ultimate aim can only be achieved once the etiology of cataractogenesis is well understood. This dissertation seeks to examine two previously unrecognized etiological aspects that, if correctly understood and managed, have the potential to achieve preventive ophthalmological goals that may indeed help to stay the ‘ruinous hand of time’. The first aspect deals with the role of lipids and was examined using a study group of dyslipidemic subjects. The first part of the study concluded that dyslipidemic patients develop cortical lens opacities more frequently and at an earlier age than the normal population, and that cortical lens opacities should be regarded as one of the most reliable clinical signs of dyslipidemia. Furthermore, an extremely strong correlation was found to exist between low HDL Cholesterol levels and the development of opacities. Below a HDL-Cholesterol level of 1,5mmol/l, subjects had more than seven-fold higher risk of falling in the lens opacity subgroup than those with HDLCholesterol levels above 1,5mmol/l. An equally strong correlation was demonstrated between high (>5) LDLHDL ratios and the development of lens opacities. Subjects with a LDL:HDL-C ratio below 5 possessed a 2.35 times greater risk of having lenticular opacities than the group with a LDL:HDL-C ratio greater than 5. The prevention or retardation of dyslipidemia associated lens opacities is therefore possible, provided patients with a genetic predisposition are detected early and their blood lipids managed adequately. The second aspect deals with the relationship between age related cataracts and the acetylation status of the individual. This study compellingly submits that the slow acetylator pheno- and genotype may be regarded as a genetic indicator of risk for age related cataract. The ability accurately to classify a patient genotypically and phenotypically, may henceforth be useful in health counseling since, if an individual is identified as being a slow acetylator, additional preventative and precautionary measures may be taken, i.e. the prevention of UVexposure to the eye and caution with the ingestion of xenobiotics like caffeine, commercial dyes, food preservatives, and drugs. Furthermore, such a finding should be taken into account in the long term therapeutic management of glaucoma, with special regard to carbonic anhydrase inhibitors which are sulphonamide-related drugs and totally dependent on the N-acetyltransferase pathway for metabolism. These drugs may accumulate in the slow acetylator over time and exert toxic effects intra-ocularly, conceivably including cataractogenesis. The search for genetic and metabolic mechanisms that may contribute to human cataractogenesis should be pursued with great enthusiasm. This endeavour may help Science to achieve its primary objective, ablate the effects of Time and really aid in preventing cataracts in man. / AFRIKAANSE OPSOMMING: Die wondergawe van visie word vir ons moontlik gemaak deur die oog wat as biologiese instrument die lig van die buitewereld inlaat na die binnewereld van die brein. So kosbaar is hierdie gawe dat die Wetenskap deurgaans moet poog om die poort oop te hou. Inteendeel, die Wetenskap word gemaan deur Shakespeare in sy Sonnet nommer 16 om “oorlog te maak teen die bloeddorstige tiran, Tyd”. Soos ‘n mens ouer word, word die lens dof en ‘n katarak mag vorm. Ten spyte van hierdie stryd tussen ‘Wetenskap’ en ‘Tyd’ leef ons in die gelukkige era waarin die Wetenskap meer en meer leer van die verskeie obstruksies tot visie. Die vraag ontstaan of die rinnewerende hand van ‘Tyd’ gestuit sal kan word. Vanwee ongenaakbare, progressiewe lensvertroebeling is die meeste bejaardes bestem om aan visie verlies, en met verloop van tyd selfs blindheid, te ly. Die wereldwye katarakchirurgie tempo is nie voldoende om by te hou by die immergroeiende finansiele en mannekrag eise wat deur die katarak probleem gestel word nie. Daar word dus ‘n reuse uitdaging aan primere oogsorg gestel naamlik: “Kan katarakte nie eerder voorkom of die aanvang daarvan ten minste uitgestel word nie?” Hierdie prysenswaardige doelwit kan nie bereik word alvorens die etiologie van kataraktogenese goed verstaan word nie. Hierdie tesis ondersoek twee voorheen onerkende etiologiese aspekte wat, indien hulle korrek verstaan en hanteer word, beslis die potensiaal het om die gemelde voorkomende doelwitte te bereik en sekerlik te kan bydrae om die rinnewerende hand van Tyd te stuit. Die eerste aspek spreek die rol van lipiede aan deur te kyk na 'n studiegroep van dislipidemiese persone. Die eerste deel van die studie kom tot die gevolgtrekking dat dislipidemiese pasiente kortikale lens opasiteite meer dikwels en op ‘n vroeer ouderdom ontwikkel as die normale populasie en dat sulke opasiteite beskou moet word as een van die mees betroubare kliniese tekens van dislipidemie. Daar is ook ‘n baie sterk korrelasie gevind tussen lae HDL cholesterol vlakke en die voorkoms van opasiteite. Persone in die studie met ‘n HDL cholesterol vlak laer as 1,5mmol/l het ‘n sewe keer hoer kans gehad om in die lensopasiteit subgroep te val as die met ‘n HDL cholesterol vlak laer as 1,5mmol/l. ‘n Sterk korrelasie tussen ‘n hoe (>5) LDLHDL verhouding en die voorkoms van lens opasiteite is ook gevind. Persone met ‘n LDLHDL verhouding >5 het ‘n 2.35 maal groter risiko gehad om lensopasiteite te he as die met ‘n LDL:HDL verhouding van <5. Die voorkoming of vertraging van dislipiedemie geassosieerde lens opasiteite is dus moontlik, solank persone met ‘n genetiese geneigdheid daartoe vroeg ontdek en hulle bloedlipiede voldoende beheer word. Die tweede deel van die tesis handel oor die verhouding tussen ouderdoms verwante katarakte en die asetilasie status van die individu. Met oortuiging kom hierdie studie tot die gevolgtrekking dat die stadige asetilator fenoen genotipe as 'n genetiese merker vir ouderdoms verwante katarakte beskou moet word. Die vermoe om ‘n individu beide genotipies en fenotipies akkuraat te klassifiseer mag voorts bruikbaar wees in gesondheidsraadgewing. Indien ‘n individu geTdentifiseer is as ‘n stadige asetileerder, kan addisionele voorsorg maatreels getref word soos bv. die voorkoming van blootstelling van die oog aan UV lig sowel as omsigtigheid met die inname van xenobiotika soos kaffei'ene, kleurstowwe, voedsel preserveermiddels en geneesmiddels. Hierdie bevinding moet ook in berekening gebring word in die langtermyn terapeutiese hantering van gloukoom. Die koolsuuranhidrase inhibitore, dikwels gebruik in die behandeling van gloukoom, is sulfonamied-agtige middels en dus totaal afhanklik van die N-asetieltransferase pad vir hulle metabolisme. Hierdie middels kan ophoop in die stadige asetileerder en gegewe genoeg tyd, bes moontlik toksiese intra-okulere effekte tot gevolg he. Die soeke na genetiese en metaboliese meganismes wat mag bydra tot menslike kataraktogenese behoort nagestreef te word met groot entoesiasme. Hierdie strewe mag dalk net vir die 'Wetenskap' bystaan om sy primere mikpunt te bereik, die effek van ‘Tyd’ te neutraliseer en te help om katarakte werklik te voorkom.
2

