Basic proteins and nucleic acids are assembled into complexes in a reaction that must be facilitated by nuclear chaperones in order to prevent protein aggregation and formation of non-specific nucleoprotein complexes. The nucleophosmin/nucleoplasmin (NPM) family of chaperones [NPM1 (nucleophosmin), NPM2 (nucleoplasmin) and NPM3] have diverse functions in the cell and are ubiquitously represented throughout the animal kingdom. The importance of this family in cellular processes such as chromatin remodeling, genome stability, ribosome biogenesis, DNA duplication and transcriptional regulation has led to the rapid growth of information available on their structure and function. The present review covers different aspects related to the structure, evolution and function of the NPM family. Emphasis is placed on the long-term evolutionary mechanisms leading to the functional diversification of the family members, their role as chaperones (particularly as it pertains to their ability to aid in the reprogramming of chromatin), and the importance of NPM2 as an essential component of the amphibian chromatin remodeling machinery during fertilization and early embryonic development.
Methyl-CpG-binding protein 2 (MeCP2) is a chromatin-binding protein that mediates transcriptional regulation, and is highly abundant in brain. The nature of its binding to reconstituted templates has been well characterized in vitro. However, its interactions with native chromatin are less understood. Here we show that MeCP2 displays a distinct distribution within fractionated chromatin from various tissues and cell types. Artificially induced global changes in DNA methylation by 3-aminobenzamide or 5-aza-2′-deoxycytidine, do not significantly affect the distribution or amount of MeCP2 in HeLa S3 or 3T3 cells. Most MeCP2 in brain is chromatin-bound and localized within highly nuclease-accessible regions. We also show that, while in most tissues and cell lines, MeCP2 forms stable complexes with nucleosome, in brain, a fraction of it is loosely bound to chromatin, likely to nucleosome-depleted regions. Finally, we provide evidence for novel associations of MeCP2 with mononucleosomes containing histone H2A.X, H3K9me2 and H3K27me3 in different chromatin fractions from brain cortex and in vitro. We postulate that the functional compartmentalization and tissue-specific distribution of MeCP2 within different chromatin types may be directed by its association with nucleosomes containing specific histone variants, and post-translational modifications.
The proper assembly of basic proteins with nucleic acids is a reaction that must be facilitated to prevent protein aggregation and formation of nonspecific nucleoprotein complexes. The proteins that mediate this orderly protein assembly are generally termed molecular (or nuclear) chaperones. The nucleophosmin/ nucleoplasmin (NPM) family of molecular chaperones encompasses members ubiquitously expressed in many somatic tissues (NPM1 and -3) or specific to oocytes and eggs (NPM2). The study of this family of molecular chaperones has experienced a renewed interest in the past few years. However, there is a lack of information regarding the molecular evolution of these proteins. This work represents the first attempt to characterize the long-term evolution followed by the members of this family. Our analysis shows that there is extensive silent divergence at the nucleotide level suggesting that this family has been subject to strong purifying selection at the protein level. In contrast to NPM1 and NPM-like proteins in invertebrates, NPM2 and NPM3 have a polyphyletic origin. Furthermore, the presence of selection for high frequencies of acidic residues as well as the existence of higher levels of codon bias was detected at the C-terminal ends, which can be ascribed to the critical role played by these residues in constituting the acidic tracts and to the preferred codon usage for phosphorylatable amino acids at these regions.
In this article, we briefly review the structural and functional information currently available on nucleoplasmin. Special emphasis is placed on the discussion of the molecular mechanism involved in the sperm chromatin remodelling activity of this protein. A model is proposed based on current crystallographic data, recent biophysical and functional studies, as well as in the previously available information.
It was perhaps a lucky coincidence that the early attempts to establish the chemical composition of the cell nucleus were initially carried out on such diverse biological systems as salmon sperm heads (1) and geese and chicken erythrocytes (2). Examination of sperm and erythrocyte systems, respectively, lead to the protamine and histone concepts (3). We know with certainty that, with the exception of the male gametes, all somatic cells exclusively contain histones. Hence, in metazoans, protamines (4, 5) are confined to the sperm nuclear chromatin, and even among sperm, protamines are not always present. Indeed, a large number of metazoans contain somatic-like histones in their sperm, and some crustaceans (order Decapoda) lack any chromosomal proteins in their sperm (6, 7). Therefore, in contrast to the somatic nucleus, sperm chromatin may have a much more diverse protein composition. It was not until the first attempt of classification of the sperm nuclear basic proteins (SNBPs) 2 by David Bloch (6,8), an effort later on extended by Harold Kasinsky (7), that a clearer picture started to emerge in this regard.More recently, an enormous effort has been carried out in several laboratories, including our own (9 -15), to extend this analysis to a large number of representative organisms from the different phylogenetic groups. With a broader perspective now available, SNBP heterogeneity can be restricted to three major groups or types: histone (H), protamine (P), and protamine-like (PL) (16).Histones consist of core histones (histones H2A, H2B, H3, and H4) and linker histones (histone H1 family). The names refer to the structural role of these proteins. Core histones are responsible for constraining DNA wrapped about a histone core to produce a nucleoprotein complex (chromatin subunit) known as a nucleosome core particle. Linker histones bind to the linker DNA regions connecting adjacent nucleosome core particles and assist in the folding of the chromatin fiber (17).Protamines are a highly compositionally and structurally heterogeneous group of proteins (9). They exhibit a high charge density and a prevalence of arginine in their composition (13), a fact that it is most likely related to the higher affinity with which this basic amino acid binds to DNA (18). They lack any secondary structure in solution but may adopt a folded conformation upon interaction with DNA. Protamine-like proteins share compositional and structural similarities between histones and protamines (9, 16). Hence they represent a structurally intermediate group that will be discussed more extensively in the following sections of this review.To a certain extent, all three types of SNBP can be considered structurally analogous as all of them produce folded chromatin fibers of 30 -50 nm (19) regardless of the particular structure of the individual nucleoprotamine complexes. At the functional level, somatic histones bind to DNA in a highly dynamic way that not only helps in the folding of the genome but also has an important role in the epigenetic reg...
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