Nucleoplasmin

Nucleoplasmin, the first identified molecular chaperone, is a thermostable acidic protein with a pentameric structure. The protein was first isolated from Xenopus species, and is now recognized as a highly conserved histone chaperone found across animals and other eukaryotes.

Family

The nucleoplasmin/nucleophosmin protein family comprises Nucleophosmin, Nucleoplasmin 2 , Nucleoplasmin 3, and nucleoplasmin-like proteins. These proteins typically share a pentameric N-terminal β-sandwich core. While NPM1 functions broadly in nuclear organization and cellular homeostasis, NPM2 is primarily associated with histone chaperoning during early development and is most frequently described as the canonical nucleoplasmin. The human NPM1 gene is also of clinical interest, as mutations in it are linked to acute myeloid leukemia.
In mammalian oocytes, NPM1, NPM2, and NPM3 are co-expressed and appear to function cooperatively during sperm chromatin remodeling, with NPM2 serving as the dominant oocyte form and NPM1 and NPM3 providing complementary and partially compensatory activities. This functional overlap is supported by evidence that the three proteins share similar histone chaperone properties and contribute collectively to paternal chromatin reorganization during early development.
Human NPM paralogs also differ in their oligomerization behavior. NPM1 and NPM2 assemble into highly stable pentamers that can further associate into decamers, whereas NPM3 primarily forms dimers and becomes pentamer-competent only when incorporated into mixed complexes with NPM1. These hetero-oligomeric assemblies typically contain a 4:1 NPM1:NPM3 stoichiometry and have been demonstrated through crosslinking and blue-native polyacrylamide gel electrophoresis analyses. Incorporation into such mixed pentamers enables NPM3 to acquire full histone chaperone activity, indicating a cooperative mechanism among NPM family members in vivo. In addition, protein–protein interaction network analysis shows that NPM1, NPM2, and NPM3 each participate in distinct interaction clusters, with NPM2 most strongly associated with transcriptional regulation, chromatin structure organization, and cell cycle–related protein networks.

Human proteins

Humans express three members of the nucleoplasmin family:

Nucleophosmin
Nucleoplasmin 2
Nucleoplasmin 3
Protozoan nucleoplasmin homologs

A nucleoplasmin-like histone chaperone has also been characterized in the malaria parasite Plasmodium falciparum, whose N-terminal domain adopts the same β-sandwich fold seen in vertebrate nucleoplasmins and assembles into a stable pentamer. Phylogenetic analysis places PfNPM with FKBP-type and HD-tuin nucleoplasmin clades rather than with the vertebrate NPM1–3 group, indicating its divergent evolutionary origin.
Structural studies of the P. falciparum nucleoplasmin homolog show that both the N- and C-termini extend from the distal face of the pentamer, reflecting an overall topology similar to NPM2 and other metazoan family members. Although this protozoan protein lacks the continuous A1 acidic tract found in vertebrate nucleoplasmins, it contains multiple acidic patches, including residues in loops L2 and L6, that generate a negatively charged surface suited for histone binding. Biophysical analyses further demonstrate that the P. falciparum pentamer is highly resistant to thermal and chemical denaturation, remaining intact at elevated temperatures and in high-salt environments, a property common across nucleoplasmins.

Structure

Nucleoplasmin 2 is encoded by a gene on chromosome 8p21.3 and includes 10 exons producing a 214-amino-acid protein. NPM2 has a two-domain architecture consisting of an N-terminal core domain and a C-terminal tail domain. The NTD forms a compact β-sandwich of eight antiparallel β-strands that assembles into a homopentamer, generating the characteristic doughnut-shaped oligomer of the nucleoplasmin family. Crystal structures of the Xenopus nucleoplasmin core reveal that each monomer adopts a jellyroll-type β-barrel, and the resulting wedge-shaped subunits pack tightly to form a highly stable pentameric ring. The core domain also contains several conserved sequence motifs that stabilize the hydrophobic β-barrel and mediate contacts between neighboring pentamers, supporting higher-order oligomerization. Under certain conditions, two nucleoplasmin pentamers can associate into a decamer, providing an expanded platform for histone binding and storage. Structural analyses indicate that specific residues—such as Glu57 in the conserved AKEE loop and Gln84 in the adjacent Q-loop—mediate inter-pentamer hydrogen bonding, contributing to decamer stabilization. Computational docking studies further support this interface, identifying Glu57 and Gln84 as key contact residues driving pentamer–pentamer recognition.
The C-terminal tail is an intrinsically disordered region containing the acidic A1, A2 and A3 tracts, a bipartite nuclear localization signal, and KR-rich basic segment. Unlike other nucleoplasmins, NPM2 contains a shortened A1 acidic loop consisting of a single glutamic acid residue, which may contribute to the inability of its core domain to bind to histones directly. The A2 acidic stretch serves as the principal histone-interaction and regulatory site. Together, this pentameric and highly acidic structure provides a scaffold capable of simultaneously engaging multiple histones. Structural analyses, including crystal and cryo-EM studies of nucleoplasmin-like proteins such as AtFKBP53, confirm that this overall fold and assembly mode are conserved across diverse eukaryotic species.

