Identification of the Pm and PmS human parotid salivary proteins as basic proline-rich proteins

Amino acid composition and electrophoretic mobility suggest that two polymorphic proteins in human parotid saliva, Pm and PmS, are basic proline-rich proteins. Comparison of two basic proline-rich proteins previously isolated by D. L. Kauffman and P. J. Keller (1979) [Arch. Oral. Biol. 24: 249], IB-6 and IB-9, with PmS and Pm demonstrated corresponding electrophoretic mobilities on cationic polyacrylamide slab gels. Further, the amino acid compositions of IB-9 and Pm were found to be similar. Although differences in amino acid composition and carbohydrate content were noted, such differences could be accounted for, suggesting that IB-9 and Pm are identical.     

Experimental determination of proline hydroxylation and hydroxyproline arabinogalactosylation motifs in secretory proteins

Many secretory and several vacuolar proteins in higher plants contain hydroxylated proline residues. In many cases, hydroxyprolines in proteins are glycosylated with either arabinogalactan or oligoarabinose. We have previously shown that a sporamin precursor is O-glycosylated at the hydroxylated proline 36 residue with an arabinogalactan-type glycan when this protein is expressed in tobacco BY-2 cells (Matsuoka et al., 1995). Taking advantage of the fact that this is the only site of proline hydroxylation and glycosylation in sporamin, we analyzed the amino acid requirement for proline hydroxylation and arabinogalactosylation. We expressed several deletion constructs and many amino acid substitution mutants in tobacco cells and analyzed glycosylation and proline hydroxylation of the expressed sporamins. Hydroxylation of a proline residue requires the five amino acid sequence [AVSTG]-Pro-[AVSTGA]-[GAVPSTC]-[APS or acidic] (where Pro is the modification site) and glycosylation of hydroxyproline (Hyp) requires the seven amino acid sequence [not basic]-[not T]-[neither P, T, nor amide]-Hyp-[neither amide nor P]-[not amide]-[APST], although charged amino acids at the -2 position and basic amide residues at the +1 position relative to the modification site seem to inhibit the elongation of the arabinogalactan side chain. Based on the combination of these two requirements, we concluded that the sequence motif for efficient arabinogalactosylation, including the elongation of the glycan side chain, is [not basic]-[not T]-[AVSG]-Pro-[AVST]-[GAVPSTC]-[APS].     

Basic proline-rich proteins from human parotid saliva: relationships of the covalent structures of ten proteins from a single individual.

Eleven basic proline-rich proteins were purified from the parotid saliva of a single individual. The complete amino acid sequences of six of these were determined by conventional protein sequence methodology, bringing to nine the number of known primary structures of nonglycosylated basic proline-rich proteins from the same individual. The partial sequence of one additional protein is also reported. All of the basic proline-rich proteins studied contain segments with identical or very similar sequences, but with two possible exceptions, none of the proteins is derived from another secreted proline-rich protein. The amino acid sequences of nine nonglycosylated basic proline-rich proteins were compared with primary structures deduced from published nucleotide sequences of DNA coding for human parotid proline-rich proteins. The sequences align well, in general, but differences also exist pointing to the complexity of the genetics of these proteins. Seven secretory basic proline-rich proteins appear to be formed from three larger precursors by selective posttranslational proteolyses of arginyl bonds. One of the basic proline-rich proteins appears to derive from human acidic proline-rich proteins. The remaining two proteins studied do not conform to any DNA structure as yet reported. Two of the basic proline-rich proteins studied are phosphoproteins and exhibit abilities to inhibit hydroxyapatite formation in vitro.     

The importance of being proline: the interaction of proline-rich motifs in signaling proteins with their cognate domains.

