Insight into the Reactivity of Metastasis Inhibitor, Imidazolium trans-[tetrachloro (dimethyl sulfoxide)(imidazole)ruthenate(III)], with Biologically-active Thiols

Adigun, Risikat Ajibola

01 January 2012

Imidazolium trans-[tetrachloro (dimethyl sulfoxide)(imidazole)ruthenate(III)], NAMI-A, is an experimental metastasis inhibitor whose specific mechanism of activation and action remains to be elucidated. In the nucleophilic and reducing physiological environment; it is anticipated that the most relevant and available reductants upon introduction of NAMI-A as a therapeutic agent will be the biologically-relevant free thiols. The kinetics and mechanisms of interaction of NAMI-A with biologically-active thiols cysteamine, glutathione, cysteine and a popular chemoprotectant, 2-mercaptoethane sulfonate (MESNA) have been studied spectrophotometrically under physiologically-relevant conditions. The reactions are characterized by initial reduction of NAMI-A with simultaneous formation of dimeric thiol and subsequent ligand exchange with water to various degrees as evidenced by Electospray Ionization Mass Spectrometry. Stoichiometry of reactions shows that one molecule of NAMI-A reacted with one mole of thiol to form corresponding disulfide cystamine, dimeric MESNA, oxidized glutathione and cystine. Observed rate constants, ko, for the reaction of NAMI-A with cysteamine, MESNA, GSH and cysteine were deduced to be 6.85 + 0.3 x 10-1, 9.4 + 0.5 x 10-2 , 7.42 + 0.4 x 10-3 and 3.63 + 0.3 x 10-2 s-1 respectively. Activation parameters determined from Arrhenius plots are indicative of formation of associative intermediates prior to formation of products. A negative correlation was obtained from the Brønsted plot derived from observed rate constants and the pKa of the different thiols demonstrating significant contribution of thiolate species towards the rate. In conclusion, interactions of NAMI-A with biologically-active thiols are kinetically and thermodynamically favored and should play significant roles in in vivo metabolism of NAMI-A.

Metastasis inhibitor

Kinetics

Mechanism

Transition metal complexes -- Research

Tumor suppressor proteins -- Research

Metastasis -- Research

Thiols -- Research

E7 PROTEINS OF HIGH-RISK (TYPE 16) AND LOW-RISK (TYPE 6) HUMAN PAPILLOMAVIRUSES REGULATE p130 DIFFERENTLY

Barrow, Lisa C.

15 October 2010

Indiana University-Purdue University Indianapolis (IUPUI) / Human papillomaviruses (HPVs) are one of the most common causes of sexually transmitted disease in the world. HPVs are divided into high-risk (HR) or low-risk (LR) types based on their oncogenic potential. HPVs 16 and 18 are considered HR types and can cause cervical cancer. HPVs 6 and 11 are classified as LR and are associated with condyloma acuminata (genital warts). Viral proteins of both HR and LR HPVs must be able to facilitate a replication competent environment. The E7 proteins of LR and HR HPVs are responsible for maintenance of S-phase activity in infected cells. HR E7 proteins target all pRb family members (pRb, p107 and p130) for degradation. LR E7 does not target pRb or p107 for degradation, but does target p130 for degradation. Immunohistochemistry experiments on HPV 6 infected patient biopsies of condyloma acuminata showed that detection of p130 was decreased in the presence of the whole HPV 6 genome. Further, the effect of HR HPV 16 E7 and LR HPV 6 E7 on p130 intracellular localization and half-life was examined. Experiments were performed using human foreskin keratinocytes transduced with HPV 6 E7, HPV 16 E7 or parental vector. Nuclear/cytoplasmic fractionation and immunofluorescence showed that, in contrast to control and HPV 6 E7-expressing cells, a greater amount of p130 was present in the cytoplasm in the viii presence of HPV 16 E7. The half-life of p130, relative to control cells, was decreased in the cytoplasm in the presence of HPV 6 E7 or HPV 16 E7, but only decreased by HPV 6 E7 in the nucleus. Inhibition of proteasomal degradation extended the half-life of p130, regardless of intracellular localization. Experiments were also conducted to detect E7-binding partners. Cyclin C and cullin 5 were identified as proteins capable of binding to both HPV 6 E7 and HPV 16 E7. Preliminary experiments showed that decreasing protein levels of p600, a binding partner of both HPV 6 E7 and HPV 16 E7, by RNA interference might affect p130 stability. Elucidating the mechanisms of p130 degradation may identify potential targets for preventing degradation of p130 and allowing restoration of cell cycle control.

Papillomaviruses -- Research

Tumor suppressor proteins -- Research

Viruses -- Reproduction -- Research