Polyproline, beta-turn helices. Novel secondary structures proposed for the tandem repeats within rhodopsin, synaptophysin, synexin, gliadin, RNA polymerase II, hordein, and gluten

Seven proteins each contain 8 to 52 tandem repeats of a unique class of oligopeptide. The consensus peptide for each is rhodopsin Tyr Pro Pro Gln Gly synaptophysin Tyr Gly Pro Gln Gly synexin Tyr Pro Pro Pro Pro Gly gliadin Tyr Pro Pro Pro Gln Pro RNA polymerase II Tyr Ser Pro Thr Ser Pro Ser hordein Phe Pro Gln Gln Pro Gln Gln Pro gluten Tyr Pro Thr Ser Pro Gln Gln Gly Tyr Although there is obvious variation of sequence and of length, the penta- to nonapeptides share an initial Tyr (or Phe) and have high Pro contents and abundant Gly, Gln, and Ser. We have evaluated helical models that both recognize the uniqueness of these sequence repeats and accommodate variations on the basic theme. We have developed a group of related helical models for these proteins with about three oligopeptide repeats per turn of 10-20 A. These models share several common features: Most of the phi dihedral angles are -54 degrees, to accommodate Pro at all positions except the first (Tyr). Except for the beta-turns, most psi dihedral angles are near +140 degrees as found in polyproline. Each oligopeptide has at least one beta-turn; several have two. Some contain a cis-Tyr, Pro peptide bond; a few have a cis-bond plus one beta-turn. Tyr side chains vary from totally exposed to buried within the helices and could move to accommodate either external hydrophobic interactions or phosphorylation. The several related structures seem to be readily interconverted without major change in the overall helical parameters, and therein may lie the key to their functions.     

Schizosaccharomyces pombe carboxyl-terminal domain (CTD) phosphatase Fcp1: distributive mechanism, minimal CTD substrate, and active site mapping

Schizosaccharomyces pombe Fcp1 is an essential protein serine phosphatase that preferentially dephosphorylates Ser(2) of the RNA polymerase II C-terminal domain (CTD) heptad repeat Y(1)S(2)P(3)T(4)S(5)P(6)S(7). Here we show that: (i) Fcp1 acts distributively during the hydrolysis of substrates containing tandem Ser(2)-PO(4) heptads; (ii) the minimal optimal CTD substrate for Fcp1 is a single heptad of phasing S(5)P(6)S(7)Y(1)S(2)P(3)T(4); and (iii) single alanine mutations of flanking residues Tyr(1) or Pro(3) result in 6-fold decrements in CTD phosphatase activity. Fcp1 belongs to the DXDX(T/V) family of phosphotransferases that act via an acyl-phosphoenzyme intermediate. An alanine scan of 11 conserved positions of S. pombe Fcp1 identifies Thr(174), Tyr(237), Thr(243), and Tyr(249) as important for phosphatase activity. Structure-activity relationships at these positions were determined by introducing conservative substitutions. Our results, together with previous mutational studies, highlight a constellation of 11 amino acids that are conserved in all Fcp1 orthologs and likely comprise the active site.     

NH2-terminal sequences of DNA-, heparin-, and gelatin-binding tryptic fragments from human plasma fibronectin

