Tailored multivalent peptide targeting the B-subunit pentamer of cholera toxin inhibits its intestinal toxicity by inducing aberrant transport of the toxin in cells.

Cholera toxin (Ctx) is a major virulence factor produced by Vibrio cholerae that can cause gastrointestinal diseases, including severe watery diarrhea and dehydration, in humans. Ctx binds to target cells through multivalent interactions between its B-subunit pentamer and the receptor ganglioside GM1 present on the cell surface. Here, we identified a series of tetravalent peptides that specifically bind to the receptor-binding region of the B-subunit pentamer using affinity-based screening of multivalent random-peptide libraries. These tetravalent peptides efficiently inhibited not only the cell-elongation phenotype but also the elevated cAMP levels, both of which are induced by Ctx treatment in CHO cells or a human colon carcinoma cell line (Caco-2 cells), respectively. Importantly, one of these peptides, NRR-tet, which was highly efficient in these two activities, markedly inhibited fluid accumulation in the mouse ileum caused by the direct injection of Ctx. In consistent, NRR-tet reduced the extensive Ctx-induced damage of the intestinal villi. After NRR-tet bound to Ctx, the complex was incorporated into the cultured epithelial cells and accumulated in the recycling endosome, affecting the retrograde transport of Ctx from the endosome to the Golgi, which is an essential process for Ctx to exert its toxicity in cells. Thus, NRR-tet may be a novel type of therapeutic agent against cholera, which induces the aberrant transport of Ctx in the intestinal epithelial cells, detoxifying the toxin.

[Ca2+]i fluctuation mediated by T-type Ca2+ channel is required for the differentiation of cortical neural progenitor cells.

The fluctuation of intracellular calcium concentration ([Ca2+]i) is known to be involved in various processes in the development of central nervous system, such as the proliferation of neural progenitor cells (NPCs), migration of intermediate progenitor cells (IPCs) from the ventricular zone (VZ) to the subventricular zone (SVZ), and migration of immature neurons from the SVZ to cortical plate. However, the roles of [Ca2+]i fluctuation in NPC development, especially in the differentiation of the self-renewing NPCs into neuron-generating NPCs and immature neurons have not been elucidated. Using calcium imaging of acute cortical slices and cells isolated from mouse embryonic cortex, we examined temporal changes in the pattern of [Ca2+]i fluctuations in VZ cells from E12 to E16. We observed intracellular Ca2+ levels in Pax6-positive self-renewing NPCs decreased with their neural differentiation. In E11, Pax6-positive NPCs and Tuj1-positive immature neurons exhibited characteristic [Ca2+]i fluctuations; few Pax6-positive NPCs exhibited [Ca2+]i transient, but many Tuj1-positive immature neurons did, suggesting that the change in pattern of [Ca2+]i fluctuation correlate to their differentiation. The [Ca2+]i fluctuation during NPCs development was mostly mediated by the T-type calcium channel and blockage of T-type calcium channel in neurosphere cultures increased the number of spheres and inhibited neuronal differentiation. Consistent with this finding, knockdown of Cav3.1 by RNAi in vivo maintained Pax6-positive cells as self-renewing NPCs, and simultaneously suppressing their neuronal differentiation of NPCs into Tbr1-positive immature neurons. These results reveal that [Ca2+]i fluctuation mediated by Cav3.1 is required for the neural differentiation of Pax6-positive self-renewing NPCs.

Immediate effects of maternal separation on the development of interneurons derived from medial ganglionic eminence in the neonatal mouse hippocampus.

