Linker polypeptides of the phycobilisome from the cyanobacterium Mastigocladus laminosus. I. Isolation and characterization of phycobiliprotein-linker-polypeptide complexes

Phycobilisomes from the cyanobacterium Mastigocladus laminosus cultured in white and red light were isolated and compared with respect to the phycoerythrocyanin (PEC) and linker polypeptide contents. It was verified that the production of PEC is induced by low light intensities. A PEC complex, (alpha PEC beta PEC)6LR34.5,PEC, and a phycocyanin (PC) complex, (alpha PC beta PC)6LR34.5,PC, were isolated from phycobilisomes by Cellex-D anion exchange chromatography and sucrose density gradient centrifugation. The absorption and fluorescence emission maxima of the PEC complex are at 575 and 620 nm and those of the PC complex are at 631 and 647 nm, respectively. The extinction coefficients of the two complexes were determined. From different experiments it was concluded that PEC is present as a hexameric complex, (alpha PEC beta PEC)6LR34.5,PEC, in the phycobilisome. The two linker polypeptides LR34.5,PEC and LR34.5,PC were isolated from their phycobiliprotein complexes by gel filtration on Bio-Gel P-100 in 50% formic acid. A 5-kDa terminal segment of both linker polypeptides was found to influence the hexamer formation of the phycobiliproteins. The same segments have been described to be responsible for the hexamer-hexamer linkage (Yu, M.-H. & Glazer, A.N. (1982) J. Biol. Chem. 257, 3429-3433). A 8.9-kDa linker polypeptide, LR(C)8.9, was isolated from a PEC fraction of the Cellex-D column by Bio-Gel P-100 gel filtration in 50% formic acid. Localisation of this protein within the phycobilisome was attempted. Its most probable function is to terminate the phycobilisomal rods at the end distal to the allophycocyanin core.     

Linker polypeptides of the phycobilisome from the cyanobacterium Mastigocladus laminosus: amino-acid sequences and relationships

Three linker polypeptides of the phycobilisome from the cyanobacterium Mastigocladus laminosus were isolated: A 8.9-kDa polypeptide, L8.9R(C), which is probably associated with C-phycocyanin, a 34.5-kDa polypeptide, L34.5,PCR, which forms a complex with C-phycocyanin, and a 34.5-kDa polypeptide, L34.5,PECR, which is linked to phycoerythrocyanin. The complete amino-acid sequence (80 residues) of the L8.9R(C) polypeptide was determined as well as the N-terminal 44 residues of both L34.5R polypeptides and the 114 C-terminal residues of L34.5,PECR. L8.9R(C) is homologous to L8.9C (Füglistaller et al. (1984) Hoppe-Seyler's Z. Physiol. Chem. 365, 1085-1096) and to the C-terminal sequence of L34.5,PECR. The N-terminal sequences of L34.5,PECR and L34.5,PCR exhibit 34% homology. The 44 N-terminal residues of L34.5,PECR are related to the beta-subunit of phycoerythrocyanin (23% homology), while the C-terminal sequence of L34.5,PECR is more related to alpha PEC (21% homology within 60 residues). This suggests that the 30-kDa-linker polypeptide family originates from a fusion of the alpha- and beta-subunit genes and the corresponding intercistronic DNA sequence, as might have arisen through mutation in the stop-codon of the beta-subunit gene. Hence, all polypeptides of the phycobilisome (including perhaps the anchor polypeptide) may be derived from an early ancestor phycobiliprotein subunit, which itself is also related to myoglobin (Schirmer et al. (1985) J. Mol. Biol. 184, 251-277).     

Three C-phycoerythrin-associated linker polypeptides in the phycobilisome of green-light-grown Calothrix sp. PCC 7601 (cyanobacteria).

