Chandramani Pathak

Queuine promotes antioxidant defence system by activating cellular antioxidant enzyme activities in cancer

Constant generation of Reactive oxygen species (ROS) during normal cellular metabolism of an organism is generally balanced by similar rate of consumption by antioxidants. Imbalance between ROS production and antioxidant defense results in increased level of ROS causing oxidative stress which leads to promotion of malignancy. Queuine is a hyper modified base analogue of guanine, found at first anti-codon position of Q- family of tRNAs. These tRNAs are completely modified with respect to queuosine in terminally differentiated somatic cells, however hypomodification of Q-tRNAs is close association with cell proliferation. Q-tRNA modification is essential for normal development, differentiation and cellular functions. Queuine is a nutrient factor to eukaryotes. It is found to promote cellular antioxidant defense system and inhibit tumorigenesis. The activities of antioxidant enzymes like catalase, SOD, glutathione peroxidase and glutathione reductase are found to be low in Daltons lymphoma ascites transplanted (DLAT) mouse liver compared to normal. However, exogenous administration of queuine to DLAT mouse improves the activities of antioxidant enzymes. The results suggest that queuine promotes antioxidant defense system by increasing antioxidant enzyme activities and in turn inhibits oxidative stress and tumorigenesis.

Modulation of Lactate Dehydrogenase Isozymes by Modified Base Queuine

The modified base queuine is a nutrient factor for lower and higher eukaryotes except yeast. It is synthesized in eubacteria and inserted into the wobble position of specific tRNAs (tRNAGUN) in exchange of guanine at position 34. The tRNAs of Q family are completely modified in terminally differentiated somatic cells. However, mainly free queuine is present in embryonic and fast proliferating cells, tRNA remains Q deficient. Lactate dehydrogenase (LDH) A mRNA and LDH A protein is known to increase when cells are grown in hypoxic conditions. In the present study, the level of LDH isozymes is analyzed in different tissues of normal and cancerous (DLA) mice and the effect of queuine treatment on LDH isozyme is observed. LDH A isozyme is shown to increase in serum and liver of DLA mice. The level and activity of LDH A decreases on queuine treatment. In skeletal muscle and heart, LDH A isozyme decreases while LDH B increases in DLA mice. Queuine administration leads to change back towards normal. In case of brain, LDH A increases but LDH B decreases in DLA mice. Queuine treatment leads to decrease in A4 anaerobic isozymes of LDH. The results suggest that queuine suppresses anaerobic glycolytic pathway, which leads to tumor suppression of DLA mice.

Curcumin Conjugated with PLGA Potentiates Sustainability, Anti-Proliferative Activity and Apoptosis in Human Colon Carcinoma Cells

Curcumin, an ingredient of turmeric, exhibits a variety of biological activities such as anti-inflammatory, anti-atherosclerotic, anti-proliferative, anti-oxidant, anti-cancer and anti-metastatic. It is a highly pleiotropic molecule that inhibits cell proliferation and induces apoptosis in cancer cells. Despite its imperative biological activities, chemical instability, photo-instability and poor bioavailability limits its utilization as an effective therapeutic agent. Therefore, enhancing the bioavailability of curcumin may improve its therapeutic index for clinical setting. In the present study, we have conjugated curcumin with a biodegradable polymer Poly (D, L-lactic-co-glycolic acid) and evaluated its apoptotic potential in human colon carcinoma cells (HCT 116). The results show that curcumin-PLGA conjugate efficiently inhibits cell proliferation and cell survival in human colon carcinoma cells as compared to native curcumin. Additionally, curcumin conjugated with PLGA shows improved cellular uptake and exhibits controlled release at physiological pH as compared to native curcumin. The curcumin-PLGA conjugate efficiently activates the cascade of caspases and promotes intrinsic apoptotic signaling. Thus, the results suggest that conjugation potentiates the sustainability, anti-proliferative and apoptotic activity of curcumin. This approach could be a promising strategy to improve the therapeutic index of cancer therapy.

