Gaining control on optical force by the stimulated-emission resonance effect.

The resonance between an electronic transition of a micro/nanoscale object and an incident photon flux can modify the radiation force exerted on that object, especially at an interface. It has been theoretically proposed that a non-linear stimulated emission process can also induce an optical force, however its direction will be opposite to conventional photon scattering/absorption processes. In this work, we experimentally and theoretically demonstrate that a stimulated emission process can induce a repulsive pulling optical force on a single trapped dye-doped particle. Moreover, we successfully integrate both attractive pushing (excited state absorption) and repulsive pulling (stimulated emission) resonance forces to control the overall exerted optical force on an object, validating the proposed non-linear optical resonance theory. Indeed, the results presented here will enable the optical manipulation of the exerted optical force with exquisite control and ultimately enable single particle manipulation.

Characterization of novel cell-penetrating peptides derived from the capsid protein of beak and feather disease virus.

Beak and feather disease virus (BFDV) is a 17-20 nm icosahedral virus belonging to the Circoviridae family. Psittacine beak and feather disease (PBFD) is caused by BFDV and its common symptoms include abnormal feather, beak, and claw development, as well as immunosuppression in various bird species. In this study, novel cell-penetrating peptides (CPPs) in the capsid protein (Cap) of BFDV were identified through bioinformatic analyses, after which they were experimentally characterized. The cell-penetrating activities of both CPP1 and CPP2 of BFDV were analyzed through flow cytometry and image analysis. The internalization of CPP1 and CPP2 was both dose- and time-dependent but their uptake efficiencies varied depending on the cell type. The cell-penetrating activities of BFDV CPP1 and CPP2 were both superior to that of a typical CPP-TAT originating from the viral protein of human immunodeficiency virus. The cellular uptake of 5 µM CPP1 was close to that of 25 µM TAT, albeit with less cytotoxicity. Using the identified CPPs, the pc-mCheery, pc-Rep, and pc-Cap plasmids were successfully delivered into the target cells for expression. Moreover, both the replication-associated protein with the tag and the Cap protein with the tag could also be successfully delivered into the cells by CPP1 and CPP2. Multiple endocytosis pathways and direct translocation were involved in the cell internalization of CPP1 and CPP2. Furthermore, the delivery of the apoptin gene using CPP1 and CPP2 effectively triggered apoptosis, thus confirming the potential of these CPPs as delivery vehicles. Similarly, green fluorescent protein (GFP) fused with CPP1 or CPP2 at their N-terminus successfully entered the cells. However, the cell internalization efficiency of CPP2-GFP was higher than that of CPP1-GFP. Taken together, our findings demonstrated that both CPP1 and CPP2 of BFDV have promising potential as novel CPPs.

Characterization of a novel reporter system for beak and feather disease virus.

Beak and feather disease virus (BFDV) belongs to the Circoviridae family, which has a relatively simple replication mechanism. As BFDV lacks a mature cell culture system, a novel mini-replicon system based on the reporter plasmid that contains the origin of replication, which can bind to the Rep protein expressed from another plasmid and thus trigger its replication and induce/increase luminescence was developed. The dual-luciferase assay was used in this system to measure replicative efficiency by comparing relative light units (RLU) of firefly luciferase. Linear relationships between the luciferase activity of the reporter plasmids with the BFDV origin of replication and the amounts of the Rep protein and vice versa were found, suggesting the mini-replicon system can be used to quantify viral replication. Moreover, the activities of reporter plasmids driven by mutated Rep proteins or the activities of reporter plasmids with mutations were significantly downregulated. The Rep and Cap promoter activities can be characterized using this luciferase reporter system. Notably, the RLU of the reporter plasmid was considerably inhibited in the presence of sodium orthovanadate (Na3VO4). When BFDV-infected birds were treated with Na3VO4, the viral loads of BFDV rapidly decreased. In conclusion, this mini-replicon reporter gene-based system provides a practical means to screen for anti-viral drug candidates.

