Antibacterial Activity and Specificity of the Six Human {alpha}-Defensins

We developed a kinetic, 96-well turbidimetric procedure thatis capable of testing the antimicrobial properties of six human ${alpha}$ -defensins concurrently on a single microplate. The defensinswere prepared by solid-phase peptide synthesis and tested againstgram-positive bacteria (Staphylococcus aureus and Bacillus cereus)and gram-negative bacteria (Enterobacter aerogenes and Escherichiacoli). Analysis of the growth curves provided virtual lethaldoses (vLDs) equivalent to conventional 50% lethal doses (LD₅₀s),LD₉₀s, LD₉₉s, and LD_99.9s obtained from colony counts. On thebasis of their respective vLD₉₀s and vLD₉₉s, the relative potenciesof human myeloid ${alpha}$ -defensins against S. aureus were HNP2 >HNP1 > HNP3 > HNP4. In contrast, their relative potenciesagainst E. coli and E. aerogenes were HNP4 > HNP2 > HNP1= HNP3. HD5 was as effective as HNP2 against S. aureus and aseffective as HNP4 against the gram-negative bacteria in ourpanel. HD6 showed little or no activity against any of the bacteriain our panel, including B. cereus, which was highly susceptibleto the other five ${alpha}$ -defensins. The assay described provides aquantitative, precise, and economical way to study the antimicrobialactivities of host-defense peptides. Its use has clarified therelative potencies of human ${alpha}$ -defensins and raised intriguingquestions about the in vivo function(s) of HD6.

INTRODUCTION

Top

Introduction

Antimicrobial peptides, such as ${alpha}$ -defensins, are believed toplay substantial roles in the innate host defense against bacterial,fungal, and viral pathogens (3, 5, 24). Four of these peptides(HNP1 to HNP4) were initially isolated from human leukocytes(13). HNP1 to HNP3 differ only at the N-terminal position, whilethe other sequences are more diverse. Human defensin 5 (HD5)and HD6, which are synthesized in and secreted by intestinalPaneth cells, were discovered through genomic studies (2, 7,8). Because native HNP1, HNP2, and HNP3 are easily purifiedfrom leukocytes, they have been widely studied. As the othernative ${alpha}$ -defensin peptides have been recovered in amounts thatare small (HNP4), smaller (HD5), or nil (HD6), considerablyless is known about their properties.

A recent synthesis procedure has made all six human ${alpha}$ -defensinsavailable for in vitro analysis (22, 23). These advances areespecially significant for the characterization of HNP4, HD5,and HD6. To study the six ${alpha}$ -defensins described in this reportand to facilitate future studies of selectively modified defensinsthat we hope to perform in the future, we developed a facileway to assay their antimicrobial properties quantitatively.

Broth microdilution methods for the testing of antibiotics aretraditionally conducted in 96-well plates, ideally accordingto guidelines approved by the National Center for Clinical LaboratoryStandards (NCCLS) (15). Although such methods are simple toperform, their inherent precision is limited by the use of serialdilutions rather than a continuous calibration curve. Colonycounting procedures are considerably more labor intensive toset up and analyze. We refer to the alternative procedure describedbelow as "virtual colony counting" and to the CFU values thatit provides as "CFU_v." The virtual colony counting assay eliminatesthe multiple dilutions, spreading, and colony counting stepsrequired in actual colony counting assays. It provides datacomparable to colony counts from efforts commensurate with thoseneeded to set up broth microdilution assays.

Since the scientific underpinnings of the virtual colony countmethod are fairly obvious, it is surprising that it has notbeen applied previously. Brewster (1a) applied its principlesto formulate a microplate procedure to enumerate bacterial concentrationsas low as $~$ 10 CFU/ml. His assay, as well as the one describedhere, is based on the fact that the time required for the turbidity(optical density) of an inoculated well to reach an arbitrarythreshold value allows the number of viable bacteria in thatinoculum to be estimated from an appropriate growth calibrationcurve (1a). Because Brewster's procedure (1a), our assay, andtraditional colony counting procedures all enumerate only viablecells, in principle, all should be applicable to a wide varietyof physiologically disparate strains.

