Human metapneumovirus (hMPV) is a recently described member of the Paramyxoviridae family/Pneumovirinae subfamily and shares many common features with respiratory syncytial virus (RSV), another member of the same subfamily. hMPV causes respiratory tract illnesses that, similar to human RSV, occur predominantly during the winter months and have symptoms that range from mild to severe cough, bronchiolitis, and pneumonia. Like RSV, the hMPV virus can be subdivided into two genetic subgroups, A and B. With RSV, a single monoclonal antibody directed at the fusion (F) protein can prevent severe lower respiratory tract RSV infection. Because of the high level of sequence conservation of the F protein across all the hMPV subgroups, this protein is likely to be the preferred antigenic target for the generation of cross-subgroup neutralizing antibodies. Here we describe the generation of a panel of neutralizing monoclonal antibodies that bind to the hMPV F protein. A subset of these antibodies has the ability to neutralize prototypic strains of both the A and B hMPV subgroups in vitro. Two of these antibodies exhibited high-affinity binding to the F protein and were shown to protect hamsters against infection with hMPV. The data suggest that a monoclonal antibody could be used prophylactically to prevent lower respiratory tract disease caused by hMPV.Respiratory viruses account for a large proportion of upper and lower respiratory tract illness in humans. In the past few decades, many etiological agents of respiratory tract illness have been identified. Of these, respiratory syncytial virus (RSV) is the single most important cause of respiratory infections during infancy and early childhood (29). However, only 60% of clinically attended respiratory infections of infants and children are of a known etiology (21). Recently, van den Hoogen et al. (26) discovered and described human metapneumovirus (hMPV) and revealed that it may account for a portion of these previously unclassified infections. Prospective and retrospective studies suggest that hMPV infections account for between 3% and 15% of respiratory tract infections (5,6,8
Expression of HIV-1 Vpr causes cell cycle G2 arrest, change in cell shape, and cell death over a large evolutionary distance ranging from human to yeast cells. As a step toward understanding these highly conserved Vpr functions, we have examined the effect of Vpr on cytoskeletal elements and the viability of fission yeast. We demonstrate that the changes in cell morphology induced by Vpr in fission yeast are caused by several underlying cellular abnormalities, including increased biosynthesis of chitin in the cell wall, disruption of the actin cytoskeleton, and altered polarity for cell growth. The extent of these cellular alterations and cell survival correlates with the level of vpr expression. Accompanying cell death, Vpr induces aberrant nuclear morphologies in fission yeast which are similar to those found during the apoptosis induced by Vpr in mammalian cells. The Vpr-induced cytopathic effects and cell death can be suppressed by treatment with pentoxifylline, a compound that inhibits HIV-1 viral replication and suppresses Vpr-induced cell cycle G2 arrest in human and fission yeast cells. The results presented here suggest that pentoxifylline suppresses the effects of Vpr by blocking interactions of Vpr with cellular proteins. Given that pentoxifylline has potential therapeutic value in blocking the effects of Vpr in HIV-infected patients, understanding the molecular mechanisms by which pentoxifylline antagonizes Vpr may have general implications for HIV therapy.
Viral protein R (Vpr) of human immunodeficiency virus type 1 induces G2 arrest in cells from distantly related eukaryotes including human and fission yeast through inhibitory phosphorylation of tyrosine 15 (Tyr15) on Cdc2. Since the DNA damage and DNA replication checkpoints also induce G2 arrest through phosphorylation of Tyr15, it seemed possible that Vpr induces G2 arrest through the checkpoint pathways. However, Vpr does not use either the early or the late checkpoint genes that are required for G2 arrest in response to DNA damage or inhibition of DNA synthesis indicating that Vpr induces G2 arrest by an alternative pathway. It was found that protein phosphatase 2A (PP2A) plays an important role in the induction of G2 arrest by Vpr since mutations in genes coding for a regulatory or catalytic subunit of PP2A reduce Vpr-induced G2 arrest. Vpr was also found to upregulate PP2A, supporting a model in which Vpr activates the PP2A holoenzyme to induce G2 arrest. PP2A is known to interact genetically in fission yeast with the Wee1 kinase and Cdc25 phosphatase that act on Tyr15 of Cdc2. Both Wee1 and Cdc25 play a role in Vpr-induced G2 arrest since a wee1 deletion reduces Vpr-induced G2 arrest and a direct in vivo assay shows that Vpr inhibits Cdc25. Additional support for both Wee1 and Cdc25 playing a role in Vpr-induced G2 arrest comes from a genetic screen, which identified genes whose overexpression affects Vpr-induced G2 arrest. For this genetic screen, a strain was constructed in which cell killing by Vpr was nearly eliminated while the effect of Vpr on the cell cycle was clearly indicated by an increase in cell length. Overexpression of the wos2 gene, an inhibitor of Wee1, suppresses Vpr-induced G2 arrest while overexpression of rad25, an inhibitor of Cdc25, enhances Vpr-induced G2 arrest. These two genes may be part of the uncharacterized pathway for Vpr-induced G2 arrest in which Vpr upregulates PP2A to activate Wee1 and inhibit Cdc25.
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