Lower general executive function is primarily associated with trait worry: A latent variable analysis of negative thought/affect measures.

This exploratory latent-variable study sought to identify common sources of variance between two multifaceted sets of constructs: executive functions (EFs) and negative thoughts/affect. One-hundred ninety-two college students completed nine tasks representing three types of EFs (inhibition, updating, and shifting) and a set of questionnaires assessing four facets of negative thought/affect (anxiety symptoms, depression symptoms, worry, and rumination). Results indicated that, although the four negative thought/affect constructs were substantially correlated with one another, trait worry was the construct uniquely associated with EFs. Specifically, worry was associated with general EF abilities underlying all three subtypes of EFs (common EF), but was not associated with specific EF abilities (i.e., shifting-specific and updating-specific). These findings highlight the importance of partitioning common and specific variances in both EFs and negative thought/affect when examining the associations between these two research domains. (PsycInfo Database Record (c) 2020 APA, all rights reserved).

Getting ready to use control: Advances in the measurement of young children's use of proactive control.

A key developmental transition in executive function is in the temporal dynamics of its engagement: children shift from reactively calling to mind task-relevant information as needed, to being able to proactively maintain information across time in anticipation of upcoming demands. This transition is important for understanding individual differences and developmental changes in executive function; however, methods targeting its assessment are limited. We tested the possibility that Track-It, a paradigm developed to measure selective sustained attention, also indexes proactive control. In this task children must track a target shape as it moves unpredictably among moving distractors, and identify where it disappears, which may require proactively maintaining information about the target or goal. In two experiments (5-6 year-olds, Ns = 33, 64), children's performance on Track-It predicted proactive control across two established paradigms. These findings suggest Track-It measures proactive control in children. Theoretical possibilities regarding how proactive control and selective sustained attention may be related are also discussed.

No Evidence of the Ego-Depletion Effect across Task Characteristics and Individual Differences: A Pre-Registered Study.

Ego-depletion, a psychological phenomenon in which participants are less able to engage in self-control after prior exertion of self-control, has become widely popular in the scientific community as well as in the media. However, considerable debate exists among researchers as to the nature of the ego-depletion effect, and growing evidence suggests the effect may not be as strong or robust as the extant literature suggests. We examined the robustness of the ego-depletion effect and aimed to maximize the likelihood of detecting the effect by using one of the most widely used depletion tasks (video-viewing attention control task) and by considering task characteristics and individual differences that potentially moderate the effect. We also sought to make our research plan transparent by pre-registering our hypotheses, procedure, and planned analyses prior to data collection. Contrary to the ego-depletion hypothesis, participants in the depletion condition did not perform worse than control participants on the subsequent self-control task, even after considering moderator variables. These findings add to a growing body of evidence suggesting ego-depletion is not a reliable phenomenon, though more research is needed that uses large sample sizes, considers moderator variables, and pre-registers prior to data collection.

Time Isn't of the Essence: Activating Goals Rather Than Imposing Delays Improves Inhibitory Control in Children.

Is it easier to inhibit inappropriate behaviors if one pauses before acting? An important finding for theory and intervention is that children's inhibitory control improves if an adult imposes a delay before they can act. Such findings have suggested that the passage of time allows impulsive urges to dissipate passively. However, in prior studies with imposed delays, children were also reminded about what they should be doing, which may have aided their activation of goal-relevant information. We tested this possibility by independently manipulating delays and task reminders, and measuring 3-year-olds' abilities to inhibit opening boxes in a go/no-go box-search task. Task reminders, but not adult-imposed delays, improved children's response inhibition. However, as in prior work, children who spontaneously delayed their action longer on go trials exhibited better response inhibition on no-go trials. These results pose a challenge to the view that the passage of time plays a causal role, suggest that spontaneous delays index other processes that improve inhibitory control, and highlight the importance of goal activation in developing inhibitory control.

Less-structured time in children's daily lives predicts self-directed executive functioning.

