Research pedagogy in a UK radiography education setting.

INTRODUCTION: This paper focuses on research pedagogy in radiography and the importance of research for the profession by exploring one university's endeavours to realise the aims of The Society and College of Radiographers Research Strategy 2016-20211 around embedding research in the curriculum. METHODS: Co-Constructed Depiction method was developed as an innovative use of imagery in data collection, analysis, and presentation of results, being symbolic of the practices of the radiography profession by foregrounding the importance of images and their interpretation. A total of eighteen radiography staff, post-graduate radiography students, and 3rd year radiography undergraduate students from both Diagnostic and Therapeutic professional backgrounds and courses took part in individual semi-structured interviews that included participant image making. RESULTS: Students and educators saw the importance of research for individuals and the profession. While students could identify where research was embedded in the curriculum, generally staff did not feel embedding was done well, but this may be because research is not made explicit enough in the curriculum. Participants suggested that research needs to become 'normalised'; being a part of all radiographers' work. CONCLUSION: The links between research, professionalism, and care can be made more evident to students from the start of their studies so increasing understanding of their own relationship with the spectrum of research, and how this links to maintaining the standing of our profession and to patient care. IMPLICATIONS FOR PRACTICE: The findings will inform future research pedagogy and undergraduate curriculum development in radiography and other Allied Health Professions around embedding research in the curriculum in a way that educators and students recognise.

The human rhinovirus internal cis-acting replication element (cre) exhibits disparate properties among serotypes.

It has been reported previously that the Human rhinovirus 14 (HRV-14) RNA genome contains a cis-acting replication element (cre) that maps to the capsid coding (P1) sequence [19]. Further characterization of the HRV-14 cre in the present study established that by moving the cre stem-loop structure downstream, adjacent to the 3'NCR, that its position is not critical for function. When the P1 sequences of two closely related serotypes of HRV-14 were analyzed for the presence of a cre, both HRV-3 and HRV-72 were found to contain similar sequence at the same positions as HRV-14. Moreover, sequence at these positions produced structures from MFOLD analysis that closely resembled the HRV-14 cre. It was also discovered that neither HRV serotypes 1a or 16 harbor replication elements that map to the P1 segments of their genomes. Computer and mutational analyses suggest that the cre in these latter HRV serotypes map instead to the 2A gene, as has been reported for HRV-2. The putative HRV-3 cre was determined to be unable to support replication when placed in an HRV-14 replicon background. Similarly, the previously identified HRV-2 cre was unable to support replication of the HRV-14 genome. This finding is in contrast to the cardiovirus cre, which has been shown to be functionally active between two members of its family, and further suggests that there is a close link between the evolution of the human rhinoviruses and the mechanisms of RNA replication.

Membrane-associated respiratory syncytial virus F protein expressed from a human rhinovirus type 14 vector is immunogenic.

Human rhinovirus (HRV) replicons have the potential to serve as respiratory vaccine vectors for mucosal immunization in humans. However, since many vaccine immunogens of interest are glycosylated, an important concern is whether HRV replicons are capable of expressing glycosylated proteins. The human respiratory syncytial virus (RSV) fusion (F) protein was chosen as a model glycoprotein and the HRV replicon DeltaP1FVP3 was generated by inserting the F protein-coding sequence in frame and in lieu of the 5' proximal 1489 nucleotides of the capsid-coding segment in the HRV-14 genome. When transfected into H1-HeLa cells, DeltaP1FVP3 replicated and led to the expression of the F protein. Inhibition with guanidine demonstrated that F-protein expression was dependent on DeltaP1FVP3 replication and did not result from translation of input RNA. Although most of the F protein remained as an immature, glycosylated precursor (F0), a readily detectable fraction of the protein was processed into the mature glycosylated subunit F1, an event known to occur within the Golgi apparatus. Packaged DeltaP1FVP3 replicons were generated in transfected HeLa cells by coexpression of homologous HRV capsid proteins using the vaccinia virus/T7 RNA polymerase hybrid system. Packaged replicon RNAs were capable of infecting fresh cells, leading to accumulation of the F protein as in RNA-transfected cells. Mice immunized with HeLa cell lysates containing F protein expressed from DeltaP1FVP3 produced neutralizing antibodies against RSV. These results indicate that an HRV-14 replicon can express a foreign glycosylated protein, providing further support for the potential of HRV replicons as a vaccine delivery system.

The rhinovirus type 14 genome contains an internally located RNA structure that is required for viral replication.

