SJL and NOD macrophages are uniquely characterized by genetically programmed, elevated expression of the IL-12(p40) gene, suggesting a conserved pathway for the induction of organ-specific autoimmunity.

Genetic susceptibility of the SJL mouse to experimental autoimmune encephalomyelitis (EAE) appears, in part, to be a result of genes that promote abnormal development of the pathogenic Type 1 (Th1) phenotype of neuroantigen-specific T-cells. Because antigen-presenting/accessory cells (APCs) produce cytokines that can modulate the development of Th1 and Th2 phenotypes, we addressed whether APCs from SJL mice were genetically programmed for elevated expression of the Th1-promoting cytokine, IL-12. Activated peritoneal macrophages (Mphi; i.e., APC) from naïve SJL mice produced levels of TNF-alpha, IL-1, IL-6, IL-10, and TGF-beta within the range of six normal strains. In contrast, SJL IL-12p40 (in addition to IL-12p70) production was consistently five- to 20-fold greater than that of any normal strain tested, which arose from elevated expression of the IL-12p40 but not the IL-12p35 gene, because p40 mRNA levels were eight- to 15-fold greater than those of normal strains. This aberrancy in IL-12p40 expression appears identical to that observed in the NOD mouse, another strain prone to organ-specific autoimmunity. A genetically programmed bias toward elevated expression of IL-12 in Mphi from the SJL and NOD strains of autoimmunity provides a conserved mechanism for the dominant Th1 development of naive, autoantigen-specific T-cells in these strains. This study is the first demonstration of a genetically programmed aberrant phenotype that is intrinsically expressed within a cell type in the SJL mouse and provides insight into its predisposition for EAE.

Aberrant macrophage cytokine production is a conserved feature among autoimmune-prone mouse strains: elevated interleukin (IL)-12 and an imbalance in tumor necrosis factor-alpha and IL-10 define a unique cytokine profile in macrophages from young nonobese diabetic mice.

Cytokines derived from macrophages (Mø) play a critical role in the development of type 1 diabetes in the nonobese diabetic (NOD) mouse. Based on earlier findings from lupus-prone strains of inherent cytokine defects in Mø , NOD Mø were evaluated for intrinsically dysregulated cytokine production with the potential to initiate or exacerbate disease. Endotoxin-activated peritoneal Mø from young prediseased NOD mice produced interleukin (IL)-1 and tumor necrosis factor (TNF)-alpha levels similar to those of Mø from a panel of control strains but reduced compared with the congenic diabetes-resistant NOR strain. IL-6 and IL-10 production were similar in NOD and NOR Mø, indicating that reduction in NOD IL-1 and TNF-alpha expression was selective. Nevertheless, the ratio of TNF-alpha and IL-10 production, a stringent index of normal Mø function, distinguished NOD from all normal strains. The most striking feature of NOD Mø, however, was their substantially elevated IL-12 production. This response was induced not only by endotoxin but also by bacillus Calmette-Guerin (BCG) and CD40 ligand and was associated with (and likely caused by) the enhanced and prolonged expression of p40 mRNA. Moreover, NOD Mø IL-12 expression appeared to be near maximally induced by lipopolysaccharide (LPS) alone, because it was only slightly enhanced by the addition of gamma-interferon, a stimulus that substantially elevated LPS-induced IL-12 production in Mø from normal strains. Accompanied by a unique profile of TNF-alpha and IL-10, the dramatic elevation of IL-12 expression by NOD Mø reflects intrinsic defects of the innate immune system with the potential to initiate and propagate the pathogenic autoreactive T-helper type 1 response characteristic of type 1 diabetes.

Topological analysis of the MraY protein catalysing the first membrane step of peptidoglycan synthesis.

