A cytoplasmic protein–protein interaction detection method based on reporter translation

Analytical Biochemistry 384 (2009) 362–364

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Analytical Biochemistry j o u r n a l h o m e p a g e : w w w . e l s e v i e r. c o m / l o c a t e / y a b i o

Notes & Tips

A cytoplasmic protein–protein interaction detection method based on reporter translation Laurence Renaut *, Khalil Bouayadi, Hakim Kharrat, Philippe Mondon Mille­Gen, Im­me­u­ble BIO­STEP, 31681 Lab­e­ge Ce­dex, France

a r t i c l e

i n f o

Article history: Received 31 July 2008 Available online 17 October 2008 

a b s t r a c t One approach to drug dis­cov­ery involves the tar­get­ing of abnor­mal pro­tein–pro­tein inter­ac­tions that lead to pathol­ogy. We pres­ent a new tech­nol­ogy allow­ing the detec­tion of such inter­ac­tions within the cyto­plasm in a yeast-based sys­tem. The inter­ac­tion detec­tion is based on the seques­tra­tion of a trans­ la­tion ter­mi­na­tion fac­tor involved in stop codon rec­og­ni­tion. This seques­tra­tion inhib­its the activ­ity of the fac­tor, thereby per­mit­ting the trans­la­tion of a reporter gene har­bor­ing a premature stop codon. This novel cyto­plas­mic pro­tein–pro­tein inter­ac­tion (CPPI) detec­tion sys­tem should prove to be use­ful in the char­ac­ter­iza­tion of pro­teins as well as in part­ner iden­ti­fi­ca­tion, inter­ac­tion map­ping, and drug dis­cov­ery appli­ca­tions. © 2008 Else­vier Inc. All rights reserved.

The human genome con­sists of 20,000–30,000 genes cod­ing for more than 500,000 dif­fer­ent pro­teins. Rather than oper­at­ing alone, more than 80% of these pro­teins form com­plexes. Pro­tein–pro­tein inter­ac­tion mech­a­nisms are involved in many cel­lu­lar events and path­ol­ og­i­cal devel­op­ment. As such, a ful­ler under­stand­ing of these mech­a­nisms could help in the dis­cov­ery of new ther­ap ­ eu­tic tar­gets and in the con­cep­tion of new drugs. Many tools are cur­rently avail­ able to study such inter­ac­tions, but all have their draw­backs, mainly involv­ing a reduced com­pat­i­bil­ity between the detec­tion sys­tem and the prop­er­ties of the pro­tein (e.g., func­tion, cel­lu­lar local­i­za­ tion, post­trans­la­tional mod­i­fi­ca­tion) [1,2]. Hence, new tech­nol­o­ gies are needed to develop a vari­ety of meth­ods that would allow the study of a wide range of pro­teins involved in pro­tein–pro­tein inter­ac­tions. With this in mind, and with regard to pro­tein diver­ sity, we devel­oped a new tech­nol­ogy allow­ing the direct anal­y­sis of cyto­plas­mic pro­tein–pro­tein inter­ac­tions (CPPIs).1 As with mam­ma­lian prion pro­teins, the yeast prion pro­teins are pres­ent in either aggre­gated or sol­u­ble form; the aggre­gated form is able to con­vert the sol­u­ble into an aggre­gated form [3]. Sup35 is a yeast prion pro­tein com­posed of three domains. The Sup35 N-ter­mi­nal domain and M domain (Sup35NM) are respon­ si­ble for Sup35 aggre­ga­tion and main­te­nance of the aggre­gated form [4]. The Sup35 C-ter­mi­nal domain (Sup35C) has been shown to con­tain a stop codon rec­og­ni­tion domain. The seques­tra­tion of Sup35C into aggre­gates within the cyto­plasm inhib­its the stop trans­la­tion activ­ity [5]. We used a yeast [PSI+] strain con­tain­ing * Cor­re­spond­ing author. Fax: +33 5 61 28 70 11. E-mail address: lau­rence.re­naut@mille­gen.com (L. Renaut). 1 Abbre­vi­a­tions used: CPPI, cyto­plas­mic pro­tein–pro­tein inter­ac­tion; Sup35NM, Sup35 N-ter­mi­nal domain and M domain; Sup35C, Sup35 C-ter­mi­nal domain; WT, wild-type; Y2H, yeast two-hybrid; PCA, pro­tein com­ple­men­ta­tion assay. 0003-2697/$ - see front matter © 2008 Else­vier Inc. All rights reserved. doi:10.1016/j.ab.2008.10.011

