Molecular portrait of lens gap junction protein MP70

A 70-kDa membrane protein (MP70) is a component of the lens fiber gap junctions. Its membrane topology and its N-terminal sequence are similar to those of the connexin family of proteins. Some features of MP70 containing fiber gap junctions are, however, distinct from gap junctions in other mammalian tissues: (i) Lens connexons form crystalline arrays only after cleavage of junctional proteins in vitro. These hexagonal arrays have a periodicity of 13.6 nm which is significantly larger than the 8- 9-nm spacing of liver and heart gap junctions. (ii) Lens fiber gap junctions dissociate in low concentrations of nonionic detergent and this provides an avenue to purify MP70 directly from a membrane mixture. Isolated MP70 in the form of 17 S structures has an appearance consistent with connexon pairs. (iii) The C-terminal half of MP70 is cleaved in situ by a lens endogenous calcium-dependent protease. The processed from MP38 remains in the membrane and is abundant in the central region of the lens. A testable hypothesis for MP70 function is presented.     

Decay accelerating factor of complement is anchored to cells by a C-terminal glycolipid

Membrane-associated decay accelerating factor (DAF) of human erythrocytes (Ehu) was analyzed for a C-terminal glycolipid anchoring structure. Automated amino acid analysis of DAF following reductive radiomethylation revealed ethanolamine and glucosamine residues in proportions identical with those present in the Ehu acetylcholinesterase (AChE) anchor. Cleavage of radiomethylated 70-kilodalton (kDa) DAF with papain released the labeled ethanolamine and glucosamine and generated 61- and 55-kDa DAF products that retained all labeled Lys and labeled N-terminal Asp. Incubation of intact Ehu with phosphatidylinositol-specific phospholipase C (PI-PLC), which cleaves the anchors in trypanosome membrane form variant surface glycoproteins (mfVSGs) and murine thymocyte Thy-1 antigen, released 15% of the cell-associated DAF antigen. The released 67-kDa PI-PLC DAF derivative retained its ability to decay the classical C3 convertase C4b2a but was unable to membrane-incorporate and displayed physicochemical properties similar to urine DAF, a hydrophilic DAF form that can be isolated from urine. Nitrous acid deamination cleavage of Ehu DAF at glucosamine following labeling with the lipophilic photoreagent 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine ([125I]TID) released the [125I]TID label in a parallel fashion as from [125I]TID-labeled AChE. Biosynthetic labeling of HeLa cells with [3H]ethanolamine resulted in rapid 3H incorporation into both 48-kDa pro-DAF and 72-kDa mature epithelial cell DAF. Our findings indicate that DAF and AChE are anchored in Ehu by the same or a similar glycolipid structure and that, like VSGs, this structure is incorporated into DAF early in DAF biosynthesis prior to processing of pro-DAF in the Golgi.     

Sequence analysis of peptide fragments from the intrinsic membrane protein of calf lens fibers MP26 and its natural maturation product MP22

Calf lens fiber plasma membranes, containing only the intrinsic membrane protein MP26 and its maturation product MP22 were treated with proteolytic enzymes such as trypsin, protease V8 from S. aureus or with chemical agents as CNBr in formic acid. The cleavage products, purified by electrophoresis, were analysed for their amino acid composition and N-terminal sequences. Proteolysis gave rise to peptides which were mainly shortened at the C-terminal end of the molecules. While the V8 protease produced a fragment with a similar N-terminal sequence as the maturation product MP22, trypsin yielded another cleavage product. Chemical hydrolysis yielded large fragments (11-15 kDa) with hydrophobic N-terminal sequences. Our results suggest that MP26 is characterised by an N-terminal signal sequence and possesses other hydrophobic domains which could function as untranslocated insertion sequences.     

In vitro synthesis and membrane insertion of bovine MP26, an integral protein from lens fiber plasma membrane

Synthesis of MP26, the principal protein of lens fiber plasma membranes, was directed in the reticulocyte lysate system by poly A mRNA enriched from whole bovine lens RNA using oligo (dt)-cellulose chromatography. Synthesized MP26 was enriched by immune precipitation. The in vitro-synthesized MP26 had an electrophoretic mobility indistinguishable from that of the native molecule. MP26 showed a cotranslational requirement for dog pancreas microsomes in order for membrane association to occur. Microsome-associated in vitro- synthesized MP26 showed a sensitivity to digestion with chymotrypsin which was similar to the sensitivity of native MP26 in isolated lens fiber plasma membranes, indicating correct insertion of the MP26 into the microsome. Synthesis and membrane insertion of MP26 using N-formyl- [35S]methionyl tRNA as label demonstrated that no proteolytic processing or significant glycosylation accompanied membrane insertion. Chymotryptic cleavage of membrane-inserted, N-formyl-[35S]methionine- labeled MP26 resulted in loss of label, suggesting that the N-terminal of the in vitro-synthesized MP26 faces the cytoplasm.     

