Haematological and histological changes in fish Heteropneustes fossilis exposed to pesticides from industrial waste water

The present study investigated the potential changes in hematologic parameters and histology of fish Heteropneustes fossilis when exposed to industrial waste water of different concentrations. The toxicant enter into the fish body from different rout, inhalation, dermal oral, and other several rout for entering in the fish body. The blood parameters of fish H. fossilis control group and treatment were investigated on 1st, 5th, 10th, and 20th days of experiment, hematologic variation was observed in RBC, WBC, MCV, MCH, and MCHC count. Histopathologic changes in liver, intestine, gill, muscle, and heart showed increasing degrees of damage in the tissues in correlation with the accumulation pattern of pesticides, while liver, intestine, gill, muscle, and heart of control group exhibited a normal architecture. Toxic effects of pesticides vary in different organs of the fish H. fossilis significant. The fish exposed to higher concentration showed uncoordinated alterations in behavioral responses, especially erratic and jerky swimming, physiologic, malformation, histologic, hematologic and biochemical changes, frequent surfacing and in gulping, mucus secretion, an increase in opercular movement, and copious secretion of mucus of all over the body.     

Long-acting peptidomimetics based DPP-IV inhibitors

Pyrrolidine based peptidomimetics are reported as potent and selective DPP-IV inhibitors for the treatment of T2DM. Compounds 16c and 16d showed excellent in vitro potency and selectivity towards DPP-IV and the lead compound 16c showed sustained antihyperglycemic effects, along with improved pharmacokinetic profile.     

De-differentiation of primary human hepatocytes depends on the composition of specialized liver basement membrane

Despite the understanding of the importance of mitogen-activated protein (MAP) kinase activation in the stimulation of growth, little is known about the role of MAP kinase regulation during contact inhibited growth control. To investigate the role of the MAP kinase extracellular signal-regulated kinase (ERK) during the transition to a contact inhibited state, cultures of normal fibroblasts (BJ) were grown to different stages of confluency. The levels of MAP kinase phosphatase (MKP) expression and the amount of active ERK and MAP ERK kinase (MEK) in these cultures were assessed through western blot analysis and were compared to fibrosarcoma cell cultures (HT-1080), which lack contact inhibition. In normal fibroblasts, the amounts of active MEK and ERK decline at contact inhibition, concurrently with a rise in MKP-1, MKP-2, and MKP-3 protein levels. In contrast, fibrosarcoma cells appear to lack density-dependent regulation of the ERK pathway. Additionally, altering the redox environment of fibrosarcoma cells to a less reducing state, as seen during contact inhibition, results in increased MKP-1 expression. Taken together, these results suggest that the altered redox environment upon contact inhibition may contribute to the regulation of ERK inactivation by MKPs.     

Biophysical studies with parallel stranded oligoduplex

The thermal denaturation profiles of parallel stranded oligoduplexes during UV-spectroscopy and fluorescence spectroscopy, for the first time, were shown to follow the similar patterns as were described for antiparallel stranded oligoduplexes. The B-form structure of these center-bubble-forming oligoduplexes was determined with circular dichroism. Thermodynamic properties were also discussed.     

Novel derivatives of ISO-1 as potent inhibitors of MIF biological function

A series of novel 1,2,4-oxadiazole, phthalimide, amide and other derivatives of ISO-1 were synthesized and probed for inhibition of macrophage migration inhibitory factor (MIF) activity. Several compounds inhibited MIF enzymatic activity at levels better than ISO-1. Of note, compounds 7, 22, 23, 24, 25 and 27 inhibited the spontaneous secretion/release/recognition of MIF from freshly isolated human peripheral blood mononuclear cells and, more importantly, inhibited the MIF-induced production of interleukin-6 (IL-6) and/or interleukin-1β (IL-1β) significantly better than ISO-1.     

