Amplification Failure of the Amelogenin X Gene Caused by a Rare Mutation in the Primer-Binding Region.

The study of gender markers is essential in forensic genetic analysis. Mutations in the X or Y homologs of the amelogenin gene can be misleading, resulting in serious mistakes in forensic genetic analysis. We recently discovered two male cases of the X homolog of the amelogenin (AMELX) allelic dropout while analyzing short tandem repeat genotypes obtained from crime scene evidence. Subsequently, we evaluated the molecular characteristics of AMELX allelic dropout in this study. We used two previously reported amelogenin primers to verify a half level of amelogenin gene amplification intensity in the two male cases, which we confirmed was caused by AMELX allelic dropout. We then characterized the point mutation using Sanger sequencing and designed mutation-specific primers that could overcome AMELX allelic dropout. Short tandem repeat genotyping analysis confirmed that the AMELX allelic dropout was recovered by the mutation-specific primer designed specifically for this case. The sequencing of the AMELX allele revealed a single-point variant from A→G at base position 7 downstream from the 3' end in the amelogenin forward primer-binding region. This point mutation was identically found in two different male cases, resulting in AMELX allelic dropout. To our knowledge, these mutations and the X homolog amplification failure of amelogenin have not been reported in the Korean population. Our study provides a reliable approach to AMELX allelic dropout due to rare case mutations and could enable the better interpretation of gender markers for forensic samples.

Development of diagnostic SNP markers and a novel SNP genotyping assay for distinguishing opium poppies.

The opium poppy acts as an important natural pain reliever but is also responsible for increased rates of severe drug abuse and addiction owing to its characteristic psychoactive effect. Non-medical illicit use of the poppy plant is markedly increasing worldwide, thereby highlighting the need for a robust species identification strategy. In this study, we identified SNPs within the region of two universal DNA barcodes, matK (maturase K) and the trnL-trnF (tRNA-Leu [3'exon]-tRNA-Phe [exon] intergenic spacer, that are forensically applicable for distinguishing opium poppy species based on a genetic analysis of 164 samples of family Papaveraceae obtained from locations spanning Jeolla-do and Jeju Island, Republic of Korea. A comparative analysis of the DNA barcode sequences for two narcotic types of the Papaver species (Papaver somniferum, Papaver somniferum subs. setigerum) to eight non-narcotic species revealed three unique nucleotide substitution events. Newly identified SNPs were located at position 255 of matK and at positions 305 and 306 of trnL-trnF; the narcotic species contained C, A, and T, whereas non-narcotic species contained T, G, and C at these positions. Phylogenetic analysis demonstrated that newly identified SNPs, which we named PsMAT255 and PsLF305/306, could be used to clearly differentiate between the narcotic and non-narcotic types of Papaver species based on the patterns of nucleotide variation. These results indicate that the nucleotide differences between the narcotic and non-narcotic species may influence genetic markers. We, therefore, developed a novel SNP-based allelic genotyping assay using the RT-PCR system that can reliably differentiate the narcotic type of the Papaver species. In summary, our findings suggest that the newly identified species-specific SNPs of both matK and trnL-trnF can be used as identification markers of narcotic Papaver species. Furthermore, a newly developed TaqMan allelic discrimination assay may be used as a practically applicable diagnostic method to survey several illicit narcotic specimens carrying the type-specific SNP.

A new minisatellite VNTR marker, Pscp1, discovered for the identification of opium poppy.

Opium poppy, a member of the Papaveraceae family, is an ancient herbaceous plant and well-known medical resource in the pharmaceutical industry. However, opium poppies are grown worldwide for producing illicit drugs, significantly increasing the incidence of narcotic drug abuse. Since the narcotic poppy has not yet been genetically investigated, we characterized a novel variable number tandem repeat (VNTR) marker of forensically important poppy species based on the genetic analysis of 164 samples collected from two locations spanning the Jeolla province and Jeju island of South Korea. Comparing analysis of the chloroplast (cp) genome sequences for four representative species of Papaver (Papaver somniferum, Papaver somniferum subs. setigerum, Papaver orientale, and Papaver rhoeas) revealed a unique region with 1-3 repeats for 16 nucleotide motifs in the genome inverted repeat A (IRA, positions 128,651 to 128,698) region. For 16 nucleotide motifs, 3 repeats were found in P. somniferum, and 2 repeats were found in P. somniferum subs. setigerum. Therefore, 10 known and the 133 unknown, seized Papaver species were compared to determine whether the species could be identified via variations in the repeat units. The sizes of a novel VNTR ranged from 181 to 252 bp between the species. Phylogenetic analysis confirmed that a novel VNTR, which we named Pscp1, could clearly distinguish between the narcotic and non-narcotic types of Papaver species based on the patterns of sequence variation. Interestingly, we found that Pscp1 could also distinguish between P. somniferum and P. somniferum subs. setigerum. The regions of eight non-narcotic species displayed similar patterns and also differences were found due to the nucleotide substitution and deletion events. The structural differences of Pscp1 were observed within the two narcotic species or between the narcotic and non-narcotic species, suggesting that these variations may act as a genetic marker. We, therefore, developed a new Pscp1 PCR-capillary electrophoresis (CE) method that can reliably identify the narcotic type of Papaver species. Taken together, our findings suggest that the newly developed Pscp1 can be used as an identification marker of opium poppy, and establish that the Pscp1 genotyping method by PCR-CE is an effective primary screening tool that can also contribute to species discrimination in the field of forensic diagnosis and applications.

