Persistence of protamine precursors in mature sperm nuclei of the mouse

During mouse spermiogenesis, two protamines, mP1 and mP2, are synthesized in replacement of histones. One of them (protamine mP2, 63 residues) appears at first in elongating spermatid nuclei as a pro-protamine of 106 residues (pmP2) with an amino-terminal extension that is progressively excised. The two protamines were previously described as the only proteins associated with DNA in sperm chromatin. This paper shows that the nuclear proteins of mouse spermatozoa are indeed heterogeneous: at least six minor polypeptides in addition to protamines can be identified. The primary structure of four of them has been established. They are intermediate in the maturation of the precursor of protamine mP2 and correspond to polypeptides pmP2/11, pmP2/16, pmP2/20, and pmP2/32, characterized previously in mouse testis. Therefore, these intermediates of proteolysis generated from pmP2 inside spermatid nuclei persist in mature sperm, whereas the largest precursors, pmP2 and pmP2/5, disappear. These findings clearly indicate that limited proteolysis events still occur outside of the testis. © 1995 Wiley-Liss, Inc.     

Separation and some properties of the major proteins of the human erythrocyte membrane

A fractionation procedure is described which allows the isolation of three major human erythrocyte membrane proteins. Their isolation involves three sequential extraction procedures followed by gel filtration in 1% sodium dodecyl sulphate and preparative gel electrophoresis. All three proteins can be isolated from a single preparation. One of the proteins is the erythrocyte sialoglycoprotein, for which no C- or N-terminal residues were found. The other two proteins, which have not previously been isolated, have subunit molecular weights of 74000 and 93000 and contain 9 and 7% carbohydrate respectively. These glycoproteins have blocked N-terminal residues and show similarities in their chemical properties. Preparations derived from blood-group O erythrocytes contain no N-acetylgalactosamine, but similar preparations from blood-group A erythrocytes do contain this sugar. These three proteins cannot easily be solubilized by gentle aqueous procedures and represent about half of the erythrocyte ;ghost' protein. They carry a large proportion of the cell-surface carbohydrate.     

Structural studies on wheat (Triticum aestivum) proteins lacking phenylalanine and histidine residues.

1. Three very similar proteins, each of approx. 120 amino acid residues but lacking phenylalanine and histidine, were isolated from wheat (Triticum aestivum) flour in sufficient quantities for further structural studies. 2. Each protein, after reduction and carboxymethylation, was cleaved at the three methionine residues with CNBr to give four major peptides, which were isolated. These peptides are suitable for future sequencing studies, as the sums of their amino acid compositions are in good agreement with those of the whole proteins. 3. The N- and C-terminal peptides were identified. 4. Evidence from amino acid analyses, N-terminal amino acids and electrophoretic mobilities of the peptides suggests a high degree of homology between the proteins. Definite differences in C-terminal amino acids and the number of glycine, alanine and arginine residues were found in the C-terminal peptides.     

Identification of cleavage sites involved in proteolytic processing of Pseudomonas aeruginosa preproelastase.

The extracellular elastase (33 kDa) of Pseudomonas aeruginosa is synthesized as a 53.6 kDa preproenzyme containing a long, N-terminal propeptide. The free propeptide and the elastase precursor generated upon propeptide removal were isolated from P. aeruginosa cells and subjected to N-terminal amino acid sequence analysis. The results identified Ala-174 and Ala+1 as the amino terminal residues of the propeptide and the elastase precursor, respectively, indicating that: (1) the signal peptide consists of 23 amino acid residues and its molecular weight is 2.4 kDa, (2) the propeptide contains 174 amino acid residues and is of 18.1 kDa molecular weight, and (3) no additional N-terminal proteolytic cleavage is required for elastase maturation.     

Protamine precursors in human spermatozoa

Basic proteins isolated from human sperm nuclei are highly heterogeneous. Three groups of nuclear basic proteins have been characterized: somatic-type as well as testis-specific histones, protamines and basic proteins with an electrophoretic mobility which is intermediate between that of histones and that of protamines. Human protamines can be separated into 2 protein families with different amino acid composition and amino-acid sequence. Protamines HP1 differ in their degree of phosphorylation. Protamines HP2, 3 and 4 differ by their amino-terminal sequence. Intermediate basic proteins (HPI1, HPI2, HPS1, HPS2) share a common C-terminal sequence of 54 residues identical to the amino-acid sequence of protamine HP3; only their N-terminal regions are different. Taking into account these structural homologies, the intermediate basic protein HPI1 appears as a precursor of protamines HP2 and HP3.     

