A Possible Source of Error in the Estimation of Stomatal Resistance

During transpiration, water vapour diffusing through the stomatamoves through air that has no mean motion: its diffusive inwardflux is balanced by a general outward mass flow. The effectis to accelerate outward diffusive flows (water vapour, CO₂in respiration) and retard inward diffusive flows (air, CO²for assimilation) and alter the apparent ratio of diffusioncoefficients. The magnitude of the effect is calculated theoretically,and estimated practically for an experiment in sugar-beet leaves.For this particular case the error in estimating mesophyll diffusiveresistance is near 2 per cent, but for other conditions couldbe much larger. Estimated values of the apparent ratio of thediffusion coefficient of water vapour and carbon dioxide (truevalue = 1.59) ranged from –0.027 to 2.79, but could lieanywhere between – and +.     

Extrastomatal Control of Transpiration in Leaves of Yellow Lupin (Lupinus luteus var. Weiko III) after Drought or Abscisic Acid Treatment

Stornata of leaves of non-stressed yellow lupin plants wereclosed with phenylmercuric acetate (PMA) and viscous flow resistanceand apparent diffusive resistance were measured for both leafsurfaces. Viscous flow resistance was proportional to the ythpower of apparent diffusive resistance with y = 1.19 ±0.10 for the upper surface and y = 1.58 ± 0.11 for thelower surface, i.e. viscous flow resistance changed faster thanapparent diffusive resistance. However, in three separate experiments where lupin plants werewatered with 10^–4 M abscisic acid (ABA) for 1 week, they values were between 0.29 and 0.59 for the upper surface andbetween 0.18 and 1.00 for the lower surface. Similarly, drought-hardened plants showed y values between 0.45and 0.52 for the upper surface, and between 0.43 and 0.88 forthe lower surface. Both ABA. and drought-induced changes iny values were statistically different from PMA results at the1% confidence level. Upon rewatering, drought-stressed plants and ABA-treated plantsrecovered within 2 and 5 d respectively. Thus with both treatments there was a considerable increasein apparent diffusive resistance (and thus a decrease in transpiration)which could not be accounted for by a comparable increase inviscous flow resistance (i.e. stomatal closure). These results suggest that drought stress and ABA treatmentcause an extrastomatal resistance to transpiration in the leavesof yellow lupin plants.     

Application of an Electrokinetic Formulation to the Study of the Effect of Alkaline-earth Cations on the Absorption of K+-ions by Lemna minor

A double effect of Ca⁺⁺ is observed on K⁺-absorption by Lemnaminor: activation through coupled (probably metabolic) processes,and inhibition through a perturbation of the structure of thecatalytical sites of K⁺-absorption. In contrast, Mg⁺⁺, whichalso exhibits a structural inhibitory effect, has not apparentlya metabolic actrvatory one. It seems that diffusive processescould account partly for the second phase of the dual-phasecurves of absorption.     

Effect of Phenolic Compounds on ABA-induced Changes in K+ Concentration of Guard Cells and in Epidermal Diffusive Resistance

The study of the structure-activity relationship of phenoliccompounds in reversing the ABA-effect on stomata led us to investigatethe changes in K⁺ concentrations in guard cells and in the epidermaldiffusive resistance of leaves, after treatment with ABA andphenolics. The amount of potassium localized in guard cells usually correspondsto stomatal aperture in different treatments. Umbelliferone,however, permits stomatal opening without retention of potassiumin the guard cells, which is an exception. The effect of phenolicsin retaining K⁺ in epidermal peels is matched by recorded epidermaldiffusive resistance changes in the leaves.Although flavonoidsand some other phenolics behave differently showing recoveryin epidermal peels with K⁺ in guard cells, epidermal diffusiveresistance is not recovered. Key words: Epidermal diffusive resistance, K⁺, ABA, phenolics, stomata     

The Effects of Low Concentrations of Sulphur Dioxide on Stomatal Conductance and Epidermal Cell Survival in Field Bean (Vicia faba L.)