Aversive experiences, including maternal separation (MS), have been known as a risk for abnormal hippocampus development. Given that impairment of GABA inhibitory system is known as one of the common features of the abnormal hippocampal development induced by MS, we examined whether the MS on 4-day-old (P4) mice for 24 hr abolishes the interneuron development. We observed that the MS reduced the volume of dorsal hippocampus on P14 as long-term effects. In addition, the MS decreased the number of parvalbumin (PV)-positive interneuron on P14 and P28 in the dorsal hippocampus. We further examined the immediate effects of MS by measuring the percentage of glutamic acid decarboxylase (GAD) 67-positive interneurons among the immature interneurons derived from medial ganglionic eminence (MGE) progenitors marked in nkx2.1cre;ß-geo EGFP mice. During normal development from P4 to P5, the percentage of GAD67-positive interneurons among the MGE-derived interneurons in the dorsal hippocampus was significantly increased from 42.29% to 70.73% in the stratum pyramidale of the CA1 and increased from 46.4% to 56.99% in the stratum pyramidale of the CA2/3 region. However, the increase was not observed on P5 among the mice treated with the MS. These results suggest that the maturation of interneurons was suppressed by the MS. The suppressed maturation of interneurons may be one of the causes of the reduced volume of the hippocampus and PV+ interneurons observed in the hippocampus on P14 and P28 as a consequence of the MS during neonatal stage.

A tailored tetravalent peptide displays dual functions to inhibit amyloid ß production and aggregation.

Inhibition of amyloid-ß peptide (Aß) accumulation in the brain is a promising approach for treatment of Alzheimer's disease (AD). Aß is produced by ß-secretase and γ-secretase in endosomes via sequential proteolysis of amyloid precursor protein (APP). Aß and APP have a common feature to readily cluster to form multimers. Here, using multivalent peptide library screens, we identified a tetravalent peptide, LME-tet, which binds APP and Aß via multivalent interactions. In cells, LME-tet-bound APP in the plasma membrane is transported to endosomes, blocking Aß production through specific inhibition of ß-cleavage, but not γ-cleavage. LME-tet further suppresses Aß aggregation by blocking formation of the ß-sheet conformation. Inhibitory effects are not observed with a monomeric peptide, emphasizing the significance of multivalent interactions for mediating these activities. Critically, LME-tet efficiently reduces Aß levels in the brain of AD model mice, suggesting it may hold promise for treatment of AD.

Ptch1-mediated dosage-dependent action of Shh signaling regulates neural progenitor development at late gestational stages.

Sonic hedgehog (Shh) signaling regulates cell differentiation and proliferation during brain development. However, the role of Shh in neurogenesis during late gestation (embryonic day 13.5-18.5) remains unclear. Herein, we used a genetic approach and in utero electroporation to investigate the role of mouse Shh and patched homolog 1 (Ptch1), the putative receptor for Shh. Proliferating cortical intermediate (basal) progenitor cells (IPCs) were severely reduced in Shh mutant mice, suggesting that endogenous Shh signaling could play an essential role in cortical IPC development. During cortical neurogenesis, strong upregulation of Shh signaling enhanced the transition from ventricular zone (VZ) progenitors to ventralized IPCs, while low levels of signaling enhanced the generation and proliferation of cortical IPCs in the subventricular zone. The effects of Shh upregulation in this study were consistent with a phenotype of conditional loss of function of Ptch1, and the phenotype of a hypomorphic allele of Ptch1, respectively. These data indicated that endogenous Ptch1 mediates the broad effects of Shh on the transition from VZ progenitors to IPCs and activation of proliferation of the IPCs in the cortex during late gestational stages.

Activation of Sonic Hedgehog Signaling Promotes Differentiation of Cortical Layer 4 Neurons via Regulation of Their Cell Positioning.

Neuronal subtypes in the mammalian cerebral cortex are determined by both intrinsic and extrinsic mechanisms during development. However, the extrinsic cues that are involved in this process remain largely unknown. Here, we investigated the role of sonic hedgehog (Shh) in glutamatergic cortical subtype specification. We found that E14.5-born, but not E15.5-born, neurons with elevated Shh expression frequently differentiated into layer 4 subtypes as judged by the cell positioning and molecular identity. We further found that this effect was achieved indirectly through the regulation of cell positioning rather than the direct activation of layer 4 differentiation programs. Together, we provided evidence that Shh, an extrinsic factor, plays an important role in the specification of cortical superficial layer subtypes.

Mouse Shh is required for prechordal plate maintenance during brain and craniofacial morphogenesis.