Primary structure of human carcinoembryonic antigen (CEA) deduced from cDNA sequence

The cDNAs corresponding to the mRNA encoding a polypeptide which is immunoreactive with the antisera specific to carcinoembryonic antigen (CEA) (1) are cloned. The amino acid sequences deduced from the nucleotide sequences of the cDNAs show that it is synthesized as a precursor with a signal peptide followed by 668 amino acids of the putative mature CEA peptide, whose N-terminal 24 amino acids and amino acids 286 to 295 exactly coincide with those known for N-terminal sequences of CEA (2) and NFA-1 (3), respectively. The first 108 N-terminal residues are followed by three very homologous repetitive domains of 178 residues each and then by 26 mostly hydrophobic residues which probably comprise a membrane anchor. Each repetitive domains contains 4 cysteines at precisely the same positions and as many as 28 possible N-glycosylation sites are found in the CEA peptide region agreeing with high carbohydrate content of purified CEA.     

The glycopeptide domain of the rat vasopressin precursor

The vasopressin precursor is composed of 3 domains, namely vasopressin, MSEL-neurophysin and a glycopeptide. Processing occurs during axonal transport from hypothalamus to neurohypophysis from which the 3 fragments can be isolated. The glycopeptide fragment of the rat vasopressin precursor has been purified and sequenced. Despite the fact that rat MSEL-neurophysin is shortened (93 residues instead of 95 for other mammals), rat glycopeptide has 39 residues, as do the other mammalian glycopeptides, suggesting a similar processing. Fifteen substitutions are however observed when compared to ox glycopeptide. The C-terminal part of MSEL-neurophysin (residues 77-93) and the glycopeptide are encoded by the same exon and the homologies when compared with their bovine counterparts are 58% and 62% respectively. In contrast, the central part of rat MSEL-neurophysin (residues 10-76), which is encoded by a separate exon, displays 96% of homology; vasopressin and the N-terminal part of MSEL-neurophysin (residues 1-9), encoded by a third exon, are nearly invariant.     

Primary structure of the A chain of human complement-classical-pathway enzyme C1r. N-terminal sequences and alignment of autolytic fragments and CNBr-cleavage peptides.

Activated human complement-classical-pathway enzyme C1r has previously been shown to undergo autolytic cleavages occurring in the A chain [Arlaud, Villiers, Chesne & Colomb (1980) Biochim. Biophys. Acta 616, 116-129]. Chemical analysis of the autolytic products confirms that the A chain undergoes two major cleavages, generating three fragments, which have now been isolated and characterized. The N-terminal alpha fragment (approx. 210 residues long) has a blocked N-terminus, as does the whole A chain, whereas N-terminal sequences of fragments beta and gamma (approx. 66 and 176 residues long respectively) do not, and their N-terminal sequences were determined. Fragments alpha, beta and gamma, which are not interconnected by disulphide bridges, are located in this order within C1r A chain. Fragment gamma is disulphide-linked to the B chain of C1r, which is C-terminal in the single polypeptide chain of precursor C1r. CNBr cleavage of C1r A chain yields seven major peptides, CN1b, CN4a, CN2a, CN1a, CN3, CN4b and CN2b, which were positioned in that order, on the basis of N-terminal sequences of the methionine-containing peptides generated from tryptic cleavage of the succinylated (3-carboxypropionylated) C1r A chain. About 60% of the sequence of C1r A chain (440-460 residues long) was determined, including the complete sequence of the C-terminal 95 residues. This region shows homology with the corresponding parts of plasminogen and chymotrypsinogen and, more surprisingly, with the alpha 1 chain of human haptoglobin 1-1, a serine proteinase homologue.     