NH₂-terminal sequence analysis was performed on subregions of human plasma fibronectin including 24,000-dalton (24K) DNA-binding, 29,000-dalton (29K) gelatin-binding, and 18,000-dalton (18K) heparin-binding tryptic fragments. These fragments were obtained from fibronectin after extensive trypsin digestion followed by sequential affinity purification on gelatin-Sepharose, heparin-agarose, and DNA-cellulose columns. The gelatin-binding fragment was further purified by gel filtration on Sephadex G-100, and the DNA-binding and heparin-binding fragments were further purified by high-performance liquid chromatography. The 29K fragment had the following NH₂-terminal sequence: AlaAlaValTyrGlnProGlnProHisProGlnProPro (Pro)TyrGlyHis HisValThrAsp(His)(Thr)ValValTyrGly(Ser) ?(Ser)?-Lys. The NH₂-terminal sequence of a 50K, gelatin-binding, subtilisin fragment by L. I. Gold, A. Garcia-Pardo, B. Prangione, E. C. Franklin, and E. Pearlstein (1979, Proc. Nat. Acad. Sci. USA76, 4803–4807) is identical to positions 3–19 (with the exception of some ambiguity at position 14) of the 29K fragment. These data strongly suggest that the 29K tryptic fragment is included in the 50K subtilisin fragment, and that subtilisin cleaves fibronectin between the Ala²Val³ residues of the 29K tryptic fragment. The 18K heparin-binding fragment had the following NH₂-terminal sequence: (Glu)AlaProGlnProHisCysIleSerLysTyrIle LeuTyrTrpAspProLysAsnSerValGly?(Pro) LysGluAla?(Val)(Pro). The 29K gelatin-binding and 18K heparin-binding fragments have proline-rich NH₂-terminal sequences suggesting that they may have arisen from protease-sensitive, random coil regions of fibronectin corresponding to interdomain regions preceding macromolecular-binding domains. Both of these fragments contain the identical sequence ProGlnProHis, a sequence which may be repeated in other interdomain regions of fibronectin. The 24K DNA-binding fragment has the following NH₂-terminal sequence: SerAspThrValProSerProCysAspLeuGlnPhe ValGluValThrAspVal LysValThrIleMetTrpThrProProGluSerAla ValThrGlyTyrArgVal AspValCysProValAsnLeuProGlyGluHisGly Gln(Cys)LeuProIleSer. The sequence of positions 9–22 are homologous to positions 15–28 of the α chain of DNA-dependent RNA polymerase from Escherichia coli. The homology observed suggests that this stretch of amino acids may be a DNA-binding site.     

The amino acid sequence of human chorionic gonadotropin. The alpha subunit and beta subunit.

The amino acid sequences of both the alpha and beta subunits of human chorionic gonadotropin have been determined. The amino acid sequence of the alpha subunit is: Ala - Asp - Val - Gln - Asp - Cys - Pro - Glu - Cys-10 - Thr - Leu - Gln - Asp - Pro - Phe - Ser - Gln-20 - Pro - Gly - Ala - Pro - Ile - Leu - Gln - Cys - Met - Gly-30 - Cys - Cys - Phe - Ser - Arg - Ala - Tyr - Pro - Thr - Pro-40 - Leu - Arg - Ser - Lys - Lys - Thr - Met - Leu - Val - Gln-50 - Lys - Asn - Val - Thr - Ser - Glu - Ser - Thr - Cys - Cys-60 - Val - Ala - Lys - Ser - Thr - Asn - Arg - Val - Thr - Val-70 - Met - Gly - Gly - Phe - Lys - Val - Glu - Asn - His - Thr-80 - Ala - Cys - His - Cys - Ser - Thr - Cys - Tyr - Tyr - His-90 - Lys - Ser. Oligosaccharide side chains are attached at residues 52 and 78. In the preparations studied approximately 10 and 30% of the chains lack the initial 2 and 3 NH2-terminal residues, respectively. This sequence is almost identical with that of human luteinizing hormone (Sairam, M. R., Papkoff, H., and Li, C. H. (1972) Biochem. Biophys. Res. Commun. 48, 530-537). The amino acid sequence of the beta subunit is: Ser - Lys - Glu - Pro - Leu - Arg - Pro - Arg - Cys - Arg-10 - Pro - Ile - Asn - Ala - Thr - Leu - Ala - Val - Glu - Lys-20 - Glu - Gly - Cys - Pro - Val - Cys - Ile - Thr - Val - Asn-30 - Thr - Thr - Ile - Cys - Ala - Gly - Tyr - Cys - Pro - Thr-40 - Met - Thr - Arg - Val - Leu - Gln - Gly - Val - Leu - Pro-50 - Ala - Leu - Pro - Gin - Val - Val - Cys - Asn - Tyr - Arg-60 - Asp - Val - Arg - Phe - Glu - Ser - Ile - Arg - Leu - Pro-70 - Gly - Cys - Pro - Arg - Gly - Val - Asn - Pro - Val - Val-80 - Ser - Tyr - Ala - Val - Ala - Leu - Ser - Cys - Gln - Cys-90 - Ala - Leu - Cys - Arg - Arg - Ser - Thr - Thr - Asp - Cys-100 - Gly - Gly - Pro - Lys - Asp - His - Pro - Leu - Thr - Cys-110 - Asp - Asp - Pro - Arg - Phe - Gln - Asp - Ser - Ser - Ser - Ser - Lys - Ala - Pro - Pro - Pro - Ser - Leu - Pro - Ser-130 - Pro - Ser - Arg - Leu - Pro - Gly - Pro - Ser - Asp - Thr-140 - Pro - Ile - Leu - Pro - Gln. Oligosaccharide side chains are found at residues 13, 30, 121, 127, 132, and 138. The proteolytic enzyme, thrombin, which appears to cleave a limited number of arginyl bonds, proved helpful in the determination of the beta sequence.     

