A combinatorial target screening strategy for deorphaning macromolecular targets of natural product.

Natural products, as an ideal starting point for molecular design, play a pivotal role in drug discovery; however, ambiguous targets and mechanisms have limited their in-depth research and applications in a global dimension. In-silico target prediction methods have become an alternative to target identification experiments due to the high accuracy and speed, but most studies only use a single prediction method, which may reduce the accuracy and reliability of the prediction. Here, we firstly presented a combinatorial target screening strategy to facilitate multi-target screening of natural products considering the characteristics of diverse in-silico target prediction methods, which consists of ligand-based online approaches, consensus SAR modelling and target-specific re-scoring function modelling. To validate the practicability of the strategy, natural product neferine, a bisbenzylisoquinoline alkaloid isolated from the lotus seed, was taken as an example to illustrate the screening process and a series of corresponding experiments were implemented to explore the pharmacological mechanisms of neferine. The proposed computational method could be used for a complementary hypothesis generation and rapid analysis of potential targets of natural products.

Attenuated SIV imparts immunity to challenge with pathogenic spleen-derived SIV but cannot prevent repair of the nef deletion.

To date, some success has been achieved with several experimental vaccines against AIDS in the available animal models. In the simian immunodeficiency virus (SIV) macaque model protection against superinfection was obtained by preinfection with a virus attenuated by a deletion in nef. To investigate the efficacy of SIVmac32H(pC8), a nef deletion mutant of SIVmac251, as a live-attenuated vaccine, rhesus monkeys were infected intravenously (i.v.) with this virus. All monkeys became productively infected by the pC8 virus. The animals had low cell-associated viral loads but developed a strong cellular and humoral antiviral immune response. Two out of eight preinfected monkeys developed signs of immunodeficiency and were excluded from the challenge. Sequence analysis of reisolates from one of them revealed a complete repair of the nef deletion. The remaining six monkeys, two preinfected for 42 weeks and four for 22 weeks, were challenged i.v. with a pathogenic SIV derived ex vivo from the spleen of a SIV infected macaque. Four of the monkeys challenged resisted the second infection whereas in two monkeys preinfected for 22 weeks full length nef was detectable. All monkeys maintained a virus-specific CD4-cell proliferative response after challenge. Thus, even after short preinfection periods with an attenuated SIV sterilising immunity against a challenge with a pathogenic SIV can be obtained. However, such a vaccine is unsafe since the attenuated virus frequently reverts to a more virulent form.

Contributions of HIV-1 Nef to immune dysregulation in HIV-infected patients: a therapeutic target?

INTRODUCTION: HIV accessory protein Nef is a factor responsible for many of the viral pathogenic effects. Progression to AIDS is dramatically delayed and in some well-documented cases completely abolished on infection with naturally occurring HIV strains lacking intact nef sequences in their genomes. The topic of this review is the contribution of Nef to the immune pathology as a possible target in HIV-infected patients. AREAS COVERED: An overview of known Nef functions accounting for its role in pathogenesis is presented, emphasizing interactions with dendritic cells and macrophages, and Nef-induced exosome secretion, all involved in immune dysregulation during the course of HIV infection. Current approaches to Nef inhibition by different classes of compounds are reviewed. EXPERT OPINION: Blocking Nef for therapeutic purposes is a challenging endeavor mainly due to intrinsic properties of this HIV accessory protein. Nef has multiple interfaces to interact with host proteins and lacks a catalytic domain. Potential benefits arising from the development of successful inhibitors could however prove beneficial for reducing gradual deterioration of immune system in chronically infected patients in absence of functional cure.

Expression and cellular localization of the Nef protein from human immunodeficiency virus-1 in stably transfected B-cells.

Nef protein, encoded by the regulatory nef gene of human immunodeficiency virus type 1 (HIV-1), was expressed in the B-cell line Raji. The cells were stably transfected with plasmids containing the nef transcriptional cassette. They expressed Nef with an Mr of 27,000; the yield could be augmented by incubation with the tumor promoter 12-O-tetradecanoylphorbol-13-acetate. The intracellular localization of Nef was analyzed applying immunofluorescence microscopy using a confocal laser scanning microscope. The antigen was stained with a monoclonal antibody directed against the N-terminal part of Nef. The experiments revealed that in non-dividing cells Nef is present both in the cytoplasm and the nucleus while in dividing cells the viral protein is present in the cytoplasm and at the nuclear membrane.