PowerPlex® Fusion kit: A 23 plex autosomal STR kit for human identity testing

PowerPlex® Fusion kit: A 23 plex autosomal STR kit for human identity testing

Forensic Science International: Genetics Supplement Series 4 (2013) e344–e345 Contents lists available at ScienceDirect Forensic Science Internation...

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Forensic Science International: Genetics Supplement Series 4 (2013) e344–e345

Contents lists available at ScienceDirect

Forensic Science International: Genetics Supplement Series journal homepage: www.elsevier.com/locate/FSIGSS

PowerPlex1 Fusion kit: A 23 plex autosomal STR kit for human identity testing A. Verzeletti a,*, V. Cortellini a, N. Cerri a, A. Bosetti b, S. Pretto a, F. De Ferrari a a b

Department of Forensic Medicine, University of Brescia, Brescia, Italy Promega Italia Srl, Milano, Italy

A R T I C L E I N F O

A B S T R A C T

Article history: Received 19 August 2013 Received in revised form 4 October 2013 Accepted 5 October 2013

In case of deficient paternity or maternity investigations with short tandem repeat (STR) analysis, sometimes common STRs cannot provide good results. Thus, it is recommended that additional STRs are used to complement conventional analysis for more reliable forensic information. We analyzed variation of 22 STRs contained in the new PowerPlex1 Fusion kit (Promega) in 52 unrelated individuals, living in Northern Italy, involved in paternity testing casework, to contribute to create an Italian database. ß 2013 Elsevier Ireland Ltd. All rights reserved.

Keywords: STR, PowerPlex1 Fusion kit, Database

information [1]. The PowerPlex1 Fusion System (Promega) is a 24-locus multiplex for human identification applications including forensic analysis, relationship testing and research use, which allows co-amplification of the 13 core CODIS loci, the 12 core ESS loci and Amelogenin. In addition, the male-specific DYS391 locus, Penta D, Penta E, D2S1338 and D19S433 loci are included. This extended panel of STR markers is intended to satisfy both CODIS

1. Introduction In case of paternity or maternity investigations with STR analysis, deficient cases, missing persons, or mutations are encountered and sometimes common STRs cannot provide good results. Thus, it is recommended that additional STR are used to complement conventional analysis for more reliable forensic Table 1 Allele frequencies and forensic parameters in a population sample from Brescia. Alleli 5 6 7 8 9 9.3 10 11 11.3 12 13 14 14.2 15 15.2 15.3 16 16.2 16.3 17 17.3 18 18.3 19 19.3 20 20.3 21 21.2 22 23 23.2 24 25

D3S1358

D1S1656

D2S441

D10S1248

D13S317

PENTA E

D16S539

D18S51

D2S1338

CSF1P0

PENTA D

0.0385

0.0385 0.1538

0.0481 0.202 0.1154 0.0962

0.0192

0.0192 0.0577

0.0288

0.0288 0.2692

0.1058 0.0865

0.0577 0.375

0.0096

0.2692 0.2885

0.0962 0.1538

0.0385 0.2692 0.3558

0.2981 0.1346 0.0577

0.1731 0.1058 0.0769

0.3077 0.1635 0.0192

0.1731 0.1827 0.1731

0.2788 0.1058 0.0192

0.1538 0.2597 0.0769

0.0769

0.0962 0.0865 0.0962

0.1827 0.327 0.0481 0.0288 0.0673 0.3077

0.2404

0.1923

0.0288

0.1634

0.0192

0.1442

0.25

0.0577 0.1346

0.0096

0.0962

0.0865

0.0962

0.0769

0.0481

0.0096

0.0673

0.25

0.0385

0.0577

0.0577

0.0288

0.0577

0.1154

0.0096

0.1154

0.0288

0.0288

0.0769

0.3077 0.1058

0.0865 0.0385 0.1058 0.0096 0.0192

0.0192

* Corresponding author at: Piazzale Spedali Civili 1, 25123 Brescia, Italy. Tel.: +39 033995480; fax: +39 030 3995839. E-mail address: [email protected] (A. Verzeletti). 1875-1768/$ – see front matter ß 2013 Elsevier Ireland Ltd. All rights reserved. http://dx.doi.org/10.1016/j.fsigss.2013.10.175

