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Biogenesis of lysosome-related organelles complex 1

April 16, 2024

BLOC-1 or biogenesis of lysosome-related organelles complex 1 is a ubiquitously expressed multisubunit protein complex in a group of complexes that also includes BLOC-2 and BLOC-3. BLOC-1 is required for normal biogenesis of specialized organelles of the endosomal-lysosomal system, such as melanosomes and platelet dense granules. These organelles are called LROs (lysosome-related organelles) which are apparent in specific cell-types, such as melanocytes. The importance of BLOC-1 in membrane trafficking appears to extend beyond such LROs, as it has demonstrated roles in normal protein-sorting, normal membrane biogenesis, as well as vesicular trafficking. Thus, BLOC-1 is multi-purposed, with adaptable function depending on both organism and cell-type.

Mutations in all BLOC complexes lead to diseased states characterized by Hermansky-Pudlak Syndrome (HPS), a pigmentation disorder subdivided into multiple types depending on the mutation, highlighting the role of BLOC-1 in proper LRO-function. BLOC-1 mutations also are thought to be linked to schizophrenia, and BLOC-1 dysfunction in the brain has important ramifications in neurotransmission.[1][2][3][4] Much effort has been given to uncovering the molecular mechanisms of BLOC-1 function to understand its role in these diseases.

Ultracentrifugation coupled with electron microscopy demonstrated that BLOC-1 has 8 subunits (pallidin, cappuccino, dysbindin, Snapin, Muted, BLOS1, BLOS2, and BLOS3) that are linked linearly to form a complex of roughly 300 Angstrom in length and 30 Angstrom in diameter.[5] Bacterial recombination also demonstrated heterotrimeric subcomplexes containing pallidin, cappucinno, and BLOS1 as well as dysbindin, Snapin, and BLOS-2 as important intermediate structures.[5] These subcomplexes may explain different functional outcomes observed by altering different BLOC-1 subunits.[2] Furthermore, dynamic bending of the complex as much as 45 degrees indicates flexibility is likely linked to proper BLOC-1 function.[5]

Within the endomembrane system, BLOC-1 acts at the early endosome, as witnessed in electron microscopy experiments, where it helps coordinate protein-sorting of LAMPS (lysosome-associate membrane proteins).[6] Multiple studies recapitulate an association with the adaptor complex AP-3, a protein involved in vesicular trafficking of cargo from the early endosome to lysosomal compartments.[6][7] BLOC-1 demonstrates physical association with AP-3 and BLOC-2 upon immunoprecipitation, although not to both complexes at the same time.[6] Indeed, BLOC-1 functions in an AP-3 dependent route to sort CD63 (LAMP3) and Tyrp1.[6] Furthermore, another study suggests an AP-3 dependent route of BLOC-1 also facilitates trafficking of LAMP1 and Vamp7-T1, a SNARE protein.[7] An AP-3-independent, BLOC-2-dependent route of BLOC-1 sorting of Tyrp1 is also observed.[6] Therefore, BLOC-1 appears to have multifaceted trafficking behavior. Indeed, AP-3 knockout mice maintain ability to deliver Tyrp1 to melanosomes, supporting existence of multiple BLOC-1 trafficking pathways.[8] Evidence, however, suggests BLOC-2 may directly or indirectly intersect BLOC-1 trafficking downstream of early endosomes; BLOC-1 deficiency promotes missorted Tyrp1 at the plasma membrane, while BLOC-2 deficiency promotes Tyrp1 concentration at intermediate endosomal compartments.[8] These studies demonstrate that BLOC-1 facilitates protein transport to lysosomal compartments, such as melanosomes, via multiple routes, although the exact functional association with BLOC-2 is unclear.

The majority of studies have focused on mammalian BLOC-1, presumably because of its association with multiple disease states in humans. Still, it is clear BLOC-1 has an evolutionarily conserved importance in trafficking because its yeast homolog, which contains Vab2, has been proposed to modulate Rab5 (Vps21), which is essential for its membrane localization, by acting as a receptor on early endosomes for Rab5-GAP Msb3.[9] Although this study purports the function of BLOC-1 on early endosomes, it has recently been argued that yeast do not contain an early endosome.[10] In light of these newer findings, it appears, BLOC-1 may actually act at the TGN in yeast. Nevertheless, BLOC-1 is important for proper endomembrane function in both lower and higher order eukaryotes.