The two-dimensional membrane topology of the Escherichia coli and Staphylococcus aureus MraY transferases, which catalyse the formation of the first lipid intermediate of peptidoglycan synthesis, was established using the beta-lactamase fusion system. All 28 constructed mraY-blaM fusions produced hybrid proteins. Analysis of the ampicillin resistance of the strains with hybrids led to a common topological model possessing 10 transmembrane segments, five cytoplasmic domains and six periplasmic domains including the N- and C-terminal ends. The agreement between the topologies of E. coli and S. aureus, their agreement to a fair extent with predicted models and a number of features arising from the comparative analysis of 25 orthologue sequences strongly suggested the validity of the model for all eubacterial MraYs. The primary structure of the 10 transmembrane segments diverged among orthologues, but they retained their hydrophobicity, number and size. The similarity of the sequences and distribution of the five cytoplasmic domains in both models, as well as their conservation among the MraY orthologues, clearly suggested their possible involvement in substrate recognition and in the catalytic process. Complementation tests showed that only fusions with untruncated mraY restored growth. It was noteworthy that S. aureus MraY was functional in E. coli. An increased MraY transferase activity was observed only with the untruncated hybrids from both organisms.

Role of the ortholog and paralog amino acid invariants in the active site of the UDP-MurNAc-L-alanine:D-glutamate ligase (MurD).

To evaluate their role in the active site of the UDP-N-acetylmuramoyl-L-alanine:D-glutamate ligase (MurD) from Escherichia coli, 12 residues conserved either in the Mur superfamily [Eveland, S. S., Pompliano, D. L., and Anderson, M. S. (1997) Biochemistry 36, 6223-6229; Bouhss, A., Mengin-Lecreulx, D., Blanot, D., van Heijenoort, J., and Parquet, C. (1997) Biochemistry 36, 11556-11563] or in the sequences of 26 MurD orthologs were submitted to site-directed mutagenesis. All these residues lay within the cleft of the active site of MurD as defined by its 3D structure [Bertrand, J. A., Auger, D., Fanchon, E., Martin, L., Blanot, D., van Heijenoort, J., and Dideberg, O. (1997) EMBO J. 16, 3416-3425]. Fourteen mutant proteins (D35A, K115A, E157A/K, H183A, Y194F, K198A/F, N268A, N271A, H301A, R302A, D317A, and R425A) containing a C-terminal (His)(6) extension were prepared and their steady-state kinetic parameters determined. All had a reduced enzymatic activity, which in many cases was very low, but no mutation led to a total loss of activity. Examination of the specificity constants k(cat)/K(m) for the three MurD substrates indicated that most mutations affected both the binding of one substrate and the catalytic process. These kinetic results correlated with the assigned function of the residues based on the X-ray structures.

Determination of the MurD mechanism through crystallographic analysis of enzyme complexes.

UDP -N- acetylmuramoyl- L -alanine: D -glutamate (MurD) ligase catalyses the addition of d -glutamate to the nucleotide precursor UDP -N- acetylmuramoyl- L -alanine (UMA). The crystal structures of three complexes of Escherichia coli MurD with a variety of substrates and products have been determined to high resolution. These include (1) the quaternary complex of MurD, the substrate UMA, the product ADP, and Mg2+, (2) the quaternary complex of MurD, the substrate UMA, the product ADP, and Mn2+, and (3) the binary complex of MurD with the product UDP - N- acetylmuramoyl- L -alanine- D -glutamate (UMAG). The reaction mechanism supported by these structures proceeds by the phosphorylation of the C-terminal carboxylate group of UMA by the gamma-phosphate group of ATP to form an acyl-phosphate intermediate, followed by the nucleophilic attack by the amino group of D-glutamate to produce UMAG. A key feature in the reaction intermediate is the presence of two magnesium ions bridging negatively charged groups.

Intrinsic defects in macrophage IL-12 production associated with immune dysfunction in the MRL/++ and New Zealand Black/White F1 lupus-prone mice and the Leishmania major-susceptible BALB/c strain.

