Conservation of surface epitopes in Pseudomonas aeruginosa outer membrane porin protein OprF

The outer membrane proteins of several prominent bacterial pathogens demonstrate substantial variation in their surface antigenic epitopes. To determine if this was also true for Pseudomonas aeruginosa outer membrane protein OprF, gene sequencing of a serotype 5 isolate was performed to permit comparison with the published serotype 12 oprF gene sequence. Only 16 nucleotide substitutions in the 1053 nucleotide coding region were observed; none of these changed the amino acid sequence. A panel of 10 monoclonal antibodies (mAbs) reacted with each of 46 P. aeruginosa strains representing all 17 serotype strains, 12 clinical isolates, 15 environmental isolates and 2 laboratory isolates. Between two and eight of these mAbs also reacted with proteins from representatives of the rRNA homology group I of the Pseudomonadaceae. Nine of the ten mAbs recognized surface antigenic epitopes as determined by indirect immunofluorescence techniques and their ability to opsonize P. aeruginosa for phagocytosis. These epitopes were partially masked by lipopolysaccharide side chains as revealed using a side chain-deficient mutant. It is concluded that OprF is a highly conserved protein with several conserved surface antigenic epitopes.

Linker-insertion mutagenesis of Pseudomonas aeruginosa outer membrane protein OprF

The oprF gene, expressing Pseudomonas aeruginosa major outer membrane protein OprF, was subjected to semi-random linker mutagenesis by insertion of a 1.3 kb HincII kanamycin-resistance fragment from plasmid pUC4KAPA into multiple blunt-ended restriction sites in the oprF gene. The kanamycin-resistance gene was then removed by PstI digestion, which left a 12 nucleotide pair linker residue. Nine unique clones were identified that contained such linkers at different locations within the oprF gene and were permissive for the production of full-length OprF variants. In addition, one permissive site-directed insertion, one non-permissive insertion and one carboxyterminal insertion leading to proteolytic truncation were also identified. These mutants were characterized by DNA sequencing and reactivity of the OprF variants with a bank of 10 OprF-specific monoclonal antibodies. Permissive clones produced OprF variants that were shown to be reactive with the majority of these monoclonal antibodies, except where the insertion was suspected of interrupting the epitope for the specific monoclonal antibody. In addition, these variants were shown to be 2-mercaptoethanol modifiable, to be resistant to trypsin cleavage in intact cells and partly cleaved to a high-molecular-weight core fragment in outer membranes and , where studied, to be accessible to indirect immunofluorescence labelling in intact cells by monoclonal antibodies specific for surface epitopes. Based on these data, a revised structural model for OprF is proposed.

Nuclear protein redistribution in heat-shocked cells

An increase was observed in the total protein mass of nuclei isolated from Chinese hamster ovary cells heated at 45 degrees C or 45.5 degrees C. An increase in the fractional recovery of DNA polymerase alpha and beta, and of DNA topoisomerase activity coincided with this increase in the protein mass of nuclei from heated cells. Nuclear protein mass which was soluble in 2.0 M NaCl decreased 0.5 fold, while DNA-associated and nuclear matrix-associated protein mass increased 2.2 and 3.4 fold, respectively. The results indicate that the increase in nuclear protein mass observed in nuclei from heated cells is due in part to an increased binding, or precipitation, of nuclear proteins onto the cell's DNA and nuclear matrix.

Content of nonhistone protein in nuclei after hyperthermic treatment

When nuclei were isolated from Chinese hamster ovary cells after being heated, there was a large increase in the amount of 3H-tryptophan labeled nonhistone protein in the nucleus relative to the whole cell. After 15 min or 30 min of heating at 45.5 degrees C, the nuclear nonhistone protein content increased by 1.6 or 1.8, respectively. In contrast, when the nuclear nonhistone protein content was determined in the intact cell by using autoradiography to quantify 3H-tryptophan labeled protein in the nucleus and cytoplasm in sections of fixed cells, the nuclear nonhistone protein content increased by only 1.14 or 1.28 for 15 or 30 min at 45.5 degrees C, respectively. Therefore, heat does not induce a massive movement of cytoplasmic protein into the nucleus.

