Polyphenoloxidase and the Respiration of Ivy Leaves

1. Polyphenoloxidase is present in ivy leaves but not in thoseof Aucuba or Euonymus.
2. Respiration of intact ivy leaves wasmarkedly stimulated bycatechol (R.Q. approximately=I), gallicacid, caffeic acid,and dihydroxyphenylalanine. The stimulationwas not relatedto injury as far as could be detected and wasnot followed byinhibition. The extra oxygen consumption representsa many timesrepeated oxidation of the amount of catechol supplied.
3. The effect of catechol on the respiration of Aucuba and Euonymusleaves was very small.
4. Cupferron and phenylthiourea, whichinhibit polyphenoloxidasein vitro, nevertheless increased respirationwhen administeredto leaves through the petiole. On the otherhand, when appliedby infiltration, cupferron did cause inhibition,but in Aucubaand Euonymus as much as in ivy.

     

Observations on the Gaseous Exchanges which take place between Menyanthes trifoliata L. and its Environment: I. THE COMPOSITION OF THE INTERNAL GAS OF THE PLANT

1. As part of a general investigation into the exchange of gasesbetween the bogbean, Menyanthes trifoliata, and its environment,determinations have been made of the composition of the internalatmosphere of the plant at five different levels, viz. leafyshoot, three successive portions of stem, and roots.
2. Procedureis described for the analysis of small gas samplesusing a modificationof the Bonnier and Mangin apparatus.
3. In darkness with thelower part of the plant surrounded by anatmosphere of nitrogen,it has not been possible to show thepresence of a regular downwardsgradient of oxygen, such aswould be expected on a basis ofnormal gaseous diffusion.
4. Under these Air Top/Nitrogen Bottomconditions the roots areshown to contain between 12?5 and 17?5percent, of oxygen intheir intercellular gas system. The portionof stem immediatelyadjacent to the roots showed an oxygen levelof from 14?0 to18?0 per cent.
5. In plants kept under NitrogenTop/Air Bottom conditions in thedark for 48 hours, the concentrationof oxygen in the rootsfell to a level of 3?1 per cent, or belowin three plants andto 6?o per cent, in a fourth. The oxygenconcentration in theadjacent lowermost part of the stem wasas high as 18?0 percent., depending on the degree of aerationof the solution bathingthe stem. It is suggested that thisdistribution of oxygen canbe related to the relative impermeabilityof roots and of stemendodermis to gaseous diffusion from without,and it is thoughtthat the major part of the oxygen supply tothe roots is transportedto them through the stelar air passages.
6. Some evidence is presented to show that oxygen passes fromthelower parts of the plant into the medium surrounding it.

     

Distribution of nitrate reductase in ageing bean seedlings

The in vivo activity of nitrate reductase (NR, E.C. 1.6.6.1 [EC] )in the roots, stem and leaves of bean (Phaseolus vulgaris L.)was measured at different ages of seedlings. The leaves alwayshad higher levels of the enzyme than the roots or stem. Thelevel of the enzyme in the very young leaves were low, increasingto a maximum by day 10 to 11 of seedling growth at 26°C,after which it start to decline. The level of the enzyme in7 dayold decotyledonized leaves was about 2.5 times higher thanthat in leaves from intact seedlings. A supply of exogenousnitrate caused a considerable increase in the total organicnitrogen in the leaf only after day 9, when the nitrogen supplyfrom the cotyledons presumably is low. (Received March 22, 1975; )     

Organic Acid Metabolism of Sedum praealtum

1. The organic acids present are citric, isocitric, and l-malic,with a small residue of unidentified acids.
2. The diurnal variationin acidity is due chiefly to changes,in malic acid, with aparallel fluctuation shown by citric acid.Under these conditionsisocitric acid shows little change.
3. The importance of carbondioxide during acidification is confirmed,and it is shown thatat room temperatures or higher the CO₂produced in respirationis sufficient to produce maximum acidification.At lower temperaturesthe supply of CO₂ limits acid production.
4. In the absence ofoxygen no acidification occurs, but even smallquantities (approx.1 per cent.) are sufficient to cause someacid production.
5. Completebalance-sheets are presented for acids, carbohydrates,CO₂ andoxygen for leaves maintained in the dark at high andlow temperatures.As acids are produced there is a correspondingloss of carbohydrate(chiefly starch). A scheme of reactionsis suggested to explainthe experimental results.

