Oral Ingestion of an Iron-Containing Hand Warmer in a Pediatric Patient.

Hand warmer packets are common products used to provide a portable, nonflammable heat source via the exothermic oxidation of iron. We present the first reported case of pediatric hand warmer packet ingestion in a three-year-old male who developed an elevated serum iron concentration (peak 335 ug/dL) and gastrointestinal injury after ingesting the contents of a HOTHANDS hand warmer packet. He was treated with endoscopic gastric foreign body removal and lavage, as well as proton-pump inhibitors and whole bowel irrigation. Hand warmer packs contain reduced elemental iron powder, which has been shown to have a more favorable safety profile when compared to iron salts. The mechanism of toxicity for reduced iron is unknown, though it is thought to be due to conversion to more toxic iron ions in an acidic environment. While the current adult literature suggests that ingestion of a single hand warmer packet is without significant risk, our case demonstrates that even a partial ingestion carries a significant risk of both iron toxicity and direct gastrointestinal caustic injury in a young child. This case demonstrates the need for multidisciplinary care and consideration of urgent endoscopic foreign body removal and gastric lavage followed by whole bowel irrigation to mitigate the potential of severe iron toxicity.

Aberrant Epithelial Differentiation Contributes to Pathogenesis in a Murine Model of Congenital Tufting Enteropathy.

BACKGROUND & AIMS: Congenital tufting enteropathy (CTE) is an intractable diarrheal disease of infancy caused by mutations of epithelial cell adhesion molecule (EpCAM). The cellular and molecular basis of CTE pathology has been elusive. We hypothesized that the loss of EpCAM in CTE results in altered lineage differentiation and defects in absorptive enterocytes thereby contributing to CTE pathogenesis. METHODS: Intestine and colon from mice expressing a CTE-associated mutant form of EpCAM (mutant mice) were evaluated for specific markers by quantitative real-time polymerase chain reaction, Western blotting, and immunostaining. Body weight, blood glucose, and intestinal enzyme activity were also investigated. Enteroids derived from mutant mice were used to assess whether the decreased census of major secretory cells could be rescued. RESULTS: Mutant mice exhibited alterations in brush-border ultrastructure, function, disaccharidase activity, and glucose absorption, potentially contributing to nutrient malabsorption and impaired weight gain. Altered cell differentiation in mutant mice led to decreased enteroendocrine cells and increased numbers of nonsecretory cells, though the hypertrophied absorptive enterocytes lacked key features, causing brush border malfunction. Further, treatment with the Notch signaling inhibitor, DAPT, increased the numbers of major secretory cell types in mutant enteroids (graphical abstract 1). CONCLUSIONS: Alterations in intestinal epithelial cell differentiation in mutant mice favor an increase in absorptive cells at the expense of major secretory cells. Although the proportion of absorptive enterocytes is increased, they lack key functional properties. We conclude that these effects underlie pathogenic features of CTE such as malabsorption and diarrhea, and ultimately the failure to thrive seen in patients.

Congenital Tufting Enteropathy: Biology, Pathogenesis and Mechanisms.

Congenital tufting enteropathy (CTE) is an autosomal recessive disease of infancy that causes severe intestinal failure with electrolyte imbalances and impaired growth. CTE is typically diagnosed by its characteristic histological features, including villous atrophy, crypt hyperplasia and focal epithelial tufts consisting of densely packed enterocytes. Mutations in the EPCAM and SPINT2 genes have been identified as the etiology for this disease. The significant morbidity and mortality and lack of direct treatments for CTE patients demand a better understanding of disease pathophysiology. Here, the latest knowledge of CTE biology is systematically reviewed, including clinical aspects, disease genetics, and research model systems. Particular focus is paid to the pathogenesis of CTE and predicted mechanisms of the disease as these would provide insight for future therapeutic options. The contribution of intestinal homeostasis, including the role of intestinal cell differentiation, defective enterocytes, disrupted barrier and cell-cell junction, and cell-matrix adhesion, is vividly described here (see Graphical Abstract). Moreover, based on the known dynamics of EpCAM signaling, potential mechanistic pathways are highlighted that may contribute to the pathogenesis of CTE due to either loss of EpCAM function or EpCAM mutation. Although not fully elucidated, these pathways provide an improved understanding of this devastating disease.

Congenital Tufting Enteropathy-Associated Mutant of Epithelial Cell Adhesion Molecule Activates the Unfolded Protein Response in a Murine Model of the Disease.

