Kris Covens

Characterization of proposed human B-1 cells reveals pre-plasmablast phenotype

Controversy has arisen about the nature of circulating human CD20(+)CD27(+)CD43(+)CD70(-)CD69(-) B cells. Although originally described as being the human counterpart of murine B-1 B cells, some studies have raised the possibility that these might instead be plasmablasts. In this article, we have further characterized the putative B-1 cells and compared them directly with memory B cells and plasmablasts for several functional characteristics. Spontaneous antibody production of different isotypes as well as the induced production of antigen-specific antibodies after vaccination with a T-cell-dependent antigen did not reveal differences between the putative B-1 cells and genuine CD20(-) plasmablasts. Gene expression profiling of different B-cell subsets positioned the phenotype of putative B-1 cells closer to CD20(-) plasmablasts than to memory B cells. Moreover, putative B-1 cells could be differentiated into CD20(-) plasmablasts and plasma cells in vitro, supporting a pre-plasmablast phenotype. In conclusion, characterization of the putative B-1 cells revealed a functional phenotype and a gene expression profile that corresponds to cells that differentiate into CD20(-) plasmablasts. Our data offer perspectives for the investigation of differentiation of B cells into antibody secreting cells.

Human liver sinusoidal endothelial cells but not hepatocytes contain factor VIII.

Although the liver is the major site of coagulation factor VIII (FVIII) synthesis, the type of cells producing FVIII within the liver is still unclear.

The FXR Agonist Obeticholic Acid Prevents Gut Barrier Dysfunction and Bacterial Translocation in Cholestatic Rats

Bacterial translocation (BTL) drives pathogenesis and complications of cirrhosis. Farnesoid X-activated receptor (FXR) is a key transcription regulator in hepatic and intestinal bile metabolism. We studied potential intestinal FXR dysfunction in a rat model of cholestatic liver injury and evaluated effects of obeticholic acid (INT-747), an FXR agonist, on gut permeability, inflammation, and BTL. Rats were gavaged with INT-747 or vehicle during 10 days after bile-duct ligation and then were assessed for changes in gut permeability, BTL, and tight-junction protein expression, immune cell recruitment, and cytokine expression in ileum, mesenteric lymph nodes, and spleen. Auxiliary in vitro BTL-mimicking experiments were performed with Transwell supports. Vehicle-treated bile duct-ligated rats exhibited decreased FXR pathway expression in both jejunum and ileum, in association with increased gut permeability through increased claudin-2 expression and related to local and systemic recruitment of natural killer cells resulting in increased interferon-γ expression and BTL. After INT-747 treatment, natural killer cells and interferon-γ expression markedly decreased, in association with normalized permeability selectively in ileum (up-regulated claudin-1 and occludin) and a significant reduction in BTL. In vitro, interferon-γ induced increased Escherichia coli translocation, which remained unaffected by INT-747. In experimental cholestasis, FXR agonism improved ileal barrier function by attenuating intestinal inflammation, leading to reduced BTL and thus demonstrating a crucial protective role for FXR in the gut-liver axis.

Glycan deletions in the HIV-1 gp120 V1/V2 domain compromise viral infectivity, sensitize the mutant virus strains to carbohydrate-binding agents and represent a specific target for therapeutic intervention.

Carbohydrate-binding agents (CBAs), such as the mannose-specific Hippeastrum hybrid agglutinin (HHA) and the GlcNAc-specific Urtica dioica agglutinin (UDA), frequently select for glycan deletions in all different domains of HIV-1 gp120, except in the V1/V2 domain. To reveal the underlying mechanisms, a broad variety of 31 different virus strains containing one or several N-glycan deletions in V1/V2 of the gp120 of the X4-tropic HIV-1(NL4.3) were constructed by chimeric virus technology. No co-receptor switch to CCR5 was observed for any of the replication-competent mutant virus strains. With a few exceptions, the more glycans were deleted in the gp120 V1/V2 domain, the more the replication capacity of the mutant viruses became compromised. None of the mutant virus strains showed a markedly decreased sensitivity to the inhibitory activity of HHA and UDA. Instead, an up to 2- to 10-fold higher sensitivity to the inhibitory activity of these CBAs was observed. Our data may provide an explanation why glycan deletions in the gp120 V1/V2 domain rarely occur under CBA pressure and confirm the important functional role of the glycans in the HIV-1 gp120 V1/V2 domain. The gp120 V1/V2 loop glycans of HIV-1 should therefore be considered as a hot spot and novel target for specific therapeutic drug intervention.