In mammalian cells, most studies have focused on the ability of BLOC-1 to sort proteins. However, recent findings indicate that BLOC-1 has more complex functions in membrane biogenesis by associating with the cytoskeleton. Recycling endosome biogenesis is mediated by BLOC-1 as a hub for cytoskeletal activity.[11] The kinesin KIF13A and actin machinery (AnxA2 and Arp2/3) appear to interact with BLOC-1 to generate recycling endosomes/recycling endosome tubules where microtubule action may lengthen tubules and microfilament action may stabilize or excise tubules.[11] The BLOC-1 subunit pallidin associates with synaptic cytoskeletal components in Drosophila melanogaster neurons.[2] Thus, BLOC-1 appears to engage in both protein sorting as well as membrane biogenesis via diverse mechanisms. Further study will be required to synthesize any of these molecular interactions into possible unified mechanisms.

Studies of BLOC-1 in the nervous system have begun to link numerous molecular and cellular mechanisms to its proposed contribution to schizophrenia. Knock-down studies of the dysbindin gene DTNBP1 via siRNA demonstrated that the dysbindin subunit is integral for the signaling and recycling of the D2 receptor (DRD2) but not the D1 receptor.[1] BLOC-1 mutations in dysbindin therefore can alter dopaminergic signaling in the brain which may confer symptoms of schizophrenia.[1] These results appear to be relevant to the whole complex as the majority of expressed dysbindin localized to the BLOC-1 complex in the mouse brain.[3] Furthermore, proper neurite extension appears to be regulated by BLOC-1, which may have molecular links to the ability of BLOC-1 to physically associate in vitro with SNARE proteins such as SNAP-25, SNAP-17, and syntaxin 13.[3] This interaction with SNAREs could aid in membrane trafficking toward neurite extensions.[3] Studies in Drosophila melanogaster indicate pallidin is non-essential for synaptic vesicle homeostasis or anatomy but is essential under conditions of increased neuronal signaling to maintain vesicular trafficking from endosomes via recycling mechanisms.[2] The effects of a non-functional Bloc1s6 gene (encoding for pallidin) on the metabolome of the post-natal mouse hippocampus were explored using LC-MS, revealing altered levels of a variety of metabolites.[4] Particularly intriguing effects include an increase in glutamate (and its precursor glutamine), an excitatory neurotransmitter linked to schizophrenia, as well as decreases in the neurotransmitters phenylalanine and tryptophan.[4] Overall, modifications in the metabolome of these mice extend to nucleobase molecules and lysophospholipids as well, implicating further dysregulation effects of BLOC-1 deficiencies to plausible molecular contributions of schizophrenia.[4]

Complex components edit

The identified protein subunits of BLOC-1 include:

References edit

  1. ^ a b c Iizuka, Yukihiko; Sei, Yoshitatsu; Weinberger, Daniel; Straub, Richard (7 November 2007). "Evidence That the BLOC-1 Protein Dysbindin Modulates Dopamine D2 Receptor Internalization and Signaling But Not D1 Internalization". The Journal of Neuroscience. 27 (45): 12390–12395. doi:10.1523/JNEUROSCI.1689-07.2007. PMC 6673263. PMID 17989303.
  2. ^ a b c d Chen, Xun; Ma, Wenpei; Zhang, Shizing; Paluch, Jeremy; Guo, Wanlin; Dickman, Dion (30 January 2017). "The BLOC-1 Subunit Pallidin Facilitates Activity-Dependent Synaptic Vesicle Recycling". eNeuro. 30 (1): ENEURO.0335–16.2017. doi:10.1523/ENEURO.0335-16.2017. PMC 5356223. PMID 28317021.
  3. ^ a b c d Ghiani, CA; Starcevic, M; Rodriguez-Fernandez, IA; Nazarian, R; Cheli, VT; Chan, LN; Malvar, JS; de Vellis, J; Sabatti, C; Dell'Angelica, EC (23 June 2009). "The dysbindin-containing complex (BLOC-1) in brain: developmental regulation, interaction with SNARE proteins and role in neurite outgrowth". Molecular Psychiatry. 15 (2): 204–215. doi:10.1038/mp.2009.58. PMC 2811213. PMID 19546860.
  4. ^ a b c d van Liempd, S.M.; Cabrera, D.; Lee, F.Y.; González, E.; Dell'Angelica, E.C.; Ghiani, C.A.; Falcon-Perez, J.M. (12 July 2017). "BLOC-1 deficiency causes alterations in amino acid profile and in phospholipid and adenosine metabolism in the postnatal mouse hippocampus". Scientific Reports. 7 (1): 5231. Bibcode:2017NatSR...7.5231V. doi:10.1038/s41598-017-05465-z. PMC 5507893. PMID 28701731.
  5. ^ a b c Ho Lee, Hyung; Nemecek, Daniel; Schindler, Christina; Smith, William; Ghirlando, Rodolfo; Steven, Alasdair; Bonifacino, Juan; Hurley, James (27 December 2011). "Assembly and Architecture of Biogenesis of Lysosome-related Organelles Complex-1 (BLOC-1)". The Journal of Biological Chemistry. 287 (8): 5882–5890. doi:10.1074/jbc.M111.325746. PMC 3285357. PMID 22203680.
  6. ^ a b c d e Di Pietro, Santiago; Falcón-Pérez, Juan; Tenza, Danièle; Setty, Subba; Marks, Michael; Raposo, Graça; Dell'Angelica, Esteban (September 2006). "BLOC-1 Interacts with BLOC-2 and the AP-3 Complex to Facilitate Protein Trafficking on Endosomes". Molecular Biology of the Cell. 17 (9): 4027–4038. doi:10.1091/mbc.E06-05-0379. PMC 1593172. PMID 16837549.
  7. ^ a b Salazar, G.; Craige, B.; Styers, M.L.; Newell-Litwa, K.A.; Doucette, M.M.; Wainer, B.H.; Falcon-Perez, J.M.; Dell-Angelica, E.C.; Peden, A.A.; Werner, E.; Faundez, V. (September 2006). "BLOC-1 Complex Deficiency Alters the Targeting of Adaptor Protein Complex-3 Cargoes". Molecular Biology of the Cell. 17 (9): 4014–4026. doi:10.1091/mbc.E06-02-0103. PMC 1556383. PMID 16760431.
  8. ^ a b Rao Gangi Setty, Subba; Tenza, Danièle; Truschel, Steven; Chou, Evelyn; Sviderskaya, Elena; Theos, Alexander; Lamoreux, M. Lynn; Di Pietro, Santiago; Starcevic, Marta; Bennett, Dorothy; Dell'Angelica, Esteban; Raposo, Graça; Marks, Michael (March 2007). "BLOC-1 Is Required for Cargo-specific Sorting from Vacuolar Early Endosomes toward Lysosome-related Organelles". Molecular Biology of the Cell. 18 (3): 768–780. doi:10.1091/mbc.E06-12-1066. PMC 1805088. PMID 17182842.
  9. ^ John Peter, Arun; Lachmann, Jens; Rana, Meenakshi; Bunge, Madeleine; Cabrera, Margarita; Ungermann, Christian (1 April 2013). "The BLOC-1 complex promotes endosomal maturation by recruiting the Rab5 GTPase-activating protein Msb3". The Journal of Cell Biology. 201 (1): 97–111. doi:10.1083/jcb.201210038. PMC 3613695. PMID 23547030.
  10. ^ Day, Kasey; Casler, Jason; Glick, Ben (8 January 2018). "Budding Yeast Has a Minimal Endomembrane System". Developmental Cell. 44 (1): 56–72. doi:10.1016/j.devcel.2017.12.014. PMC 5765772. PMID 29316441.
  11. ^ a b Delevoye, C.; Heiligenstein, X.; Ripoll, L.; Gilles-Marsens, F.; Dennis, M.K.; Linares, R.A.; Derman, L.; Gokhale, A.; Morel, E.; Faundez, V.; Marks, M.S.; Raposo, G. (11 January 2016). "BLOC-1 Brings Together the Actin and Microtubule Cytoskeletons to Generate Recycling Endosomes". Current Biology. 26 (1): 1–13. doi:10.1016/j.cub.2015.11.020. PMC 4713302. PMID 26725201.

