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Heterogeneous nuclear ribonucleoproteins (hnRNPs) are complexes of RNA and protein present in the cell nucleus during gene transcription and subsequent post-transcriptional modification of the newly synthesized RNA (pre-mRNA). The presence of the proteins bound to a pre-mRNA molecule serves as a signal that the pre-mRNA is not yet fully processed and therefore not ready for export to the cytoplasm. [1] Since most mature RNA is exported from the nucleus relatively quickly, most RNA-binding protein in the nucleus exist as heterogeneous ribonucleoprotein particles. After splicing has occurred, the proteins remain bound to spliced introns and target them for degradation.

hnRNPs are also integral to the 40S subunit of the ribosome and therefore important for the translation of mRNA in the cytoplasm. [2] However, hnRNPs also have their own nuclear localization sequences (NLS) and are therefore found mainly in the nucleus. Though it is known that a few hnRNPs shuttle between the cytoplasm and nucleus, immunofluorescence microscopy with hnRNP-specific antibodies shows nucleoplasmic localization of these proteins with little staining in the nucleolus or cytoplasm. [3] This is likely because of its major role in binding to newly transcribed RNAs. High-resolution immunoelectron microscopy has shown that hnRNPs localize predominantly to the border regions of chromatin, where it has access to these nascent RNAs. [4]

The proteins involved in the hnRNP complexes are collectively known as heterogeneous ribonucleoproteins. They include protein K and polypyrimidine tract-binding protein (PTB), which is regulated by phosphorylation catalyzed by protein kinase A and is responsible for suppressing RNA splicing at a particular exon by blocking access of the spliceosome to the polypyrimidine tract. [5]: 326  hnRNPs are also responsible for strengthening and inhibiting splice sites by making such sites more or less accessible to the spliceosome. [6] Cooperative interactions between attached hnRNPs may encourage certain splicing combinations while inhibiting others. [7]

Role in cell cycle and DNA damage

hnRNPs affect several aspects of the cell cycle by recruiting, splicing, and co-regulating certain cell cycle control proteins. Much of hnRNPs' importance to cell cycle control is evidenced by its role as an oncogene, in which a loss of its functions results in various common cancers. Often, misregulation by hnRNPs is due to splicing errors, but some hnRNPs are also responsible for recruiting and guiding the proteins themselves, rather than just addressing nascent RNAs.

BRCA1

hnRNP C is a key regulator of the BRCA1 and BRCA2 genes. In response to ionizing radiation, hnRNP C partially localizes to the site of DNA damage, and when depleted, S-phase progression of the cell is impaired. [8] Additionally, BRCA1 and BRCA2 levels fall when hnRNP C is lost. BRCA1 and BRCA2 are crucial tumor-suppressor genes which are strongly implicated in breast cancers when mutated. BRCA1 in particular causes G2/M cell cycle arrest in response to DNA damage via the CHEK1 signaling cascade. [9] hnRNP C is important for the proper expression of other tumor suppressor genes including RAD51 and BRIP1 as well. Through these genes, hnRNP is necessary to induce cell-cycle arrest in response to DNA damage by ionizing radiation. [7]

HER2

HER2 is overexpressed in 20-30% of breast cancers and is commonly associated with poor prognosis. It is therefore an oncogene whose differently spliced variants have been shown to have different functions. Knocking down hnRNP H1 was shown to increase the amount of an oncogenic variant Δ16HER2. [10] HER2 is an upstream regulator of cyclin D1 and p27, and its overexpression leads to the deregulation of the G1/S checkpoint. [11]

p53

hnRNPs also play a role in DNA damage response in coordination with p53. hnRNP K is rapidly induced after DNA damage by ionizing radiation. It cooperates with p53 to induce the activation of p53 target genes, thus activating cell-cycle checkpoints. [12] p53 itself is an important tumor-suppressor gene sometimes known by the epithet “the guardian of the genome.” hnRNP K’s close association with p53 demonstrates its importance in DNA damage control.

p53 regulates a large group of RNAs that are not translated into protein, called large intergenic noncoding RNAs ( lincRNAs). p53 suppression of genes is often carried out by a number of these lincRNAs, which in turn have been shown to act though hnRNP K. Through physical interactions with these molecules, hnRNP K is targeted to genes and transmits p53 regulation, thus acting as a key repressor within the p53-dependent transcriptional pathway. [13] [14]

Functions

hnRNP serves a variety of processes in the cell, some of which include:

  1. Preventing the folding of pre-mRNA into secondary structures that may inhibit its interactions with other proteins.
  2. Possible association with the splicing apparatus.
  3. Transport of mRNA out of the nucleus.