     

The Metabolism of Glucose and Acetate in Aspergillus niger

1. The metabolism of a citric-acid-forming strain of A. nigerwhengrown on a glucose-acetate medium has been investigated.
2. Acetate greatly accelerated the rate of utilization of glucose.
3. Citric acid production from glucose was much increased bythepresence of acetate.
4. The formation of oxalate from glucose-acetatecultures was muchless than from acetate alone.
5. In some cultureslarge amounts of glucose and acetate were consumedbut no acidicproducts were formed.

     

The Absorption of Ions by Excised Root Systems: II. OBSERVATIONS ON ROOTS OF BARLEY GROWN IN SOLUTIONS DEFICIENT IN PHOSPHORUS, NITROGEN, OR POTASSIUM

1. Barley plants were grown in complete culture solution and indeficiencies of phosphorus, nitrogen, or potassium for a periodof about 6 weeks. Excised roots of these plants were treatedwith a complete, aerated culture solution at 25? C. for varyingperiods of time, and the changes in respiration rate, phosphorus,nitrogen, potassium, sugars, and starch contents measured.
2. Therewere changes in fresh weight and dry weight of the excisedrootsduring treatment. The dry weight decreased with time butthewater-content changes were variable. There was a gain orlossof water by the roots according to the treatment.
3. In all casesthe deficient roots increased in content of theelement in whichthey were originally deficient. The roots ofthe plants suppliedwith full nutrient usually decreased incontent of phosphorus,nitrogen, and potassium, but exceptionsoccurred and the reasonsare discussed.
4. In most of the experiments described simultaneousloss of oneion and gain of another occurred.
5. Nitrogen-deficientroots accumulated nitrate when exposed toa complete nutrientsolution, and some of this was assimilatedwith formation ofprotein. Under similar conditions nitrogen-richroots decreasedin nitrogen content and proteolysis took place.
6. There wasa rapid fall in sucrose and reducing sugar contentof the excise'roots. The starch content was initially verysmall and showedlittle change with time.
7. The respiration rate declined withtime in all treatments exceptwhere a nitrogen deficiency existed.Here the respiration rateincreased to a maximum value at about8 hours and then fell.This increase in rate is attributed toprotein synthesis. Noevidence of a ‘salt respiration’was observed evenwhen active uptake of phosphorus or potassiumwas occurring.
8. In most instances the carbon dioxide evolvedin respirationgreatly exceeded the carbon dioxide equivalentof the sugarconsumed in the same period. Exceptions were foundwith thenitrogen-deficient roots where less carbon dioxidewas evolvedthan the equivalent of sugar consumed. It is probablethat apart, at least, of the sugar unaccounted for was usedin proteinsynthesis.
9. Where the carbon dioxide of respirationwas in excess of theequivalent of sugar consumed, protein oramino-acid is the mostprobable substrate. Respiration rateis found to be relatedboth to nitrogen and sugar content.

     

The Absorption of Ions by Excised Root Systems: III. OBSERVATIONS ON ROOTS OF PEA PLANTS GROWN IN SOLUTIONS DEFICIENT IN PHOSPHORUS, NITROGEN, OR POTASSIUM

1. Pea plants were grown in complete culture solution and in deficienciesof phosphorus, nitrogen, or potassium for a period of about5 weeks. Excised roots of these plants were treated with a complete,aerated culture solution for varying periods of time and thechanges in respiration rate, phosphorus, nitrogen, potassium,sugar, and starch contents measured.
2. There were changes infresh weight and dry weight of the excisedroots during treatment.The dry weight decreased with time butthe water content changeswere variable. Uptake of water wascorrelated with uptake ofpotassium and sucrose content in someinstances.
3. There wasno evidence of a ‘salt respiration’ inthose caseswhere active accumulation occurred.
4. The rates of gain or lossof phosphorus, nitrogen, or potassiumat 0 hours, 8 hours, and16 hours were calculated and it wasfound that the rate dependedboth on content of element in theroot and the sugar cotent.There was very little evidence thatone element affected therate of uptake of another. Simultaneousloss of one elementand gain of another occurred in some instances.
5. The observationsappear to be best explained on the assumptionthat the absorbedions are fixed in the cells in the form ofloosely bound compoundsand that these compounds are formedfrom sugars.

