Deletion of the prc (tsp) gene provides evidence for additional tail-specific proteolytic activity in Escherichia coli K-12

The Escherichia coli protease Prc (Tsp) exhibits specificity in vitro for proteins with nonpolar carboxyl termini. To determine whether Prc is responsible for the selective degradation in vivo of proteins with nonpolar carboxyl termini, we constructed a prc (tsp) deletion strain. Deletion of the prc gene did not prevent the rapid intracellular degradation of a variant of the amino-terminal domain of repressor with a nonpolar carboxyl terminus, even though this protein is a substrate for Prc in vitro. Our results indicate that at least one additional carboxy-terminal-specific proteolytic system must exist in E. coli.     

Salinity-Dependent Impacts of ProQ,Prc, and Spr Deficiencies on Escherichia coli Cell Structure

ProQ is a cytoplasmic protein with RNA chaperone activities that reside in FinO- and Hfq-like domains. Lesions at proQ decrease the level of the osmoregulatory glycine betaine transporter ProP. Lesions at proQ eliminated ProQ and Prc, the periplasmic protease encoded by the downstream gene prc. They dramatically slowed the growth of Escherichia coli populations and altered the morphologies of E. coli cells in high-salinity medium. ProQ and Prc deficiencies were associated with different phenotypes. ProQ-deficient bacteria were elongated unless glycine betaine was provided. High-salinity cultures of Prc-deficient bacteria included spherical cells with an enlarged periplasm and an eccentric nucleoid. The nucleoid-containing compartment was bounded by the cytoplasmic membrane and peptidoglycan. This phenotype was not evident in bacteria cultivated at low or moderate salinity, nor was it associated with murein lipoprotein (Lpp) deficiency, and it differed from those elicited by the MreB inhibitor A-22 or the FtsI inhibitor aztreonam at low or high salinity. It was suppressed by deletion of spr, which encodes one of three murein hydrolases that are redundantly essential for enlargement of the murein sacculus. Prc deficiency may alter bacterial morphology by impairing control of Spr activity at high salinity. ProQ and Prc deficiencies lowered the ProP activity of bacteria cultivated at moderate salinity by approximately 70% and 30%, respectively, but did not affect other osmoregulatory functions. The effects of ProQ and Prc deficiencies on ProP activity are indirect, reflecting their roles in the maintenance of cell structure.     

The Conserved ADAMTS-like Protein Lonely heart Mediates Matrix Formation and Cardiac Tissue Integrity

Here we report on the identification and functional characterization of the ADAMTS-like homolog lonely heart (loh) in Drosophila melanogaster. Loh displays all hallmarks of ADAMTSL proteins including several thrombospondin type 1 repeats (TSR1), and acts in concert with the collagen Pericardin (Prc). Loss of either loh or prc causes progressive cardiac damage peaking in the abolishment of heart function. We show that both proteins are integral components of the cardiac ECM mediating cellular adhesion between the cardiac tube and the pericardial cells. Loss of ECM integrity leads to an altered myo-fibrillar organization in cardiac cells massively influencing heart beat pattern. We show evidence that Loh acts as a secreted receptor for Prc and works as a crucial determinant to allow the formation of a cell and tissue specific ECM, while it does not influence the accumulation of other matrix proteins like Nidogen or Perlecan. Our findings demonstrate that the function of ADAMTS-like proteins is conserved throughout evolution and reveal a previously unknown interaction of these proteins with collagens.     

A Disease-causing Mutation Illuminates the Protein Membrane Topology of the Kidney-expressed Prohibitin Homology (PHB) Domain Protein Podocin

