K(+)-channel transgenes reduce K(+) currents in Paramecium, probably by a post-translational mechanism.

PAK11 is 1 of more than 15 members in a gene family that encodes K(+)-channel pore-forming subunits in Paramecium tetraurelia. Microinjection of PAK11 DNA into macronuclei of wild-type cells results in clonal transformants that exhibit hyperexcitable swimming behaviors reminiscent of certain loss-of-K(+)-current mutants. PAK2, a distant homolog of PAK11, does not have the same effect. But PAK1, a close homolog of PAK11, induces the same hyperexcitability. Cutting the PAK11 open reading frame (ORF) with restriction enzymes before injection removes this effect entirely. Microinjection of PAK11 ORF flanked by the calmodulin 5' and 3' UTRs also induces the same hyperexcitable phenotype. Direct examination of transformed cells under voltage clamp reveals that two different Ca(2+)-activated K(+)-specific currents are reduced in amplitude. This reduction does not correlate with a deficit of PAK11 message, since RNA is clearly produced from the injected transgenes. Insertion of a single nucleotide at the start of the PAK11 ORF does not affect the RNA level but completely abolishes the phenotypic transformation. Thus, the reduction of K(+) currents by the expression of the K(+)-channel transgenes reported here is likely to be the consequence of a post-translational event. The complexity of behavioral changes, possible mechanisms, and implications in Paramecium biology are discussed.

The cloning and molecular analysis of pawn-B in Paramecium tetraurelia.

Pawn mutants of Paramecium tetraurelia lack a depolarization-activated Ca(2+) current and do not swim backward. Using the method of microinjection and sorting a genomic library, we have cloned a DNA fragment that complements pawn-B (pwB/pwB). The minimal complementing fragment is a 798-bp open reading frame (ORF) that restores the Ca(2+) current and the backward swimming when expressed. This ORF contains a 29-bp intron and is transcribed and translated. The translated product has two putative transmembrane domains but no clear matches in current databases. Mutations in the available pwB alleles were found within this ORF. The d4-95 and d4-96 alleles are single base substitutions, while d4-662 (previously pawn-D) harbors a 44-bp insertion that matches an internal eliminated sequence (IES) found in the wild-type germline DNA except for a single C-to-T transition. Northern hybridizations and RT-PCR indicate that d4-662 transcripts are rapidly degraded or not produced. A second 155-bp IES in the wild-type germline ORF excises at two alternative sites spanning three asparagine codons. The pwB ORF appears to be separated from a 5' neighboring ORF by only 36 bp. The close proximity of the two ORFs and the location of the pwB protein as indicated by GFP-fusion constructs are discussed.

Recent advances in the molecular genetics of Paramecium.

Paramecium continues to be used to study motility, behavior, exocytosis, and the relationship between the germ and the somatic nuclei. Recent progress in molecular genetics is described. Toward cloning genes that correspond to mutant phenotypes, a method combining complementation with microinjected DNA and library sorting has been used successfully in cloning several novel genes crucial in membrane excitation and in trichocyst discharge. Paramecium transformation en masse has now been shown by using electroporation or bioballistics. Gene silencing has also been discovered in Paramecium, recently. Some 200 Paramecium genes, full length or partial, have already been cloned largely by homology. Generalizing the use of gene silencing and related reverse-genetic techniques would allow us to correlate these genes with their function in vivo.

A comparison of internal eliminated sequences in the genes that encode two K(+)-channel isoforms in Paramecium tetraurelia.

We examined both the somatic (macro-) and the germinal (micronuclear) DNAs that encode two K(+)-channel isoforms, PAK1 and PAK11, in Paramecium tetraurelia. The coding regions of these two isoforms are 88% identical in nucleotides and 95% identical in amino acids. Their introns are also highly conserved. Even some of the internal eliminated sequences in PAK1 and PAK11 are clearly related. PAK1 has five IESs; PAK11 has four. The first (5'-most) IESs of the two genes are located at the same site in the coding sequence but differ in size. The 2nd IES in PAK1 (206-bp), the largest among the nine IESs, has no PAK11 counterpart. The 3rd, 4th and 5th IESs in PAK1 have a counterpart in PAK11 that is similar in size and in sequence, and identical in its position in the coding sequence. In addition, the first IES of PAK11 bears some resemblance to the 4th one of PAK1. The similarities and differences between the two sets of IESs are discussed with respect to the origin and divergence of the two K(+)-channel isoforms.