Microanalyses by SDS-PAGE and microsequencing demonstrate that, under green-light conditions, 3 C-phycoerythrin associated rod-linker polypeptides with different N-terminal amino acid sequences are present in phycobilisomes (PBS) from Calothrix sp. 7601 cells. Two of these polypeptides, corresponding to SDS-PAGE bands at 36 and 37 kDa, could be assigned, respectively, to the cpeC and cpcD genes found on a separate cpeCD-operon in Calothrix sp. 7601 (Federspiel, N.A. and Grossman, A.R. (1990) J. Bacteriol, 172, 4072-4081). The third C-PE rod-linker polypeptide, LR,2PE,33, requires, therefore, a third gene with the suggested locus designation 'cpeE'. A C-PE (alpha beta)6-LR,2PE,33 complex containing this third rod-linker polypeptide could be isolated from phycobilisomes and characterized. PBS from both green- and red-light cells of Calothrix contain a single, unique LRC28 rod-core linker polypeptide which is not altered during chromatic adaptation.     

Functional assembly of fragments from bisected smooth muscle myosin light chain kinase

The C-terminal regulatory segment of smooth muscle myosin light chain kinase folds back on its catalytic core to inhibit kinase activity. This regulatory segment consists of autoinhibitory residues linking the catalytic core to the calmodulin-binding sequence and perhaps additional C-terminal residues including an immunoglobulin-like motif. However, mutational and biochemical analyses showed no specific involvement of residues C-terminal to the calmodulin-binding sequence. To obtain additional insights on the proposed mechanisms for autoinhibition and Ca(2+)/calmodulin activation of the kinase, the polypeptide backbone chain of myosin light chain kinase was cleaved by genetic means to produce N- and C-terminal protein fragments. The N-terminal fragment containing the catalytic core was catalytically inactive when expressed alone. Co-expression of the N-terminal fragment with the C-terminal fragment containing the regulatory segment restored kinase activity. Deletion of the autoinhibitory linker residues without or with the calmodulin-binding sequence prevented restoration of kinase activity. In the presence or absence of Ca(2+)/calmodulin, regulatory segment binding occurred through the linker region connecting the catalytic core to the calmodulin-binding sequence. Collectively, these results indicate that residues C-terminal to the calmodulin-binding sequence (including the immunoglobulin-like motif) are not functional components of the regulatory segment. Furthermore, the principal autoinhibitory motif is contained in the sequence linking the catalytic core of myosin light chain kinase to the calmodulin-binding sequence.     

The light-harvesting polypeptides of Rhodospirillum rubrum. II. Localisation of the amino-terminal regions of the light-harvesting polypeptides B 870-alpha and B 870-beta and the reaction-centre subunit L at the cytoplasmic side of the photosynthetic membrane of Rhodospirillum rubrum G-9+

The unspecific proteinase K and the specific proteases alpha-chymotrypsin, trypsin and S. aureus V 8 protease were used in order to determine the orientation of the polypeptides B 870-alpha and B 870-beta from the major antenna complex B 870 of Rs. rubrum G-9+ within the chromatophore membrane (inside-out vesicle). Although B 870-alpha exhibits cleavable peptide bonds, treatment with specific proteases yielded splitting only in B 870-beta within the N-terminal region. In the case of proteinase K, which was most effective, mainly 6 (B 870-alpha) and 16 (B 870-beta) amino acid residues were removed from their N-terminal parts as proved by means of Edman degradation of cleavage products. The major peptide bonds cleaved were identified as Gln6-Leu7 in B 870-alpha and as Lys16-Glu17 in B 870-beta. The central hydrophobic stretch regions and the relatively hydrophilic C-terminal parts of both light-harvesting polypeptides were not affected by proteinase K. On the basis of these degradation experiments a transmembrane orientation of B 870-alpha and B 870-beta is postulated, with their N-terminal towards the cytoplasm and their C-termini towards periplasm with regard to the photosynthetic membrane. This hypothesis is supported by the transmembrane model proposed by Brunisholz et al. (Hoppe-Seyler's Z., Physiol. Chem., (1984) 365, 675-688) in which the hydrophobic stretch of B 870-alpha and of B 870-beta forming an alpha-helix would span the membrane once. Organic solvent extraction of chromatophores treated with proteinase K yielded a fairly pure polypeptide fragment with an apparent molecular mass of 14000 Da. Its N-terminal amino-acid sequence is identical with the sequence within the N-terminal region of the reaction centre subunit L of Rs. rubrum G-9+. Thus it is most likely that as in the case of B 870-beta, proteinase K removed 16 amino acid residues from the N-terminal part of subunit L. This subunit therefore also seems to be exposed at the surface of the cytoplasmic side of the chromatophore membrane.     

