In cellular biology, P-bodies, or processing bodies, are distinct foci formed by phase separation within the cytoplasm of a eukaryotic cell consisting of many enzymes involved in mRNA turnover.[1] P-bodies are highly conserved structures and have been observed in somatic cells originating from vertebrates and invertebrates, plants and yeast. To date, P-bodies have been demonstrated to play fundamental roles in general mRNA decay, nonsense-mediated mRNA decay, adenylate-uridylate-rich element mediated mRNA decay, and microRNA (miRNA) induced mRNA silencing.[2] Not all mRNAs which enter P-bodies are degraded, as it has been demonstrated that some mRNAs can exit P-bodies and re-initiate translation.[3][4] Purification and sequencing of the mRNA from purified processing bodies showed that these mRNAs are largely translationally repressed upstream of translation initiation and are protected from 5' mRNA decay.[5]
P-bodies were originally proposed to be the sites of mRNA degradation in the cell and involved in decapping and digestion of mRNAs earmarked for destruction.[6][7] Later work called this into question suggesting P bodies store mRNA until needed for translation.[8][5][9]
In neurons, P-bodies are moved by motor proteins in response to stimulation. This is likely tied to local translation in dendrites.[10]
History
P-bodies were first described in the scientific literature by Bashkirov et al.[11] in 1997, in which they describe "small granules… discrete, prominent foci" as the cytoplasmic location of the mouse exoribonuclease mXrn1p. It wasn’t until 2002 that a glimpse into the nature and importance of these cytoplasmic foci was published.[12][13][14], when researchers demonstrated that multiple proteins involved with mRNA degradation localize to the foci. Their importance was recognized after experimental evidence was obtained pointing to P-bodies as the sites of mRNA degradation in the cell.[7] The researchers named these structures processing bodies or "P bodies". During this time, many descriptive names were used also to identify the processing bodies, including "GW-bodies" and "decapping-bodies"; however "P-bodies" was the term chosen and is now widely used and accepted in the scientific literature.[7] Recently evidence has been presented suggesting that GW-bodies and P-bodies may in fact be different cellular components.[15] The evidence being that GW182 and Ago2, both associated with miRNA gene silencing, are found exclusively in multivesicular bodies or GW-bodies and are not localized to P-bodies. Also of note, P-bodies are not equivalent to stress granules and they contain largely non-overlapping proteins.[5] The two structures support overlapping cellular functions but generally occur under different stimuli. Hoyle et al. suggests a novel site termed EGP bodies, or stress granules, may be responsible for mRNA storage as these sites lack the decapping enzyme.[16]
Associations with microRNA
microRNA mediated repression occurs in two ways, either by translational repression or stimulating mRNA decay. miRNA recruit the RISC complex to the mRNA to which they are bound. The link to P-bodies comes by the fact that many, if not most, of the proteins necessary for miRNA gene silencing are localized to P-bodies, as reviewed by Kulkarni et al. (2010).[2][17][18][19][20] These proteins include, but are not limited to, the scaffold protein GW182, Argonaute (Ago), decapping enzymes and RNA helicases. The current evidence points toward P-bodies as being scaffolding centers of miRNA function, especially due to the evidence that a knock down of GW182 disrupts P-body formation. However, there remain many unanswered questions about P-bodies and their relationship to miRNA activity. Specifically, it is unknown whether there is a context dependent (stress state versus normal) specificity to the P-body's mechanism of action. Based on the evidence that P-bodies sometimes are the site of mRNA decay and sometimes the mRNA can exit the P-bodies and re-initiate translation, the question remains of what controls this switch. Another ambiguous point to be addressed is whether the proteins that localize to P-bodies are actively functioning in the miRNA gene silencing process or whether they are merely on standby.
