Critical role of the H6-H7 loop in the conformational adaptation of all-trans retinoic acid and synthetic retinoids within the ligand-binding site of RARalpha.

The pleiotropic effects of the natural and synthetic retinoids are mediated by the activation of the two subfamilies of nuclear receptors, the retinoic acid receptors (RARs) and the retinoic X receptors (RXRs). At the molecular level, these events begin with the specific ligand recognition by a nuclear receptor subtype. The adaptation of ligands to the receptor binding site leads to an optimal number of interactions for binding and selectivity which justifies elucidation of the structural requirements of the ligand binding pocket. To explore the contribution of H6-H7 loop folding in the ligand-induced conformational changes explained by the mouse-trap model, four RARalpha mutants were constructed. Ligand binding and transactivation studies revealed that three residues from the H6-H7 loop (Gly(301), Phe(302) and Gly(303)) are critical for the conformational adaptation of both synthetic agonists and antagonists. Model building and analysis of both RARalpha-ATRA and RARalpha-CD367 complexes demonstrate that accommodation of CD367 results in a less tight contact of the saturated ring of this ligand with the amino acid side chains of the receptor ligand-binding pocket compared with that of ATRA. According to the flexibility of the agonists tested (ATRA>TTNPB=Am580> CD367), we observed a decrease in binding that was dependent on ligand structure rigidity. In contrast, the binding and transactivating activities of the L266A mutant confirmed the structural constraints imposed by synthetic ligands on binding affinity for the receptor and revealed that subtle local rearrangements induced by specific conformational adaptation changes result in different binding affinities. Our results illustrate the dynamic nature of the interaction between RARalpha and its ligands and demonstrate the critical role of the H6-H7 loop in the binding of both synthetic retinoid agonists and antagonists.

Critical role of tyrosine 277 in the ligand-binding and transactivating properties of retinoic acid receptor alpha.

Retinoic acid receptors specifically bind all-trans-retinoic acid (RA) and function as RA-inducible transcriptional regulatory factors. Binding of RA to RARalpha, beta, and gamma is sensitive to nitration with tetranitromethane, a tyrosine-specific modifying reagent. To identify tyrosine residue(s) that are important for RA binding, we carried out chemical modification experiments with purified RARalpha ligand-binding domain (RARalpha-LBD) subjected to partial acid hydrolysis and selective proteolysis. The chemically modified peptides containing each of the three Tyr residues present in the RARalpha-LBD sequence were then analyzed and identified by high-performance liquid chromatography coupled to electrospray ionization mass spectrometry (HPLC/ESI-MS). We found that RA binding to RARalpha-LBD protected Tyr(277)-containing peptides from nitration. Protection of Tyr(277) could result either from direct masking by the bound ligand or from ligand-induced changes in receptor conformation and tyrosine accessibility. The role of Tyr residues was further documented by site directed mutagenesis using three site-specific RARalpha mutants: Y208A, Y277A, and Y362A. The affinity for RA of these mutant receptors was in the range of that of the wild-type protein, except for the Y277A receptor mutant, which displays a 15-20-fold reduction in affinity and transactivation activity for RA. Whereas mutation of Tyr(277) into alanine had a variable effect on different agonists and antagonists binding, it caused a dramatic decrease of retinoid-dependent transactivation activity. This later effect was also observed with mutation of Tyr(277) into phenylalanine. It is unlikely that major conformational changes are responsible for the lower affinity of RA binding and RA-dependent transactivation since these mutants displayed wild-type dimerization and DNA-binding activities. Limited proteolysis revealed that upon ligand binding, the Y277A mutant induced a conformational change slightly different from that obtained with the wild-type protein. These data could suggest that Tyr(277) play a critical role in the ligand-induced conformational changes required for the activation of RARalpha.

The DNA-binding protein II from Zymomonas mobilis. Complete amino acid sequence and interaction with DNA.

The primary structure of the DNA-binding protein II from Zymomonas mobilis has been determined from data provided by automated Edman degradation of the intact protein and of peptides derived from cleavage at aspartic acid and arginine residues. When compared with the homologous protein isolated from other bacteria, the DNA-binding protein II from Z mobilis shows many substitutions. Several non-conservative substitutions at positions usually highly conserved in this type of protein probably account for the weaker DNA-binding activity of this protein compared to that of the E coli protein.

Successive elution by ion-exchange chromatography of H3-H4 histone complexes differing in their degree of acetylation.

