Monica S. Thakar

Egg Size Plasticity in a Seed Beetle: An Adaptive Maternal Effect

In the seed beetle, Stator limbatus, the fitness consequences of egg size vary substantially among host plants. There is intense selection for laying large eggs when larvae will develop on seeds of Cercidium floridum (caused by high mortality penetrating the seed coat) but selection for laying small eggs when larvae will develop on seeds of Acacia greggii (caused by very low mortality penetrating the seed coat and an egg size/egg number trade-off). We test the hypothesis that host-associated variation in egg size within populations of S. limbatus represents an adaptive maternal effect in which females adjust egg size in response to host species. In laboratory experiments, S. limbatus females laid significantly larger and fewer eggs on C. floridum than on A. greggii. When switched between hosts, females readjusted egg size, producing progressively larger eggs on C. floridum and smaller eggs on A. greggii. When conditioned to lay either small eggs (on A. greggii) or large eggs (on C. floridum), and then forced to lay on C. floridum, females conditioned on C. floridum laid eggs that had substantially higher survivorship than eggs laid by females conditioned on A. greggii. These experiments demonstrate that egg size is an adaptively plastic character in S. limbatus.

IL-22 from conventional NK cells is epithelial regenerative and inflammation protective during influenza infection

Influenza infection primarily targets the upper respiratory system, leading to a severe destruction of the epithelial cell layer. The role of immune cells in the regeneration of tracheal and bronchial epithelial cells is not well defined. Here, we investigated the production of pro-constructive cytokine, Interleukin-22 (IL-22), in the bronchoalveolar lavage (BAL), trachea, lung tissue, and spleen during influenza infection. We found that conventional natural killer (NK) cells (NCR1+NK1.1+CD127−RORγt−) were the predominant IL-22-producers in the BAL, trachea, and lung tissues. Tracheal epithelial cells constitutively expressed high levels of IL-22R and underwent active proliferation in response to IL-22 in the wild-type mice. Infection of IL-22−/− mice with influenza virus resulted in a severe impairment in the regeneration of tracheal epithelial cells. In addition, IL-22−/− mice continued to lose body weight even after 10 days post infection without any recovery. Tracheal epithelial cell proliferation was significantly reduced in IL-22−/− mice during influenza infection. Adoptive transfer of IL-22-sufficient but not IL-22-deficient NK cells into IL-22−/− mice restored the tracheal/bronchial epithelial cell regeneration and conferred protection against inflammation. Our findings strongly suggest that conventional NK cells have evolved to both kill virus-infected cells and also to provide vital cytokines for tissue regeneration.

Signaling by Fyn-ADAP via the Carma1-Bcl-10-MAP3K7 signalosome exclusively regulates inflammatory cytokine production in NK cells.

Inflammation is a critical component of the immune response. However, acute or chronic inflammation can be highly destructive. Uncontrolled inflammation forms the basis for allergy, asthma and various autoimmune disorders. Here we identified a signaling pathway that was exclusively responsible for the production of inflammatory cytokines but not for cytotoxicity. Recognition of tumor cells expressing the NK cell–activatory ligands H60 or CD137L by mouse natural killer (NK) cells led to efficient cytotoxicity and the production of inflammatory cytokines. Both of those effector functions required the kinases Lck, Fyn and PI(3)K (subunits p85α and p110δ) and the signaling protein PLC-γ2. However, a complex of Fyn and the adaptor ADAP exclusively regulated the production of inflammatory cytokines but not cytotoxicity in NK cells. That unique function of ADAP required a Carma1–Bcl-10–MAP3K7 signaling axis. Our results have identified molecules that can be targeted to regulate inflammation without compromising NK cell cytotoxicity.

Allogeneic Hematopoietic Cell Transplantation for Fanconi Anemia in Patients With Pretransplantation Cytogenetic Abnormalities, Myelodysplastic Syndrome, or Acute Leukemia