Executive functions (EFs) in childhood predict important life outcomes. Thus, there is great interest in attempts to improve EFs early in life. Many interventions are led by trained adults, including structured training activities in the lab, and less-structured activities implemented in schools. Such programs have yielded gains in children's externally-driven executive functioning, where they are instructed on what goal-directed actions to carry out and when. However, it is less clear how children's experiences relate to their development of self-directed executive functioning, where they must determine on their own what goal-directed actions to carry out and when. We hypothesized that time spent in less-structured activities would give children opportunities to practice self-directed executive functioning, and lead to benefits. To investigate this possibility, we collected information from parents about their 6-7 year-old children's daily, annual, and typical schedules. We categorized children's activities as "structured" or "less-structured" based on categorization schemes from prior studies on child leisure time use. We assessed children's self-directed executive functioning using a well-established verbal fluency task, in which children generate members of a category and can decide on their own when to switch from one subcategory to another. The more time that children spent in less-structured activities, the better their self-directed executive functioning. The opposite was true of structured activities, which predicted poorer self-directed executive functioning. These relationships were robust (holding across increasingly strict classifications of structured and less-structured time) and specific (time use did not predict externally-driven executive functioning). We discuss implications, caveats, and ways in which potential interpretations can be distinguished in future work, to advance an understanding of this fundamental aspect of growing up.

Cdk5rap2 regulates centrosome function and chromosome segregation in neuronal progenitors.

Microcephaly affects approximately 1% of the population and is associated with mental retardation, motor defects and, in some cases, seizures. We analyzed the mechanisms underlying brain size determination in a mouse model of human microcephaly. The Hertwig's anemia (an) mutant shows peripheral blood cytopenias, spontaneous aneuploidy and a predisposition to hematopoietic tumors. We found that the an mutation is a genomic inversion of exon 4 of Cdk5rap2, resulting in an in-frame deletion of exon 4 from the mRNA. The finding that CDK5RAP2 human mutations cause microcephaly prompted further analysis of Cdk5rap2(an/an) mice and we demonstrated that these mice exhibit microcephaly comparable to that of the human disease, resulting from striking neurogenic defects that include proliferative and survival defects in neuronal progenitors. Cdk5rap2(an/an) neuronal precursors exit the cell cycle prematurely and many undergo apoptosis. These defects are associated with impaired mitotic progression coupled with abnormal mitotic spindle pole number and mitotic orientation. Our findings suggest that the reduction in brain size observed in humans with mutations in CDK5RAP2 is associated with impaired centrosomal function and with changes in mitotic spindle orientation during progenitor proliferation.

Chemotactic action of prostaglandin E2 on mouse mast cells acting via the PGE2 receptor 3.

Mast cells are long-lived cells that are principally recognized for their effector function in helminth infections and allergic reactions. These cells are derived from pluripotential hematopoietic stem cells in the bone marrow that give rise to committed mast cell progenitors in the blood and are recruited to tissues, where they mature. Little is known about the chemotactic signals responsible for recruitment of progenitors and localization of mature mast cells. A mouse model was set up to identify possible mast cell progenitor chemoattractants produced during repeated allergen challenge in vivo. After the final challenge, the nasal mucosa was removed to produce conditioned medium, which was tested in chemotaxis assays against 2-wk murine bone marrow-derived c-kit+ mast cells (BMMC). A single peak of chemotactic activity was seen on reverse-phase HPLC with a retention time and electrospray mass spectrum consistent with prostaglandin E2 (PGE2). This lipid was found to be a highly potent chemoattractant for immature (2-wk) and also mature (10-wk) BMMC in vitro. Fluorescently labeled 2-wk c-kit+ BMMC, when injected intravenously, accumulated in response to intradermally injected PGE2. Analysis using TaqMan showed mRNA expression of the PGE2 receptors 3 (EP3) and 4 (EP4) on 2- and 10-wk BMMC. Chemotaxis induced by PGE2 was mimicked by EP3 agonists, blocked by an EP3 receptor antagonist, and partially inhibited by a MAPKK inhibitor. These results show an unexpected function for PGE2 in the chemotaxis of mast cells.

Resolution of airway inflammation and hyperreactivity after in vivo transfer of CD4+CD25+ regulatory T cells is interleukin 10 dependent.

