Biosynthesis of Proteus mirabilis Nuclease

The culture liquid and periplasm of Proteus mirabilis contained nuclease, an enzyme with DNase and RNase activities. The nuclease was most actively synthesized in the early exponential and stationary growth phases. Nuclease synthesis was regulated by nucleic acids (induction by substrate) and inorganic phosphate (end-product inhibition). The synthesis and secretion of nuclease by P. mirabilis was induced by mitomycin C, an inducer of the SOS functions of cells. This suggests the involvement of SOS-response proteins in the regulation of nuclease synthesis.     

Biosynthesis of Proteus mirabilis nuclease

The culture liquid and periplasm of Proteus mirabilis contained nuclease, an enzyme with DNase and RNase activities. The nuclease was most actively synthesized in the early exponential and stationary growth phases. Nuclease synthesis was regulated by nucleic acids (induction by substrate) and inorganic phosphate (end-product inhibition). The synthesis and secretion of nuclease by P. mirabilis was induced by mitomycin C, an inducer of the SOS functions of cells. This suggests the involvement of SOS-response proteins in the regulation of nuclease synthesis.     

Antitumor Lipopolysaccharide from Heptoseless Mutant of Proteus mirabilis

Studies on lipopolysaccharide (LPS) from the cells of Proteus mirabilis RMS-203 were focused upon reduction of lethal toxicity and of pyrogenicity by biological and chemical modification. A heptoseless mutant, strain N-434, was isolated by the use of phage resistancy as a tool. LPS from that heptoseless mutant was completely deficient in neutral sugars and mainly composed of 2-keto-deoxy-octonic acid (KDO), glucosamine and fatty acids. It revealed almost the same antitumor activity as LPS of the wild type but it was less toxic and less pyrogenic.

Hydroxylaminolysis and reduction with LiAlH₄ resulted in removal of fatty acids from LPS accompanied with decrease in lethal toxicity and antitumor acitivity but not in pyrogenicity.

Lipid A fractions showed almost the same antitumor activity as intact LPS but less lethality and less pyrogenicity.     

Response of Blood Platelets to Proteus mirabilis Lipopolysaccharide

The effects of the lipopolysaccharide (LPS) of Proteus mirabilis on the production of thiobarbituric acid reactive substances (TBARS) and the generation of superoxide radicals (O₂^?) by pig blood platelets were studied in vitro. The effect of LPS on TBARS formation in platelets was dependent on the concentration of endotoxin. LPS at concentrations above 0.1 μg/10⁸ platelets caused the production of TBARS concomitant with the generation of superoxide radicals. The responses of platelets to LPS suggest that endotoxin, like thrombin (a strong platelets agonist), stimulates an enzymatic cascade of platelet arachidonate via cyclooxygenase and produces thromboxane A₂ (TXA₂) concomitant with malonyldialdehyde (MDA).     

Isolation and Characterization of Antitumor Lipopolysaccharide from Proteus mirabilis

Systematic isolation of the cell constituents of Proteus mirabilis RMS–203 was performed to find out localization of antitumor principle only in the lipopolysaccharide (LPS) layer of the cell wall fraction.

LPS with strong antitumor activity was extracted from P. mirabilis RMS–203 by phenol-water method followed by purification on DEAE-Sephadex A–50 column chromatography.

The main components of purified LPS were galactose, hexosamine, 2-keto-deoxy-octonic acid (KDO), myristic acid, β-hydroxymyristic acid and α,ε-diaminopimelic acid.

The minimal effective dose of LPS against Ehrlich solid carcinoma in mice was 0.1~1.0 μg/mouse. LD₅₀ in mice and pyrogenicity in rabbits were 28 mg/kg and 10^?3–10^?5 μg/rabbit, respectively.     

Core region in Proteus mirabilis lipopolysaccharide.

Four R mutants of P. mirabilis were isolated. The composition of their degraded polysaccharides (PS) obtained from the respective lipopolysaccharides (LPS) as well as the composition and properties of the PS-fractions separated by column chromatography were examined. The results were compared with those obtained with PS of the wild type. One of the mutants could be classified as an Ra-type mutant, presenting a complete LPS core. This polysaccharide core contains: galacturonic acid, glucosamine, glucose, D-glycero-D-mannoheptose, L-glycero-D-mannoheptose in a molar ratio of 1 : 1 : 1 : 1 : 2 and 2-keto-3-deoxyoctonate. Taking into consideration the common sugars described previously in the LPS chemotypes of P. hauseri, the composition of the complete core region mentioned above represents the LPS core part of all the chemotypes, containing two different heptoses.     