MATERIALS AND METHODS

Top

Materials and Methods

${alpha}$ -Defensins. All six human ${alpha}$ -defensins were synthesized by procedures basedupon an optimized Boc chemistry protocol developed by Kent andcolleagues (9, 17), as described in detail elsewhere (22, 23).Disulfide mapping of HNP1 to HNP3 (23) and the solution of theX-ray crystal structures of HNP4, HD5, and HD6 (Jacek Lubkowski,personal communication) unequivocally demonstrate correct foldingand disulfide connectivity. The concentrations of the pure finalproducts were determined spectroscopically by using molar extinctioncoefficients at 280 nm calculated by the algorithm of Pace etal. (15a), which takes into account amino acid variations.

Bacteria. Escherichia coli ATCC 25922, Staphylococcus aureus ATCC 25923,S. aureus ATCC 29213, and Enterobacter aerogenes ATCC 13048were from Becton-Dickinson (Sparks, Md.); Bacillus cereus ATCC10876 and E. coli ATCC 8739 were from MicroBioLogics (St. Cloud,Minn.) and Remel (Lenexa, Kans.), respectively. Mueller-Hinton(MH) broth (MHB) or MH II Agar (Becton Dickinson) was preparedin deionized water. A Millipore Milli-Q deionization systemwas used to prepare water for the buffers and peptides. Sterile,polystyrene, flat-bottom, 96-well tissue culture plates (3595;Costar) were used. Growth kinetics in the 96-well microplateswas monitored (as turbidity) with a computer-controlled V_maxplate reader (Molecular Devices, Sunnyvale, Calif.) runningSoftmax Pro software (version 3.1) and a 650-nm filter. Growthof the seed cultures was monitored on a Beckman DU-640 spectrophotometerby measuring the optical density at 650 nm (OD₆₅₀) of 1-ml samples.

Conversion of turbidity to number of CFU per milliliter. E. coli ATCC 25922 was grown overnight in 2 ml of MHB. An aliquotof the overnight culture was inoculated 1/100 into 25 ml ofMHB and incubated with shaking (250 rpm) at 37°C. When thisculture reached an OD₆₅₀ of 0.5, dilutions were plated in triplicateon MH agar, and colonies were counted the next day, yieldinga conversion factor of 5 x 10⁸ CFU/ml per OD₆₅₀ unit. For convenience,turbidity, not the initial cell concentration, was held constantamong the six strains, such that the cell "concentration" quantitiesof the other five strains corresponded to the concentrationthat E. coli ATCC 25922 would have produced at the same OD₆₅₀.Moreover, turbidity is a more appropriate basis of comparisonthan CFU, since turbidity should correlate more closely withthe amount of cytoplasmic membrane present. Membranes are thesubstrates of the lethal activity of defensins (3). If the numberof CFU had been held constant, the result would have been avariation in the amount of plasma membrane roughly proportionalto the variation in the surface-to-volume ratios among thesesix strains. To emphasize this distinction, the notation C'₀for the initial cell concentration has been introduced in placeof the C₀ defined by Brewster (1a) in the calculations below.

Growth of seed cultures. Single colonies from MH agar plates were inoculated into 2 mlof PMH (MHB with 5 mM sodium phosphate buffer [pH 7.4]). Afterovernight growth at 37°C, 250 µl of this culture wasadded to 25 ml of PMH in a 250-ml capped Erlenmeyer flask andgrown at 37°C with shaking (250 rpm) to an OD₆₅₀ of 0.45to 0.55.

Calibration. One milliliter of seed culture was added to 1.5 ml of PMH toprovide a suspension with $~$ 10⁸ CFU/ml. A 10-fold dilution seriesof this suspension ranging from 10⁷ to 10^–1 CFU/ml wasmade in PMH in sextuplicate. The final volume per well was 200µl. The last well in each row was a negative control thatcontained 200 µl of uninoculated PMH. The 60 internalwells (rows B to G and columns 2 to 11) contained the dilutionseries. The 36 edge wells (rows A and H and columns 1 and 12)contained 200 µl of uninoculated PMH to minimize evaporationfrom the internal wells and to control for contamination.