The association of a pre-mRNA molecule with a hnRNP particle prevents formation of short secondary structures dependent on base pairing of complementary regions, thereby making the pre-mRNA accessible for interactions with other proteins.

CD44 Regulation

hnRNP has been shown to regulate CD44, a cell-surface glycoprotein, through splicing mechanisms. CD44 is involved in cell-cell interactions and has roles in cell adhesion and migration. Splicing of CD44 and the functions of the resulting isoforms are different in breast cancer cells, and when knocked down, hnRNP reduced both cell viability and invasiveness. [15]

Telomeres

Several hnRNPs interact with telomeres, which protect the ends of chromosomes from deterioration and are often associated with cell longevity. hnRNP D associates with the G-rich repeat region of the telomeres, possibly stabilizing the region from secondary structures which would inhibit telomere replication. [16]

hnRNP has also been shown to interact with telomerase, the protein responsible for elongating telomeres and prevent their degradation. hnRNPs C1 and C2 associate with the RNA component of telomerase, which improves its ability to access the telomere. [17] [18] [19]

Examples

Human genes encoding heterogeneous nuclear ribonucleoproteins include:

See also

  • Messenger RNP: complex between mRNA and protein(s) present in nucleus

References

  1. ^ Kinniburgh, A. J.; Martin, T. E. (1976-08-01). "Detection of mRNA sequences in nuclear 30S ribonucleoprotein subcomplexes". Proceedings of the National Academy of Sciences. 73 (8): 2725–2729. Bibcode: 1976PNAS...73.2725K. doi: 10.1073/pnas.73.8.2725. ISSN  0027-8424. PMC  430721. PMID  1066686.
  2. ^ Beyer, Ann L.; Christensen, Mark E.; Walker, Barbara W.; LeStourgeon, Wallace M. (1977). "Identification and characterization of the packaging proteins of core 40S hnRNP particles". Cell. 11 (1): 127–138. doi: 10.1016/0092-8674(77)90323-3. PMID  872217. S2CID  41245800.
  3. ^ Dreyfuss, Gideon; Matunis, Michael J.; Pinol-Roma, Serafin; Burd, Christopher G. (1993-06-01). "hnRNP Proteins and the Biogenesis of mRNA". Annual Review of Biochemistry. 62 (1): 289–321. doi: 10.1146/annurev.bi.62.070193.001445. ISSN  0066-4154. PMID  8352591.
  4. ^ Fakan, S.; Leser, G.; Martin, T. E. (January 1984). "Ultrastructural distribution of nuclear ribonucleoproteins as visualized by immunocytochemistry on thin sections". The Journal of Cell Biology. 98 (1): 358–363. doi: 10.1083/jcb.98.1.358. ISSN  0021-9525. PMC  2113018. PMID  6231300.
  5. ^ Matsudaira PT, Lodish HF, Berk A, Kaiser C, Krieger M, Scott MP, Bretscher A, Ploegh H (2008). Molecular cell biology. San Francisco: W.H. Freeman. ISBN  978-0-7167-7601-7.
  6. ^ Matlin, Arianne J.; Clark, Francis; Smith, Christopher W. J. (2005). "Understanding alternative splicing: towards a cellular code". Nature Reviews Molecular Cell Biology. 6 (5): 386–398. doi: 10.1038/nrm1645. ISSN  1471-0080. PMID  15956978. S2CID  14883495.
  7. ^ a b Martinez-Contreras, Rebeca; Cloutier, Philippe; Shkreta, Lulzim; Fisette, Jean-François; Revil, Timothée; Chabot, Benoit (2007). "HNRNP Proteins and Splicing Control". Alternative Splicing in the Postgenomic Era. Advances in Experimental Medicine and Biology. Vol. 623. pp.  123–147. doi: 10.1007/978-0-387-77374-2_8. ISBN  978-0-387-77373-5. ISSN  0065-2598. PMID  18380344.
  8. ^ Anantha, Rachel W.; Alcivar, Allen L.; Ma, Jianglin; Cai, Hong; Simhadri, Srilatha; Ule, Jernej; König, Julian; Xia, Bing (2013-04-09). "Requirement of Heterogeneous Nuclear Ribonucleoprotein C for BRCA Gene Expression and Homologous Recombination". PLOS ONE. 8 (4): e61368. Bibcode: 2013PLoSO...861368A. doi: 10.1371/journal.pone.0061368. ISSN  1932-6203. PMC  3621867. PMID  23585894.