In humans, holoprosencephaly (HPE) is a common birth defect characterized by the absence of midline cells from brain, facial, and oral structures. To understand the pathoetiology of HPE, we investigated the involvement of mammalian prechordal plate (PrCP) cells in HPE pathogenesis and the requirement of the secreted protein sonic hedgehog (Shh) in PrCP development. We show using rat PrCP lesion experiments and DiI labeling that PrCP cells are essential for midline development of the forebrain, foregut endoderm, and ventral cranial mesoderm in mammals. We demonstrate that PrCP cells do not develop into ventral cranial mesoderm in Shh(-/-) embryos. Using Shh(-/-) and chimeric embryos we show that Shh signal is required for the maintenance of PrCP cells in a non-cell autonomous manner. In addition, the hedgehog (HH)-responding cells that normally appear during PrCP development to contribute to midline tissues, do not develop in the absence of Shh signaling. This suggests that Shh protein secreted from PrCP cells induces the differentiation of HH-responding cells into midline cells. In the present study, we show that the maintenance of a viable population of PrCP cells by Shh signal is an essential process in development of the midline of the brain and craniofacial structures. These findings provide new insight into the mechanism underlying HPE pathoetiology during dynamic brain and craniofacial morphogenesis.

Author Correction: Altered kynurenine pathway metabolites in a mouse model of human attention-deficit hyperactivity/autism spectrum disorders: A potential new biological diagnostic marker.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

FGF8 signaling patterns the telencephalic midline by regulating putative key factors of midline development.

FGF8 has been reported to act as a primary regulator of neocortical patterning along the anteroposterior (AP) axis in the mouse telencephalon, and disruption of FGF signaling causes distortion of molecular arealization along the AP axis. Since hypoplasia of midline structures is observed in Fgf8 mutant mice, FGF8 is also postulated to be involved in telencephalic midline development. In this study we analyzed the role of FGF8 in midline development by means of gain-of-function and loss-of-function experiments. The results showed that FGF8 up-regulates the expression of transcription factor (TF) genes, including putative key factors involved in midline development. Although FGF8 had been thought to act downstream of SHH signaling, ectopic FGF8 up-regulates the expression of midline TF genes in Shh null mice, suggesting that FGF signaling acts as an upstream positive regulator of midline TFs during midline development independently of SHH.

Regulation of apoptosis and neurite extension by FKBP38 is required for neural tube formation in the mouse.

FKBP38 (also known as FKBP8) is a transmembrane chaperone protein that inhibits apoptosis by recruiting the anti-apoptotic proteins Bcl-2 and Bcl-x(L) to mitochondria. We have now generated mice harboring a loss-of-function mutation in Fkbp38. The Fkbp38(-/-) mice die soon after birth manifesting defects in neural tube closure in the thoraco-lumbar-sacral region (spina bifida) as well as skeletal defects including scoliosis, rib deformities, club foot and curled tail. The neuroepithelium is disorganized and that formation of dorsal root ganglia is defective in Fkbp38(-/-) embryos, likely as a result of an increased frequency of apoptosis and aberrant migration of neuronal cells. Furthermore, the extension of nerve fibers in the spinal cord is abnormal in the mutant embryos. To explore the mechanisms underlying these characteristics, we screened for proteins that interact with FKBP38 in the yeast two-hybrid system and thereby identified protrudin, a protein that promotes process formation by regulating membrane trafficking. Protrudin was found to be hyperphosphorylated in the brain of Fkbp38(-/-) mice, suggesting that FKBP38 regulates protrudin-dependent membrane recycling and neurite outgrowth. Together, our findings suggest that FKBP38 is required for neuroectodermal organization during neural tube formation as a result of its anti-apoptotic activity and regulation of neurite extension.

Mice with a targeted mutation of patched2 are viable but develop alopecia and epidermal hyperplasia.

