<Emphasis Type="Italic">Fusarium sacchari</Emphasis>: A Cause of Exogenous Fungal Endophthalmitis: First Case Report and Review of Literature

A case of exogenous fungal endophthalmitis due to Fusarium sacchari is being reported. It has never been reported in this clinical entity before; hence, to the best of our knowledge, this is first report of F. sacchari as a cause of exogenous fungal endophthalmitis and also the first time when this fungus has been isolated from an Indian patient.     

Energy determinants GAPDH and NDPK act as genetic modifiers for hepatocyte inclusion formation

Genetic factors impact liver injury susceptibility and disease progression. Prominent histological features of some chronic human liver diseases are hepatocyte ballooning and Mallory-Denk bodies. In mice, these features are induced by 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) in a strain-dependent manner, with the C57BL and C3H strains showing high and low susceptibility, respectively. To identify modifiers of DDC-induced liver injury, we compared C57BL and C3H mice using proteomic, biochemical, and cell biological tools. DDC elevated reactive oxygen species (ROS) and oxidative stress enzymes preferentially in C57BL livers and isolated hepatocytes. C57BL livers and hepatocytes also manifested significant down-regulation, aggregation, and nuclear translocation of glyceraldehyde 3-phosphate dehydrogenase (GAPDH). GAPDH knockdown depleted bioenergetic and antioxidant enzymes and elevated hepatocyte ROS, whereas GAPDH overexpression decreased hepatocyte ROS. On the other hand, C3H livers had higher expression and activity of the energy-generating nucleoside-diphosphate kinase (NDPK), and knockdown of hepatocyte NDPK augmented DDC-induced ROS formation. Consistent with these findings, cirrhotic, but not normal, human livers contained GAPDH aggregates and NDPK complexes. We propose that GAPDH and NDPK are genetic modifiers of murine DDC-induced liver injury and potentially human liver disease.     

Transplanted embryonic stem cells following mouse myocardial infarction inhibit apoptosis and cardiac remodeling

We have previously shown that mouse embryonic stem (ES) cells transplanted following myocardial infarction (MI) differentiate into the major cell types in the heart and improve cardiac function. However, the extent of regeneration was relatively meager compared with the observed functional improvement. Therefore, we hypothesize that mechanisms in addition to regeneration contribute to the functional improvement from ES cell therapy. In this study, we examined the effect of mouse ES cells transplanted post-MI on cardiac apoptosis, fibrosis, and hypertrophy. MI was produced by left coronary artery ligation in C57BL/6 mice. Two different mouse ES cell lines, expressing enhanced green fluorescent protein and beta-galactosidase, respectively, were tested. Post-MI intramyocardial injection of 3 x 10(4) ES cells was compared with injection of medium alone. Terminal deoxynucleotidyl nick end labeling (TUNEL), immunofluorescence, and histology were used to examine the effect of transplanted ES cells on apoptosis, fibrosis, and hypertrophy. Two weeks post-MI, ES cell-transplanted hearts exhibited a significant decrease in TUNEL-stained nuclei (mean +/- SE; MI+medium = 12 +/- 1.5%; MI+ES cells = 6.6 +/- 1%, P < 0.05). TUNEL-positive nuclei were confirmed to be apoptotic by colabeling with a caspase-3 antibody. Cardiac fibrosis was 57% less in the MI+ES cell group compared with the MI + medium group (P < 0.05) as shown with Masson's trichrome staining. Picrosirius red staining confirmed a decreased amount of collagen present in the MI+ES cell group. Cardiomyocyte hypertrophy was significantly decreased following ES cell transplantation compared with medium control animals. In conclusion, transplanted mouse ES cells in the infarcted heart inhibit apoptosis, fibrosis, and hypertrophy, thereby reducing adverse remodeling.     

p38 and ERK1/2 MAPKs mediate the interplay of TNF-alpha and IL-10 in regulating oxidative stress and cardiac myocyte apoptosis