Bactericidal assay. A nine-step, twofold dilution series of synthetic human ${alpha}$ -defensinswas prepared in 10 mM sodium phosphate (pH 7.4) to provide concentrationsranging from 512 to 2.0 µg/ml. The final volume of thepeptide solutions placed in each well was 50 µl. The last(10th) well in each row was a negative control that contained50 µl of buffer. Cultures were serially diluted 125-foldin three steps (2.5-fold, then 5-fold, and then 10-fold) in10 mM sodium phosphate (pH 7.4). For E. coli ATCC 25922, thisresulted in 2 x 10⁶ CFU/ml in 10 mM sodium phosphate (pH 7.4).Fifty microliters was added to each of the 60 internal wells,resulting in a cell concentration of 10⁶ CFU/ml for E. coliATCC 25922. This addition resulted in final defensin concentrationsthat ranged from 256 to 1.0 µg/ml. The edge wells remainedempty. The plate was placed in a Molecular Devices V_max platereader in a warm (37°C) room with shaking for 30 s initiallyand then for 3 s every 5 min thereafter. The purpose of placingthe 96-well plate in the plate reader during this defensin incubationwas to subject the cells to the identical condition to whichthey were subjected during the subsequent outgrowth and to shakethe plate during the incubation to ensure proper mixing. Overthe next 2 h readings were taken every 5 min by using the 650-nmfilter. Then, 100 µl of double-strength (2x) MHB was addedto each of the 60 internal wells. C'₀ was 5 x 10⁵ CFU_v/ml forcontrol wells (zero killing) after the last 2x MHB addition.Two hundred microliters of a 3:1 mixture of MHB and sodium phosphatebuffer was added to each of the 36 edge wells as a contaminationcheck and to retard evaporation of the internal wells. The platewas again shaken for 30 s initially and then for 3 s every 5min thereafter. Readings were taken at 650 nm every 5 min overthe next 12 h. Each experiment was repeated three times on separatedays by starting with overnight cultures inoculated from threedifferent colonies.

Data processing. The OD measurements from the 12-h plate reader run were importedinto Microsoft Excel software and corrected by subtracting eachwell's initial reading from the subsequent data for that well.The times at which each curve crossed the threshold change inOD₆₅₀ ( ${Delta}$ OD₆₅₀) of 0.02 absorbance units were plotted againstlog(C'₀) to generate a calibration curve that related the thresholdtimes to C'₀. The rate of survival was calculated as the numberof CFU_v of defensin-treated cells/number of CFU_v of controlcells. The virtual 50% lethal dose (vLD₅₀), vLD₉₀, vLD₉₉, andvLD_99.9 were reported as the defensin concentrations that resultedin survival rates of 0.5, 0.1, 0.01, and 10^–3, respectively.The raw data were plotted, and the y axis was rescaled to showonly the region near the threshold ${Delta}$ OD₆₅₀, which allows visualassessment of the point where the threshold crossed each growthcurve.

RESULTS

Top

Results

Calibration curves. The data used to construct a calibration curve for S. aureusATCC 29213 are shown in Fig. 1. Consistent with the laws ofprobability and the small volume (200 µl) per well, onlytwo of six wells became turbid when they were inoculated witha dilution that nominally contained 1 CFU_v/ml, and none becameturbid when they were inoculated with 0.1 CFU_v/ml. The standarddeviation for the sextuplicate wells inoculated with 1 or 10CFU_v/ml was greater than that for the wells inoculated withhigher concentrations. Again, this result is consistent withexpectations based on probability. All six standard curve experimentsyielded parallel curves that could be used to calculate thenumber of CFU_v over at least 5 orders of magnitude (Fig. 2).We always excluded the points at 10⁰ (1 CFU_v/ml) from linearregression analysis and excluded the point at 10¹ (10 CFU_v/ml)when it was noticeably off-line. Linear regression (r²) valuesranged from 0.9946 to 0.9998 at a threshold ${Delta}$ OD₆₅₀ of 0.02. Similarslopes, y intercepts, and r² values were obtained at other thresholds,and these ranged from 0.005 to 0.1 (Table 1).

View larger version (75K):
[in this window]
[in a new window]
FIG. 1. S. aureus ATCC 29213 calibration growth kinetics. Tenfold dilutions yielded C'₀ values of 10⁷ (far left) through 10⁰ (far right). (A) Log-normal plot of the raw growth kinetics data; (B) averages for each set of sextuplicate growth curves; the rightmost (C'₀ = 10⁰) series is the average for duplicate growth curves. Error bars represent standard deviations.

