Correlative Cryo-imaging Using Soft X-Ray Tomography for the Study of Virus Biology in Cells and Tissues.

Viruses are obligate intracellular pathogens that depend on their host cell machinery and metabolism for their replicative life cycle. Virus entry, replication, and assembly are dynamic processes that lead to the reorganisation of host cell components. Therefore, a complete understanding of the viral processes requires their study in the cellular context where advanced imaging has been proven valuable in providing the necessary information. Among the available imaging techniques, soft X-ray tomography (SXT) at cryogenic temperatures can provide three-dimensional mapping to 25 nm resolution and is ideally suited to visualise the internal organisation of virus-infected cells. In this chapter, the principles and practices of synchrotron-based cryo-soft X-ray tomography (cryo-SXT) in virus research are presented. The potential of the cryo-SXT in correlative microscopy platforms is also demonstrated through working examples of reovirus and hepatitis research at Beamline B24 (Diamond Light Source Synchrotron, UK) and BL09-Mistral beamline (ALBA Synchrotron, Spain), respectively.

Metabolic Reprogramming in Colon Cancer Cells Persistently Infected with Newcastle Disease Virus.

Newcastle disease virus (NDV) is an oncolytic agent against various types of mammalian cancers. As with all cancer therapies, the development of cancer resistance, both innate and acquired, is becoming a challenge. In this study, we investigated persistently NDV-infected Caco-2 colon cancer cells, designated as virus-resistant (VR) Caco-2 cells, which were then able to resist NDV-mediated oncolysis. We applied single-cell Raman spectroscopy, combined with deuterium isotope probing (Raman-DIP) techniques, to investigate the metabolic adaptations and dynamics in VR Caco-2 cells. A linear discriminant analysis (LDA) model demonstrated excellent performance in differentiating VR Caco-2 from Caco-2 cells at single-cell level. By comparing the metabolic profiles in a time-resolved manner, the de novo synthesis of proteins and lipids was found upregulated, along with decreased DNA synthesis in VR Caco-2. The results suggest that VR Caco-2 cells might reprogram their metabolism and divert energy from proliferation to protein synthesis and lipidic modulation. The ability to identify and characterise single resistant cells among a population of cancer cells would help develop a deeper understanding of the resistance mechanisms and better tactics for developing effective cancer treatment.

Anemia control program in india needs to be more comprehensive.

Iron-deficiency anemia has continued to remain high in India. It is possibly due to relying on only iron-folic acid (IFA) supplementation through Anemia Control Program (ACP) that is National Iron Plus Initiative (NIPI). Based on the WHO's recommendations, we studied different interventions that can help to increase the effectiveness of NIPI such as Vitamin C supplementation with IFA, low-dose iron (LDI) with intensified health education (IHE), LDI with Vitamin C, and iron-rich food items to increase hemoglobin (Hb%) among adolescent girls through public-private partnership named Rashtriya Kishor Swasthya Karyakram. Increments in Hb after 12 weeks of interventions were compared with that of control groups one with NIPI and the other without any intervention. Highest increment in Hb% was observed in IFA under NIPI plus Vitamin C group, followed by LDI plus IHE group which was comparable to Hb increment in only the NIPI group. It emphasizes the need of making existing NIPI more stringent and comprehensive by integrating effective measures based on up-to-date scientific knowledge.

Correlative cryo-imaging of the cellular universe with soft X-rays and laser light used to track F-actin structures in mammalian cells.

Imaging of actin filaments is crucial due to the integral role that they play in many cellular functions such as intracellular transport, membrane remodelling and cell motility. Visualizing actin filaments has so far relied on fluorescence microscopy and electron microscopy/tomography. The former lacks the capacity to capture the overall local ultrastructure, while the latter requires rigorous sample preparation that can lead to potential artefacts, and only delivers relatively small volumes of imaging data at the thinnest areas of a cell. In this work, a correlative approach utilizing in situ super-resolution fluorescence imaging and cryo X-ray tomography was used to image bundles of actin filaments deep inside cells under near-native conditions. In this case, fluorescence 3D imaging localized the actin bundles within the intracellular space, while X-ray tomograms of the same areas provided detailed views of the local ultrastructure. Using this new approach, actin trails connecting vesicles in the perinuclear area and hotspots of actin presence within and around multivesicular bodies were observed. The characteristic prevalence of filamentous actin in cytoplasmic extensions was also documented.

Correlative imaging using super-resolution fluorescence microscopy and soft X-ray tomography at cryogenic temperatures provides a new way to assess virosome solutions for vaccine development.

