ATP and MO25α Regulate the Conformational State of the STRADα Pseudokinase and Activation of the LKB1 Tumour Suppressor

Pseudokinases lack essential residues for kinase activity, yet are emerging as important regulators of signal transduction networks. The pseudokinase STRAD activates the LKB1 tumour suppressor by forming a heterotrimeric complex with LKB1 and the scaffolding protein MO25. Here, we describe the structure of STRADα in complex with MO25α. The structure reveals an intricate web of interactions between STRADα and MO25α involving the αC-helix of STRADα, reminiscent of the mechanism by which CDK2 interacts with cyclin A. Surprisingly, STRADα binds ATP and displays a closed conformation and an ordered activation loop, typical of active protein kinases. Inactivity is accounted for by nonconservative substitution of almost all essential catalytic residues. We demonstrate that binding of ATP enhances the affinity of STRADα for MO25α, and conversely, binding of MO25α promotes interaction of STRADα with ATP. Mutagenesis studies reveal that association of STRADα with either ATP or MO25α is essential for LKB1 activation. We conclude that ATP and MO25α cooperate to maintain STRADα in an “active” closed conformation required for LKB1 activation. It has recently been demonstrated that a mutation in human STRADα that truncates a C-terminal region of the pseudokinase domain leads to the polyhydramnios, megalencephaly, symptomatic epilepsy (PMSE) syndrome. We demonstrate this mutation destabilizes STRADα and prevents association with LKB1. In summary, our findings describe one of the first structures of a genuinely inactive pseudokinase. The ability of STRADα to activate LKB1 is dependent on a closed “active” conformation, aided by ATP and MO25α binding. Thus, the function of STRADα is mediated through an active kinase conformation rather than kinase activity. It is possible that other pseudokinases exert their function through nucleotide binding and active conformations.     

Comparative proteomic analysis of human mesenchymal and embryonic stem cells: Towards the definition of a mesenchymal stem cell proteomic signature

Mesenchymal stem cells (MSC) are adult multipotential progenitors which have a high potential in regenerative medicine. They can be isolated from different tissues throughout the body and their homogeneity in terms of phenotype and differentiation capacities is a real concern. To address this issue, we conducted a 2‐DE gel analysis of mesenchymal stem cells isolated from bone marrow (BM), adipose tissue, synovial membrane and umbilical vein wall. We confirmed that BM and adipose tissue derived cells were very similar, which argue for their interchangeable use for cell therapy. We also compared human mesenchymal to embryonic stem cells and showed that umbilical vein wall stem cells, a neo‐natal cell type, were closer to BM cells than to embryonic stem cells. Based on these proteomic data, we could propose a panel of proteins which were the basis for the definition of a mesenchymal stem cell proteomic signature.     

Mutational analysis of the -10 region from the Mycobacterium tuberculosis lipF promoter

The promoter driving expression of the Mycobacterium tuberculosis gene lipF (Rv3487c) had previously been identified as being upregulated by acidic stress. Subsequently a 59 base pair (bp) acid inducible minimal promoter region was isolated in which a putative -10 region was identified. In this study we use mutational analysis to investigate the -10 region of the lipF promoter. Mutations within this region lead to a dramatic decrease of promoter activity, while a mutation outside of this region does not affect promoter activity.     

Human Immunodeficiency Virus Type 2 (HIV-2)/HIV-1 Envelope Chimeras Detect High Titers of Broadly Reactive HIV-1 V3-Specific Antibodies in Human Plasma