     

Stereospecificity of hydrogen transfer by pyridine nucleotide-dependent enoyl reductases in fatty acid synthesis: Studies with enzymes obtained from developing castor bean seeds and Chlorella vulgaris

The mechanism of hydrogen incorporation into fatty acids wasinvestigated with fatty acid synthetase systems from developingcastor bean seeds and Chlorella vulgaris. Fatty acids synthesizedin the presence of D₂O or stereospecifically deuterium-labeledNADPH or NADH were isolated and analyzed by mass spectrometryto examine the localization of deuterium atoms in the molecule.The stereospecificities of ß-ketoacyl-acyl carrierprotein (ACP) reductase and enoyl-ACP reductase for reducedpyridine nucleotide were determined with acetoacetyl-ACP andcrotonyl-ACP as substrates. The products were also analyzedby gas chromatography-mass spectrometry. The following resultswere obtained:

1. ß-Ketoacyl-ACP reductases from both castor bean seedsand C. vulgaris used the B-side hydrogen of NADPH.
2. Enoyl-ACPreductase from C. vulgaris required NADH for the activity.
3. Enoyl-ACPreductase from castor bean seeds used the A-side hydrogenofNADPH, whereas that from C. vulgaris used the B-side hydrogenof NADH.
4. When stearate was synthesized with the crude fattyacid synthetasefraction from castor bean seeds, hydrogen atomsfrom water werefound on the even-numbered methylene carbonatoms (two hydrogenatoms per carbon atom) and some were foundon the odd-numberedmethylene carbon atoms. Hydrogen atoms fromthe B-side of NADPHwere found on the odd-numbered methylenecarbon atoms (one hydrogenatom per carbon atom). Hydrogen atomsfrom the A-side of NADPHwere also found on the odd-numberedmethylene carbon atoms,but the number of incorporated hydrogenatoms was less thanexpected.

(Received October 17, 1979; )     

The Isolation of l-Quinic Acid from the Apple Fruit

1. A method is described by means of which several grammes ofl-quinicacid were isolated from young fruits of the WorcesterPearmainapple stored for a number of days in nitrogen.
2. Theessential stages in the method are the removal of colouringmatter from extracts of the frozen ground pulp tissue of thefruit with charcoal, the removal of amino acids by absorptionon cation exchange resin, and the separation of the organicacid from sugars by adsorption of the former on anion exchangeresin. Finally, the quinic acid was separated from malic acidby fractional displacement from the anion exchange resin.
3. Thecharacterization of the isolated quinic acid, and of malicacidalso isolated from the fruits, is described.
4. Citric acid isshown to be formed by oxidation of quinic acidwith hot hydrogenperoxide.
5. The possible function of quinic acid in the applefruit andin plants generally is discussed.

     

The Absorption of Ions by Excised Root Systems: I. APPARATUS AND PRELIMINARY EXPERIMENTS

1. An apparatus is described by means of which the absorptionofions from a complete nutrient solution of constant compositionby excised root systems of plants, grown under known nutrientdeficiencies, may be measured in standard conditions of aerationand temperature. Results of some prelimi nary experiments aredescribed.
2. It was found that the roots readily absorbed theelement inwhich they were deficient, but tended to lose thoseelementswhich were already present in normal amounts.
3. Therewas almost invariably a loss in fresh weight of the rootsafterthe absorption period and also a loss in dry weight. Thislossappears to be complex and is partly attributable to lossofrespiratory material.
4. The addition of 2 per cent. sucroseto the solution from whichthe root systems of phosphorus-deficientbarley plants wereabsorbing increased the nitrogen and phosphoruscontents ofthe roots and maintained the potassium content,while in absenceof sucrose only the phosphorus content increased,but this increasewas significantly less than in the presenceof sucrose.
5. It was shown that roots excised from plants growingin soilwere capable of absorbing phosphorus or nitrogen—elementsin which they were apparently deficient.
6. The interpretationof data obtained from excised roots is discussed,and it isconcluded that excised roots from plants grown incomplete nutrientare not likely to behave in the same way,as regards absorption,as corresponding roots of intact plants,but that roots grownunder conditions of deficiency will behaverather similarlywhether excised or intact. This fact providesa potential methodfor diagnosing and evaluating nutrient deficiencies.
7. The low-saltcondition of roots postulated by Hoagland and Broyeris notnecessarily the primary requisite for rapid absorptionof aparticular ion. It is rather that the roots should be deficientin that ion. The roots could be high in other salts.