Active virosomes (AVs) are derivatives of viruses, broadly similar to 'parent' pathogens, with an outer envelope that contains a bespoke genome coding for four to five viral proteins capable of eliciting an antigenic response. AVs are essentially novel vaccine formulations that present on their surface selected viral proteins as antigens. Once administered, they elicit an initial 'anti-viral' immune response. AVs are also internalised by host cells where their cargo viral genes are used to express viral antigen(s) intracellularly. These can then be transported to the host cell surface resulting in a second wave of antigen exposure and a more potent immuno-stimulation. A new 3D correlative microscopy approach is used here to provide a robust analytical method for characterisation of Zika- and Chikungunya-derivatised AV populations including vesicle size distribution and variations in antigen loading. Manufactured batches were compared to assess the extent and nature of batch-to-batch variations. We also show preliminary results that verify antigen expression on the surface of host cells. We present here a reliable and efficient high-resolution 3D imaging regime that allows the evaluation of the microstructure and biochemistry of novel vaccine formulations such as AVs.

A novel combination of microscopies involving X-ray and laser light has been developed at the correlative cryo-imaging beamline B24 of the UK synchrotron which can be used to analyse across- and within-batch variability of active virosome vaccine formulations. We use 3D fluorescence imaging to localise viral components within vaccine vesicles and soft X-ray tomography to characterise sample variability and impact upon delivery to cells. Moreover, we offer the next step in automation of data processing and evaluation to further enable rapid assessment of exosome-based vaccines. Active virosome vaccines are suspensions of membrane-bounded vesicles that carry antigens and genetic material from select viral pathogens. These elicit both an initial immune response through their introduction and a subsequent sustained antigenic potential via gene expression in host cells. In this case, as in all novel vaccine formulations, rapid assessment and batch standardisation are of paramount importance for the medical community and the methods described here provide a robust way of quick and efficient assessment and validation of formulations during research and development and at the production stages.

Cryo-Structured Illumination Microscopic Data Collection from Cryogenically Preserved Cells.

Three-dimensional (3D) structured illumination microscopy (SIM) allows imaging of fluorescently labelled cellular structures at higher resolution than conventional fluorescence microscopy. This super-resolution (SR) technique enables visualization of molecular processes in whole cells and has the potential to be used in conjunction with electron microscopy and X-ray tomography to correlate structural and functional information. A SIM microscope for cryogenically preserved samples (cryoSIM) has recently been commissioned at the correlative cryo-imaging beamline B24 at the UK synchrotron. It was designed specifically for 3D imaging of biological samples at cryogenic temperatures in a manner compatible with subsequent imaging of the same samples by X-ray microscopy methods such as cryo-soft X-ray tomography. This video article provides detailed methods and protocols for successful imaging using the cryoSIM. In addition to instructions on the operation of the cryoSIM microscope, recommendations have been included regarding the choice of samples, fluorophores, and parameter settings. The protocol is demonstrated in U2OS cell samples whose mitochondria and tubulin have been fluorescently labelled.

Genomic Diversity and Evolution of Quasispecies in Newcastle Disease Virus Infections.

Newcastle disease virus (NDV) infections are well known to harbour quasispecies, due to the error-prone nature of the RNA polymerase. Quasispecies variants in the fusion cleavage site of the virus are known to significantly change its virulence. However, little is known about the genomic patterns of diversity and selection in NDV viral swarms. We analyse deep sequencing data from in vitro and in vivo NDV infections to uncover the genomic patterns of diversity and the signatures of selection within NDV swarms. Variants in viruses from in vitro samples are mostly localised in non-coding regions and 3' and 5' untranslated regions (3'UTRs or 5'UTRs), while in vivo samples contain an order of magnitude more variants. We find different patterns of genomic divergence and diversity among NDV genotypes, as well as differences in the genomic distribution of intra-host variants among in vitro and in vivo infections of the same strain. The frequency spectrum shows clear signatures of intra-host purifying selection in vivo on the matrix protein (M) coding gene and positive or diversifying selection on nucleocapsid (NP) and haemagglutinin-neuraminidase (HN). The comparison between within-host polymorphisms and phylogenetic divergence reveals complex patterns of selective pressure on the NDV genome at between- and within-host level. The M sequence is strongly constrained both between and within hosts, fusion protein (F) coding gene is under intra-host positive selection, and NP and HN show contrasting patterns: HN RNA sequence is positively selected between hosts while its protein sequence is positively selected within hosts, and NP is under intra-host positive selection at the RNA level and negative selection at the protein level.