Critical steps for induction of chromosomal aberrations in CHO cells heated in S phase

The following four effects on DNA replication are observed in cells heated in S phase of the cell cycle: (1) inhibition of replicon initiation, (2) delay in DNA chain elongation into multicluster-sized molecules > 160S, (3) reduction in fork displacement rate, and (4) increase in single-stranded regions in replicating DNA. Since cells heated in S phase manifest chromosomal aberrations when they enter metaphase, whereas cells heated in G1 do not, we attempted to determine if the effects on DNA replication are critical for the induction of chromosomal aberrations by studying these same effects during DNA replication when synchronous CHO cells had been heated (10 min at 45.5 degrees C) in G1 phase. Following a heat-induced G1 block (12 h), we found previously that when the cells entered S phase, replicon initiation was functional and chain elongation into multicluster-sized molecules > 160S was delayed but completed during S phase. In the present study, we find that the fork displacement rate was near normal and that there was no increase in single-stranded DNA. Additionally, an increase in excess nuclear protein induced in the heated G1-phase cells returns to a normal level by about 12 h, just prior to when the cells enter S phase. Since the excess nuclear protein remains for many hours in heated S-phase cells, we hypothesize that the excess nuclear protein is responsible for the drastic reduction in the fork displacement rate and the associated increase in single-stranded DNA. Furthermore, we hypothesize that this persistent increase in single-stranded DNA during replication is a critical step for the induction of chromosomal aberrations in heated S-phase cells. Consistent with this hypothesis, we observed that aphidicolin (1-2 micrograms/ml) treatment of S-phase cells for 13-16 h, which results in a twofold increase in single-stranded DNA during the inhibition of DNA synthesis, also induces chromosomal aberrations. Possibly, endogenous endonucleolytic attack occurs opposite these sites of single-stranded DNA, thus creating double-strand breaks which either can remain unrepaired or are misrepaired to account for the chromatid breaks and exchanges, respectively, observed as cells complete their cell cycle and enter metaphase.

Molecular mechanisms for the induction of chromosomal aberrations in CHO cells heated in S phase

Chromosomal aberrations are induced by heat only when Chinese hamster ovary cells are heated in S phase of the cell cycle. Studies on the hyperthermic inhibition of cellular DNA replication have indicated that four molecular aspects of DNA replication are affected after heating. New replicon initiation and DNA chain elongation are inhibited; the fork displacement rate is very sensitive to heat-inactivation; and finally, there is almost a two-fold increase in single-stranded regions in the replicating DNA after heating. From a comparison of these altered processes between S phase cells and heated G1 cells, which do not die from chromosomal aberrations, our current hypothesis involves 3 steps for the chromosomal aberration induction process. The first critical step is the persistent increase of single-stranded regions in the replicating DNA. Then, we hypothesize that the second step is the creation of transient double strand breaks (DSBs) induced at sites opposite these regions by endogenous endonucleases. Finally, the third step requires that improper repair of these DSBs occurs from either nonrepair or misrepair which then leads to the final chromosomal aberrations seen in the first mitosis after treatment. We believe that this 3 step induction process is common for any cytotoxic agent that induces chromosomal aberrations after DNA replication has been inhibited.

Enhancement of SR 2508 (etanidazole) radiosensitization by buthionine sulphoximine at low-dose-rate irradiation

SR 2508 (etanidazole) (1 mM) or buthionine sulphoximine (BSO, 50 microM) or both drugs together did not radiosensitize oxic V79 Chinese hamster cells irradiated at either an acute dose rate (2.35 Gy/min) or at a low dose rate (0.117 Gy/min). BSO pretreatment (15 h at 37 degrees C) depleted cellular glutathione (GSH) to less than or equal to 1% of control level and radiosensitized hypoxic cells at both dose rates with an enhancement ratio (ER) of 1.2. SR 2508 alone radiosensitized hypoxic cells equally at both dose rates with an ER of 1.5. However, ER values of 2.2 and 2.5 were obtained with 1 mM SR 2508 in GSH-depleted cells at acute and low dose rate, respectively, with no significant difference between the two, i.e. there is no dose rate dependence for this potentiation. Since BSO increases SR 2508 radiosensitization and the combined BSO + SR 2508 treatment is extremely cytotoxic to hypoxic cells, our results suggest that combining BSO with SR 2508 will be useful in brachytherapy as well as external-beam therapy if the toxicity from both drugs in vivo is less than the gain in radiosensitization achieved.