Toward cloning genes by complementation in Paramecium.

Conventional methods of gene cloning by complementing mutant defects is made difficult by the 800 ploidy of the Paramecium macronucleus. However, this nucleus is some 30 microns in diameter and readily propagates exogenous DNA fragments as cells divide. These attributes allow for massive injection of engineered DNA fragments and their maintenance in the transformed descendant. If a genomic DNA fraction injected into a mutant macronucleus effects complementation, it should be possible to sort a fractional library to isolate the complementing gene. Here, we investigated four aspects of establishing this method for general use. First, using the cloned CAM gene as a test case, we further investigated transformation by macronuclear injection and showed that phenotypic reversion is directly correlated with the copy number of the transgene, even when it is of a recessive allele, cam2, which has a missense mutation but produces a partially functional protein. Second, we examined the copy number of the transgene established in cells of older clonal age and discussed the likely dilution of the transgene in younger descendants of the injected cell. Third, we showed that the degree of phenotypic reversion is correlated with the transgene product, the cam2 calmodulin protein in the cell. Fourth, we extended the investigation to very recessive mutants whose genes are to be cloned. We showed that size fractions of wild-type genomic DNA digests effect strong phenotypic reversions in several pawn mutants, setting the stage for cloning these Ca(2+)-channel related genes. The general usefulness of this method in cloning genes that complement recessive alleles and current limitations of this method in dealing with dominant alleles are assessed and discussed.

Paramecium Na+ channels activated by Ca(2+)-calmodulin: calmodulin is the Ca2+ sensor in the channel gating mechanism.

Paramecium Na+ channels, which were Ca(2+)-calmodulin activated, were studied in the inside-out mode of patch clamp. After excision of the membrane patch, they were active in the presence of 10(-5) to 10(-3) M Ca+ in the bath. They became much less active in the presence of 10(-6) M Ca2+, and their activity subsided completely at 10(-8) M Ca2+. A Hill plot showed a dissociation constant of 6 microM for Ca2+ binding. This dissociation constant shifted to a submicromolar range in the presence of 1 mM Mg2+. The channels also exhibited a mild voltage dependence. When exposed to 10(-8) M Ca2+ for an extended period of 2-4 min, channels were further inactivated even after bath Ca2+ was restored to 10(-4) M. Whereas neither high voltage (+100 mV) nor high Ca2+ (10(-3) M) was effective in reactivation of the inactive channels, addition of Paramecium wild-type calmodulin together with high Ca2+ to the bath restored channel activity without a requirement of additional Mg2+ and metabolites such as ATP. The channels reactivated by calmodulin had the same ion conductance, ion selectivity and Ca2+ sensitivity as those prior to inactivation. These inactivation and reactivation of the channels could be repeated, indicating that the direct calmodulin effect on the Na+ channel was reversible. Thus, calmodulin is a physiological factor critically required for Na+ channel activation, and is the Ca2+ sensor of the Na(+)-channel gating machinery.

Induction of antibiotic resistance in Paramecium tetraurelia by the bacterial gene APH-3'-II.

We have generated a transformation marker for Paramecium using a Paramecium expression vector (pPXV) and the open reading frame (ORF) of the bacterial antibiotic resistance gene aminoglycoside 3'-phosphotransferase-II (APH-3'-II or neor) from the transposon Tn5. The expression vector contained a small multiple cloning site between the 5' and 3' non-coding regions of the calmodulin gene, and Tetrahymena telomere sequences for the stability of the plasmid in Paramecium. After the neor ORF was inserted, the plasmid was referred to as pPXV-NEO. Delivery of approximately 10-20 picoliters of linearized PXV-NEO at > or = 2000 copies/pl into the macronucleus effected 100% transformation. Southern and Northern blot hybridization showed the presence of neor-specific DNA and RNA, respectively, in all of the transformed clones but not in the untransformed clones. The degree of resistance to G-418, and the concentrations of neor-specific DNA and neor-specific RNA in the clones were proportional to the concentration of the vector injected. We have demonstrated that when the linearized plasmid was injected into the macronucleus, the prokaryotic sequence conferred an antibiotic resistance to Paramecium despite codon-usage differences.