0.0673

0.0192 0.1731 0.0962 0.0673

A. Verzeletti et al. / Forensic Science International: Genetics Supplement Series 4 (2013) e344–e345

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Table 1 (Continued ) Alleli

D3S1358

D1S1656

D2S441

D10S1248

D13S317

PENTA E

D16S539

D18S51

D2S1338

CSF1P0

PENTA D

PIC PE PD PI Hoss Hatt Estd HWE

0.7299 0.5485 0.8783 0.1217 0.8462 0.775 5.8575  10 0.1921

0.8789 0.7761 0.9564 4.3650  10 0.9615 0.8977 0.0435 0.3989

0.7186 0.5394 0.875 0.125 0.8462 0.7422 0.0595 0.0681

0.725 0.5486 0.8735 0.1265 0.8269 0.7677 5.9195  10 0.023

0.7651 0.6013 0.9223 0.0776 0.8462 0.8015 5.6102  10 0.7735

0.8692 0.672 0.9608 3.9221  10 0.9039 0.8891 4.4981  10 0.6871

0.6874 0.5007 0.8372 0.1628 0.8654 0.7388 6.1525  10 0.0941

0.8495 0.6436 0.9556 4.4429  10 0.9039 0.8729 4.7471  10 0.969

0.8414 0.7162 0.9504 4.9589  10 0.9039 0.8643 4.8592  10 0.6431

0.7111 0.5225 0.8957 0.1043 0.75 0.76 5.9763  10 0.9923

0.8213 0.6828 0.9386 6.1432  10 0.8654 0.8486 5.0786  10 0.3669

Alleli

TH01

D21S11

D7S820

D5S818

TPOX

D8S1179

0.0288 0.1731 0.1346

0.0096

0.0096 0.5865 0.0673

0.0096 0.0288

0.25 0.2309

0.0385 0.3654

0.0769 0.2309

0.0673 0.0577

0.1634 0.0192

0.3654 0.2115 0.0096

0.0288

0.1058 0.4231 0.1731

5 6 7 8 9 9.3 10 11 11.3 12 13 14 14.2 15 15.2 15.3 16 16.2 16.3 17 17.3 18 18.3 19 19.3 20 20.3 21 21.2 22 23 23.2 24 25 26 27 28 29 30 30.2 31 31.2 32.2 33.2 PIC PE PD PI Hoss Hatt Estd HWE

2

2

vWA

0.2885 0.1058 0.1635 0.0865 0.3461 0.0096

2

0.0865

2

2

2

2

2

2

D12S391

0.1731

0.0962

0.0673

0.2597

0.0288

0.0385

0.3173

0.0096

0.0865

0.1442

2

2

D19S433

FGA

0.0096

0.125

0.1154 0.2404 0.2692 0.0192 0.1828 0.0865

0.0096

0.0481 0.0192

0.2981

0.0577 0.4327

0.0673

0.0865

0.1346 0.0096 0.1827 0.2404 0.0096 0.1154 0.0577 0.0385 0.0096

0.0577 0.0673 0.125 0.2597 0.2597 0.0192 0.0096 0.0769 0.1634 0.0192

2

0.7382 0.5605 0.8942 0.1058 0.8077 0.7944 5.8049  10 0.0059

2

0.7861 0.6306 0.9114 8.8545  10 0.8846 0.8295 5.4236  10 0.0013

2

2

0.7801 0.6173 0.9305 6.9535  10 0.7885 0.8161 5.4598  10 0.9481

2

2

0.626 0.4194 0.8394 0.1605 0.6346 0.6932 0.0643 0.4215

0.5455 0.3592 0.7667 0.233 0.5385 0.6004 6.8171  10 0.0703

2

0.7369 0.576 0.8979 0.1021 0.7115 0.7683 5.9152  10 0.1509

2

0.8776 0.7743 0.9557 4.4337  10 0.9039 0.8966 4.3747  10 0.0997

0.0096

0.1154

0.125 0.0865

0.7119 0.5276 0.8817 0.1183 0.8077 0.7588 5.9929  10 0.5114

2

D22S1045

0.0192

0.1924 0.0192 0.0673 0.0096 0.1442 0.0096 0.0962

0.0096

2

2

2

2

0.7867 0.6316 0.9378 6.2154  10 0.7692 0.82 5.4170  10 0.5069

2

2

0.8347 0.7042 0.9519 4.8111  10 0.8846 0.8602 4.9311  10 0.976

2

2

0.6536 0.4634 0.8239 0.1761 0.7885 0.7071 0.0635 0.18

Hobs, observed heterozygosity; Hexp, expected heterozygosity; SE, standard error; PIC, polymorphism information content; PD, power of discrimination; PE, power of exclusion; PI, power of inclusion; HWE, p-value from exact test for Hardy-Weinberg equilibrium.

and ESS recommendations [2]. In this study we analyzed variation of 22 autosomal STRs contained in the new PowerPlex1 Fusion kit to contribute to create an Italian database. Allele frequencies and forensic parameters were used to evaluate suitability and robustness of the new kit for forensic genetic analysis as well as in concordance studies with other kit (AmpFlTR 1IdentifilerTM and NGMTM). Data regarding the allelic frequencies for STRs in these populations would be highly welcomed to be used in forensic genetics for identification and paternity testing. 2. Materials and methods The study was conducted on a sample of 52 unrelated, living in Northern Italy. DNA was extracted from buccal swabs or blood using Chelex1 100 procedure. PCR amplifications were performed in a GeneAmp1 PCR System 9700 Gold Plate using the commercial kit PowerPlex Fusion. Typing was performed by capillary electrophoresis on a ABI Prism1 310 Genetic Analyzer; allele calling was performed with the software GeneMapperID V3.2.

Bonferroni correction for multiple testing (p  0.002). Larger samples sizes are necessary to understand the cause of deviation from equilibrium model at the locus surveyed. There are two explanations for these so-called ‘‘spurious’’ associations: the excess of homozygotes observed in the three markers, due to population substructure and high inbreeding due to widespread endogamy. Designed to meet CODIS and European standards, the PowerPlex1 Fusion System kit enables laboratories to: achieve the most inter database compatibility and highest discrimination of any autosomal STR kit; obtain a higher success rate with difficult casework samples due to robustness and sensitivity; simplify validation and QC efforts by using one kit for both casework and databasing sections. Role of funding None. Conflict of interest None.

3. Results and discussion References Allele frequencies and statistical parameters of forensic importance were estimated; ARLEQUIN software Ver. 3.11 was used to assess departures Hardy-Weinberg equilibrium (Table 1). Deviation has been detected for D21S11 (p = 0.0013) locus, even after a

[1] J.M. Butler, C.R. Hill, Biology and genetics of new autosomal STR loci useful for forensic DNA analysis, Forensic Sci. Rev. 24 (1) (2012) 5–26. [2] S.H. Katsanis, J.K. Wagner, Characterization of the standard and recommended CODIS markers, J. Forensic Sci. 58 (Suppl. 1) (2013) S169–S172.