Acommon focus among molecular and cellular biologists is the identification of proteins that interact with each other. Yeast two-hybrid, cDNA expression library screening, and coimmunoprecipitation experiments are powerful methods for identifying novel proteins that bind to one's favorite protein for the purpose of learning more regarding its cellular function. These same techniques, coupled with truncation and mutagenesis experiments, have been used to define the region of interaction between pairs of proteins. One conclusion from this work is that many interactions occur over short regions, often less than 10 amino acids in length within one protein. For example, mapping studies and 3-dimensional analyses of antigen-antibody interactions have revealed that epitopes are typically 4-7 residues long (1). Other examples include protein-interaction modules, such as Src homology (SH) 2 and 3 domains, phosphotyrosine binding domains (PTB), postsynaptic density/disc-large/ZO1 (PDZ) domains, WW domains, Eps15 homology (EH) domains, and 14-3-3 proteins that typically recognize linear regions of 3-9 amino acids. Each of these domains has been the subject of recent reviews published elsewhere (2 3 4 5 6 7). Among the primary structures of many ligands for protein-protein interactions, the amino acid proline is critical. In particular, SH3, WW, and several new protein-interaction domains prefer ligand sequences that are proline-rich. In addition, even though ligands for EH domains and 14-3-3 domains are not proline-rich, they do include a single proline residue. This review highlights the analysis of those protein-protein interactions that involve proline residues, the biochemistry of proline, and current drug discovery efforts based on proline peptidomimetics.-Kay, B. K., Williamson, M. P., Sudol, M. The importance of being proline: the interaction of proline-rich motifs in signaling proteins with their cognate domains.     

Novel multigene families encoding highly repetitive peptide sequences. Sequence analyses of rat and mouse proline-rich protein cDNAs

Multigene families encode the proline-rich proteins that are so prominent in human saliva and are dramatically induced in mouse and rat salivary glands by isoproterenol treatment and by feeding tannins. A cDNA encoding an acidic proline-rich protein of rat has been sequenced (Ziemer, M. A., Swain, W. F., Rutter, W. J., Clements, S., Ann, D. K., and Carlson D. M. (1984) J. Biol. Chem. 259, 10475-10480). This study presents the nucleotide sequences of five additional proline-rich protein cDNAs complementary to both mouse and rat parotid and submandibular gland mRNAs. Amino acid compositions deduced from the nucleotide sequences are typical for proline-rich proteins: 25-45% proline, 18-22% glycine, and 18-22% glutamine and generally an absence of sulfur-containing amino acids except for the initiator methionine. These proline-rich proteins display unusual repeating peptide sequences of 14-19 amino acids. The derived amino acid sequence of the cDNA insert of plasmid pMP1 from mouse has a 19-amino acid sequence which is repeated four times. The inserts of plasmids pUMP40 and pUMP4 also from mouse encode for 12 and 11 repeats of a 14-amino acid peptide, respectively. These repetitive sequences, and others from rat and mouse cDNAs and from human genomic clones, all show very high homologies and likely evolved from duplication of internal portions of an ancestral gene. Gene conversion could account for the high degree of conservation of nucleotide sequences of the repeat regions. Protein derived from the nucleotide sequences are all characterized by four general regions: a putative signal peptide, a transition region, the repetitive region, and a carboxyl-terminal region. The 5'-flanking sequences and sequences encoding the putative signal peptides are highly conserved (greater than 94%) in all six cDNAs. This sequence conservation may be important in the regulation of the biosynthesis of these unusual proteins.     

Isolation and partial characterization of human parotid basic proteins

Methods are presented for the isolation of basic proteins (Pb proteins) from human parotid saliva collected from humans possessing different alleles at the Pb locus. The proteins were found to be extremely basic, with an isoelectric point above 9.5. They contain approximately 45% of the basic amino acids histidine, lysine, and arginine, and are devoid of cysteine, proline, threonine, valine, methionine, and tryptophan. They are free of carbohydrate. A comparison of the amino acid sequence data of Pb protein to all available amino acid sequences revealed that no sequence similarities exist between the Pb proteins and any other proteins reported, although proteins of similar amino acid compositions have been reported by others. A model is presented with accounts for the several forms of allelic proteins based on observed amino acid sequence differences.     

Definition of a consensus sequence for peptide substrate recognition by p44mpk, the meiosis-activated myelin basic protein kinase