Exposure of 3 week old field bean plants to concentrations ofSO₂ from 50–500 µg m^-3 induced comparable 20–25%increases in mean leaf diffusive conductance regardless of whetherthe diffusive conductances were obtained by porometric measurementor calculation from gas exchange data. The stomatal conductancesof the adaxial and abaxial leaf surfaces were both increasedby exposure to SO₂. Microscopic examination of epidermal strips from control andpolluted plants revealed that the stomatal opening observedin treated plants was associated with a sharp reduction in theproportion of living epidermal cells adjacent to the stomata.The proportion of surviving adjacent epidermal cells was invariablysmaller on the lower epidermis and appeared to decrease as theSO₂ concentration was raised from 50 to 500 µg m^–3.Although the guard cells appeared to be undamaged at concentrationsbelow 200 µg m^–3, structural disorganization ordeath of one or both guard cells was observed frequently ator above 500 µg m^–3. The results are discussed in relation to the controversy concerningthe effects of SO₂ on stomatal aperture.     

Fine Structure Aberrations in the Movement of 11C and 13N in the Stems of Plants

¹¹CO₂ was offered to leaves of sunflower, corn and ryegrassand ¹³N₂ to root nodules of alfalfa and alder. Movement of thetracers out of the feed region was monitored along stems orpetioles using geiger tubes. Fluctuations in radioactivity werenot detected as statistically significant from random tracerdecay in the ‘background’ section of the time-activityprofiles before mass-flow commenced, but became highly significantin the mass-flow sections. These pulses of radioactivity couldbe followed from one detector to the next over 1–3 cmand were analysed for periodicity by cross-correlation and auto-correlationcomputer programmes. Periodicity was only rarely detected in¹¹C runs, but was evident in many ¹³N experiments. Speed ofpulse movement (microfronts) were measured, both visually andby computer cross-correlations, and compared with rates foundby the ‘moving intercept’ of mass flow. Microfrontspeeds were faster. Speeds of ¹¹C movement were comparable withthose reported for phloem, but ¹³N movements were often muchhigher, suggesting xylem movements. Fine structure pulses indicatethat movements of ¹¹C photosynthate or ¹³N compounds are rapid,erratic and far more complex than expected by a simple Münchpressure flow mechanism. Key words: ¹¹C, ¹³N, plant stems, radioactive pulse     

Effects of diffusion and upwelling on the formation of red tides

In this paper, records on the timing and location of specificred tides monitored once or twice a week in Mikawa Bay, Japan,are related to horizontal and vertical mixing rates determinedfrom a numerical model. Horizontal (K_h) and vertical (K_z) diffusioncoefficients, and upwelling velocities, were estimated usinga box model analysis. In the wind-mixed period and in the upperlayer during the stratified period, K_h was estimated to be ofthe order of 10² m² s^–1. During the stratified period,K_z was estimated to be of the order of 10^–5 m² s^–1.The upwelling velocity was calculated to be in the range 0.35–5.1m day^–1 with an average of 1.5 m day^–1. Comparisonbetween the literature values of the specific growth rate (µ)of the red tide-forming diatoms and calculated K_h values duringthe red tides show that diatoms which have a low µ cannotform red tides in a strongly diffusive environment, while specieshaving a high µ can form red tides even in a strong diffusiveenvironment. On the other hand, no clear relationship was foundbetween µ of the flagellate group and K_h, although theflagellate group formed red tides even in severe diffusive conditions.From the comparison between the literature values of sinkingrate and swimming speed and the physical parameters associatedwith vertical processes, it was concluded that flagellates willform red tides, even in severe diffusive conditions, by usingtheir swimming ability, while diatoms form red tides by theirhigh growth rates with the aid of vertical diffusion and theupwelling movement of water.     

