Tooth enamel is the hardest substance in the human body and has a unique combination of hardness and fracture toughness that protects teeth from dental caries, the most common chronic disease worldwide. In addition to a high mineral content, tooth enamel comprises organic material that is important for mechanical performance and influences the initiation and progression of caries; however, the protein composition of tooth enamel has not been fully characterized. Here, we determined that epithelial hair keratins, which are crucial for maintaining the integrity of the sheaths that support the hair shaft, are expressed in the enamel organ and are essential organic components of mature enamel. Using genetic and intraoral examination data from 386 children and 706 adults, we found that individuals harboring known hair disorder–associated polymorphisms in the gene encoding keratin 75 (KRT75), KRT75A161T and KRT75E337K, are prone to increased dental caries. Analysis of teeth from individuals carrying the KRT75A161T variant revealed an altered enamel structure and a marked reduction of enamel hardness, suggesting that a functional keratin network is required for the mechanical stability of tooth enamel. Taken together, our results identify a genetic locus that influences enamel structure and establish a connection between hair disorders and susceptibility to dental caries.
Olivier Duverger, Takahiro Ohara, John R. Shaffer, Danielle Donahue, Patricia Zerfas, Andrew Dullnig, Christopher Crecelius, Elia Beniash, Mary L. Marazita, Maria I. Morasso
There are 3 major sweat-producing glands present in skin; eccrine, apocrine, and apoeccrine glands. Due to the high rate of secretion, eccrine sweating is a vital regulator of body temperature in response to thermal stress in humans; therefore, an inability to sweat (anhidrosis) results in heat intolerance that may cause impaired consciousness and death. Here, we have reported 5 members of a consanguineous family with generalized, isolated anhidrosis, but morphologically normal eccrine sweat glands. Whole-genome analysis identified the presence of a homozygous missense mutation in
Joakim Klar, Chihiro Hisatsune, Shahid M. Baig, Muhammad Tariq, Anna C.V. Johansson, Mahmood Rasool, Naveed Altaf Malik, Adam Ameur, Kotomi Sugiura, Lars Feuk, Katsuhiko Mikoshiba, Niklas Dahl
Numerous human disorders, including Cockayne syndrome, UV-sensitive syndrome, xeroderma pigmentosum, and trichothiodystrophy, result from the mutation of genes encoding molecules important for nucleotide excision repair. Here, we describe a syndrome in which the cardinal clinical features include short stature, hearing loss, premature aging, telangiectasia, neurodegeneration, and photosensitivity, resulting from a homozygous missense (p.Ser228Ile) sequence alteration of the proliferating cell nuclear antigen (PCNA). PCNA is a highly conserved sliding clamp protein essential for DNA replication and repair. Due to this fundamental role, mutations in PCNA that profoundly impair protein function would be incompatible with life. Interestingly, while the p.Ser228Ile alteration appeared to have no effect on protein levels or DNA replication, patient cells exhibited marked abnormalities in response to UV irradiation, displaying substantial reductions in both UV survival and RNA synthesis recovery. The p.Ser228Ile change also profoundly altered PCNA’s interaction with Flap endonuclease 1 and DNA Ligase 1, DNA metabolism enzymes. Together, our findings detail a mutation of PCNA in humans associated with a neurodegenerative phenotype, displaying clinical and molecular features common to other DNA repair disorders, which we showed to be attributable to a hypomorphic amino acid alteration.