Cell killing, chromosomal aberrations, and division delay as thermal sensitivity is modified during the cell cycle

Synchronous Chinese hamster ovary cells were treated in G1 or S phase with cycloheximide or procaine hydrochloride before and during heating at 43 degrees C. Cycloheximide and procaine apparently act by different mechanisms, with cycloheximide inhibiting protein synthesis and procaine hydrochloride supposedly affecting cellular membranes. Both agents, however, modify the heat damage expressed as chromosomal aberrations, cell killing, or division delay. Furthermore, the approximately twofold protection with cycloheximide treatment or twofold sensitization with procaine treatment is the same for the three end points and for heating during either G1 or S phase. However, heat induces chromosomal aberrations observed in metaphase when cells are heated in S phase but not when they are heated in G1. Finally, for the three end points, the activation energy is about 140-152 kcal/mol. Therefore, heat may induce a common intracellular phenomenon involving protein denaturation or aggregation that is responsible for the damage observed by division delay, chromosomal aberrations, and cell-killing. There are great differences in division delay induced during the cell cycle by heat or radiation. Division delay is the same when cells are heated in the relatively heat-resistant G1 phase or the relatively heat-sensitive S phase, with about 15 min of delay for 1 min of heating at 43 degrees C. This contrasts with the increase in division delay observed when cells are irradiated in the relatively radioresistant S phase compared with the relatively radiosensitive G1 phase. Quantitatively, division delay for a treatment that reduces survival to about 0.1 is 15 or 25 h for heating in S or G1, respectively, compared with only 6 or 1.5 h for irradiation in S or G1, respectively.

DNA technology

With the availability of DNA recombinant technology and DNA and RNA sequencing techniques, diseases can now be studied and treated at a molecular level, while unlimited quantities of a pure protein product can be produced through gene cloning. Before the end of this century, gene therapy will be used to repair genetic defects. This article explains these advances in genetic technology and suggests their relevance in clinical problems and practice.

Thermal tolerance during S phase for cell killing and chromosomal aberrations

Synchronous Chinese hamster ovary cells in early S phase were obtained by selecting mitotic cells, accumulating them at the G1/S border by incubating them in aphidicolin for 12 h, and then incubating them for 2 h after releasing them from the aphidicolin block. To determine if thermotolerance could be induced, the cells were heated at 43 degrees C for 20 min in early S phase, incubated for 160 min, and then heated a second time at 43 degrees C for different durations (30-100 min). For the control, nontolerant population, the cells in early S phase were incubated for 50 min and then heated once at 43 degrees C for different durations (20-60 min). Flow cytometric analysis indicated that the population receiving the second heat dose was in the same part of S phase as the population receiving the single heat dose. A comparison of the heat response for the two populations indicated that heating during early S phase induced thermotolerance for both cell killing and chromosomal aberrations; i.e., for 10% survival, which corresponded to 10% of the cells being cytologically normal, the thermal dose was twofold greater in the thermotolerant cells than in the control, nontolerant cells. Furthermore, this thermotolerance developed during S phase. These observations support the hypothesis that heating during S phase kills cells primarily by inducing chromosomal aberrations.

Glutathione depletion and cytotoxicity of buthionine sulphoximine and SR2508 in rodent and human cells

SR2508 (1 mM) increases the rate of glutathione (GSH) depletion by L-buthionine-S-R-sulphoximine (BSO) in hypoxic V79 rodent and A549 human cells. Specifically, the GSH content for V79 and A549 cells, after incubating for about 6 hr with 50 and 100 microM BSO, respectively, was lower by at least 10-fold when 1 mM SR2508 was present. In addition, 1 mM SR2508 is extremely toxic to hypoxic cells with lower GSH content. Survival probabilities of GSH-depleted V79 and A549 cells are about 10(-3) after 10 hr incubation with 1 mM SR2508. By itself, 1 mM SR2508 or 50-100 microM BSO decreased cellular viability by about 50% with a 10 hr treatment period. Both the phenomena described above are preferential towards hypoxic cells with minimal effect on aerobic cells.

