25 research outputs found
The spectrum of involuntary vocalizations in humans: A video atlas
In clinical practice, involuntary vocalizing behaviors are typically associated with Tourette syndrome and other tic disorders. However, they may also be encountered throughout the entire tenor of neuropsychiatry, movement disorders, and neurodevelopmental syndromes. Importantly, involuntary vocalizing behaviors may often constitute a predominant clinical sign, and, therefore, their early recognition and appropriate classification are necessary to guide diagnosis and treatment. Clinical literature and video-documented cases on the topic are surprisingly scarce. Here, we pooled data from 5 expert centers of movement disorders, with instructive video material to cover the entire range of involuntary vocalizations in humans. Medical literature was also reviewed to document the range of possible etiologies associated with the different types of vocalizing behaviors and to explore treatment options. We propose a phenomenological classification of involuntary vocalizations within different categorical domains, including (1) tics and tic-like vocalizations, (2) vocalizations as part of stereotypies, (3) vocalizations as part of dystonia or chorea, (4) continuous vocalizing behaviors such as groaning or grunting, (5) pathological laughter and crying, (6) vocalizations resembling physiological reflexes, and (7) other vocalizations, for example, those associated with exaggerated startle responses, as part of epilepsy and sleep-related phenomena. We provide comprehensive lists of their associated etiologies, including neurodevelopmental, neurodegenerative, neuroimmunological, and structural causes and clinical clues. We then expand on the pathophysiology of the different vocalizing behaviors and comment on available treatment options. Finally, we present an algorithmic approach that covers the wide range of involuntary vocalizations in humans, with the ultimate goal of improving diagnostic accuracy and guiding appropriate treatment
A20-Deficient Mast Cells Exacerbate Inflammatory Responses In Vivo
Mast cells are implicated in the pathogenesis of inflammatory and autoimmune diseases. However, this notion based on studies in mast cell-deficient mice is controversial. We therefore established an in vivo model for hyperactive mast cells by specifically ablating the NF-kappa B negative feedback regulator A20. While A20 deficiency did not affect mast cell degranulation, it resulted in amplified pro-inflammatory responses downstream of IgE/Fc epsilon RI, TLRs, IL-1R, and IL-33R. As a consequence house dust mite- and IL-33-driven lung inflammation, late phase cutaneous anaphylaxis, and collagen-induced arthritis were aggravated, in contrast to experimental autoimmune encephalomyelitis and immediate anaphylaxis. Our results provide in vivo evidence that hyperactive mast cells can exacerbate inflammatory disorders and define diseases that might benefit from therapeutic intervention with mast cell function
Development of immunoglobulin k-chain-positive B cells, but not editing of immunoglobulin j-chain, depends on NF-jB signals A R T I C L E S
By genetically ablating IjB kinase (IKK)-mediated activation of the transcription factor NF-jB in the B cell lineage and by analyzing a mouse mutant in which immunoglobulin k-chain-positive B cells are generated in the absence of rearrangements in the locus encoding immunoglobulin j-chain, we define here two distinct, consecutive phases of early B cell development that differ in their dependence on IKK-mediated NF-jB signaling. During the first phase, in which NF-jB signaling is dispensable, predominantly j-chain-positive B cells are generated, which undergo efficient receptor editing. In the second phase, predominantly k-chain-positive B cells are generated whose development is ontogenetically timed to occur after rearrangements of the locus encoding j-chain. This second phase of development is dependent on NF-jB signals, which can be substituted by transgenic expression of the prosurvival factor Bcl-2. It is well established that the NF-kB family of transcription factors is critical to B cell physiology 1,2 . Activation of NF-kB by the alternative pathway, which is mediated by NF-kB-inducing kinase and the inhibitor of NF-kB kinase 1 (IKK1; A001170) downstream of interactions between B cell-activation factor of the tumor necrosis factor family (BAFF) and BAFF-receptor, is essential for mature B cell survival 3 . In addition, mature B cells depend on continuous signaling through the canonical NF-kB pathway, in which activation of the IKK complex, which consists of IKK1, IKK2 (A001172) and NF-kB essential modulator (NEMO; A001628), is central 1 . In contrast, the function of NF-kB signaling in B cell development remains unclear 1 and is indeed highly controversial. Initial experiments addressed that issue in mice lacking one or two individual NF-kB transcription factors. Whereas the generation of mature B cells is generally impaired in most of these mutant mice, the effects are often mild in B cell progenitors and it has remained unresolved whether these defects are B cell autonomous 2 . Notably, genetic ablation of the BAFF-receptor or IKK1 seems not to affect B cell development in the bone marrow, at least in terms of proportions of cells at the various developmental stages 1,3 ; the same is true for ablation of the canonical pathway by knockout of IKK2 or NEMO specifically in B cell
TCR signaling is not required for the steady state homeostasis of mature NKT cells.