Cis-acting RNA signals are required for replication of positive-strand viruses such as the picornaviruses. Although these generally have been mapped to the 5' and/or 3' termini of the viral genome, RNAs derived from human rhinovirus type 14 are unable to replicate unless they contain an internal cis-acting replication element (cre) located within the genome segment encoding the capsid proteins. Here, we show that the essential cre sequence is 83-96 nt in length and located between nt 2318-2413 of the genome. Using dicistronic RNAs in which translation of the P1 and P2-P3 segments of the polyprotein were functionally dissociated, we further demonstrate that translation of the cre sequence is not required for RNA replication. Thus, although it is located within a protein-coding segment of the genome, the cre functions as an RNA entity. Computer folds suggested that cre sequences could form a stable structure in either positive- or minus-strand RNA. However, an analysis of mutant RNAs containing multiple covariant and non-covariant nucleotide substitutions within these putative structures demonstrated that only the predicted positive-strand structure is essential for efficient RNA replication. The absence of detectable minus-strand synthesis from RNAs that lack the cre suggests that the cre is required for initiation of minus-strand RNA synthesis. Since a lethal 3' noncoding region mutation could be partially rescued by a compensating mutation within the cre, the cre appears to participate in a long-range RNA-RNA interaction required for this process. These data provide novel insight into the mechanisms of replication of a positive-strand RNA virus, as they define the involvement of an internally located RNA structure in the recognition of viral RNA by the viral replicase complex. Since internally located RNA replication signals have been shown to exist in several other positive-strand RNA virus families, these observations are potentially relevant to a wide array of related viruses.

Capsid coding sequence is required for efficient replication of human rhinovirus 14 RNA.

Mechanisms by which the plus-sense RNA genomes of picornaviruses are replicated remain poorly defined, but existing models do not suggest a role for sequences encoding the capsid proteins. However, candidate RNA replicons (delta P1 beta gal and delta P1Luc), representing the sequence of human rhinovirus 14 virus (HRV-14) with reporter protein sequences (beta-galactosidase or luciferase, respectively) replacing most of the P1 capsid-coding region, failed to replicate in transfected H1-HeLa cells despite efficient primary cleavage of the polyprotein. To determine which P1 sequences might be required for RNA replication, HRV-14 mutants in which segments of the P1 region were removed to frame from the genome were constructed. Mutants with deletions involving the 5'proximal 1,489 nucleotides of the P1 region replicated efficiently, while those with deletions involving the 3' 1,079 nucleotides did not. Reintroduction of the 3' P1 sequence into the nonreplicating delta P1Luc construct resulted in a new candidate replicon, delta P1Luc/VP3, which replicated well and expressed luciferase efficiently. Capsid proteins provided in trans by helper virus failed to rescue the nonreplicating delta P1Luc genome but were able to package the larger-than-genome-length delta P1Luc/VP3 replicon. Thus, a 3'-distal P1 capsid-coding sequence has a previously unrecognized cis-active function related to replication of HRV-14 RNA.

Deduced consensus sequence of Sindbis virus strain AR339: mutations contained in laboratory strains which affect cell culture and in vivo phenotypes.

The consensus sequence of the Sindbis virus AR339 isolate, the prototype alphavirus, has been deduced. THe results presented here suggest (i) that a substantial proportion of the sequence divergence evident between the consensus sequence and sequences of laboratory strains of AR339 has resulted from selection for efficient growth in cell culture, (ii) that many of these changes affect the virulence of the virus in animal models, and (iii) that such modified genetic backgrounds present in laboratory strains can exert a significant influence on genetic studies of virus pathogenesis and host range. A laboratory strain of Sindbis virus AR339 was sequenced and cloned as a cDNA (pTRSB) from which infectious virus (TRSB) could be derived. The consensus sequence was deduced from the complete sequences of pTRSB and HRsp (E. G. Strauss, C. M. Rice, and J. H. Strauss, Virology 133:92-110, 1984), from partial sequences of the glycoprotein genes of three other AR339 laboratory strains, and by comparison with the sequences of the glycoprotein genes of three other AR339 sequence. HRsp differed form the consensus sequence by eight coding changes, and TRSB differed by three coding changes. In the 5' untranslated region, HRsp differed from the consensus sequence at nucleotide (nt) 5. These differences were likely the result of cell culture passage of the original AR339 isolate. At three of the difference loci (one in TRSB and two in HRsp), selection of cell-culture-adaptive mutations was documented with Sindbis virus or other alphaviruses. Selection in cell culture often results in attenuation of virulence in animals. Considering the TRSB and HRsp sequences together, one noncoding difference from the consensus (an A-for-G substitution in the 5' untranslated region at nt 5) and six coding differences in the glycoprotein genes (at E2 amino acids 1, 3, 70, and 172 and at E1 amino acids 72 and 237) were at loci which, either individually or in combination, significantly affected alphavirus virulence in mice. Although the levels of virulence of isogenic strains containing either nt 5 A or nt 5 G did not differ significantly in neonatal mice, the presence of nt 5 A greatly enhanced the effect of a second attenuating mutation in the E2 gene. These results suggest that minimal differences in the "wild type" genetic background into which an additional mutation is introduced can have a dramatic effect on apparent virulence and pathogenesis phenotypes. A cDNA clone of the consensus AR339 sequence, a sequence devoid of occult attenuating mutations introduced by cell culture passage, will allow the molecular genetic examination of cell culture and in vivo phenotypes of a virus which may best reflect the sequence of Sindbis virus AR339 at the time of its isolation.

