Tertiary structure of the SNX9 which gives an idea of the tertiary structure of the SNX8, since primary structure shares 20% sequence identity and 0.3 sequence similarity with SNX8 primary structure.[1]

The SNX8 is a sorting nexin protein involved in intracellular molecular traffic from the early endosomes to the TGN. It is suggested that it acts as an adaptor protein in events related to immune response and cholesterol regulation, for example. As a protein of the SNXs family, the SNX8 is formed of 465 aminoacids and presents a BAR-domain and a PX-domain which are very relevant in relation to its functions. Furthermore, SNX8 study is motivated by its medical significance in relation to diseases such as Alzheimer's Disease, cancer, neurodevelopmental malformations and to its role in fighting against viral infections.

Structure

Sorting nexins (SNXs)

SNX8 belongs to the sorting nexin family of proteins, which mainly contain two functional membrane-binding that allow SNXs to have different roles in endosomal sorting and protein trafficking thanks to its membrane curvature ability.[2] To begin with, SNX-PX is a distinct phosphoinositide (PI)-binding domain. The preferential interaction of this domain with membrane lipids makes the main function of SNX-PX the targeting of proteins to phosphatidylinositol-3-phosphate (PI(3)P) to endosomes. On the other hand, the BAR (Bin/amphiphysin/Rvs) domain is a key regulator of phosphoinositide-mediated, tubular-based endosomal sorting. Accordingly, this domain also dimerizes to sense, stabilize and induce membrane curvature. The SNX-BAR proteins that contain both domains are a part of phosphoinositide-enriched, high-curvature tubular micro-domains of the endo-lysosomal network.[3]

The mammalian genome contains 12 genes coding for SNX-BAR proteins (SNX1, SNX2, SNX4, SNX9, SNX18, SNX32 and SNX33). Other domains, such as PDZ (postsynaptic density protein-95, discs-large, zona occludens-1), SH3 (Src homology 3) and RA (Ras-associated), are involved in protein-protein interactions.

SNX8

SNX8 primary structure highlighting relevant domains and amino acids.[2][4][5]

The SNX8 protein, even though is very similar to the other sorting nexins, presents a domain structure which resembles the most to SNX1's and SNX9's; for this reason, although its terciary structure remains unknown, it theoretically resembles that of SNX9 shown in the model above. Overall, the SNX8 protein is integrated by one unique peptide chain that has 465 amino acids with a molecular mass of 52.569 Da.[2]

PX Domain-containing N-terminus

SNX8 contains a PX domain in its N-terminus, which is located between amino acids 71 and 181. A homology domain with yeast's PX domain is localized between amino acids 75 and 178 within this same domain. As it is a phosphoinositide-binding domain, it is important to highlight amino acids 109, 135 and 148 as residues directly related to phosphatidylinositol 3-phosphate since being specific binding sites, constituting a phosphoinositid binding site with a span of 40 amino acids.[2][4] Furthermore, it includes a pair of phosphorylable tyrosines in positions 95 and 126 that are key in its function in the IFNγ-triggered IKKβ-mediated noncanonical signaling pathway.[5] Overall, the PX domain main function is to target SNX8 mainly to early endosomes and other membranes rich in phosphatidylinositol 3-phosphate phospholipids.[6]

BAR Domain-containing C-terminus

SNX contains a BAR domain in its C-terminus, which is located between amino acids 256 and 440. Its ability to form coatings in membranes in order to induce their curvature is key in SNX8 participation in tubular structures formation. Furthermore, SNX8 C-terminus contains a threonine in position 452 and a serine in position 456 which can go through post-traductional changes that induces its phosphorylation, resulting in a phosphothreonine and a phosphoserine. Therefore, there are classified as phosphorylation sites.[6]

MVP1 ortholog

SNX8 has a yeast ortholog protein, the MVP1 encoded by the also homolog gene Mvp1p, which also plays a role by mediating transport of cargo to the vacuolar and lysosomal compartments. For this reason, its investigation can lead to a better understanding of SNX8 functions in human cells.[7]

Biological functions and its molecular mechanisms

SNX8 is thought to be an adaptor protein involved in the endosome-to-Golgi transport pathway, participating in endocytosis and endosomal sorting and signaling. It downregulates retrograde transport of intracellular proteins from the early endosome compartment to the trans-Golgi network in a retromer-mediated manner. SNX8 is therefore localized in early endosomes, as its colocalization with components of the retromer such as SNX1, SNX2, Vps26 and Vps35 has been demonstrated by some studies (and also with EEA1).[7] Furthermore, the dynamics of endosomal structures with SNX8-enriched membrane domains are regulated by the opposite motor proteins dynein-1 containing LIC1 and kinesin-1, both of which allow SNX8-mediated cargo movement through the cytosol by exerting forces on these structures.[8] The biological functions of SNX8 that have been studied, all of which involve its role in intracellular endosomal transport, are explained in more detail in the following sections.

