Inhibitors of farnesyl protein transferase and MEK1,2 induce apoptosis in fibroblasts transformed with farnesylated but not geranylgeranylated H-Ras

Farnesyl protein transferase inhibitors (FTIs) reverse the transformed phenotype of fibroblasts expressing activated H-Ras and block anchorage-independent growth and tumorigenesis of tumor cell lines independent of their Ras mutational status. FTIs induce significant tumor regression accompanied by apoptosis in several transgenic mouse tumor models. FTI treatment of tumor cells in vitro is proapoptotic under certain cell culture conditions. Induction of apoptosis by FTIs in vitro generally requires a second death-promoting signal. To better understand FTI-induced apoptosis we analyzed the effect of SCH 66336, a tricyclic FTI, on apoptosis of Ras-transformed Rat2 fibroblasts. Treatment of H-Ras-CVLS-transformed fibroblasts with MEK1,2 inhibitors provides a pharmacological second signal to enhance FTI-induced apoptosis. Simultaneous treatment of these cells with a MEK1,2 inhibitor markedly enhanced caspase-3 activity and the apoptotic response to SCH 66336. The combination treatment resulted in a more complete and sustained inhibition of MAPK pathway activity than observed with either drug alone. Surprisingly, after treatment with either agent alone or in combination, no apoptotic response was observed in Rat2 cells transformed with a geranylgeranylated form of H-Ras (H-Ras-CVLL). Differences were also observed when SCH 66336 treatment was combined with forced suspension growth or serum withdrawal, in that an increase in drug-induced apoptosis was observed in H-Ras-CVLS-transformed Rat2 cells but not H-Ras-CVLL-transformed Rat2 cells. The lack of apoptotic effect of SCH 66336 and MEK inhibitor, alone or in combination, in H-Ras-CVLL-transformed cells suggests a difference in the reliance of cells transformed with farnesylated and geranylgeranylated forms of H-Ras on the MAPK signal transduction cascade for survival. K-Ras-transformed cells underwent apoptosis upon MEK1,2 inhibition but not in response to SCH 66336 treatment. The apoptotic response induced by MEK1,2 inhibitors is much greater in magnitude in H-Ras-transformed cells than in K-Ras-transformed cells, also pointing to differences in pathway utilization and/or dependence for these two Ras isoforms.     

Purification and crystallization of a complex between human interferon γ receptor (extracellular domain) and human interferon γ

X-ray diffraction quality crystals have been obtained from a complex between interferon γ and the extracellular domain of its high-affinity cell surface receptor. The crystals were obtained from interferon γ/interferon γ receptor complexes purified by size exclusion chromatography. Diffraction quality crystals required analyzing these complex samples by isoelectric focusing gels to select purified complex fractions devoid of unbound interferon γ. These studies used interferon γ receptor engineered with an eight amino acid N-terminal deletion to eliminate heterogeneity generated due to proteolytic cleavage. In addition, the receptor was expressed in an E. coli secretion cell line which eliminated the need to refold the protein. Hexagonal crystals were grown from 1.6 M ammonium phosphate solutions and belong to a spacegroup of P6₅22 with unit cell dimensions a = 145.9 Å and c = 180.3 Å. These crystals diffract to at least 2.9 Å resolution when exposed to synchrotron radiation. SDS PAGE analysis of the crystals demonstrated that both interferon γ and the receptor were present. Analysis of the x-ray diffraction data revealed that the crystals contain complexes with a stoichiometry of 2:1 receptor: ligand within the crystallographic asymmetric unit and consist of approximately 55% solvent. © 1996 Wiley-Liss, Inc.     

Mass spectrometric characterization of the isoforms in Escherichia coli recombinant DNA-derived interferon alpha-2b

The isoforms Iso-2, Iso-3, and Iso-4 of Escherichia coli-derived recombinant human interferon alpha-2b (rhIFN α-2b), generated by posttranslational modifications of the protein during fermentation, present a major problem in terms of purification and the yield of the drug substance. We report here the structural characterization of these isoforms by mass spectrometry (MS) methods. An extensive MS study was conducted on Iso-4, which is composed of up to 75% of the in-process IFN, and on the native rhIFN α-2b. The trypsin-digested peptide mixtures generated from the two samples were analyzed by liquid chromatography (LC)–MS, and targeted peptides were further studied by LC–tandem MS (triple quadrupole mass spectrometer), high-resolution MSⁿ (LTQ Orbitrap), and matrix-assisted laser desorption/ionization MS (MALDI–MS). The structure of Iso-4 was elucidated as a novel pyruvic acid ketimine derivative of the N-terminal cysteine (Cys1) of IFN α-2b, where the disulfide bond between Cys1 and Cys98 was fully reduced and the other disulfide bond pair, Cys29-ss-Cys138, was partially reduced. Similarly, Iso-2 was identified as a correctly disulfide-folded rhIFN α-2b with acetylation on Cys1, and Iso-3 was identified as an S-glutathionylated form (Cys98) of partially reduced rhIFN α-2b that was pyruvated on Cys1. Based on the characterization work, a reproducible conversion procedure was successfully implemented to convert Iso-4 to rhIFN α-2b.     

