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PstI

PstI is a type II restriction endonuclease originally isolated from the Gram-negative bacterium Providencia stuartii. It specifically recognizes the palindromic hexanucleotide DNA sequence 5'-CTGCAG-3' and cleaves the phosphodiester bond immediately downstream of the 3'-A in each strand, generating 3' sticky ends with a 4-base overhang (5'-TGCA-3'). Discovered in 1976 through purification from P. stuartii strain 164 using osmotic shock extraction and chromatography, PstI was one of the early restriction enzymes characterized, producing more than 18 cleavages upon digestion of bacteriophage λ DNA. The enzyme requires Mg²⁺ as a cofactor and operates optimally at 37°C in a buffer containing 50 mM NaCl, with activity in various commercial buffers like O or rCutSmart. Its isoschizomer, BspMAI, shares the same recognition site but may differ in cleavage efficiency under certain conditions. In , PstI plays a crucial role in technology, enabling precise DNA fragmentation for , , , Southern blotting, restriction fragment length polymorphism (RFLP) analysis, and (SNP) studies. Engineered high-fidelity variants, such as PstI-HF, minimize non-specific "star" activity while maintaining full specificity, enhancing reliability in complex digests. The enzyme's production in recombinant E. coli strains ensures high purity and consistency for laboratory use.

Biological and Historical Context

Source Organism

PstI is a type II restriction endonuclease derived from the Gram-negative bacterium , a member of the family often associated with opportunistic infections in humans. In the of P. stuartii, the encoding the PstI endonuclease (pstI) and the for its cognate methyltransferase (pstM) are arranged in a divergent orientation, transcribed from separate promoters located within an of 130 base pairs separating the two coding sequences. This genomic configuration allows coordinated expression of the restriction and modification activities while maintaining distinct regulatory elements for each . The native role of the PstI system in P. stuartii is to function as part of a type II restriction-modification (R/M) system, providing defense against invading foreign DNA, such as from bacteriophages, by selectively cleaving unmethylated sequences while protecting the host genome through site-specific methylation. This mechanism contributes to the bacterium's restriction barrier, enhancing its survival in environments with potential viral threats.

Discovery and Isolation

PstI, a type II restriction endonuclease, was first isolated in the mid-1970s from the bacterium strain 164 during efforts to identify new enzymes for DNA manipulation. The discovery was reported by researchers D. I. Smith, F. R. Blattner, and J. Davies, who sought to expand the repertoire of restriction enzymes beyond those initially characterized from species like Haemophilus and . Their work built on the growing recognition of bacterial defense mechanisms against phages, leading to the identification of this enzyme through screening of bacterial lysates for endonucleolytic activity on lambda DNA. The isolation process involved large-scale cultivation of P. stuartii 164, followed by harvesting via and osmotic shock treatment to release the periplasmic into the supernatant. This crude extract contained the active endonuclease along with other proteins and cellular debris. Early studies emphasized the 's requirement for Mg²⁺ as the sole cofactor, distinguishing it from more complex type I systems. Purification from the bacterial extracts involved sequential to enhance specificity and reduce contaminants. The resulting partially purified preparation retained activity for DNA cleavage and was stable when stored at low temperatures, enabling initial characterization of its specificity on viral and substrates.

Biochemical Characteristics

Enzyme Structure

PstI is a type II restriction endonuclease that functions as a homodimer, with the catalytically active form exhibiting a molecular weight of approximately 69,500 as determined by gel filtration . Each subunit has a molecular weight of 37,370 and consists of 326 residues encoded by the . The dimeric structure displays 2-fold , which aligns with the dyad axis of its palindromic DNA recognition sequence, facilitating symmetric binding and cleavage. The subunit sequence, derived from the nucleotide sequence of the pstIR gene, includes conserved residues essential for catalysis. The protein's charge distribution features 54 positively charged residues and 41 negatively charged residues, contributing to its net positive charge and influencing solubility and electrostatic interactions during DNA binding. This asymmetry in charges may support the enzyme's affinity for the negatively charged DNA backbone while maintaining overall stability in solution.