April 16, 2024
biogenesis, lysosome, related, organelles, complex, bloc, biogenesis, lysosome, related, organelles, complex, ubiquitously, expressed, multisubunit, protein, complex, group, complexes, that, also, includes, bloc, bloc, bloc, required, normal, biogenesis, speci. BLOC 1 or biogenesis of lysosome related organelles complex 1 is a ubiquitously expressed multisubunit protein complex in a group of complexes that also includes BLOC 2 and BLOC 3 BLOC 1 is required for normal biogenesis of specialized organelles of the endosomal lysosomal system such as melanosomes and platelet dense granules These organelles are called LROs lysosome related organelles which are apparent in specific cell types such as melanocytes The importance of BLOC 1 in membrane trafficking appears to extend beyond such LROs as it has demonstrated roles in normal protein sorting normal membrane biogenesis as well as vesicular trafficking Thus BLOC 1 is multi purposed with adaptable function depending on both organism and cell type Mutations in all BLOC complexes lead to diseased states characterized by Hermansky Pudlak Syndrome HPS a pigmentation disorder subdivided into multiple types depending on the mutation highlighting the role of BLOC 1 in proper LRO function BLOC 1 mutations also are thought to be linked to schizophrenia and BLOC 1 dysfunction in the brain has important ramifications in neurotransmission 1 2 3 4 Much effort has been given to uncovering the molecular mechanisms of BLOC 1 function to understand its role in these diseases Ultracentrifugation coupled with electron microscopy demonstrated that BLOC 1 has 8 subunits pallidin cappuccino dysbindin Snapin Muted BLOS1 BLOS2 and BLOS3 that are linked linearly to form a complex of roughly 300 Angstrom in length and 30 Angstrom in diameter 5 Bacterial recombination also demonstrated heterotrimeric subcomplexes containing pallidin cappucinno and BLOS1 as well as dysbindin Snapin and BLOS 2 as important intermediate structures 5 These subcomplexes may explain different functional outcomes observed by altering different BLOC 1 subunits 2 Furthermore dynamic bending of the complex as much as 45 degrees indicates flexibility is likely linked to proper BLOC 1 function 5 Within the endomembrane system BLOC 1 acts at the early endosome as witnessed in electron microscopy experiments where it helps coordinate protein sorting of LAMPS lysosome associate membrane proteins 6 Multiple studies recapitulate an association with the adaptor complex AP 3 a protein involved in vesicular trafficking of cargo from the early endosome to lysosomal compartments 6 7 BLOC 1 demonstrates physical association with AP 3 and BLOC 2 upon immunoprecipitation although not to both complexes at the same time 6 Indeed BLOC 1 functions in an AP 3 dependent route to sort CD63 LAMP3 and Tyrp1 6 Furthermore another study suggests an AP 3 dependent route of BLOC 1 also facilitates trafficking of LAMP1 and Vamp7 T1 a SNARE protein 7 An AP 3 independent BLOC 2 dependent route of BLOC 1 sorting of Tyrp1 is also observed 6 Therefore BLOC 1 appears to have multifaceted trafficking behavior Indeed AP 3 knockout mice maintain ability to deliver Tyrp1 to melanosomes supporting existence of multiple BLOC 1 trafficking pathways 8 Evidence however suggests BLOC 2 may directly or indirectly intersect BLOC 1 trafficking downstream of early endosomes BLOC 1 deficiency promotes missorted Tyrp1 at the plasma membrane while BLOC 2 deficiency promotes Tyrp1 concentration at intermediate endosomal compartments 8 These studies demonstrate that BLOC 1 facilitates protein transport to lysosomal compartments such as melanosomes via multiple routes although the exact functional association with BLOC 2 is