Microspore mutagenesis and selection: Canola plants with field tolerance to the imidazolinones

In vitro microspore mutagenesis and selection was used to produce five fertile double-haploid imidazolinone-tolerant canola plants. The S2 plants of three of the mutants were resistant to at least the field-recommended levels of Assert and Pursuit. One mutant was tolerant to between five and ten times the field-recommended rates of Pursuit and Scepter. Two semi-dominant mutants, representing two unlinked genes, were combined to produce an F1 hybrid which was superior in imidazolinone tolerance to either of the heterozygous mutants alone. Evaluation of the mutants under field conditions indicated that this hybrid and the original homozygous mutants could tolerate at least two times the field-recommended rates of Assert. The field results indicated the mutants were unaffected in seed yield, maturity, quality and disease tolerance. These genes represent a potentially valuable new herbicide resistance system for canola, which has little effect on yield, quality or maturity. The mutants could be used to provide tolerance to several imidazolinones including Scepter, Pursuit and Assert.

Mechanism of killing Chinese hamster ovary cells heated in G1: effects on DNA synthesis and blocking in G2

To determine where in the cell cycle Chinese hamster ovary cells die following heating in G1, a mild hyperthermia treatment, i.e., 10 or 11.5 min at 45.5 degrees C, resulting in 40-50% cell kill was used. After a 7-14-h delay in G1, the cells heated in G1 eventually entered S phase and replicated all their DNA. Both an autoradiographic analysis with tritiated thymidine and a bromodeoxyuridine-propidium iodide bivariate analysis by flow cytometry revealed that both clonogenic and nonclonogenic cells were delayed in progression through S phase for at least 4 h. Then they completed replication of all their DNA and entered G2. Alkaline sucrose gradient sedimentation analysis revealed that these heated cells could complete replicon elongation into cluster-sized molecules of 120-160 S which persisted for 2-12 h after heating. However, further replicon elongation into multicluster-sized molecules greater than 160 S required an additional 12 h in heated cells compared to the 4 h needed in unheated control cells. Our results when compared with the literature suggest that when G1 cells are heated to a survival level of about 50%, the nonclonogenic cells recover from a long delay in G1, traverse S at a reduced rate, and then die either in G2 or as multinucleated cells after an aberrant division.

Growth factors, oncogenes and the autocrine hypothesis

Many aspects must be studied when considering theories of oncogenesis. Growth factors, the polypeptide hormones that are necessary for cell growth, and oncogenes, the genes that produce cancer, are only two aspects. Proto-oncogenes are found in normal cellular DNA and are believed to play regulatory roles in differentiation and development. Oncoviruses, mutation of DNA and chromosomal damage can activate proto-oncogenes and cause malignant change. Oncogenes can render transformed cells independent of growth factors. A cell can bypass the need for outside growth factors by producing the growth factor and its receptor, thereby using an autostimulatory impetus for growth. This is autocrine growth. An oncogene can also bypass the need for growth factors by activating or modifying growth factor receptors, or by stimulating intracellular events, such as tyrosine phosphorylation, both of which ultimately lead to cell division. The various mechanisms by which oncogenes act provide specific targets for treatment. Specific antigrowth factor or antireceptor antibodies or antagonists could interfere with autocrine regulation. Further research on the activation of oncogenes could provide valuable insight on regulation of the growth of tumors. Ultimately, the understanding of the molecular pathogenesis of cellular transformation will be a key to the prevention and treatment of cancer.

DNA fork displacement rate measurements in heated Chinese hamster ovary cells

DNA fork displacement rates (FDR) were measured in Chinese hamster ovary (CHO) cells heated at either 43.5 degrees C or 45.5 degrees C for various times. The inhibition of fork movement rate by heat was both time and temperature dependent, i.e., 10-20 min at 43.5 degrees C or 5 min at 45.5 degrees C was required to decrease the FDR to 20-30% of the control rate of 1 micron/min. Following heating, the reduced FDR was found to be constant for at least 75 min. The observed effects of heat on reduced rates of DNA replicon initiation and chain elongation and the increase in DNA with single-stranded regions could be explained by the heat sensitivity of the FDR. Any of these alterations in the DNA replication process may lead to many opportunities for abnormal DNA and/or protein interactions to occur which ultimately may lead to the observed formation of chromosomal aberrations.