Innate immune response

Cytosolic RNA virus-triggered response

SNX8 is a key component in the induction of downstream effector antiviral gene transcription in response to RNA viruses, as it is necessary for RLR-mediated activation of the IFNβ promoter that leads to host defense in a dose-dependent manner. It positively regulates the aggregation and activation of VISA, a key adaptor protein involved in the innate immune response against this type of infections; this process is critical in the recruitment of other signaling components. Although SNX8's standard localization includes the cytoplasm and other compartments such as the ER, the ER-Golgi intermediate compartment, the Golgi apparatus or endosomes, it is partially localized at mitochondria. Furthermore, RNA viral infections cause the translocation of SNX8 from the cytosol to the mitochondria. During the early stage of the infection, SNX8 association with VISA increases above constitutive levels (degradation of VISA in later stages results in a reduction of this phenomenon). Structurally, the C-terminus transmembrane domain of VISA and both N-terminus PX domain and C-terminus of SNX8 are necessary for this linkage. The formation of the SNX8-VISA complex potentiates VISA prion-like polymerization and aggregation. After VISA activation, its accumulation allows the recruitment of signaling components which play a role in RLR-mediated antiviral response activation such as the intermediates of this pathway TBK1, IRF3, IκBα or ISRE. IRF3 cooperative activation with NF-κB transcription factor through phosphorylation leads to the induction of the IFNβ promoter transcription. Examples of genes whose RNA virus-triggered expression is stimulated by SNX8 are IFNB1, ISG56 and IL6 (being IL6 and IFNB1 related to cytokine secretion).[9]

In addition, SNX8 also plays a role in RIG-I containing CARD domain-mediated and MDA5-mediated activation of the IFNβ promoter, since VISA works as an intermediate for both signaling pathways. The mechanism for SNX8 recruitment to VISA remains unclear, although two options have been suggested: translocation of viral RNA-bound RIG-I or MDA5 to VISA may result in a conformational switch that would increase its affinity for SNX8 or the RNA virus may induce post-translational modifications of one of these proteins allowing the translocation of SNX8 to mitochondria for its interaction with VISA.[9]

Cytosolic DNA virus-triggered response

Simplified scheme of DNA-triggered SNX8-mediated association of MITA and VPS34, and its intracellular transport pathway from RE to perinuclear microsomes via Golgi apparatus.[10]

SNX8 is a key component in the induction of downstream effector antiviral gene transcription in response to DNA viruses , as it is necessary for MITA-mediated activation of the IFNβ promoter in a dose-dependent manner. It regulates the activation of MITA, a central adaptor protein in the innate immune response to DNA viral infections that activates and onsets the antiviral response, by allowing its association with the class III phosphatylinositol 3 kinase VPS34-containing translocon machinery to form the MITA-Vps34 translocation complex; this linkage is crucial for MITA transport from the ER to perinuclear microsomal punctuate structures, which are induced by infection of viruses such as HSV-1, via Golgi mediated intracellular traffic. This MITA transport pathway is vital for the immune response to start. SNX8 is suggested to play a role in MITA's activation through this transport pathway, modulating its phosphorylation at serine in position 366 and recruiting the transcription factor IRF3 whose activation is important in the activation of the IFNβ promoter transcription. This hypothesis is supported by the fact that MITA, SNX8 and VPS34 colocalize in the cytoplasm, and that SNX8 localization in ER, ER-Golgi intermediate compartment, Golgi and endosomes is similar to that of MITA. Examples of genes whose DNA virus-triggered expression is stimulated by SNX8 are IFNB1, ISG56, CXCL10 and IL6 (being IFNB1 and IL6 related to cytokine secretion).[10]

