Canonical and Divergent N-Terminal HBx Isoform Proteins Unveiled: Characteristics and Roles during HBV Replication

Hepatitis B virus (HBV) X protein (HBx) is a viral regulatory and multifunctional protein. It is well-known that the canonical HBx reading frame bears two phylogenetically conserved internal in-frame translational initiation codons at Met2 and Met3, thus possibly generating divergent N-terminal smaller isoforms during translation. Here, we demonstrate that the three distinct HBx isoforms are generated from the ectopically expressed HBV HBx gene, named XF (full-length), XM (medium-length), and XS (short-length); they display different subcellular localizations when expressed individually in cultured hepatoma cells. Particularly, the smallest HBx isoform, XS, displayed a predominantly cytoplasmic localization. To study HBx proteins during viral replication, we performed site-directed mutagenesis to target the individual or combinatorial expression of the HBx isoforms within the HBV viral backbone (full viral genome). Our results indicate that of all HBx isoforms, only the smallest HBx isoform, XS, can restore WT levels of HBV replication, and bind to the viral mini chromosome, thereby establishing an active chromatin state, highlighting its crucial activities during HBV replication. Intriguingly, we found that sequences of HBV HBx genotype H are devoid of the conserved Met3 position, and therefore HBV genotype H infection is naturally silent for the expression of the HBx XS isoform. Finally, we found that the HBx XM (medium-length) isoform shares significant sequence similarity with the N-terminus domain of the COMMD8 protein, a member of the copper metabolism MURR1 domain-containing (COMMD) protein family. This novel finding might facilitate studies on the phylogenetic origin of the HBV X protein. The identification and functional characterization of its isoforms will shift the paradigm by changing the concept of HBx from being a unique, canonical, and multifunctional protein toward the occurrence of different HBx isoforms, carrying out different overlapping functions at different subcellular localizations during HBV genome replication. Significantly, our current work unveils new crucial HBV targets to study for potential antiviral research, and human virus pathogenesis.

HERC5 E3 ligase mediates ISGylation of hepatitis B virus X protein to promote viral replication

Ubiquitin and ubiquitin-like protein modification play important roles in modulating the functions of viral proteins in many viruses. Here we demonstrate that hepatitis B virus (HBV) X protein (HBx) is modified by ISG15, which is a type I IFN-inducible, ubiquitin-like protein; this modification is called ISGylation. Immunoblot analyses revealed that HBx proteins derived from four different HBV genotypes accepted ISGylation in cultured cells. Site-directed mutagenesis revealed that three lysine residues (K91, K95 and K140) on the HBx protein, which are well conserved among all the HBV genotypes, are involved in acceptance of ISGylation. Using expression plasmids encoding three known E3 ligases involved in the ISGylation to different substrates, we found that HERC5 functions as an E3 ligase for HBx-ISGylation. Treatment with type I and type III IFNs resulted in the limited suppression of HBV replication in Hep38.7-Tet cells. When cells were treated with IFN-α, silencing of ISG15 resulted in a marked reduction of HBV replication in Hep38.7-Tet cells, suggesting a role of ISG15 in the resistance to IFN-α. In contrast, the silencing of USP18 (an ISG15 de-conjugating enzyme) increased the HBV replication in Hep38.7-Tet cells. Taken together, these results suggest that the HERC5-mediated ISGylation of HBx protein confers pro-viral functions on HBV replication and participates in the resistance to IFN-α-mediated antiviral activity.

Optimization, Validation and Initial Clinical Implications of a Luminex-based Immunoassay for the Quantification of Fragile X Protein from Dried Blood Spots