Functions

NPM2 participates in various significant cellular activities like sperm chromatin remodeling, nucleosome assembly, genome stability, ribosome biogenesis, DNA replication, and transcriptional regulation. During the assembly of regular nucleosomal arrays, these nucleoplasmins facilitate histone deposition onto DNA by binding to the histones and delivering them to nucleosomal templates. While some studies report that this reaction requires ATP, others indicate that it can occur independently of ATP. Their acidic regions mediate histone binding, allowing NPM2 to buffer, store, and release histones in a controlled manner while preventing nonspecific interaction during chromatin assembly. As a result, NPM2 often participates in chromatin remodeling, contributing to gene expression, developmental processes, chromatin architecture, and the regulated deposition of histones.

Maternal histone storage

In Xenopus eggs, NPM2 functions as a storage histone chaperone, sequestering a large maternal pool of core histones that will later be used to package the rapidly replicating embryonic genome. Related nucleoplasmin family members in other species also act as sinks for histones displaced during sperm development and fertilization, ensuring balanced histone availability during early embryogenesis.

Sperm chromatin remodeling

This protein plays an essential role in remodeling sperm chromatin after fertilization. In vertebrates, it removes sperm-specific basic proteins and replaces them with histones, enabling the paternal DNA to decondense and become transcriptionally active. Following fertilization, the paternal genome must undergo extensive reorganization before it can participate in embryonic development, and this process depends on the orderly exchange of sperm chromatin proteins for maternal histones. The reconfiguration of paternal chromatin is an early developmental milestone that enables the formation of the functional male pronucleus and prepares the genome for the first round of DNA synthesis. Developmental studies across multiple species show that remodeling of sperm chromatin is a conserved requirement for initiating transcription from the paternal genome during early cleavage stages. In this system, the transformation of sperm chromatin proceeds through stepwise displacement of sperm-specific nuclear proteins, establishing compatibility between the paternal and maternal pronuclei. These transitions occur before the first round of zygotic DNA replication and before the initiation of the early embryonic transcriptional program. Collectively, these events demonstrate the indispensable role of sperm chromatin remodeling in paternal genome activation and early embryogenesis.
Beyond these in vivo functions, biochemical comparisons of human NPM paralogs have revealed additional mechanistic differences within the family. Chromatin remodeling and nucleosome assembly assays show that NPM1 and NPM2 each possess intrinsic nucleosome assembly activity, whereas NPM3 displays minimal activity on its own. NPM3 becomes functionally competent only when incorporated into hetero-oligomers with NPM1, indicating a cooperative mechanism among family members. Phosphorylation is also a key regulator of NPM2 activity: unmodified NPM2 exhibits lower sperm chromatin decondensation efficiency than NPM1, but phosphomimetic mutations at specific N-terminal and C-terminal residues markedly increase its sperm decondensation and histone-transfer activity, mirroring the activation that occurs during meiotic maturation in oocytes.

Histone interaction

Histone association and release are regulated through a coordinated set of structural features within NPM2. The N-terminal core forms a pentameric β-sandwich that provides a stable scaffold for histone loading, while the intrinsically disordered C-terminal tail contains acidic stretches, including the A2 region, which structural analyses identify as the primary histone-binding interface. A2 engages both H2A–H2B dimers and H3–H4 through a conserved acidic-aromatic motif. Although NPM2 is highly acidic, structural analyses indicate that histone binding relies largely on hydrophobic interactions rather than electrostatic attraction.
Experimental reconstitution assays further show that NPM2 associates with both H2A–H2B dimers and H3–H4 tetramers, supporting models in which nucleoplasmin stabilizes pre-assembled histone complexes prior to nucleosome deposition. In addition to core histones, Xenopus NPM2 can also bind linker histones such as H1 and H5, exhibiting higher affinity for these variants and suggesting a dual role in histone storage and chromatin remodeling. Biochemical studies show that Xenopus NPM2 pentamers can bind up to five H2A–H2B dimers with decreasing affinity, supporting its role as a high-capacity histone storage chaperone.
Computational docking studies predict three potential histone-binding pockets within the NPM2 core domain and suggest specific contacts with H2A–H2B dimers. Modeling and docking analyses indicate that NPM2 pentamers preferentially bind H2A–H2B dimers, whereas NPM2 decamers can accommodate both H2A–H2B dimers and H3–H4 tetramers, forming octamer-like complexes prior to nucleosome assembly.
The tail also includes a basic C-terminal segment and a nuclear localization signal capable of folding back onto the A2, generating an autoinhibited state where key histone-binding residues are partially shielded. Histone binding disrupts these intramolecular contacts, shifting the tail into a more open conformation that exposes the acidic residues and promotes histone deposition. This regulatory "self-shielding" mechanism is considered a general feature of NPM2 and is likely conserved among other vertebrate nucleoplasmins. Consistent with other histone chaperones, NPM2 is thought to prevent undesired histone–DNA and histone–histone interactions by transiently binding free histones and shielding their positively charged surfaces, thereby biasing assembly toward proper nucleosome formation rather than nonspecific aggregation.