Deficient suppression of T cell responses to allergen by CD4+CD25+ regulatory T cells has been observed in patients with allergic disease. Our current experiments used a mouse model of airway inflammation to examine the suppressive activity of allergen-specific CD4+CD25+ T cells in vivo. Transfer of ovalbumin (OVA) peptide-specific CD4+CD25+ T cells to OVA-sensitized mice reduced airway hyperreactivity (AHR), recruitment of eosinophils, and T helper type 2 (Th2) cytokine expression in the lung after allergen challenge. This suppression was dependent on interleukin (IL) 10 because increased lung expression of IL-10 was detected after transfer of CD4+CD25+ T cells, and regulation was reversed by anti-IL-10R antibody. However, suppression of AHR, airway inflammation, and increased expression of IL-10 were still observed when CD4+CD25+ T cells from IL-10 gene-deficient mice were transferred. Intracellular cytokine staining confirmed that transfer of CD4+CD25+ T cells induced IL-10 expression in recipient CD4+ T cells, but no increase in IL-10 expression was detected in airway macrophages, dendritic cells, or B cells. These data suggest that CD4+CD25+ T cells can suppress the Th2 cell-driven response to allergen in vivo by an IL-10-dependent mechanism but that IL-10 production by the regulatory T cells themselves is not required for such suppression.

High incidence, early onset of histiocytic sarcomas in mice with Hertwig's anemia.

OBJECTIVE: Histiocytic sarcoma (HS) is a rare, rapidly disseminated, usually lethal tumor in humans. Treatment specific for HS has not been developed primarily due to deficiencies of appropriate animal models with high incidence/early onset. Mice with Hertwig's anemia (an/an) provide a potential model. METHODS: Here, we compare HS susceptibility in an/an and unaffected control mice maintained on three genetic backgrounds. As a potential therapeutic measure, genetically marked bone marrow is transplanted between high and low susceptibility animals. RESULTS: HS is detected earlier and the overall incidence is 15-fold higher in WBB6F1(F1)-an/an than in F1-+/?, B6-an/an and -+/? mice. Neither WB-an/an nor their normal WB-+/? littermates present with HS. Liver myelopoiesis and aneuploidy coexist with HS but the former is also rampant (33.7% incidence) in HS-free +/? and an/an mice. Marrow transplantation experiments provide evidence that (1) myelopoiesis is associated with HS and (2) early-onset/high-incidence HS is blocked by using late-onset F1-+/+ mice, as either donor or recipient. CONCLUSIONS: Homozygosity for an on an F1 genetic background is essential for high-incidence/early-onset HS; myelopoiesis and HS coexist; and therapeutic transplantation may be feasible.

Identification of a ferrireductase required for efficient transferrin-dependent iron uptake in erythroid cells.

The reduction of iron is an essential step in the transferrin (Tf) cycle, which is the dominant pathway for iron uptake by red blood cell precursors. A deficiency in iron acquisition by red blood cells leads to hypochromic, microcytic anemia. Using a positional cloning strategy, we identified a gene, six-transmembrane epithelial antigen of the prostate 3 (Steap3), responsible for the iron deficiency anemia in the mouse mutant nm1054. Steap3 is expressed highly in hematopoietic tissues, colocalizes with the Tf cycle endosome and facilitates Tf-bound iron uptake. Steap3 shares homology with F(420)H(2):NADP(+) oxidoreductases found in archaea and bacteria, as well as with the yeast FRE family of metalloreductases. Overexpression of Steap3 stimulates the reduction of iron, and mice lacking Steap3 are deficient in erythroid ferrireductase activity. Taken together, these findings indicate that Steap3 is an endosomal ferrireductase required for efficient Tf-dependent iron uptake in erythroid cells.

nm1054: a spontaneous, recessive, hypochromic, microcytic anemia mutation in the mouse.

Hypochromic, microcytic anemias are typically the result of inadequate hemoglobin production because of globin defects or iron deficiency. Here, we describe the phenotypic characteristics and pathogenesis of a new recessive, hypochromic, microcytic anemia mouse mutant, nm1054. Although the mutation nm1054 is pleiotropic, also resulting in sparse hair, male infertility, failure to thrive, and hydrocephaly, the anemia is the focus of this study. Hematologic analysis reveals a moderately severe, congenital, hypochromic, microcytic anemia, with an elevated red cell zinc protoporphyrin, consistent with functional erythroid iron deficiency. However, serum and tissue iron analyses show that nm1054 animals are not systemically iron deficient. From hematopoietic stem cell transplantation and iron uptake studies in nm1054 reticulocytes, we provide evidence that the nm1054 anemia is due to an intrinsic hematopoietic defect resulting in inefficient transferrin-dependent iron uptake by erythroid precursors. Linkage studies demonstrate that nm1054 maps to a genetic locus not previously implicated in microcytic anemia or iron phenotypes.