Identification, characterization and cDNA cloning of two novel proteins secreted into the external space of the regenerating leg of Periplaneta americana

We have isolated two proteins (Rap 60 and Rap 40) that were expressed specifically in regenerating legs of the American cockroach (Periplaneta americana). These proteins appear to be derived from a precursor protein with 443 amino acid residues termed regeneration-associated protein (RAP). Rap 60 and Rap 40 corresponded to Glu 223 to Ser 443 and Glu 223 to Glu 366 of RAP, respectively. Hence, Rap 40 is the N-terminal part of Rap 60. These proteins contained 13 repeats of a novel motif, [Glu/Asp-Glu/Asp-Val/Ala-Lys]. The gene encoding RAP was shown to be expressed during embryogenesis and by newly-formed epidermal cells of regenerating legs. Rap 60 and Rap 40 were secreted into the external space of regenerating leg saccules, where they accumulated, suggesting that they are components of extracellular matrix of regenerating leg saccules.     

Glyoxysomal Malate Dehydrogenase in Pumpkin: Cloning of a cDNA and Functional Analysis of Its Presequence

Glyoxysomal malate dehydrogenase (gMDH) is an enzyme of theglyoxylate cycle that participates in degradation of storageoil. We have cloned a cDNA for gMDH from etiolated pumpkin cotyledonsthat encodes a polypep-tide consisting of 356 amino acid residues.The nucleotide and N-terminal amino acid sequences revealedthat gMDH is synthesized as a precursor with an N-terminal extrapeptide.The N-terminal presequence of 36 amino acid residues containstwo regions homologous to those of other micro-body proteins,which are also synthesized as large precursors. To investigatethe functions of the N-terminal presequence of gMDH, we generatedtransgenic Arabidopsis that expressed a chimeric protein consistingof rß-glucuroni-dase and the N-terminal region ofgMDH. Immunologi-cal and immunocytochemical studies revealedthat the chimeric protein was imported into microbodies suchas gly-oxysomes and leaf peroxisomes and was then subsequentlyprocessed. Site-directed mutagenesis studies showed that theconserved amino acids in the N-terminal presequence, Arg-10and His-17, function as recognition sites for the targetingto plant microbodies, and Cys-36 in the presequence is responsiblefor its processing. These results correspond to those from theanalyses of glyoxysomal citrate synthase (gCS), which was alsosynthesized as a large precursor, suggesting that common mechanismsthat can recognize the targeting or the processing of gMDH andgCS function in higher plant cells. (Received July 10, 1997; Accepted November 22, 1997)     

How can organellar protein N-terminal sequences be dual targeting signals? In silico analysis and mutagenesis approach

Organellar nuclear-encoded proteins can be mitochondrial, chloroplastic or localized in both mitochondria and chloroplasts. Most of the determinants for organellar targeting are localized in the N-terminal part of the proteins, which were therefore analyzed in Arabidopsis thaliana. The mitochondrial, chloroplastic and dual N-terminal sequences have an overall similar composition. However, Arg is rare in the first 20 residues of chloroplastic and dual sequences, and Ala is more frequent at position 2 of these two types of sequence as compared to mitochondrial sequences. According to these observations, mutations were performed in three dual targeted proteins and analyzed by in vitro import into isolated mitochondria and chloroplasts. First, experiments performed with wild-type proteins suggest that the binding of precursor proteins to mitochondria is highly efficient, whereas the import and processing steps are more efficient in chloroplasts. Moreover, different processing sites are recognized by the mitochondrial and chloroplastic processing peptidases. Second, the mutagenesis approach shows the positive role of Arg residues for enhancing mitochondrial import or processing, as expected by the in silico analysis. By contrast, mutations at position 2 have dramatic and unpredicted effects, either enhancing or completely abolishing import. This suggests that the nature of the second amino acid residue of the N-terminal sequence is essential for the import of dual targeted sequences.     

Enzymic and structural studies on processed proteins from the vacuolar (lutoid-body) fraction of latex of Hevea brasiliensis

