Lena Marmstål Hammar

Essential Elements of the Capsid Protein for Self-Assembly into Empty Virus-Like Particles of Hepatitis E Virus

ABSTRACT Hepatitis E virus (HEV) is a noncultivable virus that causes acute liver failure in humans. The viruss major capsid protein is encoded by an open reading frame 2 (ORF2) gene. When the recombinant protein consisting of amino acid (aa) residues 112 to 660 of ORF2 is expressed with a recombinant baculovirus, the protein self-assembles into virus-like particles (VLPs) (T.-C. Li, Y. Yamakawa, K. Suzuki, M. Tatsumi, M. A. Razak, T. Uchida, N. Takeda, and T. Miyamura, J. Virol. 71:7207-7213, 1997). VLPs can be found in the culture medium of infected Tn5 cells but not in that of Sf9 cells, and the major VLPs have lost the C-terminal 52 aa. To investigate the protein requirement for HEV VLP formation, we prepared 14 baculovirus recombinants to express the capsid proteins truncated at the N terminus, the C terminus, or both. The capsid protein consisting of aa residues 112 to 608 formed VLPs in Sf9 cells, suggesting that particle formation is dependent on the modification process of the ORF2 protein. In the present study, electron cryomicroscopy and image processing of VLPs produced in Sf9 and Tn5 cells indicated that they possess the same configurations and structures. Empty VLPs were found in both Tn5 and Sf9 cells infected with the recombinant containing an N-terminal truncation up to aa residue 125 and C-terminal to aa residue 601, demonstrating that the aa residues 126 to 601 are the essential elements required for the initiation of VLP assembly. The recombinant HEV VLPs are potential mucosal vaccine carrier vehicles for the presentation of foreign antigenic epitopes and may also serve as vectors for the delivery of genes to mucosal tissue for DNA vaccination and gene therapy. The results of the present study provide useful information for constructing recombinant HEV VLPs having novel functions.

Multistep Regulation of Membrane Insertion of the Fusion Peptide of Semliki Forest Virus

ABSTRACT A prevailing model for virus membrane fusion proteins has been that the hydrophobic fusion peptide is hidden in the prefusion conformation, becomes exposed once the fusion reaction is triggered, and then either inserts into target membranes or is rapidly inactivated. This model is in general agreement with the structure and mechanism of class I fusion proteins, such as the influenza virus hemagglutinin. We here describe studies of the class II fusion protein E1 from the alphavirus Semliki Forest virus (SFV). SFV fusion is triggered by low pH, which releases E1 from its heterodimeric interaction with the E2 protein and induces the formation of a stable E1 homotrimer. The exposure and target membrane interaction of the E1 fusion peptide (residues 83 to 100) were followed using a monoclonal antibody (MAb E1f) mapping to E1 residues 85 to 95. In agreement with the known structure of SFV and other alphaviruses, the fusion peptide was shielded in native SFV particles and exposed when E1-E2 dimer dissociation was triggered by acidic pH. In contrast, the fusion peptide on purified E1 ectodomains (E1*) was fully accessible at neutral pH. Functional assays showed that MAb E1f binding at neutral pH prevented subsequent low-pH-triggered E1* interaction with target membranes and trimerization. E1* was not inactivated by low pH when treated either in the absence of target membranes or in the presence of fusion-inactive cholesterol-deficient liposomes. Thus, the membrane insertion of the E1 fusion peptide is regulated by additional low-pH-dependent steps after exposure, perhaps involving an E1-cholesterol interaction.

Structure and Assembly of a T=1 Virus-Like Particle in BK Polyomavirus

ABSTRACT In polyomaviruses the pentameric capsomers are interlinked by the long C-terminal arm of the structural protein VP1. The T=7 icosahedral structure of these viruses is possible due to an intriguing adaptability of this linker arm to the different local environments in the capsid. To explore the assembly process, we have compared the structure of two virus-like particles (VLPs) formed, as we found, in a calcium-dependent manner by the VP1 protein of human polyomavirus BK. The structures were determined using electron cryomicroscopy (cryo-EM), and the three-dimensional reconstructions were interpreted by atomic modeling. In the small VP1 particle, 26.4 nm in diameter, the pentameric capsomers form an icosahedral T=1 surface lattice with meeting densities at the threefold axes that interlinked three capsomers. In the larger particle, 50.6 nm in diameter, the capsomers form a T=7 icosahedral shell with three unique contacts. A folding model of the BKV VP1 protein was obtained by alignment with the VP1 protein of simian virus 40 (SV40). The model fitted well into the cryo-EM density of the T=7 particle. However, residues 297 to 362 of the C-terminal arm had to be remodeled to accommodate the higher curvature of the T=1 particle. The loops, before and after the C-terminal short helix, were shown to provide the hinges that allowed curvature variation in the particle shell. The meeting densities seen at the threefold axes in the T=1 particle were consistent with the triple-helix interlinking contact at the local threefold axes in the T=7 structure.

Acid-induced movements in the glycoprotein shell of an alphavirus turn the spikes into membrane fusion mode

In the icosahedral (T = 4) Semliki Forest virus, the envelope protomers, i.e. E1–E2 heterodimers, make one‐to‐one interactions with capsid proteins below the viral lipid bilayer, transverse the membrane and form an external glycoprotein shell with projections. The shell is organized by protomer domains interacting as hexamers and pentamers around shell openings at icosahedral 2‐ and 5‐fold axes, respectively, and the projections by other domains associating as trimers at 3‐ and quasi 3‐fold axes. We show here, using cryo‐ electron microscopy, that low pH, as occurs in the endosomes during virus uptake, results in the relaxation of protomer interactions around the 2‐ and the 5‐fold axes in the shell, and movement of protomers towards 3‐ and quasi 3‐fold axes in a way that reciprocally relocates their putative E1 and E2 domains. This seemed to be facilitated by a trimerization of transmembrane segments at the same axes. The alterations observed help to explain several key features of the spike‐mediated membrane fusion reaction, including shell dissolution, heterodimer dissociation, fusion peptide exposure and E1 homotrimerization.