Emma L. Baple, Helen Chambers, Harold E. Cross, Heather Fawcett, Yuka Nakazawa, Barry A. Chioza, Gaurav V. Harlalka, Sahar Mansour, Ajith Sreekantan-Nair, Michael A. Patton, Martina Muggenthaler, Phillip Rich, Karin Wagner, Roselyn Coblentz, Constance K. Stein, James I. Last, A. Malcolm R. Taylor, Andrew P. Jackson, Tomoo Ogi, Alan R. Lehmann, Catherine M. Green, Andrew H. Crosby
The transcription factor steroidogenic factor 1 (SF-1; also known as NR5A1) is a crucial mediator of both steroidogenic and nonsteroidogenic tissue differentiation. Mutations within
David Zangen, Yotam Kaufman, Ehud Banne, Ariella Weinberg-Shukron, Abdulsalam Abulibdeh, Benjamin P. Garfinkel, Dima Dweik, Moein Kanaan, Núria Camats, Christa Flück, Paul Renbaum, Ephrat Levy-Lahad
The olfactory bulb (OB) receives odor information from the olfactory epithelium and relays this to the olfactory cortex. Using a mouse model, we found that development and maturation of OB interneurons depends on the zinc finger homeodomain factor teashirt zinc finger family member 1 (TSHZ1). In mice lacking TSHZ1, neuroblasts exhibited a normal tangential migration to the OB; however, upon arrival to the OB, the neuroblasts were distributed aberrantly within the radial dimension, and many immature neuroblasts failed to exit the rostral migratory stream. Conditional deletion of Tshz1 in mice resulted in OB hypoplasia and severe olfactory deficits. We therefore investigated olfaction in human subjects from families with congenital aural atresia that were heterozygous for TSHZ1 loss-of-function mutations. These individuals displayed hyposmia, which is characterized by impaired odor discrimination and reduced olfactory sensitivity. Microarray analysis, in situ hybridization, and ChIP revealed that TSHZ1 bound to and regulated expression of the gene encoding prokineticin receptor 2 (PROKR2), a G protein–coupled receptor essential for OB development. Mutations in PROKR2 lead to Kallmann syndrome, characterized by anosmia and hypogonadotrophic hypogonadism. Our data indicate that TSHZ1 is a key regulator of mammalian OB development and function and controls the expression of molecules involved in human Kallmann syndrome.
Daniela Ragancokova, Elena Rocca, Anne M.M. Oonk, Herbert Schulz, Elvira Rohde, Jan Bednarsch, Ilse Feenstra, Ronald J.E. Pennings, Hagen Wende, Alistair N. Garratt
Recombinant adeno-associated virus (rAAV) vectors have shown promise for the treatment of several diseases; however, immune-mediated elimination of transduced cells has been suggested to limit and account for a loss of efficacy. To determine whether rAAV vector expression can persist long term, we administered rAAV vectors expressing normal, M-type α-1 antitrypsin (M-AAT) to AAT-deficient subjects at various doses by multiple i.m. injections. M-specific AAT expression was observed in all subjects in a dose-dependent manner and was sustained for more than 1 year in the absence of immune suppression. Muscle biopsies at 1 year had sustained AAT expression and a reduction of inflammatory cells compared with 3 month biopsies. Deep sequencing of the TCR Vβ region from muscle biopsies demonstrated a limited number of T cell clones that emerged at 3 months after vector administration and persisted for 1 year. In situ immunophenotyping revealed a substantial Treg population in muscle biopsy samples containing AAT-expressing myofibers. Approximately 10% of all T cells in muscle were natural Tregs, which were activated in response to AAV capsid. These results suggest that i.m. delivery of rAAV type 1–AAT (rAAV1-AAT) induces a T regulatory response that allows ongoing transgene expression and indicates that immunomodulatory treatments may not be necessary for rAAV-mediated gene therapy.