IFNγ-triggered IKKβ-mediated noncanonical signaling pathway

SNX8 is a component of an IKKβ-mediated noncanonical signaling pathway triggered by the interferon gamma, which takes places parallelly to the more known IFNγ-induced JAK-STAT1 mediated pathway. Overall, it participates in a series of chemical reactions and molecular interactions that lead to the selective promotion of a particular subset of downstream effector gene transcription that encode IFNγ-induced GTPases of the GBP family, which participate in host defense against intracellular pathogens, and secretion proteins of the chemokine family such as CXCL9, CXCL10, and CXCL11 which present direct antimicrobial activity. In addition, SNX8 enhances the IFNγ-induced activation of the IRF1 promoter in a dose-dependent manner.[5]

Simplified scheme of SNX8 participation in the IFNγ-triggered IKKβ-mediated noncanonical signaling pathway (autophosphorylation not shown).[5]

Specifically, the steps of this pathway that are regulated by SNX8 are the following. The reception of IFNγ activates Janus kinase 1, resulting in the stimulation of its association with Sxn8 above standard constitutive levels. The link between these two protein within the JAK1-SNX8 complex allows JAK1 to catalyse SNX8's tyrosines phosphorylation in positions 95 and 126. This phosphorylation activates the JAK1-SNX, and the SNX8 acts as an adaptor or scaffolding protein by permitting the recruitment of the inhibitor of nuclear factor-kappa-B kinase subunit beta (IKKβ) to JAK1 in the JAK1-SNX8-IKKβ complex. This linkage is essential for IKKβ activation through autophosphorylation at serine in position 177 (as SNX8 lacks enzymatic activity) and further dimerization and oligomerization.[5]

Cholesterol regulation

SNX8 protein regulates cholesterol levels as an activator of the SREBPs (Sterol Regulatory Element Binding Proteins), which is a family of transcription factors that control the expression of enzymes needed for the synthesis and uptake of fatty acids, endogenous cholesterol, triacylglycerides and phospholipids; this results in an overall regulation of intracellular lipid homeostasis. Although its precise mechanism of action remains unknown, data suggests that SNX8 produces changes in cholesterol distribution through regulation of the SREBP transcriptional activity by modulating intracellular traffic events rather than by interacting with proteins of the SREBP pathway like INSIG or SREBP cleavage-activating protein (SCAP). For example, it is unclear if SNX8 has a direct participation in the transport of SREBP pathway components or if it regulates endosomal and lysosomal compartmentalization through the production of cholesterol cargoes. This last possibility is supported by the fact that the ability of altering membrane curvature is shared by some proteins of the SNXs family.[3]

It has been observed that variation in cholesterol levels alter SNX8 transcription: it remains unaltered in conditions of moderate high concentrations of cholesterol, and it experiments a decrease in conditions of restricted levels of cholesterol due to the action of the fungus-derived cholesterol-lowering statin mevinolin and the drug U18666a which promotes cytosolic cholesterol clustering within the endosomal and lysosomal compartments by acting as an intracellular cholesterol transport inhibitor.[11] On the other hand, SNX8 overexpression induces intracellular clustering of cholesterol under conditions of high cellular cholesterol levels and aggravates abnormal distribution of cholesterol. In relation to the SREBP pathway, SNX8 is not able to successfully reduce the inhibitory impact of cholesterol on SREBP-mediated transcription, but it has an important effect that counteracts the block of this pathway triggered by the insulin-induced gene INSIG.[3]

Intracellular non-amyloidogenic APP traffic

Simplified scheme of APP traffic and its amyloidogenic and non-amyloidogenic proteolytic degradative pathways[12]

The amyloid precursor protein (APP) is consecutively transported from the ER after its synthesis to the plasma membrane via the trans-Golgi network; during this traffic, the neuroprotective soluble fragment sAPPα is produced as a product of APP cleavage by α-secretases. Lately, APP that reaches the membrane without being severed can be internalized into endosomes in order to be proteolytically processed through two parallel pathways: an amyloidogenic pathway via acidified late endosomes and a non-amyloidogenic or anti-myloidogenic retrograde pathway via Golgi apparatus. The amyloidogenic pathway leads to APP processing by γ-secretases and β-secretases such as BACE1, resulting in production of the neurotoxic amyloid beta (Aβ) peptide that accumulates in extracellular locations forming senile plaques.[12]