Patterns of RNA Editing in Newcastle Disease Virus Infections.

The expression of accessory non-structural proteins V and W in Newcastle disease virus (NDV) infections depends on RNA editing. These proteins are derived from frameshifts of the sequence coding for the P protein via co-transcriptional insertion of one or two guanines in the mRNA. However, a larger number of guanines can be inserted with lower frequencies. We analysed data from deep RNA sequencing of samples from in vitro and in vivo NDV infections to uncover the patterns of mRNA editing in NDV. The distribution of insertions is well described by a simple Markov model of polymerase stuttering, providing strong quantitative confirmation of the molecular process hypothesised by Kolakofsky and collaborators three decades ago. Our results suggest that the probability that the NDV polymerase would stutter is about 0.45 initially, and 0.3 for further subsequent insertions. The latter probability is approximately independent of the number of previous insertions, the host cell, and viral strain. However, in LaSota infections, we also observe deviations from the predicted V/W ratio of about 3:1 according to this model, which could be attributed to deviations from this stuttering model or to further mechanisms downregulating the abundance of W protein.

Evaluation of selected flavonoids as antiangiogenic, anticancer, and radical scavenging agents: an experimental and in silico analysis.

Developing antiangiogenic agents using natural products has remained a significant hope in the mainstream of anticancer research. In the present investigation series of flavonoids possessing di-, tri-, tetra-, and penta-hydroxy substitutions were evaluated as antiangiogenic agents using in vivo choriallantoic membrane model. The MTT-based cytotoxicity against selected cancer cell lines was carried out to determine the anticancer potential. The kinetics of free radical scavenging activities of these compounds was demonstrated using 2,2-diphenyl-1-picryl hydrazine (DPPH) and superoxide anion radicals (SORs). To understand the possible antiangiogenic mechanism, the selected flavonoids were docked in silico onto the proangiogenic peptides such as vascular endothelial growth factor (VEGF), hypoxia inducible factor (HIF-1α), and vascular endothelial growth factor receptor-2 (VEGFR2) from human origin. The results of the study shows that amongst the tested flavonoids, genistein (87.1%), kaempferol, (86.3%), and quercetin (84.7%) were found to be effective inhibitors of angiogenesis in CAM model. The antiangiogenic, cytotoxic, and antioxidant activities are discussed in light of structure-activity relationship using in silico approach and other drug-related properties were also calculated using BioMed CAChe V. 6.1.10. The results of the present study focus the isoflavone genistein, kaempferol, and quercetin as lead molecules for designing novel anti-tumor/antioxidant agents targeting angiogenesis.

Effect of hydroxyl substitution of flavone on angiogenesis and free radical scavenging activities: a structure-activity relationship studies using computational tools.

Angiogenesis is a key process needed for the growth and survival of solid tumors. Anti-angiogenesis may arrest the tumor growth and keep check on cancer metastasis. Developing antiangiogenic agents have remained a significant hope in the mainstream of anticancer research. The free radical implications in the initiation of cancers are well established. In the present studies, simple flavone and flavones with hydroxyl substitution in 'A' and 'C' ring at 3, 5, 6, and 7 were studied for antiangiogenic activities using chorioallantoic membrane (CAM) model and kinetics of DPPH (2,2-diphenyl-1-picryl hydrazine) and superoxide anion radical (SOR) scavenging activities. The docking of selected flavones with specific angiogenic targets such as vascular endothelial growth factor (VEGF), hypoxia inducible factor (HIF-1alpha) and vascular endothelial growth factor receptor-2 (VEGFR2) from human origin was carried out to focus the possible underlying mechanism of anti-angiogenesis. The result of the present studies shows that the 3-hydroxy substitution of the flavone was found to be the most promising lead for antiangiogenic activity in CAM model. The same was true for DPPH reduction with greater velocity as compared to other hydroxyl substitutions. However the 7- and 6-hydroxy substitution were observed to be more favourable for SOR scavenging activities as compared to other hydroxyl substitutions. The docking experiments shows that the VEGFR2 seems to be a structurally compatible target for tight binding of the flavones especially with 3-hydroxy substitution (-9.78 kcal/mole) as compared to VEGF (-8.47 kcal/mole) and HIF-1alpha (-8.99 kcal/mole). The quantum chemical descriptors of the test flavones related to free radical scavenging and other biological activities were calculated using computational tools. The data is discussed in the light of structure-activity relationship.