The imprinting box of the Prader-Willi/Angelman syndrome domain.

A subset of mammalian genes is monoallelically expressed in a parent-of-origin manner. These genes are subject to an imprinting process that epigenetically marks alleles according to their parental origin during gametogenesis. Imprinted genes can be organized in clusters as exemplified by the 2-Mb domain on human chromosome 15q11-q13 and its mouse orthologue on chromosome 7c (ref. 1). Loss of this 2-Mb domain on the paternal or maternal allele results in two neurogenetic disorders, Prader-Willi syndrome (PWS) or Angelman syndrome (AS), respectively. Microdeletions on the paternal allele share a 4.3-kb short region of overlap (SRO), which includes the SNRPN promoter/exon1, cause PWS and silence paternally expressed genes. Microdeletions on the maternal allele share a 0.88-kb SRO located 35 kb upstream to the SNRPN promoter, cause AS and alleviate repression of genes on the maternal allele. Individuals carrying both AS and PWS deletions on the paternal allele show a PWS phenotype and genotype. These observations suggest that cis elements within the AS-SRO and PWS-SRO constitute an imprinting box that regulates the entire domain on both chromosomes. Here we show that a minitransgene composed of a 200-bp Snrpn promoter/exon1 and a 1-kb sequence located approximately 35 kb upstream to the SNRPN promoter confer imprinting as judged by differential methylation, parent-of-origin-specific transcription and asynchronous replication.

High susceptibility to bacterial infection, but no liver dysfunction, in mice compromised for hepatocyte NF-kappaB activation.

Based on the essential involvement of NF-kappaB in immune and inflammatory responses and its apoptosis-rescue function in normal and malignant cells, inhibitors of this transcription factor are potential therapeutics for the treatment of a wide range of diseases, from bronchial asthma to cancer. Yet, given the essential function of NF-kappaB in the embryonic liver, it is important to determine its necessity in the liver beyond embryogenesis. NF-kappaB is normally retained in the cytoplasm by its inhibitor IkappaB, which is eliminated upon cell stimulation through phosphorylation-dependent ubiquitin degradation. Here, we directed a degradation-resistant IkappaBalpha transgene to mouse hepatocytes in an inducible manner and showed substantial tissue specificity using various means, including a new method for live-animal imaging. Transgene expression resulted in obstruction of NF-kappaB activation, yet produced no signs of liver dysfunction, even when implemented over 15 months. However, the transgene-expressing mice were very vulnerable both to a severe immune challenge and to a systemic bacterial infection. Despite having intact immunocytes and inflammatory cells, these mice were unable to clear Listeria monocytogenes from the liver and succumbed to sepsis. These findings indicate the essential function of the hepatocyte through NF-kappaB activation in certain systemic infections, possibly by coordinating innate immunity in the liver.

DNA methylation represses transcription in vivo.

DNA in somatic tissue is characterized by a bimodal pattern of methylation, which is established in the animal through a series of developmental events. In the mouse blastula, most DNA is unmethylated, but after implantation a wave of de novo methylation modifies most of the genome, excluding the majority of CpG islands, which are mainly associated with housekeeping genes. This genomic methylation pattern is broadly maintained during the life of the organism by maintenance methylation, and generally correlates with gene expression. Experiments both in vitro and in vivo indicate that methylation inhibits transcription. It has not yet been possible, however, to determine the role of DNA methylation on specific sequences during normal development. Cis-acting regulatory elements and trans-acting factors appear to be involved in both stage- and tissue-specific demethylation processes. Sp1-like elements have a key role in protecting the CpG island of Aprt (encoding adenine phosphoribosyltransferase) from de novo methylation, and when these elements are specifically mutated, the Aprt CpG island becomes methylated in transgenic mice. We have now characterized an embryo-specific element from the CpG island sequence upstream of Aprt that can protect itself from de novo methylation in transgenic mice as well as reduce methylation of flanking sequences. We placed this element on a removable cassette adjacent to a human HBB (encoding beta-globin) reporter and generated a transgene whose methylation pattern can be switched in vivo. Analysis of globin transcription in this system showed that methylation in cis inhibits gene expression in a variety of tissues, indicating that DNA modification may serve as a global genomic repressor.