unclear The majority of studies have focused on mammalian BLOC 1 presumably because of its association with multiple disease states in humans Still it is clear BLOC 1 has an evolutionarily conserved importance in trafficking because its yeast homolog which contains Vab2 has been proposed to modulate Rab5 Vps21 which is essential for its membrane localization by acting as a receptor on early endosomes for Rab5 GAP Msb3 9 Although this study purports the function of BLOC 1 on early endosomes it has recently been argued that yeast do not contain an early endosome 10 In light of these newer findings it appears BLOC 1 may actually act at the TGN in yeast Nevertheless BLOC 1 is important for proper endomembrane function in both lower and higher order eukaryotes In mammalian cells most studies have focused on the ability of BLOC 1 to sort proteins However recent findings indicate that BLOC 1 has more complex functions in membrane biogenesis by associating with the cytoskeleton Recycling endosome biogenesis is mediated by BLOC 1 as a hub for cytoskeletal activity 11 The kinesin KIF13A and actin machinery AnxA2 and Arp2 3 appear to interact with BLOC 1 to generate recycling endosomes recycling endosome tubules where microtubule action may lengthen tubules and microfilament action may stabilize or excise tubules 11 The BLOC 1 subunit pallidin associates with synaptic cytoskeletal components in Drosophila melanogaster neurons 2 Thus BLOC 1 appears to engage in both protein sorting as well as membrane biogenesis via diverse mechanisms Further study will be required to synthesize any of these molecular interactions into possible unified mechanisms Studies of BLOC 1 in the nervous system have begun to link numerous molecular and cellular mechanisms to its proposed contribution to schizophrenia Knock down studies of the dysbindin gene DTNBP1 via siRNA demonstrated that the dysbindin subunit is integral for the signaling and recycling of the D2 receptor DRD2 but not the D1 receptor 1 BLOC 1 mutations in dysbindin therefore can alter dopaminergic signaling in the brain which may confer symptoms of schizophrenia 1 These results appear to be relevant to the whole complex as the majority of expressed dysbindin localized to the BLOC 1 complex in the mouse brain 3 Furthermore proper neurite extension appears to be regulated by BLOC 1 which may have molecular links to the ability of BLOC 1 to physically associate in vitro with SNARE proteins such as SNAP 25 SNAP 17 and syntaxin 13 3 This interaction with SNAREs could aid in membrane trafficking toward neurite extensions 3 Studies in Drosophila melanogaster indicate pallidin is non essential for synaptic vesicle homeostasis or anatomy but is essential under conditions of increased neuronal signaling to maintain vesicular trafficking from endosomes via recycling mechanisms 2 The effects of a non functional Bloc1s6 gene encoding for pallidin on the metabolome of the post natal mouse hippocampus were explored using LC MS revealing altered levels of a variety of metabolites 4 Particularly intriguing effects include an increase in glutamate and its precursor glutamine an excitatory neurotransmitter linked to schizophrenia as well as decreases in the neurotransmitters phenylalanine and tryptophan 4 Overall modifications in the metabolome of these mice extend to nucleobase molecules and lysophospholipids as well implicating further dysregulation effects of BLOC 1 deficiencies to plausible molecular contributions of schizophrenia 4 Complex components editThe identified protein subunits of BLOC 1 include pallidin muted protein dysbindin cappuccino protein Snapin BLOS1 BLOS2 BLOS3References edit a b c Iizuka Yukihiko Sei Yoshitatsu Weinberger Daniel Straub