Leucine Biosynthesis in Fungi: Entering Metabolism through the Back Door

doi:10.1128/MMBR.67.1.1-15.2003

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Microbiology and Molecular Biology Reviews, March 2003, p. 1-15, Vol. 67, No. 1
1092-2172/03/$08.00+0 DOI: 10.1128/MMBR.67.1.1-15.2003
Copyright © 2003, American Society for Microbiology. All Rights Reserved.

Leucine Biosynthesis in Fungi: Entering Metabolism through the Back Door

Gunter B. Kohlhaw^*

Department of Biochemistry, Purdue University, West Lafayette, Indiana 47907

SUMMARY

INTRODUCTION

EVOLUTIONARY ASPECTS

{alpha}-ISOPROPYLMALATE SYNTHASE OF S. CEREVISIAE: ISOFORMS, COMPARTMENTATION, AND REGULATION

    The Leu4p and Leu9p Isoforms and Their Intracellular Localization

    The Unexpected Role of Leu5p

    Regulation of {alpha}-Isopropylmalate Synthases

        Regulation of LEU4 expression.

        Regulation of synthase activity.

ISOPROPYLMALATE ISOMERASE (LEU1P) AND ß-ISOPROPYLMALATE DEHYDROGENASE (LEU2P) OF S. CEREVISIAE

    Intracellular Localization and the Question of an Isomerase-Dehydrogenase Complex

    Regulation of LEU1 and LEU2 Expression

LEU3P: A DUAL-FUNCTION TRANSCRIPTION FACTOR

    Leu3p as Transcriptional Activator and Repressor

    Structure-Function Relationships: the Self-Masking Model

        Structural aspects of Leu3p.

        Are auxiliary factors needed to render the activation domain of Leu3p ineffective?

        Masking versus repression.

        The ‘middle homology region' of Leu3p.

HOW LARGE IS THE LEU3P REGULON?

MULTIPLE LAYERS OF CONTROL

BRANCHED-CHAIN AMINO ACID BIOSYNTHESIS IN OTHER FUNGI

    Neurospora crassa

    Other Species

LEUCINE AS METABOLIC SIGNAL

OUTLOOK

ACKNOWLEDGMENTS

REFERENCES

SUMMARY

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After exploring evolutionary aspects of branched-chain aminoacid biosynthesis, the review focuses on the extended leucinebiosynthetic pathway as it operates in Saccharomyces cerevisiae.First, the genes and enzymes specific for the leucine pathwayare considered: LEU4 and LEU9 (encoding the ${alpha}$ -isopropylmalatesynthase isoenzymes), LEU1 (isopropylmalate isomerase), andLEU2 (ß-isopropylmalate dehydrogenase). Emphasis isgiven to the unusual distribution of the branched-chain aminoacid pathway enzymes between mitochondrial matrix and cytosol,on the newly defined role of Leu5p, and on regulatory mechanismsgoverning gene expression and enzyme activity, including newevidence for the metabolic importance of the regulation of ${alpha}$ -isopropylmalatesynthase by coenzyme A. Next, structure-function relationshipsof the transcriptional regulator Leu3p are addressed, definingits dual role as activator and repressor and discussing evidencein support of the self-masking model. Recent data pointing ata more extended Leu3p regulon are discussed. An overview ofthe layered controls of the extended leucine pathway is providedthat includes a description of the newly recognized roles ofIlv5p and Bat1p in maintaining mitochondrial integrity. Finally,branched-chain amino acid biosynthesis and its regulation inother fungi are summarized, the question of leucine as metabolicsignal is addressed, and possible directions of future researchin this area are outlined.

INTRODUCTION

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There has in recent years been a renewed interest in the intricaciesof branched-chain amino acid biosynthesis, particularly leucinebiosynthesis, sparked by a number of new and sometimes surprisingobservations in the yeast Saccharomyces cerevisiae, the organismof choice for many investigators in this field. These observationsinclude the following. (i) First is the unusual partitioningof the pathway enzymes between the mitochondrial matrix andthe cytoplasm and its consequences (Fig. 1). While the generalaspects of this distribution pattern have been known for a longtime, there have been recent refinements, especially with respectto the ${alpha}$ -isopropylmalate synthase isoenzymes. In addition, hithertounknown transport systems have come to light that are essentialfor efficient branched-chain amino acid biosynthesis, as wellas for other processes. They include a transporter requiredfor the accumulation of coenzyme A (CoA) inside the mitochondria;a system for the export of Fe-S clusters from the mitochondrialmatrix to the cytoplasm, involving proteins whose primary functionis to serve as branched-chain amino acid aminotransferases;and a hypothetical transporter that facilitates the exit of ${alpha}$ -isopropylmalate from the mitochondria. (ii) Second is completionof the Saccharomyces genome sequencing project and the resultingdefinitive information on the number and structural relatednessof isoenzymes, questions of particular importance for the firstspecific step in leucine biosynthesis. It is now evident thatthere are two very closely related genes that encode ${alpha}$ -isopropylmalatesynthase. Together, they are capable of producing three isoformsof the enzyme, two located in the mitochondrial matrix and onethat remains cytoplasmic. (iii) Third are new findings regardingmetabolic regulation, which emphasize the signal character ofthe leucine pathway intermediate ${alpha}$ -isopropylmalate and also assigna role to the transcriptional regulator Leu3p that reaches beyondbranched-chain amino acid biosynthesis. Great strides have beenmade toward understanding the mechanism of action of Leu3p;it appears to be a "self-masking" regulator that represses transcriptionin the absence of ${alpha}$ -isopropylmalate and becomes a strong transcriptionalactivator in its presence. Remarkably, the Leu3p- ${alpha}$ -isopropylmalatesystem works as well when expressed in mammalian cells as itdoes in yeast. Since mammals do not have the capacity to producebranched-chain amino acids, the yeast Leu3p- ${alpha}$ -isopropylmalatesystem may be useful as a novel hormone- and antibiotic-independentregulator of therapeutic genes.

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FIG. 1. Compartmentation of the branched-chain amino acid biosynthetic pathways of S. cerevisiae. The boxed characters refer to the genes involved directly or indirectly in the pathways. Their protein products are as follows: ILV1, threonine deaminase; ILV2, acetohydroxy acid synthase catalytic subunit; ILV5, acetohydroxy acid reductoisomerase; ILV3, dihydroxy acid dehydratase; BAT1, mitochondrial branched-chain amino acid aminotransferase; BAT2, cytosolic branched-chain amino acid aminotransferase; LEU4l, ${alpha}$ -isopropylmalate synthase I, long form; LEU4s, ${alpha}$ -isopropylmalate synthase I, short form; LEU9, ${alpha}$ -isopropylmalate synthase II; X, hypothetical ${alpha}$ -isopropylmalate transporter; LEU1, isopropylmalate isomerase; LEU2, ß-isopropylmalate dehydrogenase; LEU5, protein necessary for the accumulation of CoA within the mitochondria; presumably an importer of CoA or precursor thereof; ATM1, ABC transporter involved in exporting Fe-S clusters to the cytosol; the implied interaction between Bat1p and Atmp is hypothetical (58, 66). Abbreviations: KB, ${alpha}$ -ketobutyrate; AALD, active acetaldehyde; PYR, pyruvate; AL, acetolactate; AHB, ${alpha}$ -aceto- ${alpha}$ -hydroxybutyrate; DHIV, ${alpha}$ ,ß-dihydroxyisovalerate; DHMV, ${alpha}$ ,ß-dihydroxy-ß-methylvalerate; KIV, ${alpha}$ -ketoisovalerate; KMV, ${alpha}$ -keto-ß-methylvalerate; ${alpha}$ -IPM, ${alpha}$ -isopropylmalate; ß-IPM, ß-isopropylmalate; KIC, ${alpha}$ -ketoisocaproate; Fe/S, iron-sulfur cluster. Not shown for reasons of clarity: transport of leucine and/or KIC back into the mitochondria.

