Stable Isotope Fractionation Caused by Glycyl Radical Enzymes during Bacterial Degradation of Aromatic Compounds

Stable isotope fractionation was studied during the degradation of m-xylene, o-xylene, m-cresol, and p-cresol with two pure cultures of sulfate-reducing bacteria. Degradation of all four compounds is initiated by a fumarate addition reaction by a glycyl radical enzyme, analogous to the well-studied benzylsuccinate synthase reaction in toluene degradation. The extent of stable carbon isotope fractionation caused by these radical-type reactions was between enrichment factors () of −1.5 and −3.9‰, which is in the same order of magnitude as data provided before for anaerobic toluene degradation. Based on our results, an analysis of isotope fractionation should be applicable for the evaluation of in situ bioremediation of all contaminants degraded by glycyl radical enzyme mechanisms that are smaller than 14 carbon atoms. In order to compare carbon isotope fractionations upon the degradation of various substrates whose numbers of carbon atoms differ, intrinsic (_intrinsic) were calculated. A comparison of _intrinsic at the single carbon atoms of the molecule where the benzylsuccinate synthase reaction took place with compound-specific elucidated that both varied on average to the same extent. Despite variations during the degradation of different substrates, the range of found for glycyl radical reactions was reasonably narrow to propose that rough estimates of biodegradation in situ might be given by using an average if no fractionation factor is available for single compounds.     

Purification and Partial Characterization of a Fructanase which Hydrolyzes Natural Polysaccharides from Sugarcane Juice

A new sugarcane (Saccharum officinarum L.) fructanase which hydrolyzes both high molecular weight polysaccharides Fructose₄:Galactitol_5n (SP) and moderate-sized carbohydrates Fructose₂:Galactitol₃3_n (MMWC) has been purified from sugarcane juice. The K_m value has been estimated to be 33.7 micrograms per milliliter and 20 micrograms per milliliter for SP and MMWC, respectively. The optimal pH and temperature values are 6.0 and 30°C, respectively. Purified protein has a pl value of 6.35 and a molecular weight of 13.2 kilodaltons. Fructanase activity appears to be Mn²⁺-dependent.     

Common Elements Regulating Gene Expression in Temperate and Lytic Bacteriophages of Lactococcus Species

A phage-inducible middle promoter (P_15A10) from the lytic, lactococcal bacteriophage 31, a member of the P335 species, is located in an 888-base pair fragment near the right cohesive end. Sequence analysis revealed extensive homology (>95%) to the right cohesive ends of two temperate phages of the P335 species, r1t and LC3. Sequencing upstream and downstream of P_15A10 showed that the high degree of homology between 31 and r1t continued beyond the phage promoter. With the exception of one extra open reading frame in 31, the sequences were highly homologous (95 to 98%) between nucleotides 13448 and 16320 of the published r1t sequence. By use of a β-galactosidase (β-Gal) gene under the control of a smaller, more tightly regulated region within the P_15A10 promoter, P_566–888, it was established that mitomycin C induction of a lactococcal strain harboring the prophage r1t induced the P_566–888 promoter, as determined from an increase in β-Gal activity. Hybridization of nine other lactococcal strains with ³²P-labeled P_566–888 showed that the Lactococcus lactis strains C10, ML8, and NCK203 harbored sequences homologous to that of the phage-inducible promoter. Mitomycin C induced the resident prophages in all these strains and concurrently induced the P_566–888 promoter, as determined from an increase in β-Gal activity. DNA restriction analysis revealed that the prophages in C10, ML8, and NCK203 had identical restriction patterns which were different from that of r1t. In addition, DNA sequencing showed that the promoter elements in the three phages were identical to each other and to P_566–888 from the lytic phage 31. These results point to a conserved mechanism in the regulation of gene expression between the lytic phage 31 and at least two temperate bacteriophages and provide further evidence for a link in the evolution of certain temperate phages and lytic phages.     

Studies of Root Function in Zea mays: IV. Effects of Applied Pressure on the Hydraulic Conductivity and Volume Flow through the Excised Root

The volume flux, J_v, and the osmotic driving force, σπ, across excised root systems of Zea mays were measued as a function of P, the hydrostatic pressure difference applied across the root, using the pressure jump method previously described (Miller DM 1980 Can J Bot 58: 351-360). J_v varied from 5.3% to 142% of its value in intact transpiring plants as a result of the application of pressure differences from −2.4 to 2.4 bar. The calculated hydraulic conductivity was 5.9 × 10⁻⁴ cubic centimeters per second per bar per gram root and was independent of pressure. A model of root function similar to those appearing in the literature failed to provide quantitative accord with the data. A proposed model, which includes the effect of volume flux on the distribution of solutes in the symplasm, predicts accurately J_v π, and the xylem solute concentration as a function of P.     

