Frehlick LJ , Eirín-López JM , Jeffery ED , Hunt DF , Ausió J .

R01 GM037537 NIGMS NIH HHS

	Figure 1. Electrophoretic characterization of R. catesbeiana, X. laevis and B. marinus SNPBs. Characterization of histones and SNBPs extracted from different tissues by: A) SDS-PAGE; B) AUT-PAGE run for a short time duration to separate histones (H), protamine-like proteins (PL) and protamines (P); and C) AUT-PAGE run for a longer duration to separate histones. Lane 1: R. catesbeiana liver; lane 2: R. catesbeiana blood; lane 3: R. catesbeiana sperm; lane 4: R. catesbeiana testes; lane 5: X. laevis testes; lane 6: B. marinus testes. CM; Chicken erythrocyte histones used as a histone marker. The SNBPs of X. laevis in lane 5, called sperm-specific proteins (SP1-6), are labeled and arrows (<) are used when needed to clearly indicate which bands the labels refer to. The asterisks point to the sperm-specific histone H1 complement in R. catesbeiana.
	Figure 2. Western blot analysis of egg extracts and purified nucleoplasmin proteins. A) SDS-PAGE of heat soluble egg extracts from: Lane1, X.laevis; lane 2, B. marinus; lane 3, R. catesbeiana. Egg extract aliquots were mixed with an equal volume of 2 × SDS sample buffer and loaded in the gel without any previous boiling. Under these conditions the nucleoplasmin protein retains its pentameric conformatiom [25]. Molecular weights are a PageRuler Protein Ladder (Fermentas Life Sciences, Burlington, ON) B) SDS-PAGE of nucleoplasmin proteins purified from the extracts of: Lane1, X. laevis; lane 2, B. marinus; lane 3, R. catesbeiana. Samples were boiled in SDS (0.1%) sample buffer for 10 minutes before loading on the gel to separated nucleoplasmin proteins into their monomeric forms. MW is a prestained broad range molecular weight protein marker (New England Biolabs, Ipswich, MA). Western blot analysis was done using a polyclonal antibody elicited against recombinant X. laevis nucleoplasmin [28] and the results are shown in the lower panels of both A) and B) below the corresponding gels.
	Figure 3. X. tropicalis nucleoplasmin gene. A) Nucleotide sequence and corresponding protein sequence of a nucleoplasmin cDNA from X. tropicalis [GenBank: NM_001016938]. The arrow heads and lines indicate the sites of insertion of the different introns. B) Schematic representation of the organization and structure of the gene. Exons are schematically represented by solid boxes, with black representing translated regions and grey representing untranslated regions. Introns are indicated by black lines. The numbers indicate the basepair size of the regions below them.
	Figure 4. Coding nucleotide sequences of B. marinus and R. catesbeiana nucleoplasmin. The nucleotide sequences determined in this study and translated protein sequences of nucleoplasmin cDNAs from A) B. marinus [GenBank: DQ340657] and B) R. catesbeiana [GenBank:DQ340656] are shown.
	Figure 5. Protein sequence alignment of amphibian nucleoplasmins. The primary structures of nucleoplasmin from X. laevis (A) [60] [GenBank: X04766], X. laevis (Burglin et al., 1987) [GenBank: CAA68363], X. tropicalis [GenBank: NP_001016938], B. marinus and R. catesbeiana are shown. Identical amino acids are denoted by an asterisk, highly similar residues by a colon, and less similar residues by a period, as determined by CLUSTAL W software. The partial protein sequences of B. marinus and R. catesbeiana determined by mass spectroscopy peptide sequencing are underlined. The highly structured N-terminal protein core spans amino acids 1–120 and has β sheets (β1–8), two type 1 turns (T1) and a β hairpin (βh) [8]. The other boxes represent the A1, A2, A3 polyglutamic tracts and the bipartite nuclear localization signal (NLS), as indicated.
	Figure 6. Phylogenetic tree of nucleophosmin/nucleoplasmin family members from various metazoans. Amino acid sequences were aligned with CLUSTAL W (Thompson et al., 1994), and the tree was produced with MEGA 3.1 (Kumar et al., 2004) using the neighbor-joining method. Two other histone-binding proteins, NASP [61] and N1/N2 [62], which are closely related to each other [61] but unrelated to the nucleophosmin/nucleoplasmin family were used to root the tree. Bootstrap significance values are shown at the corresponding internal nodes after 1000 replications.
	Figure 7. Northern dot blot hybridizations comparing Npm2 and Npm1 mRNA levels in different R. catesbeiana tissues. In the top two rows 7.5 μg of total RNA was loaded per well and the blot was probed with P32 labeled X. laevis Npm1 or R. catesbeiana Npm2 cDNA amplified from PCR. In the bottom row 1.5 μg of total RNA was loaded per well and the blot was probed with a P32 labeled 18S ribosome cDNA probe which was used as a loading control.
	Figure 8. Schematic representation of the amphibian sperm chromatin remodeling by nucleoplasmin. The chromatin structures corresponding to each of the different SNBP types is schematically shown in the upper part of the figure. Upon fertilization of the egg, nucleoplasmin (shown here as a pentamer) stereo-specifically bound to histone H2A-H2B dimers exchanges these dimers with the SNBP components that become non-specifically (electrostatically) bound to the polyglutamic tracts of the unstructured C-terminal tails of the molecule. Note that only chromosomal proteins associated with the "linker-like" (non-helically constrained) domains of the sperm chromatin are extracted by nucleoplasmin which is highly phosphorylated at this stage of development [39]. Other nuclear chaperones are likely involved in the transition from the sperm chromatin to the male pronuclear chromatin. In this regard N1/N2 would be responsible for the assembly of H3/H4 [6] and NAP-1 for the assembly of egg/early embryo-specific histone B4 like histone H1 molecules [45].

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