Localization of reaction center and B800-850 antenna pigment proteins in membranes of Rhodobacter sphaeroides.

The localization of the N- and C-terminal regions of pigment-binding polypeptides of the bacterial photosynthetic apparatus of Rhodobacter sphaeroides was investigated by proteinase K treatment of chromatophore and spheroplast-derived vesicles and amino acid sequence determination. Under conditions of proteinase K treatment of chromatophores, which left the in vivo absorption spectrum and the membrane intact, 15 and 46 amino acyl residues from the N-terminal regions of the L and M subunits, respectively, of the reaction center polypeptides were removed. The N termini are therefore exposed on the cytoplasmic surface of the membrane. The C-terminal domain of the light-harvesting B800-850 alpha and B870 alpha polypeptides was found to be exposed on the periplasmic surface of the membrane. A total of 9 and 13 amino acyl residues were cleaved from the B800-850 alpha and B870 alpha polypeptides, respectively, when spheroplasts were treated with proteinase K. The N-terminal regions of the alpha polypeptides were not digested in either membrane preparation and were apparently protected from proteolytic attack. Seven N-terminal amino acyl residues of the B800-850 beta polypeptide were removed after the digestion of chromatophores. C-terminal residues were not removed after the digestion of chromatophores or spheroplasts. The C termini seem to be protected from protease attack by interaction with the membrane. Therefore, the N-terminal regions of the beta polypeptides are exposed on the cytoplasmic membrane surface. The C termini of the beta polypeptides are believed to point to the periplasmic space.     

The primary structure of the fourth component of human complement (C4)-C-terminal peptides

C-terminal CNBr peptides of the three polypeptide chains of C4 were obtained and sequenced. These results supplement previously obtained data, notably the protein sequence derived from cDNA sequencing of pro-C4 (Belt KT, Carroll MC & Porter RR (1984) Cell 36, 907-914) and the N-terminal sequences of the three polypeptides (Gigli I, von Zabern I & Porter RR (1977) Biochem. J. 165, 439-446), to define the complete primary structure of the plasma form of C4. The beta (656 residues), alpha (748 residues), and gamma (291 residues) chains are found in positions 1-656, 661-1408, and 1435-1725 in the pro-C4 molecule.     

Localization of N-terminal sequences in human AMP deaminase isoforms that influence contractile protein binding.

The reversible association of AMP deaminase (AMPD, EC 3.5.4.6) with elements of the contractile apparatus is an identified mechanism of enzyme regulation in mammalian skeletal muscle. All three members of the human AMPD multigene family contain coding information for polypeptides with divergent N-terminal and conserved C-terminal domains. In this study, serial N-terminal deletion mutants of up to 111 (AMPD1), 214 (AMPD2), and 126 (AMPD3) residues have been constructed without significant alteration of catalytic function or protein solubility. The entire sets of active enzymes are used to extend our understanding of the contractile protein binding of AMPD. Analysis of the most truncated active enzymes demonstrates that all three isoforms can associate with skeletal muscle actomyosin and suggests that a primary binding domain is located within the C-terminal 635-640 residues of each polypeptide. However, discrete stretches of N-terminal sequence alter this behavior. Residues 54-83 in the AMPD1 polypeptide contribute to a high actomyosin binding capacity of both isoform M spliceoforms, although the exon 2- enzyme exhibits significantly greater association compared to its exon 2+ counterpart. Conversely, residues 129-183 in the AMPD2 polypeptide reduce actomyosin binding of isoform L. In addition, residues 1-48 in the AMPD3 polypeptide dramatically suppress contractile protein binding of isoform E, thus allowing this enzyme to participate in other intracellular interactions.     

Hirunorms are true hirudin mimetics. The crystal structure of human alpha-thrombin-hirunorm V complex.