Hereditary haemolytic anaemias: unexpected sequelae of mutations in the genes for erythroid membrane skeletal proteins.

Although the haemolytic anaemia may be the primary concern for hereditary spherocytosis and elliptocytosis patients, it is clear that their situation can be compromised by primary and secondary defects in erythroid and non-erythroid systems of the body. All seven of the red cell membrane skeletal proteins discussed in this review are also expressed in non-erythroid tissues, and mutations in their genes have the potential to cause non-erythroid defects. In some instances, such as the protein 4.1R and ANK1 neurological deficits, the diagnosis is clear. In other instances, because of the complex expression patterns involved, the non-erythroid effects may be difficult to assess. An example is the large multidomain, multifunctional band 3 protein. In this case, the location of the mutation can cause defects in one functional domain or isoform and not the other. In other cases, such as the beta-adducin null mutation, other isoforms may partially compensate for the primary deficiency. In such cases, it may be that the effects of the deficit are subtle but could increase under stress or with age. To be completely successful, treatment strategies must address both primary and secondary effects of the anaemia. If gene replacement therapy is to be used, the more that is known about the underlying genetic mechanisms producing the multiple isoforms the better we will be able to design the best replacement gene. The various animal models that are now available should be invaluable in this regard. They continue to contribute to our understanding of both the primary and the secondary effects and their treatment.

Transplanted ER-MP12hi20-58med/hi myeloid progenitors produce resident macrophages from marrow that are therapeutic for lysosomal storage disease.

Lysosomal storage diseases (LSD) respond to bone marrow (BM) transplantation when donor-derived cells deliver needed enzyme. Hypothetically, the ubiquitous resident macrophages (MPhi) are the primary delivery vehicle of therapeutic protein. In mucopolysaccharidosis type VII (MPS VII) mice with LSD, transplanted mature MPhi reduce undegraded glycosaminoglycans (GAG) in the lysosome but are incapable of self-renewal, leading to return of storage after 1 month. We show here that a population of early BM-derived myeloid progenitors devoid of long-term hematopoietic stem cells (LT-HSC) engrafted MPS VII BM, released monocytes into peripheral blood (PBL), and engrafted tissues at known sites of resident MPhi. These primitive Mac-1- cells were sorted from normal whole BM and were defined by ER-MP12hi20-58med/hi labeling. Lysosomal storage was reduced in liver, spleen, thymus, heart, kidney, and bone. Cells persisted for 3 months, suggesting self-renewal capacity or a long half-life. Cells sorted from BM by ER-MP12-20hi marker expression (which are maturer myeloid cells that express Mac-1) engrafted tissues instead of BM and quantitatively repopulated less than cells derived from the ER-MP12hi20-58med/hi population. Also, reduction of lysosomal storage was variable and generally less when compared to that following transplantation of immature ER-MP12hi20-58med/hi cells. We conclude that primitive myeloid progenitors are more therapeutic for LSD than mature myeloid cells due to their greater longevity and increased capacity to seed tissues. The ability of cells derived from these primitive precursors to seed deep within tissues make them excellent candidates for both cellular therapy and gene transfer techniques to cure a wide range of metabolic diseases.

Increased erythrocyte adhesion in mice and humans with hereditary spherocytosis and hereditary elliptocytosis.

