Principles, Practice, and Evolution of Capillary Electrophoresis as a Tool for Forensic DNA Analysis.

Capillary electrophoresis (CE) is a versatile and widely used analysis platform with application in diverse areas such as analytical chemistry, chiral separations, clinical, forensics, molecular biology, natural products, organic chemistry, and the pharmaceutical industry. Forensic applications of CE include fragment analysis, DNA sequencing, SNP typing, and analysis of gunshot residues, explosive residues, and drugs. Fragment analysis is a widely used method for short tandem repeat (STR) profiling for human identification (HID) due to the single-base resolution capability of CE. This approach circumvents the tedious and expensive approach of DNA sequencing for STR typing. The high sizing precision, ability to detect fluorescence emitted from multiple dyes, automated electrophoretic runs, and data collection software are key factors in the worldwide adoption of CE as the preferred platform for forensic DNA analysis. The most common CE systems used in forensic DNA analysis include the ABI PRISM® 310, 3100, 3100 Avant, 3130, 3130xl, 3500, and 3500xL Genetic Analyzers (GAs). The 3500 series GAs are developed with features useful for forensic scientists, including a normalization feature for analysis of the data designed to reduce the variation in peak height from instrument to instrument and injection to injection. Other hardware and software features include improved temperature control, radio frequency identification (RFID) tags for monitoring instrument consumables, HID-focused software features, and security and maintenance.

Training of Forensic DNA Scientists - A Commentary.

For the past two decades, forensic DNA analysis has rapidly expanded in both utility and value to criminal investigations. As the number of crime scene and convict/arrestee samples has continued to grow, many forensic DNA laboratories find themselves struggling to test samples in a timely fashion. Agencies employ various methods for calculating their sample intake and processing capacity, yet database and casework sample backlogs continue to present a major challenge. One issue many forensic laboratories face is limited availability of resources for training new analysts. High-quality training enables analysts to effectively perform various aspects of DNA profiling, and as such, it is essential to ensuring consistent, high-quality results. This is well documented in the guidelines established in the FBI's Quality Assurance Standards for Forensic DNA Testing Laboratories in the United States as well as internationally by agencies like INTERPOL. A facility dedicated to training analysts on both theoretical and practical aspects of automated sample processing accelerates the establishment and expansion of high-throughput forensic DNA laboratories. The present article will discuss various aspects of training and agencies that provide such training programs.

Extraction of DNA from Forensic Biological Samples for Genotyping.

Biological forensic samples constitute evidence with probative organic matter. Evidence believed to contain DNA is typically processed for extraction and purification of its nucleic acid content. Forensic DNA samples are composed of two things, a tissue and the substrate it resides on. Compositionally, a sample may contain almost anything and for each, the type, integrity, and content of both tissue and substrate will vary, as will the contaminant levels. This fact makes the success of extraction one of the most unpredictable steps in genotypic analysis. The development of robust genotyping systems and analysis platforms for short tandem repeat (STR) and mitochondrial DNA sequencing and the acceptance of results generated by these methods in the court system, resulted in a high demand for DNA testing. The increasing variety of sample submissions created a need to isolate DNA from forensic samples that may be compromised or contain low levels of biological material. In the past decade, several robust chemistries and isolation methods have been developed to safely and reliably recover DNA from a wide array of sample types in high yield and free of PCR inhibitors. In addition, high-throughput automated workflows have been developed to meet the demand for processing increasing numbers of samples. This review summarizes a number of the most widely adopted methods and the best practices for DNA isolation from forensic biological samples, including manual, semiautomated, and fully automated platforms.

Extraction of DNA from Human Remains.

Improvements to analytical methods have made it possible for highly discriminative genotypic information to be gleaned from smaller and smaller amounts of sample material. This fact makes it practical to genotype samples or remains consisting of bone and tooth-samples that likely would not have yielded interpretable genotypic results a short time ago. In parallel, there have been improvements to protocols specifically designed to recover DNA from very old calcified tissues, i.e., ancient or compromised nature. This review discusses the current best practices for isolating and purifying DNA from bones and teeth with a focus on the processes of lysis and DNA purification linked together to yield DNA from these challenging samples. The mitochondrial and genomic DNA recovered from more recently developed techniques for isolation from skeletal remains and teeth, even very old samples, is surprisingly amenable to genotypic analysis.

Assessment of DNA Extracted from Forensic Samples Prior to Genotyping.