Mutations within the 5' nontranslated RNA of cell culture-adapted hepatitis A virus which enhance cap-independent translation in cultured African green monkey kidney cells.

Mutations in the 5' nontranslated RNA (5'NTR) of an attenuated, cell culture-adapted hepatitis A virus (HAV), HM175/P16, enhance growth in cultured African green monkey kidney (BS-C-1) cells but not in fetal rhesus monkey kidney (FRhK-4) cells (S. P. Day, P. Murphy, E. A. Brown, and S. M. Lemon, J. Virol. 66: 6533-6540, 1992). To determine whether these mutations enhance cap-independent translation directed by the HAV internal ribosomal entry site (IRES), we compared the translational activities of the 5'NTRs of wild-type and HM175/P16 viruses in two stably transformed cell lines (BT7-H and FRhK-T7) which constitutively express cytoplasmic bacteriophage T7 RNA polymerase and which are derived from BS-C-1 and FRhK-4 cells, respectively. Translational activity was assessed by monitoring expression of a reporter protein, chloramphenicol acetyltransferase (CAT), following transfection with plasmid DNAs containing bicistronic T7 transcriptional units of the form luciferase-5'NTR-CAT. In both cell types, transcripts containing the 5'NTR of HM175/P16 expressed CAT at levels that were 50- to 100-fold lower than transcripts containing the IRES elements of Sabin type 1 poliovirus or encephalomyocarditis virus, confirming the low activity of the HAV IRES. However, in BT7-H cells, transcripts containing the 5'NTR of wild-type virus. This translational enhancement was due to additive effects of a UU deletion at nucleotides 203 and 204 and a U-to-G substitution at nucleotide 687 of HM175/P16. These mutations did not enhance translation in FRhK-T7 or Huh-T7 cells (a T7 polymerase-expressing cell line derived from human hepatoblastoma cells) or in vitro in rabbit reticulocyte lysates. These results demonstrate that mutations in the 5'NTR of a cell culture-adapted HAV enhance viral replication by facilitating cap-independent translation in a cell-type-specific fashion and support the concept that picornaviral host range is determined in part by differences in cellular translation initiation factors.

Lethality of PE2 incorporation into Sindbis virus can be suppressed by second-site mutations in E3 and E2.

Sindbis virions contain two glycoproteins, E1 and E2. E2 is produced initially as a precursor, PE2, from which the amino-terminal 64 amino acids are cleaved by a cellular protease at a late stage in virion maturation. A mutation at E2 position 1 (Arg to Asn) was placed into Sindbis virus AR339 by site-directed mutagenesis of a full-length AR339 cDNA clone, pTRSB, to produce pTRSB-N. The mutation created a signal for N-linked glycosylation immediately adjacent to the PE2 cleavage signal. Virions derived from pTRSB-N were glycosylated at E2 position 1, and they quantitatively incorporated PE2 in place of E2. When pTRSB-N transcripts were electroporated into BHK-21 cells, TRSB-N particles were released with nearly normal efficiency; however, the specific infectivity of TRSB-N particles was very low. Analysis of seven infectious revertants of TRSB-N revealed that reversion was linked to (i) mutations that eliminated the signal for N-linked glycosylation and thus restored the PE2 cleavage phenotype or (ii) conservation of the PE2 cleavage defect combined with incorporation of suppressor mutations in E3 or E2. The genotype of each revertant was reconstructed in the genetic background of TRSB-N, and each reverting mutation also was replaced individually into the genetic background of wild-type virus (TRSB). Each PE2-containing revertant was attenuated in newborn CD-1 mice and replicated poorly in cultured mosquito cells (C6/36). Reverting mutations in the genetic background of TRSB did not reduce virulence in mice or growth in mosquito cells, suggesting that the phenotypes of attenuation in mice and reduced growth in mosquito cells were linked to failure of PE2 cleavage and not to the reverting mutations themselves.