We have demonstrated that macrophages (Mphi) from young, prediseased, lupus-prone MRL/++ and New Zealand Black/White F1 mice display defective production of TNF-alpha, IL-1, and IL-6, but normal production of IL-10. In an attempt to determine the potential functional implications of this phenotype for autoimmunity, we demonstrate here that endotoxin-activated Mphi from these lupus-prone mice showed dramatically reduced expression of IL-12, a cytokine essential for Th1 responses that may be defective during lupus. IL-12 production was also reduced by Mphi from the control BALB/c strain, compatible with the concept that a genetically programmed deficit in IL-12 levels may underlie the IL-4-dominated BALB/c response to infection by the parasite Leishmania major. Although both IL-12 and TNF-alpha expression defects by Mphi from lupus-prone strains are expressed rapidly after activation, treatment with each cytokine demonstrated that only TNF-alpha contributes to the subsequent dysregulation of Mphi IL-1 and IL-6 expression in these strains, and that the reduced autocrine activity of defective IL-12 or TNF-alpha levels was not causal to each other. Although the intrinsic defect in IL-12 expression by lupus-prone and BALB/c Mphi may lead to defective Th1 responses, these Mphi responded to the Th1-derived cytokine, IFN-gamma, in a normal fashion suggesting a defective role in the induction, rather than the propagation, of Th1 responses in these mice. Our finding of a conserved intrinsic defect in IL-12 production by Mphi from the two principal mouse models of multigenic lupus provides insight into how excessive humoral responses may develop, and perhaps be prevented, in systemic autoimmune disease.

Adhesion elicits an intrinsic defect in interleukin-1 expression by macrophages from autoimmune-prone MRL mice.

Macrophages (m phi) from prediseased autoimmune-prone MRL/+ and MRL/ lpr mice have a marked defect in endotoxin (LPS)-induced expression of several cytokines including interleukin 1 (IL-1). The progressive nature of this defect over time suggests that it may develop in response to specific extracellular stimuli. In this report, we show that adhesion is an essential factor for the development of aberrant IL-1 expression by m phi from autoimmune-prone MRL mice. Thus, when MRL/+ m phi were allowed to adhere before being stimulated with LPS, they demonstrated a striking defect in expression of both IL-1 message and protein in comparison with multiple normal strains. In marked contrast, when MRL/+ m phi were maintained in a non-adherent state by culture on agarose, the IL-1 defect was not evident and IL-1 expression was restored to nearly normal levels. Since an identical defect in IL-1 expression was found when MRL/+ m phi were cultured on a variety of extracellular matrix proteins (including laminin, fibronectin, type I collagen, and type IV collagen), it appears that IL-1 underexpression is dependent on the adhesive state per se rather than on engagement of any one specific adhesion receptor. Moreover, the cytoskeletal inhibitor cytochalasin D had no effect on the magnitude of the defect, indicating that the adhesion-dependent signaling events necessary to elicit IL-1 underexpression are independent of cytoskeletal rearrangement. Taken together, these results indicate that m phi from autoimmune prone MRL/+ mice have an adhesion-dependent signaling abnormality that leads to profound underexpression of the cytokine IL-1.

Lymphokine regulation of activation-induced apoptosis in T cells of IL-2 and IL-2R beta knockout mice.

Recent studies using IL-2R alpha knockout mice have generated conflicting results regarding the hypothesis that IL-2/IL-2R interaction is obligatory for the development of AICD, which plays a central and pivotal role in maintaining peripheral tolerance. A relevant consequence of AICD defect is the demonstrated development of autoimmune lymphoproliferative disease in IL-2, IL-2R alpha, and IL-2R beta knockout mice, but not in IL-4, IL-7, or IL-7R knockout mice. Whether IL-4, IL-7, or IL-15 can provide the required signal for AICD development is addressed here using IL-2 and IL-2R beta knockout mice. Lymph node T cells from knockout mice were stimulated with Con A plus rIL-1 for 3 days and then maintained in high concentrations of rIL-4, rIL-7, or rIL-15 for an additional 3 days before they were subjected to AICD analysis. Our study demonstrates that IL-4, IL-7, and IL-15 can transduce signals critical for AICD development in the absence of IL-2-mediated signals. The requirement for relatively high concentrations of these lymphokines suggests their limited role in maintaining peripheral T cell tolerance, thus explaining the differential expression of autoimmune lymphoproliferative disease in the targeted mutant strains described above.