A genotypic assay for the amplification and sequencing of integrase from diverse HIV-1 group M subtypes

Recently, the Food and Drug Administration (FDA) of the USA approved the first integrase inhibitor for inclusion in treatment regimens of HIV-1 patients failing their current regimens with multi-drug resistant strains. However, treatment failure has been observed during integrase inhibitor-containing therapy. Several mutational pathways have been described with signature mutations at integrase positions 66, 92, 148 and 155. Therefore, a genotypic assay for the amplification and sequencing of HIV-1 integrase was developed. The assay displayed a detection limit of 10 HIV-1 III(B) RNA copies/ml plasma. As the HIV-1 pandemic is characterised by a large genetic diversity, the new assay was evaluated on a panel of 74 genetically divergent samples belonging to the following genetic forms A, B, C, D, F, G, J, CRF01-AE, CRF02-AG, CRFF03-AB, CRF12-BF and CRF13-cpx. Their viral load ranged from 178 until >500,000 RNA copies/ml. The amplification and sequencing was successful for 70 samples (a success rate of 95%). The four failures were most probably due to low viral load or poor quality of RNA and not to subtype issues. Some of the sequences obtained from integrase inhibitor-naïve patients displayed polymorphisms at integrase positions associated with resistance: 74IV, 138D, 151I, 157Q and 163AE. The relevance of these polymorphisms in the absence of the signature mutations remains unclear.

Novel Recombinant Virus Assay for Measuring Susceptibility of Human Immunodeficiency Virus Type 1 Group M Subtypes To Clinically Approved Drugs

ABSTRACT Combination therapy can successfully suppress human immunodeficiency virus (HIV) replication in patients but selects for drug resistance, requiring subsequent resistance-guided therapeutic changes. This report describes the development and validation of a novel assay that offers a uniform method to measure susceptibility to all clinically approved HIV type 1 (HIV-1) drugs targeting reverse transcriptase (RT), protease (PR), integrase (IN), and viral entry. It is an assay in which the antiviral effect on infection within a single replication cycle is measured in triply transfected U87.CD4.CXCR4.CCR5 cells, based on homologous recombination between patient-derived amplicons and molecular proviral clones tagged with the enhanced green fluorescent protein (EGFP) reporter gene and from which certain viral genomic regions are removed. The deletions stretch from p17 codon 7 to PR codon 98 in pNL4.3-ΔgagPR-EGFP, from PR codons 1 to 99 in pNL4.3-ΔPR-EGFP, from RT codons 1 to 560 in pNL4.3-ΔRT-EGFP, from IN codons 1 to 288 in pNL4.3-ΔIN-EGFP, and from gp120 codon 34 to gp41 codon 237 in pNL4.3-Δenv-EGFP. The optimized experimental conditions enable the investigation of patient samples regardless of viral subtype or coreceptor use. The extraction and amplification success rate for a set of clinical samples belonging to a broad range of HIV-1 group M genetic forms (A-J, CRF01-03, CRF05, and CRF12-13) and displaying a viral load range of 200 to >500,000 RNA copies/ml was 97%. The drug susceptibility measurements, based on discrimination between infected and noninfected cells on a single-cell level by flow cytometry, were reproducible, with coefficients of variation for resistance ranging from 7% to 31%, and were consistent with scientific literature in terms of magnitude and specificity.

HIV-1 protease mutation 82M contributes to phenotypic resistance to protease inhibitors in subtype G

OBJECTIVES The purpose of this study was the qualitative and quantitative assessment of the in vitro effect of HIV-1 protease (PR) mutation 82M on replication capacity and susceptibility to the eight clinically available PR inhibitors (PIs). METHODS The 82M substitution was introduced by site-directed mutagenesis in wild-type subtype B and G strains, as well as reverted back to wild-type in a therapy-failing strain. The recombinant viruses were evaluated for their replication capacity and susceptibility to PIs. RESULTS The single 82M mutation within a wild-type subtype B or G background did not result in drug resistance. However, the in vitro effect of single PR mutations on PI susceptibility is not always distinguishable from wild-type virus, and particular background mutations and polymorphisms are required to detect significant differences in the drug susceptibility profile. Consequently, reverting the 82M mutation back to wild-type (82I) in a subtype G isolate from a patient that failed therapy with multiple other PR mutations did result in significant increases in susceptibility towards indinavir and lopinavir and minor increases in susceptibility towards amprenavir and atazanavir. The presence of the 82M mutation also slightly decreased viral replication, whether it was in the genetic background of subtype B or subtype G. CONCLUSIONS Our results suggest that 82M has an impact on PI susceptibility and that this effect is not due to a compensatory effect on the replication capacity. Because 82M is not observed as a polymorphism in any subtype, these observations support the inclusion of 82M in drug resistance interpretation systems and PI mutation lists.

