Role of chromosome stability and telomere length in the production of viable cell lines for somatic cell nuclear transfer

Background  

Somatic cell nuclear transfer (SCNT) provides an appealing alternative for the preservation of genetic material in non-domestic and endangered species. An important prerequisite for successful SCNT is the availability of good quality donor cells, as normal embryo development is dependent upon proper reprogramming of the donor genome so that embryonic genes can be appropriately expressed. The characteristics of donor cell lines and their ability to produce embryos by SCNT were evaluated by testing the effects of tissue sample collection (DART biopsy, PUNCH biopsy, post-mortem EAR sample) and culture initiation (explant, collagenase digestion) techniques.     

AMP-deaminase from normal and cirrhotic human liver: A comparative study

AMP-deaminase (EC 3.5.4.6) is an enzyme of nucleotide breakdown involved in regulation of adenine nucleotide pool in mammalian cells. Reaction catalysed by AMP-deaminase constitutes a rate-limiting step in adenine nucleotide catabolism in liver. In this study kinetic and regulatory properties of AMP-deaminase purified from normal and cirrhotic human liver were investigated. In comparison to AMP-deaminase extracted from the normal human liver, AMP-deaminase extracted from the cirrhotic liver was less sensitive towards substrate analogues, and only a very limited response towards pH and adenylate energy charge changes tested for enzyme isolated from this tissue source had been observed. At physiological pH 7.0, in the absence and in the presence of important allosteric effectors (ATP, ADP, GTP and orthophosphate), AMP-deaminases from the two sources studied manifested different regulatory profiles, with half-saturation constant (S0.5) values being distinctly higher for the enzyme extracted from the pathological organ. In contrast to AMP-deaminase isolated from the normal, healthy liver, where presence of relatively large (68 kDa) protein fragment was also detected, only smaller protein fragments were identified, while SDS-PAG electrophoresis of AMP-deaminase isolated from the cirrhotic liver was performed. The obtained results indicate clearly that advanced proteolytic processes occurring in the cirrhotic liver may affect structural integrity of AMP-deaminase studied, making enzyme less active and less sensitive to regulatory action of important allosteric effectors.     

Inhibition of In Vivo HIV Infection in Humanized Mice by Gene Therapy of Human Hematopoietic Stem Cells with a Lentiviral Vector Encoding a Broadly Neutralizing Anti-HIV Antibody