Short-term changes in leaf carbon isotope discrimination in salt- and water-stressed c(4) grasses

Online carbon isotope discrimination (Δ) and leaf gas exchange measurements were made with control and salt-stressed Zea mays and Andropogon glomeratus, two NADP-ME type C₄ grasses. Linear relationships between Δ and p_i/p_a (the ratio of intercellular to atmospheric CO₂ partial pressure) were found for control plants which agreed well with theoretical models describing carbon isotope discrimination in C₄ plants. These data provided estimates of , the proportion of CO₂ fixed by phosphoenolpyruvate carboxylase which leaks out of the bundle sheath and the component of fractionation due to diffusion in air. Salt-stressed plants had wider variation in Δ for the same or less range in p_i/p_a. Additional work indicated Δ changed independently of p_i/p_a in both water- and salt-stressed plants, suggesting a possible diurnal change in as plant water status changed linked to a decrease in the activity of the C₃ photosynthetic pathway relative to C₄ pathway activity. The possible effect of stress-induced changes in on organic matter δ¹³ C of C₄ plants is apt to be most apparent in chronically stressed environments.     

Polarization of Tryptophan Fluorescence from Single Striated Muscle Fibers : A molecular probe of contractile state

Instrumentation has been developed to detect rapidly the polarization of tryptophan fluorescence from single muscle fibers in rigor, relaxation, and contraction. The polarization parameter (P) obtained by exiciting the muscle tryptophans with light polarized perpendicular to the long axis of the muscle fiber had a magnitude P (relaxation) > P (contraction) > P (rigor) for the three types of muscle fibers examined (glycerinated rabbit psoas, glycerinated dorsal longitudinal flight muscle of Lethocerus americanus, and live semitendinosus of Rana pipiens). P from single psoas fibers in rigor was found to increase as the sarcomere length increased but in relaxed fibers P was independent of sarcomere length. After rigor, pyrophosphate produced little or no change in P, but following an adenosine triphosphate (ATP)-containing solution, pyrophosphate produced a value of P that fell between the contraction and relaxation values. Sinusoidal or square wave oscillations of the muscle of amplitude 0.5–2.0% of the sarcomere length and frequency 1, 2, or 5 Hz were applied in rigor when the myosin cross-bridges are considered to be firmly attached to the thin filaments. No significant changes in P were observed in either rigor or relaxation. The preceding results together with our present knowledge of tryptophan distribution in the contractile proteins has led us to the conclusion that the parameter P is a probe of the contractile state of myosin which is probably sensitive to the orientation of the myosin S1 subfragment.     

Phage Resistance in a Phage-Insensitive Strain of Streptococcus lactis: Temperature-Dependent Phage Development and Host-Controlled Phage Replication

Streptococcus lactis ME2 is a dairy starter strain that is insensitive to a variety of phage, including 18. The efficiency of plating of 18 on ME2 and N1 could be increased from <1 × 10⁻⁹ to 5.0 × 10⁻² and from 7.6 × 10⁻⁷ to 2.1 × 10⁻², respectively, when the host strains were subcultured at 40°C before plating the phage and the phage assay plates were incubated at 40°C. Host-dependent replication was demonstrated in N1 at 30°C and in N1 and ME2 at 40°C, suggesting the operation of a temperature-sensitive restriction and modification system in ME2 and N1. The increased sensitivity of ME2 and N1 to 18 at 40°C was also demonstrated by lysis of broth cultures and increased plaque size. ME2 grown at 40°C showed an increased ability to adsorb 18, indicating a second target for temperature-dependent phage sensitivity in ME2. Challenge of N1 with a 18 preparation that had been previously modified for growth on N1 indicated that at 40°C phage development was characterized by a shorter latent period and larger burst size than at 30°C. The evidence presented suggests that the high degree of phage insensitivity expressed by ME2 consists of a variety of temperature-sensitive mechanisms, including (i) the prevention of phage adsorption, (ii) host-controlled restriction of phage, and (iii) suppression of phage development. At 30°C these factors appear to act cooperatively to prevent the successful emergence of lytic phage active against S. lactis ME2.     