<p>(A) Percentages of TCRĪ²ā cells of the depicted T cell subsets 2 wk after poly(I:C) injection into <i>Mx-Cre CĪ±<sup>F/F</sup></i> mice. Bars show means and SD (error bars) of 3ā5 mice. (B) Surface TCRĪ² expression of splenic CD4+ NKT cells (NK1.1+ CD5+ CD62L<sup>low</sup>) 2 wk after poly(I:C) injection. Numbers indicate means Ā± SD of three independent experiments with altogether five mice per genotype. (C, D) Total cell counts of splenic naĆÆve conventional CD4+ T cells (CD5+ CD44<sup>low</sup> NK1.1ā; C) or of memory/effector-like CD4+ T cells (CD5+ CD44<sup>high</sup> NK1.1ā; D) from 26 control <i>CĪ±<sup>F/F</sup></i> (CTR, TCR+) animals as well as from 24 <i>Mx-Cre CĪ±<sup>F/F</sup></i> animals, all after poly(I:C) injection (TCR+, TCRā). (E) Splenic CD4+ NKT cell numbers from in total 32 control <i>CĪ±<sup>F/F</sup></i> animals (CTR, TCR+) as well as TCRĪ²+ and TCRĪ²ā CD4+ NKT cell numbers from in total 27 <i>Mx-Cre CĪ±<sup>F/F</sup></i> animals, at the indicated time after poly(I:C) injection. (CāE) Half-lives were calculated with GraphPad Prism software using nonlinear regression, one-phase decay analysis. (F) BrdU was administered for 4 wk via the drinking water, starting 2 wk after poly(I:C) injection. Directly afterwards, animals were sacrificed and BrdU incorporation was measured by flow cytometry. Representative blots of 2 <i>CĪ±<sup>F/F</sup></i> and 4 <i>Mx-Cre CĪ±<sup>F/F</sup></i> mice are shown. (G) Bar chart showing proportion of cells that incorporated BrdU of the indicated T cell subtypes. Bars show means calculated from 2 <i>CĪ±<sup>F/F</sup></i> and means and SD (error bars) 4 <i>Mx-Cre CĪ±<sup>F/F</sup></i> mice. *** <i>p</i><0.001; * <i>p</i><0.05; ns, not significant; one-way ANOVA.</p
TCR-signals are not required for the innate activation of NKT cells.
<p>(A) Intracellular Egr2 expression of the depicted splenic T cells, 90 min after PBS or Ī±GalCer injection, or 6 h after LPS injection. Plots are representative for at least three independent experiments. (B) Intracellular IFN-Ī³ expression of the depicted cells stained directly ex vivo without addition of brefeldin or monensin. Splenic cells were isolated 90 min after PBS or Ī±GalCer injection, or 6 h after LPS injection. Plots are representative for at least three independent experiments.</p
The VĪ±14i-TCR knock-in mouse produces large numbers of correctly selected, bona fide NKT cells.