Formation of specific T3-RNA-polymerase complexes with oligoribonucleotides and inhibition of DNA-dependent RNA synthesis

It was shown previously that E. coli RNA polymerase and T7 RNA polymerase being incubated with oligonucleotides of different length derived from RNA endonuclease hydrolysate bind selectively to certain oligonucleotides with the length larger than or equal to 5. The data presented demonstrate that T3 RNA polymerase also binds selectively from the isoplith mixtures certain oligonucleotides starting from pentanucleotides. Adding of excess of T3 RNA polymerase it was possible to exhaustively extract the recognizable oligonucleotides from the isoplith mixture. However, the exhausted by T3 RNA polymerase mixture of pentanucleotides still contained those which are bound selectively by T7 and E. coli RNA polymerases. The data suggest that various RNA-polymerases recognize different oligoribonucleotides. It was shown that T3 DNA inhibits the selective binding of penta-or heptaribonucleotides to T3 RNA polymerase competing obviously for the enzyme. The T3 RNA polymerase bound penta- or heptanucleotides inhibit DNA-dependent RNA synthesis carried out by the enzyme; the isoplith mixtures which do not contain T3 RNA polymerase bound oligonucleotides are deprived of the inhibitory properties. Only those isoplith mixtures contain T3 RNA polymerase bound oligonucleotides which were derived from symmetrically transcribed RNA which have obviously promoter simulating sequences. The data provide evidence that T2 RNA polymerase binds selectively the oligonucleotides mimicking the promotor recognition sites.     

“Host Shutoff” Function of Bacteriophage T7: Involvement of T7 Gene 2 and Gene 0.7 in the Inactivation of Escherichia coli RNA Polymerase

The "host shutoff" function of bacteriophage T7 involves an inactivation of the host Escherichia coli RNA polymerase by an inhibitor protein bound to the enzyme. When this inhibitor protein, termed I protein, was removed from the inactive RNA polymerase complex prepared from T7-infected cells by glycerol gradient centrifugation in the presence of 1 M KCl, the enzyme recovered its activity equivalent to about 70 to 80% of the activity of the enzyme from uninfected cells. Analysis of the activity of E. coli RNA polymerase from E. coli cells infected with various T7 mutant phages indicated that the T7 gene 2 codes for the inhibitor I protein. The activity of E. coli RNA polymerase from gene 2 mutant phage-infected cells, which was about 70% of that from uninfected cells, did not increase after glycerol gradient centrifugation in the presence of 1 M KCl, indicating that the salt-removable inhibitor was not present with the enzyme. It was found that the reduction in E. coli RNA polymerase activity in cells infected with T7(+) or gene 2 mutant phage, i.e., about 70% of the activity of the enzyme compared to that from uninfected cells after glycerol gradient centrifugation in the presence of 1 M KCl, results from the function of T7 gene 0.7. E. coli RNA polymerase from gene 0.7 mutant phage-infected cells was inactive but recovered a full activity equivalent to that from uninfected cells after removal of the inhibitor I protein with 1 M KCl. E. coli RNA polymerase from the cells infected with newly constructed mutant phages having mutations in both gene 2 and gene 0.7 retained the full activity equivalent to that from uninfected cells with or without treatment of the enzyme with 1 M KCl. From these results, we conclude that both gene 2 and gene 0.7 of T7 are involved in accomplishing complete shutoff of the host E. coli RNA polymerase activity in T7 infection.     