The rare HIV-1 gp41 mutations 43T and 50V elevate enfuvirtide resistance levels of common enfuvirtide resistance mutations that did not impact susceptibility to sifuvirtide

Mutations that are selected at low frequency and/or reside outside the enfuvirtide target region, amino acid 36-45 of gp41, might still be important determinants for drug resistance. This study aimed to investigate the phenotypic impact against enfuvirtide and sifuvirtide of uncharacterized gp41 mutations 42G, 43T and 50V, selected in patients failing enfuvirtide-containing regimens. As single mutations, neither 42G, 43T nor 50V conferred resistance to enfuvirtide. However, 50V increased slightly resistance levels for 36D, 38M, 43D or 43T as did 43T for 38M. All mutants displayed a reduced replication capacity, except 42S, 50V and 36D+/-50V. None of the mutants displayed resistance to the next-generation fusion inhibitor sifuvirtide. This study highlights the necessity to confirm the in vitro effect of infrequently selected mutations as 42G was not associated with enfuvirtide resistance whereas 43T and 50V should be considered as secondary enfuvirtide resistance mutations.

Evolution of genotypic resistance to enfuvirtide in HIV-1 isolates from different group M subtypes.

BACKGROUND Enfuvirtide is active against isolates from different HIV-1 subtypes. In vitro and in vivo studies reveal that resistance mutations are primarily found within the region spanning amino acid 36-45 of gp41. However, most studies include only subtype B strains, while it is known that especially the env region is very divergent among subtypes. OBJECTIVES To analyze the gp41 HR1 genetic evolution during failure of enfuvirtide-containing salvage regimens in 19 HIV-1 patients infected with strains from different group M subtypes. STUDY DESIGN The gp41 sequence was determined at baseline and upon failure in 19 patients. For a subset of 7 patients, samples were available after discontinuation of enfuvirtide. RESULTS Our results confirmed the conserved nature of the HR1 region. Escape mutants during chronic treatment with enfuvirtide were mainly observed within region 36-45. One novel mutation was identified, i.e. S42G in a subtype A1 strain. CONCLUSIONS Different subtypes escape enfuvirtide selective pressure through similar mutational patterns, however a new S42G variant was observed. The in vivo selection of S42G suggests that it might play a role in enfuvirtide resistance. Therefore, it could be considered as a candidate mutation to be included within drug resistance interpretation systems.

Impact on replicative fitness of the G48E substitution in the protease of HIV-1: an in vitro and in silico evaluation

We observed an unusual glycine-to-glutamate substitution at protease (PR) residue position 48 (G48E) in an African patient infected with a subtype A1 HIV-1 strain failing a saquinavir-containing regimen. Phenotypic analysis of protease inhibitor (PI) susceptibility showed that the G48E site-directed mutant, when introduced into an NL4-3 HIV-1 PR backbone, was slightly resistant to SQV (2-fold when compared with the wild-type virus). In addition, the G48E and G48E/V82A site-directed mutants were associated with a decrease in fitness, whereas a reversion to the wild type at position 48 was observed in vitro. Growth competition experiments using a novel growth competition assay based on enhanced green fluorescent protein- or Discosoma spp. red fluorescent protein-expressing viruses showed that the replicative fitness of the G48E virus was reduced to 55% compared with the parental NL4-3 virus. Synthesizing all possible site-directed mutants found in the patient strain is too time-consuming; therefore, a molecular dynamics (MD) simulation approach was used to understand why this mutation survived despite its fitness cost. These simulations documented that the G48E mutant interacted with PI resistance mutations (M46I, I54V, Q58E, and L63P) and with natural polymorphisms specific to subtype A1 (E35D, M36I, and R57K) that were present in the patients virus. We hypothesize that the polymorphisms contained in the PR flap regions of the patients virus may compensate for the presence of G48E, possibly by restoring the flexibility of the PR flaps. In summary, our results demonstrate that the G48E substitution, when introduced in the context of an HIV-1 subtype B strain, is highly unstable and gives rise to viruses with a poor replicative fitness in vitro. We also showed that when confronted with too many mutations to evaluate in vitro, MD simulations are helpful to draft hypotheses on how polymorphisms can interact with resistance mutations to stabilize their potential fitness cost.