Your search keyword '"Dell'Angelica, Esteban C."' showing total 168 results

151. Isolation and N-terminal sequence of two low molecular weight calcium-binding proteins from pig granulocytes

Author

Schleicher, Christian H., primary, Dell'Angelica, Esteban C., additional, and Santomé, JoséA., additional

Published

1993

152. Study on fatty acid binding by proteins in yeast. Dissimilar results in Saccharomyces cerevisiae and Yarrowia lipolytica

Author

Dell'Angelica, Esteban C., primary, Stella, Carlos A., additional, ermácora, Mario R., additional, Ramos, Eugenia H., additional, and Santome, JoséA., additional

Published

1992

153. Functional interactions between OCA2 and the protein complexes BLOC-1, BLOC-2, and AP-3 inferred from epistatic analyses of mouse coat pigmentation.

Author

Hoyle, Diego J., Rodriguez-Fernandez, Imilce A., and Dell'Angelica, Esteban C.

Subjects

PROTEINS, ANIMAL coloration, MEMBRANE proteins, CELL membrane formation, ALBINISM, MICE

Abstract

The biogenesis of melanosomes is a multistage process that requires the function of cell-type-specific and ubiquitously expressed proteins. OCA2, the product of the gene defective in oculocutaneous albinism type 2, is a melanosomal membrane protein with restricted expression pattern and a potential role in the trafficking of other proteins to melanosomes. The ubiquitous protein complexes AP-3, BLOC-1, and BLOC-2, which contain as subunits the products of genes defective in various types of Hermansky-Pudlak syndrome, have been likewise implicated in trafficking to melanosomes. We have tested for genetic interactions between mutant alleles causing deficiency in OCA2 (pink-eyed dilution unstable), AP-3 (pearl), BLOC-1 (pallid), and BLOC-2 (cocoa) in C57BL/6J mice. The pallid allele was epistatic to pink-eyed dilution, and the latter behaved as a semi-dominant phenotypic enhancer of cocoa and, to a lesser extent, of pearl. These observations suggest functional links between OCA2 and these three protein complexes involved in melanosome biogenesis. [ABSTRACT FROM AUTHOR]

Published

2011

154. Genetic modifiers of abnormal organelle biogenesis in a Drosophila model of BLOC-1 deficiency.

Author

Cheli, Verónica T., Daniels, Richard W., Godoy, Ruth, Hoyle, Diego J., Kandachar, Vasundhara, Starcevic, Marta, Martinez-Agosto, Julian A., Poole, Stephen, DiAntonio, Aaron, Lloyd, Vett K., Chang, Henry C., Krantz, David E., and Dell'Angelica, Esteban C.

Published

2010

155. The Drosophila Pigmentation Gene pink ( p) Encodes a Homologue of Human Hermansky–Pudlak Syndrome 5 (HPS5).

Author

Falcón-Pérez, Juan M., Romero-Calderón, Rafael, Brooks, Elizabeth S., Krantz, David E., and Dell’Angelica, Esteban C.

Subjects

DROSOPHILA melanogaster genetics, LYSOSOMES, ORGANELLES, GENETIC mutation, PHENOTYPES, BIOLOGICAL pigments, PHYSIOLOGY

Abstract

Lysosome-related organelles comprise a group of specialized intracellular compartments that include melanosomes and platelet dense granules (in mammals) and eye pigment granules (in insects). In humans, the biogenesis of these organelles is defective in genetic disorders collectively known as Hermansky–Pudlak syndrome (HPS). Patients with HPS-2, and two murine HPS models, carry mutations in genes encoding subunits of adaptor protein (AP)-3. Other genes mutated in rodent models include those encoding VPS33A and Rab38. Orthologs of all of these genes in Drosophila melanogaster belong to the ‘granule group’ of eye pigmentation genes. Other genes associated with HPS encode subunits of three complexes of unknown function, named biogenesis of lysosome-related organelles complex (BLOC)-1, -2 and -3, for which the Drosophila counterparts had not been characterized. Here, we report that the gene encoding the Drosophila ortholog of the HPS5 subunit of BLOC-2 is identical to the granule group gene pink ( p), which was first studied in 1910 but had not been identified at the molecular level. The phenotype of pink mutants was exacerbated by mutations in AP-3 subunits or in the orthologs of VPS33A and Rab38. These results validate D. melanogaster as a genetic model to study the function of the BLOCs. [ABSTRACT FROM AUTHOR]

Published

2007

156. Hermansky-Pudlak syndrome type 7 (HPS-7) results from mutant dysbindin, a member of the biogenesis of lysosome-related organelles complex 1 (BLOC-1).

