Family of G protein {alpha} chains: amphipathic analysis and predicted structure of functional domains

The G proteins transduce hormonal and other signals into regulationof enzymes such as adenylyl cyclase and retinal cGMP phosphodiesterase.Each G protein contains an subunit that binds and hydrolyzesguanine nucleotides and interacts with ß subunitsand specific receptor and effector proteins. Amphipathic andsecondary structure analysis of the primary sequences of fivedifferent chains (bovine _s, _t1 and _t2, mouse _i, and rat _o)predicted the secondary structure of a composite chain (_avg).The chains contain four short regions of sequence homologousto regions in the GDP binding domain of bacterial elongationfactor Tu (EF-Tu). Similarities between the predicted secondarystructures of these regions in _avg and the known secondary structureof EF-Tu allowed us to construct a three-dimensional model ofthe GDP binding domain of _avg. Identification of the GDP bindingdomain of _avg defined three additional domains in the compositepolypeptide. The first includes the amino terminal 41 residuesof _avg, with a predicted am phipathic helical structure; thisdomain may control binding of the chains to the ßcomplex. The second domain, containing predicted ßstrands and helices, several of which are strongly amphipathic,probably contains sequences responsible for interaction of chains with effector enzymes. The predicted structure of thethird domain, containing the carhoxy terminal 100 amino acids,is predominantly ß sheet with an amphipathic helixat the carboxy terminus. We propose that this domain is reponsiblefor receptor binding. Our model should help direct further experimentsinto the structure and function of the G protein chain.     

Effect of amino acid deletions in the O-glycosylated region of Aspergillus awamori glucoamylase

Aspergillus awamori glucoamylase (GA) contains globular catalyticand starch-binding domains (residues 1–471 and 509–616,respectively). A heavily O-glycosylated sequence comprises twoparts. The first (residues 441–471) in the crystal structurewraps around an /-barrel formed by residues 1–440. Thesecond (residues 472–508) is an extended, semi-rigid linkerbetween the two domains. To investigate the functional roleof this linker, we made internal deletions to remove residues466–512 (GA1), 485–512 (GA2) and 466–483 (GA3).GA2 and GA3 were expressed in Saccharomyces cerevisiae culturesupernatants at 60 and 20% the wild-type level, respectively,while GA1 was almost undetectable. Western blots comparing extracellularand intracellular fractions indicated that the region deletedin GA3 was critical for secretion, while the region deletedin GA2 contributed to the production of a stable enzyme structure.The activities of purified GA2 and GA3 on soluble and insolublestarch were similar to those of wild-type GA, indicating thatfor soluble starch their deletions did not affect the catalyticdomain and for insoluble starch the linker does not coordinatethe activities of the catalytic and starch-binding domains.The deletions had a significant negative effect on GA2 and GA3thermos tabilities.     

Production and characterization of anti-human interferon {gamma} receptor antibody fragments that inhibit cytokine binding to the receptor

Three single-chain antibody fragments that recognize the extracellularhuman interferon receptor -chain (IFNR), and inhibit the bindingof human IFN, have been produced in Escherichia coli. Thesefragments are derived from murine anti-receptor monoclonal antibodies,and comprise the variable heavy (V_H) domain linked to the variablelight (V_L) chain through a 15 amino acid linker [(GGGGS)₃].Using surface plasmon resonance technology (BIAcore), the solubleproteins were shown to retain a high affinity for recombinantIFNR, and by radioimmunoassay to possess high inhibitory activitytowards IFN-binding to human Raji cells. The antibody fragmentsmost likely recognize epitopes that overlap the cytokine bindingsite on the receptor surface. Attempts to dissect further theantibodies to isolated V_H- and V_L-chains and to synthetic linearand cyclic peptides derived from the individual complementaritydetermining regions failed to afford fragments with significantIFNR binding affinity. Nevertheless, these native-like variableregion fragments and petidomimetics derived from them are ofinterest in the design of novel IFNR antagonists.     

Chemical synthesis of {gamma}-echistatin analogues: elucidation of status of C-terminal (45-49)

Three analogues of -echistatin, des(45–49)--echistatin,des(46–49)-y-echistatin and des(47–49)--echistatin,were synthesized by solid-phase methodology and their biologicalactivities were measured and compared. The results reveal thatwithout the C-terminal (45–49) of -echistatin, the foldingof the protein to the final active structure is not interferedwith and Lys-45 influences the inhibition of platelet aggregation.     