The lutoid-body (bottom) fraction of latex from the rubber tree (Hevea brasiliensis) contains a limited number of major proteins. These are the chitin-binding protein hevein, its precursor and C-terminal fragment of the precursor, a basic chitinase/lysozyme, and a β-1,3-glucanase. The content and properties of the latter enzyme differ between lutoid-body fractions from four different rubber clones (cultivars). While the enzyme from clone GT.1 is a glycoprotein with carbohydrate attached to two glycosylation sites, the enzymes from other clones contain little or no carbohydrate. Latex from clone GT.1 has a higher β-1,3-glucanase content than those from the other three clones, but with a significantly lower specific activity. The enzyme exhibits a pH optimum at 4.5, but there is a second one at 6.7. Peptides isolated from β-1,3-glucanase of clone GT.1 showed that the enzyme is heterogeneous at the C-terminus, probably as a result of removal of a vacuolar targeting sequence by an endopeptidase, followed by further removal of C-terminal residues by a carboxypeptidase-like activity. This incomplete digestion can be related to glycosylation at the extreme C-terminus of the mature enzyme. Non-glycosylated Hevea β-1,3-glucanases exhibit less C-terminal heterogeneity. A homologue of the antifungal protein osmotin was isolated from rubber clones which are less susceptible to fungal diseases. Another identified protein is identical to a citrate binding protein (CBP), already sequenced as cDNA, but with cleaved-off N-terminal signal and C-terminal vacuolar targeting peptides. Four C-terminal propeptides of vacuolar proteins in Hevea are positively identified, which is a valuable contribution to previously known examples of this type of processing.     

The expression of multiple forms of troponin T in chicken-fast-skeletal muscle may result from differential splicing of a single gene

Troponin T isolated from chicken fast skeletal muscle has been shown to be present in three different molecular forms, one in breast and two in leg muscle. The three forms differ in both size and charge. Troponin T from breast muscle has a molecular mass of 33.5 kDa and a pI of about 7. Of the two leg muscle forms the larger has a molecular mass of 30.5 kDa and a pI of about 8.5 and the smaller a molecular mass of 29.8 kDa and a pI of about 10. Considerably more heterogeneity has been found in the leg than in the breast muscle proteins although this is not reflected in their N-terminal sequences. The reason for this is not clear. Troponin T from breast or leg muscle can be phosphorylated with troponin T kinase at the single serine residue at the N-terminus. No difference in the rate or extent of phosphorylation could be found between proteins from breast or leg muscle. The three proteins have been shown to differ only in the amino acid sequence of their N-terminal tryptic peptides. These peptides are of different length, that from breast troponin T being 58 residues and those from leg troponin T being 36 and 42 residues, these differences account for the difference in molecular mass of the parent proteins. Despite this difference the sequence of the first 12 and last 14 residues is identical in all three N-terminal peptides. The remainder of the sequence of the smallest peptide is also repeated in the other two but they each contain an extra piece of unique sequence. On the basis of these sequences it is proposed that chicken troponin T is coded for by a single gene containing, at the 5' end, a number of small exons and that three different mRNA molecules may be produced by alternative pathways of RNA splicing. The possible significance of these N-terminal sequence variations is discussed.     

N-terminal domain of the dual-targeted pea glutathione reductase signal peptide controls organellar targeting efficiency

Import of nuclear-encoded proteins into mitochondria and chloroplasts is generally organelle specific and its specificity depends on the N-terminal signal peptide. Yet, a group of proteins known as dual-targeted proteins have a targeting peptide capable of leading the mature protein to both organelles. We have investigated the domain structure of the dual-targeted pea glutathione reductase (GR) signal peptide by using N-terminal truncations. A mutant of the GR precursor (pGR) starting with the second methionine residue of the targeting peptide, pGRdelta2-4, directed import into both organelles, negating the possibility that dual import was controlled by the nature of the N terminus. The deletion of the 30 N-terminal residues (pGRdelta2-30) inhibited import efficiency into chloroplasts substantially and almost completely into mitochondria, whereas the removal of only 16 N-terminal amino acid residues (pGRdelta2-16) resulted in the strongly stimulated mitochondrial import without significantly affecting chloroplast import. Furthermore, N-terminal truncations of the signal peptide (pGRdelta2-16 and pGRdelta2-30) greatly stimulated the mitochondrial processing activity measured with the isolated processing peptidase. These results suggest a domain structure for the dual-targeting peptide of pGR and the existence of domains controlling organellar import efficiency therein.     

