Jing Hu scite author profile

The roles of various plasma agents in the inactivation of bacteria have recently been investigated. However, up to now, the effect of the charged particles on the inactivation of bacteria is not well understood. In this paper, an atmospheric pressure plasma jet device, which generates a cold plasma plume carrying a peak current of 300 mA, is used to investigate the role of the charged particles in the inactivation process. It is found that the charged particles play a minor role in the inactivation process when He/N2(3%) is used as working gas. On the other hand, when He/O2(3%) is used, the charged particles are expected to play an important role in the inactivation of bacteria. Further analysis shows that the negative ions O2− might be the charged particles that are playing the role. Besides, it is found that the active species, including O, O3, and metastable state O2∗, can play a crucial role in the inactivation of the bacteria. However, the excited He∗, N2 C Π3u, and N2+ B Σ2u+ have no significant direct effect on the inactivation of bacteria. It is also concluded that heat and UV play no or minor role in the inactivation process.

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Association of RNA Helicase A with Human Immunodeficiency Virus Type 1 Particles

Roy

Guo

et al. 2006

Journal of Biological Chemistry

132

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RNA helicase A (RHA) belongs to the DEAH family of proteins that are capable of unwinding double-stranded RNA structure. In addition to its involvement in the metabolism of cellular RNA, RHA has been shown to stimulate RNA transcription from the long terminal repeat promoter of human immunodeficiency virus type 1 (HIV-1) as well as to enhance Rev/Rev response element-mediated gene expression. In this study, we provide evidence that RHA associates with HIV-1 Gag in an RNA-dependent manner. This interaction results in specific incorporation of RHA into HIV-1 particles. Knockdown of endogenous RHA in virus producer cells leads to generation of HIV-1 particles that are less infectious in part as a result of restricted reverse transcription. Therefore, RHA represents the first example of cellular RNA helicases that participate in HIV-1 particle production and promote viral reverse transcription. RNA helicase A (RHA)2 is a member of the DEXH-box (where X can be any amino acid) family of proteins and is also termed DHX9 (1, 2). The DEXH-box proteins, together with the DEAD-box and the Ski2 family members, are referred to as RNA helicases that are able to rearrange the structures of RNA molecules (3). RHA contains a helicase core domain consisting of seven motifs that are conserved for all RNA helicases. Within the N-terminal region of RHA there are two copies of type A double-stranded RNA binding domains. Together with an RGG-box domain located at the C terminus, double-stranded RNA binding domains regulate RNA binding as well as helicase activities of RHA (4). RHA is a nuclear protein and shuttles between the nucleus and the cytoplasm with the assistance of a bidirectional nuclear transport domain consisting of 110 amino acids at the C terminus (5). This function of the RHA nuclear transport domain is subject to regulation of arginine methylation catalyzed by PRMT1 (protein-arginine methyltransferase 1) (6). RHA is able to unwind double-stranded RNA or DNA with the energy derived from hydrolysis of NTPs by virtue of its NTPase activity (1). This property enables RHA to participate in multiple cellular processes from RNA transcription to RNA processing to RNA nuclear export (7). These multiple functions underlie the vital role of RHA in the germ line proliferation and development of Caenorhabditis elegans (8) and also account for the early embryonic lethality observed with RHA knock-out mice (9).The regulation activity of RHA in RNA transcription is implicated by its presence within the RNA polymerase II holoenzyme complex. For example, RHA has been shown to bridge the interactions between RNA polymerase II and transcription co-activators such as CREB-binding protein and BRAC1 (breast cancer-specific tumor suppressor protein 1) (10, 11). RHA also directly interacts with the p65 subunit of NF-B and stimulates NF-B-mediated reporter gene expression (12). Involvement of RHA in transcription is further indicated by the function of its homologue in Drosophila, named the maleless (MLE) gene, that increases gene expression fr...

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Characterization of a Putative α-Helix across the Capsid-SP1 Boundary That Is Critical for the Multimerization of Human Immunodeficiency Virus Type 1 Gag

Liang

Russell

et al. 2002

J Virol

103

120

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A 14-amino-acid spacer peptide termed SP1 that separates the capsid (CA) and nucleocapsid (NC) sequences plays an active role in the assembly of human immunodeficiency virus type 1. This activity of SP1 involves its amino-terminal residues that, together with adjacent CA residues, constitute a putative ␣-helical structure spanning Gag residues from positions 359 to 371. In this study, we have determined that the virus assembly determinants within this putative ␣-helix were residues H359, K360, A361, L364, A367, and M368, of which K360 and A367 contribute to virus production to lesser extents. Notably, changes of the two basic amino acids H359 and K360 to arginine (R) impaired virus production, whereas mutations L364I and M368I, in contrast to L364A and M368A, generated near-wild-type levels of virus particles. This suggests that within Gag complexes, amino acids H359 and K360 are involved in stricter steric interactions than L364 and M368. Since L364 and M368 are separated by four residues and thus presumably located on the same side of the helical surface, they may initiate synergistic hydrophobic interactions to stabilize Gag association. Further analysis in the context of the protease-negative mutation D185H confirmed the key roles of amino acids H359, A361, L364, and M368 in virus assembly. Importantly, when transfected cells were subjected to Dounce homogenization and the cell lysates were treated by ultracentrifugation at 100,000 ؋ g, Gag molecules containing each of the H359A, A361V, L364A, and M368A mutations were found mainly in the supernatant fraction (S100), whereas approximately 80% of wild-type Gag proteins were found in the pellet. Therefore, these four mutations must have prevented Gag from generating large complexes.

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A Structurally Disordered Region at the C Terminus of Capsid Plays Essential Roles in Multimerization and Membrane Binding of the Gag Protein of Human Immunodeficiency Virus Type 1

Liang

Whitney

et al. 2003

J Virol

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Crystal structures of human immunodeficiency virus type 1 (HIV-1) capsid protein (CA) reveal that the last 11 C-terminal amino acids are disordered. This disordered region contains a glycine-rich sequence 353-GVGGP-357 (numbering refers to the initiation methionine of Gag) that is highly conserved within the Gag proteins of HIV-1, HIV-2, and simian immunodeficiency virus, which suggests the importance of this sequence in virus replication. In the present study, we demonstrate that changing any individual residue within this short region in the context of the full-length HIV-1 genome virtually abolishes production of extracellular virus particles, in either the presence or absence of viral protease activity. This severe defect in virus particle production results from impaired Gag multimerization, as well as from decreased Gag association with the cellular membranes, as demonstrated by the results of gradient sedimentation and membrane flotation centrifugation assays. These findings are further supported by the diffuse distribution pattern of the mutant Gag within the cytoplasm, as opposed to the punctate distribution of the wild-type Gag on the plasma membrane. On the basis of these results, we propose that the disordered feature of amino acid stretch 353-GVGGP-357 in the CA crystal forms may have allowed Gag to adopt multiple conformations and that such structural flexibility is needed by Gag in order to construct geometrically complex particles.

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Jing Hu

The roles of the various plasma agents in the inactivation of bacteria

Association of RNA Helicase A with Human Immunodeficiency Virus Type 1 Particles

Characterization of a Putative α-Helix across the Capsid-SP1 Boundary That Is Critical for the Multimerization of Human Immunodeficiency Virus Type 1 Gag

A Structurally Disordered Region at the C Terminus of Capsid Plays Essential Roles in Multimerization and Membrane Binding of the Gag Protein of Human Immunodeficiency Virus Type 1

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