A deoxyribonucleoprotein (DNP) is a complex of DNA and protein.[12] The prototypical examples are
nucleosomes, complexes in which genomic DNA is wrapped around clusters of eight
histone proteins in
eukaryotic cell nuclei to form
chromatin.
Protamines replace histones during spermatogenesis.
In eukaryotic cells, DNA is associated with about an equal mass of histone proteins in a highly condensed nucleoprotein complex called
chromatin.[14] Deoxyribonucleoproteins in this kind of complex interact to generate a multiprotein regulatory complex in which the intervening DNA is looped or wound. The deoxyribonucleoproteins participate in regulating DNA replication and transcription.[15]
Deoxyribonucleoproteins are also involved in
homologous recombination, a process for
repairing DNA that appears to be nearly universal. A central intermediate step in this process is the interaction of multiple copies of a
recombinase protein with single-stranded DNA to form a DNP filament. Recombinases employed in this process are produced by
archaea (RadA recombinase),[16] by bacteria (RecA recombinase)[17] and by eukaryotes from yeast to humans (
Rad51 and
Dmc1 recombinases).[18]
A ribonucleoprotein (RNP) is a complex of
ribonucleic acid and
RNA-binding protein. These complexes play an integral part in a number of important biological functions that include transcription, translation and regulating gene expression[20] and regulating the metabolism of RNA.[21] A few examples of RNPs include the
ribosome, the enzyme
telomerase,
vault ribonucleoproteins,
RNase P,
hnRNP and small nuclear RNPs (
snRNPs), which have been implicated in
pre-mRNAsplicing (
spliceosome) and are among the main components of the
nucleolus.[22] Some viruses are simple ribonucleoproteins, containing only one molecule of RNA and a number of identical protein molecules. Others are ribonucleoprotein or deoxyribonucleoprotein complexes containing a number of different proteins, and exceptionally more nucleic acid molecules.[citation needed] Currently, over 2000 RNPs can be found in the RCSB Protein Data Bank (PDB).[23] Furthermore, the
Protein-RNA Interface Data Base (PRIDB) possesses a collection of information on RNA-protein interfaces based on data drawn from the PDB.[24] Some common features of protein-RNA interfaces were deduced based on known structures. For example, RNP in snRNPs have an RNA-binding
motif in its RNA-binding protein.
Aromaticamino acid residues in this motif result in stacking interactions with RNA.
Lysine residues in the
helical portion of RNA-binding proteins help to stabilize interactions with nucleic acids. This nucleic acid binding is strengthened by
electrostatic attraction between the positive lysine
side chains and the negative
nucleic acidphosphate backbones. Additionally, it is possible to
model RNPs computationally.[25] Although computational methods of deducing RNP structures are less accurate than experimental methods, they provide a rough model of the structure which allows for predictions of the identity of significant amino acids and nucleotide residues. Such information helps in understanding the overall function the RNP.
'RNP' can also refer to
ribonucleoprotein particles. Ribonucleoprotein particles are distinct intracellular foci for
post-transcriptional regulation. These particles play an important role in
influenza A virusreplication.[27] The influenza viral genome is composed of eight ribonucleoprotein particles formed by a complex of
negative-sense RNA bound to a viral nucleoprotein. Each RNP carries with it an
RNA polymerase complex. When the nucleoprotein binds to the
viralRNA, it is able to expose the nucleotide bases which allow the viral polymerase to
transcribe RNA. At this point, once the virus enters a host cell it will be prepared to begin the process of replication.
The ribonucleoproteins play a role of protection.
mRNAs never occur as free RNA molecules in the cell. They always associate with ribonucleoproteins and function as ribonucleoprotein complexes.[14]
In the same way, the genomes of negative-strand RNA viruses never exist as free RNA molecule. The ribonucleoproteins protect their genomes from
RNase.[29] Nucleoproteins are often the major
antigens for viruses because they have strain-specific and group-specific
antigenic determinants.
^Ng, Andy Ka-Leung; Wang, Jia-Huai; Shaw, Pang-Chui (2009-05-27). "Structure and sequence analysis of influenza A virus nucleoprotein". Science in China Series C: Life Sciences. 52 (5): 439–449.
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^Ruigrok, Rob WH; Crépin, Thibaut; Kolakofsky, Dan (2011). "Nucleoproteins and nucleocapsids of negative-strand RNA viruses". Current Opinion in Microbiology. 14 (4): 504–510.
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