Photocontrol of Hypocotyl Elongation in Light-Grown Cucumis sativus L. : Responses to Phytochrome Photostationary State and Fluence Rate

The effects of the calculated photostationary state of phytochrome (_c) and the photon fluence rate on the elongation growth of the hypocotyl of light-grown seedlings of Cucumis sativus L. are examined. Two threshold responses to _c are found at values of 0.06 and 0.43. At _c = 0.06, there is no response at any fluence rate. In the _c range 0.1 to 0.43, elongation growth does not respond to changes in _c. Above the second threshold (_c = 0.43), there is a strong response to changes in _c. At all values of _c at and above 0.1, there is a response to fluence rate. A linear relationship can be demonstrated between a factor comprised of the logarithm of phytochrome cycling rate (a fluence-rate-dependent process) and _c, and the growth response.     

Effect of Increasing the Copy Number of Bacteriophage Origins of Replication, in trans, on Incoming-Phage Proliferation

Bacteriophage resistance mechanisms which are derived from a bacteriophage genome are termed Per (phage-encoded resistance). When present in trans in Lactococcus lactis NCK203, Per50, the cloned origin of replication from phage 50, interferes with 50 replication. The per50 fragment was found to afford negligible protection to NCK203 against 50 infection when present in a low-copy-number plasmid, pTRK325. A high-copy-number Per50 construct (pTRK323) dramatically affected 50 infection, reducing the efficiency of plaquing (EOP) to 2.5 × 10^-4 and the plaque size to pinhead proportions. This clone also afforded significant protection against other related small isometric phages. Per31 was cloned from phage 31 and demonstrated to function as an origin of replication by enabling replication of per31-containing plasmids, in NCK203, on 31 infection. A low-copy-number Per31 plasmid (pTRK360) reduced the EOP of 31 on NCK203 to 0.3 and the plaque diameter from 1.5 to 0.5 mm. When this plasmid was cloned in high copy number, the EOP was further reduced to 7.2 × 10^-7 but the plaques were large and contained Per31-resistant phages. Characterization of these “new” phages revealed at least two different types that were similar to 31, except that DNA alterations were noted in the region containing the origin. This novel and powerful abortive phage resistance mechanism should prove useful when directed at specific, problematic phages.     

Control of Seed Germination by Abscisic Acid : III. Effect on Embryo Growth Potential (Minimum Turgor Pressure) and Growth Coefficient (Cell Wall Extensibility) in Brassica napus L

The physical mechanism of seed germination and its inhibition by abscisic acid (ABA) in Brassica napus L. was investigated, using volumetric growth (= water uptake) rate (dV/dt), water conductance (L), cell wall extensibility coefficient (m), osmotic pressure (_i), water potential (Ψ_i), turgor pressure (P), and minimum turgor for cell expansion (Y) of the intact embryo as experimental parameters. dV/dt, _i, and Ψ_i were measured directly, while m, P, and Y were derived by calculation. Based on the general equation of hydraulic cell growth [dV/dt = Lm/(L + m) (Δ - Y), where Δ = _i - of the external medium], the terms (Lm/(L + m) and _i - Y were defined as growth coefficient (k_G) and growth potential (GP), respectively. Both k_G and GP were estimated from curves relating dV/dt (steady state) to of osmotic test solutions (polyethylene glycol 6000).

During the imbibition phase (0-12 hours after sowing), k_G remains very small while GP approaches a stable level of about 10 bar. During the subsequent growth phase of the embryo, k_G increases about 10-fold. ABA, added before the onset of the growth phase, prevents the rise of k_G and lowers GP. These effects are rapidly abolished when germination is induced by removal of ABA. Neither L (as judged from the kinetics of osmotic water efflux) nor the amount of extractable solutes are affected by these changes. _i and Ψ_i remain at a high level in the ABA-treated seed but drop upon induction of germination, and this adds up to a large decrease of P, indicating that water uptake of the germinating embryo is controlled by cell wall loosening rather than by changes of _i or L. ABA inhibits water uptake by preventing cell wall loosening. By calculating Y and m from the growth equation, it is further shown that cell wall loosening during germination comprises both a decrease of Y from about 10 to 0 bar and an at least 10-fold increase of m. ABA-mediated embryo dormancy is caused by a reversible inhibition of both of these changes in cell wall stability.