Structural organization of the lens fiber cell plasma membrane protein MP18

The 18,000-dalton bovine lens fiber cell intrinsic membrane protein MP18 was phosphorylated on a serine residue by both cAMP-dependent protein kinase and protein kinase C. In addition, this protein bound calmodulin and was recognized by a monoclonal antibody (2D10). These different regions were localized using enzymatic and chemical fragmentation of electrophoretically purified MP18 that had been phosphorylated with either cAMP-dependent protein kinase or protein kinase C. Partial digestion of 32P-labeled MP18 with protease V8 resulted in a Mr = 17,000 peptide that bound calmodulin, but neither contained 32P or was recognized by the monoclonal antibody 2D10. Furthermore, the 17-kDa peptide had the same N-terminal amino acid sequence as MP18. Thus, the monoclonal antibody 2D10 recognition site and the protein kinase phosphorylation site(s) are close together and confined to a small region in the C terminus of MP18. This conclusion was confirmed in experiments where MP18 was fragmented with trypsin, endoproteinase Lys-C, or CNBr. The location of the phosphorylation site was confirmed by sequencing the small 32P-labeled, C-terminal peptide that resulted from protease V8 digestion of 32P-labeled MP18. This peptide contained a consensus sequence for cAMP-dependent protein kinase.     

Interaction of alpha-crystallin with lens plasma membranes. Affinity for MP26

The binding of the major water-soluble lens protein alpha-crystallin to the lens plasma membrane has been investigated by reassociating purified alpha-crystallin with alpha-crystallin-depleted membranes and with phospholipid vesicles in which the lens membrane protein MP26 had been reconstituted. alpha-Crystallin reassociates at high affinity (Kd = 13 X 10(-8)M) with alkali-washed lens plasma membranes but not with lens plasma membranes treated with guanidine/HCl, nor with phospholipid vesicles or erythrocyte membranes. Binding to lens plasma membranes is dependent on salt, temperature and pH and occurs in a saturable manner. Reconstitution of MP26 into phospholipid vesicles and subsequent analysis of alpha-crystallin binding suggests the involvement of this transmembrane protein. Binding ist not influenced by pretreatment of membranes with proteases, suggesting that the 4-kDa cytoplasmic fragment of MP26 is not necessary for alpha-crystallin binding. Labeling experiments using (trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine as a probe for intrinsic membrane proteins further showed that alpha-crystallin contains hydrophobic regions on its surface which might enable this protein to make contact with the lipid bilayer. Newly synthesized alpha-crystallin, in lens culture, is not associated with the plasma membrane, suggesting that the assembly of alpha-crystallin aggregates does not take place in a membrane-bound mode.     

Drosophila acetylcholinesterase: demonstration of a glycoinositol phospholipid anchor and an endogenous proteolytic cleavage

The presence of a glycoinositol phospholipid anchor in Drosophila acetylcholinesterase (AChE) was shown by several criteria. Chemical analysis of highly purified Drosophila AChE demonstrated approximately one residue of inositol per enzyme subunit. Selective cleavage by Staphylococcus aureus phosphatidylinositol-specific phospholipase C (PI-PLC) was tested with Drosophila AChE radiolabeled by the photoactivatable affinity probe 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine [( 125I]TID), a reagent that specifically labels the lipid moiety of glycoinositol phospholipid-anchored proteins. Digestion with PI-PLC released 75% of this radiolabel from the protein. Gel electrophoresis of Drosophila AChE in sodium dodecyl sulfate indicated prominent 55- and 16-kDa bands and a faint 70-kDa band. The [125I]TID label was localized on the 55-kDa fragment, suggesting that this fragment is the C-terminal portion of the protein. In support of this conclusion, a sensitive microsequencing procedure that involved manual Edman degradation combined with radiomethylation was used to determine residues 2-5 of the 16-kDa fragment. Comparison with the Drosophila AChE cDNA sequence [Hall, L.M.C., & Spierer, P. (1986) EMBO J. 5, 2949-2954] confirmed that the 16-kDa fragment includes the N-terminus of AChE. Furthermore, the position of the N-terminal amino acid of the mature Drosophila AChE is closely homologous to that of Torpedo AChE. The presence of radiomethylatable ethanolamine in both 16- and 55-kDa fragments was also confirmed. Thus, Drosophila AChE may include a second posttranslational modification involving ethanolamine.     

