A new pharmacological agent (AKB-4924) stabilizes hypoxia inducible factor-1 (HIF-1) and increases skin innate defenses against bacterial infection.

Hypoxia inducible factor-1 (HIF-1) is a transcription factor that is a major regulator of energy homeostasis and cellular adaptation to low oxygen stress. HIF-1 is also activated in response to bacterial pathogens and supports the innate immune response of both phagocytes and keratinocytes. In this work, we show that a new pharmacological compound AKB-4924 increases HIF-1 levels and enhances the antibacterial activity of phagocytes and keratinocytes against both methicillin-sensitive and methicillin-resistant strains of Staphylococcus aureus in vitro. AKB-4924 is also effective in stimulating the killing capacity of keratinocytes against the important opportunistic skin pathogens Pseudomonas aeruginosa and Acinetobacter baumanii. The effect of AKB-4924 is mediated through the activity of host cells, as the compound exerts no direct antimicrobial activity. Administered locally as a single agent, AKB-4924 limits S. aureus proliferation and lesion formation in a mouse skin abscess model. This approach to pharmacologically boost the innate immune response via HIF-1 stabilization may serve as a useful adjunctive treatment for antibiotic-resistant bacterial infections.

Nuclear localizations of the herpes simplex virus type 1 tegument proteins VP13/14, vhs, and VP16 precede VP22-dependent microtubule reorganization and VP22 nuclear import.

Herpes simplex virus type 1 (HSV-1) induces microtubule reorganization beginning at approximately 9 h postinfection (hpi), and this correlates with the nuclear localization of the tegument protein VP22. Thus, the active retention of this major virion component by cytoskeletal structures may function to regulate its subcellular localization (A. Kotsakis, L. E. Pomeranz, A. Blouin, and J. A. Blaho, J. Virol. 75:8697-8711, 2001). The goal of this study was to determine whether the subcellular localization patterns of other HSV-1 tegument proteins are similar to that observed with VP22. To address this, we performed a series of indirect immunofluorescence analyses using synchronously infected cells. We observed that tegument proteins VP13/14, vhs, and VP16 localized to the nucleus as early as 5 hpi and were concentrated in nuclei by 9 hpi, which differed from that seen with VP22. Microtubule reorganization was delayed during infection with HSV-1(RF177), a recombinant virus that does not produce full-length VP22. These infected cells did not begin to lose microtubule-organizing centers until 13 hpi. Repair of the unique long 49 (UL49) locus in HSV-1(RF177) yielded HSV-1(RF177R). Microtubule reorganization in HSV-1(RF177R)-infected cells occurred with the same kinetics as HSV-1(F). Acetylated tubulin remained unchanged during infection with either HSV-1(F) or HSV-1(RF177). Thus, while alpha-tubulin reorganized during infection, acetylated tubulin was stable, and the absence of full-length VP22 did not affect this stability. Our findings indicate that the nuclear localizations of tegument proteins VP13/14, VP16, and vhs do not appear to require HSV-1-induced microtubule reorganization. We conclude that full-length VP22 is needed for optimal microtubule reorganization during infection. This implies that VP22 mainly functions to reorganize microtubules later, rather than earlier, in infection. That acetylated tubulin does not undergo restructuring during VP22-dependent, virus-induced microtubule reorganization suggests that it plays a role in stabilizing the infected cells. Our results emphasize that VP22 likely plays a key role in cellular cytopathology during HSV-1 infection.

Mutation of the protein tyrosine kinase consensus site in the herpes simplex virus 1 alpha22 gene alters ICP22 posttranslational modification.

We previously reported that at least eight HSV-1 and five HSV-2 proteins were tyrosine phosphorylated in infected human and mouse cells and the first phosphotyrosine-modified gene product identified was the ICP22 regulatory protein (Blaho, J. A., Zong, C. S., and Mortimer, K. A., 1997, J. Virol. 71, 9828-9832). All electrophoretic forms of ICP22 are tyrosine phosphorylated with the exception of the fastest migrating (unmodified) isoform. We now report the following. (i) ICP22 that reacted with a specific anti-phosphotyrosine antibody contained a significant amount of phosphotyrosine based on phospho-amino acid analysis. These results validate the discovery of ICP22 tyrosine phosphorylation. (ii) Wild-type ICP22 extracted from infected HEp-2 cells migrated as at least seven isoforms, termed ICP22a-g, in denaturing gels. (iii) The primary structure of ICP22 possesses a sequence that is homologous to protein tyrosine kinase recognition sites. A virus, termed RF141, was generated in which ICP22 tyrosine(193) in the kinase target site was mutated to an alanine. (iv) Biochemical analyses of infected HEp-2 and primary HFF cells indicated that the distributions of ICP22 isoforms differed between RF141 and control HSV-1(F). (v) The accumulations of representative viral polypeptides in RF141-infected HEp-2 cells appeared similar to wild-type virus. (vi) RF141 had reduced efficiencies of plating in HFF cells compared to control Vero cells. These differences increased as the multiplicity of infection decreased. Based on these results, we conclude (vii) that ICP22 tyrosine(193) is required for optimal posttranslational modification of the protein in HSV-1 infected human epithelial HEp-2 and primary human fibroblast cells.