On Biorex 70 ion exchanger at neutral pH the histones H3 and H4 are usually eluted by 4 M guanidinium chloride (gdm Cl). In order to protect cysteines and methionines from oxidation we systematically added 2-mercaptoethanol to the elution buffer. This resulted in the two histones being unexpectedly eluted together at around 1 M gdm Cl. The use of a shallower gradient resulted in a division in the peak of histones, with the acetylated species of H3 and H4 being eluted first and the nonacetylated species of H3 and H4 eluted last. When histone H3 or histone H4 was applied alone or when the chromatography was performed at low pH, these histones were eluted in the usual position at about 4 M gdm Cl. These events mean that the simultaneous elution of the histones H3 and H4 at about 1 M gdm Cl involves the formation of H3-H4 complexes. Therefore, the H3-H4 complex may be obtained by ion-exchange chromatography as the H2A-H2B complex was previously; furthermore, the former was fractionated according to postsynthetic modifications. This finding provides a new basis for explaining some of the previous elution profiles of chromatin extracts.

Application of electrospray and fast atom bombardment mass spectrometry to the identification of post-translational and other chemical modifications of proteins and peptides.

Mass spectrometry is a very powerful tool in the identification of chemical modifications of proteins and peptides. Often these modifications cannot be determined by conventional techniques. This report describes the combined use of electrospray ionization mass spectrometry and fast atom bombardment mass spectrometry to complete the primary structure of proteins and peptides. Examples illustrate how mass spectrometry is used to locate sites of phosphorylation, methylation and acetylation, and identify blocking groups and unexpected side reactions such as deamidation or alkylation.

Amino acid sequence of the human intermediate basic protein 2 (HPI2) from sperm nuclei. Structural relationship with protamine P2.

Human intermediate basic protein 2 (HPI2) is a low-molecular-mass basic protein present in small amounts in human sperm nuclei. The amino acid composition of the protein, its N-terminal amino acid sequence and peptide maps obtained after digestion with endoproteinases Lys-C and Glu-C, reveal that HPI2 is structurally related to human protamine species P2 (HP2), which is rich in Arg, His and Cys residues. Compared to HP2, which is one of the two major sperm protamines, HPI2 has an N-terminal extension of 24 residues which includes six acidic residues and does not possess any Arg residues. The amino acid sequence of HPI2 (81 residues) is identical to the sequence of the C-terminal region of another minor sperm nuclear protein, human intermediate basic protein 1 (HPI1, 101 residues), which was sequenced previously [Martinage, A., Arkhis, A., Alimi, E., Sautière, P. & Chevaillier, P. (1990) Eur. J. Biochem. 191, 449-451]. Due to this structural similarity, HPI2 must be considered as an intermediate in the maturation of proprotamine HPI1 limited proteolysis.

A corrected primary structure for dog-fish Scylliorhinus caniculus protamine Z3.

We have redetermined the primary structure for dog-fish protamine using automated amino-acid sequencing associated to mass spectrometry techniques and report, on the basis of these findings, that the previously published amino-acid sequence is incorrect. The correct protamine sequence is 37 amino acids long and differs from the original published sequence by the C-terminal hexapeptide Arg32-Gly-Arg-Arg-Ser-Arg37.

Determination of the DNA-interacting region of the archaebacterial chromosomal protein MC1. Photocrosslinks with 5-bromouracil-substituted DNA.

Protein MC1 is the major chromosomal protein in methanosarcinaceae. Using photochemical crosslinking on 5-bromouracil-substituted DNA, we identified the region of the protein that interacts with it. This region is located in the C-terminal part of the polypeptide chain, and the crosslinked amino-acids are in the region 74-86. Tryptophan 74 is one of the amino-acids crosslinked to DNA.

Complete sequence of Sipunculus nudus erythrocyte histone H2B and its gene. Identification of an N,N-dimethylproline residue at the amino-terminus.

The complete amino acid sequence (122 residues) of histone H2B from erythrocytes of the marine worm Sipunculus nudus, has been established from sequence analysis of peptides generated by highly specific cleavage of the protein and from the nucleotide sequence of the encoding gene. The isolation of the H2B gene was facilitated by using a highly specific nucleotide probe, devised from amino acids 58-68 of the protein. The presence of an N,N-dimethylproline residue at the amino-terminus of the protein was established from data provided by mass spectrometry and NMR spectroscopy. This unusual post-translational modification of histone H2B generates a stable positive charge which could strongly interact with the linker DNA.