Regulation of HA14‐1 mediated oxidative stress, toxic response, and autophagy by curcumin to enhance apoptotic activity in human embryonic kidney cells

An alteration in susceptibility to apoptosis not only contributes to promotion of malignancy but can also enhance drug resistance in response to anticancer therapies. HA14-1 is a small molecule which has the potential of inducing apoptosis in cancerous cells. HA14-1 manifests an antagonistic effect on antiapoptotic protein Bcl-2 and consequently induces cell death in various cancerous cell lines. However, it is also known to generate ROS and toxic response in the cells upon decomposition. Elevated level of ROS is responsible for oxidative stress and other pathological consequences, if not metabolized properly. The aim of the present study was to examine the synergistic effect of curcumin in promoting apoptosis by regulating the HA14-1 mediated ROS generation, toxicity, oxidative stress, and autophagy in human embryonic kidney cells. Our study demonstrates that curcumin efficiently scavenges HA14-1 mediated generation of ROS and toxic response resulting in augmentation of apoptosis in HEK 293T cells by promoting inhibition of antiapoptotic proteins and process of autophagy. Thus curcumin along with HA14-1 regulates cell proliferation by disruption of the antiapoptotic signaling mechanism. This approach could serve as a promising strategy for therapeutic potential to overcome their adverse effects.

Hypomodification of Transfer RNA in Cancer with Respect to Queuosine

Queuosine is a highly modified base analogue of guanosine. It is present only in the first position of anticodon loop of specific tRNA i.e., tRNAhis, tRNAasp, tRNAasn and tRNAtyr and post transcriptionally modified with base-for-base exchange of guanine to queuine. The transfer RNA modifying enzyme transfer RNA guanine transglycosylase (TGTase) is catalyzes the modification of tRNAs. Transfer RNA is completely modified with respect to queuosine in mature tissue, however modification is often incomplete in mitotically active cells. Hypomodification of transfer RNA is correlated with cell proliferation and malignancy. In the present study queuosine modification of transfer RNA and TGTase activity is compared in normal, Dalton’s lymphoma ascites transplanted (DLAT) cancerous mouse and queuine treated DLAT cancerous mouse liver. Transfer RNA of cancerous mouse is hypomodified in terms of queuosine modification. TGTase activity of cancerous mouse is found to decrease to less then half of enzyme activity of normal mouse; suggesting that the enzyme may be responsible for transfer RNA hypomodification. Exogenous treatment of queuine during development of cancer improves the queuosine modification of transfer RNA. The activators NaPP and ATP enhance TGTase activity of normal and DLAT cancerous mouse, where as 7mG inhibits the TGTase activity.

Modulation in the activity of lactate dehydrogenase and level of c-Myc and c-Fos by modified base queuine in cancer

In the final print edition of Modulation in the activity of lactate dehydraogenase and level of c-Myc and c-Fos by modified base queuine in cancer, by Chandramani Pathak, Yogesh K. Jaiswal and Manjula Vinayak (Cancer Biology and Therapy 2008; 7:85-91), Figure 4 was printed twice in the place of Figure 3 on page 87. Below is the represenation of Figure 3 that should have been presented.

FADD regulates NF-κB activation and promotes ubiquitination of cFLIPL to induce apoptosis

Tumor Necrosis Factor-α canonically induces the activation of NF-κB and associated gene product cellular FLICE-like inhibitory protein (cFLIPL) to promote cell survival. Previously, we demonstrated that ectopic expression of the Fas associated death domain (FADD) diminishes the expression of cFLIPL and transduces caspases-8 mediated apoptosis, independent of FasL stimulation in HEK 293T cells. However, the underlying molecular mechanism of FADD mediated ablation of cFLIP and NF-κB signaling to determining the fate of cell death or survival remains elusive. Here, we explored a novel molecular mechanism of FADD mediated apoptotic cell death that was directed by ubiquitination of cFLIPL and inhibition of NF-κB activation, independent of TNF-α stimulation. We found that induced expression of FADD firmly interacts with procaspase-8 and precludes cFLIPL to from the death inducing signaling complex (DISC). In addition, FADD negatively regulates cellular inhibitor of apoptosis protein 2 (cIAP2) and Bcl-2. Furthermore, FADD restrains cIAP2 expression and interacts with RIP1 and procaspase-8 to accomplish apoptotic cell death signaling. Interestingly, FADD was also found to promote JNK1 mediated activation of E3 ubiquitin ligase ITCH to degrade cFLIPL that may lead to commencement of apoptosis. Thus, FADD is an important regulator for determining the fate of cell death or survival.