<p>(A) Schematic representation of the knock-in transgene. The <i>VĪ±14</i> promoter, <i>loxP</i> (triangle)-flanked STOP cassette, and pre-rearranged <i>VĪ±14i</i> (VĪ±14-JĪ±18, red square) sequences were inserted 3ā² of <i>JĪ±1</i> and 5ā² of the first <i>CĪ±</i> exon (coding exons are highlighted in blue); 4pAā=ā4 SV40 polyadenylation sites. AH, arms of homology. <i>EĪ±</i>, enhancer (black oval). (B) Representative proportions of NKT cells and conventional T cells of total lymphocytes in thymus and spleen. Numbers indicate mean percentages Ā± SD of at least seven age-matched mice per genotype. (C) Representative proportions of splenic CD4+, CD8+, and DN (CD4ā CD8ā) NKT cells. Numbers indicate mean percentages Ā± SD of seven mice per genotype. (D) The VĪ² repertoires of splenic NKT cells of the indicated genotypes. Bars indicate means and error bars SD of three independent experiments. (E) Representative flow cytometric analysis of the indicated cell-surface proteins on conventional CD4+ T cells and NKT cells. (F) Intracellular flow cytometric staining of PLZF, GATA-3, ROR-Ī³t, and Th-POK in the depicted NKT cells. Numbers indicate means of the median fluorescence intensities (MFIs), normalized to CD4+ tetramerā T cells of CTR animals, or percentage of ROR-Ī³t+ cells among DN NKT cells; calculated from three animals per genotype. Histograms are representative of three independent experiments with eight mice in total. Throughout the figure, NKT cells were gated as tetramer+ TCRĪ²+, conventional (conv) T cells as tetramerā TCRĪ²+; CTR, <i>CD4-Cre</i> or <i>VĪ±14i<sup>StopF</sup>/wt</i>.</p
Signs of sterile inflammation in mice harboring TCR-switched T cells.
<p>T-cell-deficient mice were reconstituted with NKT-cell-depleted splenocytes of the indicated genotypes. Spleen weight (A), absolute splenic cell numbers (BāE, G, H), and serum TNF levels (F) of 3ā28 mice per genotype were determined 8 wk after poly(I:C) administration where indicated. Bars indicate medians. Red points show six animals with near absence of B cells and dendritic cells. (B) Total splenocytes; (C) Macrophages/monocytes (Mac1+ Gr1<sup>int</sup> SiglecFā); (D) Neutrophils (Mac1+ Gr1<sup>high</sup> SiglecFā); (E) Erythroblasts (Ter119+); (G) B cells (B220+ TCRĪ²ā); (H) Dendritic cells (CD11c+). *** <i>p</i><0.001; ** <i>p</i><0.01; * <i>p</i><0.05, one-way ANOVA.</p
The maintenance of NKT lineage identity does not depend on TCR-signals.
<p><i>CĪ±<sup>F/F</sup></i> and <i>Mx-Cre CĪ±<sup>F/F</sup></i> mice were injected with poly(I:C) and analyzed 6 wk later. (A, B) Intracellular expression of Egr2 (A) and PLZF (B) in T cells from the depicted mice. Plots are representative for at least three independent experiments. (C) Flow cytometric analysis of NK1.1 expression on splenic naĆÆve (CD62L<sup>high</sup> CD5+), memory/effector-like (CD62L<sup>low</sup> CD5+) CD4+ T cells, and CD4+ NKT cells (NK1.1+ CD5+ CD62L<sup>low</sup>), with or without TCR expression. Median fluorescence intensity, normalized to NK1.1 expression of NK cells (NK1.1+ TCRĪ²ā CD5ā). Bars indicate medians. *** <i>p</i><0.001; ** <i>p</i><0.01; * <i>p</i><0.05; ns, not significant; one-way ANOVA. (D) Flow cytometric expression analysis of extra- and intracellular markers of splenic T cells. Median fluorescence intensities of at least four mice per analyzed protein were normalized to the expression on/in conventional CD4+ T cells (tetramerā TCRĪ²+) to account for interexperimental variations. Expression of NK1.1, CD122, FasL, and T-bet were normalized to NK cells (NK1.1+ TCRĪ²ā CD5ā) and then set to 1 for naĆÆve T cells. Data are shown as heatmap, calculated by Perseus software. Blue letters, significantly reduced on splenic TCRā CD4+ NKT cells in comparison to TCR+ CD4+ NKT cells from <i>CĪ±<sup>F/F</sup></i> and <i>Mx-Cre CĪ±<sup>F/F</sup></i> mice; analyzed by one-way ANOVA.</p
NKT cell overproduction affects their maturation and NK cell homeostasis.
