Characterization of tailoring genes involved in the modification of geldanamycin polyketide in Streptomyces hygroscopicus JCM4427

Geldanamycin and its analogs are important anticancer agents that inhibit the newly targeted, heat-shock protein (Hsp) 90, which is a chaperone protein in eukaryotic cells. To resolve which geldanamycin biosynthetic genes are responsible for particular post-polyketide synthase (PKS) processing steps and in which order the reactions occur, we individually inactivated candidate genes in Streptomyces hygroscopicus subsp. duamyceticus JCM4427, and isolated and elucidated the structures of intermediates from each mutant. The results indicated that gel7 governs at least one of the benzoquinone ring oxidation steps. In addition, gel16 was found to be involved in double-bond formation between C-4 and C-5 of 4,5-dihydrogeldanamycin, which confirmed our previous findings that this double bond reduced during the post-PKS modification of the polyketide assembly. In addition, pro-geldanamycin, which does not possess a double bond at C-4/5, was purified from the gel7 and 8 double-gene-inactivated mutant.     

Application of a peptide-based PF2D platform for quantitative proteomics in disease biomarker discovery

A peptide-based 2-D liquid phase fractionation (PF2D) system was used in a quantitative proteomic analysis of hepatocellular carcinoma. 2-D liquid maps of peptide specimens showed better resolution than those of proteins, leading to the identification of differentially expressed proteins. Peptide-based PF2D gave well-matched theoretical and experimental pI values and was proven to be a very efficient and versatile analytical tool for both large-scale profiling and quantification of phosphoproteins in disease biomarker discovery.     

Altered free amino acid levels in brain cortex tissues of mice with Alzheimer's disease as their N(O,S)-ethoxycarbonyl/tert-butyldimethylsilyl derivatives

The altered amino acid (AA) levels as neurotransmitter closely correlate to neurodegenerative conditions including Alzheimer's disease (AD). Target profiling analysis of nineteen AAs in brain cortex samples from three Tg2576 mice as AD model and three littermate mice as control model was achieved as their N(O,S)-ethoxycarbonyl/tert-butyldimethylsilyl derivatives by gas chromatography. Subsequently, star pattern recognition analysis was performed on the brain AA levels of AD mice after normalization to the corresponding control median values. As compared to control mice, gamma-aminobutyric acid among ten AAs found in brain samples was significantly reduced (P 0.01) while leucine was significantly elevated (P 0.02) in AD mice. The normalized AA levels of the three AD mice were transformed into distorted star patterns which was different from the decagonal shape of control median. The present method allowed visual discrimination of the three AD mice from the controls based on the ten normalized AA levels.     

Instantaneous amyloid fibril formation of alpha-synuclein from the oligomeric granular structures in the presence of hexane

Amyloid fibrils found in various neurodegenerative disorders are also recognized as high-performance protein nanomaterials with a formidable rigidity. Elucidation of an underlying molecular mechanism of the amyloid fibril formation is crucial not only to develop controlling strategy toward the diseases, but also to apply the protein fibrils for future nanobiotechnology. alpha-Synuclein is an amyloidogenic protein responsible for the radiating filament formation within Lewy bodies of Parkinson's disease. The amyloid fibril formation of alpha-synuclein has been shown to be induced from the oligomeric granular species of the protein acting as a growing unit by experiencing structural rearrangement within the preformed oligomeric structures in the presence of an organic solvent of hexane. This granule-based concerted amyloid fibril formation model would parallel the prevalent notion of nucleation-dependent fibrillation mechanism in the area of amyloidosis.     

Dequalinium-Induced Cell Death of Yeast Expressing α-Synuclein-GFP Fusion Protein

Intracellular toxic effects of the dequalinium-induced protofibrils of alpha-synuclein have been investigated with the yeast system expressing alpha-synuclein-GFP fusion protein in single copy, which appears in the green halo around the plasma membrane. Intracellular responses of the green fluorescent protein were analyzed as the cells were treated with dequalinium (DQ) and lactacystin. Yeast cells expressing alpha-synuclein-GFP were susceptible to both compounds in alpha-synuclein-dependent manner. Upon DQ treatment, the green halo became smeared throughout the cytoplasm while lactacystin induced a few discrete green dots, reflecting intracellular formation of the protofibrils and the protein inclusions, respectively. The DQ-treated yeast cells were intensely stained with the nucleic acid stains of cell-permeable Hoechst 33342 and cell-impermeable propidium imidione, indicating that nucleus has been disrupted in addition to plasma membrane destabilization. Those DQ-treated yeast cells, however, still contained active mitochondria identified with MitoTracker Red. Therefore, the DQ-induced protofibrillar state of alpha-synuclein-GFP has been suggested to cause the nuclear damage either independently or in combination with the membrane destabilization without affecting mitochondria.     