Uptake of Abscisic Acid by Suspension-Cultured Phaseolus coccineus L. Cells: Evidence for Carrier Participation

The uptake of abscisic acid (ABA) by suspension-cultured Phaseoluscoccineus L. cv. ‘Prizewinner’ (runner bean) cellshas been studied. In addition to non-mediated diffusive uptakeof ABAH, a saturable component of uptake occurs which is demonstrableas inhibition of uptake of submicromolar concentrations of [2-¹⁴C]ABAby increasing concentrations of nonradioactive ABA to a constantplateau level. Saturation is not due to competition for extracellularbinding sites or cytoplasmic acidification and can only be partiallyaccounted for by saturation of metabolic enzymes. It is consideredlargely to represent carrier-mediated ABA uptake. The maximumvelocity of the carrier is greater at pH 4.0 than at pH 5.0,although the apparent Michaelis constants are similar (about2.0 mmol m^–3). No carrier activity was detectable abovepH 6.0. The carrier is unaffected by indol-3-yl acetic acid(IAA), gibberellin A₃, benzyladenine or 2, 3, 5-triiodobenzoicacid (TIBA). Use of protein-modifying reagents suggested a roleof histidine residues in carrier activity. Reagents expectedto modify the transmembrane pH ( pH) and electrical ( E) gradientswere used to study the driving forces for ABA uptake. Therewas no apparent effect of E, indirectly monitored by effectson an electrogenic TIBA-sensitive component of IAA transport,on ABA uptake. Both diffusive and saturable components weremodified in proportion by changes in pH, suggesting a commonsensitivity to this driving force. The carrier is suggestedto act as an ABA^–/H⁺ symport. Key words: Abscisic acid, Phaseolus coccineus L., Transport, Suspension culture     

The Diffusive Conductivity of the Stomata of Wheat Leaves

A leaf chamber (described in detail) was used alternately witha resistance porometer to measure resistance to viscous flowof air through the leaf, and with a diffusion porometer to measurethe differential diffusive flow of hydrogen and air (V_H–V_A)through the leaf and the component of hydrogen flow (V'_H) movingstraight across the leaf. The resistance of the mesophyll isneeded for interpretation: estimates by three different methodsfor viscous flow did not agree very well, but two differentmethods for diffusive flow gave good agreement. For wheat leaves,only very large errors are important. Formal analysis is in three appendixes: I. Interpretation ofviscous and diffusive flow in small pores involves some problemsin molecular physics, complicated by the particular geometryof the wheat stoma. With some uncertainty, formal expressionsare derived for the viscous resistance of a single stoma, rv,and for the resistances to diffusion of hydrogen and air, andof water vapour and carbon dioxide, all expressed as r_s persquare centimetre of leaf surface. The analysis for hydrogen/airis the most uncertain; that for water vapour and carbon dioxideis more reliable. II. An indication is given of the flow characteristicsof the leaf-chamber system, from which rv can be derived, andof the basis for estimating mesophyll resistance. III. The methodof converting estimates of r_s into estimates of V_H–V_Aand V'_H is given. The results presented are expressed as nearly as possible interms of the quantities which were measured. For five leavesthe dependence of V_H–V_A on V'_H agrees well with theoreticalpredictions; the dependence of V_H–V_A (and V'_H) on rv,on average, agrees well with prediction, but involves the assumptionthat the stomata get shorter as they close. The agreement isgood enough to suggest that the formal expressions for r_s interms of stomatal dimensions and molecular gas constants arereliable enough to be carried forward into future transpirationand assimilation studies. The minimum value of ra for watervapour (c. 3 sec cm⁺¹) is close to values found elsewhere bydifferent techniques. At very small stomatal openings there was a large deviationfrom predicted behaviour, such as would occur if the imposedexcess air pressure further closed the stomata during viscousflow experiments.     

