Targeting TL1A/DR3 Signaling Offers a Therapeutic Advantage to Neutralizing IL13/IL4Rα in Muco-Secretory Fibrotic Disorders.

Mucus secretion is an important feature of asthma that highly correlates with morbidity. Current therapies, including administration of mucolytics and anti-inflammatory drugs, show limited effectiveness and durability, underscoring the need for novel effective and longer lasting therapeutic approaches. Here we show that mucus production in the lungs is regulated by the TNF superfamily member 15 (TL1A) acting through the mucus-inducing cytokine IL-13.

Multi-cell type gene coexpression network analysis reveals coordinated interferon response and cross-cell type correlations in systemic lupus erythematosus.

Systemic lupus erythematosus (SLE) is an incurable autoimmune disease disproportionately affecting women. A major obstacle in finding targeted therapies for SLE is its remarkable heterogeneity in clinical manifestations as well as in the involvement of distinct cell types. To identify cell-specific targets as well as cross-correlation relationships among expression programs of different cell types, we here analyze six major circulating immune cell types from SLE patient blood.

Prkci is required for a non-autonomous signal that coordinates cell polarity during cavitation.

Polarized epithelia define boundaries, spaces, and cavities within organisms. Cavitation, a process by which multicellular hollow balls or tubes are produced, is typically associated with the formation of organized epithelia. In order for these epithelial layers to form, cells must ultimately establish a distinct apical-basal polarity.

Atypical PKC-iota Controls Stem Cell Expansion via Regulation of the Notch Pathway.

The number of stem/progenitor cells available can profoundly impact tissue homeostasis and the response to injury or disease. Here, we propose that an atypical PKC, Prkci, is a key player in regulating the switch from an expansion to a differentiation/maintenance phase via regulation of Notch, thus linking the polarity pathway with the control of stem cell self-renewal. Prkci is known to influence symmetric cell division in invertebrates; however a definitive role in mammals has not yet emerged.

Evaluation of a fully human monoclonal antibody against multiple influenza A viral strains in mice and a pandemic H1N1 strain in nonhuman primates.

Influenza virus is a global health concern due to its unpredictable pandemic potential. Frequent mutations of surface molecules, hemagglutinin (HA) and neuraminidase (NA), contribute to low efficacy of the annual flu vaccine and therapeutic resistance to standard antiviral agents. The populations at high risk of influenza virus infection, such as the elderly and infants, generally mount low immune responses to vaccines, and develop severe disease after infection.

Targeted deletion of protein kinase C lambda reveals a distribution of functions between the two atypical protein kinase C isoforms.

Protein kinase C lambda (PKClambda) is an atypical member of the PKC family of serine/threonine kinases with high similarity to the other atypical family member, PKCzeta. This similarity has made it difficult to determine specific roles for the individual atypical isoforms. Both PKClambda and PKCzeta have been implicated in the signal transduction, initiated by mediators of innate immunity, that culminates in the activation of MAPKs and NF-kappaB.

Thymocyte maturation is regulated by the activity of the helix-loop-helix protein, E47.

The E2A proteins, E12 and E47, are required for progression through multiple developmental pathways, including early B and T lymphopoiesis. Here, we provide in vitro and in vivo evidence demonstrating that E47 activity regulates double-positive thymocyte maturation. In the absence of E47 activity, positive selection of both major histocompatibility complex (MHC) class I- and class II-restricted T cell receptors (TCRs) is perturbed.

Interleukin 7 induces TCR gene rearrangement in adult marrow-resident murine precursor T cells.

Rearrangement of the T cell antigen receptor genes is a complex, highly regulated process. To gain a better understanding of the extracellular factors involved in the regulation of TCR beta and gamma gene rearrangement in adult murine bone marrow-resident precursor T cells, several cytokines were tested for their ability to induce gene recombination. A selected population of C58/J bone marrow cells (Thy 1(low), CD3, CD8, B220) that is enriched for pre-T cell activity was propagated in vitro in medium supplemented with IL-3 and mast cell growth factor (MGF, also referred to as stem cell factor, Steele factor and c-kit ligand).

Pre-thymic transcription of TCR genes by adult murine bone marrow cells.