Synthetic peptides have been used to define the consensus amino acid sequence for substrate recognition by the meiosis-activated myelin basic protein (MBP) kinase (p44mpk), which was purified from maturing sea star oocytes. This protein kinase shares many properties with the mitogen-activated microtubule-associated protein-2 kinase (p42mapk) in vertebrates. Recently, Thr-97 in the tryptic fragment KNIVTPRTPPPSQGK of bovine MBP was identified as the major site of phosphorylation by p44mpk (Sanghera, J. S., Aebersold, R., Morrison, H. D., Bures, E. J., and Pelech, S. L. (1990) FEBS Lett. 273, 223-226). Synthetic peptides modeled after this sequence revealed that the presence of a proline residue C-terminal (+1 position) to the phosphorylatable threonine (or serine) residue was critical for recognition by p44mpk. Although not essential, a proline residue located at the -2 position enhanced the Vmax of peptide phosphorylation. Basic, acidic, and non-polar residues were equally tolerated at the -1 position. The presence of an amino acid residue at position -3 also increased peptide phosphorylation. Thus, the optimum consensus sequence for phosphorylation by p44mpk was defined as Pro-X-(Ser/Thr)-Pro, where X is a variable amino acid residue, but ideally not a Pro. Peptides that included this sequence were phosphorylated by p44mpk with Vmax values approaching 1 mumol.min-1.mg-1 and with apparent Km values of approximately 1 mM). Pseudosubstrate peptides in which the phosphorylatable residue was replaced by valine or alanine were weak inhibitors of p44mpk (apparent Ki values of approximately 3 mM). Over 40 distinct protein kinases contain Pro-X-(Ser/Thr)-Pro sequences including the human receptors for insulin and epidermal growth factor, and kinases encoded by the human proto-oncogenes abl, neu, and raf-1, and Schizosaccharomyces pombe cell cycle control genes ran-1 and wee-1. Multiple putative sites were also identified in rat microtubule-associated protein-2, human retinoblastoma protein, human tau protein, and Drosophila myb protein and RNA polymerase II.     

Important role of the proline residue in the signal sequence that directs the secretion of human lysozyme in Saccharomyces cerevisiae

To elucidate the role of the proline residue in the engineered signal sequence that directs the secretion of human lysozyme in Saccharomyces cerevisiae, we have remodeled an idealized signal sequence L8 = Met-Arg-(Leu)8-Pro-Leu-Ala-Ala-Leu-Gly [Yamamoto, Y., Taniyama, Y., Kikuchi, M., & Ikehara, M. (1987) Biochem. Biophys. Res. Commun. 149, 431-436] in the vicinity of the proline residue. By analyzing the secretory capability of 10 engineered signal sequences, we have shown the following. (1) The proline residue is important for the secretion of human lysozyme and is allowed at position -4, -5, or -6. (2) The secretory capability of the engineered signal sequences is correlated with their predicted conformations. (3) The functional signal sequences that we have investigated can be generalized as follows: Met-Arg-(Leu)n-Pro-(Xaa)-Ala-Leu-Gly where n equals 6-12 and Xaa is Leu, Ala, or Leu-Ala or can be omitted.     

A novel proline-rich protein from wheat

A cDNA (WPRP1) encoding a wheat proline-rich protein has been isolated and sequenced. The amino acid composition shows 45% proline, with high levels of methionine, lysine and glutamic acid. The derived 378 residue amino acid sequence has a highly repetitive structure which is unlike those of other proline-rich proteins. The WPRP1 cDNA clone was used to determine the copy number and chromosomal location of the WPRP1 gene by restriction fragment length polymorphism analysis of wheat inbred lines. Although WPRP1 is encoded by a single-copy gene it is also a representative of a larger family of related sequences. RNA gel blot analysis showed that expression of WPRP1 is highest in rapidly growing tissue which together with its amino acid composition suggests a structural role for the encoded protein.     

Characterization of the human salivary basic proline-rich protein complex by a proteomic approach

Thirteen samples of human normal whole saliva were analyzed by RP-HPLC-ESI-MS and MALDI-TOF-MS to investigate the basic proline-rich protein complex. Between known basic-PRPs the P-B, P-C (or IB-8b), P-D (or IB-5), P-E (or IB-9), P-F (or IB-8c), P-H (or IB-4), IB-6, II-2, IB-1, and IB-8a glucosylated were identified, whereas the II-1, IB-7, PA, and D1-A peptides were not detected. Some detected masses not attributable to known basic-PRPs were putatively ascribed to II-2 and IB-1 nonphosphorylated, II-2 and IB-1 missing the C-terminal arginine residue, and the 1-62 fragment of IB-6, named P-J peptide. A correlation matrix analysis revealed a cluster of correlation among all the basic PRPs (apart from the P-B peptide) which is in agreement with their common parotid origin.     

The complete primary structure of a proline-rich phosphoprotein from human saliva.

The complete amino acid sequence of a calcium-binding "proline-rich phosphoprotein," named Protein A, from human saliva was determined by automated and manual Edman degradation of peptides obtained by enzymatic and chemical cleavage of the intact protein. The NH2-terminal pyrrolidone carboxylic acid was identified by means of NMR. The protein consists of 106 amino acids, including 24 residues of proline. The NH2-terminal 32 residues contain 13 of the 15 negatively charged residues including 2 phosphoserines, but only 1 proline. In spite of a high concentration of proline in the COOH-terminal part of the molecule, the longest oligoproline sequence is tetraproline. The protein contains a number of repeated sequences and there are also several sequences of 3 or 4 residues identical with known sequences of collagen, but the characteristic occurrence of glycine in every third position in collagen is not found in salivary Protein A.     

