A new approach to extend the storage of donor corneas after 28 days of corneal culture in an Italian eye bank.

This study aimed to evaluate the possibility to extend the storage of unused organ-cultured donor corneas. After 28 days of corneal culture in TISSUE-C (AL.CHI.MI.A. S.R.L., Italy) and 5-day storage in transport/deswelling medium CARRY-C (AL.CHI.MI.A. S.R.L., Italy), 25 corneas that were deemed suitable for transplantation were transferred in fresh TISSUE-C at 31 °C for additional 7 days and then in fresh CARRY-C at room temperature for 24 h. Tissues were assessed for endothelial cell density (ECD), endothelial mortality and morphology after the standard and the extended corneal storage. In addition, the effect of donor age < 85 years and ≥ 85 years on corneal characteristics was assessed. After the extended storage, 6 out of 25 tested corneas (24%) showed ECD values below the acceptance limit (< 2000 cells/mm2). 19 corneas (76%) were still suitable for transplantation and showed a 5.9% loss in ECD, which was not statistically significant (P = 0.0949) compared to standard storage period. The two donor age groups did not show statistically significant differences in any tested parameter, although a trend for lower ECD and higher mortality in Descemet's folds after standard storage was observed in the ≥ 85 age donor group. Thus, the attempt of the current study to provide new sight-restorative options for unused tissues and increasing the availability of corneas in case of shortage gave encouraging results. Although a higher vulnerability of corneas from very old donors could not be statistically demonstrated in the present study, higher sample size could be required for prolonging the shelf life of these tissues.

A new storage medium containing amphotericin B versus Optisol-GS for preservation of human donor corneas.

BACKGROUND/AIM: We compared the quality of human donor corneas stored in a cold storage medium containing 2.5 µg/ml of amphotericin B (Kerasave, AL.CHI.MI.A. S.R.L., Ponte San Nicolò, Italy) and Optisol-GS (Bausch & Lomb Inc., Bridgewater, NJ, USA) for 14 days. METHODS: Sixteen pairs of human donor corneas were collected in Eusol-C (AL.CHI.MI.A. S.R.L., Ponte San Nicolò, Italy). Next, all tissues underwent the first evaluation that included the assessments of central corneal thickness (CCT), endothelial cell density (ECD) measured using both trypan blue staining and specular microscopy, endothelial cell (EC) mortality and morphology, and corneal transparency within 24 hours from recovery (Day 1). Afterwards, one cornea of each pair was transferred into Kerasave or Optisol-GS. ECD and CCT were also assessed at Day 7, and all the metrics were evaluated again at the end of the storage period (Day 14). RESULTS: At all tested time points, no differences were found in the qualitative (corneal transparency, EC morphology) and quantitative metrics (ECD, CCT, EC mortality) between the Kerasave and the Optisol-GS storage groups. At Day 14, the corneas stored in Kerasave and Optisol-GS showed ECD of 2312±98 and 2335±128 cells/mm2 (p=0.886), CCT of 717±17 and 697±19 µm (p=0.454) and central EC mortality of 0.54%±0.40% and 0.14%±0.14% (p=0.719), respectively. CONCLUSIONS: The new amphotericin B-containing medium Kerasave was comparable to Optisol-GS in terms of preservation of corneal characteristics at 2-8°C for 14 days.

A fine-tuned ß-catenin regulation during proliferation of corneal endothelial cells revealed using proteomics analysis.

Corneal endothelial (CE) dysfunction is the main indication for corneal transplantation, an invasive procedure with several limitations. Developing novel strategies to re-activate CE regenerative capacity is, therefore, of fundamental importance. This goal has proved to be challenging as corneal endothelial cells (CEnC) are blocked in the G0/G1 phase of the cell cycle in vivo and, albeit retaining proliferative capacity in vitro, this is further hindered by endothelial-to-mesenchymal transition. Herein we investigated the mechanisms regulating CEnC proliferation in vitro. Comparing the proteome of non-proliferating (in vivo-G0/G1) and proliferating (in vitro-G2/M) rabbit CEnC (rCEnC), 77 proteins, out of 3,328 identified, were differentially expressed in the two groups (p < 0.005). Literature and Gene Ontology analysis revealed ß-catenin and transforming growth factor (TGF-ß) pathways to be correlated with the identified proteins. Treatment of rCEnC with a ß-catenin activator and inhibitor showed that ß-catenin activation was necessary during rCEnC proliferation, but not sufficient for its induction. Furthermore, both pro-proliferative activity of basic fibroblast growth factor and anti-proliferative effects of TGF-ß were regulated through ß-catenin. Overall, these results provide novel insights into the molecular basis underlying the proliferation process that CEnC re-activate in vitro, consolidating the role of ß-catenin and TGF-ß.