Author

Wei Li, Qing Zhang, Naoki Oiso, Novak, Edward K., Gautam, Rashi, O'Brien, Edward P., Tinsley, Caroline L., Blake, Derek J., Spritz, Richard A., Copeland, Neal G., Jenkins, Nancy A., Amato, Dominick, Roe, Bruce A., Starcevic, Marta, Dell'Angelica, Esteban C., Elliott, Rosemary W., Mishra, Vishnu, Kingsmore, Stephen F., Paylor, Richard E., and Swank, Richard T.

Subjects

ALBINISM, PULMONARY fibrosis, LYSOSOMES, MICE, GENETIC mutation

Abstract

Hermansky-Pudlak syndrome (HPS; MIM 203300) is a genetically heterogeneous disorder characterized by oculocutaneous albinism, prolonged bleeding and pulmonary fibrosis due to abnormal vesicle trafficking to lysosomes and related organelles, such as melanosomes and platelet dense granules. In mice, at least 16 loci are associated with HPS, including sandy (sdy; ref. 7). Here we show that the sdy mutant mouse expresses no dysbindin protein owing to a deletion in the gene Dtnbp1 (encoding dysbindin) and that mutation of the human ortholog DTNBP1 causes a novel form of HPS called HPS-7. Dysbindin is a ubiquitously expressed protein that binds to a- and ß-dystrobrevins, components of the dystrophin-associated protein complex (DPC) in both muscle and nonmuscle cells. We also show that dysbindin is a component of the biogenesis of lysosome-related organelles complex 1 (BLOC-1; refs. 9-11), which regulates trafficking to lysosome-related organelles and includes the proteins pallidin, muted and cappuccino, which are associated with HPS in mice. These findings show that BLOC-1 is important in producing the HPS phenotype in humans, indicate that dysbindin has a role in the biogenesis of lysosome-related organelles and identify unexpected interactions between components of DPC and BLOC-1. [ABSTRACT FROM AUTHOR]

Published

2003

157. The Pallidin (Pldn ) Gene and the Role of SNARE Proteins in Melanosome Biogenesis.

Author

Falcón-Pérez, Juan M and Dell'angelica, Esteban C

Subjects

*PIGMENTATION disorders, *BLOOD platelets, *GENETICS

Abstract

This review focuses on the product of the pallidin (Pldn ) gene, one of a number of genes that in mice are associated with pigmentation defects and platelet dense granule deficiency. A similar combination of defects is also observed in patients suffering from Hermansky–Pudlak (HPS) and Chediak–Higashi (CHS) syndromes. Pldn encodes a novel, ∼20-kDa protein that is expressed ubiquitously in mammalian tissues. The pallidin protein was found to bind to syntaxin 13, a member of the syntaxin family of soluble N -ethylmaleimide-sensitive factor attachment protein receptors (SNAREs). As SNARE proteins mediate fusion of intracellular membranes, pallidin may play a role in membrane fusion events required for melanosome biogenesis. [ABSTRACT FROM AUTHOR]

Published

2002

158. Purification and partial characterization of a fatty acidbinding protein from the yeast, Yarrowia lipolytica.

Author

Dell'Angelica, Esteban C., Ermácora, Mario R., and Santomé, José A.

Published

1996

159. Altered expression of a novel adaptin leads to defective pigment granule biogenesis in the Drosophila eye color mutant garnet.

Author

Chean Eng Ooi, Moreira, Jorge E., Dell'Angelica, Esteban C., Poy, George, Wassarman, David A., and Bonifacino, Juan S.