A novel class of synthetic, multisite-directed thrombin inhibitors, known as hirunorms, has been described recently. These compounds were designed to mimic the binding mode of hirudin, and they have been proven to be very strong and selective thrombin inhibitors. Here we report the crystal structure of the complex formed by human alpha-thrombin and hirunorm V, a 26-residue polypeptide containing non-natural amino acids, determined at 2.1 A resolution and refined to an R-factor of 0.176. The structure reveals that the inhibitor binding mode is distinctive of a true hirudin mimetic, and it highlights the molecular basis of the high inhibitory potency (Ki is in the picomolar range) and the strong selectivity of hirunorm V. Hirunorm V interacts through the N-terminal tetrapeptide with the thrombin active site in a nonsubstrate mode; at the same time, this inhibitor specifically binds through the C-terminal segment to the fibrinogen recognition exosite. The backbone of the N-terminal tetrapeptide Chg1"-Val2"-2-Nal3"-Thr4" (Chg, cyclohexyl-glycine; 2-Nal, beta-(2-naphthyl)-alanine) forms a short beta-strand parallel to thrombin main-chain residues Ser214-Gly219. The Chg1" side chain fills the S2 subsite, Val2" is located at the entrance of S1, whereas 2-Nal3" side chain occupies the aryl-binding site. Such backbone orientation is very close to that observed for the N-terminal residues of hirudin, and it is similar to that of the synthetic retro-binding peptide BMS-183507, but it is opposite to the proposed binding mode of fibrinogen and of small synthetic substrates. Hirunorm V C-terminal segment binds to the fibrinogen recognition exosite, similarly to what observed for hirudin C-termninal tail and related compounds. The linker polypeptide segment connecting hirunorm V N-and C-terminal regions is not observable in the electron density maps. The crystallographic analysis proves the correctness of the design and it provides a compelling proof on the interaction mechanism for this novel class of high potency multisite-directed synthetic thrombin inhibitors.     

Synthesis and membrane-dependent processing of a precursor of tick-borne encephalitis virus (flavivirus) structural proteins in cell-free systems

Conditions that permitted cell-free synthesis of at least one of the non-structural, in addition to two-structural, polypeptides of tick-borne encephalitis virus have been found. The time course of accumulation of virus-specific polypeptides in extracts of Krebs-2 cells and reticulocyte lysates as well as the peptide maps of the products synthesised were studied. A model of generation of viral structural polypeptides has been proposed, according to which a common precursor of these proteins while in a nascent form, is processed in a membrane-dependent reaction into a C-terminal segment, corresponding to the polypeptide moiety of envelope glycoprotein E, and an N-terminal segment, doublet p36/33. Subsequently, an N-terminal segment, corresponding to the core polypeptide C, is cleaved off from p36/33. The remaining C-terminal segment of p36/33 is possibly a precursor of the membrane polypeptide M. The translational strategy of flaviviruses is compared to that of other positive-stranded RNA viruses.     

Improved method for mapping the binding site of an actin-binding protein in the actin sequence. Use of a site-directed antibody against the N-terminal region of actin as a probe of its N-terminus

An antibody was raised against the N-terminal 18 residues of rabbit skeletal muscle actin. By the use of this antibody as the N-terminal probe of actin and the fluorescent label at Cys-374 as its C-terminal probe, binding sites of depactin (an actin-depolymerizing protein from starfish oocytes) were identified in the actin sequence according to the method of Sutoh [Sutoh, K. (1982) Biochemistry 21, 3654-3661]. Cross-linking of the one-to-one complex of actin and depactin with 1-ethyl-3-[3-(dimethylamino)propyl]-carbodiimide (EDC) generated two types of cross-linked products with slightly different apparent molecular weights, denoted as 60KU and 60KL. By the use of the N-terminal probe, it was unequivocally revealed that the C-terminal actin segment of residues 357-375 participated in cross-linking with depactin to form 60KL. On the other hand, by the use of the C-terminal probe it was revealed that the N-terminal actin segment of residues 1-12 participated in cross-linking with depactin to form 60KU. Since EDC cross-links Lys residue with Asp or Glu residue only when they are in direct contact, the result indicates that some of the N-terminal residues 1-12 and the C-terminal residues 357-375 of actin participate in binding depactin. The introduction of the N-terminal probe (the antibody recognizing the actin N-terminus) has increased the flexibility of the mapping method for locating binding sites of actin-binding proteins in the actin sequence.     