Protein composition
In 2017, a new method to purify processing bodies was published.[5] Hubstenberger et al. used fluorescence-activated particle sorting (a method based on the ideas of fluorescence-activated cell sorting) to purify processing bodies from human epithelial cells. From these purified processing bodies they were able to use mass spectrometry and RNA sequencing to determine which proteins and RNAs are found in processing bodies, respectively. This study identified 125 proteins that are significantly associated with processing bodies.[5] Notably this work provided the most compelling evidence up to this date that P-bodies might not be the sites of degradation in the cell and instead used for storage of translationally repressed mRNA. This observation was further supported by single molecule imaging of mRNA by the Chao group in 2017.[21]
In 2018, Youn et al. took a proximity labeling approach called BioID to identify and predict the processing body proteome.[22] They engineered cells to express several processing body-localized proteins as fusion proteins with the BirA* enzyme. When the cells are incubated with biotin, BirA* will biotinylate proteins that are nearby, thus tagging the proteins within processing bodies with a biotin tag. Streptavidin was then used to isolate the tagged proteins and mass spectrometry to identify them. Using this approach, Youn et al. identified 42 proteins that localize to processing bodies.[22]
Gene ID | Protein | References | Also found in stress granules? |
---|---|---|---|
MOV10 | MOV10 | [5][22] | Yes |
EDC3 | EDC3 | [22] | Yes |
EDC4 | EDC4 | [5] | Yes |
ZCCHC11 | TUT4 | [5] | No |
DHX9 | DHX9 | [5] | No |
RPS27A | RS27A | [5] | No |
UPF1 | RENT1 | [5] | Yes |
ZCCHC3 | ZCHC3 | [5] | No |
SMARCA5 | SMCA5 | [5] | No |
TOP2A | TOP2A | [5] | No |
HSPA2 | HSP72 | [5] | No |
SPTAN1 | SPTN1 | [5] | No |
SMC1A | SMC1A | [5] | No |
ACTBL2 | ACTBL | [5] | Yes |
SPTBN1 | SPTB2 | [5] | No |
DHX15 | DHX15 | [5] | No |
ARG1 | ARGI1 | [5] | No |
TOP2B | TOP2B | [5] | No |
APOBEC3F | ABC3F | [5] | No |
NOP58 | NOP58 | [5] | Yes |
RPF2 | RPF2 | [5] | No |
S100A9 | S100A9 | [5] | Yes |
DDX41 | DDX41 | [5] | No |
KIF23 | KIF23 | [5] | Yes |
AZGP1 | ZA2G | [5] | No |
DDX50 | DDX50 | [5] | Yes |
SERPINB3 | SPB3 | [5] | No |
SBSN | SBSN | [5] | No |
BAZ1B | BAZ1B | [5] | No |
MYO1C | MYO1C | [5] | No |
EIF4A3 | IF4A3 | [5] | No |
SERPINB12 | SPB12 | [5] | No |
EFTUD2 | U5S1 | [5] | No |
RBM15B | RB15B | [5] | No |
AGO2 | AGO2 | [5] | Yes |
MYH10 | MYH10 | [5] | No |
DDX10 | DDX10 | [5] | No |
FABP5 | FABP5 | [5] | No |
SLC25A5 | ADT2 | [5] | No |
DMKN | DMKN | [5] | No |
DCP2 | DCP2 | [5][13][14][23] | No |
S100A8 | S10A8 | [5] | No |
NCBP1 | NCBP1 | [5] | No |
YTHDC2 | YTDC2 | [5] | No |
NOL6 | NOL6 | [5] | No |
XAB2 | SYF1 | [5] | No |
PUF60 | PUF60 | [5] | No |
RBM19 | RBM19 | [5] | No |
WDR33 | WDR33 | [5] | No |