endog­e­nous aggre­gated Sup35 prion pro­tein. In such a strain, the read-through of premature stop codons has been reported in some genes when Sup35 is aggre­gated, thereby result­ing in a par­tic­u­lar phe­no­type [6]. Using the char­ac­ter­is­tics of Sup35NM and Sup35C, we ­devel­oped an inter­ac­tion detec­tion sys­tem based on the lacZ reporter gene har­bor­ing a premature stop codon. This sys­tem was devel­oped with a pair of well-char­ac­ter­ized inter­act­ing pro­teins: P53 as bait and mi­niT as prey; the mi­niT cor­re­sponds to the SV40 T anti­gen domain con­tain­ing the P53 bind­ing site [7,8]. A lacZ reporter gene mutant (W13) har­bor­ing a premature stop codon (TGG548 ! TGA) was selected among 17 mutants for its depen­dence on a Sup35 aggre­ga­tion state for trans­la­tion (Fig. 1B). As depicted in Fig. 1A, the endog­e­nous Sup35 in the yeast [PSI+] strain is aggre­gated, thereby lead­ing to a read-through of the reporter lacZ W13 mutant. The lacZ W13 trans­la­tion depen­ dence on Sup35 aggre­ga­tion was tested using Gu­HCl, a com­pound known to sol­u­bi­lize Sup35 aggre­gates. Results in Fig. 1B show that, con­trary to wild-type (WT) lacZ, the lacZ W13 mutant trans­la­tion is depen­dent on Sup35 aggre­ga­tion. The require­ment of the detec­tion sys­tem resides in the fusion activ­ity of Sup35C. In the­ory, the fusion of Sup35C to a P53 ­pro­tein should change the phe­no­type asso­ci­ated with the lacZ W13 reporter gene. Indeed, the Sup35C part of the fusion pro­tein should stop the trans­la­tion of the reporter gene at the premature stop codon (Fig. 1C). No data exist, how­ever, regard­ing the abil­ity of Sup35C fused to het­er­ol­o­gous pro­tein to stop trans­la­tion sim­i­ larly to the full-length Sup35 pro­tein. There­fore, we cotrans­formed the yeast 74D694 [PSI+] strain with the W13 lacZ mutant gene and the P53–Sup35C fusion pro­tein or an empty vec­tor (con­trol). We then mon­i­tored the capac­ity of the P53–Sup35C fusion ­pro­tein to decrease the W13 mutant trans­la­tion of five iso­lated ­col­o­nies



Notes & Tips / Anal. Biochem. 384 (2009) 362–364

363

Endogen sup 35 aggregates

Endogen sup35 aggregates P53-sup35C fusion

ATG

sup35NM aggregation domain

polyA

ATG

polyA

sup35C stop codon recognition factor P53 β-galactosidase

relative π-galactosidase activity

1

Percentage of β-galactosidase activity

100

50

0 0

3

GuHCL concentration [µM]

0.5

0 W13

W13+P53Sup35C

Fig. 1. Effect of tar­get pro­tein fused to Sup35C on yeast phe­no­type. (A) Schematic rep­re­sen­ta­tion of W13 lacZ mutant gene expres­sion in the [PSI+] strain. (B) Test of the effect of Sup35 aggre­ga­tion sta­tus on the trans­la­tion of W13 lacZ mutant (gray) and WT lacZ (black). End­o­gen, endog­e­nous. (C) Schematic rep­re­sen­ta­tion of P53–Sup35C fusion expres­sion effect on W13 trans­la­tion. (D) Mea­sure of the lacZ W13 mutant activ­ity with P53–Sup35C fusion.