A Handpiece for the Simultaneous Measurement of Photosynthetic Rate and Leaf Diffusive Conductance: I. DESIGN

The design and construction of a handpiece for the simultaneousmeasurement of photosynthetic rate and diffusive conductanceof cereal leaves in almost natural conditions in the field isdescribed. Photosynthetic rate is found from the assimilationof ¹⁴CO₂ by part of the leaf which is temporarily enclosed ina small hand-held chamber. This chamber also acts as a stirred,steady-state water vapour diffusion porometer, allowing thesimultaneous measurement of relative humidity from which theleaf diffusive conductance is estimated. The instrument alsomeasures the leaf and air temperatures and incident photon fluxdensity. The important criteria of the performance of such ahandpiece are discussed, and the sensors which measure the physicalvariables of humidity, temperature, and photon flux densityare described. An automatic sequencing system built from logiccircuits which displays the measured values of these variablesand times the operations is also described.     

Uptake and Transport of Fusicoccin in Higher Plant Tissues

The uptake and release of ³H-labelled fusicoccin (FC) fed topea internode segments and the transport of [³H]FC in wholeplants and in excised parts of plants of pea, maize, and pumpkinhave been investigated. FC uptake showed three phases apparentlycorresponding to the penetration of FC: (1) into the free space;(2) into the cytoplasm; (3) into the vacuole. The first phase is a little thermosensitive and apparently includesadsorption binding to some free space component (cell surface?).The second and third phases are highly temperaturesensitiveand in part energy-dependent. However, no accumulation of FCagainst a concentration gradient is observed at high externalFC concentration. Accumulation at low concentration seems dueto the formation of a poorly exchangeable complex with somecell structure. The efflux of the FC penetrated within the cells is limitedby some highly temperature-sensitive process. A small fractionof the accumulated FC tends to be retained in the tissue, eitherbecause sequestered in some compartment or because bound tosome cellular component. FC transport in whole plants as well as in isolated plant partsseems to depend mainly on simple diffusion and on transportby mass flow in the xylem. Long distance transport of the toxinin pumpkin plants mainly occurs in the xylem, while the slowmovement in non-vascular tissues seems to depend on diffusioncombined with mass flow in the free space, and does not seemheavily influenced by metabolic factors.     

Influence of Water Deficits on Gas-Exchange and the Leaf Area Development of Cassava Cultivars

Measurements of gas-exchange, leaf water potential and the leafdiffusive conductance of the abaxial leaf surface of six cassavacultivars, M Mex 59, M Ven 218, M Col 1684, M Col 72, M Col22, and M Col 638, were made at 48 h intervals and between 1200–1500h, on potted plants, grown outdoors during a 58 d period ofwithdrawal of irrigation. Rates of net-photosynthesis of about28 mg CO₂ dm^–2 h ^–1 were reduced to zero withinthe first 5 d of the drying cycle, despite the small differencesin leaf water potential of 0.15 MPa. Water shortage also causeda reduction in mean conductance to < 1.0 mm s^–1 atwhich level the control of transpiration maintained leaf waterpotential at > —1.6 MPa. Cultivar differences in theresponse of net-photosynthesis and leaf diffusive conductanceto water shortage were seen within 2 d of the dry cycle andthe leaf water potential was commonly 0.15 MPa lower than inthe wet controls. The most vigorous cultivars (M Mex 59, M Ven218 and M Col 1684) reduced their rates of net-photosynthesisto zero by day 5 of the dry cycle when the soil water contentwas depleted by 65%. Less vigorous cultivars (M Col 72, M Col22 and M Col 638) reduced their rates of net-photosynthesisto zero by day 30, when the soil water content was depletedby 75%. Measurements are also reported of the leaf productionper apex and leaf extension for leaves produced during the dryingcycle. Key words: Cassava (Manihot esculenta Crantz), Gas-exchange, Leaf diffusive conductance, Water deficits     

Cyanide Inhibition of Phloem Transport along the Stolon of Saxifraga sarmentosa L

Long thin stolons of Saxifraga were treated with cyanide inboth the solution and gaseous forms; the latter was much moreeffective. Cyanide strongly inhibited the transport of ¹³⁷Csand of natural ¹⁴C-assimilates. As judged by a variety of approaches,including the use of ¹⁴C-cyanide, the inhibition was certainlyeffective in the sieve tubes themselves. Callose formation didnot seem to be promoted. The inhibition was completely reversible,and was never accompanied by a build-up of tracer in, or before,the treated zone; failure to traverse it was not due thereforeto membrane damage and consequent leakage. For these reasonsthe results are held to favour a mechanism of mass flow invokingactive pumping in the sieve tubes.     