Mice with disruptions of the red blood cell (RBC) cytoskeleton provide severe hemolytic anemia models in which to study multiorgan thrombosis and infarction. The incidence of cerebral infarction ranges from 70% to 100% in mice with alpha-spectrin deficiency. To determine whether mutant RBCs abnormally bind adhesive vascular components, we measured adhesion of mouse and human RBCs to immobilized human thrombospondin (TSP) and laminin (LM) under controlled flow conditions. Mutant RBCs had at least 10-fold higher adhesion to TSP compared with normal RBCs (P <.006). Mutant relative to unaffected RBC adhesion to LM was significantly (P <.01) increased as well. Treatment of RBCs with the anionic polysaccharide dextran sulfate inhibited mutant RBC adhesion to TSP (P <.001). Treatment of RBCs with antibodies to CD47 or the CD47-binding TSP peptide 4N1K did not inhibit TSP adhesion of RBCs. Previously, we have shown that infarcts in alpha-spectrin-deficient sph/sph mice become histologically evident beginning at 6 weeks of age. TSP adhesion of RBCs from 3- to 4- and 6- to 8-week-old sph/sph mice was significantly higher than RBCs from adult mice (> 12 weeks old; P <.005). While the mechanism of infarction in these mice is unknown, we speculate that changes in RBC adhesive characteristics contribute to this pathology.

Normoblastosis, a murine model for ankyrin-deficient hemolytic anemia, is caused by a hypomorphic mutation in the erythroid ankyrin gene Ank1.

Ankyrin deficiency is one of the most common causes of hereditary spherocytosis in humans. A spontaneous mutation, normoblastosis (Ank1nb), discovered in 1969 in a mouse stock maintained at the Jackson Laboratory, provides an important animal model for these human ankyrin-deficient anemias. Study of this model has led to the finding of multiple isoforms of Ank1 as well as Ank1nb-related pathology in nonerythroid tissues. To enhance the usefulness of this model, we have identified the Ank1nb mutation as the deletion of a guanosine residue in exon 36 of the erythroid ankyrin gene (Ank1). This results in a frame shift that introduces a stop 13 codons downstream and predicts a 157 kDa nb-ankyrin lacking the regulatory domain but including intact membrane- and spectrin-binding domains. By epitope scanning on immunoblots, we show that a previously reported protein (p150) found in nb reticulocytes is the predicted nb-ankyrin. Existing evidence indicates that this protein is functional, making the normoblastosis mutation a hypomorph rather than a null as originally thought. The nb-ankyrin provides an explanation for the milder phenotype displayed by nb/nb animals relative to the murine spectrin-deficient anemias, spherocytosis (Spna1(sph), Spna1(sph-1J), Spna1(sph-2BC), Spna1(sph-DEM)) and jaundiced (Spnb1(ja)), and suggests that truncated ankyrins could be useful in gene replacement therapy.

Donor cell expansion is delayed following nonablative in utero transplantation to treat murine mucopolysaccharidosis type VII.

To block development of progressive childhood diseases, in utero transplantation (IUTx) requires immediate and significant donor peripheral blood (PB) cell amplification. To date, negligible and nontherapeutic donor PB cell levels have been observed postnatally, except in patients with immunodeficiency diseases. Donor cell fate in utero still is not clear. Ease of identifying and quantifying beta-glucuronidase (GUSB)-expressing donor cells in GUSB-null mucopolysaccharidosis type VII (MPSVII) mouse recipients allowed us to evaluate temporal donor cell engraftment and amplification post-IUTx. Like humans, MPSVII mice are unable to catabolize lysosomal glycosaminoglycans and progressively develop severe storage disease unless they are treated early in life.IUTx recipients were nonablated MPSVII fetuses and genetically stem cell-deficient, and hence myeloablated, W(41)/W(41) MPSVII fetuses. Donor GUSB+ cells were identified and counted in histochemical tissue sections. Quantitative results were confirmed by flow cytometry, enzyme analysis, and histopathology. Whereas GUSB+ cells engraft in most tissues in utero, significant amplification does not occur until the first postnatal week in the nonablated MPSVII hosts. In contrast, genetically myeloablated MPSVII recipients display widely distributed donor cell replacement accompanied by extensive amplification in utero. In both models, storage is alleviated in adult tissues with significant donor cell repopulation. To become therapeutic, IUTx must overcome the limitations of donor cell expansion in the highly competitive fetal environment. Fortunately, nonablative mechanisms to amplify cells in utero are coming on line.

Successful allogeneic neonatal bone marrow transplantation devoid of myeloablation requires costimulatory blockade.