PNRC1 | PNRC1 | [5] | No |
SLC25A6 | ADT3 | [5] | No |
MCM7 | MCM7 | [5] | Yes |
GSDMA | GSDMA | [5] | No |
HSPB1 | HSPB1 | [5] | Yes |
LYZ | LYSC | [5] | No |
DHX30 | DHX30 | [5] | Yes |
BRIX1 | BRX1 | [5] | No |
MEX3A | MEX3A | [5] | Yes |
MSI1 | MSI1H | [5] | Yes |
RBM25 | RBM25 | [5] | No |
UTP11L | UTP11 | [5] | No |
UTP15 | UTP15 | [5] | No |
SMG7 | SMG7 | [5][22] | Yes |
AGO1 | AGO1 | [5] | Yes |
LGALS7 | LEG7 | [5] | No |
MYO1D | MYO1D | [5] | No |
XRCC5 | XRCC5 | [5] | No |
DDX6 | DDX6/p54/RCK | [5][22][24][25] | Yes |
ZC3HAV1 | ZCCHV | [5] | Yes |
DDX27 | DDX27 | [5] | No |
NUMA1 | NUMA1 | [5] | No |
DSG1 | DSG1 | [5] | No |
NOP56 | NOP56 | [5] | No |
LSM14B | LS14B | [5] | Yes |
EIF4E2 | EIF4E2 | [22] | Yes |
EIF4ENIF1 | 4ET | [5][22] | Yes |
LSM14A | LS14A | [5][22] | Yes |
IGF2BP2 | IF2B2 | [5] | Yes |
DDX21 | DDX21 | [5] | Yes |
DSC1 | DSC1 | [5] | No |
NKRF | NKRF | [5] | No |
DCP1B | DCP1B | [5][25] | No |
SMC3 | SMC3 | [5] | No |
RPS3 | RS3 | [5] | Yes |
PUM1 | PUM1 | [5] | Yes |
PIP | PIP | [5] | No |
RPL26 | RL26 | [5] | No |
GTPBP4 | NOG1 | [5] | No |
PES1 | PESC | [5] | No |
DCP1A | DCP1A | [5][13][14][23][26] | No |
ELAVL2 | ELAV2 | [5] | Yes |
IGLC2 | LAC2 | [5] | No |
IGF2BP1 | IF2B1 | [5] | Yes |
RPS16 | RS16 | [5] | No |
HNRNPU | HNRPU | [5] | No |
IGF2BP3 | IF2B3 | [5] | Yes |
SF3B1 | SF3B1 | [5] | No |
STAU2 | STAU2 | [5] | Yes |
ZFR | ZFR | [5] | No |
HNRNPM | HNRPM | [5] | No |
ELAVL1 | ELAV1 | [5] | Yes |
FAM120A | F120A | [5] | Yes |
STRBP | STRBP | [5] | No |
RBM15 | RBM15 | [5] | No |
LMNB2 | LMNB2 | [5] | No |
NIFK | MK67I | [5] | No |
TF | TRFE | [5] | No |
HNRNPR | HNRPR | [5] | No |
LMNB1 | LMNB1 | [5] | No |
ILF2 | ILF2 | [5] | No |
H2AFY | H2AY | [5] | No |
RBM28 | RBM28 | [5] | No |
MATR3 | MATR3 | [5] | No |
SYNCRIP | HNRPQ | [5] | Yes |
HNRNPCL1 | HNRCL | [5] | No |
APOA1 | APOA1 | [5] | No |
XRCC6 | XRCC6 | [5] | No |
RPS4X | RS4X | [5] | No |
DDX18 | DDX18 | [5] | No |
ILF3 | ILF3 | [5] | Yes |
SAFB2 | SAFB2 | [5] | Yes |
RBMX | RBMX | [5] | No |
ATAD3A | ATD3A | [5] | Yes |
HNRNPC | HNRPC | [5] | No |
RBMXL1 | RMXL1 | [5] | No |
IMMT | IMMT | [5] | No |
ALB | ALBU | [5] | No |
CSNK1D | CK1𝛿 | [24] | No |
XRN1 | XRN1 | [11][13][22][23] | Yes |
TNRC6A | GW182 | [22][23][27][26][28] | Yes |
TNRC6B | TNRC6B | [22] | Yes |
TNRC6C | TNRC6C | [22] | Yes |
LSM4 | LSM4 | [26][13] | No |
LSM1 | LSM1 | [13] | No |
LSM2 | LSM2 | [13] | No |
LSM3 | LSM3 | [13][25] | Yes |
LSM5 | LSM5 | [13] | No |
LSM6 | LSM6 | [13] | No |
LSM7 | LSM7 | [13] | No |
CNOT1 | CCR4/CNOT1 | [25][22] | Yes |
CNOT10 | CNOT10 | [22] | Yes |
CNOT11 | CNOT11 | [22] | Yes |
CNOT2 | CNOT2 | [22] | Yes |
CNOT3 | CNOT3 | [22] | Yes |
CNOT4 | CNOT4 | [22] | Yes |
CNOT6 | CNOT6 | [22] | Yes |
CNOT6L | CNOT6L | [22] | Yes |
CNOT7 | CNOT7 | [22] | Yes |
CNOT8 | CNOT8 | [22] | Yes |
CNOT9 | CNOT9 | [22] | No |