Folding and stability of the active N-terminal domain of tissue inhibitor of metalloproteinases-1 and -2

The truncated forms of tissue inhibitor of metalloproteinase-1and -2 (TIMP-1 and -2), comprising the N-terminal active domain,are ideal molecules for structural analysis by intrinsic fluorescenceas each contains a single conserved tryptophan residue. In thispaper we describe studies on their conformational stability,unfolding/refolding kinetics and the environment of the uniquetryptophan as judged by its fluorescence properties in the nativestate and exposure to an external quencher, acrylamide. Twoforms of TIMP-2 were studied: TIMP-2 T21 derived from the full-lengthcDNA clone isolated from a mixed-tumour library, and TIMP-2A21 containing the highly conserved V18IRAK22 sequence. In allthree TIMP proteins the tryptophan environments in the nativestate appeared to be similar, but substantial differences wereseen in their conformational stabilities and refolding kinetics.TIMP-1 was approximately twice as stable as TIMP-2 T21 and 1.4-foldmore stable than TIMP-2 A21. This stability difference betweenTIMP-1 and TIMP-2 was shown to be independent of N-linked glycosylation.TTMP-1 and TIMP-2 A21 both showed simple two-state refoldingkinetics, whereas TIMP-2 T21 refolding was more complex andbiphasic in character. These differences between TIMP-2 T21and A21 suggest that residue 21 is a structurally importantsite in the TIMP protein.All three truncated molecules can beconsidered as stable independent folding domains ideally suitedfor further structural analysis     

Inhibition of {beta}S-chain dependent polymerization by synergistic complementation of contact site perturbations of {alpha}-chain: application of semisynthetic chimeric {alpha}-chains

Mouse _1–30-horse _31–141 chimeric -chain, a semisyntheticsuper-inhibitory -chain, inhibits ß^S-chain dependent polymerizationbetter than both parent -chains. Although contact site sequencedifferences are absent in the _1–30 region of the chimericchain, the four sequence differences of the region _17-22 couldinduce perturbations of the side chains at ₁₆, ₂₀ and ₂₃, thethree contact sites of the region. A synergistic complementationof such contact site perturbation with that of horse _31–141probably results in the super-inhibitory activity of the chimeric-chain. The inhibitory contact site sequence differences, bythemselves, could also exhibit similar synergistic complementation.Accordingly, the polymerization inhibitory activity of Hb Le-Lamentin(LM) mutation [His20()Gln], a contact site sequence difference,engineered into human–horse chimeric -chain has been investigatedto map such a synergistic complementation. Gln20() has littleeffect on the O₂ affinity of HbS, but in human–horse chimeric-chain it reduces the O₂ affinity slightly. In the chimeric-chain, Gln20() increased sensitivity of the ßßcleft for the DPG influence, reflecting a cross-talk betweenthe ₁ß₁ interface and ßß cleft in this semisyntheticchimeric HbS. In the human -chain frame, the polymerizationinhibitory activity of Gln20() is higher compared with horse_1–30, but lower than mouse _1–30. Gln20() synergisticallycomplements the inhibitory propensity of horse _31–141.However, the inhibitory activity of LM–horse chimeric-chain is still lower than that of mouse–horse chimeric-chain. Therefore, perturbation of multiple contact sites inthe _1–30 region of the mouse–horse chimeric -chainand its linkage with the inhibitory propensity of horse _31–141has been now invoked to explain the super-inhibitory activityof the chimeric -chain. The `linkage-map' of contact sites canserve as a blueprint for designing synergistic complementationof multiple contact sites into -chains as a strategy for generatingsuper-inhibitory antisickling hemoglobins for gene therapy ofsickle cell disease.     

A point mutation that decreases the thermal stability of human interferon {gamma}

We have identified a mutation of human gamma-interferon (IFN)causing a temperature-sensitive phenotype. We used a randomizedoligonucleotide to mutagenize a synthetic human IFN gene, thenscreened the resulting mutants produced in Escherichia colifor proteins with altered biological activity. One mutant proteinselected for detailed characterization exhibited < 0.3% ofthe specific biological activity of native IFN in an antiviralactivity assay performed at 37°C. However, the protein boundthe human IFN receptor with native efficiency at 4°C. Sequencingthe plasmid DNA encoding this protein snowed that the mutationchanged the lysine residue at amino acid 43 to glutamic acid(IFN/K43E). Site-specific mutagenesis at amino acid 43 showedthat this protein's phenotype resulted from positioning a negativecharge at position 43. Structural characterization of IFN/K43Eusing CD demonstrated that the protein had native conformationat 25°C, but assumed an altered conformation at 37°C.IFN/K43E in this altered conformation bound poorly to the IFNreceptor at 37°C, providing a rationale for the mutant'sdecreased antiviral activity.     