SNX8 promotes non-amyloidogenic transport from the Golgi apparatus to other cellular locations, leading to an increase of APP levels, a stimulated distribution throughout the outer face of cell membrane, an enhanced sAPPα secretion and a reduced production (specifically, production of Aβ40 and Aβ42) . In addition, SNX8 improves APP stability, which is responsible for a longer lifespan, without having any effect in its mRNA transcription. This hypothesis is supported by the fact that SNX8 mainly colocalizes with Rab5 at early endosomes and partially with Rab4 at recycling endosomes, with Rab7 at late endosomes and with Giantin at Golgi apparatus.[12]

Construction of tubular profiles

Although the endosomal compartment is composed of vesicular and tubular structures, it has been demonstrated that sorting involving recycling pathways is mainly tubule-mediated. Therefore, tubular structures building is essential for the activity of SNXs containing BAR domains (such as SNX1, SNX4 or SNX8) as phosphoinositide-mediated endosomal sorting proteins. This BAR domain allows them to assembly in a dose-dependent manner a helical coat with the capacity to detect, promote and stabilize the curvature of endosomal vesicular membranes into tubular profiles during the so-called incidence detection process, specially in phosphoinosited-enriched regions where they are localized thanks to the affinity of the PX domain for these membrane phospholipids. In particular, SNX8 colocalizes with Rab5 at early endosomes membranes and at the tubular endosomal network (TEN) around the endosomal vacuole, which is an important compartment for successful sorting of cargoes.[6]

It is also worth mentioning the existing coupling of tubular structures formation and the maduration processes from early endosomes to late endosomes, which is mainly characterized by a retrograde movement from the cell periphery to a juxtanuclear position, an acidification of early endosomes lumen and a switch from Rab5 GTPase to Rab7 GTPase. The construction of these tubules, which is important for SNX-mediated endosomal sorting, experiments an important acceleration during this transition process; therefore, it is suggested that SNX8 may be involved in the transport of endogenous acid environment-requiring cargo. In addition, as SNX8 interacts with elements of the retromer, it is important to highlight the role of both subcomplexes of the retromer in the coordinated relationship between endosomal maturation and the generation of tubular profiles from vesicular structures.[6]

Medical and clinical significance

Alzheimer's disease

Insoluble accumulations of β-amyloid peptide in brain regions related to memory and cognition are a defining characteristic of Alzheimer's Disease (AD).[13] SNX8 has a neuroprotective role related to AD: it enhances the non-amyloidogenic APP pathway and, hence, reduces the Aβ plaques and deposit accumulations and suppresses cognitive impairment caused by AD. Some studies found that SNX8 levels were drastically lower in patients with AD. Furthermore, it has been demonstrated that SNX8 overexpression mediated by adeno-associated virus (AVV) reduced levels and reversed cognitive impairment in AD mice.[12] It is also important mentioning that a pair of polymorphisms (rs2286206 and rs10249052) within the human SNX8 gene locus have also been associated with late-onset AD.[14]

Neurodevelopmental disorders

Several case studies studying deletions in the 7p22.3 genomic region, where the SNX8 gene is located, found that it contributes to neurodevelopmental problems with considerable impairments in the motor, cognitive and socio-emotional areas, with malformations in the heart and craniofacial structures, with developmental, intellectual and language delay, with mild intellectual disability and with cognitive impairment associated with autism in some cases.[15][16][17] This idea is supported by the fact that the overlapping deleted regions of the different patients of these studies contained SNX8, which suggests that it is one of the accountable genes.[18]

Antiviral activity

SNX8 plays an antiviral role against Listeria monocytogenes through the IFNγ-triggered IKKβ-mediated noncanonical signaling pathway; murine cells expressing SNX8 under this infection showed a higher expression and secretion of IFNβ and IL6 cytokines in blood and lower presence of bacteria in liver and spleens, which resulted in a reduction of Listeria monocytogenes lethality, in comparison to SNX8-negative induced murine cells.[5]

In addition, SNX8 plays an antiviral role against DNA viruses such as HSV-1 through the MITA-mediated activation of the IFNβ promoter; murine cells expressing SNX8 under this infection showed a higher expression and secretion of IFNβ and IL6 cytokines in blood and a decreased presence of cerebral viral titers, which resulted in a reduction of HSV-1 lethality, in comparison to SNX8-negative induced murine cells.[10]