In this review, an attempt is made to critically evaluate earlierresults and use them together with recent developments to givethe reader a comprehensive picture of the extended leucine pathwayand its metabolic ramifications in S. cerevisiae. In addition,to gain a wider perspective, information available on branched-chainamino acid biosynthesis in other fungi is summarized.

EVOLUTIONARY ASPECTS

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As depicted in Fig. 1 (using the nomenclature for S. cerevisiae),the biosynthesis of the branched-chain amino acids consistsof a common pathway that leads from pyruvate and ${alpha}$ -ketobutyrateto valine and isoleucine and a branch that leads from the immediateprecursor of valine, ${alpha}$ -ketoisovalerate, to leucine. These pathwaysoperate in eubacteria (106), archaebacteria (112), fungi (41,59), and green plants (43, 62, 79). They are not found in mammals,a fact that was important in the development of herbicides thatspecifically inhibit branched-chain amino acid biosynthesis(24). Whenever nucleotide or amino acid sequences of genes orenzymes involved in the branched-chain amino acid pathways werecompared in different species, significant similarities werefound (an example is shown in Fig. 2). There are also strongfunctional similarities among enzymes from different speciesthat relate to such properties as pH optima, kinetics, and cationrequirements. It has been concluded, based on these observations,that the branched-chain amino acid pathways are very ancientand may have been derived from a common ancestor of the threemajor lineages (112). However, while the basic catalytic functionsof the enzymes that make up these pathways have remained largelyunchanged throughout evolution, differences with respect toother properties such as gene organization, gene and enzymeregulation, and pathway compartmentation clearly exist. Forexample, the genes involved in branched-chain amino acid biosynthesisin Escherichia coli are organized in operons whereas those ofS. cerevisiae or Neurospora crassa are found throughout thegenome, often on different chromosomes. The ilvGMEDA, ilvBN,and leuABCD operons of E. coli are regulated by attenuationof transcription in response to the availability of the cognateaminoacyl-tRNAs (106, 113); the ilvIH operon is under the controlof Lrp, the leucine-responsive regulatory protein (19). By contrast,the transcription of the ILV and LEU genes of S. cerevisiaeand N. crassa is individually controlled by a regulatory protein(Leu3p) in conjunction with the leucine precursor ${alpha}$ -isopropylmalateand is also subject to other, more general controls (see below).Comparing compartmentation of the branched-chain amino acidbiosynthetic enzymes in different eukaryotic species again revealssignificant differences that demonstrate how difficult it isto foretell the way(s) in which problems of adaptation to newenvironments have been solved. For example, all of the enzymesof the common pathway plus most of the ${alpha}$ -isopropylmalate synthaseactivity of S. cerevisiae are found in the mitochondrial matrixwhile the two remaining enzymes specific for leucine synthesisare cytoplasmic (Fig. 1; also see below). By contrast, the enzymesfor leucine biosynthesis in spinach are located entirely tothe chloroplasts (43); subfractionation showed that spinach ${alpha}$ -isopropylmalate synthase is tightly associated with the thylakoidmembranes, site of the light reactions.

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FIG. 2. Alignment of the R-regions (boxed) of known ${alpha}$ -isopropylmalate synthase sequences. Amino acid sequence identities are indicated by bold letters, similarities are indicated by asterisks. Abbreviations and references: ScI, S. cerevisiae ${alpha}$ -isopropylmalate synthase I (10; the amino acid positions shown at the top refer to this sequence); Sc II, S. cerevisiae ${alpha}$ -isopropylmalate synthase II (107); Cg, Corynebacterium glutamicum (82); Ba, Buchnera aphidicola (16); Hi, Haemophilus influenzae (34); Mj, Methanococcus jannaschii (18); St, Salmonella enterica serovar Typhimurium (90); Ll, Lactococcus lactis (38); Ta, Thermus aquaticus (GenBank accession number U52907). Reprinted from reference 23 with permission of the copyright owner.

As an aside, the leucine pathway may have played a more importantrole in evolution than is evident from its present "peripheral"function. Miller and coworkers (54) have proposed that it mayhave served as the forerunner of the Krebs cycle (which, inits ancient form, is thought to have arisen as a means of supplyingthe cell with glutamate, aspartate, and related amino acids).This scenario assumes that the leucine pathway-specific geneswere duplicated and mutated so that their protein products wouldaccommodate the respective substrates of the Krebs cycle. Assumingthat an ${alpha}$ -isopropylmalate synthase homologue would act as citratesynthase, that isopropylmalate isomerase homologues would functionas aconitase and fumarase and that ß-isopropylmalatedehydrogenase homologues would act as isocitrate dehydrogenaseand malate dehydrogenase, and also that a fatty acid reductivecarboxylase was available to catalyze the interconversion ofsuccinate and ${alpha}$ -ketoglutarate, the only additional enzyme requiredto complete the cycle would then have been succinate dehydrogenase.It was also assumed that the Krebs cycle-related amino acids,because of their apparent great abundance under prebiotic conditions,would have been depleted later than the less abundant branched-chainamino acids, implying that branched-chain amino acid biosynthesispreceded that of glutamate and aspartate.

${alpha}$ -ISOPROPYLMALATE SYNTHASE OF S. CEREVISIAE: ISOFORMS, COMPARTMENTATION, AND REGULATION

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The Leu4p and Leu9p Isoforms and Their Intracellular Localization
It had long been surmised on genetic grounds that yeast cellselaborate two independent ${alpha}$ -isopropylmalate synthases (7). Withthe completion of the sequencing of the S. cerevisiae genome,it became clear that there are indeed two, and only two, genes,designated LEU4 and LEU9, that encode ${alpha}$ -isopropylmalate synthases(21, 107). LEU4 is located on chromosome XIV (27), and LEU9is located on chromosome XV (107). The primary structures ofthe two isoenzymes Leu4p ( ${alpha}$ -isopropylmalate synthase I) and Leu9p( ${alpha}$ -isopropylmalate synthase II) are 83% identical. In wild-typecells, Leu4p accounts for about 80% of the total synthase activity.It is also the better understood of the two isoenzymes.

An interesting aspect of the LEU4 gene is that it itself cangenerate two forms of ${alpha}$ -isopropylmalate synthase. This conclusionwas first arrived at when it was observed that two of four majortranscription start sites utilized in vivo are located downstreamfrom the ATG at the beginning of the open reading frame (ORF)of LEU4 (10), which suggested that LEU4 mRNAs might be translatedinto full-length and shortened versions of the isoenzyme. Thiswas subsequently shown to be true. As it turns out, the full-lengthform of ${alpha}$ -isopropylmalate synthase I contains at its N terminusa signal sequence that directs the enzyme to the mitochondrialmatrix; the short form, starting at what would be the secondin-frame AUG of the long mRNA, lacks the 30 N-terminal residuesof the long form and hence the mitochondrial import sequence.It remains in the cytoplasm (11). These observations providedan early example of how differential transcription can be usedto generate mitochondrial and nonmitochondrial forms of thesame enzyme.

Why should ${alpha}$ -isopropylmalate synthase be localized in two cellularcompartments? Its presence in the mitochondrial matrix can berationalized by arguing that both of the enzyme's substrates,acetyl-CoA and ${alpha}$ -ketoisovalerate, are prevalent in that compartment.The reason that ${alpha}$ -ketoisovalerate accumulates in mitochondriastems from the fact that all of the enzymes required to convertpyruvate and active acetaldehyde to ${alpha}$ -ketoisovalerate are alsolocated in this organelle (93) (Fig. 1). Given this logic, itis not immediately obvious why ${alpha}$ -isopropylmalate synthase shouldalso be available in the cytoplasm. It has been speculated thatthe reason for this may have to do with the ability of S. cerevisiaeto grow both aerobically and anaerobically, i.e., both withand essentially without functional mitochondria. Under anaerobicconditions, the mitochondrial form of ${alpha}$ -isopropylmalate synthasemight be unstable or nonfunctional for other reasons and thecytosolic form might take over. A similar situation might ariseunder glucose repression, a condition in which cells also elaborateonly very few mitochondria with poorly developed cristae (68).These questions of compartmentation seem to be limited to Leu4p,since Leu9p is apparently found only in the mitochondria (86).