RBFOX1 | RBFOX1 | [29] | Yes |
ANKHD1 | ANKHD1 | [22] | Yes |
ANKRD17 | ANKRD17 | [22] | Yes |
BTG3 | BTG3 | [22] | Yes |
CEP192 | CEP192 | [22] | No |
CPEB4 | CPEB4 | [22] | Yes |
CPVL | CPVL | [22] | Yes |
DIS3L | DIS3L | [22] | No |
DVL3 | DVL3 | [22] | No |
FAM193A | FAM193A | [22] | No |
GIGYF2 | GIGYF2 | [22] | Yes |
HELZ | HELZ | [22] | Yes |
KIAA0232 | KIAA0232 | [22] | Yes |
KIAA0355 | KIAA0355 | [22] | No |
MARF1 | MARF1 | [22] | Yes |
N4BP2 | N4BP2 | [22] | No |
PATL1 | PATL1 | [22] | Yes |
RNF219 | RNF219 | [22] | Yes |
ST7 | ST7 | [22] | Yes |
TMEM131 | TMEM131 | [22] | Yes |
TNKS1BP1 | TNKS1BP1 | [22] | Yes |
TTC17 | TTC17 | [22] | Yes |
References
- ↑ Luo Y, Na Z, Slavoff SA (May 2018). "P-Bodies: Composition, Properties, and Functions". Biochemistry. 57 (17): 2424–2431. doi:10.1021/acs.biochem.7b01162. PMC 6296482. PMID 29381060.
- 1 2 Kulkarni M, Ozgur S, Stoecklin G (February 2010). "On track with P-bodies". Biochemical Society Transactions. 38 (Pt 1): 242–251. doi:10.1042/BST0380242. PMID 20074068.
- ↑ Brengues M, Teixeira D, Parker R (October 2005). "Movement of eukaryotic mRNAs between polysomes and cytoplasmic processing bodies". Science. 310 (5747): 486–489. Bibcode:2005Sci...310..486B. doi:10.1126/science.1115791. PMC 1863069. PMID 16141371.
- ↑ Bhattacharyya SN, Habermacher R, Martine U, Closs EI, Filipowicz W (June 2006). "Relief of microRNA-mediated translational repression in human cells subjected to stress". Cell. 125 (6): 1111–1124. doi:10.1016/j.cell.2006.04.031. PMID 16777601. S2CID 18353167.
- 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 Hubstenberger A, Courel M, Bénard M, Souquere S, Ernoult-Lange M, Chouaib R, et al. (October 2017). "P-Body Purification Reveals the Condensation of Repressed mRNA Regulons". Molecular Cell. 68 (1): 144–157.e5. doi:10.1016/j.molcel.2017.09.003. PMID 28965817.
- ↑ Long, Roy M.; McNally, Mark T. (2003-05-01). "mRNA Decay: X (XRN1) Marks the Spot". Molecular Cell. 11 (5): 1126–1128. doi:10.1016/S1097-2765(03)00198-9. ISSN 1097-2765.
- 1 2 3 Sheth U, Parker R (May 2003). "Decapping and decay of messenger RNA occur in cytoplasmic processing bodies". Science. 300 (5620): 805–808. Bibcode:2003Sci...300..805S. doi:10.1126/science.1082320. PMC 1876714. PMID 12730603.
- ↑ Brengues, Muriel; Teixeira, Daniela; Parker, Roy (2005-10-21). "Movement of Eukaryotic mRNAs Between Polysomes and Cytoplasmic Processing Bodies". Science. 310 (5747): 486–489. doi:10.1126/science.1115791. ISSN 0036-8075. PMC 1863069. PMID 16141371.
- ↑ Horvathova, Ivana; Voigt, Franka; Kotrys, Anna V.; Zhan, Yinxiu; Artus-Revel, Caroline G.; Eglinger, Jan; Stadler, Michael B.; Giorgetti, Luca; Chao, Jeffrey A. (2017-11-02). "The Dynamics of mRNA Turnover Revealed by Single-Molecule Imaging in Single Cells". Molecular Cell. 68 (3): 615–625.e9. doi:10.1016/j.molcel.2017.09.030. ISSN 1097-2765. PMID 29056324.