Expression of recombinant {alpha}Ains-crystallin and not {alpha}A-crystallin inhibits bacterial growth

A-Crystallin and A^ins-crystallin are derived from the A-crystallingene via alternative splicing. They are identical except forthe presence of a polypeptide, 23 amino acids long, encodedby the ‘insert’ exon. Evolutionary logic would suggestthat the insertion of a 23 amino acid peptide in the middleof A-crystallin, a protein evolving more slowly than eitherhistone H1, cytochrome c or hemoglobin, would lead to appreciablestructural and functional changes. However, based on physico-chemicalstudies, it is presently believed that A-crystallin and A^ins-crystallinare functionally equivalent and that the presence of the ‘insert’peptide in A^Ins-crystallin is inconsequential. We report herethat the independent expression of recombinant A^Ins-crystallin,and not A-crystallin, inhibits growth of the bacterial host.These observations were confirmed in co-expression experiments,wherein both the proteins were expressed in the same cell. Interestingly,growth inhibition is reversible. Importantly, the data demonstratethat it is catalytic amounts and not the gross accumulationof A^Ins-crystalline which causes growth inhibition. Given theprior knowledge that A-crystallin and A^Ins-crystallin differby a peptide of 23 amino acids, these data suggest that the‘insert peptide’ in A^Ins-crystallin imparts propertieson this protein that are different from A-crystallin.     

A point mutation of human interferon {gamma} abolishes receptor recognition

We identified a single amino acid mutation that abolished thebioactivity of human IFN. The mutation was identified by screeninga mutagenized IFN expression library for molecules with alteredbiological activity. The mutant protein was expressed at highlevels in Escherichia coli, and remained soluble upon purification.However, the protein was completely inactive in all IFN assaysinvestigated, exhibiting < 0.0006% of the specific activityof native IFN antiviral activity. Sequencing the plasmid DNAencoding this mutant protein showed that the histidine at position111 of native human IFN is changed to aspartic acid (IFN/H111D).Other mutations at this site showed that only hydrophobic aminoacids at position 111 maintain significant, though low, biologicalactivity. Structural characterization of the IFN/H111D proteinby NMR as well as CD spectroscopy demonstrated that the proteinhas limited conformational differences from native IFN. Modelsof the X-ray crystal structure of human IFN [Ealick, P.E., W.J.Cook,S.Vijay-Kumar, M.Carson, T.L.Nagabhushan, P.P.Trotta and C.E.Bugg(1991) Science, 252, 698–702] suggest that this histidineresidue is located at a severe 55° bend in the C-terminalF helix. We conclude that H111 lies within or affects the receptorbinding domain of human IFN.     

Model building of disulfide bonds in proteins with known three-dimensional structure

As an aid in the selection of sites in a protein where a disulfidebond might be engineered, a computer program has been developed.The algorithm starts with the generation of Cß positionsfrom the N, C and C atom coordinates available from a three-dimensionalmodel. A first set of residue pairs that might form a disulfidebond is selected on the basis of Cß–Cßdistances between residues. Then, for each residue in this set,S positions are generated, which satisfy the requirement that,with ideal values for the C–Cß and Cß–Sbond lengths and for the bond angle at Cß, the distancebetween S of residue 1 and Cß of residue 2 in a pair(determined by the bond angle at S2) is at, or very close toits ideal value. Usually two acceptable S positions are foundfor each half cystine, resulting in up to four different conformationsfor the disulfide bond. Finally, these conformations are subjectedto an energy minimization procedure to remove large deviationsfrom ideal geometry and their final energies are calculated.User input determines which final conformations are energeticallyacceptable. These conformations are written to a file to allowfurther analysis and e.g. inspection on a computer graphicsdevice.     