While the synthesis of ${alpha}$ -isopropylmalate occurs largely withinthe mitochondria, its conversion to leucine takes place in thecytoplasm (94), as discussed in more detail below and shownin Fig. 1.

The Unexpected Role of Leu5p
An early tetrad analysis (7) had indicated that ${alpha}$ -isopropylmalatesynthase activity in yeast depended on two separate genes, whichwere designated LEU4 and LEU5. (A leu4 leu5 strain is a leucineauxotroph.) While LEU4 was identified as a structural gene,LEU5 was thought to either directly encode the second synthaseor provide some function needed for the expression of a secondstructural gene. Subsequent experiments showed that strainsdeficient in LEU5 behaved as petite strains, i.e., did not growwell on most nonfermentable carbon sources, and that LEU5 wasprobably not the second structural gene (32). The conundrumof LEU5 was solved by the recent surprising demonstration thatthe gene encodes a carrier protein located in the mitochondrialinner membrane that is required for the buildup of CoA insidethe mitochondria (86). It presumably serves to transport CoA,or a precursor thereof, from the cytosol, its likely site ofsynthesis, to the mitochondrial matrix to replenish the CoApool and allow efficient synthesis of acetyl-CoA Fig. (1). Thefact that a ${Delta}$ leu5 strain exhibits a 15-fold drop in the mitochondrialCoA level, accompanied by a slight increase in the cytoplasmicCoA level, is consistent with the carrier role of Leu5p andmight also explain the petite-like nature of leu5 cells. Additionalsupport for a carrier role of Leu5p comes from the observationthat intact mitochondria from leu5 cells are essentially incapableof synthesizing ${alpha}$ -isopropylmalate, even though they contain ${alpha}$ -isopropylmalate-synthesizingactivity that can easily be detected after lysis of the mitochondria(86).

LEU5 was later joined by several additional genes whose absencein a leu4 background substantially decreases the capacity tosynthesize ${alpha}$ -isopropylmalate (33). The additional genes (complementationgroups) were designated LEU6, LEU7, and LEU8. They have notbeen analyzed, and we do not know the functions of their proteinproducts. It is entirely possible, though, that either LEU7or LEU8 (neither of which shows petite-like deficiencies whenmutated) is identical to LEU9.

Regulation of ${alpha}$ -Isopropylmalate Synthases
Regulation of LEU4 expression. The regulation of LEU4 and its major gene product is more complexthan might be expected if the synthesis of ${alpha}$ -isopropylmalatewere to serve the leucine pathway only. Gene expression control,studied with the aid of a LEU4-lacZ fusion, was found to dependon three distal elements and one proximal element of the LEU4promoter (52). Of these, the most distal element correspondedto a binding site for the transcriptional regulator Leu3p (UAS_LEU).Mutation of UAS_LEU resulted in the loss of control by Leu3p.The other two elements in this region were identified as likelyGen4p binding sites; their inactivation by mutation eliminatedgeneral amino acid control of LEU4. Transcriptional activationfrom all three distal elements was additive, implying that theregulatory proteins bound to these elements do not compete withone another or act synergistically. The fourth, proximal regulatoryelement showed similarity to the Bas2p response element of theHIS4 promoter (102). Bas2p (Phos2p) is a "global," homeobox-containingregulatory protein that is required, together with Bas1p, forincremental HIS4 transcriptional activation and also activatestranscription of the secreted acid phosphatases. LEU4 gene expressiondecreased by as much as 45% when the inorganic phosphate concentrationin the growth medium was increased from a depleted level to5 mM. This response was absent when the presumed BRE of theLEU4 promoter was made nonfunctional by mutation (52). Eliminationof the BRE also caused a drop in LEU4 expression under phosphatesufficiency.

Regulation of synthase activity. The enzymatic activity of ${alpha}$ -isopropylmalate synthase is subjectto two major controls by small molecules. The first is feedback(end product) inhibition by leucine. The apparent inhibitorconstants for L-leucine were determined to be about 0.1 mM forthe long form of ${alpha}$ -isopropylmalate synthase I (26), about 0.4mM for the short form of synthase I (11), and about 1 mM for ${alpha}$ -isopropylmalate synthase II (27), all at pH 7.2. The secondtype of activity regulation of ${alpha}$ -isopropylmalate synthase isZn²⁺-dependent reversible inactivation by CoA (44, 103, 104,105). While CoA is a product of the reaction catalyzed by ${alpha}$ -isopropylmalatesynthase, the inactivation by CoA clearly is not simple productinhibition. Rather, it requires a second binding site for CoAthat, in contrast to the substrate/product site, opens up onlyin the presence of zinc ions (104). In the absence of zinc andother divalent metal ions, CoA (bound at the product site) isa competitive inhibitor with respect to acetyl-CoA, with anapparent inhibitor constant of 65 to 70 µM; binding tothe second CoA site in the presence of 50 µM Zn²⁺ occurswith an apparent dissociation constant of about 35 µMand causes a rapid, albeit noninstantaneous inactivation ofthe enzyme. Acetyl-CoA neither prevents nor reverses this inactivation.However, experiments performed in situ, i.e., in permeabilizedcells, demonstrated that reactivation is possible with physiologicalconcentrations of ATP or ADP. ATP is also capable of protecting ${alpha}$ -isopropylmalate synthase against CoA inactivation. As mightbe expected from these results, protection was found to increasewith increasing adenylate energy charge values (44).

Further support for the physiological importance of the CoAinactivation and its occurrence in vivo comes from a recentdemonstration that strains in which ${alpha}$ -isopropylmalate synthaseI is no longer regulated by CoA are resistant to 5',5',5'-trifluoroleucine,owing to overproduction and secretion of leucine (23). Two suchstrains were identified within a group of seven spontaneous,trifluoroleucine-resistant mutants; the other five were shownto contain an ${alpha}$ -isopropylmalate synthase I that had largely orcompletely lost its sensitivity to leucine. Remarkably, allseven mutations (six point mutations and one codon deletion)map to a short, 39-residue region near the C terminus of theenzyme, designated the R region by the authors. The R regionis also present in ${alpha}$ -isopropylmalate synthase II, with only sixconservative changes, and is found largely conserved (69 to56% similarity) in the synthases from seven bacterial species(Fig. 2). It has not been established whether the R region containspart or all of the leucine and CoA-Zn²⁺ binding sites or whetherit is involved in the signal propagation caused by these molecules.The fact that leucine can partially protect yeast ${alpha}$ -isopropylmalatesynthase against CoA inactivation (105) is consistent with bothinterpretations. Whatever the mechanism, the observations byCavalieri et al. (23) clearly show that the R region of ${alpha}$ -isopropylmalatesynthase contains subregions that respond to either leucineor CoA-Zn²⁺ and that both types of control must function toprevent overproduction of leucine.

Yet another hint at the metabolic importance of the CoA-Zn²⁺inactivation of yeast ${alpha}$ -isopropylmalate synthase comes from thework of Pronk et al. (87). These authors observed that a nullmutant lacking PDA1, the gene encoding the E1 ${alpha}$ subunit of thepyruvate dehydrogenase complex, exhibited a partial leucinerequirement. Since this requirement could not be satisfied byvaline, the basis for this phenotype was thought to lie withinthe leucine pathway itself. Knowing that deletion of the PDA1gene eliminates pyruvate dehydrogenase activity and sharplyelevates the CoA/acetyl-CoA ratio in the mitochondria, the authorssuggested that the Leu^- phenotype of the pda1 null mutant mightstem from increased CoA inactivation of ${alpha}$ -isopropylmalate synthase.It has not been ruled out, however, that the diminished availabilityof acetyl-CoA itself might contribute to the partial leucineauxotrophy.

