Epigenetic silencing of miR-26A1 in chronic lymphocytic leukemia and mantle cell lymphoma: Impact on EZH2 expression

Downregulation of miR26A1 has been reported in various B-cell malignancies; however, the mechanism behind its deregulation remains largely unknown. We investigated miR26A1 methylation and expression levels in a well-characterized series of chronic lymphocytic leukemia (CLL) and mantle cell lymphoma (MCL). From 450K methylation arrays, we first observed miR26A1 (cg26054057) as uniformly hypermethylated in MCL (n = 24) (all >75%), while CLL (n = 18) showed differential methylation between prognostic subgroups. Extended analysis using pyrosequencing confirmed our findings and real-time quantitative PCR verified low miR26A1 expression in both CLL (n = 70) and MCL (n = 38) compared to normal B-cells. Notably, the level of miR26A1 methylation predicted outcome in CLL, with higher levels seen in poor-prognostic, IGHV-unmutated CLL. Since EZH2 was recently reported as a target for miR26A1, we analyzed the expression levels of both miR26A1 and EZH2 in primary CLL samples and observed an inverse correlation. By overexpression of miR26A1 in CLL and MCL cell lines, reduced EZH2 protein levels were observed using both Western blot and flow cytometry. In contrast, methyl-inhibitor treatment led to upregulated miR26A1 expression with a parallel decrease of EZH2 expression. Finally, increased levels of apoptosis were observed in miR26A1-overexpressing cell lines, further underscoring the functional relevance of miR26A1. In summary, we propose that epigenetic silencing of miR26A1 is required for the maintenance of increased levels of EZH2, which in turn translate into a worse outcome, as shown in CLL, highlighting miR26A1 as a tumor suppressor miRNA.     

Studies on the oxidation of hemoglobin Zurich (beta 63 E7 Arg)

Autoxidation and chemically-induced oxidation of hemoglobin Zurich (beta 63 E7 Arg) have been investigated by electron paramagnetic resonance and optical absorption spectroscopy. The results show that the replacement of the distal histidine of the hemoglobin beta chains by an arginine greatly enhances the susceptibility of the heme-iron to oxidative challenge. Both the kinetics and the products of the oxidation are pH dependent. Thus, at acidic and neutral pH, treatment of the protein with ferricyanide leads to a fast conversion of the oxy-protein to aquo-methemoglobin, which, eventually, is slowly converted to hemichromes. In contrast, the hydroxy-met derivative, formed upon chemical oxidation at high pH, is rapidly converted to hemichromes. The electron paramagnetic resonance features of the ferric derivatives of hemoglobin Zurich are somewhat singular, reflecting the modifications of the heme environment in the distal region of the abnormal chains. However, they can be related to heme complexes having their structural counterparts in oxidation products of hemoglobin A.     

Characterization and chromosomal localization of the gene encoding the human cell adhesion molecule uvomorulin

We have isolated an approximately 2.0-kb human cDNA clone containing coding sequences for the human cell adhesion molecule, uvomorulin. Comparison of human and mouse cDNA revealed extensive homology of 82% for the nucleotide and 83% for the deduced amino acid sequence. This and other structural features common to both cDNAs demonstrate that uvomorulin is evolutionarily highly conserved in mammals and underline its functional importance in histogenesis. Moreover, with the use of human x mouse somatic-cell hybrids, the human uvomorulin gene was localized on chromosome 16, in the region 16p11-16qter.     

Bacterial ethylene synthesis from 2-oxo-4-thiobutyric acid and from methionine

The ability of selected bacterial cultures to synthesize ethylene during growth in nutrient broth supplemented with methionine or 2-oxo-4-methylthiobutyric acid (KMBA) was examined. Although most cultures transformed KMBA into ethylene, only those of Escherichia coli SPAO and Chromobacterium violaceum were able to convert exogenously added methionine to ethylene. In chemically defined media, E. coli SPAO produced the highest amounts of ethylene from methionine and KMBA. This capability was affected by the nature of the carbon source and the type and amount of nitrogen source used for growth. When glutamate was used as sole source of carbon and nitrogen for growth, the activity of the ethylenogenic enzymes was reduced to 25% of that observed with cultures grown with glucose and NH4Cl. Neither methionine nor KMBA significantly affected the ethylenogenic capacity of E. coli SPAO. Menadione and paraquat, compounds that generate superoxide radicals, stimulated ethylene synthesis by harvested cells, but not by cell-free extracts of E. coli SPAO. In addition, cells of Pseudomonas aeruginosa, which produced no ethylene in culture in the presence of exogenously added KMBA, yet possessed the necessary enzymes in an active form, were able to synthesize ethylene from KMBA when incubated with menadione or paraquat.     