     

Microbiological Synthesis of Fat: PRELIMINARY SURVEY OF THE FAT-PRODUCING MOULDS

1. A survey of potential fat-producing moulds has shown that atleast 40 strains from 10 species are of interest.
2. These havebeen grown on five different media and A. nidulans,P. spinu-losum,P. javanicum, P. piscarium, P. flavo-cinereum,P. oxalicum,A. flavus, A. flavipes have shown the most promise.
3. The fatcontent on felt weight was maximal at 39?7 per cent,with A.flavipes and 34?6 per cent, with F. lini, and on usedsugarwas maximal at 9?3 per cent, with A. flavipes and 6?7per cent,with A. nidulans.
4. The potential value of micro-organisms asfat producers is discussedwith reference to the moulds.

     

The Time Factor in Studies of Growth Inhibition in Excised Organ Sections

1. Apprehension over the adequncy of current techniques stimulateda detailed study of the time factor in the arsenate inhibitionof growth and respiration in excised stem and root sectionsof Pisum sativum.
2. Growth inhibition by arsenate sets in veryslowly, its rateof onset being related to the molar concentration(C) of arsenateate by the relation where T₅₀ is the time taken in hours to reduce the growthrateto 50 per cent of the control and K is a constant. An explanationof the physiological basis of this relationship is attempted.
3. Estimates were made of the final steady growth rate (relativeto control) in various arsenate concentrations. The inhibitionscalculated from this rate are held to approximate to the truearsenate effect and are shown to be very different from thosecalculated from ‘total growth’ measures.
4. Respirationof growing stem sections is not inhibited by thelow arsenateconcentrations that inhibit growth. Some inhibitionis indicatedat high concentrations (3 ? 10^–4M. and over)but onlyafter 15-20 hours of exposure.
5. Two per cent sucrose has noeffect on the arsenate inhibiitionof stem growth. Sucrose,however, markedly stimulates respirationin stem sections, butthis stimulation is prevented by arsenate.
6. The misinterpretationswhich may arise as a result of ignoringthe time factor in inhibitionstudies in excised organ sectionsare discussed and the desirabilityof constructing completegrowth curves in all such studies isstressed.

     

Studies on Plant Growth Hormones: I. BIOLOGICAL ACTIVITIES OF 3-INDOLYLACETALDEHYDE AND 3-INDOLYLACETONITRILE

1. Two neutral plant hormones, one isolated recently from plants(3-indolylacetonitrile) and the other (3-indolylacetaldehyde)reported to be present in plants, are avaible as pure syntheticcompounds for investigation of their biological activities.This paper is mainly concerned with their effects on cellelongationin the Avena coleoptile
2. 3-Indolylacetaldehyde is considerablyless active than 3-indolylaceticacid in the Avena straight-growthtest; for example, a 1.0 mg./l.solution of the aldehyde showsan activity equivalent to thatof a 0.1 mg./l. solution of theacid
3. An acidic substance is produced in solutions of the aldehydeduring the period of assay. In some experiments it accountsfor all of the activity shown by the aldehyde solutions, onthe assumption that it is 3-indoylacetic acid, and in otherexperiments it shows a greater activity than that of the aldehydesolutions from which it was obtained. Therefore, it is concludedthat 3-indolylacetaldehyde, itself is either inactive or inhibitory.Acid production in aldehyde solutions in vitro is much lower,a fact which suggests that there is enzymatic oxidation of aldehydeto acid in the presence of coleoptiles.
4. The activities of3-indolylacetaldehyde in the pea test andin root-inhibitionand of 3-indolylacetone in the straight-growthtest are brieflyreported.
5. 3-Indolylacetonitrile is considerably more activethan 3-indolylaceaticacid in the Avena straight-growth test;for erample, a 0.1 mg./l.solution of the nitrile shows an activityequivalent to a 1.0mg./l. solution of the acid. The inhibitoryeffect at concentrationsabove 1.0–10.0 mg./l. is lesswith the nitrile than withthe acid.
6. There is negligible productionof acid in solutions of the nitrileboth in vitro and in thepresence of Avena coleoptiles at temperaturesranging from –18?to 25? C. for varying lengths of time.The possibility of enzymaticconvesion of nitrile to acid insidethe cells of the coleoptileis discussed
7. The activities of 3-indolylacetamide and of 2:4-dichlorophenoxyaceticacid and the corresponding nitrile are considered in this connexion
8. The nitrile is destroyed by treatment with alkali but notbyacid. In the light of these results, it is desirable to re-examineprevious work on identification of auxins in plants by theiracid and alkali sensitivity. Evidence for the existence of thenitrile in a number of other plants is presented.