from each con­di­tion (Fig. 1D). The results showed that when fused to P53, Sup35C was still able to rec­og­nize the lacZ W13 stop premature codon and inhibit lacZ W13 expres­sion. This con­trol was essen­tial to ensure the inter­ac­tion with a given bait pro­tein. Fused to bait pro­tein, Sup35C activ­ity can be eas­ily observed, as a phe­no­typic change and the fea­si­bil­ity of the study con­firmed. In the case of non­func­tion­al­ity of the fusion pro­tein, a design of the bait pro­tein can be per­formed. This design will ensure the com­pat­ i­bil­ity between Sup35C and the bait pro­tein in a fusion con­text and enable its use in our sys­tem. The abil­ity of Sup35NM fused to a het­er­ol­o­gous pro­tein to form aggre­gates has been well described and has included pro­teins har­bor­ing dif­fer­ent pro­pri­e­ties: the Gag-P55 anti­gen of HIV-1, green fluo­res­cent pro­tein, and a tran­scrip­tion fac­tor (glu­co­cor­ti­ coid recep­tor) [9–11]. We con­cluded that a het­er­ol­o­gous pro­tein fused to Sup35NM should be found in aggre­gates. The prin­ci­ple behind this inter­act­ing sys­tem, illus­trated with P53 and mi­niT, is described in Fig. 2. An R3 pep­tide that does not bind P53 was used as a neg­at­ ive con­trol. The fusion pro­tein com­pris­ing mi­niT or R3 fused to Sup35NM was coex­pres­sed with P53–Sup35C fusion pro­tein and lacZ W13 mutant. As P53 and mi­niT inter­acted, we expected col­o­nies con­tain­ing Sup35NM–mi­niT and P53–Sup35C fusions to show a phe­no­type asso­ci­ated with a read-through of the W13 lacZ premature stop codon due to Sup35C seques­tra­tion within aggre­gates via mi­niT–P53 inter­ac­tion (Fig. 2A). In con­trast, we expected the neg­a­tive con­trol cor­re­spond­ing to Sup35NM–R3 and P53–Sup35C to gen­er­ate a phe­no­type asso­ci­ated with the ­incom­plete trans­la­tion of the reporter gene. Because P53 and R3 did not ­inter­act, the P53–Sup35C fusion remained free to stop trans­la­tion of the lacZ W13 reporter pro­tein (Fig. 2B). Because over­ex­pres­sion of Sup35NM has been described as being harm­ful for yeast via­bil­ity [12], the expres­sion of the Sup35NM–mi­niT fusion pro­tein was placed under the con­trol of the PCUP-1 pro­moter (CuSO4 induc­ible). We tested the capac­ity of the Sup35NM–mi­niT fusion to restore the W13 lacZ expres­ sion by cotrans­for­ming the yeast with W13 lacZ, P53–Sup35C, and either the inter­act­ing fusion Sup35NM–mi­niT or the non­in­ter­act­

ing fusion Sup35NM–R3. Increas­ing con­cen­tra­tions of CuSO4 were used to induce the Sup35NM fusion expres­sion and the W13 lacZ mutant expres­sion mea­sured (Fig. 2C). As expected, the expres­sion of Sup35NM–mi­niT fusion, but not Sup35NM–R3 fusion, restored the W13 lacZ expres­sion. The restored expres­sion of the W13 lacZ mutant was pro­por­tional to the level of induc­tion of 35NM–­mi­ niT expres­sion by CuSO4. Results show that the coex­pres­sion of the two fusion pro­teins con­tain­ing inter­act­ing moi­e­ties led to a ­sig­nif­i­cantly detect­able expres­sion of the lacZ W13 mutant. Finally, we have shown that the Sup35NM–mi­niT effect on the expres­sion of lacZ W13 is depen­dent on the pres­ence of P53 fused to Sup35C. Fig. 2D describes the effect of Sup35NM–mi­niT on lacZ W13 expres­sion in the pres­ence of P53–Sup35C or Sup35C alone. Expres­sion of P53–Sup35C fusion or Sup35C alone reduced the expres­sion of lacZ W13. How­ever, as shown ear­lier, the coex­pres­ sion of Sup35NM–mi­niT with P53–Sup35C fusion led to a strong expres­sion of the W13 lacZ mutant. This phe­nom­e­non was not observed with Sup35C alone coex­pres­sed with the Sup35NM–mi­ niT fusion. The data pro­vide evi­dence for the effect of Sup35NM–mi­niT on lacZ W13 expres­sion being spe­cific to the pres­ence of P53 fused to Sup35C. The inter­ac­tion of mi­niT and P53 can be mon­i­tored in the cyto­plasm of the yeast via the lacZ W13 mutant expres­sion detec­tion. Many cel­lu­lar pro­cesses are reg­u­lated by pro­tein–pro­tein inter­ ac­tion, and our tech­nol­ogy is an excel­lent tool to advance in­ter­ ac­tom­e under­stand­ing. Fur­ther­more, many cel­lu­lar events such as those involved in sig­nal­ing path­ways occur in the cyto­plasm, with some inter­ac­tions requir­ing post­trans­la­tional mod­i­fi­ca­tions of the inter­act­ing part­ners. Because our tech­nol­ogy allows the detec­ tion of pro­tein inter­ac­tions within the cyto­plasm, it is a per­ti­nent approach to study­ing pro­tein inter­ac­tions in their nat­u­ral sub­cel­ lu­lar com­part­ment. Yeast-based meth­ods, such as Y2H (yeast two-hybrid) [13] and PCA (pro­tein com­ple­men­ta­tion assay) [14], are widely used to study pro­tein inter­ac­tions. Our tech­nol­ogy pro­vides a good ­alter­na­tive to these in vivo meth­ods when performing inter­ac­tion stud­ies for a given bait pro­tein. Fur­ther­more, sim­i­lar to Y2H and