View larger version (22K):
[in this window]
[in a new window]
FIG. 2. Calibration curves calculated from the threshold times of the curves shown in Fig. 1B (or the equivalent plot for the other five strains) at ${Delta}$ OD₆₅₀s of 0.005, 0.01, 0.02, 0.03, 0.04, 0.05, and 0.1 (from bottom to top). The value of 0.02 was used to calibrate the growth of all six strains. In practice, any of these ${Delta}$ OD₆₅₀ values could be used for calibration.

View this table:
[in this window]
[in a new window]
TABLE 1. Slopes, y intercepts, and r² values of the regression lines shown in Fig. 2

Survival curves. Figure 3 plots the rate of survival (number of CFU_v) againstthe defensin concentration on a log-log scale. Zero values cannotbe plotted on such scales, and some values were mathematicallybelow a single surviving cell given the input number of CFU_v,indicating that a lag time must have occurred. Most curves hada concave-down shape over the full range of defensin concentrations,but a few deviated from this with greater than expected ratesof survival, which was especially notable when E. coli ATCC25922 was exposed to HNP1 at concentrations greater than 64µg/ml. We noted the same effect when we performed conventionalcolony counting experiments with this strain and HNP1 (datanot shown).

View larger version (28K):
[in this window]
[in a new window]
FIG. 3. Survival curves. Each curve is the mean of triplicate experiments. Open markers are human neutrophil defensins ( ${diamond}$ , HNP1; ${circ}$ , HNP2; ${triangleup}$ , HNP3; ${square}$ , HNP4). Filled symbols are human intestinal defensins ( ${blacksquare}$ , HD5; •, HD6). Points scored as zero survival could not be plotted. All strains were exposed to defensins at concentrations that varied twofold from 1 to 256 µg/ml. In addition, B. cereus was assayed against a twofold dilution series of 0.031 to 8 µg/ml (inset).

Bactericidal concentrations. The concentrations of each of the six defensins that killed50, 90, 99, or 99.9% of each of the six strains are presentedin Table 2. All six strains were tested with defensin concentrationsthat varied in twofold steps from 1 to 256 µg/ml. Thisrange was sufficient to determine the vLDs for five of the sixstrains. B. cereus, however, was more susceptible to all sixhuman ${alpha}$ -defensins than any of the other strains, such that somequantities were determined by repeating the analysis with defensinconcentrations of 0.031 to 8 µg/ml. The potency of HD5at a concentration of 0.031 µg/ml resulted in greaterthan 50% killing of B. cereus in two of the three replicates.

View this table:
[in this window]
[in a new window]
TABLE 2. Antimicrobial activities of human ${alpha}$ -defensins against six strains

Strain selectivities of human ${alpha}$ -defensins. vLD values (Table 2) and survival plots (Fig. 3) showed thathigh concentrations of HNP1 were notably less effective againstE. coli (two strains) and E. aerogenes than against S. aureus(two strains) and B. cereus. In contrast, the five highest concentrationsof HNP4 exhibited the greatest killing of all three gram-negativestrains; yet, except for HD6, HNP4 was the least potent againstall three gram-positive strains at the two highest concentrations.HNP1 and HNP2 showed almost indistinguishable activities againstthe gram-positive strains, but HNP2 appeared to be more potentthan HNP1 against the gram-negative strains. Other defensinsshowed no clear strain selectivity. HNP3 was consistently lessactive than HNP2 against all six strains. HD5 showed a relativelyhigh level of activity against all six strains, although itsactivity was the highest of the six defensins only at intermediateconcentrations against S. aureus ATCC 29213 and only at lowconcentrations against B. cereus. HD6 was active against B.cereus and both E. coli strains, but its activity was the lowestagainst all six strains at all concentrations. Similar resultswere obtained for the pairs of E. coli and S. aureus strains.The curves for E. coli varied slightly for HNP1 to HNP3, whichintersected between different concentrations, but the ordersof points on this plot were not meaningfully different at 4,8, 16, and 256 µg/ml for all six defensins (Fig. 3). Thetwo S. aureus strains also yielded sets of curves that werematerially congruent.