Deciphering antibody specificities that constrain human immunodeficiency virus type 1 (HIV-1) envelope (Env) diversity, limit virus replication, and contribute to neutralization breadth and potency is an important goal of current HIV/AIDS vaccine research. Transplantation of discrete HIV-1 neutralizing epitopes into HIV-2 scaffolds may provide a sensitive, biologically functional context by which to quantify specific antibody reactivities even in complex sera. Here, we describe a novel HIV-2 proviral scaffold (pHIV-2_KR.X7) into which we substituted the complete variable region 3 (V3) of the env gene of HIV-1_YU2 or HIV-1_Ccon to yield the chimeric proviruses pHIV-2_KR.X7 YU2 V3 and pHIV-2_KR.X7 Ccon V3. These HIV-2/HIV-1 chimeras were replication competent and sensitive to selective pharmacological inhibitors of virus entry. V3 chimeric viruses were resistant to neutralization by HIV-1 monoclonal antibodies directed against the CD4 binding site, coreceptor binding site, and gp41 membrane proximal external region but exhibited striking sensitivity to HIV-1 V3-specific monoclonal antibodies, 447-52D and F425 B4e8 (50% inhibitory concentration of [IC₅₀] <0.005 μg/ml for each). Plasma specimens from 11 HIV-1 clade B- and 10 HIV-1 clade C-infected subjects showed no neutralizing activity against HIV-2 but exhibited high-titer V3-specific neutralization against both HIV-2/HIV-1 V3 chimeras with IC₅₀ measurements ranging from 1:50 to greater than 1:40,000. Neutralization titers of B clade plasmas were as much as 1,000-fold lower when tested against the primary HIV-1_YU2 virus than with the HIV-2_KR.X7 YU2 V3 chimera, demonstrating highly effective shielding of V3 epitopes in the native Env trimer. This finding was replicated using a second primary HIV-1 strain (HIV-1_BORI) and the corresponding HIV-2_KR.X7 BORI V3 chimera. We conclude that V3 is highly immunogenic in vivo, eliciting antibodies with substantial breadth of reactivity and neutralizing potential. These antibodies constrain HIV-1 Env to a structure(s) in which V3 epitopes are concealed prior to CD4 engagement but do not otherwise contribute to neutralization breadth and potency against most primary virus strains. Triggering of the viral spike to reveal V3 epitopes may be required if V3 immunogens are to be components of an effective HIV-1 vaccine.     

Expanded Breadth of the T-Cell Response to Mosaic Human Immunodeficiency Virus Type 1 Envelope DNA Vaccination

An effective AIDS vaccine must control highly diverse circulating strains of human immunodeficiency virus type 1 (HIV-1). Among HIV-1 gene products, the envelope (Env) protein contains variable as well as conserved regions. In this report, an informatic approach to the design of T-cell vaccines directed to HIV-1 Env M group global sequences was tested. Synthetic Env antigens were designed to express mosaics that maximize the inclusion of common potential T-cell epitope (PTE) 9-mers and minimize the inclusion of rare epitopes likely to elicit strain-specific responses. DNA vaccines were evaluated using intracellular cytokine staining in inbred mice with a standardized panel of highly conserved 15-mer PTE peptides. One-, two-, and three-mosaic sets that increased theoretical epitope coverage were developed. The breadth and magnitude of T-cell immunity stimulated by these vaccines were compared to those for natural strain Envs; additional comparisons were performed on mutant Envs, including gp160 or gp145 with or without V regions and gp41 deletions. Among them, the two- or three-mosaic Env sets elicited the optimal CD4 and CD8 responses. These responses were most evident in CD8 T cells; the three-mosaic set elicited responses to an average of eight peptide pools, compared to two pools for a set of three natural Envs. Synthetic mosaic HIV-1 antigens can therefore induce T-cell responses with expanded breadth and may facilitate the development of effective T-cell-based HIV-1 vaccines.The development of AIDS vaccines has been advanced recently by demonstrations of increased survival and decreased viral load following vaccination with T-cell vaccines in nonhuman primate models (12, 19, 23, 26, 31, 37). Although such vaccine studies have implied that T cells may contribute to the control of viremia in the highly lethal simian immunodeficiency virus SIVmac251 challenge model, the applicability of these results in human studies remains uncertain. The major concern regarding the efficacy of human immunodeficiency virus (HIV) vaccines in humans is the extraordinary genetic diversity of the virus. The sequence similarity of HIV type 1 (HIV-1) envelope from diverse isolates within a clade can diverge by as much as 15%, and divergence between alternative clades may approach 30% (10). In addition, the diversity of the viral Gag gene product can approach similar levels, particularly in p17 and p15, which are much more diverse than p24 (6), although Gag does not have the extreme localized diversity seen in the highly variable regions of Env (6, 10). While the approach to viral diversity has been addressed in existing vaccines through the use of envelopes derived from representative viruses in the major clades, increasing knowledge about the genetic diversity of naturally occurring isolates has enabled alternative approaches that enhance population coverage of vaccine-elicited T-cell responses.Approaches under consideration include the use of central gene sequences based on ancestral, consensus, or center-of-the-tree genetic analyses (5, 10, 18, 31, 36). Such prototypes are derived by selection of the most common amino acids at each residue (10, 16, 17, 21, 25, 36), identifying the most recent common ancestor of diverging viruses in a vaccine target population (5, 10, 18, 36), or modeling the sequence at the center of the phylogenetic tree (29), respectively. Peptides based on any of these three centralized protein strategies enhanced the detection of T-cell responses in natural infection relative to the use of peptides based on natural strains; however, all three strategies behaved equivalently (7).The use of a single M group consensus/ancestral Env sequence has been shown to elicit T-cell responses with greater breadth of cross-reactivity than single natural strains in animal models (31, 36). Such central sequences do not exist in nature, and even phylogenetic ancestral reconstructions are just an approximate model of an ancestral state of the virus (8). Thus, central sequence strategies have provided evidence that various informatically derived gene products can elicit immune responses to T-cell epitopes found in diverse circulating strains, leading to the possibility of using computational strategies to design polyvalent vaccines which optimize T-cell coverage (6, 24). In this study, we have evaluated for the first time the ability of nonnatural mosaic Env immunogens (6) to elicit T-cell responses of increased cross-reactivity against epitopes represented in naturally circulating viruses in animals.Mosaic HIV-1 envelope genes were derived using an informatic approach, whereby in silico-generated recombinants of natural variants from the Los Alamos database M group Env alignment were created, scored, and selected in combination to optimize the coverage of 9-mers in the global database for a given vaccine cocktail size. While mosaic proteins are artificial constructs that do not occur in nature, they align well to natural proteins, and any short span found in mosaics will tend to be found repeatedly among natural strains (although some of the hypervariable loop regions of Env are so extremely variable that they are not repeated among circulating strains, and this necessitates bridging these regions with segments found in a single strain). In silico recombination breakpoints are constrained to create fusion points found in natural sequences. It is possible to provide increased breadth of coverage with a single mosaic, providing the maximum possible single-antigen diversity coverage for stretches of nine amino acids. Alternatively, multiple mosaics can increase the breadth of representation but have the drawback of requiring the synthesis of additional vectors for clinical use. Mosaics also preserve a natural Env-like sequence to retain normal antigen processing. Here, we have compared single-, double-, or triple-mosaic envelope antigen sets to naturally circulating strains or other derivatives for their ability to elicit immune responses of increased breadth. The data suggest that mosaic HIV-1 envelope sequences provide an approach that may be useful in the development of HIV vaccines that respond to T-cell epitopes represented in naturally circulating strains.     