A new gene structure of the disintegrin family: a subunit of dimeric disintegrin has a short coding region

Disintegrin is a potent platelet aggregation inhibitor isolated from various snake venoms. The cDNA of the snake venom disintegrin family precursor is well-known to encode pre-peptide, metalloprotease, spacer, and disintegrin domains. Recently, new types of disintegrins, dimeric disintegrins, have been isolated, and their amino acid sequences were determined to be approximately 65 amino acid residues in each subunit. We isolated a novel heterodimeric disintegrin, acostatin, from the venom of Agkistrodon contortrix contortrix, which consisted of 63 and 64 amino acid residues in the alpha chain and beta chain, and both chains had the Arg-Gly-Asp (RGD) sequence for binding platelet GPIIb/IIIa. The cDNA lengths of the alpha chain and the beta chain of acostatin were 902 bp and 2031 bp, respectively. The acostatin alpha chain precursor, surprisingly, has the only disintegrin domain alone and lacked almost all of the pre-peptide and metalloprotease domains. The precursor of the acostatin beta chain belongs to a well-known motif of disintegrin precursors. Furthermore, both precursors of alpha and beta chains of another heterodimeric disintegrin, piscivostatin, also have the same domain structures as those of acostatin subunits. These results indicate that the cDNAs of heterodimeric disintegrin subunits have quite a different length of coding region and their precursors have a novel domain structure of disintegrin-family proteins.     

Flagellar hook and hook-associated proteins of Salmonella typhimurium and their relationship to other axial components of the flagellum

Within the bacterial flagellum the basal-body rod, the hook, the hook-associated proteins (HAPs), and the helical filament constitute an axial substructure whose elements share structural features and a common export pathway. We present here the amino acid sequences of the hook protein and the three HAPs of Salmonella typhimurium, as deduced from the DNA sequences of their structural genes (flgE, flgK, flgL and fliD, respectively). We compared these sequences with each other and with those for the filament protein (flagellin) and four rod proteins, which have been described previously (Joys, 1985; Homma et al., 1990; Smith & Selander, 1990). Hook protein most strongly resembled the distal rod protein (FlgG) and the proximal HAP (HAP1), which are thought to be attached to the proximal and distal ends of the hook, respectively; the similarities were most pronounced near the N and C termini. Hook protein and flagellin, which occupy virtually identical helical lattices, did not resemble each other strongly but showed some limited similarities near their termini. HAP3 and HAP2, which form the proximal and distal boundaries of the filament, showed few similarities to flagellin, each other, or the other axial proteins. With the exceptions of the N-terminal region of HAP2, and the C-terminal region of flagellin, proline residues were absent from the terminal regions of the axial proteins. Moreover, with the exception of the N-terminal region of HAP2, the terminal regions contained hydrophobic residues at intervals of seven residues. Together, these observations suggest that the axial proteins may have amphipathic alpha-helical structure at their N and C termini. In the case of the filament and the hook, the terminal regions are believed to be responsible for the quaternary interactions between subunits. We suggest that this is likely to be true of the other axial structures as well, and specifically that interaction between N-terminal and C-terminal alpha-helices may be important in the formation of the axial structures of the flagellum. Although consensus sequences were noted among some of the proteins, such as the rod, hook and HAP1, no consensus extended to the entire set of axial proteins. Thus the basis for recognition of a protein for export by the flagellum-specific pathway remains to be identified.     

Structure of a Ca2+-myristoyl switch protein that controls activation of a phosphatidylinositol 4-kinase in fission yeast

Neuronal calcium sensor (NCS) proteins transduce Ca2+ signals and are highly conserved from yeast to humans. We determined NMR structures of the NCS-1 homolog from fission yeast (Ncs1), which activates a phosphatidylinositol 4-kinase. Ncs1 contains an α-NH2-linked myristoyl group on a long N-terminal arm and four EF-hand motifs, three of which bind Ca2+, assembled into a compact structure. In Ca2+-free Ncs1, the N-terminal arm positions the fatty acyl chain inside a cavity near the C terminus. The C14 end of the myristate is surrounded by residues in the protein core, whereas its amide-linked (C1) end is flanked by residues at the protein surface. In Ca2+-bound Ncs1, the myristoyl group is extruded (Ca2+-myristoyl switch), exposing a prominent patch of hydrophobic residues that specifically contact phosphatidylinositol 4-kinase. The location of the buried myristate and structure of Ca2+-free Ncs1 are quite different from those in other NCS proteins. Thus, a unique remodeling of each NCS protein by its myristoyl group, and Ca2+-dependent unmasking of different residues, may explain how each family member recognizes distinct target proteins.