Congenital tufting enteropathy (CTE) is a rare chronic diarrheal disease of infancy caused by mutations in epithelial cell adhesion molecule (EpCAM). Previously, a murine CTE model showed mis-localization of EpCAM away from the basolateral cell surface in the intestine. Here we demonstrate that mutant EpCAM accumulated in the endoplasmic reticulum (ER) where it co-localized with ER chaperone, GRP78/BiP, revealing potential involvement of ER stress-induced unfolded protein response (UPR) pathway in CTE. To investigate the significance of ER-localized mutant EpCAM in CTE, activation of the three UPR signaling branches initiated by the ER transmembrane protein components IRE1, PERK, and ATF6 was tested. A significant reduction in BLOS1 and SCARA3 mRNA levels in EpCAM mutant intestinal cells demonstrated that regulated IRE1-dependent decay (RIDD) was activated. However, IRE1 dependent XBP1 mRNA splicing was not induced. Furthermore, an increase in nuclear-localized ATF6 in mutant intestinal tissues revealed activation of the ATF6-signaling arm. Finally, an increase in both the phosphorylated form of the translation initiation factor, eIF2α, and ATF4 expression in the mutant intestine provided support for activation of the PERK-mediated pathway. Our results are consistent with a significant role for UPR in gastrointestinal homeostasis and provide a working model for CTE pathophysiology.

Enteroids expressing a disease-associated mutant of EpCAM are a model for congenital tufting enteropathy.

Congenital tufting enteropathy (CTE) is an autosomal recessive disease characterized by severe intestinal failure in infancy and mutations in the epithelial cell adhesion molecule (EPCAM) gene. Previous studies of CTE in mice expressing mutant EpCAM show neonatal lethality. Hence, to study the cellular, molecular, and physiological alterations that result from EpCAM mutation, a tamoxifen-inducible mutant EpCAM enteroid model has been generated. The presence of mutant EpCAM in the model was confirmed at both mRNA and protein levels. Immunofluorescence microscopy demonstrated the reduced expression of mutant EpCAM. Mutant enteroids had reduced budding potential as well as significantly decreased mRNA expression for epithelial lineage markers (Mucin 2, lysozyme, sucrase-isomaltase), proliferation marker Ki67, and secretory pathway transcription factors (Atoh1, Hnf1b). Significantly decreased numbers of Paneth and goblet cells were confirmed by staining. These findings were correlated with intestinal tissue from CTE patients and the mutant mice model that had significantly fewer Paneth and goblet cells than in healthy counterparts. FITC-dextran studies demonstrated significantly impaired barrier function in monolayers derived from mutant enteroids compared with control monolayers. In conclusion, we have established an ex vivo CTE model. The role of EpCAM in the budding potential, differentiation, and barrier function of enteroids is noted. Our study establishes new facets of EpCAM biology that will aid in understanding the pathophysiology of CTE and role of EpCAM in health and disease.NEW & NOTEWORTHY Here, we develop a novel ex vivo enteroid model for congenital tufting enteropathy (CTE) based on epithelial cell adhesion molecule (EPCAM) gene mutations found in patients. With this model we demonstrate the role of EpCAM in maintaining the functional homeostasis of the intestinal epithelium, including differentiation, proliferation, and barrier integrity. This study further establishes a new direction in EpCAM biology that will help in understanding the detailed pathophysiology of CTE and role of EpCAM.

EPCAM mutation update: Variants associated with congenital tufting enteropathy and Lynch syndrome.

The epithelial cell adhesion molecule gene (EPCAM, previously known as TACSTD1 or TROP1) encodes a membrane-bound protein that is localized to the basolateral membrane of epithelial cells and is overexpressed in some tumors. Biallelic mutations in EPCAM cause congenital tufting enteropathy (CTE), which is a rare chronic diarrheal disorder presenting in infancy. Monoallelic deletions of the 3' end of EPCAM that silence the downstream gene, MSH2, cause a form of Lynch syndrome, which is a cancer predisposition syndrome associated with loss of DNA mismatch repair. Here, we report 13 novel EPCAM mutations from 17 CTE patients from two separate centers, review EPCAM mutations associated with CTE and Lynch syndrome, and structurally model pathogenic missense mutations. Statistical analyses indicate that the c.499dupC (previously reported as c.498insC) frameshift mutation was associated with more severe treatment regimens and greater mortality in CTE, whereas the c.556-14A>G and c.491+1G>A splice site mutations were not correlated with treatments or outcomes significantly different than random simulation. These findings suggest that genotype-phenotype correlations may be useful in contributing to management decisions of CTE patients. Depending on the type and nature of EPCAM mutation, one of two unrelated diseases may occur, CTE or Lynch syndrome.

Biallelic Mismatch Repair Deficiency in an Adolescent Female.

Constitutional (Biallelic) Mismatch Repair Deficiency is a rare autosomal recessive disorder characterized by numerous cancers presenting as early as the first decade of life. Biallelic germline variants in one of four mismatch repair genes (MLH1, MSH2, MSH6, or PMS2) cause this devastating disease. Given the rarity of the syndrome, often-asymptomatic tumors, and overlap with neurofibromatosis-1, diagnosis is frequently unrecognized or delayed. We present a unique case of a 14-year-old female with minimal gastrointestinal symptoms diagnosed with invasive adenocarcinoma secondary to biallelic PMS2 variants.

Mutation of EpCAM leads to intestinal barrier and ion transport dysfunction.