Hedgehog (Hh) signaling plays pivotal roles in tissue patterning and development in Drosophila melanogaster and vertebrates. The Patched1 (Ptc1) gene, encoding the Hh receptor, is mutated in nevoid basal cell carcinoma syndrome, a human genetic disorder associated with developmental abnormalities and increased incidences of basal cell carcinoma (BCC) and medulloblastoma (MB). Ptc1 mutations also occur in sporadic forms of BCC and MB. Mutational studies with mice have verified that Ptc1 is a tumor suppressor. We previously identified a second mammalian Patched gene, Ptc2, and demonstrated its distinct expression pattern during embryogenesis, suggesting a unique role in development. Most notably, Ptc2 is expressed in an overlapping pattern with Shh in the epidermal compartment of developing hair follicles and is highly expressed in the developing limb bud, cerebellum, and testis. Here, we describe the generation and phenotypic analysis of Ptc2(tm1/tm1) mice. Our molecular analysis suggests that Ptc2(tm1) likely represents a hypomorphic allele. Despite the dynamic expression of Ptc2 during embryogenesis, Ptc2(tm1/tm1) mice are viable, fertile, and apparently normal. Interestingly, adult Ptc2(tm1/tm1) male animals develop skin lesions consisting of alopecia, ulceration, and epidermal hyperplasia. While functional compensation by Ptc1 might account for the lack of a strong mutant phenotype in Ptc2-deficient mice, our results suggest that normal Ptc2 function is required for adult skin homeostasis.

Altered kynurenine pathway metabolites in a mouse model of human attention-deficit hyperactivity/autism spectrum disorders: A potential new biological diagnostic marker.

Deleterious mutations in patchd1 domain containing 1 (PTCHD1) gene have been identified in patients with intellectual disability and/or autism spectrum disorder (ASD). To clarify the causal relationship between Ptchd1 deficiency and behavioral defects relevant to neurodevelopmental disorders, we generated global Ptchd1 knockout (KO) mice. Ptchd1 KO mice displayed hyperlocomotion, increased impulsivity, and lower recognition memory, which resemble attention-deficit hyperactivity disorder (ADHD)-like behaviors. Acute or chronic treatment with atomoxetine ameliorated almost all behavioral deficits in Pthcd1 KO mice. We next determined possible involvement of the kynurenine pathway (KP) metabolites in neurodevelopmental disorders in Ptchd1 KO mice and assessed the potential of KP metabolites as biomarkers for ADHD and/or ASD. Ptchd1 KO mice showed drastic changes in KP metabolite concentrations in the serum and the brain, indicating that the activated KP is associated with ADHD-like behaviors. Our findings indicate that Ptchd1 KO mice can be used as an animal model of human ADHD and/or ASD, and KP metabolites are potential diagnostic biomarkers for neurodevelopmental disorders.

Fetal ethanol exposure activates protein kinase A and impairs Shh expression in prechordal mesendoderm cells in the pathogenesis of holoprosencephaly.

BACKGROUND: In humans, fetal ethanol exposure can cause holoprosencephaly (HPE), one of the most common birth defects that is characterized by brain, facial, and oral abnormalities. However, the pathogenesis of HPE is not clear. In the present study, we investigated the teratogenic mechanism of ethanol-induced brain and facial malformations in mice. METHODS: Pregnant C57BL/6J mice were administered ethanol on E7 and facial and brain malformations were characterized on E10.5. We examined the effect of fetal ethanol exposure on Shh expression and activation of protein kinase A (PKA) because mutations in the human Shh gene are the most frequent cause of autosomal-dominant inherited HPE and PKA is a potent endogenous antagonist of Shh signaling. RESULTS: Fetal ethanol exposure on E7 induced severe midline defects characteristic of HPE. Ethanol exposure impaired Shh expression and induced excessive apoptosis only along the anterior edge of the prechordal mesendoderm (PME). In addition, ethanol activated PKA in anterior PME cells. Pretreatment of embryos with antioxidants, such as vitamins C or E, prevented the development of ethanol-induced HPE. CONCLUSIONS: Shh expression in PME cells is involved in the pathogenesis of ethanol-induced HPE. Ethanol may impair Shh expression indirectly by activating PKA. The inhibition of excessive apoptosis in PME cells by antioxidants implies that oxidative stress may underlie the teratogenic actions of ethanol. Thus, antioxidant treatment may be a simple preventative measure that could reduce the incidence of HPE following fetal ethanol exposure.

Exosome-associated Shiga toxin 2 is released from cells and causes severe toxicity in mice.