Probing functional perfection in substructures of ribonuclease T1: double combinatorial random mutagenesis involving Asn43, Asn44, and Glu46 in the guanine binding loop

Combinatorial random mutageneses involving either Asn43 with Asn44 (set 1) or Glu46 with an adjacent insertion (set 2) were undertaken to explore the functional perfection of the guanine recognition loop of ribonuclease T(1) (RNase T(1)). Four hundred unique recombinants were screened in each set for their ability to enhance enzyme catalysis of RNA cleavage. After a thorough selection procedure, only six variants were found that were either as active or more active than wild type which included substitutions of Asn43 by Gly, His, Leu, or Thr, an unplanned Tyr45Ser substitution and Glu46Pro with an adjacent Glu47 insertion. Asn43His-RNase T(1) has the same loop sequence as that for RNases Pb(1) and Fl(2). None of the most active mutants were single substitutions at Asn44 or double substitutions at Asn43 and Asn44. A total of 13 variants were purified, and these were subjected to kinetic analysis using RNA, GpC, and ApC as substrates. Modestly enhanced activities with GpC and RNA involved both k(cat) and K(M) effects. Mutants having low activity with GpC had proportionately even lower relative activity with RNA. Asn43Gly-RNase T(1) and all five of the purified mutants in set 2 exhibited similar values of k(cat)/K(M) for ApC which were the highest observed and about 10-fold that for wild type. The specificity ratio [(k(cat)/K(M))(GpC)/(k(cat)/K(M))(ApC)] varied over 30 000-fold including a 10-fold increase [Asn43His variant; mainly due to a low (k(cat)/K(M))(ApC)] and a 3000-fold decrease (Glu46Ser/(insert)Gly47 variant; mainly due to a low (k(cat)/K(M))(GpC)) as compared with wild type. It is interesting that k(cat) (GpC) for the Tyr45Ser variant was almost 4-fold greater than for wild type and that Pro46/(insert)Glu47 RNase T(1) is 70-fold more active than the permuted variant (insert)Pro47-RNase T(1) which has a conserved Glu46. In any event, the observation that only 6 out of 800 variants surveyed had wild-type activity supports the view that functional perfection of the guanine recognition loop of RNase T(1) has been achieved.     

Different substrate specificities of two triazine hydrolases (TrzNs) from Nocardioides species

Nocardioides sp. strain MTD22 degraded atrazine, ametryn and atraton, as did Arthrobacter aurescens strain TC1 and Nocardioides sp. strain C190. These strains contain trzN, a gene coding for TrzN, triazine hydrolase showing a broad substrate range. However, Nocardioides sp. strain AN3 degraded only atrazine despite containing trzN. These differences in s-triazine degradation are presumed to be due to differences in the amino acid sequences of TrzNs. Consequently, 1371 nucleotides of the trzN coding sequences of strains AN3 and MTD22 were determined. Comparisons of the amino acid sequences of TrzNs indicated that three residues of strain AN3 (Thr(214), His(215) and Gln(241)) were distinct from those of the other three strains (Pro(214), Tyr(215) and Glu(241)). To confirm the relationships between these amino acid sequences and the substrate specificities of TrzNs, wild and chimera trzN genes were constructed and expressed in Escherichia coli cells. Cells expressing wild MTD22 trzN (Pro(214)Tyr(215)Glu(241)) and chimera AN3-MTD22 trzN (Thr(214)His(215)Glu(241)) degraded all s-triazines, but the degradation rate was markedly decreased in AN3-MTD22 trzN. Wild AN3 trzN (Thr(214)His(215)Gln(241)) and chimera MTD22-AN3 trzN (Pro(214)Tyr(215)Gln(241)) degraded only atrazine. These results suggest that the substitution of Glu(241) for Gln(241) significantly decreases enzyme affinity for ametryn and atraton.     