Cysteine proteases of positive strand RNA viruses and chymotrypsin-like serine proteases. A distinct protein superfamily with a common structural fold

Evidence is presented, based on sequence comparison and secondary structure prediction, of structural and evolutionary relationship between chymotrypsin-like serine proteases, cysteine proteases of positive strand RNA viruses (3C proteases of picornaviruses and related enzymes of como-, nepo- and potyviruses) and putative serine protease of a sobemovirus. These observations lead to re-identification of principal catalytic residues of viral proteases. Instead of the pair of Cys and His, both located in the C-terminal part of 3C proteases, a triad of conserved His, Asp(Glu) and Cys(Ser) has been identified, the first two residues resident in the N-terminal, and Cys in the C-terminal beta-barrel domain. These residues are suggested to form a charge-transfer system similar to that formed by the catalytic triad of chymotrypsin-like proteases. Based on the structural analogy with chymotrypsin-like proteases, the His residue previously implicated in catalysis, together with two partially conserved Gly residues, is predicted to constitute part of the substrate-binding pocket of 3C proteases. A partially conserved ThrLys/Arg dipeptide located in the loop preceding the catalytic Cys is suggested to confer the primary cleavage specificity of 3C toward Glx/Gly(Ser) sites. These observations provide the first example of relatedness between proteases belonging, by definition, to different classes.     

Chromatographic and protein chemical analysis of the ubiquinol-cytochrome c2 oxidoreductase isolated from Rhodobacter sphaeroides

The ubiquinol-cytochrome c2 oxidoreductase (cytochrome bc1 complex) purified from chromatophores of Rhodobacter sphaeroides consists of four polypeptide subunits corresponding to cytochrome b, c1, and the Rieske iron-sulfur protein, as well as a 14-kDa polypeptide of unknown function, respectively. In contrast, the complex isolated from Rhodospirillum rubrum by the same procedure lacked a polypeptide corresponding to the 14-kDa subunit. Gel-permeation chromatography of the R. sphaeroides cytochrome bc1 complex in the presence of 200 mM NaCl removed the iron-sulfur protein, while the 14-kDa polypeptide remained tightly bound to the cytochromes; this is consistent with the possibility that the latter protein is an authentic component of the complex rather than an artifact of the isolation procedure. The individual polypeptides of the R. sphaeroides complex were purified to homogeneity by gel-permeation chromatography in the presence of 50% aqueous formic acid and their amino acid compositions determined. The 14-kDa polypeptide was found to be rich in charged and polar residues. Edman degradation analysis indicated that its N terminus is blocked and not rendered accessible by de-blocking procedures. Cyanogen bromide cleavage gave rise to a blocked N-terminal fragment as well as a C-terminal peptide comprising more than one-third of the protein. Gas-phase sequence analysis of this peptide established a sequence of 48 residues and identified a putative trans-membrane segment near the C terminus. The blocked N-terminal fragment was cleaved at tryptophan with BNPS-skatole. The resulting peptides, together with tryptic fragments derived from the intact protein, yielded additional sequence information; however, none of the sequences exhibited significant homologies to any known proteins. Tryptic fragments were also used to generate sequence information for cytochrome c1.     

Human low-molecular-weight urinary urokinase. Partial characterization and preliminary sequence data of the two polypeptide chains

Low-molecular-weight urokinase (molecular weight 33100) was separated by analytical and preparative isoelectric focusing into five major subforms with isoelectric points between 8.7 and 9.6. These subforms are very similar in molecular weight, specific activity, amino acid composition and content of amino sugar and their N-terminal sequence constellation is identical. Low-molecular-weight urokinase consists of two polypeptide chains connected by a single disulfide bridge. The N-terminal region of the heavy chain (calculated Mr 30700) exhibits homology within the first 46 residues analyzed, with the known primary structure of other serine proteases. The mini chain (Mr 2426), whose complete sequence was determined, consists of 21 residues which show homology with the primary structure of the C-terminal region of the plasmin heavy chain. Based on sequence data and homology criteria with serine proteases a single-chain urokinase precursor is postulated having a peptide bond constellation between heavy and light chain region compatible with the requirements for serine protease activation.     

