Elisabetta Manaresi scite author profile

The pathogenic Parvovirus B19 (B19V) is characterized by a strict adaptation to erythroid progenitor cells (EPCs), a heterogeneous population of differentiating cells with diverse phenotypic and functional properties. In our work, we studied the dynamics of B19V infection in EPCs in dependence on the cell differentiation stage, in terms of distribution of infected cells, synthesis of viral nucleic acids and production of infectious virus. EPCs at early differentiation stage led to an abortive infection, without viral genome replication and a very low transcriptional activity. EPCs at later stages were permissive, with highest levels of viral replicative activity at day 9 (+3.0 Log from 2 to 48 hpi) and lower levels at day 18 (+1.5 Log from 2 to 48 hpi). B19V DNA increment was in accordance with the percentage of cells positive to flow-FISH assay (41.4% at day 9, 1.1% at day 18). Quantitation of total RNA indicated a close association of genome replication and transcription with viral RNA accumulation within infected cells related to viral DNA increase during the course of infection. Analysis of the different classes of mRNAs revealed two distinct pattern of genome expression profile with a fine regulation in the frequency utilization of RNA processing signals: an early phase, when cleavage at the proximal site leading to a higher relative production of mRNA for NS protein, and a late phase, when cleavage at the distal site was more frequent leading to higher relative abundance of mRNA for VP and 11 kDA proteins. Infectious virus was released from cells at day 6–15, but not at day 18. Our results, providing a detailed description of B19V replication and expression profile in differentiating EPCs, highlight the very tight adaptation of B19V to a specific cellular target defined both by its erythroid lineage and its differentiation stage.

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Advances in the Development of Antiviral Strategies against Parvovirus B19

Manaresi

Gallinella

2019

Viruses

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Parvovirus B19 (B19V) is a human pathogenic virus, responsible for an ample range of clinical manifestations. Infections are usually mild, self-limiting, and controlled by the development of a specific immune response, but in many cases clinical situations can be more complex and require therapy. Presently available treatments are only supportive, symptomatic, or unspecific, such as administration of intravenous immunoglobulins, and often of limited efficacy. The development of antiviral strategies against B19V should be considered of highest relevance for increasing the available options for more specific and effective therapeutic treatments. This field of research has been explored in recent years, registering some achievements as well as interesting future perspectives. In addition to immunoglobulins, some compounds have been shown to possess inhibitory activity against B19V. Hydroxyurea is an antiproliferative drug used in the treatment of sickle-cell disease that also possesses inhibitory activity against B19V. The nucleotide analogues Cidofovir and its lipid conjugate Brincidofovir are broad-range antivirals mostly active against dsDNA viruses, which showed an antiviral activity also against B19V. Newly synthesized coumarin derivatives offer possibilities for the development of molecules with antiviral activity. Identification of some flavonoid molecules, with direct inhibitory activity against the viral non-structural (NS) protein, indicates a possible line of development for direct antiviral agents. Continuing research in the field, leading to better knowledge of the viral lifecycle and a precise understanding of virus–cell interactions, will offer novel opportunities for developing more efficient, targeted antiviral agents, which can be translated into available therapeutic options.

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B19 virus genome diversity: epidemiological and clinical correlations

Gallinella

Venturoli

Manaresi

et al. 2003

Journal of Clinical Virology

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Parvovirus B19 genome as a single, two-state replicative and transcriptional unit

et al. 2006

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The variation in the amount of parvovirus B19 DNA and different classes of RNA in permissive and non-permissive infected cells was analysed by means of quantitative real-time PCR and RT-PCR assays. In the permissive bone marrow mononuclear cells, UT7/Epo and KU812Ep6 cells, viral DNA usually increased within 48 hpi, rarely exceeding 2 Logs with respect to input DNA. Viral RNA was always present within 2-6 hpi, its increase paralleled that of viral DNA up to 36-48 hpi, and all the different classes of viral RNA were constantly represented in stable relative amounts throughout the infection cycle. In the non-permissive TF-1 cells, viral DNA did not increase and only one most represented single class of viral RNA was detected. Our data do not support the current model for B19 virus replication and transcription, consisting in different early and late expression patterns, but suggest an alternative model, indicating that the B19 virus genome should be considered a single, two-state replicative and transcriptional unit.

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Different Patterns of Restriction to B19 Parvovirus Replication in Human Blast Cell Lines

Gallinella¹,

Manaresi²,

Zuffi³

et al. 2000

Virology

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B19 parvovirus can replicate in erythroid progenitor cells and in a small number of human blast cell lines. To better understand and analyze the B19 virus replicative cycle, we performed and compared the infection of bone marrow cells and of different blast cell lines with erythroblastoid and megakaryoblastoid phenotypic characteristics (UT-7, TF-1, M-07, and B1647). Following in vitro infection, B19-specific nucleic acids were characterized with regard to the genome-replicative intermediates, the transcription pattern, and the localization of virus-specific nucleic acids inside infected cells. While all cell lines tested proved to be susceptible to B19 virus infection, two different patterns of restriction to replication of B19 virus were observed. In the first restriction pattern, observed in UT-7 cells, the single-stranded viral DNA was converted to double-stranded replicative intermediates, identical to those found in bone marrow cells, and a full set of viral transcripts were observed. However, replication and transcription were restricted to a small subset of cells, and production of capsid proteins was not detected. In the second restriction pattern, observed in TF-1, M-07, and B1647 cells, the single-stranded viral DNA was not converted to double-stranded replicative intermediates.

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