     

An Examination of a Method of Auxin Assay using the Growth of Isolated Sections of Avena Coleoptiles in Test Solutions

1. Methods of auxin assay using the Avena coleoptile are discussed.
2. A review is given of experimental procedure and evaluationofresults in the straight-growth method using isolated sectionsof coleoptiles in test solutions.
3. Possible sources of variationin the straight-growth methodare investigated and discussed.
4. A revised experimental procedure for the straight-growth methodis described.

The author wishes to thank Professor E. Ashby for his adviceand encouragement during the course of the experiments. Thanks are also due to Mr. D. Payne, a technical assistant inthe Botany Department, for his assistance in some of the assays.     

Physiological Studies in Plant Nutrition: XVI. The Mineral Nutrition of Bracken

1. The nutritional requirements of the bracken sporophyte wereexamined in a factorial combination of 3 potassium levels x2phosphorus levels x3 solution types, in which the cations weremainly Na, Ca, or NH₄.
2. The effects of nitrogen and phosphorusdeficiency and of shadingunder conditions of high and low potassiumsupply were alsoexamined.
3. Leaf area, total dry weight, andnet assimilation rates aremuch depressed by lack of eitherK or P.
4. Water contents of leaves and rhizomes are generallyincreasedby lack of K when Na is present in the culture mediumbut notwhen Ca is in excess.Phosphorus causes diminished succulence.
5. Starch content increases as phosphorus supply is lowered.Withincreasing doses of K, starch content falls in the highcalciumsolution, while increasing in the other two solutiontypes.
6. Reduction of light intensity is shown to have a beneficialeffectunder conditions of K deficiency.
7. Analysis revealscomplex interactions between the various factors,and possibletoxic effect of Na, NH₄, and excess P. An estimateof the relativeimportance of net assimilation rate, leaf numberand area perleaf in determining total plant size has been calculatedforthe different nutrient treatments. Comparisons are madewithprevious results for barley and flax.

     

Origin of Foliar Nitrogen and Changes in Free Amino-Acid Composition and Content of Leaves, Stubble, and Roots of Perennial Ryegrass During Re-growth after Defoliation

Nitrogen re-mobilization and changes in free amino acids werestudied as a function of time in leaves, stubble, and rootsduring ryegrass (Lolium perenne L.) re-growth. Experiments with¹⁵N labelling clearly showed that during the first days nearlyall the nitrogen in new leaves came from organic nitrogen re-mobilizedfrom roots and stubble. On the days of defoliation, stubblehad the highest content of free amino acids with 23 mg per gdry weight against 15 mg and 14 mg in leaves and roots, respectively.The major amino acids in leaves were asparagine (23% of totalcontent in free amino acids), aminobutyrate, serine, glutamine,and glutamate (between 7% and 15%) whereas in roots and stubblethe contribution of amides was high, especially asparagine (about50%). Re-growth after cutting was associated with a rapid increaseof the free amino acid content in leaves, with a progressivedecrease in roots while stubble content remained virtually unchanged.In leaves, asparagine increased from the first day of re-growth,while the aspartate level remained unchanged and glutamine increasedstrongly on the first day but decreased steadily during thenext few days of re-growth. Asparagine in stubble and rootschanged in opposite directions: in stubble it tended to increasewhereas in roots it clearly decreased. In contrast, stubbleand roots showed a similar decrease in glutamine. In these twoplant parts, as in leaves, aspartate remained at a low level.Results concerning free amino acids are discussed with referenceto nitrogen re-mobilization from source organs (stubble androots) to the sink organ (regrowing leaves). Key words: Lolium perenne L, re-growth, nitrogen, free amino acids, glutamine, asparagine     

Gametogenesis and Embryogeny of Tamarix ericoides Rottl

1. The haploid chromosome number in Tamarix ericoides Rottl., reportedfor the first time, is twelve.
2. The archesporial cell is single,rarely double.
3. There is no tetrad formation, division of themegaspore mother-cell;instead, a four nucleate embryo-sac results.
4. The nuclei are originally arranged in a cruciform type, butlater form a I+3 arrangement.
5. As a result of the third division,the embryo-sac is again four-nucleate,with two haploid nucleiat the micropylar end and two triploidnuclei at the chalazalend.
6. The cells of the embryo-sac are formed at the end ofthe fourthdivision, the embryo-sac thus representing the sixteennucleatecondition.
7. The development of the embryo-sac of Tamarixericoides conformsto the Fritillaria-type.
8. The endospermis free nuclear, and the embryo is characteristicin developinga massive suspensor and a large pad of cellulartissue fromthe proximal cell.
9. Double embryo-sacs and the occurrence ofpolyembryony are reportedfor the first time in the family.