In a wider metabolic context, it is noteworthy that CoA inactivationis not limited to ${alpha}$ -isopropylmalate synthase but is also observedwith homocitrate synthase, the enzyme catalyzing the first committedstep in lysine biosynthesis, and with ß-hydroxy-ß-methylglutaryl-CoAreductase, a key enzyme in the biosynthesis of sterols (101,103). (In the latter case, the actual inactivating species isprobably CoA disulfide [37].) By contrast, citrate synthaseis entirely resistant to inactivation by CoA or derivativesthereof. This scenario was interpreted to mean that under conditionswhere the intramitochondrial CoA/acetyl-CoA ratio is high dueto a low acetyl-CoA level, the remaining acetyl-CoA would bechanneled into the citric acid cycle by limiting its consumptionin biosynthetic pathways (44).

Why is the production of ${alpha}$ -isopropylmalate subject to such elaboratecontrols? This question can be answered at least in part bypointing to the likely involvement of ${alpha}$ -isopropylmalate, whencomplexed with Leu3p, in metabolic processes that go distinctlybeyond the biosynthesis of the branched-chain amino acids (seebelow). The CoA-Zn²⁺ inactivation of ${alpha}$ -isopropylmalate synthasemay then be looked on not just as an acetyl-CoA saving devicebut also as an important link between those metabolic processesand central energy metabolism.

ISOPROPYLMALATE ISOMERASE (LEU1P) AND ß-ISOPROPYLMALATE DEHYDROGENASE (LEU2P) OF S. CEREVISIAE

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Intracellular Localization and the Question of an Isomerase-Dehydrogenase Complex
Of several reasons to lump together the two yeast enzymes neededto convert ${alpha}$ -isopropylmalate to ${alpha}$ -ketoisocaproate, their intracellularlocalization is perhaps the most compelling. In contrast tothe enzymes responsible for the conversion of ${alpha}$ -ketobutyrateand pyruvate to the ${alpha}$ -ketoacid precursors of isoleucine and valineand to ${alpha}$ -isopropylmalate, which are largely mitochondrial, isopropylmalateisomerase and ß-isopropylmalate are entirely cytoplasmic(94). A recent independent confirmation of the cytoplasmic localizationof the isomerase came from work done by Lill and coworkers onthe maturation of Fe-S proteins (57, 58, 67, 75, 85). Theseauthors observed that lesions in the ATM1 gene lead to leucineauxotrophy. They explained this behavior by pointing out thatAtm1p, a mitochondrial ATP binding cassette (ABC) transporter,is required for the efficient generation of extramitochondrial(but not intramitochondrial) Fe-S clusters and that, in theabsence of functional Atm1p, isopropylmalate isomerase, an Fe-Sprotein, would not be able to function if it were cytoplasmic.

The spatial separation of (most of) the ${alpha}$ -isopropylmalate synthasesfrom the isomerase and the dehydrogenase means that ${alpha}$ -isopropylmalatewould have to be transported from the mitochondrial matrix tothe cytoplasm. The molecule also would have to enter the nucleusin order to form an active complex with Leu3p. The possibilitythat ${alpha}$ -isopropylmalate binds to Leu3p in the cytoplasm cannotbe dismissed but is considered unlikely since Leu3p localizesto the nucleus and interacts with its target promoters irrespectiveof whether ${alpha}$ -isopropylmalate is present (17, 56). So far, no ${alpha}$ -isopropylmalate transporter has been identified.

It has long been known that both isopropylmalate isomerase andß-isopropylmalate deydrogenase are unusually labilewhen removed from their natural environment (13, 14, 48). Forexample, isomerase precipitated from crude extract by ammoniumsulfate fractionation has a half-life of only 2 to 3 h. Theenzyme can be stabilized by a combination of cryoprotectantsand, to some extent, by the presence of ß-isopropylmalate.The dehydrogenase is exceptionally sensitive to low temperatures(and to dilution), but this occurs only when it is outside thecells; intact yeast cells can be stored frozen for months withoutloss of dehydrogenase activity. Strikingly, when LEU2 is expressedin E. coli, the yeast dehydrogenase is cold sensitive even inintact cells (60). This behavior of the two enzymes has ledto the speculation that they might exist as a mutually stabilizingcomplex in vivo (59). It should be pointed out in this contextthat when a polyfunctional complex of isomerase and dehydrogenasewas sought in N. crassa because of the coordinate expressionof the corresponding genes, none was found (41).

Regulation of LEU1 and LEU2 Expression
Regulation of the synthesis of isopropylmalate isomerase andß-isopropylmalate dehydrogenase is achieved by controllingthe rate of transcription of LEU1 and LEU2, mainly through Leu3p- ${alpha}$ -isopropylmalate.The levels of the encoded enzymes and the cognate mRNAs respondsimilarly to genetic or physiological changes that affect LEU3or alter the intracellular concentration of ${alpha}$ -isopropylmalate(3, 7, 50). In addition to being controlled by Leu3p- ${alpha}$ -isopropylmalate,LEU1 appears to be mildly up-regulated by Gcn4p, although theeffect may be indirect (76). The response of LEU2 to Gen4p isatypical (17). There is no up-regulation by Gcn4p, but Gcn4pis needed to maintain a low but significant level of expression(basal level I) when Leu3p is absent. By an unknown mechanism,UAS_LEU-bound, activation-incompetent Leu3p abolishes this Gcn4peffect and reduces LEU2 expression to basal level II, a verylow level of expression (see also the next section).

LEU3P: A DUAL-FUNCTION TRANSCRIPTION FACTOR

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Leu3p as Transcriptional Activator and Repressor
The LEU3 gene of S. cerevisiae was originally identified asa positive regulator of the expression of LEU1 and LEU2, thegenes encoding isopropylmalate isomerase and ß-isopropylmalatedehydrogenase, respectively (7). The activation of these geneswas found to depend not only on the presence of an intact LEU3gene product but also on the rate at which ${alpha}$ -isopropylmalateis produced. In the absence of ${alpha}$ -isopropylmalate synthase activity,the activities of the LEU1 and LEU2 gene products were lessthan 10% of those found in wild-type cells. On the other hand,when ${alpha}$ -isopropylmalate was synthesized in largely uncontrolledfashion (in a LEU4^fbr strain that produces feedback-resistant ${alpha}$ -isopropylmalate synthase), the LEU1 and LEU2 gene product activitiesrose three- to fivefold over those seen in wild-type cells.When, in addition, ${alpha}$ -isopropylmalate was made to accumulate toeven higher concentrations by preventing it from being metabolized(using LEU4^fbr leu1 and LEU4^fbr leu2 strains), the activitiesof the LEU2 or the LEU1 gene product increased about 15- and10-fold, respectively. It was concluded that, by analogy tothe pattern seen previously with N. crassa (41), the expressionof LEU1 and LEU2 is subject to induction by a Leu3p- ${alpha}$ -isopropylmalatecomplex. Subsequent refinement of the analysis of LEU2 expressionusing a LEU2-lacZ fusion confirmed this conclusion and demonstrated,furthermore, that Leu3p is a dual regulator (17): in the presenceof ${alpha}$ -isopropylmalate, it is a transcriptional activator; in itsabsence, it acts as a repressor. To understand this behavior,one has to realize that in the total absence of Leu3p, LEU2gene expression is not zero but still proceeds at about 8% ofthat of the wild-type control, rendering ${Delta}$ leu3 strains leaky(basal level I expression). Leu3p molecules that are activation-incompetentbut retain an intact DNA binding function decrease basal levelI expression of LEU2 by another fourfold, to basal level II,a very low level of expression also seen in cells that are wildtype with respect to LEU3 but are essentially unable to produce ${alpha}$ -isopropylmalate (e.g., in a leu4 leu5 strain). The switch frombasal level I to basal level II defines the repressive effectof Leu3p. It follows from these observations that Leu3p shouldbind to its cognate DNA irrespective of the presence or absenceof ${alpha}$ -isopropylmalate. That was indeed shown to be the case (17,99). It was shown independently that Leu3p localizes to thenucleus (and binds to target sites) under a variety of growthconditions which included the presence and the absence of ${alpha}$ -isopropylmalate(56).