New non-lethal calmodulin mutations in Paramecium. A structural and functional bipartition hypothesis.

The mechanisms by which calmodulin coordinates its numerous molecular targets in living cells remain largely unknown. To further understand how this pivotal Ca(2+)-binding protein functions in vivo, we isolated and studied nine new Paramecium behavioral mutants defective in calmodulin. Nucleotide sequences of mutant calmodulin genes indicated single amino-acid substitutions in mutants cam4(E104K), cam5-1 (D95G), cam6 (A102V), cam7 (H135R), cam14-1 (G59S) and cam15 (D50G). In addition, we encountered a second occurrence of three identified substitutions; they are cam1-2 (S101F), cam5-2 (D95G) and cam14-2 (G59S). Most of these mutational changes occurred in sites that have been highly conserved throughout evolution. Furthermore, most of these changes were not among the amino acids known to interact with the basic amphiphilic peptides of calmodulin targets. Consistent with our previous finding [Kink, J. A., Maley, M. E., Preston R. R., Ling, K.-Y., Wallen-Friedman, M. A., Saimi, Y. & Kung, C. (1990) Cell 62, 165-174], mutants that under-reacted to certain stimuli (allele number above 10) had substitutions in the N-terminal lobe of calmodulin, and those that over-reacted (below 10) had substitutions in the C-terminal lobe. No mutations were found in the central helix that connects the lobes. Thus, through undirected in vivo mutation analyses of Paramecium, we discovered that each of the two lobes of calmodulin has a distinct role in regulating the function of a specific ion channel and eventually the behavior of Paramecium. We, therefore, propose a hypothesis of functional bipartition of calmodulin that reflects its structural bipartition.

Structure of the recombinant Paramecium tetraurelia calmodulin at 1.68 A resolution.

The crystal structure of the recombinant calmodulin from Paramecium tetraurelia (rPCaM, M(r) = 16 700, 148 residues) has been determined at 1.68 A resolution. X-ray intensity data were collected at 263 K using a Siemens-Nicolet area detector and Cu Kalpha radiation from a rotating-anode source. A total of 35 936 observations were processed with XENGEN1.3 and scaled to yield 16 255 unique reflections with R(symm)(I) of 4.1%. The crystals are triclinic, with unit-cell dimensions a = 29.89, b = 53.42, c = 25.35 A, alpha = 93.67, beta = 96.88, gamma = 89.24 degrees, space group P1, with one molecule in the unit cell. The atomic coordinates of the wild-type Paramecium calmodulin (PCaM) studied in our laboratory provided the starting model. Refinement of the structure by X-PLOR and refitting it into omit maps yielded an R value of 0.194 for 15 965 reflections greater than 3sigma(F) in the 6.0-1.68 A resolution range. The final model contained 1165 protein atoms for all of the 148 residues, four Ca(2+) ions, and 172 water molecules. The dumbbell structure has seven alpha-helices including a long 7.8 turn central helix connecting the two terminal domains each containing two EF-hand (helix-loop-helix motif) calcium-binding sites. The loops within each pair of EF-hand motifs in the N- and C-terminal domains are brought into juxtaposition to form a pair of hydrogen-bonded antiparallel beta-sheets which are extended at either ends by water bridges. The four calcium-binding EF-hands are superposable with r.m.s. deviations of 0.31-0.79 A. The best agreement is between site 1 and site 3 and the worst agreement is between site 1 and 4. The largest differences are in the ninth and tenth residues of the calcium-binding loops probably because of their involvement in the mini beta-sheets. The calcium coordination distances vary between 2.04 and 2.69 A, average 2.34 A. The rPCaM and wild-type PCaM have an r.m.s. deviation of 0.36 A for equivalent C(alpha) atoms. The side chains of Lys13 and Lys115 are more extended in rPCaM compared to the wild type where the post-translational modified di- and tri-methylated lysine residues are more folded. The sequence of PCaM differs from those of mammalian (MCaM) and Drosophila calmodulin (DCaM), but the overall structures are very similar, with r.m.s,. deviations of 0.44 and 1.68 A for equivalent C(alpha) atoms, respectively. However, in rPCaM, the first four N-terminal residues stretch out and make intermolecular crystal contacts, in contrast to those in recombinant Drosophila calmodulin (rDCaM), they stretch out in the opposite direction and towards the second calcium-binding site (see note below), while in MCaM and wild-type PCaM, the N-terminal residues are not visible. The central helix in rPCaM has all its backbone hydrogen bonds intact with no unusually long separation between the carbonyl and amide groups as found in MCaM and rDCaM.