Cuttlefish sperm protamines. 1. Amino acid sequences of two distinct variants.

The amino acid sequences of two cuttlefish protamine variants Sp1 and Sp2 have been established from automated sequence analysis and mass spectrometry data. Sp1 (57 residues) and Sp2 (56 residues) have molecular masses of 8410 and 8253 Da, respectively. They are almost identical proteins which differ only by one residue of arginine and the position of two of the serine residues (14 and 37 in Sp1; 13 and 35 in Sp2). With an arginine content of about 77%, cuttlefish protamine is one of the most basic proteins which have ever been characterized and the first typical protamine sequenced in invertebrates. It is closely similar to sperm basic proteins identified in squids but strongly differs from the protamine-like components isolated from the sperm of bivalve molluscs.

Primary structure of the chromosomal proteins MC1a, MC1b, and MC1c from the archaebacterium Methanothrix soehngenii.

The chromosomal protein MC1 of Methanothrix soehngenii is a family of three variants a, b, and c. These are small basic polypeptides of 89, 87, and 90 residues, respectively. Their primary structures have been determined from automated sequence analyses of the intact proteins and from structural data provided by peptides derived from the variants by cleavage at aspartic acid, glutamic acid, arginine, and methionine residues. By comparison with variant b taken as reference, variants a and c present 18 and 24 differences, respectively. The extent of sequence homologies between protein MC1 from M. soehngenii and proteins MC1 from two other species of Methanosarcinaceae is only 60%. The sequences 17-35 and 45-58 of the protein MC1 appear well conserved. Deletions are observed in region 36-44. Many changes, most of them nonconservative, occur in the carboxyl-terminal third of the protein. However, proline residues at positions 68, 72, 76, and 82 remain strictly conserved. Predictive methods for secondary structures indicate a low content of alpha helix and beta sheet structures in proteins MC1.

Primary structure of the chromosomal protein MC1 from the archaebacterium Methanosarcina sp. CHTI 55.

The DNA of the thermophilic archaebacterium Methanosarcina sp. CHTI 55 has been shown to be associated with two proteins called MC1 and MC2, of molecular mass 11 kDa and 17 kDa (Chartier et al. (1988) Biochim. Biophys. Acta 951, 149-156). The most abundant of these proteins, protein MC1, can protect DNA against thermal denaturation. In the present paper we report the covalent structure of protein MC1 and its effect on transcription of DNA in vitro. The covalent structure was determined from automated sequence analysis of the protein and from structural data provided by peptides derived from cleavage of the protein at aspartic acid and arginine residues. The amino-acid sequence of protein MC1 from Methanosarcina sp. CHTI 55 is closely related to that of the protein MC1 (previously called HMb) isolated from Methanosarcina barkeri strain MS: among the nine substitutions observed between the two proteins seven are conservative. Transcription of DNA in vitro is stimulated by protein MC1 at low protein-to-DNA ratio but is inhibited at a ratio higher than 0.1 (w/w), which is the one determined in the bacterial deoxyribonucleoprotein complex.

'In situ' Edman degradation of protein(s) blotted to immobilon membranes suitable for unblocking reversible chemical modification and elimination of coomassie blue in sodium dodecyl sulfate-polyacrylamide gel electrophoresis.

Conditions for unblocking reversible chemical modifications such as maleylation or citraconylation 'in situ' at the N-terminus of proteins after transfer of proteins to immobilon membranes from SDS-PAGE are described. Demaleylation or decitraconylation occurred at 55 degrees C in 70% formic acid (pH 1.50) during 60 min. During the unblocking reaction, Coomassie blue dye was completely removed, resulting in superior high performance liquid chromatographic separation of phenylthiohydantoin-amino acid (PTH-AA) after Edman degradation (automatic gas phase sequencer). The protein fixed on the matrix after demaleylation and removal of Coomassie blue was not degraded. The possible cleavage at the aspartyl-prolyl peptide bonds was considered, but no side reaction was observed. Furthermore, the incubation time in 70% formic acid at 55 degrees C could be reduced to 10 min in the absence of maleylation of the starting material, and this was suitable for the removal of Coomassie blue and the quantification of phenylthiolhydantoin-amino acids (PTH-AAs) by HPLC. The yield from the starting protein through SDS-PAGE, blotting, and Edman degradation to quantitative analysis of PTH-aminoacid(s) by HPLC was established.