Sequences of tryptic peptides containing the five cysteinyl residues of ribulosebisphosphate carboxylase/oxygenase from Rhodospirillum rubrum

Tryptic peptides which account for all five cysteinyl residues in ribulosebisphosphate carboxylase/oxygenase from Rhodospirillum rubrum have been purified and sequenced. Collectively, these peptides contain 94 of the approximately 500 amino acid residues per molecule of subunit. Due to one incomplete cleavage at a site for trypsin and two incomplete chymotryptic-like cleavages, eight major radioactive peptides (rather than five as predicted) were recovered from tryptic digests of the enzyme that had been carboxymethylated with [³H]iodoacetate. The established sequences are: GlyTyrThrAlaPheValHisCys¹Lys TyrValAspLeuAlaLeuLysGluGluAspLeuIleAla GlyGlyGluHisValLeuCys¹AlaTyr AlaGlyTyrGlyTyrValAlaThrAlaAlaHisPheAla AlaGluSerSerThrGlyThrAspValGluValCys¹ ThrThrAsxAsxPheThrArg AlaCys¹ThrProIleIleSerGlyGlyMetAsnAla LeuArg ProPheAlaGluAlaCys¹HisAlaPheTrpLeuGly GlyAsnPheIleLys In these peptides, radioactive carboxymethylcysteinyl residues are denoted with asterisks and the sites of incomplete cleavage with vertical wavy lines. None of the peptides appear homologous with either of two cysteinyl-containing, active-site peptides previously isolated from spinach ribulosebisphosphate carboxylase/oxygenase.     

Human carbonic anhydrase I: Effect of specific site mutations on its function

Carbonic anhydrase I (CAI) is one out of ten CA isoenzymes that have been identified in humans. X-ray crystallographic and inhibitor complex studies of human carbonic anhydrase I (HCAI) and related studies in other CA isoenzymes identified several residues, in particular Thr199, GlulO6, Tyr7, Glull7, His l07, with likely involvement in the catalytic activity of HCAI. To further study the role of these residues, we undertook, site-directed mutagenesis of HCAI. Using a polymerase chain reaction based strategy and altered oligonucleotide primers, we modified a cloned wild type hCAI gene so as to produce mutant genes encoding proteins with single amino acid substitutions. Thrl99Val, Thrl99Cys, Thr199Ser, GlulO6Ile, Glul06Gln, Tyr7Trp, Glu.117Gln, and His 107Val mutations were thus generated and the activity of each measured by ester hydrolysis. Overproduction of the Glu117Gln and HisI07Val mutant proteins inEscherichia coli resulted in a large proportion of the enzyme forming aggregates probably due to folding defect. The mutations Thr199Val, GlulO6Ile and GlulO6Gln gave soluble protein with drastically reduced enzyme activity, while the Tyr7Trp mutation had only marginal effect on the activity, thus s.uggesting important roles for Thr199 and Glu lO6 but not for Tyr7 in the catalytic function of HCAI.     

SPXX, a frequent sequence motif in gene regulatory proteins

A new DNA-binding unit, composed of four amino acid residues and common in gene regulatory proteins, is proposed. The occurrences of the sequences Ser-Pro-X-X (SPXX) and Thr-Pro-X-X (TPXX) in gene regulatory proteins are compared with those in general proteins. These sequences are found more frequently in gene regulatory proteins including homoeotic gene products, segmentation gene products, steroid hormone receptors and certain oncogene products, than they are in DNA-binding proteins that are not directly involved in gene regulation, such as the core histones, or in general proteins. It is therefore suggested that these sequences contribute to DNA-binding in a manner important for gene regulation. Amino acid residues characteristic of the types of proteins are found as the variable residues X: basic residues, Lys and Arg, in histones, H1 and sea urchin spermatogenous H2B; Tyr in RNA polymerase II; and Ser, Thr, Ala, Leu and Pro in other gene regulatory proteins S(T)PXX sequences are located on either side of other DNA-recognizing units such as Zn fingers, helix-turn-helices, and cores of histones. The structure of a S(T)PXX sequence is presumed to be a beta-turn I stabilized by two hydrogen bonds, and its potential mode of DNA-binding is discussed.