Comparative stability of dihydrofolate reductase mutants in vitro and in vivo

Dihydrofolate reductase mutants with amino acid replacementsin the active center (Thr35 Asp mutant, Arg57 His mutant andthe mutant with triple replacement Thr35 Asp, Asn37 Ser, Arg57 His) were obtained by site-directed mutagenesis. The stabilizationeffect of trimethoprim and NADP·H on the protein tertiarystructure in vitro has been investigated. In the case of mutantswith a ‘weak’ tertiary structure (Thr35 Asp35 andthe triple mutant) the separate addition of ligands does notaffect their stability. The simultaneous addition of these ligandsto Thr35 Asp35 and the triple mutant leads to the large increasein their stability. A distinct correlation was found betweenthe in vitro studied stability of the mutant proteins to theurea- or heat-induced denaturation and the level of proteolyticdegradation of these mutants previously observed in vivo.     

Recombinant-derived interleukin-1{alpha} stabilized against specific deamidation

Recombinant-derived human interleukln-1 (IL-1), purified fromEscherichia coli, was resolved by isoelectric focusing on polyacrylamidegels into two species of isoelectric points (pI) 5.45 and 5.20,which constituted 75% and 25% of the total IL-1 protein respectively.The pI 5.45 and pI 5.20 species were separated by chromatofocusingand subjected to N-terminal sequence analysis. The pI 5.45 speciescontained the expected Asn residue at position 36 of the matureprotein sequence whereas the pI 5.20 species contained an Aspresidue at the same position. A mutant protein in which Asn-36was substituted for a Ser residue was isolated from E.coli andshown to be homogeneous on isoelectric focusing analysis witha pI = 5.45. ¹H-n.m.r. and circular dichroism analyses of wild-typeand the mutant IL-1 indicated a similar conformation which wasalso indicated by the identical receptor binding affinitiesof IL-1 with Asn, Asp or Ser in position 36. The mutant proteinwas stabilized against specific base catalysed and temperature-induceddeamidation, and may be more suitable than the wild-type positionfor physical and structural studies.     

The role of the sequence extensions in {beta}-crystallin assembly

The modular construction of the eye lens ß-crystallinsmakes them good candidates for protein engineering to ascertainthe rules of assembly of oligomers. X-ray studies have shownthat although the polypeptide chains of ßB2-crystallinand -crystallins fold to form similar N- and C-terminal domains,the conformation of the connecting peptides are such that the-crystallins are monomers and the ß-crystallin isa dimer. Unlike -crystallins, the numerous -crystallins haveextensions of variable sequence from the globular domains. Wehave tested the effect of removing the N- and C-terminal extensionsfrom rat ßB2-crystallin using a bacterial expressionsystem. Abundant proteins were produced in Escherichia coliusing the pET or pQE vectors. Full-length and truncated proteinswere purified and checked for refolding using circular dichroism.Sizing of the truncated proteins using gel filtration chroma-tographyshowed that the absence of either the N- or C-terminal extensiondoes not affect dimerization of ßB2-crystallin.     

Recombinant hirudin: kinetic mechanism for the inhibition of human thrombin

Recombinant hirudin variant-2(Lys⁴⁷ ), was found to be a competitiveinhibitor of human -thrombin with respect to peptidyl p-Miitroanilidesubstrates. These results contrast with those of Degryse andcoworkers that suggest that recombinant hirudin variant-2(Lys⁴⁷)inhibited thrombin by a non-competitive mechanism [Degryse etal. (1989) Protein Engng, 2, 459–465], -Thrombin, whichcan arise from -thrombin by autolysis, was shown to have anaffinity for recombinant hirudin variant-2(Lys⁴⁷) that was fourorders of magnitude lower than that of -thrombin. It was demonstratedthat the apparent noncompetitive mechanism observed previouslywas probably caused by a contamination of the thrombin preparationby -thrombin. Comparison of the inhibition of -thrombin by recombinanthirudins variant-2(Lys⁴⁷) and variant-1, which differ from oneanother in eight out of 65 amino acids, indicated that the twovariants have essentially the same kinetic parameters.     