- ↑ Cougot N, Bhattacharyya SN, Tapia-Arancibia L, Bordonné R, Filipowicz W, Bertrand E, Rage F (December 2008). "Dendrites of mammalian neurons contain specialized P-body-like structures that respond to neuronal activation". The Journal of Neuroscience. 28 (51): 13793–13804. doi:10.1523/JNEUROSCI.4155-08.2008. PMC 6671906. PMID 19091970.
- 1 2 Bashkirov VI, Scherthan H, Solinger JA, Buerstedde JM, Heyer WD (February 1997). "A mouse cytoplasmic exoribonuclease (mXRN1p) with preference for G4 tetraplex substrates". The Journal of Cell Biology. 136 (4): 761–773. doi:10.1083/jcb.136.4.761. PMC 2132493. PMID 9049243.
- ↑ Eystathioy T, Chan EK, Tenenbaum SA, Keene JD, Griffith K, Fritzler MJ (April 2002). "A phosphorylated cytoplasmic autoantigen, GW182, associates with a unique population of human mRNAs within novel cytoplasmic speckles". Molecular Biology of the Cell. 13 (4): 1338–1351. doi:10.1091/mbc.01-11-0544. PMC 102273. PMID 11950943.
- 1 2 3 4 5 6 7 8 9 10 11 Ingelfinger D, Arndt-Jovin DJ, Lührmann R, Achsel T (December 2002). "The human LSm1-7 proteins colocalize with the mRNA-degrading enzymes Dcp1/2 and Xrnl in distinct cytoplasmic foci". RNA. 8 (12): 1489–1501. doi:10.1017/S1355838202021726. PMC 1370355. PMID 12515382.
- 1 2 3 van Dijk E, Cougot N, Meyer S, Babajko S, Wahle E, Séraphin B (December 2002). "Human Dcp2: a catalytically active mRNA decapping enzyme located in specific cytoplasmic structures". The EMBO Journal. 21 (24): 6915–6924. doi:10.1093/emboj/cdf678. PMC 139098. PMID 12486012.
- ↑ Gibbings DJ, Ciaudo C, Erhardt M, Voinnet O (September 2009). "Multivesicular bodies associate with components of miRNA effector complexes and modulate miRNA activity". Nature Cell Biology. 11 (9): 1143–1149. doi:10.1038/ncb1929. PMID 19684575. S2CID 205286867.
- ↑ Hoyle NP, Castelli LM, Campbell SG, Holmes LE, Ashe MP (October 2007). "Stress-dependent relocalization of translationally primed mRNPs to cytoplasmic granules that are kinetically and spatially distinct from P-bodies". The Journal of Cell Biology. 179 (1): 65–74. doi:10.1083/jcb.200707010. PMC 2064737. PMID 17908917.
- ↑ Liu J, Valencia-Sanchez MA, Hannon GJ, Parker R (July 2005). "MicroRNA-dependent localization of targeted mRNAs to mammalian P-bodies". Nature Cell Biology. 7 (7): 719–723. doi:10.1038/ncb1274. PMC 1855297. PMID 15937477.
- ↑ Liu J, Rivas FV, Wohlschlegel J, Yates JR, Parker R, Hannon GJ (December 2005). "A role for the P-body component GW182 in microRNA function". Nature Cell Biology. 7 (12): 1261–1266. doi:10.1038/ncb1333. PMC 1804202. PMID 16284623.
- ↑ Sen GL, Blau HM (June 2005). "Argonaute 2/RISC resides in sites of mammalian mRNA decay known as cytoplasmic bodies". Nature Cell Biology. 7 (6): 633–636. doi:10.1038/ncb1265. PMID 15908945. S2CID 6085169.
- ↑ Eystathioy T, Jakymiw A, Chan EK, Séraphin B, Cougot N, Fritzler MJ (October 2003). "The GW182 protein colocalizes with mRNA degradation associated proteins hDcp1 and hLSm4 in cytoplasmic GW bodies". RNA. 9 (10): 1171–1173. doi:10.1261/rna.5810203. PMC 1370480. PMID 13130130.
- ↑ Horvathova, Ivana; Voigt, Franka; Kotrys, Anna V.; Zhan, Yinxiu; Artus-Revel, Caroline G.; Eglinger, Jan; Stadler, Michael B.; Giorgetti, Luca; Chao, Jeffrey A. (2017-11-02). "The Dynamics of mRNA Turnover Revealed by Single-Molecule Imaging in Single Cells". Molecular Cell. 68 (3): 615–625.e9. doi:10.1016/j.molcel.2017.09.030. ISSN 1097-2765. PMID 29056324.