Construction of an in-house allelic ladder for Canine Genotypes™ Panel 2.1 Kit.

Dogs (Canis lupus familiaris) are among the most common companion animals in the Republic of Korea. Recently, there have been many criminal cases of dog cruelty, injury, and theft, among others. This has increased the importance of dog-related biological evidence at crime scenes. The National Forensic Service of the Republic of Korea conducts short tandem repeat (STR) analysis using the Thermo Scientific Canine Genotypes™ Panel 2.1 Kit (Canine Kit) to identify individual dogs through forensic analysis. The Canine Kit was developed as a forensic STR kit for the identification of individual dogs. However, an allelic ladder was neither developed nor included in the commercial kit, leaving an issue of accurate genotyping. Primer details for the 18 markers used in the Canine Kit are proprietary information, and thus, unavailable to end-users. In this study, an allelic ladder was constructed with 160 fragments by combining 158 fragments of STR alleles obtained by nested PCR and two fragments artificially obtained from the sex-determination marker. By including the new allelic ladder in analysis of samples amplified with the Canine Kit, the accuracy and reliability of data analysis were improved. Application of this allelic ladder would be helpful for interlaboratory data sharing and standardization of canine genotype databases.

A New Lineage of Cryptococcus gattii (VGV) Discovered in the Central Zambezian Miombo Woodlands.

We discovered a new lineage of the globally important fungal pathogen Cryptococcus gattii on the basis of analysis of six isolates collected from three locations spanning the Central Miombo Woodlands of Zambia, Africa. All isolates were from environments (middens and tree holes) that are associated with a small mammal, the African hyrax. Phylogenetic and population genetic analyses confirmed that these isolates form a distinct, deeply divergent lineage, which we name VGV. VGV comprises two subclades (A and B) that are capable of causing mild lung infection with negligible neurotropism in mice. Comparing the VGV genome to previously identified lineages of C. gattii revealed a unique suite of genes together with gene loss and inversion events. However, standard URA5 restriction fragment length polymorphism (RFLP) analysis could not distinguish between VGV and VGIV isolates. We therefore developed a new URA5 RFLP method that can reliably identify the newly described lineage. Our work highlights how sampling understudied ecological regions alongside genomic and functional characterization can broaden our understanding of the evolution and ecology of major global pathogens.IMPORTANCECryptococcus gattii is an environmental pathogen that causes severe systemic infection in immunocompetent individuals more often than in immunocompromised humans. Over the past 2 decades, researchers have shown that C. gattii falls within four genetically distinct major lineages. By combining field work from an understudied ecological region (the Central Miombo Woodlands of Zambia, Africa), genome sequencing and assemblies, phylogenetic and population genetic analyses, and phenotypic characterization (morphology, histopathological, drug-sensitivity, survival experiments), we discovered a hitherto unknown lineage, which we name VGV (variety gattii five). The discovery of a new lineage from an understudied ecological region has far-reaching implications for the study and understanding of fungal pathogens and diseases they cause.

Roles of Three Cryptococcus neoformans and Cryptococcus gattii Efflux Pump-Coding Genes in Response to Drug Treatment.

Cryptococcus neoformans and Cryptococcus gattii species complexes are the etiologic agents of cryptococcosis. We have deciphered the roles of three ABC transporters, Afr1, Afr2, and Mdr1, in the representative strains of the two species, C. neoformans H99 and C. gattii R265. Deletion of AFR1 in H99 and R265 drastically reduced the levels of resistance to three xenobiotics and three triazoles, suggesting that Afr1 is the major drug efflux pump in both strains. Fluconazole susceptibility was not affected when AFR2 or MDR1 was deleted in both strains. However, when these genes were deleted in combination with AFR1, a minor additive effect in susceptibility toward several drugs was observed. Deletion of all three genes in both strains caused further increases in susceptibility toward fluconazole and itraconazole, suggesting that Afr2 and Mdr1 augment Afr1 function in pumping these triazoles. Intracellular accumulation of Nile Red significantly increased in afr1Δ mutants of both strains, but rhodamine 6G accumulation increased only in the mdr1Δ mutant of H99. Thus, the three efflux pumps play different roles in the two strains when exposed to different azoles and xenobiotics. AFR1 and AFR2 expression was upregulated in H99 and R265 when treated with fluconazole. However, MDR1 expression was upregulated only in R265 under the same conditions. We screened a library of transcription factor mutants and identified several mutants that manifested either altered fluconazole sensitivity or an increase in the frequency of fluconazole heteroresistance. Gene expression analysis suggests that the three efflux pumps are regulated independently by different transcription factors in response to fluconazole exposure.