Comparative Screening of Digestion Tract Toxic Genes in Proteus mirabilis

Proteus mirabilis is a common urinary tract pathogen, and may induce various inflammation symptoms. Its notorious ability to resist multiple antibiotics and to form urinary tract stones makes its treatment a long and painful process, which is further challenged by the frequent horizontal gene transferring events in P. mirabilis genomes. Three strains of P. mirabilis {"type":"entrez-nucleotide","attrs":{"text":"C02011","term_id":"1434241"}}C02011/{"type":"entrez-nucleotide","attrs":{"text":"C04010","term_id":"1467261"}}C04010/C04013 were isolated from a local outbreak of a food poisoning event in Shenzhen, China. Our hypothesis is that new genes may have been acquired horizontally to exert the digestion tract infection and toxicity. The functional characterization of these three genomes shows that each of them independently acquired dozens of virulent genes horizontally from the other microbial genomes. The representative strain {"type":"entrez-nucleotide","attrs":{"text":"C02011","term_id":"1434241"}}C02011 induces the symptoms of both vomit and diarrhea, and has recently acquired a complete type IV secretion system and digestion tract toxic genes from the other bacteria.     

Structural and Functional Studies of Truncated Hemolysin A from Proteus mirabilis

In this study we analyzed the structure and function of a truncated form of hemolysin A (HpmA265) from Proteus mirabilis using a series of functional and structural studies. Hemolysin A belongs to the two-partner secretion pathway. The two-partner secretion pathway has been identified as the most common protein secretion pathway among Gram-negative bacteria. Currently, the mechanism of action for the two-partner hemolysin members is not fully understood. In this study, hemolysis experiments revealed a unidirectional, cooperative, biphasic activity profile after full-length, inactive hemolysin A was seeded with truncated hemolysin A. We also solved the first x-ray structure of a TpsA hemolysin. The truncated hemolysin A formed a right-handed parallel β-helix with three adjoining segments of anti-parallel β-sheet. A CXXC disulfide bond, four buried solvent molecules, and a carboxyamide ladder were all located at the third complete β-helix coil. Replacement of the CXXC motif led to decreased activity and stability according to hemolysis and CD studies. Furthermore, the crystal structure revealed a sterically compatible, dry dimeric interface formed via anti-parallel β-sheet interactions between neighboring β-helix monomers. Laser scanning confocal microscopy further supported the unidirectional interconversion of full-length hemolysin A. From these results, a model has been proposed, where cooperative, β-strand interactions between HpmA265 and neighboring full-length hemolysin A molecules, facilitated in part by the highly conserved CXXC pattern, account for the template-assisted hemolysis.Hemolysin A (HpmA)² and B (HpmB) from Proteus mirabilis belong to the Type V_b or two-partner secretion pathway (1), the most widespread of the five porin-type protein translocating systems found within bacterial, fungal, plant, and animal kingdoms (2). Cell surface adhesions, iron-acquisition proteins, and cytolysins/hemolysins all use two-partner secretion pathways (3–5). The A-component of the two-partner secretion in P. mirabilis is a 166-kDa virulence factor capable of mammalian blood cell lysis upon secretion from the cell. This is accomplished by Sec-dependent transport to the periplasm followed by N-terminal proteolytic processing. Extracellular secretion occurs by transport through the B-component, HpmB, which is a 16-stranded β-barrel transmembrane channel (6). In addition to its role in efficient secretion, HpmB is also necessary for activation of the larger exoprotein A-component (HpmA) (7–10).Studies on hemolytic TpsA members report that: 1) a truncated TpsA containing the N-terminal secretion cap (11) complements and restores hemolytic activity within a non-secreted/inactive pool of full-length TpsA (12), 2) the conserved cysteine residues within a CXXC motif are not required for secretion (12), and 3) the first asparagine within a NPNG hemagglutinin motif is required for efficient secretion (13). Other investigations demonstrate significant conformational change within TpsA members during B-component dependent secretion (8, 14–16).Recent x-ray crystal structures for two TpsA adhesion orthologs, hemagglutinin from Bordetella pertussis (FHA) and high molecular weight protein from Haemophilus influenzae (HMW1) adopt a right-handed parallel β-helix similar to pectate lyase (11, 18, 19). The 301-residue N-terminal FHA fragment (Fha30) contains a 37 parallel stranded β-helix. Stabilization of type I β-turns at two highly conserved regions: ⁶⁶NPNL and ¹⁰⁵NPNG is proposed to play a large role in the ability of this N-terminal fragment to rapidly adopt β-helix architecture (11, 20). Despite 21% sequence identity, the 371-residue HMW1 structure (HMW1-PP) is a similar 47 parallel stranded β-helix. A hypothesis arose from these β-helix structures that suggests extracellular secretion through TpsB channels, and the progressive folding of TpsA members is energetically coupled. Full-length TpsA adhesion members have been proposed to have a filamentous appearance built from a right-handed β-helix fold (21). To date, there is little known about the full-length HpmA domain architecture. However, there are two filamentous hemagglutinin type domains. The N-terminal domain is positioned between residues 30 and 167, whereas the C-terminal domain lies between residues 1200 and 1264 and has been proposed to facilitate cellular aggregation.In this work, we investigated the functional and structural role of truncated hemolysin A (HpmA265) during the template-assisted activation of hemolysis. A previous investigation with ShlA, a homologous TpsA member from Serratia marcescens, has shown similar complementation using a 255-amino acid fragment (12). Here, we demonstrate that HmpA265 can cooperatively cross seed an inactive pool of full-length hemolysin A (HpmA*) to form an exotoxin measured by our template-assisted hemolytic assay (TAHA). We also report that the CXXC motif provides structural stability and facilitates reversible re-folding. The structure reveals a right-handed β-helix, similar to those of FHA and HMW1. A number of conserved features found at the putative subunit interface suggest a mechanism by which activation of inactive HpmA* occurs.     