The complete amino-acid sequence of the large bacteriochlorophyll-binding polypeptide from light-harvesting complex II (B800-850) of Rhodopseudomonas capsulata

The large bacteriochlorophyll-a-binding polypeptide of the light-harvesting complex II (B800-850), having an apparent Mr with sodium dodecyl sulfate/polyacrylamide electrophoresis of 10000, has been isolated and purified from intracytoplasmic membranes of the phototrophically negative mutant strain Y5 of Rhodopseudomonas capsulata. The primary structure of this polypeptide has been determined. The polypeptide consists of 60 amino acid residues yielding an Mr of 7322. The hydrophobic stretch in positions 16-35 with a histidine in position 31 might be of importance for interaction with bacteriochlorophyll. The C-terminal part is also hydrophobic while the N-terminal part consists of hydrophilic amino acids. The polarity of the total amino acids was determined to be 28.3%.     

Nuclear magnetic resonance solution structure of hirudin(1-51) and comparison with corresponding three-dimensional structures determined using the complete 65-residue hirudin polypeptide chain.

The three-dimensional structure of the N-terminal 51-residue domain of recombinant hirudin in aqueous solution was determined by 1H nuclear magnetic resonance (NMR) spectroscopy, and the resulting high-quality solution structure was compared with corresponding structures obtained from studies with the intact, 65-residue polypeptide chain of hirudin. On the basis of 580 distance constraints derived from nuclear Overhauser effects and 109 dihedral angle constraints, a group of 20 conformers representing the solution structure of hirudin(1-51) was computed with the program DIANA and energy-minimized with a modified version of the program AMBER. Residues 3 to 30 and 37 to 48 form a well-defined molecular core with two antiparallel beta-sheets composed of residues 14 to 16 and 20 to 22, and 27 to 31 and 36 to 40, and three reverse turns at residues 8 to 11 (type II), 17 to 20 (type II') and 23 to 26 (type II). The average root-mean-square deviation of the individual NMR conformers relative to their mean co-ordinates is 0.38 A for the backbone atoms and 0.77 A for all heavy atoms of these residues. Increased structural disorder was found for the N-terminal dipeptide segment, the loop at residues 31 to 36, and the C-terminal tripeptide segment. The solution structure of hirudin(1-51) has the same molecular architecture as the corresponding polypeptide segment in natural hirudin and recombinant desulfatohirudin. It is also closely similar to the crystal structure of the N-terminal 51-residue segment of hirudin in a hirudin-thrombin complex, with root-mean-square deviations of the crystal structure relative to the mean solution structure of 0.61 A for the backbone atoms and 0.91 A for all heavy atoms of residues 3 to 30 and 37 to 48. Further coincidence is found for the loop formed by residues 31 to 36, which shows increased structural disorder in all available solution structures of hirudin, and of which residues 32 to 35 are not observable in the electron density map of the thrombin complex. Significant local structural differences between hirudin(1-51) in solution and hirudin in the crystalline thrombin complex were identified mainly for the N-terminal tripeptide segment and residues 17 to 21. These are further analyzed in an accompanying paper.     

Structure, composition, and assembly of paracrystalline phycobiliproteins in Synechocystis sp. strain BO 8402 and of phycobilisomes in the derivative strain BO 9201.

The phycobiliproteins of the unicellular cyanobacterium Synechocystis sp. strain BO 8402 and its derivative strain BO 9201 are compared. The biliproteins of strain BO 8402 are organized in paracrystalline inclusion bodies showing an intense autofluorescence in vivo. These protein-pigment aggregates have been isolated. The highly purified complexes contain phycocyanin with traces of phycoerythrin, corresponding linker polypeptides LR35PC and LR33PE (the latter in a small amount), and a unique colored polypeptide with an M(r) of 55,000, designated L55. Allophycocyanin and the core linker polypeptides are absent. The substructure of the aggregates has been studied by electron microscopy. Repetitive subcomplexes of hexameric stacks of biliproteins form extraordinary long rods associated side by side in a highly condensed arrangement. Evidence that the linker polypeptides LR35PC and LR33PE stabilize the biliprotein hexamers is presented, while the location and function of the colored linker L55 remain uncertain. The derivative strain BO 9201 contains established hemidiscoidal phycobilisomes comprising phycoerythrin, phycocyanin, and allophycocyanin as well as the corresponding linker polypeptides. The core-membrane linker protein (LCM), and two polypeptides with M(r)s of 40,000 and 45,000 which are present in small amounts, exhibit strong cross-reactivity in Western blot (immunoblot) analysis using an antibody directed against the colored LCM of a Nostoc sp. In contrast, strain BO 8402 exhibits no polypeptide with a significant immunological cross-reactivity in Western blot analysis. Physiological and genetic implications of the unusual pigment compositions of both strains are discussed.     