Due to the inherent immune evasion properties of the HIV envelope, broadly neutralizing HIV-specific antibodies capable of suppressing HIV infection are rarely produced by infected individuals. We examined the feasibility of utilizing genetic engineering to circumvent the restricted capacity of individuals to endogenously produce broadly neutralizing HIV-specific antibodies. We constructed a single lentiviral vector that encoded the heavy and light chains of 2G12, a broadly neutralizing anti-HIV human antibody, and that efficiently transduced and directed primary human B cells to secrete 2G12. To evaluate the capacity of this approach to provide protection from in vivo HIV infection, we used the humanized NOD/SCID/γ_c^null mouse model, which becomes populated with human B cells, T cells, and macrophages after transplantation with human hematopoietic stem cells (hu-HSC) and develops in vivo infection after inoculation with HIV. The plasma of the irradiated NOD/SCID/γ_c^null mice transplanted with hu-HSC transduced with the 2G12-encoding lentivirus contained 2G12 antibody, likely secreted by progeny human lymphoid and/or myeloid cells. After intraperitoneal inoculation with high-titer HIV-1_JR-CSF, mice engrafted with 2G12-transduced hu-HSC displayed marked inhibition of in vivo HIV infection as manifested by a profound 70-fold reduction in plasma HIV RNA levels and an almost 200-fold reduction in HIV-infected human cell numbers in mouse spleens, compared to control hu-HSC-transplanted NOD/SCID/γ_c^null mice inoculated with equivalent high-titer HIV-1_JR-CSF. These results support the potential efficacy of this new gene therapy approach of using lentiviral vectors encoding a mixture of broadly neutralizing HIV antibodies for the treatment of HIV infection, particularly infection with multiple-drug-resistant isolates.While broadly neutralizing human immunodeficiency virus (HIV)-specific antibodies have the capacity to prevent or suppress HIV infection, they are rarely produced by infected individuals, thereby markedly compromising the ability of the humoral response to control HIV infection (reviewed in reference 28). The high degree of sequence variability in the gp120 structure limits the number of highly conserved epitopes available for targeting by neutralizing antibodies (40). In addition, HIV utilizes several mechanisms to shield the limited number of conserved neutralizing epitopes from the potentially potent antiviral effects of HIV envelope-specific antibodies (14). First, the envelope protein is heavily glycosylated, and the linkage of the most immunoreactive envelope peptide structures to poorly immunogenic glycans shields them from antibody binding (37). Second, exposure of neutralizing epitopes not protected from antibody binding by glycosylation is greatly reduced by trimerization of the gp120-gp41 structure (5). Third, susceptibility of other neutralizing epitopes to antibodies is greatly reduced by limiting their accessibility to antibody binding to the brief transient phase of conformational changes that occur only during binding of the envelope protein to its cellular receptors, CD4 and CCR5 or CXCR4 (41). These intrinsic structural features of gp120 greatly reduce the capacity of natural HIV infection or vaccination to generate broadly neutralizing antibodies able to prevent or control infection. Despite these constraints, rare human antibodies with broad anti-HIV neutralizing activity, i.e., 2G12, b12, 2F5, and 4E10, have been isolated (2).The capacity of passive immunization with neutralizing antibodies to prevent infection was suggested by challenge studies demonstrating that transferred neutralizing antibodies protected monkeys from infection by simian immunodeficiency virus (SIV) and simian-human immunodeficiency virus (SHIV) (15). These studies were extended to humans, including several studies that examined the effect of passive immunotherapy using 2G12, 2F5, and 4E10 on inhibition of HIV replication in infected individuals (20). Passive immunotherapy with a triple combination of 2G12, 2F5, and 4E10 delayed viral rebound after the cessation of highly active antiretroviral therapy (HAART), and activity of 2G12 was critical for inhibitory activity by this antibody combination (18). The key role of 2G12 in suppressing HIV replication was supported by the development of viral rebound in parallel with the emergence of HIV isolates resistant to neutralization by 2G12 (19).While HIV infection may be controlled by the lifelong treatment of HIV-infected individuals with periodic infusions of neutralizing-antibody cocktails every few weeks, this is not a practical or cost-effective therapeutic approach. Eliciting these antibodies by vaccination has not been successful. Therefore, we investigated whether we could circumvent the mechanisms that limit the endogenous production of broadly neutralizing HIV-specific antibodies using a molecular genetic approach to generate B cells that secrete these protective antibodies. In a proof-of-concept study, we examined the capacity of a single lentiviral vector to express the heavy and light chains of the 2G12 antibody, a well-studied anti-HIV human antibody that has broad neutralizing activity both against T cell line-adapted and primary HIV isolates (31). The 2G12 antibody was generated by applying murine/human xenohybridoma technology to establish human hybridoma cell lines from B cells isolated from HIV-infected individuals (16), and it targets the high-mannose and/or hybrid glycans of residues 295, 332, and 392 and peripheral glycans from residues 386 and 448 on gp120. In the current study we demonstrated that a lentiviral vector encoding the heavy and light chains of the 2G12 antibody reprogrammed B cells in vitro to secrete 2G12 with functional neutralizing activity. Furthermore, we demonstrated that the 2G12 lentiviral vector genetically modified human hematopoietic stem cells (hu-HSC), enabling them to differentiate in vivo into progeny cells that secreted 2G12 antibody that inhibited the development of in vivo HIV infection in humanized mice.     