Genomic and Proteomic Studies on Plesiomonas shigelloides Lipopolysaccharide Core Biosynthesis

We report here the identification of waa clusters with the genes required for the biosynthesis of the core lipopolysaccharides (LPS) of two Plesiomonas shigelloides strains. Both P. shigelloideswaa clusters shared all of the genes besides the ones flanking waaL. In both strains, all of the genes were found in the waa gene cluster, although one common core biosynthetic gene (wapG) was found in a different chromosome location outside the cluster. Since P. shigelloides and Klebsiella pneumoniae share a core LPS carbohydrate backbone extending up at least to the second outer-core residue, the functions of the common P. shigelloides genes were elucidated by genetic complementation studies using well-defined K. pneumoniae mutants. The function of strain-specific inner- or outer-core genes was identified by using as a surrogate acceptor LPS from three well-defined K. pneumoniae core LPS mutants. Using this strategy, we were able to assign a proteomic function to all of the P. shigelloideswaa genes identified in the two strains encoding six new glycosyltransferases (WapA, -B, -C, -D, -F, and -G). P. shigelloides demonstrated an important variety of core LPS structures, despite being a single species of the genus, as well as high homologous recombination in housekeeping genes.     

The phospholipases of Proteus mirabilis

The method of screening Proteus for phospholipase activity has been worked out. The study of isolated clones of the same strain, used as an example, has revealed that clones differing in their phospholipase activity also differ in virulence and in some parameters of interaction in the host-parasite system. P. mirabilis phospholipases are supposed to be of importance as one of the factors contributing to the invasive properties of these microorganisms at the stage of overcoming the epithelial cell barrier of mucous membranes.     

Fimbriae of uropathogenic Proteus mirabilis

Proteus mirabilis is a common causative agent of cystitis and pyelonephritis in patients with urinary catheters or structural abnormalities of the urinary tract. Several types of fimbriae, which are potentially involved in adhesion to the uroepithelium, can be expressed simultaneously by P. mirabilis: mannose-resistant/Proteus-like (MR/P) fimbriae, P. mirabilis fimbriae (PMF), uroepithelial cell adhesin (UCA), renamed by some authors nonagglutinating fimbriae (NAF), and ambient-temperature fimbriae (ATF). Proteus mirabilis is a common cause of biofilm formation on catheter material and MR/P fimbriae are involved in this process. The considerable serious pathology caused by P. mirabilis in the urinary tract warrants the development of a prophylactic vaccine, and several studies have pointed to MR/P fimbriae as a potential target for immunization. This article reviews P. mirabilis fimbriae with regard to their participation in uropathogenesis, biofilm formation and as vaccine targets.     

Characterization of Indole-Positive Proteus mirabilis

Thirteen indole-producing, swarming strains of Proteus were identified by additional biochemical testing as being Proteus mirabilis. These strains were characterized by 40 biochemical tests and by susceptibility testing to 11 antibiotics. All produced ornithine decarboxylase and were susceptible to members of the penicillin-cephalosporin groups of antibiotics. These indole-positive strains are similar to indole-negative P. mirabilis and are distinctly different from P. vulgaris. For greatest accuracy and to insure greatest clinical relevancy, P. mirabilis and P. vulgaris should be distinguished from one another in the laboratory by performing both the indole and ornithine decarboxylase tests.     