Structure of Paramecium tetraurelia calmodulin at 1.8 A resolution.

The crystal structure of calmodulin (CaM; M(r) 16,700, 148 residues) from the ciliated protozoan Paramecium tetraurelia (PCaM) has been determined and refined using 1.8 A resolution area detector data. The crystals are triclinic, space group P1, a = 29.66, b = 53.79, c = 25.49 A, alpha = 92.84, beta = 97.02, and gamma = 88.54 degrees with one molecule in the unit cell. Crystals of the mammalian CaM (MCaM; Babu et al., 1988) and Drosophila CaM (DCaM; Taylor et al., 1991) also belong to the same space group with very similar cell dimensions. All three CaMs have 148 residues, but there are 17 sequence changes between PCaM and MCaM and 16 changes between PCaM and DCaM. The initial difference in the molecular orientation between the PCaM and MCaM crystals was approximately 7 degrees as determined by the rotation function. The reoriented Paramecium model was extensively refitted using omit maps and refined using XPLOR. The R-value for 11,458 reflections with F > 3 sigma is 0.21, and the model consists of protein atoms for residues 4-147, 4 calcium ions, and 71 solvent molecules. The root mean square (rms) deviations in the bond lengths and bond angles in the model from ideal values are 0.016 A and 3 degrees, respectively. The molecular orientation of the final PCaM model differs from MCaM by only 1.7 degrees. The overall Paramecium CaM structure is very similar to the other calmodulin structures with a seven-turn long central helix connecting the two terminal domains, each containing two Ca-binding EF-hand motifs. The rms deviation in the backbone N, Ca, C, and O atoms between PCaM and MCaM is 0.52 A and between PCaM and DCaM is 0.85 A. The long central helix regions differ, where the B-factors are also high, particularly in PCaM and MCaM. Unlike the MCaM structure, with one kink at D80 in the middle of the linker region, and the DCaM structure, with two kinks at K75 and I85, in our PCaM structure there are no kinks in the helix; the distortion appears to be more gradually distributed over the entire helical region, which is bent with an apparent radius of curvature of 74.5(2) A. The different distortions in the central helical region probably arise from its inherent mobility.

Activities of a mechanosensitive ion channel in an E. coli mutant lacking the major lipoprotein.

The activity of the mechanosensitive (MS) ion channels in membrane patches, excised from E. coli spheroplasts, was analyzed using the patch-clamp technique. Outer membranes from a mutant lacking the major lipoprotein (Lpp) and its wild-type parent were examined. The MS-channel activities in the wild-type membrane rarely revealed substates at the time resolution used. These channels showed a stretch sensitivity indicated by the 1/Sp (the suction for an e-fold increase in channel open probability) of 4.9 mm Hg suction. The MS-channel activities of lpp included a prominent substrate and showed a weaker mechanosensitivity with an 1/Sp of 10.0 mm Hg. Whereas small amphipaths (chlorpromazine, trinitrophenol) or a larger amphipath (lysolecithin) all activated the MS channel in the wild-type membrane under minimal suction, only the larger lysolecithin could activate the MS channel in the lpp membranes. After lysolecithin addition, the lpp membrane became more effective in transmitting the stretch force to the MS channel, as indicated by a steepening of the Boltzmann curve. We discuss one interpretation of these results, in which the major lipoprotein services as a natural amphipath inserted in the inner monolayer and the loss of this natural amphipath makes the bilayer less able to transmit the gating force.

In vivo Paramecium mutants show that calmodulin orchestrates membrane responses to stimuli.