IL-15 functions as a potent autocrine regulator of macrophage proinflammatory cytokine production: evidence for differential receptor subunit utilization associated with stimulation or inhibition.

The cytokine IL-15 appears to mimic the stimulatory activity of IL-2 on lymphocytes by utilizing part of the IL-2R complex. Although effects of IL-15 on Mphi activities have not previously been reported, its derivation from activated Mphi suggested a possible autocrine role in regulating Mphi functions and prompted us to determine whether IL-15 modulated LPS-activated Mphi cytokine production. Whereas high IL-15 concentrations enhanced proinflammatory (i.e., TNF-alpha, IL-1, and IL-6) and anti-inflammatory (i.e., IL-10) cytokine production by two- to sixfold, extremely low IL-15 concentrations (picomolar to attomolar range) markedly and selectively suppressed Mphi proinflammatory, but not anti-inflammatory, cytokine production by two- to fourfold. The stimulation (but not the suppression) of TNF-alpha production by IL-15 required the (IL-2/IL-15) receptor beta chain, as demonstrated by receptor subunit-blocking studies and lack of stimulation of Mphi from IL-2Rbeta-deficient mice. Conversely, suppression most likely involved the alpha receptor (IL-15R alpha) because this high affinity receptor would be engaged by low concentrations of IL-15, and its inducible expression correlated with the degree of suppression in both a time- and LPS dose-dependent fashion. Moreover, Ab-mediated neutralization studies revealed that endogenous IL-15 activity regulated Mphi activation with kinetics similar to that seen in response to exogenously added IL-15: suppressor activity increased over time in correlation with IL-15R alpha gene expression. This study demonstrates a novel dose-dependent and autocrine activity of IL-15 in Mphi regulation.

Aberrant cytokine expression and autocrine regulation characterize macrophages from young MRL+/+ and NZB/W F1 lupus-prone mice.

We investigated whether macrophages (Mphi) from young, lupus-prone MRL+/+ and NZB/W F1 mice expressed common defects in immunoregulatory cytokine production. Endotoxin-activated Mphi from both strains, obtained well before disease signs, had a markedly reduced capacity to maintain IL-1 production compared with Mphi from normal strains (BALB/c, A/J, and C57BL/6). Mphi from lupus-prone mice showed similar defects in IL-6 and TNF-alpha production, which preceded the IL-1 defect. In fact, defective TNF-alpha production appeared to be responsible for aberrant expression of the other cytokines because this defect was the first to be expressed, and treatment with exogenous TNF-alpha reduced the extent of defective IL-1 and IL-6. These "proinflammatory" cytokine defects appeared to be selective because the anti-inflammatory cytokine IL-10 was not expressed aberrantly in the lupus-prone strains. For this reason, and because anti-IL-10 mAb treatment did not correct defective proinflammatory cytokine production, IL-10 did not appear to be responsible for these defects. IFN-gamma was able to normalize TNF-alpha production in Mphi from lupus-prone mice, demonstrating a stimulus-specific induction of the proinflammatory defects. These studies also revealed that Mphi from the three normal strains studied here maintain a precise inverse relationship between levels of TNF-alpha and IL-10, a relationship not seen in Mphi from lupus-prone strains. These findings reveal shared elements of cytokine dysregulation in the two principal animal models of multigenic lupus, and suggest that the study of Mphi (and perhaps other cells of the innate immune system) may provide valuable insights into intrinsic functional defects associated with systemic autoimmunity.

Endogenous substance P mediates cold water stress-induced increase in interleukin-6 secretion from peritoneal macrophages.