     

Genomic characterization of Ralstonia solanacearum phage phiRSA1 and its related prophage (phiRSX) in strain GMI1000

RSA1 is a wide-host-range bacteriophage isolated from Ralstonia solanacearum. In this study, the complete nucleotide sequence of the RSA1 genomic DNA was determined. The genome was 38,760 bp of double-stranded DNA (65.3% G+C) with 19-bp 5′-extruding cohesive ends (cos) and contained 51 open reading frames (ORFs). Two-thirds of the RSA1 genomic region encodes the phage structural modules, and they are very similar to those reported for coliphage P2 and P2-like phages. A RSA1 minireplicon with an 8.2-kbp early-expressing region was constructed. A late-expression promoter sequence motif was predicted for these RSA1 genes as 5′ TGTTGT-(X)₁₃-ACAACA. The genomic sequence similarity between RSA1 and related phages 52237 and CTX was interrupted by three AT islands, one of which contained an insertion sequence element, suggesting that they were recombinational hot spots. RSA1 was found to be integrated into at least three different strains of R. solanacearum, and the chromosomal integration site (attB) was identified as the 3′ portion of the arginine tRNA(CCG) gene. In the light of the RSA1 gene arrangement, one possible prophage sequence previously detected on the chromosome of R. solanacearum strain GMI1000 was characterized as a RSA1-related prophage (designated RSX). RSX was found to be integrated at the serine tRNA (GGA) gene as an att site, and its size was determined to be 40,713 bp. RSX ORFs shared very high amino acid identity with their RSA1 counterparts. The relationships and evolution of these P2-like phages are discussed.     

Lysine-2,3-Aminomutase and β-Lysine Acetyltransferase Genes of Methanogenic Archaea Are Salt Induced and Are Essential for the Biosynthesis of Nɛ-Acetyl-β-Lysine and Growth at High Salinity

The compatible solute N-acetyl-β-lysine is unique to methanogenic archaea and is produced under salt stress only. However, the molecular basis for the salt-dependent regulation of N-acetyl-β-lysine formation is unknown. Genes potentially encoding lysine-2,3-aminomutase (ablA) and β-lysine acetyltransferase (ablB), which are assumed to catalyze N-acetyl-β-lysine formation from α-lysine, were identified on the chromosomes of the methanogenic archaea Methanosarcina mazei Gö1, Methanosarcina acetivorans, Methanosarcina barkeri, Methanococcus jannaschii, and Methanococcus maripaludis. The order of the two genes was identical in the five organisms, and the deduced proteins were very similar, indicating a high degree of conservation of structure and function. Northern blot analysis revealed that the two genes are organized in an operon (termed the abl operon) in M. mazei Gö1. Expression of the abl operon was strictly salt dependent. The abl operon was deleted in the genetically tractable M. maripaludis. Δabl mutants of M. maripaludis no longer produced N-acetyl-β-lysine and were incapable of growth at high salt concentrations, indicating that the abl operon is essential for N-acetyl-β-lysine synthesis. These experiments revealed the first genes involved in the biosynthesis of compatible solutes in methanogens.

     

Spontaneous muscle action potentials fail to develop without fetal-type acetylcholine receptors

In mammals, two combinations of muscle nicotinic acetylcholine receptors (AChRs) are used: α₂βγδ (γ-AChR) or α₂βδ (-AChR). After birth, γ-AChRs are replaced by -AChRs (γ/-switch). The two receptors have different conductances and open times. During perinatal period, the long open time γ-AChRs generate random myofiber action potentials from uniquantal miniature end-plate potentials (mEPPs). -AChRs are suitable for strong adult muscle activities. Since the effect of the γ/-switch on neuromuscular development was unclear, despite the many differences in channel characteristics, we carried out this study to generate γ-subunit-deficient mice. Homozygotes born alive survived for 2 days in a stable condition, and were able to move their forelimbs. Endplate AChRs included -subunits, and muscle fibers had multiple neuromuscular junctions. Both pre- and postsynapses were abnormal and spontaneous action potentials generated from mEPPs were totally absent. Results suggest a requirement for γ-AChRs in mediating synaptically-induced action potential activity critical for neuromuscular development.     