Curcumins as inhibitors of nitrosation in vitro

The effects of turmeric extract and its pure yellow pigments curcumin I, II and III were tested on the nitrosation of methylurea by sodium nitrite at pH 3.6 and 30 degrees C. The nitrosomethylurea formed was monitored by checking the mutagenicity in S. typhimurium strains TA1535 and TA100 without metabolic activation. Turmeric extract as well as curcumins exhibit dose-dependent decreases of nitrosation. Curcumin III was the most effective nitrosation inhibitor among the compounds tested. The simultaneous treatment of inhibitor with nitrosation precursors was essential and pre- or post-treatment of inhibitor had no effect on the mutagenicity of nitrosomethylurea. The binding of nitrite with the inhibitors was studied at pH 3.6 and 30 degrees C. Curcumin I shows a dose-dependent depletion of nitrite ions thus making nitrite non-available for nitrosation. Curcumin I and III when tested also showed a time-dependent depletion of nitrite ions at pH 3.6 and 30 degrees C. Curcumin III has a higher affinity for nitrite ions than curcumin I.     

Enhancement of intravesical delivery with Syn3 potentiates interferon-alpha2b gene therapy for superficial bladder cancer

Intravesical administration of interferon alpha-2b protein (IFN) has been successfully used in the treatment of patients with superficial bladder tumors. Local dosing of IFN minimizes well-known systemic side effects of the drug, but exposure to bladder tumors is limited by the duration of instillation and transient concentrations achieved in the urothelium. Intravesical delivery of the gene encoding interferon results in an alternative strategy for IFN-based therapy of the disease, enabling sustained exposure of IFN protein that results from production by tumor and non-tumor cells in the urothelium. Efficient gene delivery and expression of IFN has been achieved using a recombinant adenovirus gene delivery system (rAd-IFN) in conjunction with the novel small molecule excipient Syn3. Studies with rAd-IFN/Syn3 in animal models result in urine concentrations of IFN that persisted for weeks and correlated with potent anti-tumor effects. The objective of this review is to communicate the rationale and preclinical findings that support ongoing clinical investigation of intravesical rAd-IFN/Syn3 in superficial bladder cancer.     

Isolation and characterization of a resistant core peptide of recombinant human granulocyte-macrophage colony-stimulating factor (GM-CSF); confirmation of the GM-CSF amino acid sequence by mass spectrometry.

A trypsin-resistant core peptide of recombinant human granulocyte-macrophage colony-stimulating factor (rhGM-CSF) was isolated and analyzed by high-energy Cs+ liquid secondary-ion (LSI) mass spectrometric analysis. This analysis provided successful detection of the high-mass disulfide-linked core peptide as well as information confirming the existence of disulfide pairing. Similarly, LSI mass spectrometric analysis of the peptide fragments isolated chromatographically from a Staphylococcus aureus V8 protease digest of rhGM-CSF provided rapid confirmation of the cDNA-derived sequence and determination of the existing disulfide bonds between cysteine residues 54-96 and 88-121. Electrospray ionization mass spectrometry was employed to measure the molecular weight of the intact protein and to determine the number of the disulfide bonds in the protein molecule by comparative analysis of the protein before and after reduction with beta-mercaptoethanol.     

Design and analysis of an engineered human interleukin-10 monomer

A monomeric form of human interleukin 10 (IL-10M1) has been engineered for detailed structure-function studies on IL-10 and its receptor complexes. Wild type IL-10 (wtIL-10) is a domain swapped dimer whose structural integrity depends on the intertwining of two peptide chains. wtIL-10 was converted to a monomeric isomer by inserting 6 amino acids into the loop connecting the swapped secondary structural elements. Characterization of IL-10M1 by mass spectroscopy, size exclusion chromatography, cross-linking, and circular dichroism shows that IL-10M1 is a stable alpha-helical monomer at physiological pH whose three-dimensional structure closely resembles one domain of wtIL-10. As previously reported, incubation of wtIL-10 with a soluble form of the IL-10Ralpha (sIL-10Ralpha) generates a complex that consists of 2 wtIL-10 molecules and 4 sIL-10Ralphas. In contrast, IL-10M1 forms a 1:1 complex with the sIL-10Ralpha. Characterization of the interaction using isothermal titration calorimetry confirmed the 1:1 stoichiometry and yielded a dissociation constant of 30 nm with an apparent binding enthalpy of -12.2 kcal/mol. Despite forming a 1:1 complex, IL-10M1 is biologically active in cellular proliferation assays. These results indicate that the 1:1 interaction between IL-10M1 and IL-10Ralpha is sufficient for recruiting the signal transducing receptor chain (IL-10Rbeta) into the signaling complex and eliciting IL-10 cellular responses.     

Construction of high-density linkage map and identification of QTLs for resistance to sorghum downy mildew in maize (<Emphasis Type="Italic">Zea mays</Emphasis> L.)

Sorghum downy mildew (SDM), caused by obligate biotrophic fungi Peronosclerospora sorghi, is an economically important disease of maize. The genetics of resistance was reported to be polygenic thereby necessitating identification of QTLs for resistance to SDM to initiate effective marker-assisted selection programs. During post-rainy and winter season of 2012, 645 F_2:3 progeny families from the cross CML153 (susceptible) × CML226 (resistant) were screened for their reaction to SDM. Characterization of QTLs affecting resistance to SDM was undertaken using the genetic linkage map with 319 polymorphic SSR and SNP marker loci and the phenotypic data of F_2:3 families. Three QTLs conferring resistance to SDM were consistently identified on chromosomes 2, 3 and 6 in both seasons. The resistant parent CML226 contributed all the QTL alleles conferring resistance to SDM. The major QTL located on chromosome 2 explained 38.68% of total phenotypic variation in the combined analysis with a LOD score of 9.12. All the three QTL showed partially dominant gene effects in combined analysis. The detection of more than one QTL supports the hypothesis that quantitative genes control resistance to P. sorghi. The generation was advanced to F₆ using markers linked to major QTLs on chromosomes 2 and 3 to derive 33 SDM resistant maize inbred lines.