Previous studies from this laboratory had shown that exposure of mice to cold water stress leads to an increase in the secretion of interleukin-1 (IL-1) and tumor necrosis factor-alpha (TNF alpha) from their peritoneal macrophages. We now report that the secretion of IL-6 from peritoneal macrophages is also increased after cold water stress and that the peptide substance P (SP) participates in this stress-induced response. The stress paradigm involved subjecting male C57BL/6J mice to 5 min swim tests in 10 +/- 2 degrees C water twice daily for 4 d. Cold water stress augments the lipopolysaccharide-induced IL-6 secretion from peritoneal macrophages, elevates immunoreactive SP (iSP) in the peritoneal wash fluid, and reduces iSP in certain peritoneum-containing tissues or organs (i.e., diaphragm, abdominal wall, ileum, and rectum). The 10 d stress time studies indicate that increased IL-6 secretion is positively related to elevated iSP in the peritoneal wash fluid and inversely related to reduced iSP in certain peritoneum-containing tissues. Pretreatment with capsaicin, which depletes SP in the sensory nerve endings, eliminates stress-control differences in the peritoneal wash fluid and in certain peritoneal tissues. Moreover, RP67,580, a specific SP antagonist, eliminates the cold water stress-induced augmentation of IL-6 secretion from peritoneal macrophages. These results suggest that cold water stress promotes the release of SP from peritoneal tissues into the peritoneal cavity, where it participates in the cold water stress-induced macrophage functional alterations.

Dysregulated cytokine expression in vivo in prediseased and diseased autoimmune-prone MRL mice.

Macrophages (mø) from prediseased autoimmune-prone MRL/ + and MRL/lpr mice produce markedly decreased levels of IL-1 in vitro in response to LPS. In contrast, tissues from diseased MRL/lpr mice overexpress IL-1 in vivo. To determine whether IL-1 underproduction in the MRL strains is solely an in vitro phenomenon, we compared in vivo cytokine mRNA expression from prediseased age-matched MRL/ + and MRL/lpr mice to that from normal BALB/c and C3HeB/FeJ mice. Like mø in vitro, whole organ RNA from the spleen, liver, and kidney of MRL/ + and MRL/lpr mice showed down-regulation of IL-1 RNA following intraperitoneal injection of LPS. This abnormality in inducible IL-1 expression was present in all MRL mice, irrespective of disease stage or the presence of the lpr gene. On the other hand, only diseased MRL/lpr mice displayed elevated and constitutive expression of IL-1 in their livers and kidneys. We suggest that inducible expression is most indicative of the intrinsic, or genetic, capacity of cells to produce cytokine, whereas constitutive expression reflects extracellular disease-related inflammatory stimuli present only in the diseased MRL/lpr strains. By restricting our studies to prediseased MRL mice, we have tried to eliminate the effects of disease and to focus on the predisposing genetic background. The existence both in vitro and in vivo of a defect in inducible IL-1 expression by prediseased MRL mice suggests that the molecular abnormality underlying this defect may be a part of this predisposing background to autoimmunity.

Substance P and stress-induced changes in macrophages.

The present paper further links nervous-endocrine-immune systems by describing influences of SP on the immune system, and more specifically, on macrophage function. We have discussed how macrophages are important to immune responses in that much of cellular and humoral responses depend on macrophage function. Macrophages are sensitive to stress in that cold-water stress causes increased cytokine production, either spontaneously (IL-1), or after induction with LPS (IL-6, TNF alpha). Increased cytokine levels (IL-1, IL-6) may induce acute phase reactants in the liver, which is presumably the mechanism operative in the studies indicating increases in acute phase reactants after certain stressors in animals. SP is a likely candidate to affect immune function. Previous data show that macrophages from various species have receptors for and respond to SP in vitro. SP stimulates phagocytic and chemotactic capacity, as well as increased cytokine, PGE2, and thromboxane B2 production. SP is also involved in neurogenic inflammation and is likely to be involved in the pathogenesis of several inflammatory diseases. Present data indicate SP's involvement in macrophage responses to stress. We have shown that stress induced differential SP receptor binding to peritoneal macrophages, although the precise nature of binding differences has not yet been clearly elucidated. Stress also induces more immunoreactive SP in the peritoneal fluid that bathes the peritoneal macrophages. We hypothesize that the two events, altered SP binding and concomitant increased ligand, are causally related. In addition to other correlational data showing concomitant increased SP binding plus ligand concentrations, there is more direct evidence that SP ligand may induce SP receptor expression since the SP antagonist, CP-96,345, prevents the induction of SP receptor mRNA in the staphylococcal toxin A-induced gastroenteritis (C. Pothoulakis and S. E. Leeman, personal communication). Further supporting our notion for a causal relationship we have found the elimination of SP in vivo (via capsaicin pretreatment) reduced SP binding, as has been previously reported. We have also examined the role of SP on stress-induced altered macrophage function in vitro. SP greatly enhanced the LPS-induced macrophage TNF alpha production from stressed animals; in contrast, it produced relatively little effect on macrophages from control animals. Capsaicin pretreatment diminished the enhanced cytokine production in response to stress, such that levels of TNF alpha and IL-6 approximated those of control mice. Taken together, past and present data suggest that (1) stress may initiate, or at least contribute to, an inflammatory response, and that (2) SP is involved in the macrophage stress response. SP has long been known to be involved in inflammatory processes; our data further suggest its role in mediating stress-induced cytokine alterations.