Activation of the low oxygen affinity-inducing potential of the Asn108({beta}){->}Lys mutation of Hb-Presbyterian on intramolecular {{alpha}}{{alpha}}-fumaryl cross-bridging

The Asn108ßLys mutation in hemoglobin (HbPresbyterianmutation) endows a low O₂ affinity-inducing propensity to theprotein. Introduction of a fumaryl cross-bridge between itstwo 99 lysine residues also induces a low O₂ affinity into HbA.We have now engineered an -fumaryl cross-bridge into Hb-Presbyterianto determine the synergy or additivity, if any, that can beachieved between these two low O₂ affinity-inducing structuralperturbations. Despite the presence of the additional -aminogroup of Lys108(ß) within the central cavity, the-amino group of Lys99() of deoxy Hb-Presbyterian retained highselectivity for -fumaryl cross-bridging, with an overall efficiencycomparable to that with HbA. The -fumaryl cross-linking of Hb-Presbyterianreduced its O₂ affinity much more significantly than that observedwith HbA, indicating a synergy between the two low O₂ affinity-inducingstructural perturbations. Apparently, the -fumaryl cross-bridgein Hb-Presbyterian activates part of the latent low O₂ affinity-inducingpotential of Lys108(ß) that is generally activatedin the presence of chloride. The synergy between the Asn108(ß)Lysmutation and the -fumaryl cross-bridging was conserved in thepresence of chloride, but not in the presence of DPG. Furthermore,in the presence of chloride and DPG, -fumaryl Hb-Presbyterianaccessed a low O₂ affinity T-state that is accessed by HbA,-HbA and Hb-Presbyterian only in the presence of IHP. Isoelectricfocusing analysis suggested that the -fumaryl cross-linkingof Hb-Presbyterian induces changes in the ionization behaviorof one or more of the functional groups neighboring Lys99()and Lys108(ß) [presumably His103() and/or Glu101(ß)]to compensate for the extra positive charge of Lys108(ß).Molecular modeling studies identified two potential chloridebinding sites per ß dimer within the middle of thecentral cavity of -fumaryl HbA involving residues His103(),Arg104(ß) and Asn108(ß). The affinity ofthese sites is increased in -fumaryl Hb-Presbyterian as a resultof the Asn108(ß)Lys mutation. Thus, the results ofthe present study suggest that the enhanced neutralization ofthe positive charges in the middle of the central cavity ofHb achieved by these two electrostatic modifications, one (the-fumaryl cross-bridge) acting directly and the other (the Presbyterianmutation) acting indirectly through the mediation of chlorideion binding, facilitates the - fumaryl-Hb Presbyterian to accessa low O₂ affinity T-state structure much more readily than eitherHb-Presbyterian or -fumaryl HbA.     

A Pore-forming protein with a protease-activated trigger

Hemolysin (HL) is a 293 amino acid pore-forming toxin, whichis secreted as a water-soluble monomer by Staphylococcus aureus.By forming a hexameric pore, HL damages the plasma membranesof target cells. Previous studies established that HL proteinswith nicks near the midpoint of a central glycine-rich loopare held together by a domain-domain interaction and are hemolyticallyactive. In contrast, HL proteins comprising two HL truncationmutants that overlap in the central loop have no or greatlyreduced pore-forming activity, even though the two chains againform a tight complex. Based on these findings, overlap mutantshave now been designed that are activated when redundant aminoacids in the loop are removed by proteases. Further, the identityof the activating enzyme can be specified by additional mutagenesisof the protease recognition site in the overlap sequence. Mutantsof aHL that are activated by tumor-associated proteases mightbe useful components of immunotoxins     

Structure of {alpha}-{alpha}-hairpins with short connections

This paper presents the results of detailed stereochemical analysisof structures and sequences of --hairpins with short connections.It is shown that --hairpins of each given type have very similarpatterns of hydrophobic, hydrophilic and glycine residues intheir amino acid sequences. These results can be used in theprediction of --hairpin conformation as well as in protein designand engineering.     

Altered specificities of genetically engineered {alpha}1 antitrypsin variants

Seven active site variants of human ₁-antitrypsin (₁AT) wereproduced in Escherichia coli following site-specific mutagenesisof the ₁AT complementary DNA. ₁AT (Ala ³⁵⁸), ₁AT (Ile³⁵⁸ and₁AT (Val³⁵⁸), were efficient inhibitors of both neutrophil andpancreatic elastases, but not of cathepsin G. ₁AT (Ala³⁵⁸, Val³⁵⁸)and ₁AT (Phe³⁵⁸ specifically inhibited pancreatic elastase andcathepsin G respectively. The most potent inhibitor of neutrophilelastase was ₁AT (Leu³⁵⁸), which also proved to be effectiveagainst cathepsin G. The ₁AT (Arg³⁵⁸) variant inactivated thrombinwith kinetics similar to antithrombin III in the presence ofheparin. Electrophoretic analysis showed that SDS-stable highmol. wt complexes were formed between the mutant inhibitorsand the cognate proteases in each case. These data indicatethat effective inhibition occurs when the ₁AT P1 residue (position358) corresponds to the primary specificity of the target protease.Moreover, alteration of the P3 residue (position 356) can furthermodify the reactivity of the inhibitor. Two of the variantshave therapeutic potential: ₁AT (Leu³⁵⁸ may be more useful thanplasma ₁AT in the treatment of destructive lung disorders and₁ (Arg³⁵⁸ could be effective in the control of thrombosis.     