Cloning of cDNA encoding the membrane-bound form of bovine beta 1,4-galactosyltransferase

UDPgalactose: N-acetyl-D-glucosamine 4-beta-D-galactosyltransferase (EC 2.4.1.38) (GalT) is a Golgi-membrane-bound enzyme that participates in the biosynthesis of the oligosaccharide structures of glycoproteins and glycolipids. Synthetic DNA oligomers representing segments of the published partial cDNA sequence for bovine GalT were used as molecular probes to isolate from bovine-liver cDNA libraries overlapping cDNA clones that span 1728 nucleotides and potentially code for the entire polypeptide chain of bovine galactosyltransferase. The cDNA sequence for bovine GalT reveals a 1206-base-pair open reading frame that codes for 402 amino acids, including a presumptive N-terminal membrane anchoring domain of 20 hydrophobic amino acids. The colinearity between the cDNA sequence and 29 non-overlapping amino acid residues which were positively identified by N-terminal sequencing of two polypeptides isolated from the soluble form of the enzyme was consistent with the translation frame and confirmed the authenticity of the cDNA clones. The finding of an N-terminal hydrophobic segment which serves as the membrane anchor and signal sequence suggests that the C-terminal region of the GalT polypeptide is oriented within the lumen of the Golgi membranes. This conclusion is in agreement with previous biochemical studies which indicated that the 51-kDa and 42-kDa soluble forms of the enzyme which encompass the C-terminal 324 and 297 amino acid residues of the entire GalT polypeptide, respectively, include the catalytic site.     

End-label fingerprintings show that the N- and C-termini of actin are in the contact site with gelsolin

Gelsolin was cleaved by chymotrypsin or thermolysin into an N-terminal Mr 45,000 fragment (45N) and a C-terminal Mr 38,000 fragment (38C). The N-terminal half was further cleaved into two fragments with Mr 17,000 (17N) and Mr 28,000 (28N). These fragments were complexed with actin and cross-linked with 1-ethyl-3-[3-(dimethylamino)prophyl]carbodiimide (EDC) to introduce covalent bonds into their contact sites. The location of these bonds was mapped along the actin sequence by end-label fingerprinting with highly sensitive probes for the N- and C-termini of actin. The mapping studies revealed that two gelsolin N-terminal fragments (17N and 28N) were cross-linked with the actin C-terminal segment. The result indicates that the actin N- and C-terminal segments are in the binding site of gelsolin.     

Affinity labelling with MgATP analogues reveals coexisting Na+ and K+ forms of the alpha-subunits of Na+/K+-ATPase.

To test the hypothesis that Na+/K+-ATPase works as an (alpha beta)2-diprotomer with interacting catalytic alpha-subunits, tryptic digestion of pig kidney enzyme, that had been inactivated with substitution-inert MgATP complex analogues, was performed. This led to the demonstration of coexisting C-terminal Na+-like 80-kDa as well as K+-like 60-kDa peptides and N-terminal 40-kDa peptides of the alpha-subunit. To localize the ATP binding sites on tryptic peptides, studies with radioactive MgATP complex analogues were performed: Co(NH3)4-8-N3-ATP specifically modified the E2ATP (low affinity) binding site of Na+/K+-ATPase with an inactivation rate constant (k2) of 12 x 10-3.min-1 at 37 degrees C and a dissociation constant (Kd) of 207 +/- 28 microm. Tryptic digestion of the [gamma32P]Co(NH3)4-8-N3-ATP-inactivated and photolabelled alpha-subunit (Mr = 100 kDa) led, in the absence of univalent cations, to a K+-like C-terminal 60-kDa fragment which was labelled in addition to an unlabelled Na+-like C-terminal 80-kDa fragment. Tryptic digestion of [alpha32P]-or [gamma32P]Cr(H2O)4ATP - bound to the E1ATP (high affinity) site - led to the labelling of a Na+-like 80-kDa fragment besides the immediate formation of an unlabelled K+-like N-terminal 40-kDa fragment and a C-terminal 60-kDa fragment. Because a labelled Na+-like 80-kDa fragment cannot result from an unlabelled K+-like 60-kDa fragment, and because unlabelled alpha-subunits did not show any catalytic activity, the findings are consistent with a situation in which Na+- and K+-like conformations are stabilized by tight binding of substitution-inert MgATP complex analogues to the E1ATP and E2ATP sites. Hence, all data are consistent with the hypothesis that ATP binding induces coexisting Na+ and K+ conformations within an (alphabeta)2-diprotomeric Na+/K+-ATPase.     