- 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 Youn JY, Dunham WH, Hong SJ, Knight JD, Bashkurov M, Chen GI, et al. (February 2018). "High-Density Proximity Mapping Reveals the Subcellular Organization of mRNA-Associated Granules and Bodies". Molecular Cell. 69 (3): 517–532.e11. doi:10.1016/j.molcel.2017.12.020. PMID 29395067.
- 1 2 3 4 Kedersha N, Stoecklin G, Ayodele M, Yacono P, Lykke-Andersen J, Fritzler MJ, et al. (June 2005). "Stress granules and processing bodies are dynamically linked sites of mRNP remodeling". The Journal of Cell Biology. 169 (6): 871–884. doi:10.1083/jcb.200502088. PMC 2171635. PMID 15967811.
- 1 2 Zhang B, Shi Q, Varia SN, Xing S, Klett BM, Cook LA, Herman PK (July 2016). "The Activity-Dependent Regulation of Protein Kinase Stability by the Localization to P-Bodies". Genetics. 203 (3): 1191–1202. doi:10.1534/genetics.116.187419. PMC 4937477. PMID 27182950.
- 1 2 3 4 Cougot N, Babajko S, Séraphin B (April 2004). "Cytoplasmic foci are sites of mRNA decay in human cells". The Journal of Cell Biology. 165 (1): 31–40. doi:10.1083/jcb.200309008. PMC 2172085. PMID 15067023.
- 1 2 3 Eystathioy T, Jakymiw A, Chan EK, Séraphin B, Cougot N, Fritzler MJ (October 2003). "The GW182 protein colocalizes with mRNA degradation associated proteins hDcp1 and hLSm4 in cytoplasmic GW bodies". RNA. 9 (10): 1171–1173. doi:10.1261/rna.5810203. PMC 1370480. PMID 13130130.
- ↑ Eystathioy T, Chan EK, Tenenbaum SA, Keene JD, Griffith K, Fritzler MJ (April 2002). "A phosphorylated cytoplasmic autoantigen, GW182, associates with a unique population of human mRNAs within novel cytoplasmic speckles". Molecular Biology of the Cell. 13 (4): 1338–1351. doi:10.1091/mbc.01-11-0544. PMC 102273. PMID 11950943.
- ↑ Yang Z, Jakymiw A, Wood MR, Eystathioy T, Rubin RL, Fritzler MJ, Chan EK (November 2004). "GW182 is critical for the stability of GW bodies expressed during the cell cycle and cell proliferation". Journal of Cell Science. 117 (Pt 23): 5567–5578. doi:10.1242/jcs.01477. PMID 15494374.
- ↑ Kucherenko MM, Shcherbata HR (January 2018). "Stress-dependent miR-980 regulation of Rbfox1/A2bp1 promotes ribonucleoprotein granule formation and cell survival". Nature Communications. 9 (1): 312. Bibcode:2018NatCo...9..312K. doi:10.1038/s41467-017-02757-w. PMC 5778076. PMID 29358748.
Further reading
- Kulkarni M, Ozgur S, Stoecklin G (February 2010). "On track with P-bodies". Biochemical Society Transactions. 38 (Pt 1): 242–251. doi:10.1042/BST0380242. PMID 20074068.
- Eulalio A, Behm-Ansmant I, Izaurralde E (January 2007). "P bodies: at the crossroads of post-transcriptional pathways". Nature Reviews. Molecular Cell Biology. 8 (1): 9–22. doi:10.1038/nrm2080. PMID 17183357. S2CID 41419388.
- Marx J (November 2005). "Molecular biology. P-bodies mark the spot for controlling protein production". Science. 310 (5749): 764–765. doi:10.1126/science.310.5749.764. PMID 16272094. S2CID 11106208.
- Anderson P, Kedersha N (June 2009). "RNA granules: post-transcriptional and epigenetic modulators of gene expression". Nature Reviews. Molecular Cell Biology. 10 (6): 430–436. doi:10.1038/nrm2694. PMID 19461665. S2CID 26578027.