Structural studies of MFE-1: the 1.9 A crystal structure of the dehydrogenase part of rat peroxisomal MFE-1

The 1.9 A structure of the C-terminal dehydrogenase part of the rat peroxisomal monomeric multifunctional enzyme type 1 (MFE-1) has been determined. In this construct (residues 260-722 and referred to as MFE1-DH) the N-terminal hydratase part of MFE-1 has been deleted. The structure of MFE1-DH shows that it consists of an N-terminal helix, followed by a Rossmann-fold domain (domain C), followed by two tightly associated helical domains (domains D and E), which have similar topology. The structure of MFE1-DH is compared with the two known homologous structures: human mitochondrial 3-hydroxyacyl-CoA dehydrogenase (HAD; sequence identity is 33%) (which is dimeric and monofunctional) and with the dimeric multifunctional alpha-chain (alphaFOM; sequence identity is 28%) of the bacterial fatty acid beta-oxidation alpha2beta2-multienzyme complex. Like MFE-1, alphaFOM has an N-terminal hydratase part and a C-terminal dehydrogenase part, and the structure comparisons show that the N-terminal helix of MFE1-DH corresponds to the alphaFOM linker helix, located between its hydratase and dehydrogenase part. It is also shown that this helix corresponds to the C-terminal helix-10 of the hydratase/isomerase superfamily, suggesting that functionally it belongs to the N-terminal hydratase part of MFE-1.     

The tertiary structure of endo-beta-1,4-glucanase B (CenB), a multidomain cellulase from the bacterium Cellulomonas fimi.

Endo-beta-1,4-glucanase B (CenB) is a large (110 kDa) extracellular enzyme from the cellulolytic bacterium Cellulomonas fimi. CenB contains five domains, including a typical C.fimi cellulose-binding domain, separated by distinctive linker polypeptides (Meinke et al., 1991b). X-ray scattering analyses show that CenB has a highly elongated shape resembling beads on a string. The sizes of the polypeptides produced by treatment of CenB with proteases, together with their N-terminal amino acid sequences, show that at least two of the four linkers connecting the five domains of CenB are more sensitive to proteolysis than the domains themselves. It is concluded that the beads represent the domains of CenB, the string represents the linkers.     

New biologically active hybrid bacteriocins constructed by combining regions from various pediocin-like bacteriocins: the C-terminal region is important for determining specificity.

The pediocin-like bacteriocins, produced by lactic acid bacteria, are bactericidal polypeptides with very similar primary structures. Peptide synthesis followed by reverse-phase and ion-exchange chromatographies yielded biologically active pediocin-like bacteriocins in amounts and with a purity sufficient for characterizing their structure and mode of action. Despite similar primary structures, the pediocin-like bacteriocins, i.e., pediocin PA-1, sakacin P, curvacin A, and leucocin A, differed in their relative toxicities against various bacterial strains. On the basis of the primary structures, the polypeptides of these bacteriocins were divided into two modules: the relatively hydrophilic and well conserved N-terminal region, and the somewhat more diverse and hydrophobic C-terminal region. By peptide synthesis, four new biologically active hybrid bacteriocins were constructed by interchanging corresponding modules from various pediocin-like bacteriocins. All of the new hybrid bacteriocin constructs had bactericidal activity. The relative sensitivity of different bacterial strains to a hybrid bacteriocin was similar to that to the bacteriocin from which the C-terminal module was derived and quite different from that to the bacteriocin from which the N-terminal was derived. Thus, the C-terminal part of the pediocin-like bacteriocins is an important determinant of the target cell specificity. The synthetic bacteriocins were more stable than natural isolates, presumably as a result of the absence of contaminating proteases. However, some of the synthetic bacteriocins lost activity, but this was detectable only after months of storage. Mass spectrometry suggested that this instability was due to oxidation of methionine residues, resulting in a 10- to 100-fold reduction in activity.