Finally, SNX8 also plays an antiviral role against RNA viruses such as SeV (Sendai virus) through VISA-mediated activation of the IFNβ promoter; murine cells expressing SNX8 under this infection showed a higher expression and secretion of IFNβ and IL6 cytokines in blood and a reduced presence of viral accumulations, which resulted in a reduction of SeV lethality, in comparison to SNX8-negative induced murine cells.[9]

Cardiac malformations

It is suggested that SNX8 participates in the development of the embryonic cardiac tissue since the gene is expressed with cells within the area of heart. This hypothesis is supported by the fact that SNX8 activity has been associated to sortin nexin L, a protein of the same family encoded by the SNX21 gene, which plays a role in the development of the embryonic liver. Deletions of chromosome 7p22 that induce happloinsufficiency of SNX8 among other genes (FTSJ2, NUDTI and MAD1L1) seem to cause craniosynostosis, dysmorphic features and cardiac malformations encompassing tetralogy of Fallot, one of the most common cyanotic congenital heart defects. Nevertheless, evidence demonstrates the existence of patients with SNX8 deletion whose cardiac tissue development does not experience any alteration. Finally, although cardiac malformation requires SNX8 haploinsufficiency, its deletion is not enough to cause this malformations on its own.[17][19][15]

Relationship between cardiac malformations and cholesterol regulation

This bar plot shows the proportion of tumor samples from 15 cancer types that have any kind of altering mutation(s) in the given protein.[20]

SNX8 role in cholesterol levels regulation is markedly relevant since disruption of intracellular cholesterol metabolism and trafficking is the main cause of multiple human disorders. For example, some studies suggest that SNX8 deletions might produce cardiac malformations since its function in normal cholesterol levels regulations would be completely impaired.[21][22][3]

Neuropathic pain

SNPs (single nucleotide polymorphisms) in the SNX8 gene are related to neuropathy due to its role in endosomal content sorting. Neuropathic pain is a chronic debilitating pain condition caused by a nervous system lesion or dysfunction, which usually emerges after head and neck cancer treatment. This hypothesis is supported by the fact that other SNXs activity has also been identified with other pain conditions.[23][24]

Cancer

Some mutations of SNX8 have been related to certain types of cancer, specially to stomach and endometrial cancer. The bar plot on the right shows the proportion of tumor samples from 15 cancer types that have any kind of altering mutations in the given protein.[20] Moreover, some studies seem to draw an important relationship between different type of cancers and SNX8 expression; although most of the patients with colorectal, stomach or testis cancer showed high levels of SNX8, almost any patient with prostate, endometrial or carcinoid cancer presented low or any concentrations of SNX8. The rationale behind this differential phenotype of SNX8 synthesis remains unclear.[25]