Recognition and Cleavage Mechanism

PstI is a type II restriction endonuclease that specifically recognizes the palindromic DNA sequence 5'-CTGCAG-3' and cleaves the phosphodiester backbone between the and residues on both strands, resulting in the notation 5'-CTGCA^G-3'. This staggered cleavage generates cohesive ends with 3' overhangs of four , specifically the sequence 5'-TGCA-3', which facilitates ligation in procedures. The enzyme operates as a homodimer, with each binding symmetrically to one half of the recognition site, aligning the active sites for precise incision. Cleavage is magnesium ion-dependent, requiring Mg²⁺ as a cofactor to facilitate the of the phosphodiester bonds at the defined staggered positions within the recognition sequence. This ensures in target site selection, characteristic of type II restriction enzymes. PstI exhibits site-specific cleavage preferences even among identical recognition sequences, as demonstrated in plasmid pSM1, where four equivalent sites are cleaved sequentially at markedly different rates. These differences arise from flanking sequences, particularly adjacent G-C-rich regions, which impose resistance to cleavage by altering local DNA accessibility or enzyme binding affinity. Notably, the enzyme's cleavage efficiency remains unaffected by DNA superhelicity, showing consistent site preferences across supercoiled, relaxed circular, nicked, and linear forms of the substrate.

Applications in Biotechnology

DNA Cloning and Manipulation

PstI is widely utilized in DNA cloning workflows due to its ability to produce cohesive 3' overhangs of the sequence 5'-TGCA-3', which enable efficient ligation of DNA fragments into vectors. These sticky ends are generated by cleavage within the recognition site 5'-CTGCAG-3', allowing for the creation of recombinant molecules with high fidelity when compatible overhangs are present. This property has made PstI a staple enzyme for inserting genes or DNA segments into plasmids, particularly in strategies where precise joining is essential to maintain reading frames or promoter orientations. The 3' overhangs produced by PstI are compatible with those generated by enzymes such as NsiI (which recognizes 5'-ATGCA^T-3'), AspEI, and AspHI, permitting to form hybrid sites like CTGCAT that cannot be recut by either enzyme, thus stabilizing inserts. For instance, NsiI-compatible ends from PstI-digested fragments can be ligated into vectors prepared with NsiI, facilitating of PCR-amplified products or synthetic genes without altering the sequence significantly. Isoschizomers like BspMAI and SalPI share the same recognition sequence and produce identical 3' overhangs, offering alternatives in reactions where sensitivity or compatibility varies, though PstI's overhang orientation remains distinct from neoschizomers that cut the same site differently. In preparation, PstI is commonly employed to linearize plasmids or excise inserts from multiple cloning sites (MCS), such as those in the pUC series, where the enzyme's site is positioned within the lacZα gene for blue-white screening of recombinants. For example, digestion of with PstI alongside another enzyme like allows directional insertion of gene fragments, ensuring proper orientation for expression. This approach was instrumental in early technologies during the 1970s and 1980s, as seen in the construction of vectors, where PstI sites enabled insertional inactivation of antibiotic resistance genes to select for hybrid molecules.

Analytical and Diagnostic Uses

PstI plays a significant role in restriction fragment length polymorphism (RFLP) analysis, where it detects sequence variations by generating distinct DNA fragment patterns based on the presence or absence of its recognition site (CTGCA^G). In this technique, genomic DNA is digested with PstI, and the resulting fragments are separated by gel electrophoresis, revealing polymorphisms that arise from mutations creating or eliminating restriction sites. For instance, PstI RFLP has been used to identify codominant alleles in the human placental alkaline phosphatase (ALPP) gene, enabling the study of genetic variation through Southern blot hybridization of the digested fragments. Additionally, PstI's methylation sensitivity makes it valuable for enriching libraries with single- or low-copy sequences during RFLP probe development, as it preferentially cuts unmethylated DNA in gene-poor regions. In Southern blotting and applications, PstI-digested DNA fragments are transferred to membranes and probed to visualize specific alleles or insertions/deletions, facilitating precise . This approach has been employed to map polymorphisms in the human F1 beta subunit , where PstI digestion produced variant fragment sizes detectable via hybridization, aiding in linkage analysis and disease association studies. PstI's generation of 3' overhangs (sticky ends) enhances fragment separation on gels, improving resolution in these assays for downstream hybridization. Southern blotting with PstI has also been integral to early forensic , where it helped distinguish individual genotypes by comparing restriction patterns from crime scene samples against known profiles. For (SNP) detection and , PstI is commonly integrated into PCR-RFLP assays, where amplified DNA regions containing potential SNPs are digested to produce allele-specific fragments. Tools like SNP-RFLPing software select PstI for designing such assays across multiple SNPs, optimizing for discriminatory power in . In , PstI-based RFLP markers have contributed to high-density linkage maps by integrating with other markers to span the . In forensic and evolutionary studies, the frequency of PstI sites serves as a marker for genetic diversity; for example, RFLP analysis with PstI has elucidated phylogenetic relationships among inbred lines by quantifying shared restriction patterns, reflecting evolutionary divergence. These applications underscore PstI's utility in diagnostics, where its specific cleavage enables reliable detection of genetic variations without requiring extensive sequencing.