Aberrant cytokine regulation in macrophages from young autoimmune-prone mice: evidence that the intrinsic defect in MRL macrophage IL-1 expression is transcriptionally controlled.

We have reported that, when compared to macrophages from normal strains, macrophages from the autoimmune-prone MRL and NZB mouse strains demonstrate dramatically reduced IL-1 expression in response to LPS. In MRL mice, this is an intrinsic defect which is unmodified by age, the progression of disease, or the presence of the Ipr gene. Here we report that the key events leading to aberrant IL-1 expression appear to be transcriptional, based on the following three sets of findings. (1) Nuclear run-on analysis demonstrates that the patterns of IL-1 transcription in MRL/+ and BALB/c macrophages are distinct, as the former is clearly more transient. The reduction in MRL/+ IL-1 transcription coincides with a reduction in the levels of nuclear NF-KB and precedes a drop in IL-1 mRNA steady-state levels. (2) Reduced levels of IL-1 transcripts are found in both nuclear and cytosolic fractions of MRL/+ macrophages, arguing against faculty IL-1 mRNA transport into the cytosol as a contributing factor in the establishment of this defect. (3) In the presence of actinomycin D, the rate of RNA degradation is similar in MRL/+ and BALB/c macrophages. Moreover, in vitro RNA decay assays demonstrate that even in the absence of metabolic inhibitors, there is no evidence for an accelerated decay of IL-1 mRNA during exposure to lysates isolated from MRL/+ vs BALB/c macrophages. Taken together, these findings argue that transcription is the predominant level at which this striking example of cytokine dysregulation is controlled.

Enzymatic glucosylation of hydrophobic alcohols in organic medium by the reverse hydrolysis reaction using almond-beta-D-glucosidase.

Alkyl beta-D-glucosides were synthesized from D-glucose and alcohols by reverse hydrolysis using the commercially available almond beta-D-glucosidase in 9:1 (v/v) acetonitrile-water medium. The main characteristics of this enzyme-catalyzed glucosylation were established by using 2-hydroxybenzyl alcohol. The reaction is entirely regio- and stereoselective. The solvent plays a fundamental role because, by decreasing the water concentration in the medium, the shift of the reaction equilibrium toward synthesis is realized without using an excessive amount of alcohol. Nevertheless, a minimum amount of water is necessary to maintain the enzyme activity. In contrast to the use of the enzyme in aqueous medium, the pH of the added water in acetonitrile did not influence the synthesis. Using this procedure, we have conducted systematic glucosylation of numerous alcohols and we have investigated enzyme specificity and alcohol reactivity. The enzyme has a pronounced affinity for the alcohols containing a phenyl group, and enantioselectivity for the aglycon is obtained with 1-phenylethyl alcohol. Moreover, by using almond beta-D-glucosidase it was also possible to synthesize alkyl beta-D-galactosides. (c) 1995 John Wiley & Sons, Inc.

Cytokine dysregulation and the initiation of systemic autoimmunity.