A systems-biology analysis of feedback inhibition in the Sho1 osmotic-stress-response pathway

BACKGROUND: A common property of signal transduction systems is that they rapidly lose their ability to respond to a given stimulus. For instance in yeast, the mitogen-activated protein (MAP) kinase Hog1 is activated and inactivated within minutes, even when the osmotic-stress stimulus is sustained. RESULTS: Here, we used a combination of experimental and computational analyses to investigate the dynamic behavior of Hog1 activation in vivo. Computational modeling suggested that a negative-feedback loop operates early in the pathway and leads to rapid attenuation of Hog1 signaling. Experimental analysis revealed that the membrane-bound osmosensor Sho1 is phosphorylated by Hog1 and that phosphorylation occurs on Ser-166. Moreover, Sho1 exists in a homo-oligomeric complex, and phosphorylation by Hog1 promotes a transition from the oligomeric to monomeric state. A phosphorylation-site mutation (Sho1(S166E)) diminishes the formation of Sho1-oligomers, dampens activation of the Hog1 kinase, and impairs growth in high-salt or sorbitol conditions. CONCLUSIONS: These findings reveal a novel phosphorylation-dependent feedback loop leading to diminished cellular responses to an osmotic-stress stimulus.     

Soluble TNF-like cytokine (TL1A) production by immune complexes stimulated monocytes in rheumatoid arthritis

TNF-like cytokine (TL1A) is a newly identified member of the TNF superfamily of ligands that is important for T cell costimulation and Th1 polarization. However, despite increasing information about its functions, very little is known about expression of TL1A in normal or pathological states. In this study, we report that mononuclear phagocytes appear to be a major source of TL1A in rheumatoid arthritis (RA), as revealed by their strong TL1A expression in either synovial fluids or synovial tissue of rheumatoid factor (RF)-seropositive RA patients, but not RF-/RA patients. Accordingly, in vitro experiments revealed that human monocytes express and release significant amounts of soluble TL1A when stimulated with insoluble immune complexes (IC), polyethylene glycol precipitates from the serum of RF+/RA patients, or with insoluble ICs purified from RA synovial fluids. Monocyte-derived soluble TL1A was biologically active as determined by its capacity to induce apoptosis of the human erythroleukemic cell line TF-1, as well as to cooperate with IL-12 and IL-18 in inducing the production of IFN-gamma by CD4(+) T cells. Because RA is a chronic inflammatory disease with autoimmune etiology, in which ICs, autoantibodies (including RF), and various cytokines contribute to its pathology, our data suggest that TL1A could be involved in its pathogenesis and contribute to the severity of RA disease that is typical of RF+/RA patients.     

Non-hinge-binding pyrazolo[1,5-a]pyrimidines as potent B-Raf kinase inhibitors

As part of our research effort to discover B-Raf kinase inhibitors, we prepared a series of C-3 substituted N-(3-(pyrazolo[1,5-a]pyrimidin-7-yl)phenyl)-3-(trifluoromethyl)benzamides. X-ray crystallography studies revealed that one of the more potent inhibitors (10n) bound to B-Raf kinase without forming a hinge-binding hydrogen bond. With basic amine residues appended to C-3 aryl residues, cellular activity and solubility were enhanced over previously described compounds of this class.     

Harvesting of novel polyhydroxyalkanaote (PHA) synthase encoding genes from a soil metagenome library using phenotypic screening

Salmonella enterica serovar Typhi and Typhimurium are closely related serovars. However, S. Typhi, a human-specific pathogen, has 5% of genes as pseudogenes, far more than S. Typhimurium, which only has 1%. One of these pseudogenes corresponds to sopD2, which in S. Typhimurium encodes an effector protein involved in Salmonella-containing vacuole biogenesis in human epithelial cell lines, which is needed for full virulence of the pathogen. We investigated whether S. Typhi trans-complemented with the functional sopD2 gene from S. Typhimurium (sopD2(STM) ) would reduce the invasion of human epithelial cell lines. Our results showed that the presence of sopD2(STM) in S. Typhi significantly modified the bacterial ability to alter cellular permeability and decrease the CFUs recovered after cell invasion of human epithelial cell line. These results add to mounting evidence that pseudogenes contribute to S. Typhi adaptation to humans.