Catechin and Catechin Fractions as Biochemical Markers to Study the Diversity of Indian Tea (Camellia sinensis (L.) O. Kuntze) Germplasm

The heterogeneous Indian tea germplasm includes ‘China’, ‘Assam’, ‘Cambod’, and their hybrids which were evaluated using biochemical markers viz., total catechin and their fractions, for varietal identification and characterization. Principal component analysis (PCA) of biochemical characters showed that the total catechin and trihydroxylated catechin has higher eigenvalues. The first two principal components (PCs) could differentiate more than 90% of the clones studied. This grouping based on first two principal component matrices differentiated ‘China’, and their hybrids with ‘Assam’ and ‘Cambod’ variety. Morphologically indistinct large‐leaved ‘Cambod’ variety and ‘Assam’ varieties could not be differentiated using biochemical markers, since both varietal types taxonomically belong to a single species. Clones of ‘China’ type showed low total catechin content and catechin ratio which are distinctly grouped. The ‘China–Assam’ and ‘China–Cambod’ hybrids formed intermediate groups between ‘China’ PC group and ‘Cambod’/‘Assam’ PC groups, providing evidence for genetic control of catechin ratio variation. Tea clones which are differentially positioned in the PC group could be explained based on the genetic contribution by other varietal type as parents. This biochemical characterization will be a useful tool in the development of quality‐tea clones with different proportion of total catechin and their fractions.     

Synthesis, calorimetric studies, and crystal structures of N, O-diacylethanolamines with matched chains

Recent studies show that N-, O-diacylethanolamines (DAEs) can be derived by the O-acylation of N-acylethanolamines (NAEs) under physiological conditions. Because the content of NAEs in a variety of organisms increases in response to stress, it is likely that DAEs may also be present in biomembranes. In view of this, a homologous series of DAEs with matched acyl chains (n = 10–20) have been synthesized and characterized. Transition enthalpies and entropies obtained from differential scanning calorimetry show that dry DAEs with even and odd acyl chains independently exhibit linear dependence on the chainlength. Linear least-squares analyses yielded incremental values contributed by each methylene group to the transition enthalpy and entropy and the corresponding end contributions. N-, O-Didecanoylethanolamine (DDEA), N-, O-dilauroylethanolamine (DLEA), and N-, O-dimyristoylethanolamine (DMEA) crystallized in the orthorhombic space group Pbc₂₁ with four symmetry-related molecules in the unit cell. Single-crystal X-ray diffraction studies show that DDEA, DLEA, and DMEA are isostructural and adopt an L-shaped structure with the N-acyl chain and the central ethanolamine moiety being essentially identical to the structure of N-acylethanolamines, whereas the O-acyl chain is linear with all-trans conformation. In all three DAEs, the lipid molecules are organized in a bilayer fashion wherein the N-acyl and O-acyl chains from adjacent layers oppose each other.     

