Targeted inhibition of metastatic melanoma through interference with Pin1-FOXM1 signaling.

Melanoma is the most lethal form of skin cancer and successful treatment of metastatic melanoma remains challenging. BRAF/MEK inhibitors only show a temporary benefit due to rapid occurrence of resistance, whereas immunotherapy is mainly effective in selected subsets of patients. Thus, there is a need to identify new targets to improve treatment of metastatic melanoma. To this extent, we searched for markers that are elevated in melanoma and are under regulation of potentially druggable enzymes. Here, we show that the pro-proliferative transcription factor FOXM1 is elevated and activated in malignant melanoma. FOXM1 activity correlated with expression of the enzyme Pin1, which we found to be indicative of a poor prognosis. In functional experiments, Pin1 proved to be a main regulator of FOXM1 activity through MEK-dependent physical regulation during the cell cycle. The Pin1-FOXM1 interaction was enhanced by BRAF(V600E), the driver oncogene in the majority of melanomas, and in extrapolation of the correlation data, interference with\ Pin1 in BRAF(V600E)-driven metastatic melanoma cells impaired both FOXM1 activity and cell survival. Importantly, cell-permeable Pin1-FOXM1-blocking peptides repressed the proliferation of melanoma cells in freshly isolated human metastatic melanoma ex vivo and in three-dimensional-cultured patient-derived melanoids. When combined with the BRAF(V600E)-inhibitor PLX4032 a robust repression in melanoid viability was obtained, establishing preclinical value of patient-derived melanoids for prognostic use of drug sensitivity and further underscoring the beneficial effect of Pin1-FOXM1 inhibitory peptides as anti-melanoma drugs. These proof-of-concept results provide a starting point for development of therapeutic Pin1-FOXM1 inhibitors to target metastatic melanoma.

Evaluation of antiretroviral therapy results in Blantyre, Malawi.

UNLABELLED: We performed a cross sectional study to evaluate treatment results of the paying antiretroviral therapy clinic of Queen Elizabeth Central Hospital, Blantyre. The only antiretroviral therapy was a fixed drug combination of stavudine, lamivudine and nevirapine. METHODS: Interviews, laboratory tests (CD4 count, viral load, nevirapine plasma levels, transaminases) and data extraction from files. 422 (59 %) of the patients who started antiretroviral therapy since 2000 were lost to follow up. The 176 patients enrolled in the study had good virological and excellent clinical treatment results. The most common side effect was peripheral neuropathy. Nevirapine plasma levels were remarkably high and associated with successful virological treatment results. Two simple adherence questions pertaining to the use of medication in the previous 8 days corresponded well with nevirapine levels. The most important reasons for non-adherence were shortage of drugs in the hospital pharmacy and personal financial constraints. CONCLUSIONS: Many patients were lost to follow up.High nevirapine levels contributed to good therapy results in those studied.Simple adherence questions predicted sub-therapeutic nevirapine levels.Antiretroviral drug supply needs to be uninterrupted and free of charge, to prevent avoidable non-adherence.

Single rapid real-time monitored isothermal RNA amplification assay for quantification of human immunodeficiency virus type 1 isolates from groups M, N, and O.

Because human immunodeficiency virus type 1 (HIV-1) subtypes and circulating recombinant forms (CRFs) are spreading rapidly worldwide and are becoming less confined to a geographical area, RNA assays that can detect and quantify all HIV-1 isolates reliably are in demand. We have developed a fast, real-time monitored RNA assay based on an isothermal nucleic acid sequence-based amplification technology that amplifies a part of the long terminal repeat region of the HIV-1 genome. Real-time detection was possible due to the addition of molecular beacons to the amplification reaction that was monitored in a fluorimeter with a thermostat. The lower level of detection of the assay was 10 HIV-1 RNA molecules per reaction, and the lower level of quantification was 100 copies of HIV-1 RNA with a dynamic range of linear quantification between 10(2) and 10(7) RNA molecules. All HIV-1 groups, subtypes, and CRFs could be detected and quantified with equal efficiency, including the group N isolate YBF30 and the group O isolate ANT70. To test the clinical utility of the assay, a series of 62 serum samples containing viruses that encompassed subtypes A through G and CRFs AE and AG of HIV-1 group M were analyzed, and these results were compared to the results of a commercially available assay. This comparison showed that the quantification results correlated highly (R(2) = 0.735) for those subtypes that could be well quantified by both assays (subtypes B, C, D, and F), whereas improved quantification was obtained for subtypes A and G and CRFs AE and AG. A retrospective study with six individuals infected with either a subtype A, B, C, or D or an AG isolate of HIV-1 group M, who were treated with highly active antiretroviral therapy, revealed that the assay was well suited to the monitoring of therapy effects. In conclusion, the newly developed real-time monitored HIV-1 assay is a fast and sensitive assay with a large dynamic range of quantification and is suitable for quantification of most if not all subtypes and groups of HIV-1.