Paramecium generates a Ca2+ action potential and can be considered a one-cell animal. Rises in internal [Ca2+] open membrane channels that specifically pass K+, or Na+. Mutational and patch-clamp studies showed that these channels, like enzymes, are activated by Ca(2+)-calmodulin. Viable CaM mutants of Paramecium have altered transmembrane currents and easily recognizable eccentricities in their swimming behavior, i.e. in their responses to ionic, chemical, heat, or touch stimuli. Their CaMs have amino-acid substitutions in either C- or N-terminal lobes but not the central helix. Surprisingly, these mutations naturally fall into two classes: C-lobe mutants (S101F, I136T, M145V) have little or no Ca(2+)-dependent K+ currents and thus over-react to stimuli. N-lobe mutants (E54K, G40E+D50N, V35I+D50N) have little or no Ca(2+)-dependent Na+ current and thus under-react to certain stimuli. Each mutation also has pleiotropic effects on other ion currents. These results suggest a bipartite separation of CaM functions, a separation consistent with the recent studies of Ca(2+)-ATPase by Kosk-Kosicka et al. [41, 55]. It appears that a major function of Ca(2+)-calmodulin in vivo is to orchestrate enzymes and channels, at or near the plasma membrane. The orchestrated actions of these effectors are not for vegetative growth at steady state but for transient responses to stimuli epitomized by those of electrically excitable cells.

Primary mutations in calmodulin prevent activation of the Ca(++)-dependent Na+ channel in Paramecium.

Paramecium tetraurelia behavioral mutant cam12 displays a "fast-2" behavioral phenotype: it fails to respond to Na+ stimuli. Electrophysiologically, it lacks a Ca(++)-dependent Na+ current. Genetics and DNA sequencing showed the primary defect of cam12 to be in the calmodulin gene (Kink et al., 1990). To correlate calmodulin structure and function in Paramecium, we elucidated the primary structure of cam12 calmodulin. Peptide sequencing confirmed the two point mutations predicted by the DNA sequence: a glycine-to-glutamate substitution at position 40 and an aspartate-to-asparagine substitution at position 50. Our results further showed that lysine 13 and lysine 115 were methylated normally in cam12. It is likely that the electrophysiological abnormalities of cam12 are a direct reflection of the amino-acid substitutions, as opposed to improper posttranslational modification.

Efficient expression of the Paramecium calmodulin gene in Escherichia coli after four TAA-to-CAA changes through a series of polymerase chain reactions.

We have expressed the Paramecium calmodulin gene in Escherichia coli by changing the four TAA codons in this gene to CAAs. This was carried out by three polymerase chain reactions (PCRs) and then cloning the product into the expression vector pKK223-3 immediately downstream of its trp-lac hybrid promoter. JM109 strain of E. coli, transformed with the recombinant plasmid harboring the altered Paramecium calmodulin gene, produces a protein judged to be calmodulin. It is recognized by a monoclonal antibody to Paramecium calmodulin; it migrates with the native protein at nearly the same rate in electrophoreses; and it shows a Ca(2+)-dependent shift in electrophoretic pattern. The production of calmodulin is about 170 times as efficient with E. coli as with Paramecium in terms of unit volume of packed cells, and is about 400 times as efficient in unit volume of liquid culture. This method appears useful in site-directed mutageneses and in the heterologous productions of other ciliate proteins. A critique of this method is provided. A calmodulin half-molecule, a by-product of this project, is described.

Calmodulin activation of calcium-dependent sodium channels in excised membrane patches of Paramecium.

Calmodulin is a calcium-binding protein that participates in the transduction of calcium signals. The electric phenotypes of calmodulin mutants of Paramecium have suggested that the protein may regulate some calcium-dependent ion channels. Calcium-dependent sodium single channels in excised patches of the plasma membrane from Paramecium were identified, and their activity was shown to decrease after brief exposure to submicromolar concentrations of calcium. Channel activity was restored to these inactivated patches by adding calmodulin that was isolated from Paramecium to the cytoplasmic surface. This restoration of channel activity did not require adenosine triphosphate and therefore, probably resulted from direct binding of calmodulin, either to the sodium channel itself or to a channel regulator that was associated with the patch membrane.

Mutations in paramecium calmodulin indicate functional differences between the C-terminal and N-terminal lobes in vivo.