Mitochondrial regulation pathways in the lens: pink1/parkin- and bnip3l-mediated mechanisms

Unknown Date (has links)
The mitochondrion is the powerhouse of the cell. Therefore, it is critical to the homeostasis of the cell that populations of mitochondria that are damaged or in excess are degraded. The process of targeted elimination of damaged or excess mitochondria by autophagy is called mitophagy. In this report, analysis of the mitophagy regulators PINK1/PARKIN and BNIP3L and their roles are assessed in the lens. PARKIN, an E3 ubiquitin ligase, has been shown to play a role in directing damaged mitochondria for degradation. While BNIP3L, an outer mitochondrial membrane protein, increases in expression in response to excess mitochondria and organelle degradation during cellular differentiation. We have shown that PARKIN is both induced and translocates from the cytoplasm to the mitochondria in human epithelial lens cells upon oxidative stress exposure. In addition, our findings also show that overexpression of BNIP3L causes premature clearance of mitochondria and other organelles, while loss of BNIP3L results in lack of clearance. Prior to this work, PARKIN mediated mitophagy had not been shown to act as a protective cellular response to oxidative stress in the lens. This project also resulted in the novel finding that BNIP3L-mediated mitophagy mechanisms are required for targeted organelle degradation in the lens. / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2015 / FAU Electronic Theses and Dissertations Collection
3

aB- crystallin/sHSP is required for mitochondrial function in human ocular tissue