It is known that TNF-alpha increases the production of ROS and decreases antioxidant enzymes, resulting in an increase in oxidative stress. IL-10 appears to modulate these effects. The present study investigated the role of p38 and ERK1/2 MAPKs in mediating the interplay of TNF-alpha and IL-10 in regulating oxidative stress and cardiac myocyte apoptosis in Sprague-Dawley male rats. Isolated adult cardiac myocytes were exposed to TNF-alpha (10 ng/ml), IL-10 (10 ng/ml), and IL-10 + TNF-alpha (ratio 1) for 4 h. H(2)O(2) (100 microM) as a positive control and the antioxidant Trolox (20 micromol/l) were used to confirm the involvement of oxidative stress. H(2)O(2) treatment increased oxidative stress and apoptosis; TNF-alpha mimicked these effects. Exposure to TNF-alpha significantly increased ROS production, caused cell injury, and increased the number of apoptotic cells and Bax-to-Bcl-xl ratio. This change was associated with an increase in the phospho-p38 MAPK-to-total p38 MAPK ratio and a decrease in the phospho-ERK1/2-to-total ERK1/2 ratio. IL-10 treatment by itself had no effect on these parameters, but it prevented the above-listed changes caused by TNF-alpha. The antioxidant Trolox modulated TNF-alpha-induced changes in Bax/Bcl-xl, cell injury, and MAPKs. Preexposure of cells to the p38 MAPK inhibitor SB-203580 prevented TNF-alpha-induced changes. Inhibition of the ERK pathway with PD-98059 attenuated the protective role of IL-10 against TNF-alpha-induced apoptosis. This study provides evidence in support of the essential role of p38 and ERK1/2 MAPKs in the interactive role of TNF-alpha and IL-10 in cardiac myocyte apoptosis.     

Trichostatin A alters the expression of cell cycle controlling genes and microRNAs in donor cells and subsequently improves the yield and quality of cloned bovine embryos in vitro

Trichostatin A (TSA), a histone deacetylase inhibitor, has been used to improve nuclear reprogramming in somatic cell nuclear transfer embryos. However, the molecular mechanism of TSA for the improvement of the pre- and postimplantation embryonic development is unknown. In the present study, we investigated mechanism of cell cycle arrest caused by TSA and also determined embryo quality and gene expression in cloned bovine embryos produced from TSA-treated donor cells compared with embryos produced by in vitro fertilization or parthenogenetic activation. We observed that, 50 nM TSA-treated cells were synchronized at G0/G1 stage with concomitant decrease in the proportion of these cells in the S stage of the cell cycle, which was also supported by significant changes in cell morphology and decreased proliferation (P < 0.05). Measurement of relative expression using real-time polymerase chain reaction of a some cell cycle–related genes and microRNAs in treated donor cells showed decreased expression of HDAC1, DNMT1, P53, CYC E1, and CDK4 and increased expression of DNMT3a, CDKN1A, CDK2, CDK3, miR-15a, miR-16, and miR-34a (P < 0.05). No change in the relative expression of miR-449a was noticed. Trichostatin A treatment of donor cells significantly improved both cleavage and blastocyst rate (P < 0.05) compared with the control embryos, also apoptotic index in treated cloned blastocysts was significantly decreased compared with the nontreated blastocysts (P < 0.05) and was at the level of IVF counterpart. Relative expression of HDAC1 and DNMT3a was significantly lower in treated cloned and parthenogenetic embryos than that of nontreated and IVF counterpart, whereas in case of P53, expression level between treated and IVF embryos was similar, which was significantly lower than nontreated cloned and parthenogenetic embryos. In conclusion, our data suggested that TSA improves yield and quality of cloned bovine embryos by modulating the expression of G0/G1 cell cycle stage–related microRNA in donor cells, which support that TSA might be great cell cycle synchronizer apart from potent epigenetic modulator in cloning research in future.     

Analysis of emergence stage facilitates the evaluation of chickpea (Cicer arietinum L.) genotypes for salinity tolerance imparted by mycorrhizal colonization

Salinity is an ever-increasing constraint limiting crop production in arid and semi-arid regions. Arbuscular mycorrhiza (AM) helps host plant to cope with detrimental effects of salinity. Experiments were aimed to examine the hypothesis that emergence is a better stage to determine salt tolerance of chickpea genotypes than germination and genotypic variability in their tolerance ability at emergence and subsequent vegetative growth is the manifestation of differential benefits imparted by mycorrhiza. Investigations were carried out at germination and emergence stage of genotypes (PBG 5, GPF 2, PBG 1, BG 1053, L 550) at 0, 40, 60, 80 mM NaCl. Significant genotypic variations in salt tolerance were observed at emergence rather than germination because of greater inhibitory effects on seedling emergence. Percent mycorrhizal colonization (MC) and its resulting impact on respiration rate (RR) and salt tolerance index (STI) at emergence indicated that PBG 5, with lowest RR, highest STI and mycorrhiza benefit percentage was the most tolerant whereas, L 550 the most sensitive genotype. Genotypic variability recorded at 30 days was consistent with that at emergence stage. Superior salt tolerance of PBG 5 than L 550 could be attributed to higher correlation between MC and physio-biochemical traits (RWC, chlorophyll a/b, proline accumulation, antioxidant activities). The study supported the hypothesis that both emergence stage and mycorrhizal effectiveness are important determinants of salt tolerance in chickpea genotypes. Evaluation of genotypes for relative adaptation to salinity should include estimation of their differential salt tolerance at different growth stages and symbiotic effectiveness of AM .