We examined calmodulin and its gene from the wild-type and viable mutants of P. tetraurelia. The mutants, selected for their behavioral aberrations, have little or no defects in growth rates, secretion, excretion, or motility. They can be grouped according to whether they underreact or overreact behaviorally to certain stimuli, reflecting their respective loss of either a Ca2(+)-dependent Na+ current or a Ca2(+)-dependent K+ current. Sequence analyses showed that all three underreactors have amino acid substitutions in the N-terminal lobe of the calmodulin dumbbell, whereas all three overreactors have substitutions in the C-terminal lobe. No mutations fell in the central helix connecting the two lobes. These results may indicate that the sites defined by these mutations are important in membrane excitation but not in other biological functions. They also suggest that the two lobes of calmodulin may be used differentially for the activation of different Ca2(+)-dependent channels.

Polyethylene glycol 900 permeability of rat intestinal and colonic segments in vivo and brush border membrane vesicles in vitro.

Increased intestinal absorption of medium-sized aqueous probes has been found in patients with a variety of disorders. We studied the physiologic control mechanisms, intestinal regions, and effects of lumenal factors on the intestinal absorption of polyethylene glycol (PEG) 900 in the rat in vivo and in rabbit brush border membrane vesicles (BBMVs). The kinetics of PEG 900 intestinal absorption were compatible with simple passive diffusion. Because transport across BBMVs was minimal, we concluded that transport of PEG 900 is mostly through the paracellular tight junctions. Absorption was highest in the midcolon (104.3 +/- 9.5 mumol/100 mg protein per hour vs 9.1 +/- 1.2 mumol/100 mg protein per hour in the jejunum). Absorption was decreased by higher lumenal osmolarity (greater than 400 mOsm/L) after the additions of 2.5 to 5.0 mmol/L chenodeoxycholate or 2.5 mmol/L lysolecithin, or at higher lumenal flow rates (greater than 1 ml/minute), higher lumenal pressure (7.5 cm H2O),or higher lumenal pH (8.0). Lipid solubility of PEG 900 was less than 0.00079%. Under all experimental conditions, PEG net absorption followed changes in water transport. When water transport changed from absorption to secretion, PEG absorption decreased. When water absorption increased, PEG 900 absorption increased in parallel. We conclude that PEG 900 is absorbed by passive diffusion that is modulated by solvent drag and is maximal in the midcolon. Transport directly across cell membranes is mimimal, but overall PEG 900 permeability is closely linked to water absorption by solvent drag and takes place primarily through the paracellular junctions. We propose that these features and mechanisms of PEG 900 transport make PEG 900 a suitable probe molecule for studying intestinal permeability changes.

Mechanisms of linoleic acid uptake by rabbit small intestinal brush border membrane vesicles.

We examined the initial transport of a long-chain unsaturated fatty acid, linoleic acid, by brush border membrane vesicles isolated from rabbit small intestine. This preparation allowed us to examine the transport of linoleic acid across the brush border membrane without the effect of the unstirred water layer or cytosol binding proteins. Linoleic acid was solubilized in a 2 mM taurocholate solution which did not compromise the functional integrity of the vesicles. Linoleic acid uptake in the range of 1 to 100 microM followed passive diffusion kinetics. Time course study showed that linoleic acid uptake reached maximal levels during the initial 15 seconds. Although the amount of linoleic acid accumulated in the vesicles diminished over the next 30 minutes, the molar quantity was still twentyfold higher than that of D-glucose (6.5 vs 0.33 nmol/mg protein). Uptake of D-glucose by the vesicles demonstrated typical osmotic responsiveness. We found no osmotic effect on linoleic acid uptake. Hypotonic lysis of membrane vesicles loaded with linoleic acid released 40% of the fatty acid. We concluded that a major portion of the accumulated fatty acid was bound to or incorporated into the membrane itself while ca. 40% did traverse the membrane and accumulated in the intravesicular space as nonmicellar aggregates. The known inhibitors of anion transport, diisothiocyanatostilbene and isothiocyanatostilbene did not change the transport of linoleic acid. We conclude that, in the absence of an unstirred layer or cytosol proteins, linoleic acid transport at up to 100 microM concentration is passive with rapid accumulation both by the cell membrane and the lumen of vesicles.