One-tube real-time isothermal amplification assay to identify and distinguish human immunodeficiency virus type 1 subtypes A, B, and C and circulating recombinant forms AE and AG.

To halt the human immunodeficiency virus type 1 (HIV-1) epidemic requires interventions that can prevent transmission of numerous HIV-1 subtypes. The most frequently transmitted viruses belong to the subtypes A, B, and C and the circulating recombinant forms (CRFs) AE and AG. A fast one-tube assay that identifies and distinguishes among subtypes A, B, and C and CRFs AE and AG of HIV-1 was developed. The assay amplifies a part of the gag gene sequence of the genome of all currently known HIV-1 subtypes and can identify and distinguish among the targeted subtypes as the reaction proceeds, because of the addition of subtype-specific molecular beacons with multiple fluorophores. The combination of isothermal nucleic acid sequence-based amplification and molecular beacons is a new approach in the design of real-time assays. To obtain a sufficiently specific assay, we developed a new strategy in the design of molecular beacons, purposely introducing mismatches in the molecular beacons. The subtype A and CRF AG isolates reacted with the same molecular beacon. We tested the specificity and sensitivity of the assay on a panel of the culture supernatant of 34 viruses encompassing all HIV-1 subtypes: subtypes A through G, CRF AE and AG, a group O isolate, and a group N isolate. Assay sensitivity on this panel was 92%, with 89% correct subtype identification relative to sequence analysis. A linear relationship was found between the amount of input RNA in the reaction mixture and the time that the reaction became positive. The lower detection level of the assay was approximately 10(3) copies of HIV-1 RNA per reaction. In 38% of 50 serum samples from HIV-1-infected individuals with a detectable amount of virus, we could identify subtype sequences with a specificity of 94% by using sequencing and phylogenetic analysis as the "gold standard." In conclusion, we showed the feasibility of the approach of using multiple molecular beacons labeled with different fluorophores in combination with isothermal amplification to identify and distinguish subtypes A, B, and C and CRFs AE and AG of HIV-1. Because of the low sensitivity, the assay in this format would not be suited for clinical use but can possibly be used for epidemiological monitoring as well as vaccine research studies.

Natural residues versus antiretroviral drug-selected mutations in HIV type 1 group O reverse transcriptase and protease related to virological drug failure in vivo.

HIV-1 group O viruses were first recognized as a distinct subgroup of HIV-1 with the isolation and characterization in 1990 of a virus (ANT70) from a woman (individual A) and her spouse (individual B), both from Cameroon (De Leys R, et al.: J Virol 1990;64:1207-1216). During the 5-6 years before treatment, individual A remained asymptomatic, with viral RNA levels between 2.5 and 2.8 log10 copies/ml, as measured by a newly developed group O-specific quantitative NASBA-based RNA assay. Individual B developed mild clinical symptoms, with 3.1 to 3.6 log10 copies of viral RNA per milliliter. HIV-1 sequences obtained from both individuals showed pretreatment residues in protease that confer resistance to protease inhibitors in group M viruses (10I, 36I, and 71V). Individual A showed an initial response to AZT, but shortly after addition of ddC and saquinavir, the RNA levels returned to baseline, while subsequent treatment with d4T, 3TC, and indinavir reduced the RNA level to less than 50 copies/ml for the time of follow-up. Individual B showed no response to AZT or ddC monotherapy, and a change to d4T, 3TC, and indinavir had, in contrast to individual A, only a temporary effect. While a multitude of mutations in HIV-1 group O reverse transcriptase (RT) and protease appeared that are associated with drug resistance in group M viruses, the observed T215N mutation in RT and the V15I and V22A mutations in protease have not previously been described and may represent resistance-conferring mutations specific to group O viruses. These results indicate that treatment of HIV-1 group O-infected individuals with antiretroviral drug regimens that include protease inhibitors might lead to rapid selection for resistance-conferring mutations. This probably results from preexisting protease residues contributing to reduced sensitivity of group O viruses to protease inhibitors, as is observed in vitro.