The Dynamic Envelope of a Fusion Class II Virus PREFUSION STAGES OF SEMLIKI FOREST VIRUS REVEALED BY ELECTRON CRYOMICROSCOPY

Semliki Forest virus is among the prototypes for Class II virus fusion and targets the endosomal membrane. Fusion protein E1 and its envelope companion E2 are both anchored in the viral membrane and form an external shell with protruding spikes. In acid environments, mimicking the early endosomal milieu, surface epitopes in the virus rearrange along with exposure of the fusion loop. To visualize this transformation into a fusogenic stage, we determined the structure of the virus at gradually lower pH values. The results show that while the fusion loop is available for external interaction and the shell and stalk domains of the spike begin to deteriorate, the E1 and E2 remain in close contact in the spike head. This unexpected observation points to E1 and E2 cooperation beyond the fusion loop exposure stage and implies a more prominent role for E2 in guiding membrane close encounter than has been earlier anticipated.

Finding the key to communion – Caregivers’ experience of ‘music therapeutic caregiving’ in dementia care : A qualitative analysis

‘Music therapeutic caregiving’ (MTC), when caregivers sing for or together with persons with dementia (PWDs) during caring situations, has been suggested as a way to reduce PWDs’ behavioral and psychological symptoms of dementia (BPSD). An intervention was designed to elucidate what influences MTC might have on PWDs and their caregivers. The aim was to describe professional caregiverś experiences of caring for PWDs during morning care situations without and with MTC. Group interviews were conducted, and a qualitative content analysis was performed. Two themes were revealed. The first (without MTC), Struggling for care in communion, encompassed four sub-themes: Hampered communication; Physical and mental struggle with aggression; Struggling with ethical demands; and The reward — consolation and love. The second theme (with MTC), Consolidating care in communion, encompassed two sub-themes: awakening cooperation, and feeling of well-being. The authors conclude that MTC could be used to help caregivers provide improved care.

Reactions of Persons with Dementia to Caregivers Singing in Morning Care Situations

’Music therapeutic caregiving’, when caregivers sing for or together with persons with severe dementia during care situations, has been suggested as a way to reduce problematic behaviors in dementia care. The present study implemented this technique as an intervention in dementia care. Six caregivers participated in group interviews about their experiences of morning care situations without and with’Music therapeutic caregiving’. Through a qualitative content analysis two themes emerged.’Being in a different reality’ was based on’usual’ morning care situations. The caregivers’ experienced the persons with dementia as absent-minded; communication and cooperation were difficult. The second theme,’Being present’, was based on morning care situations with the intervention. The caregivers described communication as enhanced; the persons with dementia expressed themselves more appropriately, making cooperation possible. The results indicate that’Music therapeutic caregiving’ might lead to a more positive experience of the person with dementia and seems to increase receptivity to caregiving.

The functional organization of the internal components of Rice dwarf virus.

The capsid structures of particles of Rice dwarf virus that consisted of different components, namely, intact particles, empty particles lacking the 12 segments of double-stranded RNA (dsRNA), and virus-like particles composed of only the P3 core and P8 outer capsid proteins, generated with a baculovirus gene-expression system, were determined by cryo-electron microscopy. Combining the results with those of biochemical analysis, we assigned proteins of the transcriptional machinery and dsRNA to density clusters around the 5-fold axes and along the radial concentric layers, respectively. P7 protein, a component of the transcriptional machinery, was assigned to the outermost region of the density clusters. The density connecting the transcription complex to the outermost RNA densities implied interactions between the dsRNA and the P7 protein. Our structural analysis and the non-specific nucleic acid-binding activity of P7 explain the spiral organization of dsRNA around the 5-fold axis.

The Impact of Singing in Caring for a Person With Dementia : Single Case Analysis of Video Recorded Sessions

Music Therapeutic Caregiving (MTC), when a caregiver sings for or together with a resident with dementia, has been used to enhance communication between caregivers and residents. This single case s ...

Pleomorphic Configuration of the Trimeric Capsid Proteins of Rice dwarf virus that Allows Formation of Both the Outer Capsid and Tubular Crystals

In the double-shelled capsid of Phytoreovirus, the outer capsid attaches firmly to the 3-fold axes of the T=1 core. It then forms a T=13 lattice via lateral interactions among the P8 trimers (Wu et al., 2000, Virology 271, 18-25). Purified P8 molecules also assemble into hexagonal monolayers as well as tubular crystals. To explore the mechanisms of formation of these structures, the configurations of P8 trimers were compared and verified in particles of Rice dwarf virus and in tubular crystals (tubes) whose structure was determined by cryoelectron microscopy using helical reconstruction technique. Remarkable variations in intertrimer contacts were observed in the tubes and in the surface lattice of Rice dwarf virus capsid. Superposition of the atomic structure of P8 trimers in the structures analyzed by cryoelectron microscopy allowed us to identify groups of specific and stable interactions, some of which were preserved in the tubes and the quasi-equivalent T=13 icosahedral lattice of the virions shell. The flexible nature of the binding between P8 trimers, created via electrostatic interactions that hold radially inward, appears to allow the outer-capsid P8 trimers to envelop the ragged surface of the core, forming the double shell of an intact viral particle.