DDB2, an Essential Mediator of Premature Senescence

Reactive oxygen species (ROS) is critical for premature senescence, a process significant in tumor suppression and cancer therapy. Here, we reveal a novel function of the nucleotide excision repair protein DDB2 in the accumulation of ROS in a manner that is essential for premature senescence. DDB2-deficient cells fail to undergo premature senescence induced by culture shock, exogenous oxidative stress, oncogenic stress, or DNA damage. These cells do not accumulate ROS following DNA damage. The lack of ROS accumulation in DDB2 deficiency results from high-level expression of the antioxidant genes in vitro and in vivo. DDB2 represses antioxidant genes by recruiting Cul4A and Suv39h and by increasing histone-H3K9 trimethylation. Moreover, expression of DDB2 also is induced by ROS. Together, our results show that, upon oxidative stress, DDB2 functions in a positive feedback loop by repressing the antioxidant genes to cause persistent accumulation of ROS and induce premature senescence.DDB2 is encoded by the nucleotide excision repair (NER) XPE gene (17, 24, 33). Unlike other NER gene-deficient cells or xeroderma pigmentosum (XP) cells, the XPE cells exhibit only a mild deficiency in NER (55). However, because of its high affinity for cyclobutane pyrimidine dimers (CPDs) and 6-4 photoproducts, several studies implicated DDB2 in the early damaged-DNA recognition step of NER (61). However, a direct role of DDB2 in NER is a point of controversy (28, 41, 57). Lower organisms (yeasts), in which other XP genes are conserved, apparently do not encode a DDB2 homolog (55, 64). We showed that DDB2 associates with Cul4, a component of an E3 ubiquitin ligase complex that is now known to involve the DDB2 binding protein DDB1 as its adapter (48). The Cul4-DDB1 E3 ligase associates with a number of substrate-specific adapter proteins to target substrates for ubiquitination (30, 35). DDB2 is believed to be one of those substrate adapters, which allows Cul4-DDB1 to target specific proteins. Two studies suggested that the Cul4A-DDB1-DDB2 complex could participate in the ubiquitination of histones, indicating a role of DDB2 in chromatin remodeling (23, 59). Other investigators suggested a role of Cul4A-DDB1-DDB2 in the ubiquitination of XPC (15, 52). We recently found that DDB2 is involved also in targeting p21 for proteolysis and demonstrated that DDB2 stimulated NER by regulating the level of p21 (51).It was shown elsewhere that DDB2^−/− mouse embryonic fibroblasts (MEFs) are resistant to UV-induced apoptosis (20, 21). Recently, we extended those observations by demonstrating that DDB2^−/− MEFs or DDB2-deficient human cells are resistant to apoptosis induced by a variety of DNA-damaging agents (50). Moreover, DDB2^−/− MEFs are deficient in E2F1-induced apoptosis. The resistance to apoptosis is linked also to high-level accumulation of p21 because deletion of p21 restored apoptosis. The polyubiquitination of p21 is significantly reduced in DDB2-deficient cells (50), suggesting that after DNA damage DDB2 plays a key role in polyubiquitinating p21. Also, we observed evidence for a physical association between DDB2 and p21, which was increased in UV-irradiated cells (50), indicating that DDB2 plays a direct role in targeting p21 for proteolysis after DNA damage. These observations provided evidence that DDB2, in addition to stimulating NER, plays a significant role in terminating DNA damage checkpoint, allowing cells with extensive DNA damage to undergo apoptosis.In addition to its role in the inhibition of cell cycle and apoptosis, p21 has been implicated also in cellular senescence, as its level increases in senescent cells (7). Cellular senescence is defined as a proliferative arrest of a cell after a limited number of cell divisions while the cell remains metabolically and synthetically active (6, 63). Senescence can be triggered by both extrinsic factors such as oncogenic stress, DNA damage, oxidative stress, and culture shock and intrinsic factors such as telomere regression in human cells (19). When grown in cell culture medium, human diploid fibroblasts undergo 60 to 80 population doublings, after which they cease proliferation as a result of telomere erosion and enter into the stage of replicative senescence characterized by enlarged and flattened morphology, increased granularity, and enhanced senescence-associated β-galactosidase (SA-β-Gal) activity (13). In contrast, telomere length does not limit the ability of the murine fibroblasts to proliferate in culture. It was shown that the supraphysiological level of oxygen or reactive oxygen species (ROS) under which the cells are grown led murine fibroblasts to senesce (39). ROS accumulation or oxidative stress induces the senescent phenotype in response to oncogenic stress as well as in response to DNA-damaging agents (56). These pathways have been termed premature senescence, which recapitulates molecular features of replicative senescence. Premature senescence induced by oncogene expression is a significant mechanism of tumor suppression involving the Ink4a/Arf locus (47). Moreover, DNA damage-induced premature senescence is significant, as many anticancer drugs have been shown to induce premature senescence of tumor cells (12, 44).Because DDB2^−/− MEFs express p21 at a high level, we expected those cells to undergo premature senescence at an earlier passage than the wild-type (WT) MEFs. Surprisingly, we found that DDB2^−/− MEFs escape senescence at a very high frequency. Moreover, DDB2^−/− MEFs or DDB2-deficient human cells are resistant to premature senescence induced by a variety of agents, including oncogenic stress, exogenous oxidative stress, and DNA damage. The lack of premature senescence in the presence of high-level p21, especially after DNA damage, suggests that DDB2 functions in the senescence program through a mechanism that is downstream of the p21 pathway senescence. Here we show that DDB2 participates in the senescence program by inducing persistent accumulation of ROS.