PURPOSE Allogeneic hematopoietic cell transplantation (HCT) can cure bone marrow failure in patients with Fanconi anemia (FA). Data on outcomes in patients with pretransplantation cytogenetic abnormalities, myelodysplastic syndrome (MDS), or acute leukemia have not been separately analyzed. PATIENTS AND METHODS We analyzed data on 113 patients with FA with cytogenetic abnormalities (n = 54), MDS (n = 45), or acute leukemia (n = 14) who were reported to the Center for International Blood and Marrow Transplant Research from 1985 to 2007. RESULTS Neutrophil recovery occurred in 78% and 85% of patients at days 28 and 100, respectively. Day 100 cumulative incidences of acute graft-versus-host disease grades B to D and C to D were 26% (95% CI, 19% to 35%) and 12% (95% CI, 7% to 19%), respectively. Survival probabilities at 1, 3, and 5 years were 64% (95% CI, 55% to 73%), 58% (95% CI, 48% to 67%), and 55% (95% CI, 45% to 64%), respectively. In univariate analysis, younger age was associated with superior 5-year survival (≤ v > 14 years: 69% [95% CI, 57% to 80%] v 39% [95% CI, 26% to 53%], respectively; P = .001). In transplantations from HLA-matched related donors (n = 82), younger patients (≤ v > 14 years: 78% [95% CI, 64% to 90%] v 34% [95% CI, 20% to 50%], respectively; P < .001) and patients with cytogenetic abnormalities only versus MDS/acute leukemia (67% [95% CI, 52% to 81%] v 43% [95% CI, 27% to 59%], respectively; P = .03) had superior 5-year survival. CONCLUSION Our analysis indicates that long-term survival for patients with FA with cytogenetic abnormalities, MDS, or acute leukemia is achievable. Younger patients and recipients of HLA-matched related donor transplantations who have cytogenetic abnormalities only have the best survival.

Biodistributions, Myelosuppression, and Toxicities in Mice Treated with an Anti-CD45 Antibody Labeled with the α-Emitting Radionuclides Bismuth-213 or Astatine-211

We previously investigated the potential of targeted radiotherapy using a bismuth-213 ((213)Bi)-labeled anti-CD45 antibody to replace total body irradiation as conditioning for hematopoietic cell transplantation in a canine model. Although this approach allowed sustained marrow engraftment, limited availability, high cost, and short half-life of (213)Bi induced us to investigate an alternative alpha-emitting radionuclide, astatine-211 ((211)At), for the same application. Biodistribution and toxicity studies were conducted with conjugates of the anti-murine CD45 antibody 30F11 with either (213)Bi or (211)At. Mice were injected with 2 to 50 muCi on 10 microg or 20 muCi on 2 or 40 microg of 30F11 conjugate. Biodistribution studies showed that the spleen contained the highest concentration of radioactivity, ranging from 167 +/- 23% to 417 +/- 109% injected dose/gram (% ID/g) after injection of the (211)At conjugate and 45 +/- 9% to 166 +/- 11% ID/g after injection of the (213)Bi conjugate. The higher concentrations observed for (211)At-labeled 30F11 were due to its longer half-life, which permitted better localization of isotope to the spleen before decay. (211)At was more effective at producing myelosuppression for the same quantity of injected radioactivity. All mice injected with 20 or 50 muCi (211)At, but none with the same quantities of (213)Bi, had lethal myeloablation. Severe reversible acute hepatic toxicity occurred with 50 muCi (213)Bi, but not with lower doses of (213)Bi or with any dose of (211)At. No renal toxicity occurred with either radionuclide. The data suggest that smaller quantities of (211)At-labeled anti-CD45 antibody are sufficient to achieve myelosuppression and myeloablation with less nonhematologic toxicity compared with (213)Bi-labeled antibody.

Clinical Relevance of Natural Killer Cells Following Hematopoietic Stem Cell Transplantation

Natural killer (NK) cells are one of the first cells to recover following allogeneic hematopoietic stem cell transplantation (HSCT), and are believed to play an important role in facilitating engraftment or preventing post-transplant infection and tumor recurrence. Recent studies have provided novel insights into the mechanisms by which NK cells mediate these highly clinically relevant immunological functions. In particular, the ability of NK cells to reduce the risk of graft versus host disease (GVHD) and increase the graft versus leukemia effect (GVL) in the setting of human leukocyte antigen (HLA)-haploidentical HSCT highlights their clinical potentials. NK cells also mediate anti-viral protection, in particular against cytomegalovirus (CMV), an infection that causes significant morbidity and mortality following transplant. Another crucial function of NK cells is providing protection against bacterial infections at the mucosal barriers. NK cells achieve this by promoting anti-microbial defenses and regeneration of epithelial cells. These recent exciting findings provide a strong basis for the formulation of novel NK cell-based immunotherapies. In this review, we summarize the recent advances related to the mechanisms, functions, and future clinical prospects of NK cells that can impact post-transplant outcomes.

