Aminoflavone (AF) is an anticancer drug in early clinical trials, and its antiproliferative activity involves the induction of DNA-protein cross-links. To identify the proteins cross-linked to nucleic acids, cesium chloride (CsCl) gradient centrifugation was used to isolate proteins tightly bound to nucleic acids in AF-treated human breast carcinoma MCF-7 cells. The identified proteins included structural proteins (several cytokeratins), transcription regulators, and stress response proteins. The identification of the cytokeratins was validated using direct immunoblotting of the high-density CsCl (nucleic acid) fractions isolated from AF-treated cells. Ribonuclease A pretreatment caused the cytokeratin signal in the heaviest CsCl fractions to disappear, suggesting that AF mediates RNA-cytokeratin cross-links. Additional experiments using radiolabeled AF showed that AF formed adducts with total RNA and mRNA with similar affinity to that of DNA. Moreover, 18S RNA was selectively pulled down using an anti-cytokeratin antibody after AF treatment. Consistent with the formation of these adducts, we found that AF inhibits RNA and protein synthesis in a dose- and time-dependent manner. This study provides evidence for the formation of AF-mediated cytokeratin-RNA cross-links and the presence of cytokeratin-RNA complexes. Thus, in addition to its anticancer activity, AF might be a useful molecular probe to study the potential role of cytokeratins in the subcellular localization and metabolism of RNA.
Here we report the design, fabrication, and operation of a polymer-based microchip device interfaced to a nanoelectrospray ionization source and a Fourier transform ion cyclotron resonance mass spectrometer. The poly(methyl methacrylate) micromachined device was fabricated using X-ray lithography to produce a network of channels with high aspect ratios. Fabrication of high aspect ratio channels allows for zero dead volume interfaces between the microchip platform and the nanoelectrospray capillary interface. The performance of this device was evaluated with standard peptide and protein samples. High-quality mass spectral data from peptide and proteins (and mixtures thereof) were obtained without any interfering chemical noise from the polymer or the developers and plasticizers used in the fabrication process. Sample cross-contamination is not a problem using this polymer-based microchip device as demonstrated by the sequential analysis of several proteins. The nanoelectrospray source was operated at flow rates from 20 to 100 nL/min using pressure-driven flow, and uninterrupted operation for several hours is demonstrated without any noticeable signal degradation. The ability to fabricate multiple devices using injection molding or hot-embossing techniques of polymers provides a lower cost alternative to silica-based devices currently utilized with mass spectrometry.
Ticks--vectors of medical and veterinary importance--are themselves also significant pests. Tick salivary proteins are the result of adaptation to blood feeding and contain inhibitors of blood clotting, platelet aggregation, and angiogenesis, as well as vasodilators and immunomodulators. A previous analysis of the sialotranscriptome (from the Greek sialo, saliva) of Amblyomma variegatum is revisited in light of recent advances in tick sialomes and provides a database to perform a proteomic study. The clusterized data set has been expertly curated in light of recent reviews on tick salivary proteins, identifying many new families of tick-exclusive proteins. A proteome study using salivary gland homogenates identified 19 putative secreted proteins within a total of 211 matches. The annotated sialome of A. variegatum allows its comparison to other tick sialomes, helping to consolidate an emerging pattern in the salivary composition of metastriate ticks; novel protein families were also identified. Because most of these proteins have no known function, the task of functional analysis of these proteins and the discovery of novel pharmacologically active compounds becomes possible.
Abstract The establishment of infection with the lymphatic dwelling filarial parasites is dependent on the infectivity and subsequent development of the infective larvae (L3) within the human host to later stages (L4, adults) that require several developmental molts. The molecular mechanisms underlying the developmental processes in parasitic nematodes are not clearly defined. We report the proteomic profiles throughout the entire L3 to L4 molt using an established in vitro molting process for the human pathogen B. malayi . A total of 3466 proteins of B. malayi and 54 from Wolbachia were detected at one or more time points. Based on the proteomic profiling, the L3 to L4 molting proteome can be broadly divided into an early, middle and late phase. Enrichment of proteins, protein families and functional categories between each time point or between phases primarily relate to energy metabolism, immune evasion through secreted proteins, protein modification, and extracellular matrix-related processes involved in the development of new cuticle. Comparative analyses with somatic proteomes and transcriptomes highlighted the differential usage of cysteine proteinases (CPLs), BmCPL-1, -4 and -5 in the L3-L4 molt compared to the adults and microfilariae. Inhibition of the CPLs effectively blocked the in-vitro L3 to L4 molt. Overall, only 4 Wolbachia proteins (Wbm0495, Wbm0793, Wbm0635, and Wbm0786) were detected across all time points and suggest that they play an inconsequential role in the early developmental process. Importance The neglected tropical diseases of lymphatic filariasis, onchocerciasis (or river blindness), and loiasis are the three major filarial infections of humans that cause long-term disability, impaired childhood growth, reduced reproductive capacity. Global efforts to control and/or eliminate these infections as a public health concern are based on strategies and tools to strengthen the diagnostics, therapeutic and prophylactic measures. A deeper understanding of the genes, proteins and pathways critical for the development of the parasite is needed to help further investigate the mechanisms of parasite establishment and disease progression, because not all the transmitted infective larvae get to develop successfully and establish infections. The significance of this study is in identifying the proteins and the pathways that are needed by the parasite for successful developmental molts, that in turn will allow for investigating targets of therapeutic and prophylactic potential.