Mechanisms of carrageenan injury of IEC18 small intestinal epithelial cell monolayers.

Hydrolyzed carrageenan is used to induce ileocecal inflammation in laboratory animals. We used ileal epithelial cell monolayer cultures (IEC18) to study the cellular and paracellular injurious effects of hydrolyzed carrageenan via an examination of its effects on deoxyribonucleic acid synthesis, chromium release, and cell morphology. Phase-contrast microscopy showed that carrageenan-treated cells initially contracted and pulled away from neighboring cells. Cell and viability counts illustrated that hydrolyzed carrageenan retarded cell growth and eventually caused cell death. [3H]Thymidine incorporation revealed that hydrolyzed carrageenan at a concentration of 0.25 g/L inhibited deoxyribonucleic acid synthesis by 20% during a 5-h labeling period in 1-wk-old confluent monolayers. Chromium 51 release assay demonstrated that a 22-h exposure to 0.75 g/L of hydrolyzed carrageenan induced the release of 30% of the 51Cr trapped in 1-wk-old confluent monolayers. Scanning electron microscopy showed that the disruption of cellular junctions occurred before cell membrane injury. When we treated the monolayers with drugs commonly used for the treatment of inflammatory bowel disease, including prednisolone, 5-aminosalicylic acid, metronidazole, and 6-mercaptopurine, we were not able to demonstrate a reduction in carrageenan-induced cell injury; however, catalase at 1 mg/ml decreased carrageenan cytotoxicity. These studies demonstrate that hydrolyzed carrageenan produces intestinal epithelial injury in a time- and dose-dependent fashion. Morphologic injury starts at the site of cell junctions and eventually affects cell membrane integrity. Drugs commonly used to treat inflammatory bowel disease do not inhibit carrageenan injury in this cell model system, although catalase does decrease injury.

Induction of nephrotoxicity by high doses of gentamicin in diabetic rats.

Rats with streptozotocin-induced diabetes mellitus (DM) are resistant to aminoglycoside (AG) nephrotoxicity presumably because of defective transport and accumulation of drug by proximal tubular cells. To test this hypothesis we injected DM rats with saline or with gentamicin, 100, 200, and 400 mg/kg per day for 6 days, to determine if the renal cortical concentration of gentamicin could be raised to toxic levels. Nephrotoxicity was assessed by monitoring for evidence of accelerated lipid peroxidation in the renal cortex, for elevation of the serum creatinine concentration, and for evidence of proximal tubular cell injury and necrosis by light and electron microscopy. At 100 mg/kg per day renal cortical gentamicin was 454 +/- 85 micrograms/g. Except for an increase in renal cortical phospholipids these rats manifested no evidence of accelerated lipid peroxidation or elevation of serum creatinine. At 200 mg/kg per day renal cortical gentamicin rose to 636 +/- 20 micrograms/g. These rats manifested mild functional and morphological evidence of toxicity. At 400 mg/kg renal cortical gentamicin rose to 741 +/- 43 micrograms/g. These rats developed severe nephrotoxic injury as manifested by a marked increase of lipid peroxidation evident by an increase of malondialdehyde from a control level of 0.48 +/- 0.02 to 1.72 +/- 0.12 nmole/mg protein, a shift from unsaturated to saturated fatty acids esterified in renal cortical phospholipids, depression of superoxide dismutase and catalase, and a shift from reduced to oxidized glutathione. The serum creatinine rose from a baseline level of 0.24 +/- 0.01 to 0.46 +/- 0.05 mg/dl. Light and electron microscopy revealed enlarged lysosomes distended with typical myeloid bodies and extensive proximal tubular cell necrosis. These observations provide compelling evidence in support of the view that the resistance of DM rats to AG nephrotoxicity is causally linked to the low rate of drug uptake by renal proximal tubular cells. When the renal cortical concentration reaches a critical level, it elicits a pattern of toxic injury indistinguishable from that of nondiabetic rats. Thus, there is nothing inherent to the diabetic state that prevents AGs from causing their usual adverse effects on the metabolism of renal proximal tubular cells once they gain access in sufficient quantity into these cells.