Mutations in the NPHS2 gene are a major cause of steroid-resistant nephrotic syndrome, a severe human kidney disorder. The NPHS2 gene product podocin is a key component of the slit diaphragm cell junction at the kidney filtration barrier and part of a multiprotein-lipid supercomplex. A similar complex with the podocin ortholog MEC-2 is required for touch sensation in Caenorhabditis elegans. Although podocin and MEC-2 are membrane-associated proteins with a predicted hairpin-like structure and amino and carboxyl termini facing the cytoplasm, this membrane topology has not been convincingly confirmed. One particular mutation that causes kidney disease in humans (podocin^P118L) has also been identified in C. elegans in genetic screens for touch insensitivity (MEC-2^P134S). Here we show that both mutant proteins, in contrast to the wild-type variants, are N-glycosylated because of the fact that the mutant C termini project extracellularly. Podocin^P118L and MEC-2^P134S did not fractionate in detergent-resistant membrane domains. Moreover, mutant podocin failed to activate the ion channel TRPC6, which is part of the multiprotein-lipid supercomplex, indicative of the fact that cholesterol recruitment to the ion channels, an intrinsic function of both proteins, requires C termini facing the cytoplasmic leaflet of the plasma membrane. Taken together, this study demonstrates that the carboxyl terminus of podocin/MEC-2 has to be placed at the inner leaflet of the plasma membrane to mediate cholesterol binding and contribute to ion channel activity, a prerequisite for mechanosensation and the integrity of the kidney filtration barrier.     

Multiple Sequence Signals Direct Recognition and Degradation of Protein Substrates by the AAA+ Protease HslUV

Proteolysis is important for protein quality control and for the proper regulation of many intracellular processes in prokaryotes and eukaryotes. Discerning substrates from other cellular proteins is a key aspect of proteolytic function. The Escherichia coli HslUV protease is a member of a major family of ATP-dependent AAA+ degradation machines. HslU hexamers recognize and unfold native protein substrates and then translocate the polypeptide into the degradation chamber of the HslV peptidase. Although a wealth of structural information is available for this system, relatively little is known about mechanisms of substrate recognition. Here, we demonstrate that mutations in the unstructured N-terminal and C-terminal sequences of two model substrates alter HslUV recognition and degradation kinetics, including changes in V_max. By introducing N- or C-terminal sequences that serve as recognition sites for specific peptide-binding proteins, we show that blocking either terminus of the substrate interferes with HslUV degradation, with synergistic effects when both termini are obstructed. These results support a model in which one terminus of the substrate is tethered to the protease and the other terminus is engaged by the translocation/unfolding machinery in the HslU pore. Thus, degradation appears to consist of discrete steps, which involve the interaction of different terminal sequence signals in the substrate with different receptor sites in the HslUV protease.     

Vectors for the expression of tagged proteins in Schizosaccharomyces pombe

A series of vectors is described which enables the episomal expression of proteins fused to different tag sequences in Schizosaccharomyces pombe. Proteins can be expressed with their amino termini fused to GFP/EGFP, three copies of the HA or Pk epitopes or a combined tag which contains two copies of the myc epitope and six histidine residues (MH). Fusion of the carboxyl terminus of a protein to a tag is possible with GFP/EGFP or Pk. Expression of the fusion proteins is controlled by the medium strength mutant version of the regulatable nmt1 promoter.     

A new Escherichia coli gene,fdrA, identified by suppression analysis of dominant negative FtsH mutations

An Escherichia coli membrane protein, FtsH, has been implicated in several cellular processes, including integration of membrane proteins, translocation of secreted proteins, and degradation of some unstable proteins. However, how it takes part in such diverse cellular events is largely unknown. We previously isolated dominant negative ftsH mutations and proposed that FtsH functions in association with some other cellular factor(s). To test this proposal we isolated multicopy suppressors of dominant negative ftsH mutations. One of the multicopy suppressor clones contained an N-terminally truncated version of a new gene that was designated fdrA. The FdrA fragment suppressed both of the phenotypes — increased abnormal translocation of a normally cytoplasmic domain of a model membrane protein and retardation of protein export — caused by dominant negative FtsH proteins. The intact fdrA gene (11.9 min on the chromosome) directed the synthesis of a 60 kDa protein in vitro.     