Subjects

BIOSYNTHESIS, ORGANIC synthesis, ENZYMES, DROSOPHILA, BIOCHEMISTRY, GENETICS, GENETIC mutation

Abstract

Drosophila eye pigmentation defects have thus far been attributed to mutations in genes encoding enzymes required for biosynthesis of pigments and to ABC-type membrane transporters for pigments or their precursors. We report here that a defect in a gene encoding a putative coat adaptor protein leads to the eye color defect of garnet mutants. We first identified a human cDNA encoding δ-adaptin, a structural homolog of the α- and γ-adaptin subunits of the clathrin coat adaptors AP-1 and AP-2, respectively. Biochemical analyses demonstrated that δ-adaptin is a component of the adaptor-like complex AP-3 in human cells. We then isolated a full-length cDNA encoding the Drosophila ortholog of δ-adaptin and found that transcripts specified by this cDNA are altered in garnet mutant flies. Examination by light and electron microscopy indicated that these mutant flies have reduced numbers of eye pigment granules, which correlates with decreased levels of both pteridine (red) and ommachrome (brown) pigments. Thus, the eye pigmentation defect in the Drosophila garnet mutant may be attributed to compromised function of a coat protein involved in intracellular transport processes required for biogenesis or function of pigment granules. [ABSTRACT FROM AUTHOR]

Published

1997

160. Intracellular Cycling of Lysosomal Enzyme Receptors Cytoplasmic Tails' Tales

Author

Dell'Angelica, Esteban C. and Payne, Gregory S.

161. Correction to: An autosomal dominant neurological disorder caused by de novo variants in FAR1resulting in uncontrolled synthesis of ether lipids