Characterization of two soybean repetitive proline-rich proteins and a cognate cDNA from germinated axes

We have resolved and analyzed two proline-rich proteins isolated from the walls of soybean cells in culture. The proteins are similar in amino acid content, containing 20% proline, 20% hydroxyproline, 20% lysine, 16% valine, 10% tyrosine, and 10% glutamate. The proteins undergo a rearrangement or a limited cleavage in dilute NaOH, but are otherwise remarkably stable to a high concentration of alkali. We have cloned and sequenced a cDNA from soybean axes germinated for 31 hours (1A10-2) coding for a protein that closely corresponds in its amino acid content to that of the proline-rich proteins. The cDNA sequence predicts a decameric repeat of Pro-Pro-Val-Tyr-Lys-Pro-Pro-Val-Glu-Lys. Consequently, this class of proteins is referred to as repetitive proline-rich proteins, i.e., RPRP2 and RPRP3. We have also analyzed RNA gel blots with probes that discriminate between the new cDNA clone and a related cDNA previously reported [SbPRP1; Hong, Nagao, and Key (1987). J. Biol. Chem. 262, 8367-8376]. Messenger RNAs from young seedlings and from soybean suspension cultures correspond primarily to the new RPRP clone (1A10-2), whereas the predominant mRNA accumulating later in the roots corresponds to SbPRP1.     

The IgA-binding β antigen of the c protein complex of Group B streptococci: sequence determination of its gene and detection of two binding regions

The beta antigen of the lbc protein complex of Group B streptococci is a cell-surface receptor which binds the Fc region of human immunoglobulin A (IgA). Determination of the nucleotide sequence of the beta antigen gene shows that it encodes a preprotein having a molecular weight of 130,963 daltons and a polypeptide of 1164 amino acid residues that is typical of other Gram-positive cell-wall proteins. There is a long signal sequence of 37 amino acids at the N-terminus. Four of the five C-terminal amino acid residues are basic and are preceded by a hydrophobic stretch that appears to anchor the C-terminus in the cell membrane. To the N-terminal side of this hydrophobic stretch is a putative cell-wall-spanning region containing proline-rich repeated sequences. An unusual feature of these repeated sequences is a three-residue periodicity, whereby every first residue is a proline, the second residue is alternating positively or negatively charged, and the third residue is uncharged. The IgA-binding activity was approximately localized by expressing subfragments of the beta antigen as fusion proteins. Two distinct but adjacent DNA segments specified peptides that bound IgA, which indicates that the IgA-binding activity is located in two distinct regions of the protein.     

Isolation and amino acid sequences of proline-rich peptides of human whole saliva.

Three basic peptides with extremely high proline contents were isolated from human whole saliva. The amino acid sequences of two of these proline-rich peptides comprising 57 and 38 residues were determined by conventional methods. The sequence suggested that the smaller peptide was derived from the larger one and also revealed the occurrence of characteristic repeating units within the molecules. The present study is the first to describe this structural feature of proline-rich proteins or peptides.     

Genome-based identification and analysis of collagen-related structural motifs in bacterial and viral proteins

Collagens are extended trimeric proteins composed of the repetitive sequence glycine-X-Y. A collagen-related structural motif (CSM) containing glycine-X-Y repeats is also found in numerous proteins often referred to as collagen-like proteins. Little is known about CSMs in bacteria and viruses, but the occurrence of such motifs has recently been demonstrated. Moreover, bacterial CSMs form collagen-like trimers, even though these organisms cannot synthesize hydroxyproline, a critical residue for the stability of the collagen triple helix. Here we present 100 novel proteins of bacteria and viruses (including bacteriophages) containing CSMs identified by in silico analyses of genomic sequences. These CSMs differ significantly from human collagens in amino acid content and distribution; bacterial and viral CSMs have a lower proline content and a preference for proline in the X position of GXY triplets. Moreover, the CSMs identified contained more threonine than collagens, and in 17 of 53 bacterial CSMs threonine was the dominating amino acid in the Y position. Molecular modeling suggests that threonines in the Y position make direct hydrogen bonds to neighboring backbone carbonyls and thus substitute for hydroxyproline in the stabilization of the collagen-like triple-helix of bacterial CSMs. The majority of the remaining CSMs were either rich in proline or rich in charged residues. The bacterial proteins containing a CSM that could be functionally annotated were either surface structures or spore components, whereas the viral proteins generally could be annotated as structural components of the viral particle. The limited occurrence of CSMs in eubacteria and lower eukaryotes and the absence of CSMs in archaebacteria suggests that DNA encoding CSMs has been transferred horizontally, possibly from multicellular organisms to bacteria.     