Cloning, Characterization, and Functional Expression of the Klebsiella oxytoca Xylodextrin Utilization Operon (xynTB) in Escherichia coli

Escherichia coli is being developed as a biocatalyst for bulk chemical production from inexpensive carbohydrates derived from lignocellulose. Potential substrates include the soluble xylodextrins (xyloside, xylooligosaccharide) and xylobiose that are produced by treatments designed to expose cellulose for subsequent enzymatic hydrolysis. Adjacent genes encoding xylobiose uptake and hydrolysis were cloned from Klebsiella oxytoca M5A1 and are functionally expressed in ethanologenic E. coli. The xylosidase encoded by xynB contains the COG3507 domain characteristic of glycosyl hydrolase family 43. The xynT gene encodes a membrane protein containing the MelB domain (COG2211) found in Na⁺/melibiose symporters and related proteins. These two genes form a bicistronic operon that appears to be regulated by xylose (XylR) and by catabolite repression in both K. oxytoca and recombinant E. coli. Homologs of this operon were found in Klebsiella pneumoniae, Lactobacillus lactis, E. coli, Clostridium acetobutylicum, and Bacillus subtilis based on sequence comparisons. Based on similarities in protein sequence, the xynTB genes in K. oxytoca appear to have originated from a gram-positive ancestor related to L. lactis. Functional expression of xynB allowed ethanologenic E. coli to metabolize xylodextrins (xylosides) containing up to six xylose residues without the addition of enzyme supplements. 4-O-methylglucuronic acid substitutions at the nonreducing termini of soluble xylodextrins blocked further degradation by the XynB xylosidase. The rate of xylodextrin utilization by recombinant E. coli was increased when a full-length xynT gene was included with xynB, consistent with xynT functioning as a symport. Hydrolysis rates were inversely related to xylodextrin chain length, with xylobiose as the preferred substrate. Xylodextrins were utilized more rapidly by recombinant E. coli than K. oxytoca M5A1 (the source of xynT and xynB). XynB exhibited weak arabinosidase activity, 3% that of xylosidase.     

Co‐evolution of multipartite interactions between an extended tmRNA tag and a robust Lon protease in Mycoplasma

Messenger RNAs that lack in‐frame stop codons promote ribosome stalling and accumulation of aberrant and potentially harmful polypeptides. The SmpB‐tmRNA quality control system has evolved to solve problems associated with non‐stop mRNAs, by rescuing stalled ribosomes and directing the addition of a peptide tag to the C‐termini of the associated proteins, marking them for proteolysis. In Escherichia coli, the ClpXP system is the major contributor to disposal of tmRNA‐tagged proteins. We have shown that the AAA+ Lon protease can also degrade tmRNA‐tagged proteins, but with much lower efficiency. Here, we present a unique case of enhanced recognition and degradation of an extended Mycoplasma pneumoniae (MP) tmRNA tag by the MP‐Lon protease. We demonstrate that MP‐Lon can efficiently and selectively degrade MP‐tmRNA‐tagged proteins. Most significantly, our studies reveal that the larger (27 amino acids long) MP‐tmRNA tag contains multiple discrete signalling motifs for efficient recognition and rapid degradation by Lon. We propose that higher‐affinity multipartite interactions between MP‐Lon and the extended MP‐tmRNA tag have co‐evolved from pre‐existing weaker interactions, as exhibited by Lon in E. coli, to better fulfil the function of MP‐Lon as the sole soluble cytoplasmic protease responsible for the degradation of tmRNA‐tagged proteins.     

Phage Shock Protein C (PspC) of Yersinia enterocolitica Is a Polytopic Membrane Protein with Implications for Regulation of the Psp Stress Response

Phage shock proteins B (PspB) and C (PspC) are integral cytoplasmic membrane proteins involved in inducing the Yersinia enterocolitica Psp stress response. A fundamental aspect of these proteins that has not been studied in depth is their membrane topologies. Various in silico analyses universally predict that PspB is a bitopic membrane protein with the C terminus inside. However, similar analyses yield conflicting predictions for PspC: a bitopic membrane protein with the C terminus inside, a bitopic membrane protein with the C terminus outside, or a polytopic protein with both termini inside. Previous studies of Escherichia coli PspB-LacZ and PspC-PhoA fusion proteins supported bitopic topologies, with the PspB C terminus inside and the PspC C terminus outside. Here we have used a series of independent approaches to determine the membrane topologies of PspB and PspC in Y. enterocolitica. Our data support the predicted arrangement of PspB, with its C terminus in the cytoplasm. In contrast, data from multiple independent approaches revealed that both termini of PspC are located in the cytoplasm. Additional experiments suggested that the C terminus of PspC might be the recognition site for the FtsH protease and an interaction interface with PspA, both of which would be compatible with its newly proposed cytoplasmic location. This unexpected arrangement of PspC allows a new model for events underlying activation of the Psp response, which is an excellent fit with observations from various previous studies.     

