PspGI, a Type II Restriction Endonuclease from the Extreme Thermophile Pyrococcus sp.: Structural and Functional Studies to Investigate an Evolutionary Relationship with Several Mesophilic Restriction Enzymes

“…However, with few exceptions concerning isoschizomers, restriction enzymes do not show sufficient sequence similarities to infer phylogenetic relationships without additional structural and/or functional information. Based on sequence alignments, we previously proposed that SsoII, PspGI, and EcoRII belong to the EcoRI branch and are structurally related to Bse634I, Cfr10I, and NgoMIV (23,25). This hypothesis was supported by a detailed experimental analysis and homology modeling, which demonstrated amino acid residues of SsoII and PspGI that align with functionally important residues in Bse634I, Cfr10I, and NgoMIV to be indeed essential for DNA binding and catalysis by SsoII and PspGI.…”

“…The involvement of this region in DNA binding and cleavage by Cfr10I and EcoRII is also apparent from crystal structures (32,33). For SsoII and PspGI, mutational analysis and protein-DNA cross-linking determined this region to be likewise important (23,25).…”

“…This has been interpreted as the enzymes having diverged early in evolution, presumably from a Type IIP enzyme that recognized 2CCXGG or X2CCGGX. It is intriguing to note that the sequence similarity over an interrupted stretch of ϳ70 amino acid residues can be extended to enzymes such as MboI (2GATC) that recognize unrelated sequences (25). Showing that MboI uses secondary structure elements composed of these ϳ70 amino acid residues for DNA binding and cleavage would be the first example of an evolutionary relationship between two subfamilies of restriction endonucleases with widely differing specificities within the EcoRI branch.…”

“…That these five enzymes (and their close relatives, see above) belong to different families (Type IIP, Type IIE, and Type IIF) is interpreted as their having a common ancestor, presumably a homodimeric enzyme that already had the variant active site and that acquisition of an effector domain (Type IIE) or generation of a dimer-dimer interface (Type IIF) is a more recent event in evolution (23). Although this evolutionary relationship is well supported by a previous structure-function relationship study of SsoII and PspGI, the suggestion that other Type II restriction enzymes that recognize unrelated sequences, such as 2GATC, G2GYRCC, and GG2CC (25), are evolutionarily related to SsoII, PspGI, EcoRII, NgoMIV, and Cfr10I has not yet been explored experimentally.…”

“…Cfr10I (R2CCGGY) (23)(24)(25). It is noteworthy that this group of related enzymes and their close relatives (SsoII: Kpn2kI/ Ecl18kI/StyD4I/SenPI; Cfr10I: Bse634I/BsrFI) comprises: (i) Type IIP enzymes such as SsoII and PspGI, homodimeric enzymes that recognize palindromic sequences; (ii) Type IIE enzymes such as EcoRII, homodimeric enzymes that need two recognition sequences for DNA cleavage, one sequence being cleaved and the other serving as an effector (26 -29); and (iii) Type IIF enzymes such as NgoMIV and Cfr10I, homotetrameric enzymes that cleave, in a concerted manner, DNA with two recognition sites (26,27,29,30).…”

Specificity Changes in the Evolution of Type II Restriction Endonucleases

“…However, with few exceptions concerning isoschizomers, restriction enzymes do not show sufficient sequence similarities to infer phylogenetic relationships without additional structural and/or functional information. Based on sequence alignments, we previously proposed that SsoII, PspGI, and EcoRII belong to the EcoRI branch and are structurally related to Bse634I, Cfr10I, and NgoMIV (23,25). This hypothesis was supported by a detailed experimental analysis and homology modeling, which demonstrated amino acid residues of SsoII and PspGI that align with functionally important residues in Bse634I, Cfr10I, and NgoMIV to be indeed essential for DNA binding and catalysis by SsoII and PspGI.…”

“…The involvement of this region in DNA binding and cleavage by Cfr10I and EcoRII is also apparent from crystal structures (32,33). For SsoII and PspGI, mutational analysis and protein-DNA cross-linking determined this region to be likewise important (23,25).…”

“…This has been interpreted as the enzymes having diverged early in evolution, presumably from a Type IIP enzyme that recognized 2CCXGG or X2CCGGX. It is intriguing to note that the sequence similarity over an interrupted stretch of ϳ70 amino acid residues can be extended to enzymes such as MboI (2GATC) that recognize unrelated sequences (25). Showing that MboI uses secondary structure elements composed of these ϳ70 amino acid residues for DNA binding and cleavage would be the first example of an evolutionary relationship between two subfamilies of restriction endonucleases with widely differing specificities within the EcoRI branch.…”

“…That these five enzymes (and their close relatives, see above) belong to different families (Type IIP, Type IIE, and Type IIF) is interpreted as their having a common ancestor, presumably a homodimeric enzyme that already had the variant active site and that acquisition of an effector domain (Type IIE) or generation of a dimer-dimer interface (Type IIF) is a more recent event in evolution (23). Although this evolutionary relationship is well supported by a previous structure-function relationship study of SsoII and PspGI, the suggestion that other Type II restriction enzymes that recognize unrelated sequences, such as 2GATC, G2GYRCC, and GG2CC (25), are evolutionarily related to SsoII, PspGI, EcoRII, NgoMIV, and Cfr10I has not yet been explored experimentally.…”

“…Cfr10I (R2CCGGY) (23)(24)(25). It is noteworthy that this group of related enzymes and their close relatives (SsoII: Kpn2kI/ Ecl18kI/StyD4I/SenPI; Cfr10I: Bse634I/BsrFI) comprises: (i) Type IIP enzymes such as SsoII and PspGI, homodimeric enzymes that recognize palindromic sequences; (ii) Type IIE enzymes such as EcoRII, homodimeric enzymes that need two recognition sequences for DNA cleavage, one sequence being cleaved and the other serving as an effector (26 -29); and (iii) Type IIF enzymes such as NgoMIV and Cfr10I, homotetrameric enzymes that cleave, in a concerted manner, DNA with two recognition sites (26,27,29,30).…”

Specificity Changes in the Evolution of Type II Restriction Endonucleases

Restriction Endonuclease and DNA-Modification Methyltransferases

Theoretical model of restriction endonuclease HpaI in complex with DNA, predicted by fold recognition and validated by site‐directed mutagenesis