Author

Ferdinandusse, Sacha, McWalter, Kirsty, te Brinke, Heleen, IJlst, Lodewijk, Mooijer, Petra M., Ruiter, Jos P.N., van Lint, Alida E.M., Pras-Raves, Mia, Wever, Eric, Millan, Francisca, Guillen Sacoto, Maria J., Begtrup, Amber, Tarnopolsky, Mark, Brady, Lauren, Ladda, Roger L., Sell, Susan L., Nowak, Catherine B., Douglas, Jessica, Tian, Cuixia, Ulm, Elizabeth, Perlman, Seth, Drack, Arlene V., Chong, Karen, Martin, Nicole, Brault, Jennifer, Brokamp, Elly, Toro, Camilo, Gahl, William A., Macnamara, Ellen F., Wolfe, Lynne, Alejandro, Mercedes E., Azamian, Mahshid S., Bacino, Carlos A., Balasubramanyam, Ashok, Burrage, Lindsay C., Chao, Hsiao-Tuan, Clark, Gary D., Craigen, William J., Dai, Hongzheng, Dhar, Shweta U., Emrick, Lisa T., Goldman, Alica M., Hanchard, Neil A., Jamal, Fariha, Karaviti, Lefkothea, Lalani, Seema R., Lee, Brendan H., Lewis, Richard A., Marom, Ronit, Moretti, Paolo M., Murdock, David R., Nicholas, Sarah K., Orengo, James P., Posey, Jennifer E., Potocki, Lorraine, Rosenfeld, Jill A., Samson, Susan L., Scott, Daryl A., Tran, Alyssa A., Vogel, Tiphanie P., Wangler, Michael F., Yamamoto, Shinya, Eng, Christine M., Liu, Pengfei, Ward, Patricia A., Behrens, Edward, Deardorff, Matthew, Falk, Marni, Hassey, Kelly, Sullivan, Kathleen, Vanderver, Adeline, Goldstein, David B., Cope, Heidi, McConkie-Rosell, Allyn, Schoch, Kelly, Shashi, Vandana, Smith, Edward C., Spillmann, Rebecca C., Sullivan, Jennifer A., Tan, Queenie K.-G., Walley, Nicole M., Agrawal, Pankaj B., Beggs, Alan H., Berry, Gerard T., Briere, Lauren C., Cobban, Laurel A., Coggins, Matthew, Cooper, Cynthia M., Fieg, Elizabeth L., High, Frances, Holm, Ingrid A., Korrick, Susan, Krier, Joel B., Lincoln, Sharyn A., Loscalzo, Joseph, Maas, Richard L., MacRae, Calum A., Pallais, J. Carl, Rao, Deepak A., Rodan, Lance H., Silverman, Edwin K., Stoler, Joan M., Sweetser, David A., Walker, Melissa, Walsh, Chris A., Esteves, Cecilia, Kelley, Emily G., Kohane, Isaac S., LeBlanc, Kimberly, McCray, Alexa T., Nagy, Anna, Dasari, Surendra, Lanpher, Brendan C., Lanza, Ian R., Morava, Eva, Oglesbee, Devin, Bademci, Guney, Barbouth, Deborah, Bivona, Stephanie, Carrasquillo, Olveen, Chang, Ta Chen Peter, Forghani, Irman, Grajewski, Alana, Isasi, Rosario, Lam, Byron, Levitt, Roy, Liu, Xue Zhong, McCauley, Jacob, Sacco, Ralph, Saporta, Mario, Schaechter, Judy, Tekin, Mustafa, Telischi, Fred, Thorson, Willa, Zuchner, Stephan, Colley, Heather A., Dayal, Jyoti G., Eckstein, David J., Findley, Laurie C., Krasnewich, Donna M., Mamounas, Laura A., Manolio, Teri A., Mulvihill, John J., LaMoure, Grace L., Goldrich, Madison P., Urv, Tiina K., Doss, Argenia L., Acosta, Maria T., Bonnenmann, Carsten, D’Souza, Precilla, Draper, David D., Ferreira, Carlos, Godfrey, Rena A., Groden, Catherine A., Macnamara, Ellen F., Maduro, Valerie V., Markello, Thomas C., Nath, Avi, Novacic, Donna, Pusey, Barbara N., Toro, Camilo, Wahl, Colleen E., Baker, Eva, Burke, Elizabeth A., Adams, David R., Gahl, William A., Malicdan, May Christine V., Tifft, Cynthia J., Wolfe, Lynne A., Yang, John, Power, Bradley, Gochuico, Bernadette, Huryn, Laryssa, Latham, Lea, Davis, Joie, Mosbrook-Davis, Deborah, Rossignol, Francis, Solomon, Ben, MacDowall, John, Thurm, Audrey, Zein, Wadih, Yousef, Muhammad, Adam, Margaret, Amendola, Laura, Bamshad, Michael, Beck, Anita, Bennett, Jimmy, Berg-Rood, Beverly, Blue, Elizabeth, Boyd, Brenna, Byers, Peter, Chanprasert, Sirisak, Cunningham, Michael, Dipple, Katrina, Doherty, Daniel, Earl, Dawn, Glass, Ian, Golden-Grant, Katie, Hahn, Sihoun, Hing, Anne, Hisama, Fuki M., Horike-Pyne, Martha, Jarvik, Gail P., Jarvik, Jeffrey, Jayadev, Suman, Lam, Christina, Maravilla, Kenneth, Mefford, Heather, Merritt, J. Lawrence, Mirzaa, Ghayda, Nickerson, Deborah, Raskind, Wendy, Rosenwasser, Natalie, Scott, C. Ron, Sun, Angela, Sybert, Virginia, Wallace, Stephanie, Wener, Mark, Wenger, Tara, Ashley, Euan A., Bejerano, Gill, Bernstein, Jonathan A., Bonner, Devon, Coakley, Terra R., Fernandez, Liliana, Fisher, Paul G., Fresard, Laure, Hom, Jason, Huang, Yong, Kohler, Jennefer N., Kravets, Elijah, Majcherska, Marta M., Martin, Beth A., Marwaha, Shruti, McCormack, Colleen E., Raja, Archana N., Reuter, Chloe M., Ruzhnikov, Maura, Sampson, Jacinda B., Smith, Kevin S., Sutton, Shirley, Tabor, Holly K., Tucker, Brianna M., Wheeler, Matthew T., Zastrow, Diane B., Zhao, Chunli, Byrd, William E., Crouse, Andrew B., Might, Matthew, Nakano-Okuno, Mariko, Whitlock, Jordan, Brown, Gabrielle, Butte, Manish J., Dell’Angelica, Esteban C., Dorrani, Naghmeh, Douine, Emilie D., Fogel, Brent L., Gutierrez, Irma, Huang, Alden, Krakow, Deborah, Lee, Hane, Loo, Sandra K., Mak, Bryan C., Martin, Martin G., Martínez-Agosto, Julian A., McGee, Elisabeth, Nelson, Stanley F., Nieves-Rodriguez, Shirley, Palmer, Christina G.S., Papp, Jeanette C., Parker, Neil H., Renteria, Genecee, Signer, Rebecca H., Sinsheimer, Janet S., Wan, Jijun, Wang, Lee-kai, Perry, Katherine Wesseling, Woods, Jeremy D., Alvey, Justin, Andrews, Ashley, Bale, Jim, Bohnsack, John, Botto, Lorenzo, Carey, John, Pace, Laura, Longo, Nicola, Marth, Gabor, Moretti, Paolo, Quinlan, Aaron, Velinder, Matt, Viskochil, Dave, Bayrak-Toydemir, Pinar, Mao, Rong, Westerfield, Monte, Bican, Anna, Brokamp, Elly, Duncan, Laura, Hamid, Rizwan, Kennedy, Jennifer, Kozuira, Mary, Newman, John H., Phillips, John A., Rives, Lynette, Robertson, Amy K., Solem, Emily, Cogan, Joy D., Cole, F. Sessions, Hayes, Nichole, Kiley, Dana, Sisco, Kathy, Wambach, Jennifer, Wegner, Daniel, Baldridge, Dustin, Pak, Stephen, Schedl, Timothy, Shin, Jimann, Solnica-Krezel, Lilianna, Waisfisz, Quinten, Zwijnenburg, Petra J.G., Ziegler, Alban, Barth, Magalie, Smith, Rosemarie, Ellingwood, Sara, Gaebler-Spira, Deborah, Bakhtiari, Somayeh, Kruer, Michael C., van Kampen, Antoine H.C., Wanders, Ronald J.A., Waterham, Hans R., Cassiman, David, and Vaz, Frédéric M.