DISCUSSION

Top

Discussion

${alpha}$ -Defensins are found in various leukocytes and in the Panethcells of the small intestines of many mammals. Although humanneutrophils contain four ${alpha}$ -defensins, HNP1 to HNP3 are collectivelyabout 60 times more abundant than HNP4 (6). Largely becauseit has been difficult to obtain HNP4 from natural sources, thisdefensin has been studied less than HNP1 to HNP3. Wilde et al.(21) used size-exclusion and reverse-phase high-performanceliquid chromatography to purify native HNP4 from human neutrophilsand then tested its antimicrobial activity. They asserted, "comparedto a mixture of the other human defensins, HNP4 was found tobe approximately 100 times more potent against E. coli and fourtimes more potent against both Streptococcus faecalis and Candidaalbicans" (21). Our study provides partial support to theirfindings with E. coli. The relative potencies of two peptides,e.g., HNP4 and HNP1, can be estimated from the ratio of theirvLDs. When we used the mean vLD₉₀s shown in Table 2 for E. coliATCC 8739, these ratios were 3 for HNP1, 4 for HNP2, and 13for HNP3, signifying that HNP4 is approximately 3- to 13-foldmore potent on a weight basis. If we used the mean vLD₉₀ ratiosfor the other E. coli strain, ATCC 25922, the ratios were 2for HNP1 and HNP2 and 5 for HNP3. Had we chosen to use the vLD₉₉sfor E. coli ATCC 8739, they would have returned ratios thatwere two- to fourfold higher than the vLD₉₀ ratios: 15 for HNP1and 23 for HNP2 and HNP3.

Human neutrophils may have compensated for the lower intrinsicpotencies of HNP1 to HNP3 against gram-negative bacteria byproducing these peptides at a 60-fold greater abundance. Thegreater intrinsic potency of HNP4 against gram-negative bacteriaevidently came with a price, since it was less potent than HNP1and HNP2 against the gram-positive test organisms in our panel.In contrast, HD5 was as active as (or more so than) HNP4 againstgram-negative bacteria, and it was almost as effective as HNP2against the gram-positive organisms.

Perhaps the greatest surprise from our study was the exceedinglypoor performance of HD6 against our bacterial test panel. Indeed,the relative inactivity of HD6 against bacteria initially ledus to question its raison d'être. However, subsequentdata from our group indicated that HD6 can inhibit infectionof peripheral blood mononuclear cells by human immunodeficiencyvirus type 1 as effectively as HNP1 to HNP4 (unpublished data),suggesting that HD6 may have evolved specificity for virusesat the expense of its antibacterial activity. In the future,HD6 (and other intestinal defensins) deserve to be tested fortheir activities against anaerobes, fungi, protozoans, and helminthsand for other properties within the purview of defensins, e.g.,chemotaxis, adjuvanticity, and enhancement of wound healing(11, 12, 18).

The conspicuous diversity of the survival curves shown in Fig.3 was also unexpected. Most defensins tested against gram-positivestrains, including all six defensins against B. cereus, consistentlyproduced concave-down dose-response relationships that followsimple exponential killing (14). Each curve that appears entirelyconcave down, as plotted on the log-log scale of Fig. 3, islinear on a lognormal plot (data not shown). This type of resultwould suggest that neither saturation by increasing defensinconcentrations nor resistance to defensins influences the activitymeasured. By contrast, HNP4 produced bimodal curves againstboth S. aureus strains, consistent with a small (<1:100)subpopulation of organisms that were phenotypically resistantto defensins rather than genotypically resistant (1, 10), especiallysince we used cloned organisms in each experiment. Similarly,bimodal curves were observed with HNP4 and HD5 against gram-negativestrains E. coli ATCC 8739 and E. aerogenes. With the exceptionof the scant activity of HD6, none of the defensins tested againstgram-negative strains produced strictly exponential survivalcurves. When deviations from a linear lognormal survival curveexist, only the most linear portions of the curve should beused to calculate relative potency. The human ${alpha}$ -defensins areconsiderably less potent than antimicrobial peptides, such asovine SMAP-29, porcine protegrins, or the horseshoe crab's tachyplesins.Although the vLD₉₀s and vLD₉₉s of human defensins are reliable,vLD_99.9s could be calculated for only one organism in our testpanel. When more potent antimicrobial peptides (e.g., SMAP-29,protegrins, and tachyplesins) are assayed, reliable vLD_99.9scan also be obtained.