Glycation of MP26 and MP22 in bovine lens membranes.

Alkali treated membranes were isolated from mature bovine lenses and incubated with different sugars for 3 weeks to study the effect of glycation on the lens intrinsic membrane proteins, MP26 and MP22. The obtained results show that a) [1-14C] ascorbic acid (ASA) was able to glycate the intrinsic membrane proteins as rapidly as soluble lens proteins; b) on 15% acrylamide gels in SDS, glucose, fructose, galactose and ribose exhibited low activity for crosslinking membrane proteins; whereas ASA, dehydroascorbate (DHA), diketogulonate (DKG), xylosone and threose, all showed not only the formation of protein multimers, but also highly crosslinked products, which did not enter the spacer gel; c) except glycated MP22, all of the crosslinks of MP26 or MP22, and also the glycated MP26, showed cross reactivity with polyclonal MP26 antibody; d) the extent of crosslinking correlated with an equal loss of lysine and arginine contents by amino acid analysis.     

KdpD and KdpE, proteins that control expression of the kdpABC operon, are members of the two-component sensor-effector class of regulators.

The Kdp system of Escherichia coli, a transport ATPase with high affinity for potassium, is expressed when turgor pressure is low. Expression requires KdpD, a 99-kDa membrane protein, and KdpE, a 25-kDa soluble cytoplasmic protein. The sequences of KdpD and KdpE show they are members of the sensor-effector class of regulatory proteins: the C-terminal half of KdpD is homologous to sensors such as EnvZ and PhoR, and KdpE is homologous to effectors such as OmpR and PhoB. The predicted structure of KdpD suggests that it is anchored to the membrane by four membrane-spanning segments near its middle, with both C- and N-terminal portions in the cytoplasm. Subcellular fractionation confirms the expected location of the protein in the inner membrane. The N-terminal region has no homology to known proteins and is the site of mutations that make Kdp expression partially constitutive; this portion may serve to sense turgor pressure. Since several other sensor-effectors have been shown to mediate control through phosphorylation, this mechanism is proposed to control expression of Kdp.     

Targeting of the 22 kDa integral peroxisomal membrane protein

Investigating targeting of the 22 kDa peroxisomal membrane protein (Pmp22p) to the peroxisomal membrane we have confined the targeting signal to amino acid residues 16-37 located in the N-terminal cytoplasmic tail. Comparison of Pmp22p orthologous sequences revealed a conserved motif Y3xL3xP3x(KQN) which might represent the core of this targeting signal not found so far in other Pmps. Fusion of the Pmp22p N-terminal tail to the C-terminal portion of Pmp22p which per se is not targeted to peroxisomes, conveys peroxisomal targeting. These data suggest that Pmp22p is targeted to peroxisomes by a new membrane targeting signal which is necessary and sufficient to target a polypeptide containing two transmembrane spans to peroxisomes.     

The hemagglutinating action of Vibrio vulnificus metalloprotease

Vibrio vulnificus protease (VVP), a 45-kDa zinc metalloprotease, consists of two functional domains: an N-terminal 35-kDa polypeptide having endoproteinase activity, and a C-terminal 10-kDa polypeptide that mediates the binding of VVP to the erythrocyte membrane. Therefore, VVP, but not its N-terminal endoproteinase domain alone, has agglutinating activity to rabbit erythrocytes. When a single zinc atom in the catalytic center was substituted by treatment with CuCl2 or NiCl2, proteolytic and hemagglutinating activities were reduced by Ni substitution but not by Cu substitution. Cu-treated 35-kDa polypeptide showed sufficient affinity of the catalytic center and weak binding ability to the erythrocyte membrane, but the Ni-treated polypeptide did not. These results suggest that the binding of endoproteinase domain to membrane is also necessary for hemagglutination.     