The primary structures of six human salivary acidic proline-rich proteins (PRP-1, PRP-2, PRP-3, PRP-4, PIF-s and PIF-f).

Human glandular salivary secretions contain several acidic proline-rich phosphoproteins (PRPs). These proteins have important biological functions related to providing a protective environment for the teeth, and appear to possess other activities associated with modulation of adhesion of bacteria to oral surfaces. These functions and activities depend on the primary structures of the PRPs. Previously determined amino acid sequences of two 150-residue molecules, PRP-1 and PRP-2, and two related 106-residue proteins, PRP-3 and PRP-4, indicated that residue 4 was Asn in PRP-1 and PRP-3, and Asp in PRP-2 and PRP-4, and position 50 was Asn in all four proteins. Recent data from cDNA sequence studies and further structural studies, however, showed that the previously proposed sequences cannot be completely correct. The present work has shown that the protein previously designated as PRP-1 actually consisted of two positional isomers, PIF-s, which has Asn and Asp at positions 4 and 50 respectively, and authentic PRP-1, which has the reverse arrangement. The same isomerism is present in the smaller proteins, PIF-f and PRP-3. Since the isomeric pairs have identical compositions and charges, their presence was not previously detected. Also, by using a more highly purified preparation, it has been found that position 50 in PRP-2 and PRP-4 is Asp, rather than Asn previously reported. These new findings for the six PRPs define their complete primary structures, which are now consistent with those proposed for PRP-1 and PIF-s from cDNA data, and are also consistent with the chromatographic and electrophoretic behaviours of the six PRPs and their derived peptides. These corrected structures are important for understanding the biological functions and activities of these unusual proteins.     

Differential processing of human and rat E1 α precursors of the branched-chain α-keto acid dehydrogenase complex caused by an N-terminal proline in the rat sequence

The N-terminal sequences of the E1 α, E1β and E2 subunits of the human branched-chain α-keto acid dehydrogenase complex have been determined by microsequencing. The N-termini of human E1β and E2 subunits (Val and Gly, respectively) are indentical to those of the corresponding rat and bovine subunits. However, the N-terminus of the human E1 α subunit (Ser) is identical to bovine, but differs from the rat E1 α (Phe0 subunit. Comparison of the N-terminal sequences of human and rat E1 α subunits shows that the serine residue at the + 1 position in the human sequence is replaced by a proline residue in the rat sequence. The presence of the proline residue apparently causes a 5′-shift by one residue in the cleavage site by the mitochondrial processing peptidase in the rat sequence, when compared to the human sequence. The results provide evidence that the mitochondrial processing peptidase cannot cleave an X-pro bond, similar to trypsin, chymotrypsinand microsomal signal peptidases.     

Proline-rich proteins and glycoproteins: expression of salivary gland multigene families

Our recent research interests have focused on a group of unusual proteins and glycoproteins high in proline content, or the so-called proline-rich proteins (PRPs). The PRPs are tissue-specific expressions of salivary gland multigene families. Normally PRPs are not detected or are present in very low amounts in rat, mouse and hamster salivary glands, but these unusual proteins are dramatically induced by treatment with the catecholamine isoproterenol. The structures and organizations of several PRP mRNAs and PRP genes have been determined. The amino acid sequences of all PRPs show 4 distinct regions, namely, a signal peptide, a transition region, a repeat region and a carboxyl-terminal region. Glycoproteins induced by isoproterenol treatment may be N-glycosylated or O-glycosylated. The N-glycosylated glycoprotein GP-158 from rat submandibular glands has a 12 amino acid glycopeptide which repeats possibly 49 times. Proline-rich proteins of the parotid glands of rats and mice are also greatly induced by dietary tannins. The apparent unique occurrence of PRPs in saliva suggests that one biological role is to neutralize the detrimental effects of dietary tannins and other polyphenols. The upstream regions of the mouse and hamster PRP genes contain cyclic AMP-regulated sequences as demonstrated by deletions and transient transfections. The PRP multigene family members of mouse are all located on chromosome 8.