Application and Prospect of RNA Profiling Analysis in Forensic Body Fluid Identification.

In forensic physical evidence identification, the accurate identification of the individual origin and their body fluid composition of the biological samples obtained from the crime scene play a critical role in determining the nature of a crime. In recent years, RNA profiling has become one of the fastest developing methods for body fluids identification. Due to the characteristics of tissue or body fluid specific expression, various types of RNA markers have been proven to be promising candidate markers for body fluids identification in previous studies. This review summarizes the research progress of RNA markers in body fluids identification, including the RNA markers that have been effectively verified in current research and their advantages and disadvantages. Meanwhile, this review prospects the application of RNA markers in forensic medicine.

PCR-RFLP for Detection of Fusarium graminearum Genotypes with Resistance to Phenamacril.

Phenamacril is a cyanoacrylate fungicide that provides excellent control of Fusarium head blight (FHB) or wheat scab, which is caused predominantly by Fusarium graminearum and F. asiaticum. Previous studies revealed that codon mutations of the myosin-5 gene of Fusarium spp. conferred resistance to phenamacril in in vitro lab experiments. In this study, PCR restriction fragment length polymorphism (RFLP) was developed to detect three common mutations (A135T, GCC to ACC at codon 135; S217L, TCA to TTA at codon 217; and E420K, GAA to AAA at codon 420) in F. graminearum induced by fungicide domestication in vitro. PCR products of 841 bp (for mutation of A135T), 802 bp (for mutation of S217L), or 1,649 bp (for mutation of E420K) in the myosin-5 gene were amplified by appropriate primer pairs. Restriction enzyme KpnI, TasI, or DraI was used to distinguish phenamacril-sensitive and -resistant strains with mutation genotypes of A135T, S217L, and E420K, respectively. KpnI digested the 841-bp PCR products of phenamacril-resistant strains with codon mutation A135T into two fragments of 256 and 585 bp. In contrast, KpnI did not digest the PCR products of sensitive strains. TasI digested the 802-bp PCR products of phenamacril-resistant strains with codon mutation S217L into three fragments of 461, 287, and 54 bp. In contrast, TasI digestion of the 802-bp PCR products of phenamacril-sensitive strains resulted in only two fragments of 515 and 287 bp. DraI digested the 1,649-bp PCR products of phenamacril-resistant strains with codon mutation E420K into two fragments of 932 and 717 bp, while the PCR products of phenamacril-sensitive strains was not digested. The three genotypes of resistance mutations were determined by analyzing electrophoresis patterns of the digestion fragments of PCR products. The PCR-RFLP method was evaluated on 48 phenamacril-resistant strains induced by fungicide domestication in vitro and compared with the conventional method (mycelial growth on fungicide-amended agar). The accuracy of the PCR-RFLP method for detecting the three mutation genotypes of F. graminearum resistant to phenamacril was 95.12% compared with conventional method. Bioinformatics analysis revealed that the PCR-RFLP method could also be used to detect the codon mutations of A135T and E420K in F. asiaticum.

Characterization of tissue-specific biomarkers with the expression of circRNAs in forensically relevant body fluids.

Messenger RNA (mRNA) markers have been extensively investigated for the identification of forensically relevant body fluids and tissues based on their expression profiles among cell types. As products of the backsplicing of pre-mRNAs, circular RNAs (circRNAs) share exonic sequences with their linear counterparts. The inclusion of circRNAs in mRNA profiling is shown to facilitate the detection of biomarkers in the identification of body fluids. In this study, we identified the expression of circRNAs of 14 out of 45 biomarkers from five body fluid types using outward-facing primer sets and revealed the ratio of circular to total transcripts of biomarkers by RNase R treatment. Furthermore, our results of qPCR analysis show that the inclusion of circRNAs in the detection of biomarkers, including HBA and ALAS2 for blood; MMP7 and MMP10 for menstrual blood; HTN3 for saliva; SPINK5, SERPINB3, ESR1, and CYP2B7P1 for vaginal secretions; TGM4, KLK3, and PRM2 for semen; and SLC22A6 and MIOX for urine, does not impair the specificity of these biomarkers. Additionally, a high copy number of targets from linear transcripts could be employed to increase the detection sensitivity of TGM4 and KLK3 with a low expression level of circRNAs in urine samples. Altogether, these results will help with the development of robust multiplex assays for body fluid identification.