Shiga toxin (Stx), a major virulence factor of enterohemorrhagic Escherichia coli (EHEC), is classified into two subgroups, Stx1 and Stx2. Clinical data clearly indicate that Stx2 is associated with more severe toxicity than Stx1, but the molecular mechanism underlying this difference is not fully understood. Here, we found that after being incorporated into target cells, Stx2, can be transported by recycling endosomes, as well as via the regular retrograde transport pathway. However, transport via recycling endosome did not occur with Stx1. We also found that Stx2 is actively released from cells in a receptor-recognizing B-subunit dependent manner. Part of the released Stx2 is associated with microvesicles, including exosome markers (referred to as exo-Stx2), whose origin is in the multivesicular bodies that formed from late/recycling endosomes. Finally, intravenous administration of exo-Stx2 to mice causes more lethality and tissue damage, especially severe renal dysfunction and tubular epithelial cell damage, compared to a free form of Stx2. Thus, the formation of exo-Stx2 might contribute to the severity of Stx2 in vivo, suggesting new therapeutic strategies against EHEC infections.

Essential roles of Gli3 and sonic hedgehog in pattern formation and developmental anomalies caused by their dysfunction.

Pattern formation along the body axis directs the proportion of different types of cells required for functional tissue structures. The secreted protein sonic hedgehog (Shh) and zinc finger transcription factor Gli3 are key players in pattern formation during brain and limb development; the antagonistic action of Shh towards Gli3 may be crucial for pattern formation. Recent findings from Shh/Gli3 double homozygous mutants suggest that a balance of both activities is required for the production of the normal proportion of different cell types during organogenesis. This conclusion contrasts with the alternative hypothesis that a Shh gradient directs the specification of several different cell types. The observations reviewed here offer a new perspective on understanding the pathogenesis of human birth defects caused by mutations of the Shh and Gli3 genes.

Differential activities of Sonic hedgehog mediated by Gli transcription factors define distinct neuronal subtypes in the dorsal thalamus.

The dorsal thalamus (DT) is a pivotal region in the vertebrate brain that relays inputs from the peripheral sensory organs to higher cognitive centers. It consists of clusters of neurons with relevant functions, called brain nuclei. However, the mechanisms underlying development of the DT, including specification of the neuronal subtypes and morphogenesis of the nuclear structures, remain largely unknown. As a first step to this end, we focused on two transcription factors Sox14 and Gbx2 that are expressed in the specific brain nuclei in the chick DT. The onset of their expression was found in distinct populations of the postmitotic cells in the prosomere 2, which was regulated by the differential activities of Sonic hedgehog (Shh) in a manner consistent with the action as a morphogen. Furthermore, both gain- and loss-of-function results strongly suggest that such distinct inductive activities are mediated selectively by different Gli factors. These results suggest that cooperation of the differential expression of Gli factors and the activity gradient of Shh signaling generates the distinct thalamic neurons at the specific locations.

Retinoic Acid Treatment Induces Cell Death and the Protein Expression of Retinoic Acid Receptor ß in the Mesenchymal Cells of Mouse Facial Primordia in Vitro: (RA/facial mesenchymal cells/chondrogenesis/cell death/RAR b and g protein expression/ micromass culture).

We isolated mesenchymal cells from individual facial primordia of mouse embryos on 11 days post coitum and examined the effects of retinoic acid (RA) on chondrogenesis, induction of cell death, and the protein expression of retinoic acid receptor (RAR) ß and γ in micromass culture. Under the control condition, cells of both medial and lateral nasal prominences (MNP and LNP) displayed high chondrogenic potential, while those of maxillary and mandibular prominences (Mx and Md) had constant growth activity and low chondrogenic potential. Though none of the cells expressed detectable levels of the RAR ß protein, RAR γ was expressed in the cells of all the facial primordia. One µM RA inhibited the chondrogenesis, and induced cell death accompanied with the induction of the RAR ß protein in LNP, MX and Md cells within 6 hr. On the contrary, both cell death and RAR ß protein induction were detected in the MNP cells treated with RA for 24 hr. These results suggest that the RAR ß is involved in the process of the cell death induced by the RA treatment in the mesenchymal cells of the mouse facial primordia.

Genetic analysis of Hedgehog signaling in ventral body wall development and the onset of omphalocele formation.

