Recovery of complete genomes of canine parvovirus from clinical samples.

Canine parvovirus (CPV) is a highly pathogenic virus that affects dogs, especially puppies. CPV is believed to have evolved from feline panleukopenia virus (FPV), eventually giving rise to three antigenic types, CPV-2a, 2b, and 2c. CPV-2 is recognized for its resilience in contaminated environments, ease of transmission among dogs, and pathogenicity for puppies. Despite the relevance of the virus, complete genome sequences of CPV available at GenBank, to date, are scarce. In the current study, we have developed a methodology to allow the recovery of complete CPV-2 genomes directly from clinical samples. For this, seven fecal samples from Gurupi, Tocantins, North Brazil, were collected from puppies with clinical signals of viral enteritis, and submitted to viral DNA isolation and amplification. Two multiplex PCR strategies were designed including primers targeting fragments of 400 base pairs (bp) and 1,000 bp along the complete genome. Sequencing was performed with the Nanopore® technology and results obtained with the two approaches were compared. Genome assembly revealed that the 400 bp amplicons generated larger numbers of reads, allowing a more reliable coverage of the whole genome than those attained with primers targeting the larger (1000 bp) amplicons. Nevertheless, both enrichment methodologies were efficient in amplification and sequencing. Viral genome sequences were of high quality and allowed more precise typing and subtyping of viral genomes compared to the commonly employed strategy relying solely on the analysis of the VP2 region, which is limited in scope. The CPV-2 genomes recovered in this study belong to the CPV2a and CPV-2c subtypes, closely related to isolates from the neighboring Amazonian region. In conclusion, the technique reported here may contribute to increase the number of full CPV genomes available, which is essential for understanding the genetic mechanisms underlying the evolution and spread of CPV-2.

Human Cytomegalovirus Interleukin 10 Homologs: Facing the Immune System.

Human Cytomegalovirus (HCMV) can cause a variety of health disorders that can lead to death in immunocompromised individuals and neonates. The HCMV lifecycle comprises both a lytic (productive) and a latent (non-productive) phase. HCMV lytic infection occurs in a wide range of terminally differentiated cell types. HCMV latency has been less well-studied, but one characterized site of latency is in precursor cells of the myeloid lineage. All known viral genes are expressed during a lytic infection and a subset of these are also transcribed during latency. The UL111A gene which encodes the viral IL-10, a homolog of the human IL-10, is one of these genes. During infection, different transcript isoforms of UL111A are generated by alternative splicing. The most studied of the UL111A isoforms are cmvIL-10 (also termed the "A" transcript) and LAcmvIL-10 (also termed the "B" transcript), the latter being a well-characterized latency associated transcript. Both isoforms can downregulate MHC class II, however they differ in a number of other immunomodulatory properties, such as the ability to bind the IL10 receptor and induce signaling through STAT3. There are also a number of other isoforms which have been identified which are expressed by differential splicing during lytic infection termed C, D, E, F, and G, although these have been less extensively studied. HCMV uses the viral IL-10 proteins to manipulate the immune system during lytic and latent phases of infection. In this review, we will discuss the literature on the viral IL-10 transcripts identified to date, their encoded proteins and the structures of these proteins as well as the functional properties of all the different isoforms of viral IL-10.

Molecular detection and characterization of BK and JC polyomaviruses in urine samples of renal transplant patients in Southern Brazil.

The human polyomaviruses JC (JCPyV) and BK (BKPyV) are widespread in the human population. Following the primary infection, virus reactivation may lead to nephropathy and graft rejection in renal transplant patients. This study was carried out to access the presence of BKPyV and JCPyV DNA in urine samples collected from renal transplant patients (n = 92) and healthy individuals (n = 88) in Porto Alegre, Rio Grande do Sul. The samples were submitted to a nested PCR. A significantly higher frequency (P < 0.001) of BKPyV was found in renal transplant patients (65.2%) in comparison to the control group (32.9%). JCPyV was detected equally in both groups. Phylogenetic analysis of both BKPyV and JCPyV amplicons demonstrates the presence of the BKPyV subtypes I and II, whereas for JCPyV, four different groups are found (1, 2, 3, and 4).

Virus-encoded 7 transmembrane receptors.

Herpesviruses are an ancient group which have exploited gene capture of multiple cellular modulators of the immune response. Viral homologues of 7 transmembrane receptors (v7TMRs) are a consistent feature of beta- and gammaherpesviruses; the majority of the v7TMRs are homologous to cellular chemokine receptors (CKRs). Conserved families of v7TMRs distinguish between beta- versus gammaherpesviruses; furthermore, significant divisions within these subfamilies, such as between genera of the gammaherpesviruses or between the primate and rodent cytomegaloviruses, coincide with specific v7TMR gene families. Divergence of functional properties between the viral 7TMR and their cellular counterparts is likely, therefore, to reflect adaptation supporting various aspects of the viral lifecycle with concomitant effects upon viral pathogenesis. Consistent with their long evolutionary history, the v7TMRs have acquired a range of distinctive characteristics. This chapter reviews key features of the v7TMRs which are likely to impact upon their functional roles: trafficking properties, ligand specificity, and signaling capacity. Rapid, constitutive endocytosis, reminiscent of cellular "scavenger" receptors, may provide a mechanism for immune evasion, or alternatively relate to virion assembly, including incorporation of v7TMRs within the virion envelope. Some v7TMRs display relatively broad chemokine-binding specificity, whereas others remain "orphan" and may be completely independent of ligand activation. Indeed, many of the v7TMRs have been shown to signal constitutively, associated in some cases with notable divergence of highly conserved regulatory elements such as the "DRY" motif of TMIII. The availability of rodent models for v7TMR functional studies has provided evidence for important biological roles, including cellular transformation, tissue tropism, and viral persistence. Recent studies addressing signaling pathways critical to these phenotypes will be discussed, with reference to both beta- and gammaherpesviruses.