UNLABELLED: Congenital tufting enteropathy (CTE) is a devastating diarrheal disease seen in infancy that is typically associated with villous changes and the appearance of epithelial tufts. We previously found mutations in epithelial cell adhesion molecule (EpCAM) to be causative in CTE. We developed a knock-down cell model of CTE through transfection of an EpCAM shRNA construct into T84 colonic epithelial cells to elucidate the in vitro role of EpCAM in barrier function and ion transport. Cells with EpCAM deficiency exhibited decreased electrical resistance, increased permeability, and decreased ion transport. Based on mutations in CTE patients, an in vivo mouse model was developed, with tamoxifen-inducible deletion of exon 4 in Epcam resulting in mutant protein with decreased expression. Tamoxifen treatment of Epcam (Δ4/Δ4) mice resulted in pathological features of villous atrophy and epithelial tufts, similar to those in human CTE patients, within 4 days post induction. Epcam (Δ4/Δ4) mice also showed decreased expression of tight junctional proteins, increased permeability, and decreased ion transport in the intestines. Taken together, these findings reveal mechanisms that may underlie disease in CTE. KEY MESSAGES: Knock-down EpCAM cell model of congenital tufting enteropathy was developed. In vivo inducible mouse model was developed resulting in mutant EpCAM protein. Cells with EpCAM deficiency demonstrated barrier and ion transport dysfunction. Tamoxifen-treated Epcam (Δ4/Δ4) mice demonstrated pathological features. Epcam (Δ4/Δ4) mice showed improper barrier function and ion transport.

Functional consequences of EpCam mutation in mice and men.

Congenital tufting enteropathy (CTE) is a severe diarrheal disease of infancy characterized by villous changes and epithelial tufts. We previously identified mutations in epithelial cell adhesion molecule (EpCAM) as the cause of CTE. We developed an in vivo mouse model of CTE based on EpCAM mutations found in patients with the aim to further elucidate the in vivo role of EpCAM and allow for a direct comparison to human CTE. Using Cre-LoxP recombination technology, we generated a construct lacking exon 4 in Epcam. Epcam(Δ4/Δ4) mice and CTE patient intestinal tissue integrity was analyzed by histology using both light immunohistochemistry and electron microscopy. Epcam(Δ4/Δ4) mice demonstrate neonatal lethality and growth retardation with pathological features, including epithelial tufts, enterocyte crowding, altered desmosomes, and intercellular gaps, similar to human CTE patients. Mutant EpCAM protein is present at low levels and is mislocalized in the intestine of Epcam(Δ4/Δ4) mice and CTE patients. Deletion of exon 4 was found to decrease expression of both EpCAM and claudin-7 causing a loss of colocalization, functionally disrupting the EpCAM/claudin-7 complex, a finding for the first time confirmed in CTE patients. Furthermore, compared with unaffected mice, mutation of Epcam leads to enhanced permeability and intestinal cell migration, uncovering underlying disease mechanisms.

Absence of cell-surface EpCAM in congenital tufting enteropathy.

Mutations in the epithelial cell adhesion molecule (EpCAM; CD326) gene are causal for congenital tufting enteropathy (CTE), a disease characterized by intestinal abnormalities resulting in lethal diarrhea in newborns. Why the different mutations all lead to the same disease is not clear. Here, we report that most mutations, including a novel intronic variant, will result in lack of EpCAM's transmembrane domain, whereas two mutations allow transmembrane localization. We find that these mutants are not routed to the plasma membrane, and that truncated mutants are secreted or degraded. Thus, all epcam mutations lead to loss of cell-surface EpCAM, resulting in CTE.

Identification of EpCAM as the gene for congenital tufting enteropathy.

BACKGROUND & AIMS: Congenital tufting enteropathy (CTE) is a rare autosomal recessive diarrheal disorder presenting in the neonatal period. CTE is characterized by intestinal epithelial cell dysplasia leading to severe malabsorption and significant morbidity and mortality. The pathogenesis and genetics of this disorder are not well understood. The objective of this study was to identify the gene responsible for CTE. METHODS: A family with 2 children affected with CTE was identified. The affected children are double second cousins providing significant statistical power for linkage. Using Affymetrix 50K single nucleotide polymorphism (SNP) chips, genotyping was performed on only 2 patients and 1 unaffected sibling. Direct DNA sequencing of candidate genes, reverse-transcription polymerase chain reaction, immunohistochemistry, and Western blotting were performed on specimens from patients and controls. RESULTS: SNP homozygosity mapping identified a unique 6.5-Mbp haplotype of homozygous SNPs on chromosome 2p21 where approximately 40 genes are located. Direct sequencing of genes in this region revealed homozygous G>A substitution at the donor splice site of exon 4 in epithelial cell adhesion molecule (EpCAM) of affected patients. Reverse-transcription polymerase chain reaction of duodenal tissue demonstrated a novel alternative splice form with deletion of exon 4 in affected patients. Immunohistochemistry and Western blot of patient intestinal tissue revealed decreased expression of EpCAM. Direct sequencing of EpCAM from 2 additional unrelated patients revealed novel mutations in the gene. CONCLUSIONS: Mutations in the gene for EpCAM are responsible for CTE. This information will be used to gain further insight into the molecular mechanisms of this disease.