With these caveats, the virtual colony counting assay describedin this report can produce results comparable to those of theNCCLS-approved colony counting procedures with far less effort.Our virtual constants were so named to distinguish them fromany existing published constants while making their meaningreadily understandable to workers in various fields of study.We do not intend to imply that our vLDs have been rigorouslyverified to correlate with LDs determined by other methods.However, our findings do appear to correlate well with thoseproduced by colony counting. As expected, the mean vLD₅₀s reportedin Table 2 were slightly greater than the LD₅₀s reported previously(22) in a colony counting study of the same preparations ofthese six defensins against E. coli ATCC 25922 and S. aureusATCC 29213 with 3-h defensin exposure times. Colony countingdata comparable to the remainder of the data in Table 2 haveyet to be reported, but our results agree generally with whatis known about these peptides. For instance, in our study HNP3was less active than HNP1 and HNP2 against all six strains,which agrees with the findings from studies that used a varietyof methods (4, 16, 19). Furthermore, the calibration data shownin Table 1 and Fig. 2 satisfied each of the assumptions underlyingthe use of growth kinetic curves to calculate C'₀, as specifiedby Brewster (1a), i.e., the curves were parallel and evenlyspaced, with similar slopes for all thresholds and excellentlinear regression r² values. Any error added by using this calibrationprocedure to enumerate small concentrations of bacteria is insignificant.The growth rates in the experimental wells with the same strainwere similar, but they were not as close to identical as thosefor the strain in the calibration growth curves (Fig. 1) orthe control wells. Threshold time variations were minimizedby averaging the results of experiments performed on 3 daysand by choosing a low threshold ${Delta}$ OD₆₅₀ of 0.02.

Several technical details were crucial in the development ofthe virtual colony counting assay. A potential drawback of using96-well plates for a 14-h experiment is that moisture can condenseon the inner surface of the lid. Brewster (1a) applied detergentto the insides of 96-well lids before their use to deter theaccumulation of hanging droplets. We found this step to be unnecessary,perhaps because we did the experiments in a 37°C room orused a different instrument for the measurements. Evaporationof liquid from the edge wells caused us to limit the collectionof experimental data to the internal 60 wells, none of whichdecreased in volume by more than 3% when the volumes were measuredafter overnight experiments. Antimicrobial activity must beantagonized in order to allow cells to grow exponentially afterthe addition of twice-concentrated media. Inhibition of defensinactivity was likely due to the carbohydrates present in thegrowth medium. MH II powder is composed of Casamino Acids; 14%(wt/wt) beef extract, which contains a variety of carbohydrates;and 7% (wt/wt) starch. Defensins are known to bind to variouspolysaccharides, including protein glycosyl moieties (20), cellulose,and dextran sulfate, with high affinities. Virtual colony countingcould be adapted to measure the activities of agents other thandefensins if their antimicrobial activities are also stronglyinhibited by 2x MHB itself or if a peptide binder, such as dextransulfate, that does not slow bacterial growth is added to theMHB. Virtual colony counting is also adaptable to address hypothesesinvolving high salt concentrations, various divalent cationconcentrations, or physiological conditions by supplementingthe low-salt 10 mM sodium phosphate incubation buffer as desired.

Our virtual colony counting procedure allows the convenient,concurrent comparison of the antibacterial specificities ofthe human ${alpha}$ -defensins. In addition, libraries of mutated defensinscould be screened at one (or more) critical concentration(s)to deduce sequence-to-activity relationships, test mechanistichypotheses, or identify candidate therapies that can be usedto combat pathogenic bacteria. The assay may also have potentialas a general method for determination of cationic peptide antibacterialactivity.

ACKNOWLEDGMENTS

We thank Jacek Lubkowski of the National Cancer Institute, Frederick,Md., for communicating the results of crystallographic studies;Fiorenza Cocchi for conducting anti-human immunodeficiency virusassays; and Rob Powell for valuable technical advice.

This work was supported by National Institutes of Health grantsAI056264 and AI058939 (to W.L.).

FOOTNOTES

* Corresponding author. Mailing address for Wuyuan Lu: Institute of Human Virology, University of Maryland Biotechnology Institute, 725 West Lombard St., Baltimore, MD 21201. Phone: (410) 706-4980. Fax: (410) 706-7583. E-mail: luw{at}umbi.umd.edu. Mailing address for Robert I. Lehrer: Department of Medicine, CHS 37-062, David Geffen School of Medicine, University of California, Los Angeles, CA 90095. Phone: (310) 825-5340. Fax: (310) 206-8766. E-mail: rlehrer{at}mednet.ucla.edu.

REFERENCES

Top