Engineered disulfide bonds in recombinant human interferon-{gamma}: the impact of the N-terminal helix A and the AB-loop on protein stability

Insertion sites for cysteines with optimal stereochemistry forthe formation of unstrained disulfide bridges were identifiedin recombinant human interferon- (rhu-IFN-) by computer modelling.We have engineered two different disulfide cross-linked mutants,containing a pair of symmetry-related disulfide bonds, whichstabilize the N-termini of both monomers of the homodimenc protein.Mutations E7C and S69C allow the formation of an intramonomerdisuffide bond between helices A and D. In contrast, the A17Cand H111C mutations lead to a covalent cross-link between bothmonomers. The AB-loop is linked to helix F. The fluorescenceproperties of native and disulfide cross-linked proteins werestudied as a function of guanidine hydrochloride concentration.Melting temperatures (T_m) were calculated from the decreasein CD ellipticity at 220 nm. The induction of the antiviraleffect was measured using A549 fibroblast cells infected withencephalomyocarditis virus. The ability to induce the expressionof the HLA-DR antigen in Colo 205 cells was determined by fluorescence-activatedcell scanning analysis. The stability of both mutants was stronglyenhanced against temperature- and cosolvent-induced unfolding.The T_m of mutant IFN- E7C/S69C was 15°C. All measured biologicalactivities of this mutant were equal to wild type. In the caseof the other mutant IFN- A17C/H111C, the T_m value was 25°C.This mutation abolishes nearly the entire biological activity(<1%) with no detectable changes of secondary structure inthe CD spectrum. Our results illustrate the importance of theN-terminal helix A and the AB-loop for the unfolding pathwayand thermodynamic stability of rhu-IFN-.     

The use of alanine scanning mutagenesis to determine the role of the N-terminus of the regulatory chain in the heterotropic mechanism of Escherichia coli aspartate transcarbamoylase

The location of the first seven residues of the regulatory chainof Escherichia coli aspartate transcarbamoylase has been identifiedby X-ray crystallography to be near the binding site of theregulatory nucleotides. In order to determine the function ofthe N-terminus of the regulatory chain of aspartate transcarbamoylasein heterotropic regulation, alanine scanning mutagenesis wasused. Specifically, Thr2r, His3r, Asp4r, Asn5r, Lys6r and Leu7rwere each replaced with alanine. Analyses of these mutant enzymesindicate that none of these substitutions significantly alterthe catalytic properties of the enzyme. However, three of themutant enzymes, Asp4r Ala, Lys6r Ala and Leu7r Ala, exhibitednotable changes in their response to the regulatory nucleotides,while mutations at Thr2r, His3r and Asn5r exhibited only minorchanges in their heterotropic responses. For the Asp4r Alaenzyme, the responses to ATP and CTP were reduced 30 and 40%respectively, compared with the wild-type enzyme. For the Lys6r Ala enzyme, the response to ATP was reduced 70%, while theCTP response was reduced 50%. In the case of the Leu7r Alaenzyme, a 30 and 20% reduction in response to ATP and CTP respectively,was observed. The synergistk inhibition by UTP in the presenceof CTP for the Lys6r Ala enzyme was reduced 40% compared withthat of the wild type enzyme. For the Leu7r Ala enzyme, thesynergistic inhibition was abolished. In addition, UTP decreasedthe CTP binding affinity of the Leu7r Ala enzyme. Analysisof the kinetic data from these mutant enzymes suggests thatresidues Thr2r, His3r and Asn5r have little effect on the heterotropicmechanism, while residues Asp4r, Lys6r and Leu7r play a moresignificant role in the heterotropic response of the enzymetoward the nucleotides. Furthermore, residue Leu7r appears tobe directly involved in the mechanism for synergistic inhibitionof aspartate transcarbamoylase. In this study alanine scanningmutagenesis has provided a rapid method of identifying thoseresidues in the N-terminal region of the regulatory chain ofaspartate transcarbamoylase important for heterotropic regulation.