Published

2021

162. Biogenesis of lysosome-related organelles complex 3 (BLOC-3): A complex containing the Hermansky-Pudlak syndrome (HPS) proteins HPS1 and HPS4.

Author

Nazarian, Ramin, Falcón-Pérez, Juan M., and Dell'Angelica, Esteban C.

Subjects

*LYSOSOMES, *ORGANELLES, *SYNDROMES, *GENETIC code, *HELA cells

Abstract

Hermansky-Pudlak syndrome (HPS) defines a group of autosomal recessive disorders characterized by deficiencies in lysosomerelated organelles such as melanosomes and platelet-dense granules. Several HPS genes encode proteins of unknown function including HPS1, HPS3, and HPS4. Here we have identified and characterized endogenous HPS3 and HPS4 proteins from HeLa cells. Both proteins were found in soluble and membrane-associated forms. Sedimentation-velocity and coimmunoprecipitation experiments revealed that HPS4 but not HPS3 associates with HPS1 in a complex, which we term biogenesis of lysosome-related organelles complex 3 (BLOC-3). Mutant fibroblasts deficient in either HPS1 or HPS4 displayed abnormal localization of lysosomes and late endosomes, which were less concentrated at the juxtanuclear region in mutant cells than in control fibroblasts. The coat-color phenotype of young homozygous double-mutant mice deficient in subunits of BLOC-3 (HPS1) and BLOC-1 (pallidin) was indistinguishable from that of BLOC-1 single mutants. Taken together, these observations suggest that HPS1 and HPS4 are components of a protein complex that regulates the intracellular localization of lysosomes and late endosomes and may function in a BLOC-l-dependent pathway for melanosome biogenesis. [ABSTRACT FROM AUTHOR]

Published

2003

163. Myosin Vc Interacts with Rab32 and Rab38 Proteins and Works in the Biogenesis and Secretion of Melanosomes.

Author

Bultema, Jarred J., Boyle, Judith A., Malenke, Parker B., Martin, Faye E., Dell'Angelica, Esteban C., Cheney, Richard E., and Di Pietro, Santiago M.