Unknown Date (has links)
by Rebecca McGreal. / Vita. / Thesis (Ph.D.)--Florida Atlantic University, 2012. / Includes bibliography. / Electronic reproduction. Boca Raton, Fla., 2012. Mode of access: World Wide Web. / The central premise of this dissertation is that the small heat shock protein (sHSP), (Sa(BB-crystallin is essential for lens and retinal pigmented epithelial (RPE) cell function and oxidative stress defense. To date, the mechanism by which it confers protection is not known. We hypothesize that these functions could occur through its ability to protect mitochondrial function in lens and RPE cells. To test this hypothesis, we examined the expression of (Sa(BB-crystallin/sHSP in lens and RPE cells, we observed its localization in the cells, we examined translocation to the mitochondria in these cells upon oxidative stress treatment, we determined its ability to form complexes with and protect cytochrome c (cyt c) against damage, and we observed its ability to preserve mitochondrial function under oxidative stress conditions in lens and RPE cells. In addition to these studies, we examined the effect of mutations of (Sa(BB-crystallin/sHSP on its cellular localization and translocation patterns under oxidative stress, its in vivo and in vitro chaperone activity, and its ability to protect cyt c against oxidation. Our data demonstrated that (Sa(BB-crystallin/sHSP is expressed at high levels in the mitochondria of lens and RPE cells and specifically translocates to the mitochondria under oxidative stress conditions. We demonstrate that (Sa(BB-crystallin/sHSP complexes with cyt c and protects it against oxidative inactivation. Finally, we demonstrate that (Sa(BB-crystallin/sHSP directly protects mitochondria against oxidative inactivation in lens and RPE cells. Since oxidative stress is a key component of lens cataract formation and age-related macular degeneration (AMD), these data provide a new paradigm for understanding the etiology of these diseases.
4

Developmental and Protective Mechanisms of the Ocular Lens.

Unknown Date (has links)
The vertebrate eye lens functions to focus light onto the retina to produce vision. The lens is composed of an anterior monolayer of cuboidal epithelial cells that overlie a core of organelle free fiber cells. The lens develops and grows throughout life by the successive layering of lens fiber cells via their differentiation from lens epithelial cells. Lens developmental defect and damage to the lens are associated with cataract formation, an opacity of the lens that is a leading cause of visual impairment worldwide. The only treatment to date for cataract is by surgery. Elucidating those molecules and mechanisms that regulate the development and lifelong protection of the lens is critical toward the development of future therapies to prevent or treat cataract. To determine those molecules and mechanisms that may be important for these lens requirements we employed high-throughput RNA sequencing of microdissected differentiation statespecific lens cells to identify an extensive range of transcripts encoding proteins expressed by these functionally distinct cell types. Using this data, we identified differentiation state-specific molecules that regulate mitochondrial populations between lens epithelial cells that require the maintenance of a functional population of mitochondria and lens fiber cells that must eliminate their mitochondria for their maturation. In addition, we discovered a novel mechanism for how lens epithelial cells clear apoptotic cell debris that could arise from damage to the lens and found that UVlight likely compromises this system. Moreover, the data herein provide a framework to determine novel lens cell differentiation state-specific mechanisms. Future studies are required to determine the requirements of the identified molecules and mechanisms during lens development, lens defense against damage, and cataract formation. / Includes bibliography. / Dissertation (Ph.D.)--Florida Atlantic University, 2016. / FAU Electronic Theses and Dissertations Collection

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