Isolation and Characterization of Five Erwinia amylovora Bacteriophages and Assessment of Phage Resistance in Strains of Erwinia amylovora

Phages able to infect the fire blight pathogen Erwinia amylovora were isolated from apple, pear, and raspberry tissues and from soil samples collected at sites displaying fire blight symptoms. Among a collection of 50 phage isolates, 5 distinct phages, including relatives of the previously described phages Ea1 and Ea7 and 3 novel phages named Ea100, Ea125, and Ea116C, were identified based on differences in genome size and restriction fragment pattern. Ea1, the phage distributed most widely, had an approximately 46-kb genome which exhibited some restriction site variability between isolates. Phages Ea100, Ea7, and Ea125 each had genomes of approximately 35 kb and could be distinguished by their EcoRI restriction fragment patterns. Ea116C contained an approximately 75-kb genome. Ea1, Ea7, Ea100, Ea125, and Ea116C were able to infect 39, 36, 16, 20, and 40, respectively, of 40 E. amylovora strains isolated from apple orchards in Michigan and 8, 12, 10, 10, and 12, respectively, of 12 E. amylovora strains isolated from raspberry fields (Rubus spp.) in Michigan. Only 22 of 52 strains were sensitive to all five phages, and 23 strains exhibited resistance to more than one phage. Ea116C was more effective than the other phages at lysing E. amylovora strain Ea110 in liquid culture, reducing the final titer of Ea110 by >95% when added at a ratio of 1 PFU per 10 CFU and by 58 to 90% at 1 PFU per 10⁵ CFU.     

Cell wall yield properties of growing tissue : evaluation by in vivo stress relaxation

Growing pea stem tissue, when isolated from an external supply of water, undegoes stress relaxation because of continued loosening of the cell wall. A theoretical analysis is presented to show that such stress relaxation should result in an exponential decrease in turgor pressure down to the yield threshold (Y), with a rate constant given by ε where is the metabolically maintained irreversible extensibility of the cell wall and ε is the volumetric elastic modulus of the cell. This theory represents a new method to determine in growing tissues.

Stress relaxation was measured in pea (Pisum sativus L.) stem segments using the pressure microprobe technique. From the rate of stress relaxation, of segments pretreated with water was calculated to be 0.08 per megapascal per hour while that of auxin-pretreated tissue was 0.24 per megapascal per hour. These values agreed closely with estimates of made by a steady-state technique. The yield threshold (0.29 megapascal) was not affected by auxin. Technical difficulties with measuring by stress relaxation may arise due to an internal water reserve or due to changes in subsequent to excision. These difficulties are discussed and evaluated.

A theoretical analysis is also presented to show that the tissue hydraulic conductance may be estimated from the T_½ of tissue swelling. Experimentally, pea stems had a swelling T_½ of 2.0 minutes, corresponding to a relative hydraulic conductance of about 2.0 per megapascal per hour. This value is at least 8 times larger than . From these data and from computer modeling, it appears that the radial gradient in water potential which sustains water uptake in growing pea segments is small (0.04 megapascal). This means that hydraulic conductance does not substantially restrict growth. The results also demonstrate that the stimulation of growth by auxin can be entirely accounted for by the change in .

     

Partitioning of Noncyclic Photosynthetic Electron Transport to O(2)-Dependent Dissipative Processes as Probed by Fluorescence and CO(2) Exchange

The partitioning of noncyclic photosynthetic electron transport between net fixation of CO₂ and collective O₂-dependent, dissipative processes such as photorespiration has been examined in intact leaf tissue from Nicotiana tabacum. The method involves simultaneous application of CO₂ exchange and pulse modulated fluorescence measurements. As either irradiance or CO₂ concentration is varied at 1% O₂ (i.e. absence of significant O₂-dependent electron flow), the quantum efficiency of PSII electron transport (_se) with CO₂ as the terminal acceptor is a linear function of the ratio of photochemical:nonphotochemical fluorescence quenching coefficients (i.e. q_Q:q_NP). When the ambient O₂ concentration is raised to 20.5% or 42% the q_Q:q_NP is assumed to predict the quantum efficiency of total noncyclic electron transport (′_se). A factor which represents the proportion of electron flow diverted to the aforementioned dissipative processes is calculated as (′_se − _se)/′_se where _se is now the observed quantum efficiency of electron transport in support of net fixation of CO₂. Examination of changes in electron allocation with CO₂ and O₂ concentration and irradiance at 25°C provides a test of the applicability of the Rubisco model to photosynthesis in vivo.     