Photosynthesis and Diffusion Conductance of the Valencia Orange Fruit under Field Conditions

CO₂ uptake and diffusion conductance of Valencia orange fruits(Citrus sinensis L. Osbeck) were measured in the field duringthe growing season of 1977/78 to ascertain if, as in the leaf,stomata control photosynthesis and transpiration under changingenvironmental conditions. Measurements were made on 15 yearold trees grown in a sandy loam soil and receiving either adry or a wet treatment. Fruit diffusive conductance was measuredwith a modified water vapour diffusion conductance meter andgross photosynthesis was measured with a ¹⁴CO₂ uptake meter.Photosynthetically active radiation (PAR) was measured witha quantum sensor. Fruits exposed to light assimilated CO₂ ata rate which was 25–50% of that assimilated by leaves.The uptake was dependent on fruit size, PAR, chlorophyll content,and on diffusive conductance of the fruit epidermis. Epidermalconductance showed a diurnal trend which was similar in shapeto that of the leaf except in the late afternoon. Cuticularconductance of the fruit was calculated and ranged between 0.22and 0.30 mm s^–1. It was speculated that the CO₂ uptakeby the fruit could support the growth of flavedo cell layerswhen exposed to light. Dry soil caused an increase in the ¹⁴CO₂uptake by fruit possibly caused by the increased potential areaof the stomatal opening per unit of fruit surface area.     

Contrasting Incorporation of 2H from 2H2O into ABA, Xanthoxin and Carotenoids in Tomato Shoots

Nonhebel, H. M. and Milborrow, B. V. 1987. Contrasting incorporationof ²H from ²H²O into ABA, xanthoxin and carotenoids in tomatoshoots.—J. exp. Bot. 38: 980–991. The incorporation of ²H into abscisie acid, xanthoxin, ß-carotene,lutein, lutein epoxide and violaxanthin in tomato shoots incubatedfor 6 d in 70% ²H₂O was compared to investigate whether thesecompounds are precursors of abscisie acid. On average, 5% ofabscisie acid molecules became labelled with a single ²H atomand 21% with from 3 to 14 atoms of ²H. However, mass spectralanalysis of endogenous xanthoxin extracted from the same plants,in darkness, under nitrogen, and derivatized to the pentafluorobenzyloximeshowed incorporation of only single ²H atoms, ruling out xanthoxinas an abscisie acid precursor. Normal-phase HPLC analysis oftomato shoot extracts showed four major carotenoid peaks; ß-carotene,lutein, lutein epoxide and violaxanthin. Calculations basedon the measured carotenoid pool sizes and on the calculatedminimum pool size of the ABA precursor predicted that at least6·8% of violaxanthin molecules or 7·9% of luteinepoxide molecules should become labelled with from 3 to 14 ²Hatoms if these molecules are precursors of abscisie acid. However,mass spectral analysis of xanthoxin derived from purified violaxanthinand lutein epoxide showed no molecules with more than a single²H atom, with detection limits of less than 1% and 0·2%respectively. Similarly, mass spectra of ß-caroteneand lutein did not show any ²H. We conclude that these carotenoidsare not precursors of abscisie acid. Key words: Abscisic acid, xanthoxin, carotenoids     

Energy Coupled Transport of Sorbitol and Other Sugars into the Protoplast Isolated from Apple Fruit Flesh