The First Successful Prenatal Diagnosis on a Korean Family with Citrullinemia

DNA prenatal diagnosis was successfully performed on a family with citrullinemia. The father carried the G324S mutation and the mother carried the IVS6–2A > G mutation in the argininosuccinate synthase gene. They had a previous child with citrullinemia who died in the week after birth owing to complicated hyperammonemia. The lost child turned out to be a compound heterozygote. DNA was extracted from the cultured amniotic cells after amniocentesis done at 18-week gestation. For the detection of the G324S mutation, the PCR and restriction fragment length polymorphism method was used, and for the IVS6–2A > G mutation, allele-specific PCR was performed. The fetus was found to carry G324S but not IVS6–2A > G, suggesting a heterozygote carrier. Pregnancy was continued and a healthy boy was born. Plasma amino acid analysis performed on the third day after birth was normal and the serial ammonia level was in the normal range. A molecular study on his genomic DNA after birth also agreed with the previous fetal DNA analysis. He is now 2-months old with normal growth and development.     

Interaction of soluble pig heart glutamate-aspartate transaminase with various beta,gamma-unsaturated amino acids

beta-Ethylidene-DL-aspartate (beta EA) and beta-methylene-DL-glutamate (beta MG) were synthesized and tested as potential suicide inhibitors of soluble pig heart glutamate-aspartate transaminase (sGAT). beta MG was found to be a) a substrate with a very low turnover number relative to glutamate and b) a competitive inhibitor with respect to aspartate (albeit with a large binding constant). At high concentrations beta MG inactivated the enzyme but only very slowly. beta EA was also found to be a substrate with a very low turnover number; it did not inactivate the enzyme (1 hr, 25 degrees C) even at a high concentration. However, beta EA was found to bind to the enzyme with an affinity comparable to that of aspartate and glutamate. beta-Methylene-DL-aspartate (beta MA) has been shown to rapidly inactivate glutamate-aspartate transaminase. Therefore, it appears that glutamate-aspartate transaminase can bind analogues of aspartate with alkene groups in the beta position. The conjugated carbonyl groups of beta MA and beta EA will enhance Michael addition in comparison with that expected for vinylglycine. On the other hand, the presence of the methyl groups should reduce the electrophilicity of the double bond of beta EA compared to beta MA. This deactivation and/or steric hindrance to Michael attack may account for the inability of beta EA to inactivate sGAT. Therefore, it may be possible to design selective suicide inhibitors of glutamate-aspartate++ transaminase with the following structure: HO2CC(= CHX)CH(CO2H)NH2, where X is an electron-withdrawing group. Ideally, X would increase the reactivity of the double bond while affording a minimum of steric hindrance to susceptible enzyme-bound bases.     

Studies on S-adenosylmethionine:protein-carboxyl methyltransferase in the hypothalamo-neurohypophysial complex in organ culture.

The level of protein methylase II (S-adenosylmethionine: protein-carboxyl-methyltransferase, EC.2.1.1.24) activity in the hypothalamo-neurohypophysial complex in organ culture was studied during the period of 21 days. 1. The endogenous enzyme activity, which is a measure of both enzyme and substrate protein levels, in hypothalamus is maximum at the 7th day of culture showing 100% increase, compared to the activity at 0 day. Exogenous enzyme activity in hypothalamus which is a measure of enzyme level only, did not show a peak at 7th day. Thus, this increase is a measure of enzyme level only, did not show a peak at 7th day. Thus, this increase of the activity indicates that newly synthesized neurophysin served as endogenous substrate protein. 2. Endogenous enzyme activity of cytosol fraction from anterior pituitary gland gradually increased during the culture period reaching 3-fold increase at 12th day of culture, while the exogenous activity remained unchanged. This specific increase of endogenous enzyme activity also indicates that $\text{in vivo}$ newly synthesized anterior pituitary peptide hormones serve as substrate.     

Polo-like kinase 1 (Plk1) is expressed by cutaneous T-cell lymphomas (CTCLs), and its downregulation promotes cell cycle arrest and apoptosis

Polo-like kinases are serine/threonine kinases crucial for mitosis and DNA integrity. Plk1, the most well studied member of this family, is upregulated in several cancers, as well as in dividing cells with peak expression during G2/M phase. Recently, employing lesional skin from patients with cutaneous T-cell lymphoma (CTCL), we showed that Plk1 was increased mainly in advanced lesions. In this study, employing western blot and quantitative RT-PCR analyses, we demonstrated that Plk1 was overexpressed in multiple CTCL cell lines (HH, Hut78, MyLa, SeAx and SZ4). Further, a genetic knockdown (by short hairpin RNA) or enzyme activity inhibition (via a small molecule inhibitor, GW843682X) was found to result in a decrease in cell growth, viability and proliferation. Plk1 inhibition in CTCL cells also resulted in: (1) increased G2/M phase cell cycle arrest, (2) alteration in key mitotic proteins, (3) apoptosis and (4) multiple mitotic errors. Given our findings, clinical trials of Plk1 inhibitors in CTCL may be a promising area for further translational investigation. We speculate that overexpression of Plk1 may prove to be relevant to the progression and prognosis of CTCL through its direct impact on the regulation of tumor cell proliferation and indirect influence on the acquisition of somatic mutations by proliferating tumor cells.