Characterization of agapornis fischeri interferon gamma and its activity against beak and feather disease virus.

This study sought to clone and sequence the interferon-γ (IFN-γ) gene of the Fischer's lovebird parrot (Agapornis fischeri). Raw264.7 cells treated with the expressed IFN-γ protein exhibited an upregulation in inducible nitric oxide synthase protein expression and nitric oxide (NO) production coupled with increases in phagocytosis and pinocytosis, as well as an induction of interferon-stimulated genes through the activation of the NF-κB factor, all of which are indicators of the innate immune responses of the activated macrophages. Similar to the IFN-γ protein of other species, the NO production activity of the parrot IFN-γ protein decreased by 80% after exposure at 60 °C for 4 min. Additionally, only half of the NO production activity of the parrot IFN-γ protein remained upon exposure to HCl for 30 min. These findings suggested that the parrot IFN-γ protein was heat-labile and sensitive to acidic conditions. Therefore, all of these effects contributed to the blockage of the uptake of BFDV virus-like particles (VLPs) by cells, the nuclear entry of the Cap protein of BFDV VLPs, and the clearance of the virus from BFDV-infected parrots by the IFN-γ protein of Agapornis fischeri. This study is the first to describe the cloning of the IFN-γ gene of Agapornis fischeri and characterize the anti-beak and feather disease virus activity of the IFN-γ protein of Agapornis fischeri.

Characterization of the nuclear localization sequence of beak and feather disease virus capsid proteins and their assembly into virus-like particles.

Beak and feather disease virus (BFDV) is a single-stranded circular DNA icosahedral virus that belongs to the Circoviridae family. This virus is the causative pathogen of beak and feather disease, which leads to feather loss, malformed claws, and immunosuppression of psittacine birds. Our study produced BFDV virus-like particles (VLPs) including capsid proteins, mutant Cap proteins (Cap ΔNLS54, Cap ΔNLS62, Cap C228S, and Cap ΔNES) and chimeric Cap proteins carrying the epitope (amino acid residues 64-70) of the replication-associated protein (R-Cap, Cap-R, R-Cap ΔNLS54, and Cap ΔNLS54-R). All of the aforementioned VLPs were observed via transmission electron microscopy and verified through immunogold labeling. The nuclear localization sequence (NLS) of the Cap protein was identified between amino acid residues 55-62. Nuclear export of the Cap protein depended on the nuclear export sequence (NES). All VLPs except Cap ΔNLS62 and Cap ΔNES entered the cells 2 h post-infection (hpi) and were shuttled into the nucleus at 8 hpi. Wheat germ agglutinin (WGA) blocked the nuclear entry of Cap proteins at 8 hpi and the nuclear export of Cap proteins at 16 hpi was inhibited by leptomycin B. The nuclear entry of Cap protein was inhibited by importin α and importin ß inhibitors, as well as NLS peptides. Moreover, the interactions of Cap proteins and Cap VLPs with both importin α and importin ß were characterized via the GST pull-down and immunofluorescence assays. These interactions were blocked by the presence of importin α and importin ß inhibitors, as well as NLS peptides. Therefore, our study is the first to describe the precise position of the NLS of the BFDV Cap protein and the interaction of Cap protein with importin α and importin ß in vitro.

Characterization of the endonuclease activity of the replication-associated protein of beak and feather disease virus.