Quantification of human DNA has been an integral part of forensic DNA analysis. Hybridizationbased methods such as Quantiblot® kits were used extensively in the 1990s. These methods fulfilled the need at the time, since their sensitivity range was similar to the genotyping methods in use, such as restricted fragment length polymorphism. Later, the development of robust and more sensitive megaplex genotyping systems such as short tandem repeat profiling, mitochondrial DNA sequencing, and single nucleotide polymorphism typing, created the need not only for quantification of DNA at the picogram level but also for assessment of the quality of the DNA extract to make informed decisions to ensure the success of downstream analysis. Real-time PCR-based quantification methods fulfilled this need. The different real-time PCR methods developed range from singleplex reactions for quantification of human or mitochondrial DNA to multiplex systems that enable analysis of up to four targets for quantification of human DNA, human male DNA, mitochondrial DNA, detection of PCR inhibitors, or determination of the extent of DNA degradation. Incorporation of these assays into the workflow enables selection of appropriate genotyping systems and increases the first-pass success rate for obtaining a genotype using a minimal amount of evidence sample. The real-time PCR methods described here would also be useful as DNA assessment tools prior to other genotyping methods like copy number variation, insertion/deletion, and Alu dimorphism analysis as well as sequencing, etc., that are currently being investigated as additional informative tools for human identification purposes.

Y-Short Tandem Repeat Multiplex Systems - Y-PLEX™ 6 and Y-PLEX™ 5.

Y-Chromosome short tandem repeats (Y-STRs) have become a very useful tool in forensic casework, paternity, and male lineage studies. In forensic casework, one can obtain the male profile from a mixture sample containing male and female DNA. Two Y-STR genotyping systems, Y-PLEX™ 6 and Y-PLEX™ 5, have been developed for use in human identification. Y-PLEX™ 6 enables simultaneous amplification of DYS393, DYS19, DYS389II, DYS390, DYS391, and DYS385; Y-PLEX™ 5 enables simultaneous amplification of DYS389I, DYS389II, DYS439, DYS438, and DYS392 loci. The Y-PLEX™ 6 and Y-PLEX™ 5 systems together provide analysis of all nine Y-STR loci generating minimal haplotype and two additional loci, DYS438 and DYS439. These systems also provide analysis for all 11 Y-STR loci recommended by the Scientific Working Group on DNA Analysis Methods (SWGDAM) for forensic casework and population database studies. Both the systems were validated following the Federal Bureau of Investigation (FBI) Director's Quality Assurance Standards. Allelic ladders, which serve as a reference in genotyping, were generated. The nucleotide sequence of alleles in the allelic ladder was determined and the nomenclature is in accord with the recommendations of the International Society of Forensic Genetics (ISFG). The minimum sensitivity of the Y-PLEX™ 6 and Y-PLEX™ 5 systems was 0.2 and 0.1 ng of male DNA, respectively. The nonhuman study revealed that the primers in the Y-PLEX™ 6 and Y-PLEX™ 5 systems were specific for the DNA from humans and some higher primates. Mean stutter values ranged from 3.6 to 11.9%. The Y-PLEX™ 6 and Y-PLEX™ 5 systems were used in several forensic cases. The results from these multiplex systems have been admitted in various U.S. Courts. Thus, Y-PLEX™ 6 and Y-PLEX™ 5 genotyping systems are sensitive, reliable, and robust for use in human forensic and male lineage identification studies.

Detection and correction of a migration anomaly on a 310 genetic analyzer.

During STR analysis on the 310 Genetic Analyzer, retarded migration of GS500ROX size standards and alleles in some samples was observed. The contribution of reagents, capillary and performance optimized polymer POP 4 to the observed anomaly was experimentally eliminated. Variation in electrophoresis temperature between 55 degrees C and 65 degrees C did not alter the rate of migration of GX500ROX size standard and sample alleles. An eroded connector for the cathode mounted on the heat plate assembly caused the abnormal migration. Hence, it is important to verify the mobility of all fragments in the size standard for each sample to avoid any erroneous allele calls by the automated data analysis software.

Beaded reactive polymers. 3. Effect of triacrylates as crosslinkers on the physical properties of glycidyl methacrylate copolymers and immobilization of penicillin G acylase.