Structure-Function Relationships: the Self-Masking Model
Structural aspects of Leu3p. Important regions along the primary structure of Leu3p and theirsignificance are shown schematically in Fig. 3.

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FIG. 3. Regions of interest along the primary structure of Leu3p of S. cerevisiae.^aDNA binding region, residues 37 to 67, containing the cysteine motif for Zn(II)₂Cys₆ cluster formation;^bMHR, residues 300 to 380;^cthree clusters of residues (604 to 611, 643 to 664, and 738 to 741) potentially involved in activation domain masking;^dregion dispensable for all known functions, residues 774 to 854;^etranscriptional activation domain, residues 857 to 875; N, N terminus; C, C terminus. Note that the 11 C-terminal residues (residues 876 to 886), while not needed for the activation function, are essential for the masking process. See the text for further details.

Leu3p is a homodimeric DNA binding protein with 886 residuesper monomer and a deduced monomer molecular weight of closeto 100,000 (89, 118). It binds to cognate promoters at upstreamactivating sequences (UAS_LEU) with the structure 5'-CCGN₄CGG-3'(45). This structure is not entirely invariable. For example,the element found in the promoter of the LEU4 gene fits theabove palindrome only when one mismatch is allowed (10, 45).Also, the sequence of the spacing nucleotides is not randombut provides additional information for binding specificity(78). The DNA binding region of Leu3p is of the Zn(II)₂Cys₆binuclear cluster type and is located near the N terminus. TheDNA binding motif is Cys-Xxx₂-Cys-Xxx₆-Cys-Xxx_n-Cys-Xxx₂-Cys-Xxx₆-Cys,where Xxx is any amino acid. This motif is found in at least79 fungal proteins, including at least a dozen transactivators(95). Apparent dissociation constants of Leu3p-DNA complexesusing purified Leu3p and a LEU2 promoter-derived 30-mer containingthe UAS_LEU were determined to be in the low nanomolar range(97), values very close to those seen with other yeast transcriptionalfactors and with mammalian hormone receptors. Circular permutationand cyclization experiments showed that binding of Leu3p toUAS_LEU causes DNA bending (H. Guo and G. B. Kohlhaw, unpublishedresults). The apparent flexure angle, calculated from circularpermutation assays, was found to be 47° with full-lengthLeu3p and 25° with a Leu3p fragment containing residues17 to 147, i.e., little more than the DNA binding region. Thisresult suggests that interaction between Leu3p and its cognateDNA not only depends on the DNA binding motif but also is influencedby other regions of the protein.

The transcriptional activation domain of Leu3p is located nearthe C terminus. This region is promiscuous: it is functionalacross species and when attached to other DNA binding domains(42, 98, 110). There is very little sequence homology amongthe activation domains of this class of transactivators. Rather,what seems to be important is the presence (and probably thespatial arrangement) of both acidic and hydrophobic residues.The activation domain of Leu3p is surprisingly small. The 30-C-terminal-amino-acidresidue region originally identified as encompassing the activationfunction was subsequently whittled down to only 19 residues;even a Leu3p molecule lacking 17 of the 30 C-terminal residuesretains about 25% of the activation potential of the wild-typeprotein (109). Reassuringly, its activation domain still containsthree acidic and four hydrophobic residues.

In agreement with the notion that the regions of Leu3p thatare responsible for DNA binding, dimerization, and transcriptionactivation operate largely autonomously, a large internal segmentof Leu3p that encompasses more than two-thirds of the entireprotein can be deleted without infringing on the above functions.However, the shortened protein now behaves as a constitutiveactivator that maximally stimulates the expression of genesunder its control irrespective of the presence or absence of ${alpha}$ -isopropylmalate (35, 117). These results suggest that someaspects of the internal region (consisting of residues 174 to773) are essential for the modulation of Leu3p by ${alpha}$ -isopropylmalate.Additional deletion analysis showed that an 81-residue regionon the N-terminal side of the activation domain is dispensablefor all known functions of Leu3p (119). Since deletions oftenled to instability, other strategies were used to elucidatethe mechanism by which the activation domain of Leu3p is maskedin the absence of ${alpha}$ -isopropylmalate and unmasked in its presence.One important question was whether auxiliary factors were neededfor the masking-unmasking process, as is the case with someother modulated transactivators, e.g., Gal4p (63, 64) and possiblyHap1p (115, 116).

Are auxiliary factors needed to render the activation domain of Leu3p ineffective? In a first approach to answer this question, the LEU3 gene wasexpressed in mammalian cells (42). To this end, mouse preadipocyteswere transfected with two plasmids, one containing the LEU3gene behind the human cytomegalovirus major intermediate-earlypromoter and the other carrying a luciferase reporter gene withfour consecutive UAS_LEU sequences in its promoter. Culturedcells strongly expressed Leu3p, irrespective of whether ${alpha}$ -isopropylmalatewas added to the cell suspension. A basal level of reportergene expression was seen in the absence of LEU3. This leveldecreased by about fourfold when LEU3 was present. When bothLEU3 and ${alpha}$ -isopropylmalate were present, reporter gene expressionincreased about 17-fold compared to the "repressed" level. Similarresults were obtained in in vitro transcription assays usingnuclear extract from mouse preadipocytes and highly purifiedLeu3p. These assays showed in addition that induction by ${alpha}$ -isopropylmalatewas specific since it was not observed when ß-isopropylmalatewas used instead. Several conclusions may be drawn from theseexperiments. First, Leu3p assumes its masked (and repressive)configuration when expressed in the absence of the coactivator.This is in striking contrast to what was observed when Lac9p,a Gal4p-related activator from Kluyveromyces lactis, was expressedin mammalian cells (96). In that case, it was necessary to coexpressthe inhibitory yeast Gal80 protein in order to prevent transcriptionactivation of a reporter gene. Second, both repression and activationby Leu3p occur in mammalian cells very much like they do inyeast. Third, since LEU3 was the only yeast gene present inthe mammalian cell experiment and since mammalian cells do notelaborate branched-chain amino acid pathways, masking and unmaskingof the activation domain of Leu3p very probably occur withoutthe participation of additional Leu-specific factors.

More direct support for the idea that masking and unmaskingof the activation domain are intra-Leu3p events comes from extensivemutant analyses and physical interaction studies (109, 110).Permutation of the activation domain showed that the modulationfunction was much more sensitive to amino acid changes and deletionsthan was the activation function. The effects seen on modulationcould be classified as either permanent unmasking of the activationdomain (i.e., generation of constitutive activators), diminishedmasking, or intensified masking. Of particular interest wasa doubly mutated Leu3p (Leu3p[D872N/D874N], designated Leu3-dd)that is essentially unresponsive to ${alpha}$ -isopropylmalate, even thoughit is able to interact with the coactivator and possesses strongintrinsic activation capability. The latter was demonstratedby creating a Leu3-dd molecule from which the large internalsegment recognized earlier as important for modulation had beendeleted; it was fully active. To further investigate whetherthe "permanent mask" for the activation domain of Leu3-dd wasprovided by the Leu3 protein itself, a modified two-hybrid experimentwas designed in which a Leu3p wild-type molecule minus its activationdomain served as "bait" and separate activation domains servedas potential "prey." The results were consistent with a self-maskingmodel. It was found that (i) both wild-type and Leu3-dd activationdomains interacted with the remainder of the Leu3p molecule;(ii) the interaction between the Leu3-dd activation domain andthe bulk of Leu3p was much stronger than the interaction betweenthe wild-type activation domain and the remainder of Leu3p,which, nevertheless, was clearly visible; (iii) most importantly,the interaction in both cases depended on the ${alpha}$ -isopropylmalateconcentration, i.e., took place only when little or no coactivatorwas present, demonstrating that the interactions were specificand physiologically meaningful. It should be noted that interactionbetween the activation domain and an internal region of Leu3pmight well involve both subunits of the protein; i.e., activationdomain masking could be an intradimer rather than an intramonomerevent.

