Literature DB >> 17062724

The Slc35d3 gene, encoding an orphan nucleotide sugar transporter, regulates platelet-dense granules.

Sreenivasulu Chintala1, Jian Tan, Rashi Gautam, Michael E Rusiniak, Xiaoli Guo, Wei Li, William A Gahl, Marjan Huizing, Richard A Spritz, Saunie Hutton, Edward K Novak, Richard T Swank.   

Abstract

Platelet dense granules are lysosome-related organelles which contain high concentrations of several biologically important low-molecular-weight molecules. These include calcium, serotonin, adenine nucleotides, pyrophosphate, and polyphosphate, which are necessary for normal blood hemostasis. The synthesis of dense granules and other lysosome-related organelles is defective in inherited diseases such as Hermansky-Pudlak syndrome (HPS) and Chediak-Higashi syndrome (CHS). HPS and CHS mutations in 8 human and at least 16 murine genes have been identified. Previous studies produced contradictory findings for the function of the murine ashen (Rab27a) gene in platelet-dense granules. We have used a positional cloning approach with one line of ashen mutants to establish that a new mutation in a second gene, Slc35d3, on mouse chromosome 10 is the basis of this discrepancy. The platelet-dense granule defect is rescued in BAC transgenic mice containing the normal Slc35d3 gene. Thus, Slc35d3, an orphan member of a nucleotide sugar transporter family, specifically regulates the contents of platelet-dense granules. Unlike HPS or CHS genes, it has no apparent effect on other lysosome-related organelles such as melanosomes or lysosomes. The ash-Roswell mouse mutant is an appropriate model for human congenital-isolated delta-storage pool deficiency.

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Year:  2006        PMID: 17062724      PMCID: PMC1794067          DOI: 10.1182/blood-2006-08-040196

Source DB:  PubMed          Journal:  Blood        ISSN: 0006-4971            Impact factor:   22.113


  37 in total

Review 1.  The platelet release reaction: granules' constituents, secretion and functions.

Authors:  F Rendu; B Brohard-Bohn
Journal:  Platelets       Date:  2001-08       Impact factor: 3.862

2.  Mutations in RAB27A cause Griscelli syndrome associated with haemophagocytic syndrome.

Authors:  G Ménasché; E Pastural; J Feldmann; S Certain; F Ersoy; S Dupuis; N Wulffraat; D Bianchi; A Fischer; F Le Deist; G de Saint Basile
Journal:  Nat Genet       Date:  2000-06       Impact factor: 38.330

3.  A mutation in Rab27a causes the vesicle transport defects observed in ashen mice.

Authors:  S M Wilson; R Yip; D A Swing; T N O'Sullivan; Y Zhang; E K Novak; R T Swank; L B Russell; N G Copeland; N A Jenkins
Journal:  Proc Natl Acad Sci U S A       Date:  2000-07-05       Impact factor: 11.205

4.  The gene mutated in cocoa mice, carrying a defect of organelle biogenesis, is a homologue of the human Hermansky-Pudlak syndrome-3 gene.

Authors:  T Suzuki; W Li; Q Zhang; E K Novak; E V Sviderskaya; A Wilson; D C Bennett; B A Roe; R T Swank; R A Spritz
Journal:  Genomics       Date:  2001-11       Impact factor: 5.736

5.  Hermansky-Pudlak syndrome is caused by mutations in HPS4, the human homolog of the mouse light-ear gene.

Authors:  Tamio Suzuki; Wei Li; Qing Zhang; Amna Karim; Edward K Novak; Elena V Sviderskaya; Simon P Hill; Dorothy C Bennett; Alex V Levin; H Karel Nieuwenhuis; Chin-To Fong; Claudio Castellan; Bianca Miterski; Richard T Swank; Richard A Spritz
Journal:  Nat Genet       Date:  2002-02-11       Impact factor: 38.330

Review 6.  Disorders of vesicles of lysosomal lineage: the Hermansky-Pudlak syndromes.

Authors:  M Huizing; W A Gahl
Journal:  Curr Mol Med       Date:  2002-08       Impact factor: 2.222

7.  Functional redundancy of Rab27 proteins and the pathogenesis of Griscelli syndrome.

Authors:  Duarte C Barral; José S Ramalho; Ross Anders; Alistair N Hume; Holly J Knapton; Tanya Tolmachova; Lucy M Collinson; David Goulding; Kalwant S Authi; Miguel C Seabra
Journal:  J Clin Invest       Date:  2002-07       Impact factor: 14.808

Review 8.  Human and mouse disorders of pigmentation.

Authors:  Richard A Spritz; Pei Wen Chiang; Naoki Oiso; Asem Alkhateeb
Journal:  Curr Opin Genet Dev       Date:  2003-06       Impact factor: 5.578

9.  The regulation of platelet-dense granules by Rab27a in the ashen mouse, a model of Hermansky-Pudlak and Griscelli syndromes, is granule-specific and dependent on genetic background.