The gas vacuole membrane of Microcystis aeruginosa. A partial amino acid sequence.

The primary structure and hydrophobicity of the gas vacuole membrane were investigated in order to determine if this simple membrane, containing only one protein and no lipid, typifies integral membrane proteins. Peptides obtained by trypsin digestion and N-bromosuccinimide treatment of the gas vacuole protein were sequenced. Two aspects of the sequence analysis are of interest: a long stretch of 15 aliphatic residues (in peptide NPT), and a thrice repeating octapeptide. The location of the aliphatic portion of peptide NPT between the amino and carboxyl termini of the gas vacuole protein sequence means that the protein is amphipathic i.e., the protein has stretches of primarily either nonpolar residues or polar residues in its sequence. Based on this and a comparison of the relative polarities of gas vacuole protein with other integral membrane proteins, the gas vacuole protein is an integral membrane protein. The presence of the repeating octapeptide in the sequence suggests that it may serve as a structural building block for the membrane. Based on the presence of the aliphatic sequence in peptide NPT, a functional model for the gas vacuole membrane was proposed. To allow gas to pass through the membrane without a conformational change in the protein, it is speculated that either the gas must pass through the intermolecular space in the protein or through hydrophobic pores.     

Proteolysis and synthetic strategy of human G-CSF in Escherichia coli BL21(DE3)

We report for the first time that the C-terminal region of hG-CSF suffers from proteolytic degradation when human granulocyte colony-stimulating factor (hG-CSF) is directly expressed in Escherichia coli BL21(DE3). It is believed that the rapid proteolysis occurs at the C-terminus of hG-CSF that is very easily exposed to E. coli protease(s) during a short period following protein synthesis and prior to completion of the formation of the inclusion body. The recombinant hG-CSF that is expressed with an N-terminal fusion partner is effectively protected from the proteolysis. It seems that since the N-terminus of hG-CSF is located very close to the C-terminus, the presence of the N-terminal fusion partner masks the C-terminal region of hG-CSF and protects it from proteolytic degradation by E. coli protease(s). Furthermore, the solubility of hG-CSF markedly increased in E. coli cytoplasm when a stress-responsive and aggregation-resistant protein, i.e. aspartate carbamoyl-transferase catalytic chain (PyrB) was used as a novel N-terminal fusion partner proteins.     

N-terminally truncated GADD34 proteins are convenient translation enhancers in a human cell-derived in vitro protein synthesis system

Human cell-derived in vitro protein synthesis systems are useful for the production of recombinant proteins. Productivity can be increased by supplementation with GADD34, a protein that is difficult to express in and purify from E. coli. Deletion of the N-terminal 120 or 240 amino acids of GADD34 improves recovery of this protein from E. coli without compromising its ability to boost protein synthesis in an in vitro protein synthesis system. The use of N-terminally truncated GADD34 proteins in place of full-length GADD34 should improve the utility of human cell-based cell-free protein synthesis systems.     

Biochemical Insights on Degradation of Arabidopsis DELLA Proteins Gained From a Cell-Free Assay System

The phytohormone gibberellic acid (GA) regulates diverse aspects of plant growth and development. GA responses are triggered by the degradation of DELLA proteins, which function as repressors in GA signaling pathways. Recent studies in Arabidopsis thaliana and rice (Oryza sativa) have implied that the degradation of DELLA proteins occurred via the ubiquitin-proteasome system. Here, we developed an Arabidopsis cell-free system to recapitulate DELLA protein degradation in vitro. Using this cell-free system, we documented that Lys-29 of ubiquitin is the major site for ubiquitin chain formation to mediate DELLA protein degradation. We also confirmed the specific roles of GA receptors and multisubunit E3 ligase components in regulating DELLA protein degradation. In addition, blocking DELLA degradation with a PP1/PP2A phosphatase inhibitor in our cell-free assay suggested that degradation of DELLA proteins required protein Ser/Thr dephosphorylation activity. Furthermore, our data revealed that the LZ domain of Arabidopsis DELLA proteins is essential for both their stability and activity. Thus, our in vitro degradation system provides biochemical insights into the regulation of DELLA protein degradation. This in vitro assay system could be widely adapted for dissecting cellular signaling pathways in which regulated proteolysis is a key recurrent theme.     