Subjects

*MYOSIN, *PROTEIN research, *ORGANELLES, *LYSOSOMES, *MEMBRANE proteins

Abstract

Class V myosins are actin-based motors with conserved functions in vesicle and organelle trafficking. Herein we report the discovery of a function for Myosin Vc in melanosome biogenesis as an effector of melanosome-associated Rab GTPases. We isolated Myosin Vc in a yeast two-hybrid screening for proteins that interact with Rab38, a Rab protein involved in the biogenesis of melanosomes and other lysosome-related organelles. Rab38 and its close homolog Rab32 bind to Myosin Vc but not to Myosin Va or Myosin Vb. Binding depends on residues in the switch II region of Rab32 and Rab38 and regions of the Myosin Vc coiled-coil tail domain. Myosin Vc also interacts with Rab7a and Rab8a but not with Rab11, Rab17, and Rab27. Although Myosin Vc is not particularly abundant on pigmented melanosomes, its knockdown in MNT-1 melanocytes caused defects in the trafficking of integral membrane proteins to melanosomes with substantially increased surface expression of Tyrp1, nearly complete loss of Tyrp2, and significant Vamp7 mislocalization. Knockdown of Myosin Vc in MNT-1 cells more than doubled the abundance of pigmented melanosomes but did not change the number of unpigmented melanosomes. Together the data demonstrate a novel role for Myosin Vc in melanosome biogenesis and secretion. [ABSTRACT FROM AUTHOR]

Published

2014

164. Mutations in the PCNA-binding domain of CDKN1C cause IMAGe syndrome.

Author

Arboleda, Valerie A, Lee, Hane, Parnaik, Rahul, Fleming, Alice, Banerjee, Abhik, Ferraz-de-Souza, Bruno, Délot, Emmanuèle C, Rodriguez-Fernandez, Imilce A, Braslavsky, Debora, Bergadá, Ignacio, Dell'Angelica, Esteban C, Nelson, Stanley F, Martinez-Agosto, Julian A, Achermann, John C, and Vilain, Eric

Subjects

*DEVELOPMENTAL disabilities, *LOCUS (Genetics), *CHROMOSOMES, *EXONS (Genetics), *BECKWITH-Wiedemann syndrome, *MISSENSE mutation, *NUCLEOTIDE sequence

Abstract

IMAGe syndrome (intrauterine growth restriction, metaphyseal dysplasia, adrenal hypoplasia congenita and genital anomalies) is an undergrowth developmental disorder with life-threatening consequences. An identity-by-descent analysis in a family with IMAGe syndrome identified a 17.2-Mb locus on chromosome 11p15 that segregated in the affected family members. Targeted exon array capture of the disease locus, followed by high-throughput genomic sequencing and validation by dideoxy sequencing, identified missense mutations in the imprinted gene CDKN1C (also known as P57KIP2) in two familial and four unrelated patients. A familial analysis showed an imprinted mode of inheritance in which only maternal transmission of the mutation resulted in IMAGe syndrome. CDKN1C inhibits cell-cycle progression, and we found that targeted expression of IMAGe-associated CDKN1C mutations in Drosophila caused severe eye growth defects compared to wild-type CDKN1C, suggesting a gain-of-function mechanism. All IMAGe-associated mutations clustered in the PCNA-binding domain of CDKN1C and resulted in loss of PCNA binding, distinguishing them from the mutations of CDKN1C that cause Beckwith-Wiedemann syndrome, an overgrowth syndrome. [ABSTRACT FROM AUTHOR]

Published

2012

165. Sex-dimorphic effects of biogenesis of lysosome-related organelles complex-1 deficiency on mouse perinatal brain development.

