Cell biology of IL-7, a key lymphotrophin.

IL-7 is essential for the development and survival of T lymphocytes. This review is primarily from the perspective of the cell biology of the responding T cell. Beginning with IL-7 receptor structure and regulation, the major signaling pathways appear to be via PI3K and Stat5, although the requirement for either has yet to be verified by published knockout experiments. The proliferation pathway induced by IL-7 differs from conventional growth factors and is primarily through posttranslational regulation of p27, a Cdk inhibitor, and Cdc25a, a Cdk-activating phosphatase. The survival function of IL-7 is largely through maintaining a favorable balance of bcl-2 family members including Bcl-2 itself and Mcl-1 on the positive side, and Bax, Bad and Bim on the negative side. There are also some remarkable metabolic effects of IL-7 withdrawal. Studies of IL-7 receptor signaling have yet to turn up unique pathways, despite the unique requirement for IL-7 in T cell biology. There remain significant questions regarding IL-7 production and the major producing cells have yet to be fully characterized.

p205, a potential tumor suppressor, inhibits cell proliferation via multiple pathways of cell cycle regulation.

p205 is a member of the interferon-inducible p200 family of proteins that regulate cell proliferation. Over-expression of p205 inhibits cell growth, although its mechanism of action is currently unknown. Therefore, we evaluated the effect of p205 on the p53 and Rb-dependent pathways of cell cycle regulation. p205 expression results in elevated levels of p21, and activates the p21 promoter in vitro in a p53-dependent manner. In addition, p205 induces increased expression of Rb, and binds directly to Rb and p53. Interestingly, p205 also induces growth inhibition independent of p53 and Rb by delaying G2/M progression in proliferating cells, and is a substrate for Cdk2 kinase activity. Finally, we have identified other binding partners of p205 by a yeast two-hybrid screen, including the paired homeodomain protein HoxB2. Taken together, our results indicate that p205 induces growth arrest by interaction with multiple transcription factors that regulate the cell cycle, including but not entirely dependent on the Rb- and p53-mediated pathways of growth inhibition.

Heterologous HIV-based lentiviral/adenoviral vectors immunizations result in enhanced HIV-specific immunity.

Viral vectors are considered as one of the major means for the induction of strong immune responses against recombinant antigens by genetic immunization. Among these, lentiviral vectors are particularly attractive vehicles, as they can infect a wide variety of cells and can transduce replicating as well as non-replicating cells. We have engineered VRX1023, an HIV-1-based lentiviral vector (LV) vaccine candidate, to deliver HIV-1 Gag, Pol and Rev antigens under control of the native LTR promoter. While VRX1023 has been shown to elicit strong cell-mediated and humoral immunity as a stand-alone vaccine, we report here its combination in a heterologous prime-boost approach. Its combination with an adenovirus serotype 5 (Ad5)-based vector in the mouse model increased the frequency and polyfunctionality of HIV-specific CD4+ and CD8+ T cells. Homologous prime-boost regimens induced high levels of anti-vector neutralizing antibodies in Ad5-immunized mice, whereas the VSV-G-pseudotyped VRX1023 LV elicited low levels of anti-lentiviral vector neutralization. In addition, the heterologous prime-boost strategy resulted in a 5-fold reduction in Ad5-specific vector neutralization as compared to Ad5 homologous immunization. In conclusion, this study demonstrates that LV and Ad5 vector candidates can be combined in a heterologous immunization regimen, yielding dramatically improved immunogenicity while overcoming anti-vector immunity. These findings may have implications for the development of HIV vaccine regimens in populations with elevated Ad5 seroprevalence or when repeated vector administrations are required.

An HIV-based lentiviral vector as HIV vaccine candidate: Immunogenic characterization.

Recently developed viral-vectored HIV vaccine candidates, despite achieving high levels transgene expression and inducing high magnitude immune responses to HIV, have faced limitations related to anti-vector immunity. In contrast, lentiviral vectors (LV) have been shown to be less sensitive to anti-vector neutralizing activity, while displaying desirable characteristics, such as transduction of non-dividing cells, including antigen-presenting cells, and long-term transgene expression. We have developed VRX1023, an HIV-based LV expressing HIV Gag, Pol and Rev under the control of the native HIV LTR. In mice, this vector induced significant mucosal and systemic cellular and humoral responses against HIV after sub-cutaneous injection. Similarly to other viral vectors, this LV candidate can be effectively used in DNA prime, LV boost strategies, where it elicited as high as 21% HIV Gag-specific CD8 responses as measured by intracellular cytokine staining. Moreover, anti-vector immunity is not an obstacle to repeated LV administrations, as shown by improved anti-HIV responses compared to single LV immunization. In head to head comparisons with Ad5 vectors expressing the same vaccine payload, VRX1023 elicited higher and more persistent cellular and antibody responses to HIV than its adenoviral counterpart. In preparation for clinical use, manufacturing scale-up of a highly purified VRX1023 vector lot following cGMP was successfully achieved without altering the robust immunogenicity observed with the research-grade vector. VRX1023, in addition to competing favorably with existing vectors such as Ad5 for anti-HIV immune responses, demonstrates unique features likely to address some of the pitfalls of current vector-based HIV vaccine strategies.

Synergistic effect of TRM2/RNC1 and EXO1 in DNA double-strand break repair in Saccharomyces cerevisiae.