Various glycidyl methacrylate (GMA) copolymers were synthesized by suspension polymerization, using pentaerythritol triacrylate (PETA), trimethylolpropane triacrylate (TMPTA), and trimethylolpropane trimethacrylate (TRIM) as crosslinking comonomers. These copolymers were evaluated for the immobilization of penicillin G acylase. Broad pore-size distribution that was observed was in the range 5-300 nm. Both surface area and pore volume increased with increase in the mole fraction of crosslinking comonomer (increasing crosslink density). The pore volume of the copolymers was more than doubled by including lauryl alcohol as porogen. Binding of penicillin G acylase (PGA) was quantitative on highly crosslinked copolymers. The expression of bound PGA was better on the relatively more hydrophilic GMA-TMPTA and GMA-PETA copolymer supports compared to the GMA-TRIM copolymers. Among the different copolymers studied, GMA-TMPTA copolymer 7411 exhibited highest activity of immobilized penicillin G acylase (167.4 IU/g) with 35.1% expression.

Thermal stability of penicillin G acylase : effect of stabilizing agents.

The role of sugars, polyhydroxy compounds, phenylacetic acid and 6-aminopenicillanic acid in stabilization of immobilized penicillin G acylase (IMPGA) was studied. The loss in the activity of IMPGA at 50 degrees C, 2 h, after incorporation of sucrose and mannitol at 0.1 M concentration was 16 and 18% respectively; the loss in the activity of the enzyme under these conditions in the absence of stabilizing agents was 40%.

Effect of amino acids on the production and activities of cephalosporin C acylase and penicillin V acylase from Aeromonas species ACY 95.

Amino acids altered the production and activities of cephalosporin C acylase and penicillin V acylase from Aeromonas species ACY 95 to a varying degree. DL-Tryptophan enhanced the cephalosporin C acylase formation by 222% while suppressed the penicillin V acylase formation by 68%.

Evaluation of product analogues for purification of penicillinase by affinity chromatography.

Among different matrices prepared, ampicilloic acid-polymer matrix offered 86.7% adsorption, 95% elution and 82.4% overall recovery of penicillinase. The structure of both the side chain and penicilloic or cephalosporoic acid moieties contribute to the affinity interactions.

Cephalosporin C acylase and penicillin V acylase formation by Aeromonas sp. ACY 95.

Aeromonas sp. ACY 95 produces constitutively and intracellularly a penicillin V acylase at an early stage of fermentation (12 h) and a cephalosporin C acylase at a later stage (36 h). Some penicillins, cephalosporin C and their side chain moieties/analogues, phenoxyacetic acid, penicillin V and penicillin G, enhanced penicillin V acylase production while none of the test compounds affected cephalosporin C acylase production. Supplementation of the medium with some sugars and sugar derivatives repressed enzyme production to varying degrees. The studies on enzyme formation, induction and repression, and substrate profile suggest that the cephalosporin C acylase and penicillin V acylase are two distinct enzymes. Substrate specificity studies indicate that the Aeromonas sp. ACY 95 produces a true cephalosporin C acylase which unlike the enzymes reported hitherto hydrolyses cephalosporin C specifically.

Purification and characterization of extracellular penicillin V acylase from Fusarium sp. SKF 235.

Penicillin V acylase from Fusarium sp. SKF 235 culture filtrate was purified to homogeneity. The enzyme was a glycoprotein and composed of single polypeptide chain with molecular weight of 83,200 Daltons. The pH and temperature optima were 6.5 and 55 degrees C, respectively. The KM for penicillin V was 10 mM but the enzyme was inhibited by penicillin V at concentrations above 50 mM. Products of reaction, 6-aminopenicillanic acid and phenoxyacetic acid inhibited the enzyme competitively and noncompetitively with Ki values of 18 mM and 45 mM, respectively. The enzyme specifically hydrolyzed penicillin V, cephalosporanic acid V and penicillin V sulphoxide. Other phenoxy acetyl amides studied were not hydrolysed. It is proposed that phenoxyacetyl moiety alone is not recognized by the penicillin V acylase and in addition, the beta-lactam structure contributes in formation of enzyme-substrate complex.

Aryl beta-galactosidase from Sclerotium rolfsii: physiological and biochemical studies.