Subtype-specific sequence variation of the HIV type 1 long terminal repeat and primer-binding site.

We studied sequence differences in regulatory elements of the long terminal repeat (LTR) and primer-binding site (PBS) among various human immunodeficiency virus type 1 (HIV-1) subtypes. Phylogenetic sequence analysis of a fragment of 729 base pairs (bp) covering the Gag-coding region for half of p24 and all of p17 revealed the gag subtype of all 60 viruses included in the study: A (n = 20), B (n = 12), C (n = 7), D (n = 10), E (n = 3), F (n = 4), G (n = 3), and H (n = 1). The subtype was also determined by analysis of a 689-bp fragment comprising the LTR and the PBS motif. Comparison of the LTR versus gag sequences showed a mosaic genome for seven isolates. After analysis of all sequences, we could describe subtype-specific differences in sequences encompassing the regulatory elements of the LTR and the PBS motif.

Design and evaluation of a human immunodeficiency virus type 1 RNA assay using nucleic acid sequence-based amplification technology able to quantify both group M and O viruses by using the long terminal repeat as target.

Currently available human immunodeficiency virus type 1 (HIV-1) RNA quantification assays can detect most viruses of the group M subtypes, but a substantial number are missed or not quantified reliably. Viruses of HIV-1 group O cannot be detected by any commercially available assay. We developed and evaluated a quantitative assay based on nucleic acid sequence-based amplification (NASBA) technology, with primers and probes located in the conserved long terminal repeat (LTR) region of the HIV-1 genome. In 68 of 72 serum samples from individuals infected with HIV-1 subtypes A to H of group M, viruses could be detected and quantified. In serum samples from two patients infected with HIV-1 group O viruses, these viruses as well could be detected and quantified. In contrast, the currently used gag-based assay underestimated the presence of subtype A viruses and could not detect subtype G and group O viruses. The discrepancy between the results of the two assays may be explained by the number of mismatches found within and among the probe and primer regions of the subtype isolates. These data indicate that LTR-based assays, including the NASBA format chosen here, are better suited to monitoring HIV-1 therapy than are gag-based assays in an era in which multiple HIV-1 subtypes and groups are spreading worldwide.

Detection of human immunodeficiency virus type 1 nucleocapsid protein p7 in vitro and in vivo.

We developed and evaluated an immunoassay for the detection and quantification of human immunodeficiency virus type 1 (HIV-1) nucleocapsid protein p7 using electrochemiluminescence technology. The assay had a dynamic range of 50 to 20,000 pg/ml and a lower detection limit equivalent to approximately 10(6.5) HIV-1 RNA copies/ml in culture supernatant. In vitro kinetic replication studies showed that the amount of p7 correlated strongly with the amount of p24 (R2 = 0.869; P < 0.0001) and viral RNA (R2 = 0.858; P = 0.0009). On the basis of the p7 and RNA concentrations, we calculated the median p7:RNA ratio to be approximately 1,400 p7 molecules per RNA molecule. HIV-1 p7 could be detected and quantified in culture supernatants of both group M subtype A to E viruses and group O viruses. The presence of p7 in vivo was evaluated in 81 serum samples collected from 62 HIV-1-infected individuals. Five samples were p7 positive, whereas 45 samples were HIV-1 p24 positive. Four of the five p7-positive samples were p24 positive as well. p7 could be detected only when serum HIV-1 RNA levels were greater than 10(6) copies/ml. Anti-p7 antibodies were found in six samples, and all six were p7 negative. In contrast to the in vitro results, it appeared that HIV-1 p7 could not be used as a marker for viral quantification in vivo, since more than 90% of the serum samples were p7 negative. In combination with the low prevalence of anti-p7 antibodies, this may, in turn, be advantageous: the p7 assay may be a good alternative to the p24 assay as the readout system for determination of neutralizing activity against HIV-1 in serum or other fluids containing anti-p24 antibodies.