Autoimmunity (AI) exemplifies the potent and destructive activity expressed by the immune system when normal constraints against self-reactivity are lost or compromised. We have previously described a dramatic and intrinsic defect in cytokine expression in macrophages (M phi) from young AI-prone mice [1-3]. There are two points in particular that we believe speak to the importance of this observation: (i) Cytokine dysregulation is distinguished from many of the aberrancies reported in AI-prone mouse strains in that, as an inherent trait, it cannot arise as a consequence of the disease process. (ii) This defect is a remarkably consistent characteristic of M phi from strains that develop manifestations of systemic AI, including MRL/+, NZB, NZB/W F1, BXSB, and NOD, and distinguishes these strains from mice whose disease is predicated on defects in apoptosis (e.g., the lpr and gld mutations). The multigenic basis for disease and renal pathology in the former strains more closely mirror human lupus than do the disease manifestations of lpr and gld mice. In light of clear evidence that cytokines are key mediators of lymphocyte growth and function, a defect in the cytokine network has the potential to disrupt the normal regulation of self-reactivity, leading to the initiation of systemic AI.

A comparison of isokinetic lifting strength with static strength and maximum acceptable weight with special reference to speed of lifting.

A laboratory study was conducted to determine the effects of the speed of lifting and box size on isokinetic strength and to compare isokinetic lifting strengths with static lifting strengths and psychophysically determined maximum acceptable weights. Nine male college students lifted three different boxes (250, 380 and 510 mm wide) from the floor to a bench height of 0.8 m using a free-style lifting technique at a rate of 0.2 lifts min-1. For each lifting task static strength was measured at the origin of lift. Isokinetic lifting strength was measured at 0.41, 0.51 and 0.6 ms-1 using a Biokinetic ergometer and attaching boxes to the load cell. Ratings of perceived exertion were recorded for the low back. There was a progressive decrease in mean and peak isokinetic lifting strengths both with an increase in lifting speed and with an increase in box width (p < 0.01). The lifting speed had a much greater effect (29% and 27%) than the box width (18% and 15%) on mean and peak isokinetic lifting strengths. However, high speed lifting was perceived subjectively to be less stressful (RPE = 10.7) than slow speed lifting (RPE = 12.7). Static strength and maximum acceptable weight had higher correlations with mean isokinetic strength (r = 0.65 and 0.82) than with peak isokinetic strength (r = 0.52 and 0.73). At 0.41 ms-1, mean isokinetic strength peak 6% greater than the mean static strength (p > or = 0.05). Extrapolation of mean isokinetic strength data showed that at 0.73 ms-1 the estimated mean isokinetic strengths were within 6% of maximum acceptable weights. It is concluded that isokinetic strength is highly dependent upon the speed of lifting. At a slow speed (0.41 ms-1), mean isokinetic strength is equal to mean static strength; and, at a high speed (0.73 ms-1), it appears to be equal to the maximum acceptable weight. It is recommended that both speed of lifting and box width should be controlled carefully to stimulate job-specific isokinetic lifting strength.

Interleukin-1 dysregulation is an intrinsic defect in macrophages from MRL autoimmune-prone mice.

Macrophages (M phi) from pre-diseased autoimmune-prone MRL mice (both MRL/+ and MRL/lpr) dramatically underproduce the cytokine interleukin-1 (IL-1) in comparison to M phi from a number of normal strains. In this study we show that IL-1 dysregulation by MRL M phi is fully expressed at birth, and that this defect does not change with time or the development of disease. We also constructed adult irradiation chimeras (consisting of A/J-->MRL and MRL-->A/J mice), and show that M phi isolated from these chimeras display a pattern of IL-1 production indistinguishable from that of the donor strain controls. Moreover, when we constructed a mixed chimera (A/J + MRL-->A/J, the A/J and MRL M phi coexisting within the same animal retained their individual patterns of IL-1 production when isolated by negative selection. Taken together, these results provide the first substantive evidence for an intrinsic defect (IL-1 dysregulation) in M phi from MRL autoimmune-prone mice.