Characterization of Temperate Bacillus Bacteriophage phi105

Temperate Bacillus phage 105 is serologically unrelated to previously described virulent Bacillus phages. Phage 105 is incapable of generalized transduction. Prophage 105 is inducible with mitomycin C. Phage 105 contains double-stranded deoxyribonucleic acid (DNA) with a molecular weight of about 25 × 10⁷ as determined by band sedimentation and electron microscopy. The per cent guanine plus cytosine of 105 DNA is 43.5 as determined by buoyant density in CsCl and by thermal denaturation. Phage 105 DNA may contain complementary single-stranded ends.     

Bacteriophage phi6: a Lipid-Containing Virus of Pseudomonas phaseolicola

The purification and properties of a lipid-containing bacteriophage, 6, are described. The phage contains a lipid envelope which is probably essential for infection. Infectivity of 6 was lost in the presence of organic solvents, sodium deoxycholate, and phospholipase A. The fatty acid composition of the phage lipid was similar to that of the Pseudomonas phaseolicola host cells. The phage was composed of about 25% lipid, 13% RNA, and 62% protein. The buoyant density of 6 was 1.27 g/ml in cesium chloride. The morphology of 6 was unusual; it had a polyhedral head of about 60 nm surrounded by a membranous, compressible envelope which appeared to assume an elongated configuration upon attachment to pili. The adsorption rate constant was 3.3 × 10⁻¹⁰ ml/min in a semi-synthetic medium and 3.8 × 10⁻¹⁰ ml/min in a nutrient broth-yeast extract medium. The latent period was shorter in the former medium (80-115 min compared with 120-160 min), and the average burst size was larger (250-400 compared with 125-150). The eclipse period coincided with the latent period.     

Cell division cycles and circadian clocks : phase-response curves for light perturbations in synchronous cultures of euglena

The cell division rhythm in Euglena gracilis Klebs (Z strain) freeruns with a circadian period (30.2 ± 1.8 hours for 156 monitored oscillations) in aerated, magnetically stirred, 8-liter, axenic batch cultures grown photoautotrophically at 25°C in LD: 3,3, (7,500 lux, cool-white fluorescent) 6-hour light cycles from the moment of inoculation. Cell number was measured at 2-hour intervals with an automatic fraction collector and Coulter Electronic Particle Counter. At different circadian times throughout the 30-hour division cycle, 3-hour light perturbations were imposed on free-running cell populations by giving light during one of the intervals when dark would have fallen in the LD: 3,3 regimen. Using the onset of division as the phase reference point, the net steady-state phase advance or delay (±Δ) of the rhythm was determined after transients, if any, had subsided (usually in one or two days) relative to an unperturbed control culture. Both +Δ and −Δ were found, with maximum values of approximately ±11 to 12 hours being obtained at circadian time (CT) 20 to 22 (the `breakpoint'); little, if any phase shift occurred if the light signal was given between CT 6 and CT 12. The phase-resetting curve obtained by plotting new phase (′) versus old phase () was of the type 0 (`strong') variety. Light perturbations, no matter when imposed, engendered new phases which mapped to a relatively restricted portion (CT 6 to CT 13) of the circadian cycle.

These data provide the first detailed phase-response curve for a circadian mitotic clock. The findings, therefore, not only further support the hypothesis that a circadian oscillator (perhaps exhibiting limit cycle behavior) can modulate cell division in eukaryotic cells, but also provide a useful basis for the dissection of the nature and extent of the coupling between cell division and circadian cycles.

     

Growth-sustaining Water Potential Distributions in the Primary Corn Root: A NONCOMPARTMENTED CONTINUUM MODEL

An equation is derived from transport theory to relate local growth rate to local water potential in an expanding tissue. For a noncompartmented continuum model, the relative elemental growth rate (L) equals the divergence of the tensor product of hydraulic conductivity () and the gradient of water potential, ψ, i.e. L = • [ · ψ]. This equation is solved numerically using published values of L and to show the water potential distribution which can sustain the observed growth pattern in the primary root of Zea mays L. The water potential required to sustain growth decreases from the outside to the inside of the root, and the longitudinal profile shows most negative values near the location of the highest growth rate. A cell originally located near the apex experiences a loss and then a gain in water potential as it is displaced through the growth zone.