As expected, the Leu3-dd protein caused repression, and cellscontaining Leu3-dd grew only very slowly on minimal medium,opening the door to select for faster-growing suppressors. Methodswere developed to select for intragenic suppressors of the Leu3-ddphenotype that were limited to an internal region of LEU3 coveringresidues 172 to 772 of Leu3p (109, 110). Interestingly, allnine missense mutations thus identified mapped to three veryshort regions located within the C-terminal one-third of Leu3pand extending from residues 604 to 611, 643 to 664, and 738to 741, respectively (Fig. 3). Every one of the nine mutationsrestored substantial activation potential and various degreesof modulation, i.e., response to ${alpha}$ -isopropylmalate, to the Leu3-ddmolecule. When transferred to wild-type Leu3p, each of the ninemutations gave rise to constitutive, highly active activators,apparently abolishing masking altogether. It has been arguedthat at least some of the nine residues, in their wild-typeform, might be directly involved in trapping the activationdomain. However, more structural knowledge is needed to answerthat question.

Cha4p is a serine/threonine-responsive transcriptional activatorin yeast with an arrangement of functional and structural regionsalong the primary structure that is not unlike that of Leu3p(47). Domain swapping between Leu3p and Cha4p demonstrated thateach activation domain requires its cognate internal segmentin order to be eclipsed (110). This requirement does not extendto the DNA binding domains since normal regulatory behaviorwas seen in both cases when only these regions were swapped.

It is not known exactly where and how ${alpha}$ -isopropylmalate interactswith Leu3p. It has, however, been possible to determine apparentbinding constants for the coactivator, using in vitro transcriptionassays. The values obtained were 0.2 mM using an S. cerevisiaesystem (99) and 0.25 mM using a nuclear extract from mammaliancells (42). No interaction was detected with ß-isopropylmalate.

Masking versus repression. The masked form of Leu3p is also the form that represses geneexpression below the basal level. However, masking and repressionare two entirely different processes. While it is now clearthat masking of the activation domain requires (part of) thecentral region of the protein and does not require any partof the extended DNA binding domain (defined as residues 1 to173), it has been shown that repression is as efficient witha peptide encompassing residues 17 to 147 of Leu3p as it iswith the full-length protein (98). The region of Leu3p fromresidues 17 to 147 contains the cysteine residues that giverise to the Zn(II)₂Cys₆ cluster and a heptad repeat that issimilar to the one observed in Gal4p (72) and is therefore probablyinvolved in dimerization. The fragment from residues 17 to 147is identical to the one that has been shown to bind to and bendUAS_LEU-containing DNA (Guo and Kohlhaw, unpublished), and repressioncould be a (direct or indirect) consequence of this change inDNA structure. It is also possible, however, that the regionof Leu3p from residues 17 to 147 recruits another protein(s)that in turn exerts a negative effect on transcription. It hasbeen shown that repression by Leu3p requires the presence ofMot1p (108). Mot1p is an evolutionarily conserved repressorof transcription by RNA polymerase II that acts by displacingthe TATA box binding protein from its sites, perhaps throughATP-dependent conformational changes (1, 6). However, sinceit is unclear how Leu3p and Mot1p communicate, the exact pathwayby which Leu3p exerts its repressive effect remains unresolved.

The ‘middle homology region' of Leu3p. Many of the Zn(II)₂Cys₆ cluster-forming proteins, Leu3p included,contain an internal region known as the middle homology region(MHR). This homology was first identified by Chasman and Kornberg(28) and was thereafter reported to be present in as many as50 such proteins but not in other protein classes (95). TheMHR of Leu3p is located between residues 300 and 380. No conclusivefunction has been established for the MHR, but it has been speculatedthat it might be involved in decreasing the affinity of Zn(II)₂Cys₆cluster proteins for "wrong" genomic binding sites, based mainlyon the observation that binding site specificity of full-lengthGal4p in vivo is stricter than that of the Gal4p binding domainin vitro (72, 73). As far as Leu3p is concerned, it is possiblethat the much stronger bending of cognate DNA by the full-lengthmolecule than by the Leu3p [17-147] fragment is due to the presenceof the MHR, but direct evidence to support this idea is notavailable.

HOW LARGE IS THE LEU3P REGULON?

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Genetic and biochemical analyses have demonstrated that theexpression of seven S. cerevisiae genes is, at least in part,under the control of Leu3p (Table 1, first category). Five ofthese genes belong to the branched-chain amino acid pathways.The product of the sixth gene (BAP2) belongs to a family ofpermeases concerned primarily with the uptake of branched-chainamino acids (reference 77 and references therein). The seventhgene (GDH1) is responsible in a major way for the assimilationof ammonia in S. cerevisiae. To date, no systematic DNA microarraystudy relating to Leu3p has been carried out. There are, however,two recent items that bear on the potential range of Leu3p-mediatedregulation. The first of these is a genome-wide analysis ofregions located upstream of ORF's with regard to Leu3p bindingand occupancy (69). These authors determined the equilibriumdissociation constants of 43 variants of the consensus Leu3pbinding site which made it possible to predict an equilibriumdissociation constant for all potential binding sites in thegenome and to calculate the fractional occupancy of these sitesat an assumed intranuclear concentration of Leu3p. A total of6,276 ORFs were analyzed in this way and ranked according tothe number and quality of Leu3p binding sites present in theirpotential 5'-"regulatory" regions (defined as the 600 bp 5'to an ORF). Over a range of free Leu3p concentrations between1 and 100 nM, all seven genes known to be regulated by Leu3pwere found among the top 5% of all yeast genes (with four ofthem being among the top 0.2%), demonstrating the predictivepower of the method. The second item concerns results from alimited DNA microarray experiment (L. Breeden, personal communication).In this experiment, which was a by-product of an unrelated project,the following genotypes were compared: leu2 HAA1 with LEU2 haa1and LEU2 HAA1 with LEU2 haa1. Cells with an intact LEU2 geneaccumulate much less ${alpha}$ -isopropylmalate than do cells with a deficientLEU2 gene and would therefore be expected to show lesser inductionof genes controlled by the Leu3p- ${alpha}$ -isopropylmalate complex. Geneswhose expression was specifically depressed when LEU2 was intactincluded not only LEU1, ILV3, ILV5, and GDH1 but also abouttwo dozen other genes and hypothetical ORFs. Four of the additionalgenes (BAT1, GAP1, OAC1, and MAE1) were also found to rank withinthe top 5% of all genes in the above occupancy calculation (threeof them ranked within the top 0.5%). Since the likelihood thatthese four genes are regulated by Leu3p is based on the resultsof two very different approaches, they are included as a secondcategory ("potential Leu3p targets") in Table 1. Also addedto this category was LEU9, a close homologue of LEU4 that likewiseranked very high in the occupancy analysis. The 12 genes listedin Table 1 can be assigned to three classes. The first and largestclass encompasses nine genes involved in branched-chain aminoacid biosynthesis and amino acid uptake into the cell (LEU1,LEU2, LEU4, LEU9, ILV2, ILV5, BAT1, BAP2, and GAP1). The secondclass includes two genes that function in central nitrogen andcarbohydrate metabolism (GDH1 and MAE1). Finally, the one geneof the third class (OAC1) produces an inner mitochondrial membrane-basedcarrier protein for oxaloacetate and sulfate. It is relativelyeasy to see connections between these classes. For example,the well-established activation of GDH1 by Leu3p- ${alpha}$ -isopropylmalatemay be looked on as a signal transduction from the peripheryof nitrogen metabolism (represented by the leucine pathway)to an essential early step in nitrogen metabolism (the assimilationof ammonia). The product of the MAE1 gene, mitochondrial malicenzyme, functions in the intramitochondrial synthesis of pyruvateand may therefore be considered a supplier of an important precursorin the biosynthesis of valine, leucine, and isolecine withinthe very compartment where most of these biosynthetic reactionsoccur (15). Also, given the sensitivity of ${alpha}$ -isopropylmalatesynthase I (and probably II as well) to changes in the mitochondrialCoA/acetyl-CoA ratio and the dependence of ${alpha}$ -isopropylmalatesynthase II on functioning CoA import into the mitochondria,it is perhaps not surprising to find that the Leu3p- ${alpha}$ -isopropylmalatecomplex might regulate a gene like OAC1. In terms of the numberof genes controlled, the presumptive extended Leu3p regulonis comparable to several other yeast regulons. For example,the Zap1p zinc-responsive regulon encompasses some 40 genes(70), Mac1p activates seven genes of a copper regulon (39),and a multidrug resistance regulon consists of 26 targets controlledby Pdr1p-Pdr3p (31).