  9. ^ Yoshida, Kiyotsugu; Miki, Yoshio (November 2004). "Role of BRCA1 and BRCA2 as regulators of DNA repair, transcription, and cell cycle in response to DNA damage". Cancer Science. 95 (11): 866–871. doi: 10.1111/j.1349-7006.2004.tb02195.x. ISSN  1347-9032. PMID  15546503. S2CID  24297965.
  10. ^ Gautrey, Hannah; Jackson, Claire; Dittrich, Anna-Lena; Browell, David; Lennard, Thomas; Tyson-Capper, Alison (2015-10-03). "SRSF3 and hnRNP H1 regulate a splicing hotspot of HER2 in breast cancer cells". RNA Biology. 12 (10): 1139–1151. doi: 10.1080/15476286.2015.1076610. ISSN  1547-6286. PMC  4829299. PMID  26367347.
  11. ^ Moasser, M M (2007). "The oncogene HER2: its signaling and transforming functions and its role in human cancer pathogenesis". Oncogene. 26 (45): 6469–6487. doi: 10.1038/sj.onc.1210477. ISSN  1476-5594. PMC  3021475. PMID  17471238.
  12. ^ Moumen, Abdeladim; Masterson, Philip; O'Connor, Mark J.; Jackson, Stephen P. (2005). "hnRNP K: An HDM2 Target and Transcriptional Coactivator of p53 in Response to DNA Damage". Cell. 123 (6): 1065–1078. doi: 10.1016/j.cell.2005.09.032. PMID  16360036. S2CID  16756766.
  13. ^ Huarte, Maite; Guttman, Mitchell; Feldser, David; Garber, Manuel; Koziol, Magdalena J.; Kenzelmann-Broz, Daniela; Khalil, Ahmad M.; Zuk, Or; Amit, Ido (2010). "A Large Intergenic Noncoding RNA Induced by p53 Mediates Global Gene Repression in the p53 Response". Cell. 142 (3): 409–419. doi: 10.1016/j.cell.2010.06.040. PMC  2956184. PMID  20673990.
  14. ^ Sun, Xinghui; Ali, Mohamed Sham Shihabudeen Haider; Moran, Matthew (2017-09-01). "The role of interactions of long non-coding RNAs and heterogeneous nuclear ribonucleoproteins in regulating cellular functions". Biochemical Journal. 474 (17): 2925–2935. doi: 10.1042/bcj20170280. ISSN  0264-6021. PMC  5553131. PMID  28801479.
  15. ^ Loh, Tiing Jen; Moon, Heegyum; Cho, Sunghee; Jang, Hana; Liu, Yong Chao; Tai, Hongmei; Jung, Da-Woon; Williams, Darren R.; Kim, Hey-Ran (September 2015). "CD44 alternative splicing and hnRNP A1 expression are associated with the metastasis of breast cancer". Oncology Reports. 34 (3): 1231–1238. doi: 10.3892/or.2015.4110. ISSN  1791-2431. PMID  26151392.
  16. ^ Eversole, A.; Maizels, N. (August 2000). "In vitro properties of the conserved mammalian protein hnRNP D suggest a role in telomere maintenance". Molecular and Cellular Biology. 20 (15): 5425–5432. doi: 10.1128/mcb.20.15.5425-5432.2000. ISSN  0270-7306. PMC  85994. PMID  10891483.
  17. ^ Ford, L. P.; Suh, J. M.; Wright, W. E.; Shay, J. W. (December 2000). "Heterogeneous nuclear ribonucleoproteins C1 and C2 associate with the RNA component of human telomerase". Molecular and Cellular Biology. 20 (23): 9084–9091. doi: 10.1128/mcb.20.23.9084-9091.2000. ISSN  0270-7306. PMC  86561. PMID  11074006.
  18. ^ Ford, Lance P.; Wright, Woodring E.; Shay, Jerry W. (2002-01-21). "A model for heterogeneous nuclear ribonucleoproteins in telomere and telomerase regulation". Oncogene. 21 (4): 580–583. doi: 10.1038/sj.onc.1205086. ISSN  0950-9232. PMID  11850782.
  19. ^ Görlach, M.; Burd, C. G.; Dreyfuss, G. (1994-09-16). "The determinants of RNA-binding specificity of the heterogeneous nuclear ribonucleoprotein C proteins". The Journal of Biological Chemistry. 269 (37): 23074–23078. doi: 10.1016/S0021-9258(17)31621-6. ISSN  0021-9258. PMID  8083209.
  20. ^ Dityatev, Alexander; El-Husseini, Alaa (2006-11-24). Molecular Mechanisms of Synaptogenesis. Springer. ISBN  9780387325620.

Further reading

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