Practical Considerations

Reaction Conditions

PstI exhibits optimal activity at 37°C, with complete typically achieved within 1 hour under standard conditions. The can be inactivated by heating at 80°C for 20 minutes, which denatures the protein and stops further cleavage. PstI is optimally active in such as NEB's rCutSmart Buffer (50 mM , 20 mM Tris-acetate, 10 mM , 100 µg/ml recombinant , pH 7.9) or Thermo Scientific's Buffer O (50 mM Tris-HCl (pH 7.5 at 37°C), 10 mM MgCl₂, 100 mM NaCl, 0.1 mg/ml BSA). High-fidelity variants of PstI are compatible with rCutSmart , which supports efficient while reducing off-target effects. One unit of PstI is defined as the amount required to digest 1 μg of lambda DNA (containing 28 recognition sites) in 1 hour at 37°C in a 50 μL reaction volume. Several factors can affect PstI activity, including the presence of high glycerol concentrations (>10-12% v/v), which may lead to incomplete digestion or star activity (non-specific cleavage). Similarly, impure DNA substrates, such as those contaminated with salts, , or from preparation, can inhibit enzymatic efficiency. Star activity is notably minimized in high-fidelity engineered variants of PstI, which maintain specificity under a broader range of conditions.

Commercial Availability and Variants

PstI is commercially available from several major biotechnology suppliers, including (NEB), , and Jena Bioscience. These suppliers offer the enzyme in various package sizes with concentrations typically ranging from 10 to 100 units per microliter. For instance, Thermo Fisher provides PstI at 10 U/μL in packages of 3,000 units or larger, while NEB offers formulations at 20,000 U/mL or 100,000 U/mL in 10,000-unit or 50,000-unit vials, and Jena Bioscience supplies it at 10 U/μL in 8,000-unit formats. Note that NEB's large concentrated size will be discontinued on December 15, 2025, but smaller sizes remain available. The enzyme is produced through recombinant expression in strains engineered to carry the from its source organism, . This method, pioneered by NEB in the early 1980s, enables high-yield production and over 100-fold increased expression compared to native sources. Starting from lot #10237495, NEB formulations include recombinant (rAlbumin) for enhanced stability and consistency. Suppliers implement rigorous , including assays for contaminating endonuclease, , and DNase activities, ensuring high purity and consistent performance, often exceeding 95% purity in commercial preparations. Engineered variants of PstI address limitations such as star activity, which can occur under non-optimal conditions like high enzyme concentrations. NEB's PstI-HF, a high-fidelity version introduced in the , maintains the same recognition specificity (CTGCA^G) but exhibits significantly reduced off-target cleavage, allowing precise digestion even in broader buffer ranges and shorter incubation times. This variant is available in similar concentrations and sizes as the standard , enhancing reliability for applications requiring accuracy. Standard pricing for PstI varies by supplier and package size but generally ranges from $5 to $10 per 1,000 units for larger formats (as of November 2025), making it highly accessible for use. For example, Thermo Fisher's 3,000-unit package costs approximately $31, while NEB's 10,000-unit vial is priced at $76. The availability of high-fidelity updates like PstI-HF has modernized the enzyme's utility, overcoming drawbacks of the wild-type form without increasing costs substantially.

References

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