Modification of M1 cells by exogenous introduction of IL6 gene: a model for gene therapy of acute and chronic myeloid leukemia in mice.

A number of recent studies has shown that animals immunized with cytokine secreting primary tumors show resistance against an unmodified tumor cell challenge. In the present study we have evaluated the potential role of IL6, a myeloid differentiation inducing factor, in modifying myeloid leukemia cells, a tumor so far not challenged by this approach. M1 cells transduced with N2 based retrovirus carrying the murine IL6 gene exhibit morphological and functional alterations. Genetically modified M1 cells show significant reduction in the growth constant coefficient and in the ability to form hematopoietic colonies. Flow cytometry analysis demonstrate increased expression of CD11b, CD18, F4/80, FcR and MHC class II, suggesting driven differentiation towards commitment. Transduced cells secrete high level of autocrine IL6 and, upon activation with LPS, high levels of TNF further indicating a functional alteration and differentiation. The insertion of IL6 gene coding for signals of cell activation and improved expression of MHC antigens into myeloid leukemia cells may enable more effective tumor recognition in vivo, and boost the local as well as the systemic immune-mediated anti-leukemia response.

Neutrophil CD14: biochemical properties and role in the secretion of tumor necrosis factor-alpha in response to lipopolysaccharide.

CD14 is a myeloid cell differentiation Ag expressed primarily by monocytes and macrophages. CD14 has recently been shown to function as a receptor for a complex of LPS and LPS binding protein (LBP), an acute phase serum protein also present in normal serum in trace amounts. In the presence of LBP, LPS strongly activates monocytes via CD14 as measured by TNF secretion. This pathway of monocyte activation is thought to be a major contributor to the symptoms of endotoxin shock. Another major cell type involved in the response to Gram-negative infection is the neutrophil. Recent studies have shown that neutrophils also express CD14 and suggest that they can respond to LPS through a similar pathway. However, the biochemical nature of neutrophil CD14 has not previously been described. In this report, we have analyzed several biochemical characteristics of neutrophil CD14. We show that CD14 is actively synthesized by neutrophils as a glycosylphosphatidyl-inositol-anchored protein, indistinguishable in size from monocyte CD14. Furthermore, neutrophils, like monocytes, shed a smaller soluble form of CD14 into culture supernatants. In addition, like monocytes, neutrophils respond to LPS/LBP complexes via CD14 by releasing TNF-alpha. The described properties and function of neutrophil CD14 suggest that it may directly participate in the acute inflammatory response and in endotoxin shock.

Transgenic mice expressing human CD14 are hypersensitive to lipopolysaccharide.

In vitro studies have previously shown that the myelomonocytic differentiation antigen CD14 is a receptor for a complex consisting of lipopolysaccharide (LPS) and LPS-binding protein. To investigate the role of CD14 in vivo and its relationship to induction of LPS-induced endotoxin shock, transgenic mice expressing human CD14 were produced. These mice express human CD14 strongly on the surface of their monocytes, neutrophils, and Thy-1(+) lymphocytes and are hypersensitive to LPS, as evidenced by their increased susceptibility to endotoxin shock. These results document the importance of CD14 in vivo as a primary mediator of this lethal syndrome. Furthermore, these mice provide an important model for testing the therapeutic effects of agents directed specifically against the human, as opposed to the murine, CD14 protein in preventing LPS-induced endotoxin shock.

In vitro and in vivo cytokine-induced facilitation of immunohematopoietic reconstitution in mice undergoing bone marrow transplantation.