Christian Mueller, Jeffrey D. Chulay, Bruce C. Trapnell, Margaret Humphries, Brenna Carey, Robert A. Sandhaus, Noel G. McElvaney, Louis Messina, Qiushi Tang, Farshid N. Rouhani, Martha Campbell-Thompson, Ann Dongtao Fu, Anthony Yachnis, David R. Knop, Guo-jie Ye, Mark Brantly, Roberto Calcedo, Suryanarayan Somanathan, Lee P. Richman, Robert H. Vonderheide, Maigan A. Hulme, Todd M. Brusko, James M. Wilson, Terence R. Flotte
A systems pharmacological approach that capitalizes on the characterization of intracellular signaling networks can transform our understanding of human diseases and lead to therapy development. Here, we applied this strategy to identify pharmacological targets for the treatment of Stargardt disease, a severe juvenile form of macular degeneration. Diverse GPCRs have previously been implicated in neuronal cell survival, and crosstalk between GPCR signaling pathways represents an unexplored avenue for pharmacological intervention. We focused on this receptor family for potential therapeutic interventions in macular disease. Complete transcriptomes of mouse and human samples were analyzed to assess the expression of GPCRs in the retina. Focusing on adrenergic (AR) and serotonin (5-HT) receptors, we found that adrenoceptor α 2C (
Yu Chen, Grazyna Palczewska, Debarshi Mustafi, Marcin Golczak, Zhiqian Dong, Osamu Sawada, Tadao Maeda, Akiko Maeda, Krzysztof Palczewski
Nuclear factor-κB (NF-κB) regulates cellular responses to inflammation and aging, and alterations in NF-κB signaling underlie the pathogenesis of multiple human diseases. Effective clinical therapeutics targeting this pathway remain unavailable. In primary human keratinocytes, we found that hypochlorite (HOCl) reversibly inhibited the expression of
Thomas H. Leung, Lillian F. Zhang, Jing Wang, Shoucheng Ning, Susan J. Knox, Seung K. Kim
Approximately 90% of patients with isolated agammaglobulinemia and failure of B cell development have mutations in genes required for signaling through the pre–B cell and B cell receptors. The nature of the gene defect in the majority of remaining patients is unknown. We recently identified 4 patients with agammaglobulinemia and markedly decreased numbers of peripheral B cells. The B cells that could be detected had an unusual phenotype characterized by the increased expression of CD19 but the absence of a B cell receptor. Genetic studies demonstrated that all 4 patients had the exact same de novo mutation in the broadly expressed transcription factor E47. The mutant protein (E555K) was stable in patient-derived EBV-transformed cell lines and cell lines transfected with expression vectors. E555K in the transfected cells localized normally to the nucleus and resulted in a dominant negative effect when bound to DNA as a homodimer with wild-type E47. Mutant E47 did permit DNA binding by a tissue-specific heterodimeric DNA-binding partner, myogenic differentiation 1 (MYOD). These findings document a mutational hot-spot in E47 and represent an autosomal dominant form of agammaglobulinemia. Further, they indicate that E47 plays a critical role in enforcing the block in development of B cell precursors that lack functional antigen receptors.
Bertrand Boisson, Yong-Dong Wang, Amma Bosompem, Cindy S. Ma, Annick Lim, Tatiana Kochetkov, Stuart G. Tangye, Jean-Laurent Casanova, Mary Ellen Conley
Lumbar disc degeneration (LDD) is associated with both genetic and environmental factors and affects many people worldwide. A hallmark of LDD is loss of proteoglycan and water content in the nucleus pulposus of intervertebral discs. While some genetic determinants have been reported, the etiology of LDD is largely unknown. Here we report the findings from linkage and association studies on a total of 32,642 subjects consisting of 4,043 LDD cases and 28,599 control subjects. We identified carbohydrate sulfotransferase 3 (
You-Qiang Song, Tatsuki Karasugi, Kenneth M.C. Cheung, Kazuhiro Chiba, Daniel W.H. Ho, Atsushi Miyake, Patrick Y.P. Kao, Kit Ling Sze, Anita Yee, Atsushi Takahashi, Yoshiharu Kawaguchi, Yasuo Mikami, Morio Matsumoto, Daisuke Togawa, Masahiro Kanayama, Dongquan Shi, Jin Dai, Qing Jiang, Chengai Wu, Wei Tian, Na Wang, John C.Y. Leong, Keith K.D. Luk, Shea-ping Yip, Stacey S. Cherny, Junwen Wang, Stefan Mundlos, Anthi Kelempisioti, Pasi J. Eskola, Minna Männikkö, Pirkka Mäkelä, Jaro Karppinen, Marjo-Riitta Järvelin, Paul F. O’Reilly, Michiaki Kubo, Tomoatsu Kimura, Toshikazu Kubo, Yoshiaki Toyama, Hiroshi Mizuta, Kathryn S.E. Cheah, Tatsuhiko Tsunoda, Pak-Chung Sham, Shiro Ikegawa, Danny Chan