Beak and feather disease virus (BFDV) belongs to the family Circoviridae. A rolling-circle replication strategy based on a replication-associated protein (Rep) has been proposed for BFDV. The Rep gene of BFDV was expressed and purified, and it was shown to cleave short oligonucleotides containing the conserved nonanucleotide sequence found in the replication origin of circoviruses. This endonuclease activity was most efficient in the presence of the divalent metal ions Mg2+ and Mn2+. Rep proteins containing mutation in the ATPase/GTPase motifs and the 14FTLNN18, 61KKRLS65, 89YCSK92, and 170GKS172 motifs lacked endonuclease activity. The endonuclease activity was not affected by ATPase inhibitors, with the exception of N-ethylmaleimide (NEM), or by GTPase inhibitors, but it was decreased by treatment with the endonuclease inhibitor L-742001. Both the ATPase and GTPase activities were decreased by site-directed mutagenesis and deletion of the ATPase/GTPase and endonuclease motifs. The Rep protein was able to bind a double-stranded DNA fragment of P36 (dsP36) containing the stem-loop structure of the replication origin of BFDV. All of the Rep mutant proteins showed reduced ability to bind this fragment, suggesting that all the ATPase/GTPase and endonuclease motifs are involved in the binding. Other than NEM, all ATPase, GTPase, and endonuclease inhibitors inhibited the binding of the Rep protein to the dsP36 fragment. This is the first report describing the endonuclease activity of the Rep protein of BFDV.

Dual ATPase and GTPase activity of the replication-associated protein (Rep) of beak and feather disease virus.

BACKGROUND: Psittacine beak and feather disease affects parrots resulting in an immunosuppressive disease that is often characterized by an abnormal shape and growth of the animal's beak, feathers, and claws. Beak and feather disease virus (BFDV) is a single-stranded circular DNA virus and is classified as a member of the Circoviridae family. Two major open reading frames (ORFs) are known to encode the replication-associated (Rep) protein and the capsid-associated (Cap) protein. METHODS: The Rep and Cap genes of BFDV were fused with tags and then expressed and purified, respectively. Both the ATPase and GTPase activities of the recombinant Rep protein are measured. The substrate and ion preference, the optimal conditions, the effects of ATPase and GTPase inhibitors and the presence of Cap protein on the ATPase and GTPase activity of the Rep protein are examined. Finally, the effects of the Walker A motif, the Walker B motif, and a novel GYDG motif of the Rep protein on the ATPase and GTPase activities are studied by various mutants. RESULTS: The recombinant Rep protein could display ATPase activity and GTPase activity. The Rep protein was able to hydrolyze both deoxyribonucleotides and ribonucleotides. Among nucleoside triphosphates and deoxynucleoside triphosphates, the substrate preference orders were found to be ATP>GTP>CTP≥UTP and dATP>dGTP>dTTP>dCTP, respectively. Both the ATPase and GTPase activity of the BFDV Rep protein required magnesium ions and the presence of calcium ions significantly inhibited the ATPase and GTPase activity of the Rep protein. The optimal temperatures for ATPase activity and GTPase activity were both 56 °C, while their optimal pH values were both pH 7.5. Both the ATPase activity and GTPase activity of the BFDV Rep protein were significantly down-regulated by polynucleotides and the dsDNA of 36 bp (located in origin of replication) of BFDV genome. The ATPase activity of the BFDV Rep protein was found to be more sensitive to sodium azide than sodium orthovanadate and N-ethylmaleimide. Linoleic acid more strongly inhibited the GTPase activity of the Rep protein than dynasore. This suggested the Rep protein of BFDV should be classified as an F-type ATPase and polyunsaturated fatty acid-sensitive GTPase. In the presence of 10 ng of the Cap protein, the ATPase activity and GTPase activity of the BFDV Rep protein were significantly increased. Furthermore, the BFDV Rep protein contains the Walker A motif, the Walker B motif and a novel GYDG motif. Both the ATPase activity and the GTPase activity of various deletion and site-directed mutants of the Rep protein affecting these motifs were significantly reduced, suggesting all the three motifs contribute to the ATPase and GTPase activities; specifically. In addition, the ATPase activity and GTPase activity of the deletion mutants of the Rep protein were reversed in the presence of the Cap protein. This is the first example of dual ATPase and GTPase activity being reported in the Rep protein of BFDV.