The aim of this study was to test whether colony stimulating factors (CSF) and other cytokines facilitate the recovery of a variety of immunohematopoietic functions in lethally irradiated mice undergoing bone marrow transplantation (BMT). Two experimental systems were employed: (a) lethally irradiated mice transplanted with syngeneic or T cell-depleted semi-allogeneic bone marrow (BM) cells (0.1-10 x 10(6)), subsequently treated by multiple doses of cytokines; and (b) lethally irradiated mice transplanted with BM cells that had previously been cultivated with cytokines. The cytokines used were: pure natural mouse interleukin-3 (IL-3); recombinant mouse granulocyte-macrophage CSF (rGM-CSF); recombinant human interleukin-2 (rIL-2); and crude cytokine preparations obtained from the culture supernatants of murine leukemia WEHI-3b cells (containing mainly IL-3), and of phorbol myristate acetate (PMA)-stimulated EL4 leukemia cells and concanavalin A-stimulated rat splenocytes (each containing a multitude of cytokines). For BM cultures (1-9 days), the cytokines were used at a dosage of 1-100 U/ml; for in vivo treatment, 2 x 10(2)-5 x 10(4) units were administered intraperitoneally and subcutaneously at different schedules for varying periods (1-3 weeks). The following parameters were tested 1-10 weeks post-BMT: white blood cell count, colony formation in agar and in the spleen of lethally irradiated mice, proliferative responses to mitogens and alloantigens, allocytotoxicity and antibody production (serum agglutinins and plaque-forming cells) against sheep red blood cells. Under appropriate conditions, cytokine treatment either in vitro or in vivo significantly enhanced (2- to 50-fold compared with controls) most functions tested at 2-8 weeks post-BMT, and shortened the time interval required for full immunohematopoietic recovery by 2-5 weeks. In recipients of semi-allogeneic, T lymphocyte-depleted BM no evidence of graft-versus-host disease was found. It is suggested that judicious application in vitro and/or in vivo of certain pure cytokines (e.g. GM-CSF, IL-3) or cytokine 'cocktails' might be beneficial in enhancing hematopoiesis and in the treatment of immunodeficiency associated with BMT.

Bone marrow transplantation with T-cell-depleted grafts. II. Reconstitution of immunohemopoietic functions in lethally irradiated mice transplanted with unseparated or T-cell-depleted bone marrow grafts disparate at minor histocompatibility antigens.

Graft-versus-host disease (GVHD), a serious complication of allogeneic bone marrow transplantation (BMT), can be prevented by in vitro depletion of T cells from the bone marrow (BM) prior to transplantation. The purpose of this study was to assess the role of BMT cells in the reconstitution of various immune functions following BMT across minor histocompatibility barriers. Lethally irradiated CBA/J (H-2k) mice were grafted with either 10(7) unseparated or T-cell-depleted BM cells from B10.BR (H-2k, minor-histoincompatible) mice. Blood counts, BM colonies in agar, and various immune functions of spleen cells from the recipient mice were tested 2-12 weeks post-BMT and compared with those of normal donors. The following observations were made: (A) Peripheral blood lymphocyte counts decreased to 30% of normal 2 weeks post-BMT with almost normal recovery at 8 weeks. (B) The percentage of Thy1.2+ splenocytes reached normal levels at 8 weeks post-BMT. (C) The number of BM colonies (GM-CFU) was reduced to 10% at 2 weeks and fully recovered at 12 weeks. (D) Proliferative response to the B-cell mitogen LPS was fully reconstituted after 4 weeks; however, anti-SRBC PFC (following Mishell-Dutton cultures) was restored 50% at 8-12 weeks. (E) Reconstitution of T cell functions including proliferative responses to concanavalin A, phytohemagglutinin, and allogeneic leukocytes, and allocytotoxicity, did not exceed 50% even 12 weeks post-BMT. Overall, depletion of T cells from donor BM allografts incompatible at minor histocompatibility loci, did not seem to significantly alter the rate of immunohematopoietic reconstitution in the lethally irradiated BM recipients.