Author

Lee FY, Larimore J, Faundez V, Dell'Angelica EC, and Ghiani CA

Subjects

Animals, Animals, Newborn, Female, Male, Mice, Mice, Inbred C57BL, Mice, Mutant Strains, Brain growth & development, Brain metabolism, Intracellular Signaling Peptides and Proteins metabolism, Neurogenesis physiology, Sex Characteristics

Abstract

The function(s) of the Biogenesis of Lysosome-related Organelles Complex-1 (BLOC-1) during brain development is to date largely unknown. Here, we investigated how its absence alters the trajectory of postnatal brain development using as model the pallid mouse. Most of the defects observed early postnatally in the mutant mice were more prominent in males than in females and in the hippocampus. Male mutant mice, but not females, had smaller brains as compared to sex-matching wild types at postnatal day 1 (P1), this deficit was largely recovered by P14 and P45. An abnormal cytoarchitecture of the pyramidal cell layer of the hippocampus was observed in P1 pallid male, but not female, or juvenile mice (P45), along with severely decreased expression levels of the radial glial marker Glutamate-Aspartate Transporter. Transcriptomic analyses showed that the overall response to the lack of functional BLOC-1 was more pronounced in hippocampi at P1 than at P45 or in the cerebral cortex. These observations suggest that absence of BLOC-1 renders males more susceptible to perinatal brain maldevelopment and although most abnormalities appear to have been resolved in juvenile animals, still permanent defects may be present, resulting in faulty neuronal circuits, and contribute to previously reported cognitive and behavioral phenotypes in adult BLOC-1-deficient mice., (© 2020 Wiley Periodicals, Inc.)

Published

2021

166. Diagnostic utility of transcriptome sequencing for rare Mendelian diseases.

Author

Lee H, Huang AY, Wang LK, Yoon AJ, Renteria G, Eskin A, Signer RH, Dorrani N, Nieves-Rodriguez S, Wan J, Douine ED, Woods JD, Dell'Angelica EC, Fogel BL, Martin MG, Butte MJ, Parker NH, Wang RT, Shieh PB, Wong DA, Gallant N, Singh KE, Tavyev Asher YJ, Sinsheimer JS, Krakow D, Loo SK, Allard P, Papp JC, Palmer CGS, Martinez-Agosto JA, and Nelson SF

Subjects

Exome genetics, Genetic Diseases, Inborn genetics, Genetic Testing standards, Humans, Mutation genetics, RNA-Seq standards, Rare Diseases genetics, Sequence Analysis, DNA standards, Exome Sequencing standards, Whole Genome Sequencing standards, Genetic Diseases, Inborn diagnosis, Pathology, Molecular, Rare Diseases diagnosis, Transcriptome genetics

Abstract

Purpose: We investigated the value of transcriptome sequencing (RNAseq) in ascertaining the consequence of DNA variants on RNA transcripts to improve the diagnostic rate from exome or genome sequencing for undiagnosed Mendelian diseases spanning a wide spectrum of clinical indications., Methods: From 234 subjects referred to the Undiagnosed Diseases Network, University of California-Los Angeles clinical site between July 2014 and August 2018, 113 were enrolled for high likelihood of having rare undiagnosed, suspected genetic conditions despite thorough prior clinical evaluation. Exome or genome sequencing and RNAseq were performed, and RNAseq data was integrated with genome sequencing data for DNA variant interpretation genome-wide., Results: The molecular diagnostic rate by exome or genome sequencing was 31%. Integration of RNAseq with genome sequencing resulted in an additional seven cases with clear diagnosis of a known genetic disease. Thus, the overall molecular diagnostic rate was 38%, and 18% of all genetic diagnoses returned required RNAseq to determine variant causality., Conclusion: In this rare disease cohort with a wide spectrum of undiagnosed, suspected genetic conditions, RNAseq analysis increased the molecular diagnostic rate above that possible with genome sequencing analysis alone even without availability of the most appropriate tissue type to assess.

Published

2020

167. Sleep/Wake Disruption in a Mouse Model of BLOC-1 Deficiency.

Author

Lee FY, Wang HB, Hitchcock ON, Loh DH, Whittaker DS, Kim YS, Aiken A, Kokikian C, Dell'Angelica EC, Colwell CS, and Ghiani CA