References

  1. "Q9Y5X2". SWISS-MODEL Repository.
  2. 1 2 3 4 "SNX8 - Sorting nexin-8 - Homo sapiens (Human) - SNX8 gene & protein". www.uniprot.org. Retrieved 25 October 2019.
  3. 1 2 3 4 Muirhead, Gillian; Dev, Kumlesh K. (2014). "The Expression of Neuronal Sorting Nexin 8 (SNX8) Exacerbates Abnormal Cholesterol Levels". Journal of Molecular Neuroscience. 53 (1): 125–134. doi:10.1007/s12031-013-0209-z. PMID 24362679. S2CID 14668542.
  4. 1 2 "SNX8 sorting nexin 8 [Homo sapiens (human)] - Gene - NCBI". www.ncbi.nlm.nih.gov. Retrieved 26 October 2019.
  5. 1 2 3 4 5 6 Wei, Jin; Guo, Wei; Lian, Huan; Yang, Qing; Lin, Heng; Li, Shu; Shu, Hong-Bing (5 December 2017). "SNX8 mediates IFNγ-triggered noncanonical signaling pathway and host defense against Listeria monocytogenes". Proceedings of the National Academy of Sciences of the United States of America. 114 (49): 13000–13005. Bibcode:2017PNAS..11413000W. doi:10.1073/pnas.1713462114. PMC 5724276. PMID 29180417.
  6. 1 2 3 4 van Weering, Jan R.T.; Verkade, Paul; Cullen, Peter J. (January 2012). "SNX-BAR-Mediated Endosome Tubulation is Co-ordinated with Endosome Maturation". Traffic. 13 (1): 94–107. doi:10.1111/j.1600-0854.2011.01297.x. PMID 21973056. S2CID 7295814.
  7. 1 2 Dyve, Anne Berit; Bergan, Jonas; Utskarpen, Audrun; Sandvig, Kirsten (December 2009). "Sorting nexin 8 regulates endosome-to-Golgi transport". Biochemical and Biophysical Research Communications. 390 (1): 109–114. doi:10.1016/j.bbrc.2009.09.076. PMID 19782049.
  8. Hunt, Sylvie D.; Townley, Anna K.; Danson, Chris M.; Cullen, Peter J.; Stephens, David J. (1 June 2013). "Microtubule motors mediate endosomal sorting by maintaining functional domain organization". Journal of Cell Science. 126 (11): 2493–2501. doi:10.1242/jcs.122317. PMC 3679488. PMID 23549789.
  9. 1 2 3 Guo, Wei; Wei, Jin; Zhong, Xuan; Zang, Ru; Lian, Huan; Hu, Ming-Ming; Li, Shu; Shu, Hong-Bing; Yang, Qing (11 September 2019). "SNX8 modulates the innate immune response to RNA viruses by regulating the aggregation of VISA". Cellular & Molecular Immunology. 17 (11): 1126–1135. doi:10.1038/s41423-019-0285-2. PMC 7784681. PMID 31511639. S2CID 202558274.
  10. 1 2 3 Wei, Jin; Lian, Huan; Guo, Wei; Chen, Yun-Da; Zhang, Xia-Nan; Zang, Ru; Zhong, Li; Yang, Qing; Hu, Ming-Ming; Luo, Wei-Wei; Shu, Hong-Bing; Li, Shu; Feng, Pinghui (15 October 2018). "SNX8 modulates innate immune response to DNA virus by mediating trafficking and activation of MITA". PLOS Pathogens. 14 (10): e1007336. doi:10.1371/journal.ppat.1007336. PMC 6188873. PMID 30321235.
  11. Liang, Xiao-Dong; Zhang, Yun-Na; Liu, Chun-Chun; Chen, Jing; Chen, Xiong-Nan; Sattar Baloch, Abdul; Zhou, Bin (1 November 2019). "U18666A inhibits classical swine fever virus replication through interference with intracellular cholesterol trafficking". Veterinary Microbiology. 238: 108436. doi:10.1016/j.vetmic.2019.108436. PMID 31648726. S2CID 204882235.
  12. 1 2 3 4 Xie, Yongzhuang; Niu, Mengxi; Ji, Chengxiang; Huang, Timothy Y.; Zhang, Cuilin; Tian, Ye; Shi, Zhun; Wang, Chen; Zhao, Yingjun; Luo, Hong; Can, Dan; Xu, Huaxi; Zhang, Yun-wu; Zhang, Xian (6 September 2019). "SNX8 Enhances Non-amyloidogenic APP Trafficking and Attenuates Aβ Accumulation and Memory Deficits in an AD Mouse". Frontiers in Cellular Neuroscience. 13: 410. doi:10.3389/fncel.2019.00410. PMC 6743354. PMID 31551717.
  13. Glenner, George G.; Wong, Caine W. (May 1984). "Alzheimer's disease: Initial report of the purification and characterization of a novel cerebrovascular amyloid protein". Biochemical and Biophysical Research Communications. 120 (3): 885–890. doi:10.1016/S0006-291X(84)80190-4. PMID 6375662.