Regulatory roles of introns in fungicide sensitivity of Fusarium graminearum.

Although the roles of introns have been much debated in eukaryotic organisms, none of them have been functionally characterized in Fusarium graminearum. In this study, we characterized the roles of introns in regulation of fungicide-sensitivity of F. graminearum. ß2 tub, cyp51A and myosin-5 are important target genes of benzimidazoles, triazoles and cyanoacrylates respectively. To explore the sensitivity regulation functions of introns in target genes, several detailed deletion studies were completed on the intronic regions of ß2 tub, cyp51A and myosin-5. Phenotypic analyses showed that deletion of the fourth intron from ß2 tub gene (designated ß2 Δi4), the sole intron from cyp51A gene (cyp51A-Δi) and the second intron from myosin-5 gene (myo5-Δi2) exhibited an increased sensitivity to corresponding fungicides. In contrast, deletion of the first or second intron from ß2 tub gene exhibited a decreased sensitivity to carbendazim. qRT-PCR showed that the mRNA transcript levels of target genes were significantly downregulated in ß2 Δi4, cyp51A-Δi and myo5-Δi2 respectively. Meanwhile, Western blot assays revealed that the protein expression levels of ß2 tub was also dramatically reduced in ß2 Δi4, but accumulated in ß2 Δi1 and ß2 Δi2. Overall, our results indicate that introns in target genes significantly regulate the fungicide-sensitivity by influencing expression of the corresponding resident genes in F. graminearum.

The plasma membrane H+ -ATPase FgPMA1 regulates the development, pathogenicity, and phenamacril sensitivity of Fusarium graminearum by interacting with FgMyo-5 and FgBmh2.

Fusarium graminearum, as the causal agent of Fusarium head blight (FHB), not only causes yield loss, but also contaminates the quality of wheat by producing mycotoxins, such as deoxynivalenol (DON). The plasma membrane H+ -ATPases play important roles in many growth stages in plants and yeasts, but their functions and regulation in phytopathogenic fungi remain largely unknown. Here we characterized two plasma membrane H+ -ATPases: FgPMA1 and FgPMA2 in F. graminearum. The FgPMA1 deletion mutant (∆FgPMA1), but not FgPMA2 deletion mutant (∆FgPMA2), was impaired in vegetative growth, pathogenicity, and sexual and asexual development. FgPMA1 was localized to the plasma membrane, and ∆FgPMA1 displayed reduced integrity of plasma membrane. ∆FgPMA1 not only impaired the formation of the toxisome, which is a compartment where DON is produced, but also suppressed the expression level of DON biosynthetic enzymes, decreased DON production, and decreased the amount of mycelial invasion, leading to impaired pathogenicity by exclusively developing disease on inoculation sites of wheat ears and coleoptiles. ∆FgPMA1 exhibited decreased sensitivity to some osmotic stresses, a cell wall-damaging agent (Congo red), a cell membrane-damaging agent (sodium dodecyl sulphate), and heat shock stress. FgMyo-5 is the target of phenamacril used for controlling FHB. We found FgPMA1 interacted with FgMyo-5, and ∆FgPMA1 showed an increased expression level of FgMyo-5, resulting in increased sensitivity to phenamacril, but not to other fungicides. Furthermore, co-immunoprecipitation confirmed that FgPMA1, FgMyo-5, and FgBmh2 (a 14-3-3 protein) form a complex to regulate the sensitivity to phenamacril and biological functions. Collectively, this study identified a novel regulating mechanism of FgPMA1 in pathogenicity and phenamacril sensitivity of F. graminearum.

A collaborative exercise on DNA methylation-based age prediction and body fluid typing.