<p>(A) Intracellular IL-4, IL-13, IFN-Ī³, and TNF expression of splenic CD4+ NKT cells isolated from the depicted animals 90 min after Ī±GalCer injection. Cells were stained directly ex vivo without addition of brefeldin or monensin. Black numbers indicate mean percentages Ā± SD, and red numbers indicate mean total NKT cell counts expressing the respective cytokine. Data are from three animals per genotype; FSC, forward scatter. (B) Representative proportions of stage 1 (CD44<sup>low</sup> NK1.1<sup>low</sup>), stage 2 (CD44<sup>high</sup> NK1.1<sup>low</sup>), and stage 3 (CD44<sup>high</sup> NK1.1<sup>high</sup>) thymic and splenic NKT cells. Numbers indicate mean percentages Ā± SD of 10 mice per genotype. (C) Flow cytometric analysis of the depicted markers on thymic and splenic, transgenic, and control NKT cells. Bars indicate means and error bars SD calculated from 4ā7 mice. (D) Extracellular and intracellular flow cytometric stainings of CD69 and T-bet in the depicted NKT cell subpopulations. Numbers in representative histogram indicate percentage of CD69<sup>high</sup> or T-bet+ cells among the indicated NKT cells calculated from eight animals per genotype (CD69) or three animals per genotype (T-bet). Histograms are representative of at least three independent experiments with each at least seven mice in total. (E) Absolute splenic NK cell numbers (NK1.1+ TCRĪ²ā tetramerā) of age-matched 6ā12-wk-old animals (7ā16 per genotype). Bars indicate medians. *** <i>p</i><0.001; ns, not significant; one-way ANOVA. Throughout the figure, NKT cells were gated as tetramer+ TCRĪ²+, conventional (conv) T cells as tetramerā TCRĪ²+; CTR, <i>CD4-Cre</i> or <i>VĪ±14i<sup>StopF</sup>/wt</i>.</p
TCR switch on mature conventional T cells.
<p>(A) Genetic set-up of the TCR switch experiment. In <i>Mx-Cre CĪ±<sup>F</sup>/VĪ±14i<sup>StopF</sup></i> mice, the endogenous TCRĪ±-chains (VĪ±(x)JĪ±(y)) are exclusively expressed from the <i>CĪ±<sup>F</sup></i> allele. Cre-mediated recombination leads to termination of expression from the <i>CĪ±<sup>F</sup></i> allele, and simultaneous start of expression of the VĪ±14i-TCRĪ±-chain from the <i>VĪ±14i<sup>StopF</sup></i> allele. (B) T-cell-deficient mice were reconstituted with NKT cell-depleted splenocytes of the indicated genotypes. After 2 wk, the TCR switch was induced by poly(I:C) injection. Eight weeks later, percentages of tetramer+ and tetramerā T cells (TCRĪ²+) were analyzed in spleen and liver. Black numbers indicate percentages of total lymphocytes, red numbers absolute cell number calculated from 9ā17 animals. (C) Bars indicate means and SD (error bars) of CD4+, CD8+, or DN (CD4ā CD8ā) cells among tetramerā and tetramer+ T cells, calculated from at least nine mice per genotype. (D, E) The VĪ² repertoires of the depicted splenic CD4+ (D) or CD8+ (E) T cell subsets isolated from T-cell-deficient animals that received NKT cell-depleted <i>Mx-Cre CĪ±<sup>F</sup>/VĪ±14i<sup>StopF</sup></i> splenocytes. Some of these mice were injected with poly(I:C) 2 wk later to induce the TCR switch. Eight weeks after poly(I:C) injection, the VĪ² repertoires were analyzed. Data represent means and SD (error bars) of two independent experiments with a total of three mice (tetramerā without poly(I:C) injection) or eight mice (poly(I:C) injected) per T cell population. VĪ²s typical for glycolipid selection of NKT cells are highlighted in red.</p