A significant number of nonmalignant, progressive childhood disorders respond to bone marrow transplantation (BMT). Toxic myeloablative pretreatment regimens, graft failure, and graft-vs-host disease complicate the utility of BMT for neonatal treatment. We recently demonstrated high-dose BMT in neonatal animals enables chimeric engraftment without toxic myeloablation. Reagents that block T cell costimulation (anti-CD40L mAb and/or CTLA-4Ig) establish tolerant allogeneic engraftment in adult recipients. Donor lymphocyte infusion (DLI) re-establishes failing grafts and treats malignant relapse via a graft-vs-leukemia response. In this study, we tested the hypothesis that combining these approaches would allow tolerant allogeneic engraftment devoid of myeloablation in neonatal normal and mutant mice with lysosomal storage disease. Tolerant chimeric allogeneic engraftment was achieved before DLI only in the presence of both anti-CD40L mAb and CTLA-4Ig. DLI amplified allografts to full donor engraftment long-term. DLI-treated mice either maintained long-term tolerance or developed late-onset chronic graft-vs-host disease. This combinatorial approach provides a nontoxic method to establish tolerant allogeneic engraftment for treatment of progressive childhood diseases.

Mutations in the murine erythroid alpha-spectrin gene alter spectrin mRNA and protein levels and spectrin incorporation into the red blood cell membrane skeleton.

Tetramers of alpha- and beta-spectrin heterodimers, linked by intermediary proteins to transmembrane proteins, stabilize the red blood cell cytoskeleton. Deficiencies of either alpha- or beta-spectrin can result in severe hereditary spherocytosis (HS) or hereditary elliptocytosis (HE) in mice and humans. Four mouse mutations, sph, sph(Dem), sph(2BC), and sph(J), affect the erythroid alpha-spectrin gene, Spna1, on chromosome 1 and cause severe HS and HE. Here we describe the molecular alterations in alpha-spectrin and their consequences in sph(2BC)/sph(2BC) and sph(J)/sph(J) erythrocytes. A splicing mutation, sph(2BC) initiates the skipping of exon 41 and premature protein termination before the site required for dimerization of alpha-spectrin with beta-spectrin. A nonsense mutation in exon 52, sph(J) eliminates the COOH-terminal 13 amino acids. Both defects result in instability of the red cell membrane and loss of membrane surface area. In sph(2BC)/sph(2BC), barely perceptible levels of messenger RNA and consequent decreased synthesis of alpha-spectrin protein are primarily responsible for the resultant hemolysis. By contrast, sph(J)/sph(J) mice synthesize the truncated alpha-spectrin in which the 13-terminal amino acids are deleted at higher levels than normal, but they cannot retain this mutant protein in the cytoskeleton. The sph(J) deletion is near the 4.1/actin-binding region at the junctional complex providing new evidence that this 13-amino acid segment at the COOH-terminus of alpha-spectrin is crucial to the stability of the junctional complex.

Delayed administration of carrier marrow can decrease competition on donor stem cells during engraftment and maintain radioprotection of the host.

OBJECTIVE: The goal of this study was to determine if competitive pressure was placed on hematopoietic stem cells (HSC) by a coinjected "carrier" population that maintains short-term survival of the host. Our hypothesis was that delayed introduction of "carrier" cells would increase engraftment of donor HSC. MATERIALS AND METHODS: Competitive repopulation assays were performed using genetically distinguishable whole bone marrow (BM) populations. Donor BM was competed against carrier BM that was coinjected or injected 3 or 4 days later. Radioprotection with delayed carrier injection also was examined by performing the initial HSC transplantation with Hoechst(lo) side population (SP) cells. SP HSC incubated with cytokines and BM stroma to stimulate cell cycling before transplantation also were tested using coinjection or delayed carrier administration. RESULTS: Delayed introduction of carrier whole BM increased peripheral expansion of donor whole BM, freshly isolated HSC, or cytokine-stimulated HSC compared to coinjection with carrier cells. A 3-day delay in carrier administration maintained radioprotection in 100% of lethally irradiated recipients of highly enriched HSC, whereas a 4-day delay did not rescue these recipients from death. When recipients are rescued, recovering host marrow can compete against donor HSC unless sufficient donor cells are injected. CONCLUSIONS: Delayed introduction of carrier BM significantly increases donor HSC engraftment and peripheral expansion by reducing competition in the host. Competition by a coinjected carrier cell population or recovery of host marrow significantly reduces the therapeutic efficacy of normal or in vitro manipulated donor HSC.