Abstract

Mice lacking a functional Biogenesis of Lysosome-related Organelles Complex 1 (BLOC-1), such as those of the pallid line, display cognitive and behavioural impairments reminiscent of those presented by individuals with intellectual and developmental disabilities. Although disturbances in the sleep/wake cycle are commonly lamented by these individuals, the underlying mechanisms, including the possible role of the circadian timing system, are still unknown. In this paper, we have explored sleep/circadian malfunctions and underlying mechanisms in BLOC-1-deficient pallid mice. These mutants exhibited less sleep behaviour in the beginning of the resting phase than wild-type mice with a more broken sleeping pattern in normal light-dark conditions. Furthermore, the strength of the activity rhythms in the mutants were reduced with significantly more fragmentation and lower precision than in age-matched controls. These symptoms were accompanied by an abnormal preference for the open arm in the elevated plus maze in the day and poor performance in the novel object recognition at night. At the level of the central circadian clock (the suprachiasmatic nucleus, SCN), loss of BLOC-1 caused subtle morphological changes including a larger SCN and increased expression of the relative levels of the clock gene Per2 product during the day but did not affect the neuronal activity rhythms. In the hippocampus, the pallid mice presented with anomalies in the cytoarchitecture of the Dentate Gyrus granule cells, but not in CA1 pyramidal neurones, along with altered PER2 protein levels as well as reduced pCREB/tCREB ratio during the day. Our findings suggest that lack of BLOC-1 in mice disrupts the sleep/wake cycle and performance in behavioural tests associated with specific alterations in cytoarchitecture and protein expression.

Published

2018

168. Identification of Atg2 and ArfGAP1 as Candidate Genetic Modifiers of the Eye Pigmentation Phenotype of Adaptor Protein-3 (AP-3) Mutants in Drosophila melanogaster.

Author

Rodriguez-Fernandez IA and Dell'Angelica EC

Subjects

Animals, Autophagy, Autophagy-Related Proteins, Chromosome Mapping, DNA-(Apurinic or Apyrimidinic Site) Lyase physiology, Drosophila melanogaster physiology, Evolution, Molecular, Eye Proteins genetics, Eye Proteins physiology, Female, GTP Phosphohydrolases genetics, GTP Phosphohydrolases metabolism, GTP Phosphohydrolases physiology, GTPase-Activating Proteins genetics, Gene Deletion, Gene Expression Regulation, Developmental, Hemizygote, Lysosomes metabolism, Male, Models, Genetic, Mutation, Phenotype, Photoreceptor Cells, Invertebrate physiology, rab GTP-Binding Proteins, DNA-(Apurinic or Apyrimidinic Site) Lyase genetics, Drosophila Proteins genetics, Drosophila Proteins physiology, Drosophila melanogaster genetics, GTPase-Activating Proteins physiology, Pigmentation genetics

Abstract

The Adaptor Protein (AP)-3 complex is an evolutionary conserved, molecular sorting device that mediates the intracellular trafficking of proteins to lysosomes and related organelles. Genetic defects in AP-3 subunits lead to impaired biogenesis of lysosome-related organelles (LROs) such as mammalian melanosomes and insect eye pigment granules. In this work, we have performed a forward screening for genetic modifiers of AP-3 function in the fruit fly, Drosophila melanogaster. Specifically, we have tested collections of large multi-gene deletions--which together covered most of the autosomal chromosomes-to identify chromosomal regions that, when deleted in single copy, enhanced or ameliorated the eye pigmentation phenotype of two independent AP-3 subunit mutants. Fine-mapping led us to define two non-overlapping, relatively small critical regions within fly chromosome 3. The first critical region included the Atg2 gene, which encodes a conserved protein involved in autophagy. Loss of one functional copy of Atg2 ameliorated the pigmentation defects of mutants in AP-3 subunits as well as in two other genes previously implicated in LRO biogenesis, namely Blos1 and lightoid, and even increased the eye pigment content of wild-type flies. The second critical region included the ArfGAP1 gene, which encodes a conserved GTPase-activating protein with specificity towards GTPases of the Arf family. Loss of a single functional copy of the ArfGAP1 gene ameliorated the pigmentation phenotype of AP-3 mutants but did not to modify the eye pigmentation of wild-type flies or mutants in Blos1 or lightoid. Strikingly, loss of the second functional copy of the gene did not modify the phenotype of AP-3 mutants any further but elicited early lethality in males and abnormal eye morphology when combined with mutations in Blos1 and lightoid, respectively. These results provide genetic evidence for new functional links connecting the machinery for biogenesis of LROs with molecules implicated in autophagy and small GTPase regulation.

Published

2015