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TABLE 1. Targets for regulation by Leu3p- ${alpha}$ -isopropylmalate in S. cerevisiae

MULTIPLE LAYERS OF CONTROL

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As illustrated in Fig. 4, the most direct control of the genesthat define the extended leucine pathway is exerted by the Leu3p- ${alpha}$ -isopropylmalatecomplex, which functions at six of the seven steps shown (ILV2,ILV5, LEU4, LEU1, LEU2, and BAT1), with the caveat that Leu3pcontrol of BAT1 has not yet been directly demonstrated. Superimposedon this leucine-specific regulation is general amino acid control,mediated by Gcn4p. The effect of Gcn4p is twofold. First, itincreases the Leu3p level, as inferred from experiments showingan increase in the rate of production of a Leu3p-ß-galactosidasefusion protein in a manner typical for the general amino acidcontrol system (118). This probably has physiological consequencessince increased production of Leu3p can lead to increased targetgene expression (110). Second, it acts directly on at leastfour genes (ILV3, LEU4, and BAT1-BAT2) of the extended leucinepathway; the effect on three more genes (ILV2, ILV5, and LEU1)may be indirect, through Leu3p (49, 52, 76). The Leu3p regulonthus becomes part of a remarkable regulatory network that encompassesat least 539 bona fide targets, among them a total of 26 genesthat encode DNA binding transcription factors (76). By stimulatingLEU3 expression, Gcn4p would amplify its impact in cascade-typefashion. Its simultaneous stimulation of LEU3 and LEU4 ensuresthat both components of the Leu3p- ${alpha}$ -isopropylmalate complex willbe made at increased rates. It can be imagined that, in a typicalsequence of events, starvation for amino acids (or purines orglucose) would elicit an overriding response in a multitudeof pathways, through the Gcn4p general amino acid control system.The Leu3p regulon would obey these starvation signals and augmentthem. In addition, it would respond independently to other signals,e.g. changes in the CoA/acetyl-CoA ratio, the cell's adenylateenergy charge, or the leucine pool, that have an effect on theintracellular ${alpha}$ -isopropylmalate level. This would give the yeastcell even more flexibility in its adjustment to environmentalchanges and demands.

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FIG. 4. Major regulatory mechanisms impacting the extended leucine pathway of S. cerevisiae. For abbreviations of intermediates and the protein products of the genes shown, see the legend to Fig. 1. See the text for further explanation.

Yet another layer of control that acts on genes of the extendedleucine pathway is represented by Tpk1p (Fig. 4). This proteinis one of three catalytic subunits of yeast protein kinase A.Like Tpk2p and Tpk3p, Tpk1p is released from an inactive complexunder conditions that raise the intracellular cyclic AMP level,for example when cells leave stationary phase after gainingaccess to glucose or other fermentable carbon sources. The functionsof the three subunits were recently studied by genome-wide transcriptionalprofiling, and it was established by comparing a TPK1 mutantstrain with the wild type that there was a significant reductionin the expression of BAT1 and ILV5 in the TPK1 mutant in YPDmedium (91). Why should BAT1 and ILV5 be regulated by Tpk1p?It turns out that the enzymes encoded by these two genes playother important roles besides their catalytic functions in thebranched-chain amino acid pathways, and it is likely that thestimulatory effect of Tpk1p is aimed at these other functions,which have to do with mitochondrial integrity.

The pathway function of Bat1p is to serve as mitochondrial branched-chainamino acid aminotransferase; Bat2p is an isoenzyme located inthe cytosol (58, 85). Cells deficient in both proteins do notgrow on minimal media unless supplied with all three branched-chainamino acids. However, even in the presence of these amino acids,growth remains sluggish. A possible explanation for this behaviorcomes from the observation that the Bat proteins, in particularBat1p, perform an essential function in iron homeostasis bybeing involved in the efficient transfer of Fe-S clusters fromthe mitochondria, where the clusters are synthesized, to thecytosol, a process that also involves the mitochondrial ABCtransporter Atm1p. In fact, the BAT1 gene was isolated as asuppressor of a temperature-sensitive ATM1 mutant, and elevatedlevels of Bat1p were able to stabilize mutant Atm1p at the nonpermissivetemperature. This suggested direct interaction between Bat1pand Atm1p, but other possibilities have not been ruled out (57,58, 66) (Fig. 1). An important point is that a disturbance inthe process of maintaining iron homeostasis can lead to a severeaccumulation of iron in the mitochondria with subsequent damageand loss of mitochondrial DNA (mtDNA).

Ilv5p, which normally functions as acetohydroxy acid reductoisomerase,is also involved in enhancing the stability of mtDNA (114).This feature of Ilv5p was first discovered when ILV5 was identifiedas a suppressor of the mtDNA instability phenotype of ${Delta}$ abf2 cellsgrown on rich glucose medium (Abf2p is required for maintenanceof mtDNA under these conditions). Suppression was achieved witha relatively small increase in ILV5 copy number or increasedexpression of the ILV5 gene in a strain with a constitutivelyactive GCN4 allele. The fact that an ILV5 null mutant showeda strong tendency to produce ${rho}$ ^- petite strains further supportedthe notion that Ilv5p stabilizes mtDNA. More recently, it wasshown that Gcn4p-mediated activation of ILV5 expression resultsin increased formation of nucleoids (mtDNA-protein complexesconsidered to be the basic unit of mtDNA segregation) and thatsuch an increase in nucleoid number also increases the transmissionof mtDNA to daughter cells (71). It was proposed that the simultaneousactivation of amino acid biosynthesis and nucleoid formationby Gcn4p might enhance the chance of progeny survival.

By increasing the expression of BAT1 and ILV5, Gcn4p and Tpk1pare likely to achieve similar results with respect to preservationof mtDNA, parsing of mtDNA into nucleoids, and respiratory competence.Apparently, the action of Tpk1p is reinforced by Gcn4p sincethe TPK1 gene is controlled, at least in part, by Gcn4p (76).Also, given the possibility that Gcn4p regulation of ILV5 actuallyworks through the Leu3p- ${alpha}$ -isopropylmalate complex, the lattermight likewise contribute to mtDNA maintenance.