DNA methylation has become one of the most useful biomarkers for age prediction and body fluid identification in the forensic field. Therefore, several assays have been developed to detect age-associated and body fluid-specific DNA methylation changes. Among the many methods developed, SNaPshot-based assays should be particularly useful in forensic laboratories, as they permit multiplex analysis and use the same capillary electrophoresis instrumentation as STR analysis. However, technical validation of any developed assays is crucial for their proper integration into routine forensic workflow. In the present collaborative exercise, two SNaPshot multiplex assays for age prediction and a SNaPshot multiplex for body fluid identification were tested in twelve laboratories. The experimental set-up of the exercise was designed to reflect the entire workflow of SNaPshot-based methylation analysis and involved four increasingly complex tasks designed to detect potential factors influencing methylation measurements. The results of body fluid identification from each laboratory provided sufficient information to determine appropriate age prediction methods in subsequent analysis. In age prediction, systematic measurement differences resulting from the type of genetic analyzer used were identified as the biggest cause of DNA methylation variation between laboratories. Also, the use of a buffer that ensures a high ratio of specific to non-specific primer binding resulted in changes in DNA methylation measurement, especially when using degenerate primers in the PCR reaction. In addition, high input volumes of bisulfite-converted DNA often caused PCR failure, presumably due to carry-over of PCR inhibitors from the bisulfite conversion reaction. The proficiency of the analysts and experimental conditions for efficient SNaPshot reactions were also important for consistent DNA methylation measurement. Several bisulfite conversion kits were used for this study, but differences resulting from the use of any specific kit were not clearly discerned. Even when different experimental settings were used in each laboratory, a positive outcome of the study was a mean absolute age prediction error amongst participant's data of only 2.7 years for semen, 5.0 years for blood and 3.8 years for saliva.

The potential use of Piwi-interacting RNA biomarkers in forensic body fluid identification: A proof-of-principle study.

In the forensic community, RNA profiling has been investigated as a potential method to identify body fluids. Several RNA molecules, including messenger RNA (mRNA), microRNA (miRNA) and circular RNA (circRNA), have been explored as biomarkers to distinguish different body fluids and have led to considerable interest in the development of RNA biomarkers for forensic purposes. Piwi-interacting RNA (piRNA), a class of noncoding RNAs, is a potential biomarker for body fluid identification because of its short length (˜24-32 nt) and specific expression pattern in human tissues. In this proof-of-principle study, we examined the expression levels of four carefully selected piRNAs in forensically relevant biological fluids (venous blood, saliva, semen, menstrual blood and vaginal secretions) using TaqMan quantitative real-time polymerase chain reaction (TaqMan qPCR). piR-55521, which was not detectable in saliva, can differentiate semen from other body fluids because it was strongly expressed in semen compared to the remaining three fluids (> 4000-fold change). Furthermore, piR-55521 could be detected in semen samples made from as little as 200 pg of total RNA, and addition of female component had no effect on the detection limit. Furthermore, the expression differences of other piRNAs, piR-61648, piR-43994 and piR-33151, were statistically significant between at least two types of body fluids. Stability tests also indicated that these piRNAs could be effectively detected in dried samples under laboratory and outdoor conditions for at least six months. Although limited to four piRNAs, this study suggests that the expression pattern of piRNAs could be used to identify body fluids, and that piRNA (piR-55521) is specifically expressed in semen. Such findings suggest that additional work could identify other piRNAs that could serve as biomarkers to identify body fluids.

Expression profile analysis of piwi-interacting RNA in forensically relevant biological fluids.