  14. Rosenthal, Samantha L; Wang, Xingbin; Demirci, F Yesim; Barmada, Michael M; Ganguli, Mary; Lopez, Oscar L; Kamboh, M Ilyas (13 August 2012). "Beta-amyloid toxicity modifier genes and the risk of Alzheimer's disease". American Journal of Neurodegenerative Disease. 1 (2): 191–198. PMC 3560458. PMID 22984654.
  15. 1 2 Richards, Elliott G.; Zaveri, Hitisha P.; Wolf, Varina L.; Kang, Sung-Hae Lee; Scott, Daryl A. (July 2011). "Delineation of a less than 200 kb minimal deleted region for cardiac malformations on chromosome 7p22". American Journal of Medical Genetics Part A. 155 (7): 1729–1734. doi:10.1002/ajmg.a.34041. PMID 21671376. S2CID 7570369.
  16. Rendu, John; Satre, Véronique; Testard, Hervé; Devillard, Francoise; Vieville, Gaëlle; Fauré, Julien; Amblard, Florence; Jouk, Pierre-Simon; Coutton, Charles (August 2014). "7p22.3 microdeletion disrupting SNX8 in a patient presenting with intellectual disability but no tetralogy of Fallot". American Journal of Medical Genetics Part A. 164 (8): 2133–2135. doi:10.1002/ajmg.a.36566. PMID 24715298. S2CID 8191354.
  17. 1 2 Vanzo, Rena J.; Martin, Megan M.; Sdano, Mallory R.; Teta, Kathie; Aggarwal, Vimla; South, Sarah T. (February 2014). "SNX8: A candidate gene for 7p22 cardiac malformations including tetralogy of fallot". American Journal of Medical Genetics Part A. 164 (2): 554–556. doi:10.1002/ajmg.a.36242. PMID 24311514. S2CID 31142228.
  18. Mastromoro, Gioia; Capalbo, Anna; Guido, Cristiana Alessia; Torres, Barbara; Fabbretti, Maria; Traversa, Alice; Giancotti, Antonella; Ventriglia, Flavia; Bernardini, Laura; Spalice, Alberto; Pizzuti, Antonio (September 2019). "Small 7p22.3 microdeletion: Case report of Snx8 haploinsufficiency and neurological findings". European Journal of Medical Genetics. 63 (4): 103772. doi:10.1016/j.ejmg.2019.103772. PMID 31568860. S2CID 203624241.
  19. Vanzo, Rena J.; Martin, Megan M.; Sdano, Mallory R.; Teta, Kathie; South, Sarah T. (August 2014). "Correspondence regarding SNX8 haploinsufficiency and its potential for cardiac anomalies including tetralogy of Fallot". American Journal of Medical Genetics Part A. 164 (8): 2136–2137. doi:10.1002/ajmg.a.36572. PMID 24733602. S2CID 39609715.
  20. 1 2 "SNX8 (human)". www.phosphosite.org. Retrieved 25 October 2019.
  21. Chatterjee, Sandipan; Szustakowski, Joseph D.; Nanguneri, Nirmala R.; Mickanin, Craig; Labow, Mark A.; Nohturfft, Axel; Dev, Kumlesh K.; Sivasankaran, Rajeev; Xu, Aimin (21 April 2009). "Identification of Novel Genes and Pathways Regulating SREBP Transcriptional Activity". PLOS ONE. 4 (4): e5197. Bibcode:2009PLoSO...4.5197C. doi:10.1371/journal.pone.0005197. PMC 2668173. PMID 19381295.
  22. Eberlé, Delphine; Hegarty, Bronwyn; Bossard, Pascale; Ferré, Pascal; Foufelle, Fabienne (November 2004). "SREBP transcription factors: master regulators of lipid homeostasis". Biochimie. 86 (11): 839–848. doi:10.1016/j.biochi.2004.09.018. PMID 15589694.
  23. Reyes-Gibby, Cielito C.; Wang, Jian; Yeung, Sai-Ching J.; Chaftari, Patrick; Yu, Robert K.; Hanna, Ehab Y.; Shete, Sanjay (8 June 2018). "Genome-wide association study identifies genes associated with neuropathy in patients with head and neck cancer". Scientific Reports. 8 (1): 8789. Bibcode:2018NatSR...8.8789R. doi:10.1038/s41598-018-27070-4. PMC 5993794. PMID 29884837.
  24. Lin, Tzer-Bin; Lai, Cheng-Yuan; Hsieh, Ming-Chun; Wang, Hsueh-Hsiao; Cheng, Jen-Kun; Chau, Yat-Pang; Chen, Gin-Den; Peng, Hsien-Yu (4 November 2015). "VPS26A–SNX27 Interaction-Dependent mGluR5 Recycling in Dorsal Horn Neurons Mediates Neuropathic Pain in Rats". Journal of Neuroscience. 35 (44): 14943–14955. doi:10.1523/JNEUROSCI.2587-15.2015. PMC 6605230. PMID 26538661.
  25. "Expression of SNX8 in cancer". The Human Protein Atlas.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.