Identification of an autoinhibitory domain in the C-terminal region of the plant plasma membrane H(+)-ATPase.

Proteolytic (trypsin) treatment removes a small terminal segment from the 100-kDa plant plasma membrane H(+)-ATPase. This results in activation of H+ pumping across the plasma membrane, suggesting that an inhibitory domain is located in one of the terminal regions of the enzyme (Palmgren, M.G., Larsson, C., and Sommarin, M. (1990) J. Biol. Chem. 265, 13423-13426). In order to identify the origin of the fragment released by trypsin, polyclonal antibodies were raised against the first 55 amino acids (N-terminal region), the last 99 amino acids (C-terminal region), and a portion of 150 amino acids in the central part of the enzyme as deduced from one of the H(+)-ATPase genes (PMA2) of Arabidopsis thaliana. The native, 100-kDa H(+)-ATPase was recognized by all three antisera in Western blots. By contrast, the approximately 90-kDa polypeptide appearing after trypsin treatment was only recognized by the antisera against the N-terminal and central region, but not by the antiserum against the C-terminal region, suggesting that the inhibitory domain is located in this part of the enzyme. To more closely determine the position of the inhibitory domain, three peptides representing conserved parts of the C-terminal region were synthesized (residues 861-888, 912-943, and 936-949 of the Arabidopsis (PMA2) sequence). Only one of the peptides (residues 861-888) affected H+ pumping by the trypsin-activated (approximately 90-kDa) enzyme. This peptide of 28 amino acids inhibited H+ pumping with an IC50 of about 15 microM, suggesting that the auto-inhibitory domain is located within the corresponding part of the C-terminal region.     

Interaction of CPa-1 with the manganese-stabilizing protein of photosystem II: identification of domains cross-linked by 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide.

The structural organization of photosystem II proteins has been investigated by use of the zero-length protein cross-linking reagent 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide and monoclonal and polyclonal antibody reagents. Photosystem II membranes were treated with 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide which cross-links amino groups to carboxyl groups which are in van der Waals contact. This treatment did not affect the oxygen evolution rates of these membranes and increased the retention of oxygen evolution after CaCl2 washing. Analysis of the proteins cross-linked by this treatment indicated that two cross-linked species with apparent molecular masses of 95 and 110 kDa were formed which cross-reacted with antibodies against both the 33-kDa manganese-stabilizing protein and the chlorophyll protein CPa-1. Cleavage of the 110-kDa cross-linked species with cyanogen bromide followed by N-terminal sequence analysis was used to identify the peptide fragments of CPa-1 and the manganese-stabilizing protein which were cross-linked. Two cyanogen bromide fragments were identified with apparent molecular masses of 50 and 25 kDa. N-Terminal sequence analysis of the 50-kDa cyanogen bromide fragment indicates that this consists of the C-terminal 16.7-kDa fragment of CPa-1 and the intact manganese-stabilizing protein. This strongly suggests that the manganese-stabilizing protein is cross-linked to the large extrinsic loop domain of CPa-1. N-Terminal analysis of the 25-kDa cyanogen bromide fragment indicates that this consists of the C-terminal 16.7-kDa peptide of CPa-1 and the N-terminal 8-kDa peptide of the manganese-stabilizing protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of a G protein in rough endoplasmic reticulum of canine pancreas

Employing [32P]ADP-ribosylation by pertussis toxin we have identified a G protein that is located in the rough endoplasmic reticulum of canine pancreas and therefore termed it GRER. Identification of GRER is based on the following data. A 41-kDa polypeptide was the only polypeptide that was [32P]ADP-ribosylated by pertussis toxin in pancreas rough microsomes. Guanosine 5'-(gamma-thio)triphosphate (GTP gamma S) and 1 mM ATP, 6 mM MgCl2, 10 mM NaF (AMF) inhibited ADP-ribosylation of this polypeptide. The [32P]ADP-ribosylated 41-kDa polypeptide was immunoprecipitated by antisera which specifically recognized the C-terminal residues of the alpha subunits of Gi and transducin, indicating that the 41-kDa polypeptide is immunologically related to the alpha subunits of heterotrimeric G proteins. Treatment with GTP gamma S resulted in a reduction in the sedimentation rate of the [32P]ADP-ribosylated, detergent-solubilized GRER. It also induced the release of the [32P]ADP-ribosylated 41-kDa polypeptide from rough microsomes in the absence of detergent, unlike ADP-ribosylated alpha subunits of plasma membrane-associated G proteins. These data are consistent with an oligomeric nature of GRER. The codistribution of GRER with an endoplasmic reticulum marker protein during subcellular fractionation and the lack of plasma membrane contamination of the rough microsomal fraction, combined with the isodensity of GRER with rough microsomes as well as the isodensity of GRER with "stripped" microsomes after extraction of rough microsomes with EDTA and 0.5 M KCl, localized GRER to the rough endoplasmic reticulum. Preliminary experiments suggest that GRER appears not to be involved in translocation of proteins across the rough endoplasmic reticulum membrane.     