During the last decade, RNA profiling has emerged as one of the fastest developed methods for discriminating forensically relevant biological samples. As a category of small non-coding RNA, piwi-interacting RNA (piRNA) has recently been proposed to be differentially expressed in different types of body fluids, which indicates that its potential in forensic science is worth exploring. In this study, small RNA from 6 types of biological samples (venous blood, menstrual blood, saliva, semen, vaginal secretions and skin) was prepared and sequenced in order to characterize the expression pattern of piRNA using Ion S5 XL platform. Multiple bioinformatic methods were applied to make interpretation of the massively parallel sequencing data and identify representative biomarkers. A total of 376 piRNAs were initially identified after normalization and filtering. Hierarchical clustering and partial least squares-discriminant analysis (PLS-DA) revealed that their expression profiles exhibited an acceptable discriminating ability for most biological samples. Besides, a panel consists of 37 piRNA candidates was subsequently established for further analysis. The results suggested that with the optimal number of PLS components, the marker-reduced panel was sufficient to construct a PLS-DA model with the same performance as that can be achieved by the entire 376 piRNAs (classification error rate = 0.04). In addition, 5 targeted candidates were further selected for validation. TaqMan RT-qPCR assay results verified the potential of 3 piRNAs (piR-hsa-27622, piR-hsa-1207 and piR-hsa-27493) in distinguishing venous blood and menstrual blood, as well as 2 piRNA (piR-hsa-27493 and piR-hsa-26591) for the discrimination of saliva and vaginal secretions, which emphasized the feasibility of our biomarker selection approach. In brief, our study expanded the amount of potential piRNA biomarkers and demonstrated that the expression features of piRNA could provide valuable information for discriminating forensically relevant biological samples.

Resistance mechanism of Fusarium fujikuroi to phenamacril in the field.

BACKGROUND: Rice bakanae disease, mainly caused by Fusarium fujikuroi, is an important disease of rice. Phenamacril has been used to control the disease for a few years in China. In 2016, nine phenamacril-resistant strains were found in the field in Zhejiang Province. The aim of the study was to clarify the mechanism of resistance of F. fujikuroi to phenamacril and the fitness of resistant strains. RESULTS: The nine F. fujikuroi strains examined were highly resistant to phenamacril. Eight of them had the point mutation TCA (Ser) → CCA (Pro) at codon 219 in the Myosin-5 protein, while the other had the point mutation TCA (Ser) → TTA (Leu) at codon 219. Myosin-5 replacement between resistant and sensitive strains confirmed that the point mutation in Myosin-5 caused the resistance of F. fujikuroi to phenamacril. Docking of phenamacril into the modeled binding pocket of Myosin-5 showed that the affinity between phenamacril and Myosin-5 decreased and a hydrogen bond could not be formed between phenamacril and the amino acid at codon 219 after it changed to Pro or Leu. There was no cross-resistance between phenamacril and other fungicides. The eight resistant strains containing the point mutation S219P had almost the same fitness as the sensitive strains, while the one resistant strain containing the point mutation S219 L showed decreased mycelial growth, sporulation and pathogenicity. CONCLUSION: In the field, the point mutation S219P or S219 L in Myosin-5 conferred high resistance to phenamacril in F. fujikuroi. The point mutation S219P did not affect the fitness of F. fujikuroi, while the point mutation S219 L decreased its fitness. © 2017 Society of Chemical Industry.

Characterization of microRNA expression profiles in blood and saliva using the Ion Personal Genome Machine(®) System (Ion PGM™ System).

MicroRNA (miRNA) expression profiling is gaining interest in the forensic community because the intrinsically short fragment and tissue-specific expression pattern enable miRNAs as a useful biomarker for body fluid identification. Measuring the quantity of miRNAs in forensically relevant body fluids is an important step to screen specific miRNAs for body fluid identification. The recent introduction of massively parallel sequencing (MPS) has the potential for screening miRNA biomarkers at the genome-wide level, which allows both the detection of expression pattern and miRNA sequences. In this study, we employed the Ion Personal Genome Machine(®) System (Ion PGM™ System, Thermo Fisher) to characterize the distribution and expression of 2588 human mature miRNAs (miRBase v21) in 5 blood samples and 5 saliva samples. An average of 1,885,000 and 1,356,000 sequence reads were generated in blood and saliva respectively. Based on miRDong, a Perl-based tool developed for semi-automated miRNA distribution designations, and manually ascertained, 6 and 19 miRNAs were identified respectively as potentially blood and saliva-specific biomarkers. Herein, this study describes a complete and reliable miRNA workflow solution based on Ion PGM™ System, starting from efficient RNA extraction, followed by small RNA library construction and sequencing. With this workflow solution and miRDong analysis it will be possible to measure miRNA expression pattern at the genome-wide level in other forensically relevant body fluids.