Heme, as a chaperone, binds to amyloid fibrils and forms peroxidase in vitro: Possible evidence on critical role of non-specific peroxidase activity in neurodegenerative disease onset/progression using the α-crystallin-based experimental system

We report that heme not only displays high binding affinity to the aggregates of crystallin, but also it is effectively able to interfere with this type of aggregation. In the present study, the influence of heme concentration on the crystallin fibrillogenesis was also investigated and experimental evidence of heme’s prevention of crystallin aggregation was provided with the help of spectroscopic measurements. Significantly, using α-crystallin-based experimental system, we proposed that elevated levels of peroxidase activity may have a determinant role in amyloid pathogenesis. The substantial peroxidase activity of “crystallin aggregate-heme” may partially explain the acceleration of oxidative damage in several amyloid-affected neurodegenerative diseases. The present study also suggests that lipid peroxidation accompanying amyloidogenesis may be considered as a major cause in the pathogenesis of amyloid disorders. Since the consequence of heme-amyloid interaction has yet to be identified, additional data on it may help us to manage amyloid aggregation processes.     

Increased Mitochondrial Fatty Acid Oxidation Is Sufficient to Protect Skeletal Muscle Cells from Palmitate-induced Apoptosis

The mechanisms underlying the protective effect of monounsaturated fatty acids (e.g. oleate) against the lipotoxic action of saturated fatty acids (e.g. palmitate) in skeletal muscle cells remain poorly understood. This study aimed to examine the role of mitochondrial long-chain fatty acid (LCFA) oxidation in mediating oleate''s protective effect against palmitate-induced lipotoxicity. CPT1 (carnitine palmitoyltransferase 1), which is the key regulatory enzyme of mitochondrial LCFA oxidation, is inhibited by malonyl-CoA, an intermediate of lipogenesis. We showed that expression of a mutant form of CPT1 (CPT1mt), which is active but insensitive to malonyl-CoA inhibition, in C2C12 myotubes led to increased LCFA oxidation flux even in the presence of high concentrations of glucose and insulin. Furthermore, similar to preincubation with oleate, CPT1mt expression protected muscle cells from palmitate-induced apoptosis and insulin resistance by decreasing the content of deleterious palmitate derivates (i.e. diacylglycerols and ceramides). Oleate preincubation exerted its protective effect by two mechanisms: (i) in contrast to CPT1mt expression, oleate preincubation increased the channeling of palmitate toward triglycerides, as a result of enhanced diacylglycerol acyltransferase 2 expression, and (ii) oleate preincubation promoted palmitate oxidation through increasing CPT1 expression and modulating the activities of acetyl-CoA carboxylase and AMP-activated protein kinase. In conclusion, we demonstrated that targeting mitochondrial LCFA oxidation via CPT1mt expression leads to the same protective effect as oleate preincubation, providing strong evidence that redirecting palmitate metabolism toward oxidation is sufficient to protect against palmitate-induced lipotoxicity.     

Timing of migration dates and detection of first wintering sites for the Turtle Dove in Northwest Africa

The identification of migration dates and wintering zones for migratory birds are key elements for the understanding of the Afro-Palearctic migration system. From 2015 to 2022, a large-scale survey of Turtle Doves Streptopelia turtur, a vulnerable species, was established in Northwest Africa, including Morocco, Algeria, and Tunisia. We monitored migration dates and wintering individuals using the line-transect method. We found that Turtle Doves arrived in the last week of March and left the North African region in mid-October. Compared with Morocco, Doves arrived significantly earlier in Algeria and Tunisia. Moreover, Doves were discovered wintering on nine Northwest African sites, from October to February, where individuals feed in groups. We found that the occurrence probability of wintering Turtle Doves decreased significantly with increasing temperature and rainfall. Birds wintered most often close to wetlands since the overwintering probability decreased with the increasing distance from the recording area to the nearest water body. These are the first and only detailed findings on the migration phenology of the globally vulnerable Turtle Dove in north western Africa.