Recovery from effects of heat on DNA synthesis in Chinese hamster ovary cells

The hyperthermic inhibition of cellular DNA synthesis, i.e., reduction in replicon initiation and delay in DNA chain elongation, was previously postulated to be involved in the induction of chromosomal aberrations believed to be largely responsible for killing S-phase cells. Utilizing asynchronous Chinese hamster ovary cells heated for 15 min at 45.5 degrees C, an increase in single-stranded regions in replicating DNA (as measured by BND-cellulose chromatography) persisted in heated cells for as long as replicon initiation was affected. Alkaline sucrose gradient analyses of cells pulse-labeled immediately after heating with [3H]thymidine and subsequently chased at 37 degrees C revealed that these S-phase cells can eventually complete elongation of the replicons in operation at the time of heating, but required about six times as long relative to control cells which completed replicon elongation within 4 h. DNA chain elongation into multicluster-sized molecules was prevented for up to 18 h in these heated cells, resulting in a buildup of cluster-sized molecules (approximately 120-160 S) mainly because of the long-term heat damage to the replicon initiation process. Utilizing bromodeoxyuridine (BrdU)-propidium iodide bivariate analysis on a flow cytometer to measure cell progression, control cells pulsed with BrdU and chased in unlabeled medium progressed through S and G2M with cell division starting after 2 h of chase time. In contrast, the majority of the heated S-phase cells progressed slowly and remained blocked in S phase for about 18 h before cell division was observed after 24 h postheat. Our findings suggest that possible sites for where the chromosomal aberrations may be occurring in heated S-phase cells are either (1) at the persistent single-stranded DNA regions or (2) at the regions between clusters of replicons, because this long-term heat damage to the DNA replication process might lead to many opportunities for abnormal DNA and/or protein exchanges to occur at these two sites.

A scanning electron-microscopic, stereo-pair study of methacrylate corrosion casts of the mouse palatal and molar periodontal microvasculature

Microvascular beds of the palate, gingiva and periodontal ligament had interconnected but distinct, regional patterns. The palatal vasculature reflected mucosal-crest morphology: crestal capillary vessels of the rugae anastomosed with sagitally-orientated rows of 8 microns capillary loops, and, in the inter-rugal troughs, these formed a flat plexus overlying collecting veins more than 100 microns in diameter. Maxillary and mandibular molar ligaments had similar microvascular patterns. The molar gingiva had a circular, outer capillary and inner venous system linked by radial anastomoses. The outer (7 microns) capillaries enclosed the three molars in a continuous horizontal loop coursing beneath the crestal epithelium; the inner (10-15 microns) venous vessels encircled each molar just below the epithelial attachment. Glomerulus-like vascular formations, with an arterial and venous stalk, were associated with the inner circular system and extended toward the crevicular epithelium. Axially aligned, post-capillary, periodontal-ligament vessels (21 microns) anastomosed with the inner circular system, forming different patterns in the occlusal, middle and apical thirds. The apical pattern comprised an enveloping plexus of anastomosing venous vessels supplied by arterio-venous shunts; similar shunts were present throughout the ligament. The microvascular bed of the mandibular inter-radicular ligament was characterized by the presence of a large venous ampulla measuring 60 by 200 microns. Some regions of the ligament microvasculature drained via the medullary vessels into 50 microns-diameter venules located interdentally deep to the molar apices. Volumetrically, the ligament microvascular bed was predominantly of post-capillary venules, and morphologically, a paired arterial and venous system was not demonstrated.