Queuine mediated inhibition in phosphorylation of tyrosine phosphoproteins in cancer

Protein phosphorylation or dephosphorylation is the most important regulatory switch of signal transduction contributing to control of cell proliferation. The reversibility of phosphorylation and dephosphorylation is due to the activities of kinases and phosphatase, which determine protein phosphorylation level of cell under different physiological and pathological conditions. Receptor tyrosine kinase (RTK) mediated cellular signaling is precisely coordinated and tightly controlled in normal cells which ensures regulated mitosis. Deregulation of RTK signaling resulting in aberrant activation in RTKs leads to malignant transformation. Queuine is one of the modified base of tRNA which participates in down regulation of tyrosine kinase activity. The guanine analogue queuine is a nutrient factor to eukaryotes and occurs as free base or modified nucleoside queuosine into the first anticodon position of specific tRNAs. The tRNAs are often queuine deficient in cancer and fast proliferating tissues. The present study is aimed to investigate queuine mediated inhibition in phosphorylation of tyrosine phosphorylated proteins in lymphoma bearing mouse. The result shows high level of cytosolic and membrane associated tyrosine phosphoprotein in DLAT cancerous mouse liver compared to normal. Queuine treatments down regulate the level of tyrosine phosphoproteins, which suggests that queuine is involved in regulation of mitotic signaling pathways.

Expression of cFLIPL Determines the Basal Interaction of Bcl-2 With Beclin-1 and Regulates p53 Dependent Ubiquitination of Beclin-1 During Autophagic Stress.

Autophagy and apoptosis are two different physiological processes, which is required for the maintenance of cellular homeostasis. The apoptosis associated proteins such as Bcl‐2 and p53 have a close association with autophagic proteins HMGB1 and Beclin‐1 to modulate autophagic signaling. We demonstrate here the involvement of anti‐apoptotic protein cFLIPL in the regulation of autophagy during cellular stress. We found that ectopic expression of cFLIPL decreases the sensitivity of HEK 293T cells against rapamycin and H2O2 induced autophagic stress. Notably, the selective knockdown of cFLIPL augments autophagic stress in the cells accompanied with JNK1 activation and p53 dependent ubiquitination of Beclin‐1. However, re‐expression of cFLIPL in cFLIP knockdown cells restores autophagic equilibrium collectively with reversible effects on JNK1 and Beclin‐1 integrity. The co‐immunoprecipitation analysis suggests that cFLIPL is essential to maintain the canonical interaction of Bcl‐2 with Beclin‐1 to regulate autophagic stress and cell death. Altogether, our findings suggest that expression of cFLIPL regulates the basal interaction of Bcl‐2 with Beclin‐1 and substantiates p53 dependent ubiquitination of Beclin‐1 during autophagic stress to determine the fate of cell death or survival. J. Cell. Biochem. 117: 1757–1768, 2016.

Expression of FADD and cFLIPL balances mitochondrial integrity and redox signaling to substantiate apoptotic cell death

FADD and cFLIP both are pivotal components of death receptor signaling. The cellular signaling of apoptosis accomplished with death receptors and mitochondria follows independent pathways for cell death. FADD and cFLIP both have an important role in the regulation of apoptotic and non-apoptotic functions. Dysregulated expression of FADD and cFLIP is associated with resistance to apoptosis in cancer cells. Mitochondria are known to play critical role in maintaining cellular respiration and homeostasis in the cells as well as transduces various signals to determine the fate of cell death. However, involvement of FADD and cFLIP in regulation of mitochondrial integrity and programmed cell death signaling to define the fate of cells remains elusive. In the present study, we explored that, induced expression of FADD challenges the mitochondrial integrity and pulverizes the membrane potential by altering the expression of Bcl-2 and cytochrome c. In contrast, mutant of FADD was unable to affect the mitochondrial integrity. Interestingly, expression of FADD and cFLIP helps to balance redox potential by regulating the anti-oxidant levels. Further, we noticed that, knockdown of cFLIPL and induced expression of FADD rapidly accumulate intracellular ROS accompanied by JNK1 activation to substantiate apoptosis. Notably, the ectopic expression of cFLIPL resists the sensitivity of cancer cells against apoptosis inducers Etoposide and HA14-1. Altogether, our findings suggest that FADD and cFLIPL are important modulators of mitochondrial-associated apoptosis apart from the death receptor signaling.