The uptake kinetics of sorbitol, sucrose, glucose and fructoseacross the plasma membrane using protoplasts isolated from applefruit flesh (Malus pumila Mill. var. domestica Schneid.) wasinvestigated. When sorbitol was taken up into the cell, PCMBS-sensitivesaturable transport was distinguishable from the diffusive transport.At a low sorbitol concentration, the saturable transport systemaccounted for more than 50% of the total uptake, whereas ata high concentration the diffusive transport system was moredominant. The saturable transport was suggested be a carrier-mediatedtransport system coupled with ATP because the system was inhibitedCCCP or orthovanadate. The K_m value for sorbitol was computedto be 3.6mM. A carrier-mediated transport system coupled withATP was also observed for glucose and fructose with correspondingK_m values of 5.0 and 2.5 mM. However, no saturable transportfor sucrose was observed over a range of 0.1 to 10 mM sucroseconcentration. The relationship among these sugar transportsystems across the plasma membrane, apoplastic unloading, andsugar accumulation vacuoles are discussed. ¹Present address: Laboratory of Horticulture, Faculty of Agriculture,Nagoya University, Chikusa, Nagoya 464, Japan. (Received April 8, 1988; Accepted June 8, 1988)     

Estimating Water Flux through Stems of Scots Pine with Tritiated Water and Phosphorus-32

The radioisotopes of tritium (³H) and phosphorus-32 (³²P) weresimultaneously injected into the conducting tissue of more than40 Scots pine trees over a 6 month period. Analysis of coresamples indicated that ³²P and ³H are transported by mass movementat similar rates. ³H exhibits diffusion as well as mass flowproperties. The strong beta emission of ³²P at the bark surfacewas monitored to determine the velocity of the pulse. Core samplesprovided an estimate of the volume of waterfilled conductingtissue. The calculations of flux were compared with actual uptakeby two trees severed at their bases and supported in water-filledcontainers. Over a 5 d period, periodic estimations of cumulativewater uptake showed an excellent linear relationship with measureduptake (r² 0.98). Refinements in the model are discussed, emphasizingthe importance of assessing diurnal variation in sapwood watercontent.     

Influence du d?bit d'eau de mer dans un dispositif de culture ? fibres creuses dialysantes sur la croissance phytoplanctonique et 1'extraction des nitrates du milieu

It is demonstrated that the productive capacity of mass dialysisculture of phytoplankton is intimately related to the rate offlow of nutrient medium along the membrane. Comparison of culturesof Phaeodactylum tricornutum, subject to different medium flowrates (92 versus 250 ml.min^–1) during a 17-day growthperiod, reveals increased productivity (in terms of cell numbers,chlorophyll a, dry weight, cell nitrogen, cell carbon, ATP)at the higher flow rate. Differences are most pronounced inthe latter stages of growth (i.e., linear and stationary) attainingratios between 2 and 3 for cell nitrogen, cell carbon and ATP.Lower C/N ratios for the greater yielding culture translatesas enhanced osmotic diffusion as well as cellular assimilationof nitrates. The positive effects of increasing medium flowrate on phytoplankton growth result from improved dialyzer performancewith respect to low molecular weight solutes. This is evidencedin the proportionately greater values obtained for mass transferof nitrate-nitrogen. Accordingly, measures of nitrate clearanceindicate a progression from 29 to 85 ml.min^–1 in responseto augmenting sea water flow from 32 to 292 ml.min ^–1.The culture apparatus recently developed consists of a separatedialysis unit (a hollow-fiber cartridge used in hemodialysis)coupled to a temperature-controlled growth chamber. Culturesreceive a continuous flow of natural sea water and are grownin the batch dialysis mode. The main advantages of this methodrelate to its potential for large-scale, axenic algal culturebased on the abundant source of cheap nutrients that constitutesnatural sea water.     