In the adult mouse, the earliest thymocytes are derived from bone marrow-resident T lymphocyte precursor (pre-T) cells that immigrate to the thymus. There they undergo maturation through a series of developmental steps that include rearrangement and expression of the TCR genes, positive and negative selection, and functional maturation. Although these intrathymic processes have been extensively characterized, little is known about the T cell-specific events that take place in the bone marrow microenvironment.

Transcription of the TCR-beta locus initiates in adult murine bone marrow.

Successful expression of the TCR beta-chain gene is a multistep process that involves: 1) initial transcription of multiple, unrearranged gene segments, 2) rearrangement of V, D, and J gene segments to form a complete beta-chain gene, and 3) transcription of the fully rearranged beta gene. All of these events have been shown to occur in the thymus, where the majority of T cell development takes place; however, the extent to which any of these events may occur prethymically has not been established. To examine prethymic TCR-beta gene expression, RNA was isolated from a precursor T cell-enriched population (Thy 1low CD3-) of C58/J mouse bone marrow, and analyzed by reverse transcriptase-PCR.

The expression of CD4 by T cell precursors resident in both the thymus and the bone marrow.

A very small fraction of thymocytes has recently been identified that expresses low levels of CD4 in the absence of CD8, CD3, or a TCR. These CD4lo thymocytes appear to be the precursors of the early CD4-CD8-CD3- thymic subset and contain most of the T cell progenitor activity found within the thymus. Here, we examined adult bone marrow for the presence of a similar population of cells and found that 0.

In vitro growth of bone marrow-resident T cell precursors supported by mast cell growth factor and IL-3.

The growth requirements of bone marrow-resident cells that are able to differentiate along the T cell lineage (pre-T cells) have not been well established. We recently have shown that the T cell-derived lymphokine IL-3 is able to maintain pre-T cells in vitro for at least 2 weeks. However, in our initial studies, we were not able to ascertain whether IL-3 induced pre-T cell growth during culture, or whether IL-3 simply maintained the viability of these progenitors.

Characterization of the progeny of precursor-T (pre-T) cells maintained in vitro by interleukin-3 (IL-3). Development of T-cell function in vivo.

We have recently described a bone marrow culture system which is able to maintain a portion of the precursor-T (pre-T) cell compartment of adult murine marrow in vitro, in the presence of interleukin-3 (IL-3), for at least 2 weeks. However, because growth in IL-3 might also induce the differentiation of the pre-T cells, it is necessary to determine the extent to which the developmental potential of the pre-T cells is altered during their residency in vitro. Previously, we analysed the progeny of cultured pre-T cells and compared their intrathymic development, their appearance in the periphery, and their V beta gene utilization to that of the progeny of fresh pre-T cells.

Characterization of the progeny of pre-T cells maintained in vitro by IL-3: appearance in the periphery and V beta utilization in vivo.

We have recently demonstrated that bone marrow-resident cells, which are able to repopulate the thymus of irradiated recipient mice (pre-T cells), can be maintained in vitro for at least 2 weeks in the presence of exogenous IL-3. Because this marrow culture system can be applied to the study of early T cell differentiation, it is important to ascertain the extent to which in vitro culture of the pre-T cells might alter the T cell progeny which can develop from them. In previous work, we showed that the progeny of cultured pre-T cells appeared to develop in a kinetically normal fashion within the thymus of recipients and that the acquisition of key developmental markers (IL-2R and CD3) was identical in the progeny of fresh and cultured pre-T cells.

Characterization of the progeny of pre-T cells maintained in vitro by IL-3: expression of the IL-2 receptor and CD3 during thymic development.

We have recently described a bone marrow culture system which is able to maintain, for at least 2 weeks, cells which have the capacity to repopulate the thymus of irradiated recipient mice (pre-T cells). Because this culture system depends upon the addition of an exogenous growth factor (IL-3) which may potentially influence the differentiation of the cultured pre-T cells, it is important to determine whether or not the progeny of cultured marrow cells are able to develop within the thymus in a kinetically normal fashion. Here we report the results of an analysis of the progeny of those cultured progenitor cells at 2, 3, and 4 weeks following intrathymic transfer.