Selection for transport competence of C-terminal polypeptides derived from Escherichia coli hemolysin: the shortest peptide capable of autonomous HIyB/HIyD-dependent secretion comprises the C-terminal 62 amino acids of HlyA

Escherichia coli hemolysin (HlyA) is secreted by a specific export machinery which recognizes a topogenic secretion signal located at the C-terminal end of HlyA. This signal sequence has been variously defined as comprising from 27 to about 300 amino acids at the C-terminus of HlyA. We have used here a combined genetic and immunological approach to select for C-terminal HlyA peptides that are still secretion-component. A deletion library of HlyA mutant proteins was generated in vitro by successive degradation of hy1A from the 5′ end with exonuclease III. Secretion competence was tested by immunoblotting of the supernatant of each clone with an antiserum raised against a C-terminal portion of hemolysin. It was found that the hemolysin secretion system has no apparent size limitation for HlyA proteins over a range from 1024 to 62 amino acids. The smallest autonomously secretable peptide isolated in this selection procedure consists of the C-terminal 62 amino acids of HlyA. This sequence is shared by all secretion-competent, truncated HlyA proteins, which suggests that secretion of the E.coli hemolysin is strictly post-translational. The capacity of the hemolysin secretion machinery was found to be unsaturated by the steady-state level of its natural HlyA substrate and large amounts of truncated HlyA derivatives could still be secreted in addition to full-length HlyA.     

Soluble expression of Candida antarctica lipase B in Escherichia coli by fusion with Skp chaperone

Candida antarctica lipase B (CalB) is an industrially versatile enzyme, especially for biodiesel production and organic synthesis. Recombinant expression using the E. coli system has advantages, such as lower costs, easier handling, and higher number of clones that can be screened daily compared to expression using higher organism. But the expression of CalB in E. coli is not feasible because insoluble aggregates are formed and proteolytic degradation is known to occur during expression. In this study, fusion proteins were designed to express soluble CalB in E. coli. The periplasmic chaperone of E. coli, Skp was fused with CalB and this fusion protein showed a high solubility (yielding 82.5 ??g/mL). The fusion protein system can be applied to the rapid expression and evaluation of CalB variants for functional improvement.     

Characterization of subunit structural alterations which occur during purification of nitrate reductase from Escherichia coli

Nitrate reductase from Escherichia coli, purified to homogeneity after release from membranes by deoxycholate treatment, was composed of two subunits of 155,000 (α) and 58,000 (β) daltons and contained no cytochrome b₁. Analysis of fractions at different stages of purification by gel electrophoresis and immunoprecipitation revealed that during the early steps of the purification cytochrome b₁ dissociated from the enzyme and the β subunit was altered in size as determined by sodium dodecyl sulfate-gel electrophoresis. Analysis of the peptide patterns obtained by partial proteolysis of isolated α and β subunits established that these subunits are composed of distinct sequences and ruled out a precursor-product relationship between the two subunits. The β subunit was altered during the purification by loss of a 2000-dalton fragment, apparently from its carboxyl terminus. The protease inhibitor tosyllysine chloromethylketone protected nitrate reductase from more extensive degradation by endogenous proteases during the purification but did not prevent the removal of the 2000-dalton fragment. This carboxyl terminal fragment was part of a 15,000-dalton sequence which was removed by trypsin and which was required for the self-associating character of the unmodified enzyme monomers. From the structural changes which occurred during the purification procedure, it is proposed that the carboxyl terminal segment of the β subunit is involved in the binding of nitrate reductase to cytochrome b₁ and its association with the membrane.