BACKGROUND: An omphalocele is one of the major ventral body wall malformations and is characterized by abnormally herniated viscera from the body trunk. It has been frequently found to be associated with other structural malformations, such as genitourinary malformations and digit abnormalities. In spite of its clinical importance, the etiology of omphalocele formation is still controversial. Hedgehog (Hh) signaling is one of the essential growth factor signaling pathways involved in the formation of the limbs and urogenital system. However, the relationship between Hh signaling and ventral body wall formation remains unclear. METHODOLOGY/PRINCIPAL FINDINGS: To gain insight into the roles of Hh signaling in ventral body wall formation and its malformation, we analyzed phenotypes of mouse mutants of Sonic hedgehog (Shh), GLI-Kruppel family member 3 (Gli3) and Aristaless-like homeobox 4 (Alx4). Introduction of additional Alx4(Lst) mutations into the Gli3(Xt/Xt) background resulted in various degrees of severe omphalocele and pubic diastasis. In addition, loss of a single Shh allele restored the omphalocele and pubic symphysis of Gli3(Xt/+); Alx4(Lst/Lst) embryos. We also observed ectopic Hh activity in the ventral body wall region of Gli3(Xt/Xt) embryos. Moreover, tamoxifen-inducible gain-of-function experiments to induce ectopic Hh signaling revealed Hh signal dose-dependent formation of omphaloceles. CONCLUSIONS/SIGNIFICANCE: We suggest that one of the possible causes of omphalocele and pubic diastasis is ectopically-induced Hh signaling. To our knowledge, this would be the first demonstration of the involvement of Hh signaling in ventral body wall malformation and the genetic rescue of omphalocele phenotypes.

The role of sonic hedgehog-Gli2 pathway in the masculinization of external genitalia.

During embryogenesis, sexually dimorphic organogenesis is achieved by hormones produced in the gonad. The external genitalia develop from a single primordium, the genital tubercle, and their masculinization processes depend on the androgen signaling. In addition to such hormonal signaling, the involvement of nongonadal and locally produced masculinization factors has been unclear. To elucidate the mechanisms of the sexually dimorphic development of the external genitalia, series of conditional mutant mouse analyses were performed using several mutant alleles, particularly focusing on the role of hedgehog signaling pathway in this manuscript. We demonstrate that hedgehog pathway is indispensable for the establishment of male external genitalia characteristics. Sonic hedgehog is expressed in the urethral plate epithelium, and its signal is mediated through glioblastoma 2 (Gli2) in the mesenchyme. The expression level of the sexually dimorphic genes is decreased in the glioblastoma 2 mutant embryos, suggesting that hedgehog signal is likely to facilitate the masculinization processes by affecting the androgen responsiveness. In addition, a conditional mutation of Sonic hedgehog at the sexual differentiation stage leads to abnormal male external genitalia development. The current study identified hedgehog signaling pathway as a key factor not only for initial development but also for sexually dimorphic development of the external genitalia in coordination with androgen signaling.

Hyperthermic treatment of DMBA-induced rat mammary cancer using magnetic nanoparticles.

BACKGROUND: We have developed magnetite cationic liposomes (MCLs) and applied them as a mediator of local hyperthermia. MCLs can generate heat under an alternating magnetic field (AMF). In this study, the in vivo effect of hyperthermia mediated by MCLs was examined using 7,12-dimethylbenz(a)anthracene (DMBA)-induced rat mammary cancer as a spontaneous cancer model. METHOD: MCLs were injected into the mammary cancer and then subjected to an AMF. RESULTS: Four rats in 20 developed mammary tumors at more than 1 site in the body. The first-developed tumor in each of these 4 rats was selected and heated to over 43 degrees C following administration of MCLs by an infusion pump. After a series of 3 hyperthermia treatments, treated tumors in 3 of the 4 rats were well controlled over a 30-day observation period. One of the 4 rats exhibited regrowth after 2 weeks. In this rat, there were 3 sites of tumor regrowth. Two of these regrowths were reduced in volume and regressed completely after 31 days, although the remaining one grew rapidly. These results indicated hyperthermia-induced immunological antitumor activity mediated by the MCLs. CONCLUSION: Our results suggest that hyperthermic treatment using MCLs is effective in a spontaneous cancer model.