Background: Fragile X syndrome (FXS) is the most common inherited form of intellectual disability affecting 1 in 4,000 males and 1 in 6-8,000 females. FXS is caused by a trinucleotide expansion in the 5’UTR of the Fragile X Mental Retardation (FMR1) gene which in full mutation carriers (>200 repeats) leads to hypermethylation and transcriptional silencing of the gene and lack of expression of Fragile X Protein (FXP, formerly known as Fragile X Mental Retardation Protein, FMRP). Phenotypic presentation of FXS is highly variable, and molecular markers explaining or predicting this variability are lacking. Recent studies suggest that trace amounts of FXP can be detected even in fully methylated individuals and may have clinical relevance; however, the lack of available reproducible, sensitive assays to detect FXP in peripheral tissue makes evaluation of peripheral FXP as a source of clinical variability challenging. Methods: We optimized a Luminex-based assay to detect FXP in dried blot spots for increased reproducibility and sensitivity by improving reagent concentrations and buffer conditions. The optimized assay was used to quantify FXP in 187 individuals (101 males, 86 females; 0-78.4 years) including 35 typically developing controls (24 males, 11 females), 103 individuals carrying full mutations (70 males, 33 females), and 49 individuals with premutations (7 males, 42 females). A subset of these individuals showed repeat number or methylation mosaicism. We investigated the clinical relevance of peripheral FXP levels by examining its relationship with general intellectual functioning in a subset of individuals with available IQ scores. Results: We show that the optimized assay is highly reproducible and detects a wide range of FXP levels. Mosaic individuals had, on average, higher FXP levels than fully methylated individuals, and trace amounts of FXP were consistently detectable in a subset of individuals with full mutation FXS. IQ scores were positively correlated with peripheral FXP levels in male and female individuals with full mutation FXS. Conclusions: We demonstrate that our optimized Luminex-based assay to detect FXP is reproducible, highly sensitive, and related to the core intellectual disability phenotype. Further, our data suggest that trace amounts of FXP detectable in dried blood spots of individuals with FXS could be clinically relevant and may be used to stratify individuals with FXS for optimized treatment. Future studies are needed with larger sample sizes, evaluating FXP across development and expanded analysis of the relevance of FXP levels for behavioral and electrophysiological phenotypes in FXS.

Optimization, validation and initial clinical implications of a Luminex-based immunoassay for the quantification of Fragile X Protein from Dried Blood Spots

BackgroundFragile X syndrome (FXS) is the most common inherited form of intellectual disability affecting 1 in 4,000 males and 1 in 6-8,000 females. FXS is caused by a trinucleotide expansion in the 5’UTR of the Fragile X Mental Retardation (FMR1) gene which in full mutation carriers (>200 repeats) leads to hypermethylation and transcriptional silencing of the gene and lack of expression of Fragile X Protein (FXP, formerly known as Fragile X Mental Retardation Protein, FMRP). Phenotypic presentation of FXS is highly variable, and molecular markers explaining or predicting this variability are lacking. Recent studies suggest that trace amounts of FXP can be detected even in fully methylated individuals and may have clinical relevance; however, the lack of available reproducible, sensitive assays to detect FXP in peripheral tissue makes evaluation of peripheral FXP as a source of clinical variability challenging. MethodsWe optimized a Luminex-based assay to detect FXP in dried blot spots for increased reproducibility and sensitivity by improving reagent concentrations and buffer conditions. The optimized assay was used to quantify FXP in 187 individuals (101 males, 86 females; 0-78.4 years) including 35 typically developing controls (24 males, 11 females), 103 individuals carrying full mutations (70 males, 33 females), and 49 individuals with premutations (7 males, 42 females). A subset of these individuals showed repeat number or methylation mosaicism. We investigated the clinical relevance of peripheral FXP levels by examining its relationship with general intellectual functioning in a subset of individuals with available IQ scores. ResultsWe show that the optimized assay is highly reproducible and detects a wide range of FXP levels. Mosaic individuals had, on average, higher FXP levels than fully methylated individuals, and trace amounts of FXP were consistently detectable in a subset of individuals with full mutation FXS. IQ scores were positively correlated with peripheral FXP levels in male and female individuals with full mutation FXS. ConclusionsWe demonstrate that our optimized Luminex-based assay to detect FXP is reproducible, highly sensitive, and related to the core intellectual disability phenotype. Further, our data suggest that trace amounts of FXP detectable in dried blood spots of individuals with FXS could be clinically relevant and may be used to stratify individuals with FXS for optimized treatment. Future studies are needed with larger sample sizes, evaluating FXP across development and expanded analysis of the relevance of FXP levels for behavioral and electrophysiological phenotypes in FXS.