Richard 7 November 2007 Evidence That the BLOC 1 Protein Dysbindin Modulates Dopamine D2 Receptor Internalization and Signaling But Not D1 Internalization The Journal of Neuroscience 27 45 12390 12395 doi 10 1523 JNEUROSCI 1689 07 2007 PMC 6673263 PMID 17989303 a b c d Chen Xun Ma Wenpei Zhang Shizing Paluch Jeremy Guo Wanlin Dickman Dion 30 January 2017 The BLOC 1 Subunit Pallidin Facilitates Activity Dependent Synaptic Vesicle Recycling eNeuro 30 1 ENEURO 0335 16 2017 doi 10 1523 ENEURO 0335 16 2017 PMC 5356223 PMID 28317021 a b c d Ghiani CA Starcevic M Rodriguez Fernandez IA Nazarian R Cheli VT Chan LN Malvar JS de Vellis J Sabatti C Dell Angelica EC 23 June 2009 The dysbindin containing complex BLOC 1 in brain developmental regulation interaction with SNARE proteins and role in neurite outgrowth Molecular Psychiatry 15 2 204 215 doi 10 1038 mp 2009 58 PMC 2811213 PMID 19546860 a b c d van Liempd S M Cabrera D Lee F Y Gonzalez E Dell Angelica E C Ghiani C A Falcon Perez J M 12 July 2017 BLOC 1 deficiency causes alterations in amino acid profile and in phospholipid and adenosine metabolism in the postnatal mouse hippocampus Scientific Reports 7 1 5231 Bibcode 2017NatSR 7 5231V doi 10 1038 s41598 017 05465 z PMC 5507893 PMID 28701731 a b c Ho Lee Hyung Nemecek Daniel Schindler Christina Smith William Ghirlando Rodolfo Steven Alasdair Bonifacino Juan Hurley James 27 December 2011 Assembly and Architecture of Biogenesis of Lysosome related Organelles Complex 1 BLOC 1 The Journal of Biological Chemistry 287 8 5882 5890 doi 10 1074 jbc M111 325746 PMC 3285357 PMID 22203680 a b c d e Di Pietro Santiago Falcon Perez Juan Tenza Daniele Setty Subba Marks Michael Raposo Graca Dell Angelica Esteban September 2006 BLOC 1 Interacts with BLOC 2 and the AP 3 Complex to Facilitate Protein Trafficking on Endosomes Molecular Biology of the Cell 17 9 4027 4038 doi 10 1091 mbc E06 05 0379 PMC 1593172 PMID 16837549 a b Salazar G Craige B Styers M L Newell Litwa K A Doucette M M Wainer B H Falcon Perez J M Dell Angelica E C Peden A A Werner E Faundez V September 2006 BLOC 1 Complex Deficiency Alters the Targeting of Adaptor Protein Complex 3 Cargoes Molecular Biology of the Cell 17 9 4014 4026 doi 10 1091 mbc E06 02 0103 PMC 1556383 PMID 16760431 a b Rao Gangi Setty Subba Tenza Daniele Truschel Steven Chou Evelyn Sviderskaya Elena Theos Alexander Lamoreux M Lynn Di Pietro Santiago Starcevic Marta Bennett Dorothy Dell Angelica Esteban Raposo Graca Marks Michael March 2007 BLOC 1 Is Required for Cargo specific Sorting from Vacuolar Early Endosomes toward Lysosome related Organelles Molecular Biology of the Cell 18 3 768 780 doi 10 1091 mbc E06 12 1066 PMC 1805088 PMID 17182842 John Peter Arun Lachmann Jens Rana Meenakshi Bunge Madeleine Cabrera Margarita Ungermann Christian 1 April 2013 The BLOC 1 complex promotes endosomal maturation by recruiting the Rab5 GTPase activating protein Msb3 The Journal of Cell Biology 201 1 97 111 doi 10 1083 jcb 201210038 PMC 3613695 PMID 23547030 Day Kasey Casler Jason Glick Ben 8 January 2018 Budding Yeast Has a Minimal Endomembrane System Developmental Cell 44 1 56 72 doi 10 1016 j devcel 2017 12 014 PMC 5765772 PMID 29316441 a b Delevoye C Heiligenstein X Ripoll L Gilles Marsens F Dennis M K Linares R A Derman L Gokhale A Morel E Faundez V Marks M S Raposo G 11 January 2016 BLOC 1 Brings Together the Actin and Microtubule Cytoskeletons to Generate Recycling Endosomes Current Biology 26 1 1 13 doi 10 1016 j cub 2015 11 020 PMC 4713302 PMID 26725201 Retrieved from https en wikipedia org w index php title Biogenesis of lysosome related organelles complex 1 amp oldid 1138929287, wikipedia, wiki, book, books, library,

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