Lipopolysaccharide from Proteus mirabilis O29 induces changes in red blood cell membrane lipids and proteins

Alterations in red blood cell (RBC) plasma membranes, i.e. in lipids and proteins, and osmotic fragility of these cells after treatment with Proteus mirabilis O29 endotoxin (lipolysaccharide (LPS)) were examined using a spin labelling method. At the highest concentration of LPS, insignificantly decreased fluidity of membrane lipids was observed. Changes in conformation of membrane proteins were determined by two covalently bound spin labels, 4-maleimido-2,2,6,6-tetramethylpiperidine-1-oxyl (MSL) and 4-iodoacetamido-2,2,6,6-tetramethylpiperidine-1-oxyl (ISL). The analysis of spectra of MSL and ISL showed modifications in membrane proteins in red blood cells treated with the highest concentration of lipopolysaccharide. On the other hand, in the case of isolated membranes, disturbances in membrane were observed for all concentrations of LPS. The alterations in membrane lipids and proteins are paralleled in a significant rise in osmotic fragility of RBCs upon endotoxin treatment. These results provide experimental evidence that P. mirabilis O29 LPS causes deleterious changes in membranes of human red blood cells. They show that action of lipopolysaccharide mainly concerns the membrane cytoskeleton.     

Bacteriophage Typing of Proteus mirabilis, Proteus vulgaris, and Proteus morganii

A bacteriphage typing scheme for differentiating Proteus isolated from clinical specimens was developed. Twenty-one distinct patterns of lysis were seen when 15 bacteriophages isolated on 8 Proteus mirabilis, 1 P. vulgaris, and 1 P. morganii were used to type 162 of 189 (85.7%) P. mirabilis and P. vulgaris isolates. Seven phages isolated on 3 P. morganii were used to type 13 of 19 (68.4%) P. morganii isolates. Overall, 84.1% of the 208 isolates were lysed by at least 1 phage at routine test dilution (RTD) or 1,000 x RTD. Fifty isolates, retyped several weeks after the initial testing, showed no changes in lytic patterns. The phages retained their titers after storage at 4 C for several months. A computer analysis of the data showed that there was no relationship between the source of the isolate and bacteriophage type. This bacteriophage typing system may provide epidemiological information on strains involved in human infections.     

甜菊醇糖苷生物合成关键基因的导入和鉴定分析

甜叶菊（Stevia rebaudiana Bertoni）生产的甜菊醇糖苷因具有高甜度、低热能、不参与人体内代谢兼具保健功能等特点,被誉为最有发展前途的新糖源。从甜叶菊叶片克隆了甜菊醇糖苷生物合成途径中的关键基因SrUGT85C2、SrUGT91D2m和SrUGT76G1,构建植物基因过量表达载体,以单独或组合的形式将这些基因导入到甜叶菊中,获得转基因植株。与野生型对照植株相比,单独导入SrUGT85C2的转基因植株中甜菊醇单糖苷含量提高,总糖苷、莱包迪苷A含量及占比没有明显变化;单独导入SrUGT91D2m的转基因植株中甜菊醇单糖苷含量显著降低,而甜菊醇双糖苷含量显著增加;单独导入SrUGT76G1的转基因植株中,总糖苷含量显著提高,莱包迪苷A含量达到10%以上,比对照提高了2倍,而甜菊糖苷含量减少了一半。3个基因组合同时导入的转基因甜叶菊植株与单独导入SrUGT76G1的转基因甜叶菊植株类似,其总糖苷、莱包迪苷A含量及其占比均显著提高。这些结果为以后通过分子生物学技术来调控甜菊醇糖苷生物合成关键基因的表达,培育莱包迪苷A含量高的高品质甜叶菊新品系提供了理论依据和技术方法。     

Production of superoxide dismutases from Proteus mirabilis and Proteus vulgaris

Proteus mirabilis and Proteus vulgaris expressed a combination of superoxide dismutase (Sod) activities, which was assigned to FeSod1, FeSod2 and MnSod for P. mirabilis, and FeSod, MnSod and CuZnSod for P. vulgaris. Production of the Sod proteins was dependent on the availability of iron, whether cells were grown under anaerobiosis or aerobiosis and growth phase. Nalidixic acid and chloramphenicol inhibited cell growth and the iron- and dioxygen-dependent production of Sod. These results support the involvement of metal ions and redox status in the production of Proteus Sods.