Comparison of the amino acid sequences of human protamines HP2 and HP3 and of intermediate basic nuclear proteins HPS1 and HPS2. Structural evidence that HPS1 and HPS2 are pro-protamines.

Two intermediate nuclear basic proteins HPS1 and HPS2 were isolated from human sperm. They were characterized by their electrophoretic mobility in acid-urea gels, their amino acid composition, and their peptide maps after digestion by endoproteinase Lys-C and by endoproteinase Glu-C. Their amino-terminal amino acid sequences have also been determined. The structural data thus obtained suggest that HPS1 and HPS2 are precursors of human protamines HP2 and HP3.

Isolation and characterization of ATP-dependent proteolytically active ubiquitin in cock testis.

1. We have successfully isolated and purified ubiquitin from cock testis by using an inhibitor, p-CMB (p-chloromercuribenzoate), which is one of the inhibitors specific for thiol-proteases and with the following procedures: heating up to 85 degrees C, ammonium sulfate fractionation, gel filtration on Sephadex G-75, chromatography on DE-52 and CM-11 and lyophilization. 2. Amino-acid analysis showed that Ub isolated from cock testis has 76 residues including 6 glycines. 3. Hydrazinolysis and carboxypeptidase digestion were also performed: the C-terminal residue is glycine. 4. The purity was checked by analytical SDS-PAGE and the isolated Ub exhibited only one band. 5. The Ub-dependent proteolysis experiment showed that this Ub was ATP-dependently proteolytically active. 6. In this paper we present evidence that a thiol enzyme is present during the purification procedure.

Isolation and characterization of two protamines St1 and St2 from stallion spermatozoa, and amino-acid sequence of the major protamine St1.

Two protamines, St1 and St2, were isolated from stallion sperm nuclei, where they represent about 75 and 25%, respectively, of the total basic protein complement. The primary structure of protamine St1 (49 residues; Mr approximately equal to 6600) has been determined. The structure of this protamine is compared to the amino-acid sequence of other mammalian protamines already known.

Purification and characterization of nuclear basic proteins of human sperm.

Highly purified nuclei were obtained from human sperm without protein loss through the use of CHAPS (3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate), a newly available detergent. The basic protein complement of these nuclei is highly heterogeneous and comprises histones (some of which are testis-specific), protamines and proteins of intermediate basicity and molecular size. The protamines belong to two different classes of protein. Microheterogeneity observed in some of these protamines originates from slight variations in their amino acid composition as well as from post-synthetic modifications. Two of these protamines previously considered as two different proteins are in fact the same protein with different degrees of phosphorylation. All these protamines and intermediate basic proteins are characterized by high amounts of arginine and cysteine. Three of the protamines and all five intermediate basic proteins are also histidine-rich.

Primary structure of the two variants of a sperm-specific histone H1 from the annelid Platynereis dumerilii.

The amino acid sequences of the two variants (H1a 121 residues and H1b 119 residues) of the sperm-specific histone H1 from the polychaete annelid Platynereis dumerilii have been completely established. Comparison of the sequences of these two variants shows one deletion of two residues in histone H1b and 22 substitents, of which most occur in the globular domain. The two variants differ highly in a sequence of nine residues adjacent to the conservative phenylalanine residue of histone H1 (64-72 in H1a, 62-70 in H1b) which makes H1a less hydrophobic than H1b. The small molecular size of Platynereis H1a and H1b is a unique feature among the histones H1 of which the size ranges between 189 residues (chicken erythrocyte H5) and 248 residues (sea urchin sperm H1). H1a and H1b have short N- and C-terminal basic domains but the size of the globular domain (approximately equal to 80 residues) is similar to that of other H1s. In the globular region the variant H1a exhibits a close relationship with somatic or sperm H1s whereas the variant H1b is more related to H5 histones.

Primary structure of the ram (Ovis aries) protamine.

The amino acid sequence of the protamine isolated from mature sperm nuclei of the ram (Ovis aries) has been established from automated sequence analysis of the S-carboxymethylated protamine. Ram and bull protamines differ only by two point changes and the deletion in bull protamine of the tripeptide Cys39-Arg-Arg41. In mammalian protamines the central region (residues 13-36) consisting mainly of arginine clusters appears to be conserved whereas the N-terminal and C-terminal regions are more variable.