Method for sterility testing of corneal storage and transport media after removal of interfering antimicrobials: prospective validation study in compliance with the European Pharmacopoeia.

OBJECTIVE: This study aimed at validating the method for sterility testing of the corneal culture medium, TISSUE-C, and the transport/deswelling medium, CARRY-C, according to the method suitability test, as defined by the European Pharmacopoeia (EP), using RESEP, which is a new medical device for removal of antimicrobial agents and an automated culture system. METHODS AND ANALYSIS: The six EP reference strains were inoculated in TISSUE-C and CARRY-C. Half of the samples were treated with RESEP (RESEP+ group) prior to the sterility testing, whereas the remaining samples were untreated (RESEP- group). Growth controls were obtained by direct inoculation of the micro-organisms in the culture broths. Microbial growth was read by an automated light scattering culture system within 48 hours. RESULTS: The use of RESEP allowed detection of microbial growth in 100% of the tested samples, with a mean time to detection (TTD) comparable with that of the growth control group. Significantly lower sensitivity (38.83%±20.03% for both media, P<0.05) and TTD variability, depending on the tested micro-organism, were observed in the RESEP- group. The method specificity was 100% for both groups. CONCLUSION: The use of RESEP increased the sensitivity of the sterility testing method to 100% and, for the first time, allowed validation of the method for sterility testing of corneal storage media according to the EP method suitability test. This further increases the safety of the corneas intended for transplantation.

Inherited Mendelian defects of nuclear-mitochondrial communication affecting the stability of mitochondrial DNA.

The presence of mtDNA abnormalities inherited as Mendelian traits indicates the existence of mutations in nuclear genes affecting the integrity of the mitochondrial genome. Two groups of nucleus-driven abnormalities have been described: qualitative alterations of mtDNA, i.e. multiple large-scale deletions of mtDNA, and quantitative decrease of the mtDNA copy number, i.e. tissue-specific depletion of mtDNA. Autosomal dominant or recessive (adPEO), progressive ophthalmoplegia and autosomal-recessive mitochondrial neurogastrointestinal encephalomyopathy (MNGIE), are three neurodegenerative disorders associated with the coexistence of wild-type mtDNA with several deletion-containing mtDNA species. Heterozygous mutations of the genes encoding the muscle-heart isoform of the adenosine diphosphate/adenosine triphosphate mitochondrial translocator (ANT1), the main subunit of polymerase gamma (POLG1), and of the putative mtDNA helicase (Twinkle) have been found in adPEO families linked to three different loci, on chromosomes 4q34-35, 10q24, and 15q25, respectively. Mutations in the gene encoding thymidine phosphorylase have been identified in several MNGIE patients. Severe, tissue-specific depletion of mtDNA is the molecular hallmark of rapidly progressive hepatopathies or myopathies of infancy and childhood. Two genes, deoxyguanosine kinase and thymidine kinase type 2, both involved in the mitochondrion-specific salvage pathways of deoxynucleotide pools, have been associated with depletion syndromes in selected families.

A donor cornea with metastatic cells from a cutaneous malignant melanoma.