Use of Comet-FISH in the study of DNA damage and repair: review

The Comet-FISH technique is a useful tool to detect overall and region-specific DNA damage and repair in individual cells. It combines two well-established methods, the Comet assay (single cell gel electrophoresis) and the technique of fluorescence in situ hybridization (FISH). Whereas the Comet assay allows separating fragmented from non-fragmented DNA, FISH helps to detect specifically labelled DNA sequences of interest, including whole chromosomes. Thus the combination of both techniques has been applied in particular for detection of site-specific breaks in DNA regions which are relevant for development of different diseases. This paper reviews the relevant literature and presents three examples on how Comet-FISH was used for studying the induction of DNA damage by genotoxic compounds related to oxidative stress in colon cancer-relevant genes (TP53, APC, KRAS) of a colon adenoma cell line. The accumulated evidence on relative sensitivity of these genes in comparison to global damage allows a more definite conclusion on the possible contribution of the genotoxic factors during colorectal carcinogenesis. Telomere fragility was compared in different cell lines treated with cytostatic agents, and revealed new patterns of biological activities through the drugs and different sensitivities of the cell lines that were found to be associated with their tumour origin. A third example relates to measuring repair of specific gene regions using Comet-FISH, a method that can be developed to biomarker application. Taken together, available data suggests that Comet-FISH helps to get further insights into sensitivity of specific DNA regions and consequently in mechanisms of carcinogenesis. Although the nature of the measured Comet-FISH endpoint precludes us from stating basically that damage and repair are occurring within the specific gene, it is at least possible to evaluate whether the damage and repair are occurring within the vicinity of the gene of interest.     

The Structure of Neuroglobin at High Xe and Kr Pressure Reveals Partial Conservation of Globin Internal Cavities

Neuroglobin (Ngb) is a hexacoordinate globin expressed in the brain of vertebrates. Ferrous Ngb binds dioxygen with high affinity and the O₂ adduct is able to scavenge NO. Convincing in vitro and in vivo data indicate that Ngb is involved in neuroprotection during hypoxia and ischemia. The 3D structure of Ngb reveals the presence of a wide internal cavity connecting its heme active site with the bulk. To explore the role of this “tunnel” in the control of ligand binding, we determined the structure of metNgb and NgbCO equilibrated with Xe or Kr. We show four docking sites for Xe (only two for Kr); two of the four Xe sites are within the large cavity. They are only partially conserved in globins, since the two proximal Xe sites identified in myoglobin (Xe1 and Xe2) are absent in Ngb, as well as in cytoglobin. The Xe docking sites in Ngb map a pathway within the protein matrix, leading to the heme, which becomes more accessible in the ligand-bound species. This may be of significance in connection with the redox chemistry that may be the primary function of this hexacoordinate globin.