Root Confinement and its Effects on the Water Relations, Growth and Assimilate Partitioning of Tomato (Lycopersicon esculentum Mill)

Although it is well established that the root growth in manyspecies is very sensitive to mechanical impedance or to confinementin small volumes, little is known about the consequent effectson growth of the whole plant and the mechanisms involved. Thiswork investigated the effects of root confinement on the waterrelations, growth and assimilate partitioning of tomato (Lycopersiconesculentum Mill) grown in solution culture. Six-week old plants were transferred to either 4500 ml or 75ml containers filled with nutrient solution, and allowed togrow for 14 d. Transpiration, leaf-air temperature differences,and leaf diffusive resistances were measured frequently. Leaf,stem and shoot dry masses, leaf area and root length, were estimatedwhen the treatments were imposed and at the end of the experiment.After 14 d growth the root and shoot hydraulic resistances wereestimated from measurements of leaf water potential and transpirationrate, using a steady-state technique. Confining root growth to the small containers substantiallyreduced shoot and root growth and increased the proportion oftotal dry matter present in the stems. These effects were dueto drought stress. The hydraulic resistance of the root systemwas greatest in the confined plants. This led to more negativeleaf water potentials, increased leaf diffusive resistance,and reduced the net assimilation rate by a factor of 2.5. Transpirationper unit leaf area was less affected. However, cumulative transpirationwas also reduced by a factor of 2.5. mostly because of the smallerleaf area on the confined plants. Root hydraulic resistivitywas measured at 3.1 x 10¹²s m^–1 in the control treatment,but increased to 3.9 x 10¹² s m^–1 for roots in the smallcontainer. The mechanisms by which root confinement caused drought stressand disrupted the pattern of assimilate partitioning are discussedin detail. Assimilate partitioning, Lycopersicon esculentum, root confinement, plant growth, root growth, root resistance, shoot resistance, tomato, transpiration, water-use efficiency     

Muscle use during dynamic knee extension: implication for perfusion and metabolism

Dynamic one-legged knee extension (DKE) iscommonly used to examine physiological responses to "aerobic"exercise. Muscle blood flow during DKE is often expressed relative toquadriceps femoris muscle mass irrespective of work rate.This is contrary to the notion that increased force is achieved byrecruitment in large muscles. The purpose of this study, therefore, wasto determine muscle use during DKE. Six subjects had magnetic resonance images taken of their quadriceps femoris before and after 4 min of DKEat 20 and 40 W. Muscle use was determined by shifts in T2. Thecross-sectional area of quadriceps femoris that had an elevated T2 was16 ± 1% (mean ± SE) preexercise, and 54 ± 5 and 94 ± 4% after 20- and 40-W DKE, respectively. Volume of quadriceps femorisincreased 11.4 ± 0.2% (P = 0.006), from 2,230 ± 233 cm³before exercise to 2,473 ± 232 cm³ after 40-W DKE. Extrapolationof these data indicates that 1,301 ± 111 cm³ of quadriceps femoris wereengaged during 20-W DKE compared with 2,292 ± 154 cm³ during 40-W DKE. By usingmuscle blood flow data for submaximal DKE at 20 W [P. Andersenand B. Saltin. J. Physiol. (Lond.)366: 233-249, 1985; and L. B. Rowell, B. Saltin, B. Kiens, and N. J. Christensen. Am. J. Physiol. 251 (Heart Circ.Physiol. 20): H1038-H1044, 1986] andestimating muscle use in those studies from our data (total muscle mass × 0.54), extrapolated blood flow to active muscle (263 and 278 ml · min¹ · 100 g¹, respectively) iscomparable to that obtained during peak aerobic DKE when expressedrelative to total muscle mass (243 and 250 ml · min¹ · 100 g¹,respectively). These findings indicate that increasedpower during aerobic DKE is achieved by recruitment.Additionally, they suggest that blood flow to the active quadricepsfemoris muscle does not increase with increases in submaximal work ratebut instead is maximal to support aerobic metabolism. Thus increases inmuscle blood flow are directed to newly recruited muscle, not toincreased perfusion of muscle already engaged.