Background: Cervical cancer is the second most common cancer among females and also the most preventable. In the literature there is abundant evidence that awareness regarding cervical cancer and its prevention is low in the developing countries. Medical students are the future health professionals and can play an important role in increasing awareness among the general population. To assess the knowledge regarding symptoms, risk factors and prevention of cervical carcinoma among medical students in th Kingdom of Saudi Arabia, the present study was planned. Materials and Methods: This cross-sectional study was conducted using a self-administered questionnaire with students at the College of Medicine, King Faisal University, Al-Ahsa, KSA, from December 2012 to May 2013. Results: The responses of 188 students (males 111, females 77) in their second, third, fourth, and fifth years were recorded and used in the data analysis. The majority of the students were not aware of the early warning signs, symptoms and risk factors. On average, only 43.7% males and 56% of females were aware about the early signs and symptoms whereas 51.4% males and 57.8% females had knowledge about the risk factors of cervical cancers. Some 55% males and 46.8% females were unable to select the correct answer regarding human papilloma virus (HPV) infection as the cause of cervical cancer. Majority of the students (67%) were not aware about the availability of vaccine against HPV. Conclusions: Lack of knowledge regarding early signs and symptoms, risk factors and prevention of cervical cancer was observed in the present study.
Human lipoxygenases (LOXs) and their metabolites have a great impact on human homeostasis and are of interest for targeted drug design. This goal requires detailed knowledge of their structures and an understanding of structure-function relationship. At the moment, there are two complete crystal structures for mammalian LOX [rabbit 12/15LOX (r-12/15LOX) and human 5LOX (h-5LOX)] and a fragment of human 12LOX. The low-resolution structures in solution for various LOX isoforms have brought about controversial results. Here we explored the behavior of r-12/15LOX in aqueous solution under different conditions (salt and pH) by small-angle X-ray scattering (SAXS) and compared it with human platelet-type 12S-LOX (hp-12LOX) and h-5LOX. Thermodynamic calculations concerning the stability of molecular assemblies, thermal motion analysis [TLSMD (translation, libration, and screw rotation motion detection based on crystallographic temperature factor B j )], and results of SAXS analyses brought about the following conclusions: (i) in contrast to its crystal structure, r-12/15LOX functions as a monomer that dominates in solution; (ii) it dimerizes at higher protein concentrations in the presence of salt and with increasing degree of motional freedom of the N-terminal PLAT domain, as suggested by the Y98,614→ R double mutant; (iii) in aqueous solutions, hp-12LOX is stable as a dimer, in contrast to h-5LOX and r-12/15LOX, which are monomeric; and (iv) all three *Corresponding author. E-mail address: ewa.skrzypczak-jankun@utoledo.edu. Present address: A. M. Aleem, Biochemistry Department, College of Sciences, King Saud University, Riyadh 11451, Kingdom of Saudi Arabia.Abbreviations used: LOX, lipoxygenase; r-12/15LOX, rabbit 12/15LOX; h-5LOX, human 5LOX; SAXS, small-angle X-ray scattering; hp-12LOX, human platelet-type 12S-LOX; PDB, Protein Data Bank. doi:10.1016/j.jmb.2011.04.035 J. Mol. Biol. (2011
Platelet 12-lipoxygenase (P-12-LOX) is overexpressed in different types of cancers, including prostate cancer, and the level of expression is correlated with the grade of this cancer. Arachidonic acid is metabolized by 12-LOX to 12(S)-hydroxyeicosatetraenoic acid [12(S)-HETE], and this biologically active metabolite is involved in prostate cancer progression by modulating cell proliferation in multiple cancer-related pathways inducing angiogenesis and metastasis. Thus, inhibition of P-12-LOX can reduce these two processes. Several lipoxygenase inhibitors are known, including plant and mammalian lipoxygenases, but only a few of them are known inhibitors of P-12-LOX. Curcumin is one of these lipoxygenase inhibitors. Using a homology model of the three-dimensional structure of human P-12-LOX, we did computational docking of synthetic curcuminoids (curcumin derivatives) to identify inhibitors superior to curcumin. Docking of the known inhibitors curcumin and NDGA to P-12-LOX was used to optimize the docking protocol for the system in study. Over 75% of the compounds of interest were successfully docked into the active site of P-12-LOX, many of them sharing similar binding modes. Curcuminoids that did not dock into the active site did not inhibit P-12-LOX. From a set of the curcuminoids that were successfully docked and selected for testing, two were found to inhibit human lipoxygenase better than curcumin. False-positive curcuminoids showed high LogP (theoretical) values, indicating poor water solubility, a possible reason for lack of inhibitory activity or/and nonrealistic binding. Additionally, the curcuminoids inhibiting P-12-LOX were tested for their ability to reduce sprout formation of endothelial cells (in vitro model of angiogenesis). We found that only curcuminoids inhibiting human P-12-LOX and the known inhibitor NDGA reduced sprout formation. Only limited inhibition of sprout formation at fIC 50 concentrations has been seen. At IC 50 , a substantial amount of 12-HETE can be produced by lipoxygenase, providing a stimulus for angiogenic sprouting of endothelial cells. Increasing the concentration of lipoxygenase inhibitors above IC 50 , thus decreasing the concentration of 12(S)-HETE produced, greatly reduced sprout formation for all inhibitors tested. This universal event for all tested lipoxygenase inhibitors suggests that the inhibition of sprout formation was most likely due to the inhibition of human P-12-LOX but not other cancer-related pathways. [Mol Cancer Ther 2006;5(5):1371 -82]
Plasminogen activator inhibitor (PAI-1) is an anticancer agent that inhibits plasmin driven proteolysis, limiting angiogenesis and metastasis. In low concentrations it could induce cancer cell motility by interacting with urokinase (uPA), its receptor (uPAR), vitronectin and integrins. Active PAI-1 binds to uPA forming a complex with uPAR, while the latent form of PAI-1 does not. PAI-1 is found in both forms in the circulation. It is not clear which form acts as an anticancer agent and how it interacts with malignant cells. To investigate how these forms reduce angiogenesis or metastasis, we have created PAI-1 cysteine mutants in the active conformation (VLHL PAI-1) with an extended half-life that reaches ~700 h and its R369A mutant, which has an active conformation but cannot bind to uPA (VLHL NS PAI-1). Both VLHL PAI-1s convert into the latent form when treated with a reducing agent (DTT) that breaks disulfide bridges. Unexpectedly, during routine investigation of LnCAP cell proliferation, we have found that cells detach from the culture vessels regardless of PAI-1 conformation or activity. Further investigation showed that treatment of cancer cells with VLHL PAI-1 downregulated nucleophosmin, while all forms of PAI-1 downregulated fortilin. These two proteins are implicated in important cellular processes (cell growth, cell cycle, malignant transformation). This suggests that PAI-1, in addition to its well-known anticancer properties, plays an important role in cell signaling. We hope that by exploring PAI-1's structure and function we might be able to understand and separate the different effects of PAI-1 on cancer cells and develop more effective therapeutic strategies in cancer treatment.
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