BRANCHED-CHAIN AMINO ACID BIOSYNTHESIS IN OTHER FUNGI

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Neurospora crassa
Our knowledge of leucine as well as isoleucine-valine biosynthesisand its regulation in N. crassa stems to a large extent fromthe pioneering biochemical and genetic work of S. Gross andcoworkers. The three leucine pathway-specific enzymes of N.crassa are encoded by three genes: leu-4 ( ${alpha}$ -isopropylmalate synthase),leu-2 (isopropylmalate isomerase), and leu-1 (ß-isopropylmalatedehydrogenase). These genes are not only unlinked but actuallylocated on different linkage groups. It was observed early on(40, 41) (i) that the synthesis of the leu-2 and leu-1 geneproducts was proportional to the amount of leu-4 product generated;(ii) that leu-4 mutants unable to make synthase would also producevery little isomerase and dehydrogenase; (iii) that leu-2 mutants,which accumulate ${alpha}$ -isopropylmalate, produce relatively largeamounts of the leu-1 and leu-4 gene products (and that leu-1mutants overproduce leu-2 and leu-4 gene products); and (iv)that the expression of leu-2 and leu-1 was reduced to very lowlevels in leu-3 mutants. It was suggested on the basis of theseand other results that ${alpha}$ -isopropylmalate, in conjunction withthe leu-3 gene product, induces the expression of leu-2 andleu-1. Variations in the intracellular concentration of ${alpha}$ -isopropylmalatewere initially achieved by indirect means. Later, isolationof an ${alpha}$ -isopropylmalate-permeable strain allowed direct demonstrationof the induction of isopropylmalate isomerase by the leucineprecursor (88). Additional work showed that leu-4 as well asfour genes involved in isoleucine-valine biosynthesis and encodingthreonine deaminase, acetohydroxy acid synthase, acetohydroxyacid isomeroreductase, and dihydroxy acid dehydratase requirethe leu-3 gene and ${alpha}$ -isopropylmalate for full expression (80,84).

Of considerable interest in terms of defining a "regulon" forleu-3 of N. crassa was the discovery of a connection betweenthe leucine and histidine pathways (55). A connection was suspectedafter it was observed that the degree of resistance to 3-amino-1,2,4-triazoleexactly paralleled the ability of the cell to generate leu-3product and ${alpha}$ -isopropylmalate. It was then established (againby using the ${alpha}$ -isopropylmalate-permeable mutations mentionedabove) that the target for regulation was his-1, which encodesimidazoleglycerol-phosphate dehydratase, a key enzyme in histidinebiosynthesis. There thus exists a second layer of control forhistidine biosynthesis in addition to what is kown as "cross-pathwaycontrol," a cpc-1-governed mechanism that affects the histidinepathway and several other amino acid biosynthetic pathways byresponding to amino acid starvation and that is analogous tothe GCN4 system of S. cerevisiae (20, 81). The physiologicalimportance of the N. crassa leu-3 product- ${alpha}$ -isopropylmalate complexwas underscored even further by the observation that the complexis able to cause transient repression of stable RNA and overallprotein synthesis, an effect reminiscent of the "stringent response"of bacteria (5). While the mechanism of the negative effectof the complex on macromolecular synthesis is not known, itwas established that the onset of repression is very rapid comparedto the Neurospora doubling time and that one of the consequencesis a significant efflux of Ca²⁺ from the cells, which is alsotransient.

Viewing the information gathered for both S. cerevisiae andN. crassa with regard to the metabolic effects of the Leu3p- ${alpha}$ -isopropylmalatecomplex, one would seem justified in concluding that the fungalregulator known as Leu3p plays a rather more comprehensive rolethan its name suggests.

As far as the intracellular localization of branched-chain aminoacid biosynthetic enzymes in N. crassa is concerned, it appearsthat only the enzymes of the isoleucine-valine pathway havebeen studied in this respect. Of these, threonine deaminaseis apparently cytosolic while most, if not all, of a cell'sacetohydroxy acid synthase, acetohydroxy acid isomeroreductase,and dihydroxy acid dehydratase is localized to the mitochondrialmatrix (22, 80).

Other Species
There are very few studies with fungi other than S. cerevisiaeand N. crassa that deal with the full set of genes and geneproducts concerned with the biosynthesis of all three branched-chainamino acids or even just the leucine branch. One exception isa report on leucine auxotrophs of the basidiomycete Phanerochaetechryosporium, an organism that is potentially useful in schemesfor the bioprocessing of lignocellulose (74). The authors ofthis report found three complementation groups correspondingto three genes encoding ${alpha}$ -isopropylmalate synthase, isopropylmalateisomerase, and ß-isopropylmalate dehydrogenase. Mutationsin any one of these genes caused the loss of the encoded enzymeonly. In auxotrophs that lack synthase, the activities of theisomerase and the dehydrogenase were found to be 3- to 4-foldhigher than in wild-type cells; auxotrophs that lack isomerasehad 2-fold-elevated synthase and unchanged dehydrogenase levels;and auxotrophs deficient in dehydrogenase had 20% more synthasethan did wild-type cells and up to 10-fold elevated activitiesof isomerase. The authors concluded that these results are indicativeof leucine pathway regulation but did not elaborate further.However, the regulation seems to differ in at least some respectsfrom that seen in S. cerevisiae and N. crassa, where very littleformation of isomerase and dehydrogenase occurs in synthase-minusstrains (see above). Another study of leucine biosynthesis wascarried out with Candida maltosa, an imperfect yeast that isable to assimilate liquid hydrocarbons for biomass production(9). In this case, 13 leucine auxotrophs were found to constitutefive complementation groups (determined by protoplast fusionsince C. maltosa lacks a sexual cycle), one affecting ${alpha}$ -isopropylmalatesynthase, three affecting isopropylmalate isomerase, and oneaffecting ß-isopropylmalate dehydrogenase. Again,a unique pattern of apparent regulation was observed, in thatin a synthase-minus strain, isomerase activity was decreasedonly marginally and dehydrogenase still proceeded at about 25%of wild-type activity. When isomerase was missing, causing significantexcretion of ${alpha}$ -isopropylmalate, synthase activity increased four-to sixfold while dehydrogenase activity remained essentiallyunchanged. When dehydrogenase was missing, synthase activityagain increased 4- to 6-fold while isomerase activity rose 12-to 20-fold. These data are not easily interpreted in terms ofknown regulatory mechanisms and appear to be at odds with anearlier report that a cloned gene from C. maltosa that showed76% homology (at the protein sequence level) to LEU2 from S.cerevisiae (4), and was therefore named C-LEU2, was regulatedjust like LEU2 from S. cerevisiae when transferred into thatorganism (100). The interpretation of genetic data from C. maltosais complicated by evidence of a highly aneuploid genome andthe spontaneous occurrence of auxotrophy-prototrophy-auxotrophychanges due to the presence of silent gene copies (8).

Ever since the first successful transformation of yeast, whichused cloned LEU2 from S. cerevisiae to complement a leu2 doublemutant (46), the LEU2 gene or its homologues have been the selectablemarker of choice in developing new host-vector systems. Thisgene is therefore one of the best-studied genes of the branched-chainamino acid pathway in fungi. A partial list of organisms fromwhich a LEU2 homologue has been cloned, sequenced, or otherwisecharacterized includes (in addition to the C. maltosa examplementioned above) the yeast Yarrowia lipolytica (29), the methylotrophicyeasts Hansenula polymorpha (2) and Pichia anomala (30), andthe industrially used Kluyveromyces marxianus (12) and Aspergillusniger (111). A. niger elaborates two isoenzymes of ß-isopropylmalatedehydrogenase (Leu2A and Leu2B) that are only 52% identicalat the amino acid level. In fact, Leu2A is more closely relatedto its S. cerevisiae and N. crassa homologues than to Leu2B.Since A. niger has been shown previously to incorporate DNAfrom other organisms in its environment, the authors speculatethat the gene encoding Leu2B was introduced from another species.In all of the above cases, with the exception of A. niger, wherethis question was not studied, sequences were found in the 5'-noncodingregions that strongly resemble the consensus binding site forLeu3p, suggesting that Leu3p- ${alpha}$ -isopropylmalate regulation ofthe kind seen in S. cerevisiae and N. crassa may be importantin these other yeasts as well.

LEUCINE AS METABOLIC SIGNAL

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The use of leucine or a precursor of leucine to coordinate thestatus of peripheral nitrogen metabolism with other cellularprocesses is not limited to the fungi. Another prominent exampleof this type of signal transduction is the leucine-responsiveregulatory protein (Lrp) of E. coli. This DNA binding proteincontrols its own regulon of more than 20 operons that are involvedprincipally in amino acid biosynthesis, the assimilation ofammonia, amino acid degradation, nutrient transport, and theformation of pili (19). (Interestingly enough, Lrp does notdirectly affect the leuABCD operon which, as pointed out above[see "Evolutionary A