PURPOSE: To describe the case of a donor cornea that showed hematogenous metastatic spread of cutaneous melanoma to the sclerocorneal limbus. METHODS: Corneal tissue obtained from a donor with cutaneous malignant melanoma was evaluated for endothelial cell density, corneal transparency, and epithelial morphology. Subsequently, hematoxylin and eosin staining and immunohistochemical characterization using S100, HMB45, Melan-A, and CD34 antibodies were performed on the corneal sections. RESULTS: The corneal tissue was transparent with high endothelial cell density; it was graded as being suitable for transplantation according to the current eye bank criteria. However, the aggressiveness of the donor's cancer and the diffuse melanosis of the sclera led to the suspicion of malignant melanoma metastasis to the cornea. Histochemical analysis of the corneoscleral rim showed small aggregates rich in pigmented cells that were localized in cleft-like structures in the sclera, at the sclerocorneal interface and in the peripheral avascular portion of the cornea. The aggregates were positive for the melanocytic tumor markers S100, HMB45, and Melan-A; the rims of the clefts expressed the panvascular CD34 antigen, which was suggestive of neovascularization. CONCLUSIONS: Corneal tissue from a donor with malignant cutaneous melanoma displayed neoplastic lesions of melanocytic origin that had spread from a primitive melanoma through hematogenous routes to the sclerocorneal limbus. On the basis of this finding, we believe that having a metastatic cutaneous malignant melanoma could in some cases be reviewed as an exclusionary criterion for undergoing cornea transplantation.

Molecular insight into mitochondrial DNA depletion syndrome in two patients with novel mutations in the deoxyguanosine kinase and thymidine kinase 2 genes.

Thymidine kinase 2 (TK2) and deoxyguanosine kinase (dGK) are the two key enzymes in mitochondrial DNA (mtDNA) precursor synthesis. Deficiencies in TK2 or dGK activity, due to genetic alteration, have been shown to cause tissue-specific depletion of mtDNA. In the case of TK2 deficiency, affected individuals suffer severe myopathy and, in the case of dGK deficiency, devastating liver or multi-systemic disease. Here, we report clinical and biochemical findings from two patients with mtDNA depletion syndrome. Patient A was a compound heterozygote carrying the previously reported T77M mutation and a novel mutation (R161K) in the TK2 gene. Patient B carried a novel mutation (L250S) in the dGK gene. The clinical symptoms of patient A included muscular weakness and exercise intolerance due to a severe mitochondrial myopathy associated with a 92% reduction in mtDNA. There was minimal involvement of other organs. Patient B suffered from rapidly progressive, early onset fatal liver failure associated with profoundly decreased mtDNA levels in liver and, to a lesser extent, in skeletal muscle. Site-directed mutagenesis was used to introduce the mutations detected in patients A and B into the TK2 and dGK cDNAs, respectively. We then characterized each of these recombinant enzymes. Catalytic activities of the three mutant enzymes were reduced to about 2-4% for TK2 and 0.5% for dGK as compared to the wild-type enzymes. Altered competition between dCyd and dThd was observed for the T77M mutant. The residual activities of the two mitochondrial enzymes correlated directly with disease development.

Mutations in AAC2, equivalent to human adPEO-associated ANT1 mutations, lead to defective oxidative phosphorylation in Saccharomyces cerevisiae and affect mitochondrial DNA stability.

Autosomal dominant and recessive forms of progressive external ophthalmoplegia (adPEO and arPEO) are mitochondrial disorders characterized by the presence of multiple deletions of mitochondrial DNA in affected tissues. Four adPEO-associated missense mutations have been identified in the ANT1 gene. In order to investigate their functional consequences on cellular physiology, we introduced three of them at equivalent positions in AAC2, the yeast orthologue of human ANT1. We demonstrate here that expression of the equivalent mutations in aac2-defective haploid strains of Saccharomyces cerevisiae results in (a) a marked growth defect on non-fermentable carbon sources, and (b) a concurrent reduction of the amount of mitochondrial cytochromes, cytochrome c oxidase activity and cellular respiration. The efficiency of ATP and ADP transport was variably affected by the different AAC2 mutations. However, irrespective of the absolute level of activity, the AAC2 pathogenic mutants showed a significant defect in ADP versus ATP transport compared with wild-type AAC2. In order to study whether a dominant phenotype, as in humans, could be observed, the aac2 mutant alleles were also inserted in combination with the endogenous wild-type AAC2 gene. The heteroallelic strains behaved as recessive for oxidative growth and petite-negative phenotype. In contrast, reduction in cytochrome content and increased mtDNA instability appeared to behave as dominant traits in heteroallelic strains. Our results indicate that S. cerevisiae is a suitable in vivo model to study the pathogenicity of the human ANT1 mutations and the pathophysiology leading to impairment of oxidative phosphorylation and damage of mtDNA integrity, as found in adPEO.