Mitochondrial DNA rearrangements in somatic hybrids of Solanum tuberosum and Solanum brevidens

Thirty somatic hybrids between Solanum tuberosum and Solanum brevidens were analysed for mitochondrial and chloroplast genome rearrangements. In all cases, the chloroplast genomes were inherited from one of the parental protoplast populations. No chloroplast DNA alterations were evident but a range of mitochondrial DNA alterations, from zero to extensive intra- and inter-molecular recombinations, were found. Such recombinations involved specific 'recombination hot spots' in the mitochondrial genome. Not all hybrids regenerated from a common callus possessed identical mitochondrial genomes, suggesting that sorting out of mitochondrial populations in the callus may have been incomplete at the plant regeneration stage. Sorting out of organelles in planta was not observed.

Hyperthermic radiosensitization of thermotolerant Chinese hamster ovary cells

Synchronous G1 cells were given a priming dose of heat (45.5 degrees C for 15 min) and then heated and irradiated 6-120 h later. Compared to heat radiosensitization for cells irradiated 10 min after the priming heat dose (thermal enhancement ratio, TER of 2.6 for a 10-fold reduction in survival), heat radiosensitization 18-24 h after the priming heat dose was less (i.e., TER of 1.6 for radiation at 24 h compared with heat-radiation at 24 h). A thermotolerance ratio (TTR) at 24 h was calculated to be 2.6/1.6 = 1.6. TERs at 100-fold or 1000-fold reduction in survival and ratios of slopes of radiation survival curves also showed that the cells developed a similar amount of thermotolerance for heat radiosensitization at 18-24 h. Furthermore, since the TER for heat radiosensitization increased with heat killing either from the priming heat dose or the second heat dose in a similar manner for single or fractionated doses, the TER for nonthermotolerant and thermotolerant cells was the same when related to the heat damage (i.e., amount of killing from heat alone). When the radiation response of cells heated and irradiated 6-120 h after the priming heat dose was compared with the response of cells receiving radiation only, changes in TER as a function of time after the initial priming heat dose were shown to involve: recovery of heat damage interacting with the subsequent radiation dose, thermotolerance for heat radiosensitization, and redistribution of cells surviving the first heat dose into radioresistant phases of the cell cycle. In fact, redistribution resulted in a minimal TER at 72 h for heat-radiation compared with radiation alone, instead of at 24 h where maximal thermotolerance for heat killing was observed [P. K. Holahan and W. C. Dewey, Radiat. Res. 106, 111 (1986)]. These observations are discussed relative to clinical considerations and similar results reported from in vivo experiments.

A direct correlation between hyperthermia-induced membrane blebbing and survival in synchronous G1 CHO cells

Heating synchronous G1 cells at 45.5 degrees C for 3-20 min induced varying degrees of membrane blebbing ranging from nonblebbed cells indistinguishable from control cells to those with blebs larger than the cell itself. Both the proportion of cells exhibiting blebbing and the mean diameter of the blebs increased with heating duration. Scoring individual cells for both blebbing and colony formation demonstrated that cells with blebs larger than 50% of the cell diameter did not survive to form colonies. Electron microscopy showed that all subcellular organelles, save the ribosomes, were absent from the membrane blebs. Freeze fracture replicas revealed no changes in membrane ultrastructure, except on some 15% of the blebs that contained bald patches devoid of membrane particles.

The role of glandular kallikrein in the formation of a salivary proline-rich protein A by cleavage of a single bond in salivary protein C

An enzyme was purified from human parotid saliva that can cleave a single arginine-glycine peptide bond between residues 106 and 107 in human salivary proline-rich protein C, hereby giving rise to another proline-rich protein A, which is also found in saliva. The enzyme was purified 2400-fold. It cleaved salivary protein C at the rate of 59 micrograms of protein/h per microgram of enzyme and had amino acid composition, molecular weight and inhibition characteristics similar to those reported for human salivary kallikrein. Confirmation that the enzyme was kallikrein was demonstrated by its kinin-generating ability. Histochemical evidence indicates that a post-synthetic cleavage of protein C by kallikrein would have to take place during passage of saliva through the secretory ducts. In secreted saliva, cleavage of salivary protein C can only be observed after 72 h incubation. In addition, there is no effect of salivary flow rate on the relative amounts of proteins A and C in saliva. On the basis of the experimental observations, it is proposed that in vivo it is unlikely that kallikrein secreted from ductal cells plays a significant role in converting protein C into protein A.