Insertion of the mannitol permease into the membrane of Escherichia coli. Possible involvement of an N-terminal amphiphilic sequence

The in vivo membrane assembly of the mannitol permease, the mannitol Enzyme II (IImtl) of the Escherichia coli phosphotransferase system, has been studied employing molecular genetic approaches. Removal of the N-terminal amphiphilic leader of the permease and replacement with a short hydrophobic sequence resulted in an inactive protein unable to transport mannitol into the cell or catalyze either phosphoenol-pyruvate-dependent or mannitol 1-phosphate-dependent mannitol phosphorylation in vitro. The altered protein (68 kDa) was quantitatively cleaved by an endogenous protease to a membrane-associated 39-kDa fragment and a soluble 28-kDa fragment as revealed by Western blot analyses. Overproduction of the wild-type plasmid-encoded protein also led to cleavage, but repression of the synthesis of the plasmid-encoded enzyme by inclusion of glucose in the growth medium prevented cleavage. Several mtlA-phoA gene fusions encoding fused proteins with N-terminal regions derived from the mannitol permease and C-terminal regions derived from the mature portion of alkaline phosphatase were constructed. In the first fusion protein, F13, the N-terminal 13-aminoacyl residue amphiphilic leader sequence of the mannitol permease replaced the hydrophobic leader sequence of alkaline phosphatase. The resultant fusion protein was inefficiently translocated across the cytoplasmic membrane and became peripherally associated with both the inner and outer membranes, presumably via the noncleavable N-terminal amphiphilic sequence. The second fusion protein, F53, in which the N-terminal 53 residues of the mannitol permease were fused to alkaline phosphatase, was efficiently translocated across the cytoplasmic membrane and was largely found anchored to the inner membrane with the catalytic domain of alkaline phosphatase facing the periplasm. This 53-aminoacyl residue sequence included the amphiphilic leader sequence and a single hydrophobic, potentially transmembrane, segment. Analyses of other MtlA-PhoA fusion proteins led to the suggestion that internal amphiphilic segments may function to facilitate initiation of polypeptide trans-membrane translocation. The dependence of IImtl insertion on the N-terminal amphiphilic leader sequence was substantiated employing site-specific mutagenesis. The N-terminal sequence of the native permease is Met-Ser-Ser-Asp-Ile-Lys-Ile-Lys-Val-Gln-Ser-Phe-Gly.... The following point mutants were isolated, sequenced, and examined regarding the effects of the mutations on insertion of IImtl into the membrane: 1) S3P; 2) D4P; 3) D4L; 4) D4R; 5) D4H; 6) I5N; 7) K6P; and 8) K8P.(ABSTRACT TRUNCATED AT 400 WORDS)     

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).     

A Major Outer Membrane Protein of Rahnella aquatilis Functions as a Porin and Root Adhesin

A 38-kDa major outer membrane protein (OMP) was isolated from the nitrogen-fixing enterobacterium Rahnella aquatilis CF3. This protein exists as a stable trimer in the presence of 2% sodium dodecyl sulfate at temperatures below 60°C. Single channel experiments showed that this major OMP of R. aquatilis CF3 is able to form pores in the planar lipid membrane. Two oligonucleotides encoding the N-terminal portion of the 38-kDa OMP and C-terminal portion of OmpC were used to amplify the 38-kDa gene by PCR. The deduced amino acid sequence showed a strong homology with Escherichia coli, Klebsiella pneumoniae, Salmonella typhi, and Serratia marcescens OmpC sequences, except loops L6 and L7, which are postulated to be cell surface exposed. On the basis of the OmpF-PhoE three-dimensional structure, it seems likely that this 38-kDa organizes three 16-strand β-barrel subunits. The relationship between the structure and the double functionality of this protein as porin and as a root adhesin is discussed.