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Notes & Tips / Anal. Biochem. 384 (2009) 362–364

Interaction (Sup35NM-miniT)

No interaction (Sup35NM-R3)

↔ Endogen sup 35 aggregates

Endogen sup 35 aggregates

↔ ↔

ATG

polyA

ATG

Sup35NM aggregation domain Sup35C stop codon recognition factor

CuSO4 (20µM)

P53 R3 miniT

0

W13+sup35NM-miniT

W13+P53sup35C+sup35NMminiT

W13+P53sup35C+sup35NMR3

W13+P53-sup35C

0

0.7

W13+sup35 C+sup35NM-miniT

CuSO4 (10µM)

CuSO4 (0µM) CuSO4 (5µM) CuSO4 (10µM) CuSO4 (20µM)

1.4

W13+sup35C

β-galactosidase

CuSO4 (5µM)

W13+P53sup35C+sup35NM-miniT

CuSO4 (2µM)

W13+P53-sup35C

CuSO4 (0µM)

relativeβ-galactosidaseactivity

Relativeβ-galactosidse activity

1

0.5

polyA Reporter protein

Fig. 2. Effect of pres­ence of both part­ners fused to Sup35C and Sup35NM on yeast phe­no­type. (A,B) Schematic rep­re­sen­ta­tions of expected results when express­ing Sup35NM– mi­niT (A) or Sup35NM–R3 (B). End­og ­ en, endog­e­nous. (C) Mea­sure of W13 expres­sion with a pair of inter­act­ing pro­teins or non­in­ter­act­ing pro­teins. (D) Test of the influ­ence of P53 fused to Sup35C on the Sup35NM–mi­niT effect on W13 expres­sion res­to­ra­tion.

PCA, in our sys­tem bait and prey pro­teins are in a trans­la­tional fusion for­mat. Our tech­nol­ogy allows us to ensure the func­tion­al­ity of Sup35C fused to a given bait pro­tein before pur­su­ing the inter­ ac­tion stud­ies. Y2H has been suc­cess­fully used to iden­tify pro­tein– pro­tein ­inter­ac­tions in sev­eral model organ­isms. Nev­er­the­less, the inter­ac­tion in Y2H occurs in the nucleus, which is not the nat­u­ral cel­lu­lar ­com­part­ment of many pro­teins of inter­est for inter­ac­tion stud­ies. In con­trast, our sys­tem pro­vides a direct detec­tion in the cyto­plasm, where the post­trans­la­tional mod­i­fi­ca­tions are impor­ tant for pro­tein inter­ac­tion. This tech­nol­ogy should prove to be use­ful in the ­char­ac­ter­iza­tion of pro­teins as well as in part­ner iden­ti­fi­ca­tion, inter­ac­tion map­ ping, and drug dis­cov­ery appli­ca­tions. It may also be adapted in the devel­op­ment of a tool for use in drug dis­cov­ery such as the screen­ ing of small mol­ec­ ules, pep­tides, or in­tra­bod­ies able to ­mod­u­late intra­cy­to­plas­mic inter­ac­tions in a high-through­put screen­ing ­for­mat. For this pur­pose, other reporter genes and expres­sion cas­ settes are cur­rently opti­mized for use in stud­ies that could be the basis of devel­op­ing drugs for use in dis­or­ders often involv­ing the path­ol­ og­i­cal dereg­u­la­tion of otherwise finely reg­u­lated cel­lu­lar pro­tein inter­ac­tions. Acknowl­edg­ments We thank M. Blon­del (U613-IN­SERM, Brest) for pro­vid­ing the yeast 74D694 strain and yeast expres­sion plas­mids and for engag­ing in help­ful dis­cus­sions at the begin­ning of this pro­ject. We thank Mille­Gen’s sequenc­ing ser­vice for the qual­ity of the results. We also thank our col­lab­o­ra­tors: M.J. Car­les for tech­ni­ cal sup­port and A. Def­lis­que, C. Mon­net, O. Dub­reuil, F. Cro­zet, and P. Brune for dis­cus­sions and crit­i­cal reviews of the man­u­ script.

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