Production of beta-galactosidase by Sclerotium rolfsii NCIM 1084 was studied under submerged fermentation conditions. The enzyme was produced extracellularly and constitutively on glucose. The enzyme production was enhanced when galactose, raffinose, cellobiose, sucrose, xylose, maltose, cellulose and pectin were used as carbon sources. Cellulose and diammonium hydrogen phosphate were best carbon and nitrogen sources, respectively. Surfactants such as Sag, Paraffin oil, Tween 20 and Tween 80 increased the enzyme production. Maximum yield of beta-galactosidase obtained was 3.8-4.2 nkat/ml. The optimum pH, optimum temperature and molecular weight of the beta-glactosidase were 2.7, 60 degrees C and 2,21,000 daltons, respectively. The enzyme is an aryl beta-glactosidase and did not hydrolyse lactose. The Km value for o-nitrophenyl beta-D-galactoside was 3.7 mM. Galactose and 2-mercaptoethanol inhibited the enzyme.

Molecular biology of ß-lactam acylases.

ß-Lactam acylases such as penicillin G acylases, penicillin V acylases and glutaryl 7-aminocephalosporanic acid acylases are used in the manufacture of 6-aminopenicillanic acid, 7-aminodesacetoxycephalosporanic acid and 7-aminocephalosporanic acid (7-ACA). Genetically-engineered strains producing 1050 U/g, 3200 U/g and 7000 to 10,000 U/I of penicillin G acylase, penicillin V acylase and glutaryl-7-ACA acylase, respectively, have been developed. The penicillin G acylase studied to date and the glutaryl-7-ACA acylase from Pseudomonas sp. share some common features: the active enzyme molecules are composed of two dissimilar subunits that are generated from respective precursor polypeptide; the proteolytic processing is a post-translational modification which is regulated by temperature; and the Ser residue at the N-terminus of the ß-sub-unit (Ser(290); penicillin G acylase numbering) is implicated as the active site residue. Protein engineering, to generate penicillin G acylase molecules and their precursors with altered sequences, and the structure-function correlation of the engineered molecules are discussed.

Comparative evaluation of determination of beta-lactam intermediates.

The Schiff's base formation between 6-aminopenicillanic acid, 7-aminodesacetoxycephalosporanic acid and 7-aminocephalosporanic acid and p-dimethylaminobenzaldehyde (PDAB) was investigated. The factors that affect the reaction such as concentration of PDAB, time and pH were studied and optimised for estimation of these intermediates.

Cephalosporin acylases: enzyme production, structure and application in the production of 7-ACA.

Cephalosporin acylases have application in the production of 7-aminocephalosporanic acid which forms a key raw material for the preparation of semisynthetic injectable cephalosporins. The enzymes are of industrial importance and hyperproducing genetically engineered strains have been constructed. Different aspects of these enzymes such as subunit structure, post translational modification, primary structure, substrate specificity and their importance in pharmaceutical industry are discussed.

Biosynthesis of penicillin V acylase by Fusarium sp.: effect of culture conditions.

Penicillin V acylase was produced, both intracellularly and extracellularly, by Fusarium sp. SKF 235 grown in submerged fermentation. When neopeptone was added to the medium, >95% of the penicillin V acylase was extracellular. In the absence of a complex organic nitrogen source, the fungus produced low levels of totally intracellular penicillin V acylase. MgSO4 was essential for synthesis of the enzyme, which was induced by phenoxyacetic acid and penicillin V. The maximum yield of penicillin V acylase was 430 IU/g dry cell wt. The optimum pH value and temperature for the penicillin V acylase were 6.5 and 55°C, respectively.

Enzymatic splitting of penicillin V for the production of 6-APA using immobilized penicillin V acylase.

Penicillin V acylase from Fusarium sp. SKF 235 was immobilized on several cation-exchange resins, of which Amberlite CG-50 was preferred. Maximum activity of the immobilized penicillin V acylase was 250 to 280 IU/g dry beads. The pH and temperature optima of the enzyme shifted from 6.5 to 6.8 and 55°C to 60°C, respectively, as a result of immobilization. However, the K m for penicillin V remained at 10MM. Parameters for producing 6-aminopenicillanic acid were investigated and the immobilized penicillin V acylase was used for 68 cycles in a stirred tank reactor.

Production of carbohydrases by Sclerotium rolfsii.

Coproduction of alpha-amylase, beta-amylase, amyloglucosidase, cellulase, xylanase, pectinase and beta-galactosidase by Sclerotium rolfsii was studied on various polysaccharides. Starch induced alpha-amylase, beta-amylase, amyloglucosidase and beta galactosidase; cellulose induced cellulase, xylanase, pectinase and beta-galactosidase; and pectin induced pectinase and beta-galactosidase. None of the enzymes studied except beta-galactosidase were induced on xylan. Group controlled mechanism for production of carbohydrases by Sclerotium rolfsii is suggested.