     

ADAPTIVE FORMATION OF NITRATE REDUCING SYSTEM IN ANABAENA CYLINDRICA

1. Changes in capacities for reducing nitrate, nitrite and hydroxylaminecaused by provision or depletion of various nitrogen sourceswere investigated with a nitrogen fixing blue-green alga, Anabaenacylindrica, and adaptive nature of these reducing system wasdemonstrated.
2. It was found that, under light-aerobic conditions,nitrate-and nitrite- reducing systems were induced by nitrateor nitritebut not by N₂ ammonia and glutamate. On the otherhand, theactivity of enzymes pertaining to hydroxylamine reductionwasstimulated equally by nitrate, nitrite and N₂. The latteractivitywas suppressed markedly in the presence of ammoniaor glutamate.
3. Adaptive formation of nitrite reducing systemis completelyinhibited by chloramphenicol, a potent inhibitorof proteinsynthesis. No formation was also observed under theanaerobiccondition or in the dark.
4. On the basis of thesefindings, a tentative scheme for pathwaysof nitrate reductionand nitrogen fixation in Analaena cylindricawas proposed.

(Received August 22, 1962; )     

REDUCTION OF DEHYDRO-L-ASCORBIC ACID IN GREEN LEAVES

1. The capacity of green leaves for absorbing and converting substancesrelated to L-ascorbic acid was investigated, using detachedleaves of various plants, including soybean, pea, barley andspinach.
2. The greater portion of the absorbed dehydroascorbicacid wasrecovered in the leaves as ascorbic acid, minor portionsbeingdiscovered as dehydroascorbic acid and 2,3-diketogulonicacid. The recovery was about 60% of the absorbed dehydro ascorbicacid, in the cases of detached soybean and barley leaves, forinstance, thus suggesting the instability of the substance invivo.
3. The absorption and conversion of ascorbic acid and 2,3-di-ketogulonic acid in detached green leaves were also investigated.Most of the absorbed ascorbic acid reappeared in the leaves.On the other hand, no evidence for the conversion of 2,3-diketogulonicacid into ascorbic and dehydroascorbic acids was observed. Thegreater portion of the absorbed 2, 3-diketogulonic acid seemsto be decomposed in the leaves, under the condition of the presentstudy.

(Received April 17, 1961; )     

The Assimilation of Nitrogen from Ammonium Salts and Nitrate by Fungi

1. The assimilation of inorganic nitrogen by Scopulariopsis brevicaulisand some physiologically similar species has been studied. Theirfailure to assimilate completely from ammonium sulphate hasbeen shown to be due to the fall in pH of the medium inducedby the initial uptake of ammonia.
2. Complete assimilation ofammonia takes place in the presenceof the neutral salts ofeach of thirteen organic acids investigated.The organic acidsact primarily through their buffering effectwhich preventsor slows down the fall in pH. They are not specificallyrequiredfor ammonia assimilation by these fungi and can beeffectivelyreplaced by certain inorganic buffers.
3. The influence of severalexternal factors on the rate of assimilationof ammonia, nitrate,and nitrite has been studied in S. brevicaulis.In correspondingconditions the mycelium assimilates ammoniamore rapidly thannitrate over a wide range of conditions.
4. Ammonia, even invery low concentration, completely suppressesnitrate assimilationwhen both sources of nitrogen are presenttogether. Nitrite,however, is assimilated simultaneously withammonia. It is thereforeconcluded that ammonia blocks the reductionof nitrate to nitriteby the fungus.
5. The suppression of nitrate assimilation inthe presence of ammoniais common to many mould fungi besidesS. brevicaulis, and isbelieved to have adaptive significancein natural habitats.
6. The nitrate-reducing and assimilatingsystem is formed, evenwhen S. brevicaulis is grown in completeabsence of nitrate(ammonia medium with organic acid). It comesinto action rapidlywhen the inhibiting effect of ammonia isremoved. Similarly,nitrate-grown mycelium is capable of assimilatingammonia atmaximal rate without any adaptive lag.