Developed and evaluated a multiplex mRNA profiling system for body fluid identification in Chinese Han population.

In forensic casework, identification the cellular origin from a biological sample is crucial to the case investigation and reconstruction in crime scene. DNA/RNA co-extraction for STR typing and human body fluids identification has been proposed as an efficient and comprehensive assay for forensic analysis. Several cell-specific messenger RNA (mRNA) markers for identification of the body fluids have been proposed by previous studies. In this study, a novel multiplex mRNA profiling system included 19 markers was developed and performed by reverse transcription endpoint polymerase chain reaction (RT-PCR). The multiplex combined 3 housekeeping gene markers and 16 cell-specific markers that have been used to identify five types of human body fluids: peripheral blood, semen, saliva, vaginal secretions and menstrual blood. The specificity, sensitivity, stability and detectability of the mixture were explored in our study. Majority of the cell-specific mRNA markers showed high specificity, although cross-reactivity was observed sporadically. Specific profiling for per body fluid was obtained. Moreover, the interpretation guidelines for inference of body fluid types were performed according to the A. Lindenbergh et al. The scoring guidelines can be applied to any RNA multiplex, which was based on six different scoring categories (observed, observed and fits, sporadically observed and fits, not observed, sporadically observed, not reliable, and non-specific due to high input). The simultaneous extraction of DNA showed positive full or partial profiling results of all samples. It demonstrated that the approach of combined STR-profiling and RNA profiling was suitable and reliable to detect the donor and origin of human body fluids in Chinese Han population.

Identification of Saliva Using MicroRNA Biomarkers for Forensic Purpose.

In the forensic science community, microRNA (miRNA) profiling has started to be explored as an alternative tool for body fluid identification. Several origins of body fluid can be distinguished by measuring differential expression patterns of particular miRNAs. However, most of reported saliva miRNAs are nonoverlapping and debatable. The aim of this study was to develop a strategy of identifying saliva using miRNA biomarkers for forensic purpose. Eight miRNA candidates were selected to examine expression abundance in forensically relevant body fluids using hydrolysis probes quantitative real-time PCR (TaqMan qPCR). Results revealed that none of them was truly saliva specific, and only miR-200c-3p, miR-203a, and miR-205-5p were higher or more moderate expression in saliva. A stepwise strategy that combines each of three miRNAs with different body fluid-specific miRNAs was developed, and three miRNA combinations could effectively differentiate saliva from other body fluids.

A model for data analysis of microRNA expression in forensic body fluid identification.

MicroRNAs (miRNAs, 18-25 bases in length) are small, non-coding RNAs that regulate gene expression at the post-transcriptional level. MiRNA expression patterns, including presence and relative abundance of particular miRNA species, provide cell- and tissue-specific information that can be used for body fluid identification. Recently, two published studies reported that a number of body fluid-specific miRNAs had been identified. However, the results were inconsistent when different technology platforms and statistical methods were applied. To further study the role of miRNAs in identification of body fluids, this study sets out to develop an accurate and reliable model for data analysis of miRNA expression. To that end, the relative expression levels of three miRNAs were studied using the mirVana™ miRNA Isolation Kit, high-specificity stem-loop reverse transcription (RT) and high-sensitivity hydrolysis probes (TaqMan) quantitative real-time polymerase chain reaction (qPCR) in forensically relevant biological fluids, including venous blood, vaginal secretions, menstrual blood, semen and saliva. Accurate quantification of miRNAs requires not only a highly sensitive and specific detection platform for experiment operation, but also a reproducible methodology with an adequate model for data analysis. In our study, the efficiency-calibrated model that incorporated the impact of the quantification cycle (Cq) values and PCR efficiencies of target and reference genes was developed to calculate the relative expression ratio of miRNAs in forensically relevant body fluids. Our results showed that venous blood was distinguished from other body fluids according to the relative expression ratio of miR16 using as little as 50pg of total RNA, while the expression level of miR658 was unstable and that of miR205 was nonspecific among different body fluids. Collectively, the findings may constitute a basis for future miRNA-based research on body fluid identification and show miRNAs as a promising biomarker in forensic identification of body fluids.