In our recently published study, we provided in vitro as well as in vivo data demonstrating the involvement of TRM2/RNC1 in homologous recombination based repair (HRR) of DNA double strand breaks (DSBs), in support of such claims reported earlier. To further validate its role in DNA DSB processing, our present study revealed that the trm2 single mutant displays higher sensitivity to persistent induction of specific DSBs at the MAT locus by HO-endonuclease with higher sterility rate among the survivors compared to wild type (wt) or exo1 single mutants. Intriguingly, both sensitivity and sterility rate increased dramatically in trm2exo1 double mutants lacking both endo-exonucleases with a progressively increased sterility rate in trm2exo1 double mutants with short-induction periods, reaching a very high level of sterility with persistent DSB inductions. Mutation analysis of the mating type (MAT) locus among the sterile survivors with persistent HO-induction in trm2 and exo1 single mutants as well as in trm2exo1 double mutants revealed a similar small insertions and deletions events, characteristic of non-homologous end joining (NHEJ) that might have occurred due to the lack of proper processing function in these mutants. In addition, trm2ku80 and trm2rad52 double mutants also displayed significantly higher sterility with persistent DSB induction compared to ku80 and rad52 single mutants, respectively, exhibiting a mutation spectra that shifted from base substitution (in ku80 and rad52 single mutants) to small insertions and deletions in the double mutants (in trm2ku80 and trm2rad52 mutants). These data indicate a defective processing in absence of TRM2, with a synergistic effect of TRM2, and EXO1 in such processing.

Functional and genetic analysis of the Saccharomyces cerevisiae RNC1/TRM2: evidences for its involvement in DNA double-strand break repair.

We previously isolated the RNC1/TRM2 gene and provided evidence that it encodes a protein with a possible role in DNA double strand break repair. RNC1 was independently re-isolated as the TRM2 gene encoding a methyl transferase involved in tRNA maturation. Here we show that Trm2p purified as a fusion protein displayed 5' --> 3' exonuclease activity on double-strand (ds) DNA, and endonuclease activity on single-strand (ss) DNA, properties characteristic of previously isolated endo-exonucleases. A variant of Trm2p, Trm2p(ctDelta76aa) lacking 76 amino acids at the C-terminus retained nuclease activities but not the methyl transferase activity. Both the native and the variant exhibited sensitivity to the endo-exonuclease inhibitor pentamidine. The Saccharomyces cerevisiae trm2(Delta232-1920nt) mutant (containing only the first 231 nucleotides of the TRM2 gene) displayed low sensitivity to methyl methane sulfonate (MMS) and suppressed the MMS sensitivity of rad52 mutants in trm2(Delta232-1920nt)rad52 double mutants. The deletion of KU80, in trm2(Delta232-1920nt) mutant background displayed higher MMS sensitivity supporting the view of the possible role of Trm2p in a competing repair pathway separate from NHEJ. In addition, trm2 exo1 double mutants were synergistically more sensitive to MMS and ionizing radiation than either of the single mutant suggesting that TRM2 and EXO1 can functionally complement each other. However, the C-terminal portion, required for its methyl transferase activity was found not important for DNA repair. These results propose an important role for TRM2 in DNA repair with a potential involvement of its nuclease function in homologous recombination based repair of DNA DSBs.

The interferon-inducible p200 family of proteins: a perspective on their roles in cell cycle regulation and differentiation.

The interferon-inducible p200 (IFI-200) family of proteins is among the numerous gene products induced by interferons (IFNs), which are important regulators of cell growth, immunomodulation and host resistance to tumors and viral infections. The members of this family of proteins are highly homologous to one another and consist of five murine proteins including p202, p203, p204 and p205 as well as three human homologues; IFI-16, myeloid cell nuclear differentiation antigen (MNDA) and absent in melanoma (AIM) 2. They possess at least one copy of a conserved 200 amino-acid motif which exists in two types; the a and b domains. Most of the IFI-200 proteins also possess a domain in apoptosis and interferon response (DAPIN)/PYRIN domain, which is a conserved motif associated with protein-protein interactions in the regulation of apoptotic and inflammatory signaling pathways. The p200 proteins have been implicated in cell cycle regulation and differentiation based on their ability to interact with and modulate the activities of multiple transcriptional factors such as Rb and p53, and there are significant findings that link mutations in their genetic loci to the incidence of cancer. Here, we describe the structure and biological activities of these proteins, and discuss recent studies that describe their relevant roles in processes regulating cell proliferation and differentiation.

Inhibition of growth by p205: a nuclear protein and putative tumor suppressor expressed during myeloid cell differentiation.

p205 belongs to a family of interferon-inducible proteins called the IFI-200 family, which have been implicated in the regulation of cell growth and differentiation. While p205 is induced in hematopoietic stem cells during myeloid cell differentiation, its function is not known. Therefore, the aim of this study was to determine the role of p205 in regulating proliferation in hematopoietic progenitor cells and in nonhematopoietic cell lines. We found that p205 localizes to the nucleus in hematopoietic and nonhematopoietic cell lines. Transient expression of p205 in murine IL-3-dependent BaF3 and 32D-C123 progenitor cell lines inhibited IL-3-induced growth and proliferation. The closely related IFI-200 family members, p204 and p202, similarly inhibited IL-3-dependent progenitor cell proliferation. p205 also inhibited the proliferation and growth of normal hematopoietic progenitor cells. In nonhematopoietic cell lines, p205 and p204 expression inhibited NIH3T3 cell colony formation in vitro, and microinjection of p205 expression vectors into NIH3T3 fibroblasts inhibited serum-induced proliferation. We have determined the functional domains of p205 necessary for activity, which were identified as the N-terminal domain in apoptosis and interferon response (DAPIN)/PYRIN domain, and the C-terminal retinoblastoma protein (Rb)-binding motif. In addition, we have demonstrated that a putative ataxia telangiectasia, mutated (ATM) kinase phosphorylation site specifically regulates the activity of p205. Taken together, these data suggest that p205 is a potent cell growth regulator whose activity is mediated by its protein-binding domains. We propose that during myelomonocytic cell differentiation, induction of p205 expression contributes to cell growth arrest, thus allowing progenitor cells to differentiate.