IL-22: An Evolutionary Missing-Link Authenticating the Role of the Immune System in Tissue Regeneration

Tissue regeneration is a critical component of organ maintenance. The ability of lymphocytes to kill pathogen-infected cells has been well-studied. However, the necessity for lymphocytes to participate in reconstruction of destroyed tissues has not been explored until recently. Interleukin (IL)-22, a newly defined cytokine exclusively produced by subsets of lymphocytes, provides the strongest proof yet for the tissue regenerative potentials of the immune system. IL-22 plays an obligatory role in epithelial homeostasis in the gut, liver and lung. The receptor for IL-22 (IL-22R1 and IL-10R2) is predominantly expressed by epithelial cells. While the pro-inflammatory effect is questioned, the pro-constructive potential of IL-22 is well established. It is evident from the response to IL-22, that epithelial cells not only produce anti-microbial peptides but also actively proliferate. Aryl hydrocarbon receptor (AhR) and retinoic acid-related orphan receptor (RORγt) transcription factor are required for IL-22 generation from Lymphoid Tissue inducer cells LTi, Th22 and NK-like cells. However, IL-22 production from conventional NK cells is independent of AhR and RORγt. In this review, we present a case for a paradigm shift in how we define the function of the immune system. This would include tissue regeneration as a legitimate immune function.

IQGAP1: A Regulator of Intracellular Spacetime Relativity

Activating and inhibiting receptors of lymphocytes collect valuable information about their mikròs kósmos. This information is essential to initiate or to turn off complex signaling pathways. Irrespective of these advances, our knowledge on how these intracellular activation cascades are coordinated in a spatiotemporal manner is far from complete. Among multiple explanations, the scaffolding proteins have emerged as a critical piece of this evolutionary tangram. Among many, IQGAP1 is one of the essential scaffolding proteins that coordinate multiple signaling pathways. IQGAP1 possesses multiple protein interaction motifs to achieve its scaffolding functions. Using these domains, IQGAP1 has been shown to regulate a number of essential cellular events. This includes actin polymerization, tubulin multimerization, microtubule organizing center formation, calcium/calmodulin signaling, Pak/Raf/Mek1/2-mediated Erk1/2 activation, formation of maestrosome, E-cadherin, and CD44-mediated signaling and glycogen synthase kinase-3/adenomatous polyposis coli-mediated β-catenin activation. In this review, we summarize the recent developments and exciting new findings of cellular functions of IQGAP1.

IQGAP1: insights into the function of a molecular puppeteer.

The intracellular spatiotemporal organization of signaling events is critical for normal cellular function. In response to environmental stimuli, cells utilize highly organized signaling pathways that are subject to multiple layers of regulation. However, the molecular mechanisms that coordinate these complex processes remain an enigma. Scaffolding proteins (scaffolins) have emerged as critical regulators of signaling pathways, many of which have well-described functions in immune cells. IQGAP1, a highly conserved cytoplasmic scaffold protein, is able to curb, compartmentalize, and coordinate multiple signaling pathways in a variety of cell types. IQGAP1 plays a central role in cell-cell interaction, cell adherence, and movement via actin/tubulin-based cytoskeletal reorganization. Evidence also implicates IQGAP1 as an essential regulator of the MAPK and Wnt/β-catenin signaling pathways. Here, we summarize the recent advances on the cellular and molecular biology of IQGAP1. We also describe how this pleiotropic scaffolin acts as a true molecular puppeteer, and highlight the significance of future research regarding the role of IQGAP1 in immune cells.

ASH evidence-based guidelines: is there a role for second allogeneic transplant after relapse?

A 35-year-old male with a FLT3(+) AML underwent allogeneic peripheral blood stem cell transplant using a myeloablative non-total body irradiation (TBI) conditioning regimen from his HLA-matched sibling donor. Following transplantation, he developed grade II acute graft-versus-host disease (GVHD) that resolved with increasing immunosuppression. The medications were subsequently discontinued, and he did not develop any evidence of chronic GVHD. Eighteen months after transplant, while off all immunosuppression, he developed fatigue and a blood count showed circulating blasts consistent with relapse of his disease. Among the various therapeutic questions is whether there is a role for a second allogeneic transplant to treat his disease and if so, at what time, with what conditioning, and with which type of donor.