Authors:  Edward K Novak; Rashi Gautam; Madonna Reddington; Lucy M Collinson; Neal G Copeland; Nancy A Jenkins; Michael P McGarry; Richard T Swank
Journal:  Blood       Date:  2002-07-01       Impact factor: 22.113

10.  Mutational data integration in gene-oriented files of the Hermansky-Pudlak Syndrome database.

Authors:  Wei Li; Min He; Helin Zhou; Jonathan W Bourne; Ping Liang
Journal:  Hum Mutat       Date:  2006-05       Impact factor: 4.878
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  19 in total

1.  MKL1 and MKL2 play redundant and crucial roles in megakaryocyte maturation and platelet formation.

Authors:  Elenoe C Smith; Jonathan N Thon; Matthew T Devine; Sharon Lin; Vincent P Schulz; Yanwen Guo; Stephanie A Massaro; Stephanie Halene; Patrick Gallagher; Joseph E Italiano; Diane S Krause
Journal:  Blood       Date:  2012-07-17       Impact factor: 22.113

Review 2.  Storage pool diseases illuminate platelet dense granule biogenesis.

Authors:  Andrea L Ambrosio; Santiago M Di Pietro
Journal:  Platelets       Date:  2016-11-16       Impact factor: 3.862

3.  SLC35D3 delivery from megakaryocyte early endosomes is required for platelet dense granule biogenesis and is differentially defective in Hermansky-Pudlak syndrome models.

Authors:  Ronghua Meng; Yuhuan Wang; Yu Yao; Zhe Zhang; Dawn C Harper; Harry F G Heijnen; Anand Sitaram; Wei Li; Graça Raposo; Mitchell J Weiss; Mortimer Poncz; Michael S Marks
Journal:  Blood       Date:  2012-05-18       Impact factor: 22.113

4.  A zinc transporter, transmembrane protein 163, is critical for the biogenesis of platelet dense granules.

Authors:  Yefeng Yuan; Teng Liu; Xiahe Huang; Yuanying Chen; Weilin Zhang; Ting Li; Lin Yang; Quan Chen; Yingchun Wang; Aihua Wei; Wei Li
Journal:  Blood       Date:  2021-04-01       Impact factor: 22.113

5.  SLC35D3 increases autophagic activity in midbrain dopaminergic neurons by enhancing BECN1-ATG14-PIK3C3 complex formation.

Authors:  Zong-Bo Wei; Ye-Feng Yuan; Florence Jaouen; Mei-Sheng Ma; Chan-Juan Hao; Zhe Zhang; Quan Chen; Zengqiang Yuan; Li Yu; Corinne Beurrier; Wei Li
Journal:  Autophagy       Date:  2016-05-12       Impact factor: 16.016

6.  Global gene expression profiling of somatic motor neuron populations with different vulnerability identify molecules and pathways of degeneration and protection.

Authors:  Eva Hedlund; Martin Karlsson; Teresia Osborn; Wesley Ludwig; Ole Isacson
Journal:  Brain       Date:  2010-08       Impact factor: 13.501

7.  The Vps33a gene regulates behavior and cerebellar Purkinje cell number.

Authors:  Sreenivasulu Chintala; Edward K Novak; Joseph A Spernyak; Richard Mazurchuk; German Torres; Suchith Patel; Kristie Busch; Beth A Meeder; Judith M Horowitz; Mary M Vaughan; Richard T Swank
Journal:  Brain Res       Date:  2009-02-27       Impact factor: 3.252

8.  Rab27a and MyRIP regulate the amount and multimeric state of VWF released from endothelial cells.

Authors:  Thomas D Nightingale; Krupa Pattni; Alistair N Hume; Miguel C Seabra; Daniel F Cutler
Journal:  Blood       Date:  2009-03-06       Impact factor: 22.113

9.  Rab27b regulates number and secretion of platelet dense granules.

Authors:  Tanya Tolmachova; Magnus Abrink; Clare E Futter; Kalwant S Authi; Miguel C Seabra
Journal:  Proc Natl Acad Sci U S A       Date:  2007-03-23       Impact factor: 11.205

10.  SLC45A2 protein stability and regulation of melanosome pH determine melanocyte pigmentation.

Authors:  Linh Le; Iliana E Escobar; Tina Ho; Ariel J Lefkovith; Emily Latteri; Kirk D Haltaufderhyde; Megan K Dennis; Lynn Plowright; Elena V Sviderskaya; Dorothy C Bennett; Elena Oancea; Michael S Marks
Journal:  Mol Biol Cell       Date:  2020-09-23       Impact factor: 4.138
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