Rck1 promotes pseudohyphal growth via the activation of Ubp3 phosphorylation in Saccharomyces cerevisiae.

Previously, we reported that Rck1 up-regulates Ras2 and pseudohyphal growth of Saccharomyces cerevisiae. Here, we further investigate the involvement of Rck1 in the activation of pseudohyphal growth. Rck1 activated phosphorylation of the deubiquitinase Ubp3 through a direct protein interaction between Rck1 and Ubp3. The N-terminal Bre5 binding region of Ubp3 physically interacted with Rck1, and Ubp3 and Rck1 co-precipitated. Overexpression of UBP3 using a high-copy plasmid resulted in the upregulation of Ras2, and deletion of UBP3 blocked the upregulation of Ras2 by RCK1 overexpression. Treatment with the proteasome inhibitor MG132 resulted in accumulation of Ras2, indicating that Rck1 is involved in Ras2 degradation in a proteasome-dependent manner. Furthermore, deletion of UBP3 blocked the upregulation of FLO11, a flocculin required for pseudohyphal and invasive growth induced by RCK1 overexpression in S. cerevisiae. Taken together, these results demonstrate that Rck1 promotes S. cerevisiae pseudohyphal growth via the activation of Ubp3 phosphorylation.

Identification of high-affinity copper transporters in Aspergillus fumigatus.

We investigated the copper metabolism of Aspergillus fumigatus, which has not been characterized well. We cloned the putative copper transporters ctrA2 and ctrC from A. fumigatus and investigated the functions of these transporters in copper metabolism. Four putative copper transporters were identified in the A. fumigatus genome; ctrA2 and ctrC complemented CTR1 functionally and localized to the plasma membrane in Saccharomyces cerevisiae. ctrA2 and ctrC single-deletion mutants and a double-deletion mutant of ctrA2 and ctrC were constructed in A. fumigatus. The ctrA2 and ctrC double-deletion mutant exhibited a growth defect on Aspergillus minimal medium (AMM) supplemented with bathocuproine disulfonic acid (BCS) and was sensitive to H2O2. Furthermore, the deletion of ctrA2 and ctrC reduced superoxide dismutase (SOD) activity, laccase activity, and intracellular copper contents. The activities of the ctrA2 and ctrC genes were up-regulated by BCS treatment. In addition, the deletion of ctrA2 up-regulated ctrC and vice versa. ctrA2 and ctrC were localized to the A. fumigatus plasma membrane. Although ctrA2 and ctrC failed to affect the mouse survival rate, these genes affected conidial killing activity. Taken together, these results indicate that ctrA2 and ctrC may function as membrane transporters and that the involvement of these genes in pathogenicity merits further investigation.

The expression of PHO92 is regulated by Gcr1, and Pho92 is involved in glucose metabolism in Saccharomyces cerevisiae.

Ydr374c (Pho92) contains a YTH domain in its C-terminal region and is a human YTHDF2 homologue. Previously, we reported that Pho92 regulates phosphate metabolism by regulating PHO4 mRNA stability. In this study, we found that growth of the ∆pho92 strain on SG media was slower than that of the wild type and that PHO92 expression was up-regulated by non-fermentable carbon sources, such as ethanol and glycerol, but not by fermentable carbon sources. Furthermore, two conserved Gcr1-binding regions were identified in the upstream, untranslated region of PHO92. Gcr1 is an important factor involved in the coordinated regulation of glycolytic gene expression. Mutation of two Gcr1-binding sites of the PHO92 upstream region resulted in a growth defect on SD media. Finally, mutagenesis of the Gcr1-binding sites of the PHO92 upstream region and deletion of GCR1 resulted in up-regulation of PHO92, and this resulted from inhibition of PHO4 mRNA degradation. Based on these results, we suggest that Gcr1 regulates the expression of PHO92, and Pho92 is involved in glucose metabolism.

Rck1 up-regulates pseudohyphal growth by activating the Ras2 and MAP kinase pathways independently in Saccharomyces cerevisiae.

Previously, we reported that Rck1 regulates Hog1 and Slt2 activities and affects MAP kinase activity in Saccharomyces cerevisiae. Recently, we found that Rck1 up-regulates phospho-Kss1 and phospho-Fus3. Kss1 has been known as a component in the pseudohyphal growth pathway, and we attempted to identify the function of Rck1 in pseudohyphal growth. Rck1 up-regulated Ras2 at the protein level, not the transcriptional level. Additionally, FLO11 transcription was up-regulated by RCK1 over-expression. RCK1 expression was up-regulated during growth on SLAD+1% butanol medium. On nitrogen starvation agar plates, RCK1 over-expression induced pseudohyphal growth of colonies, and cells over-expressing RCK1 showed a filamentous morphology when grown in SLAD medium. Furthermore, 1-butanol greatly induced filamentous growth when RCK1 was over-expressed. Moreover, invasive growth was activated in haploid cells when RCK1 was over-expressed. The growth defect of cells observed on 1-butanol medium was recovered when RCK1 was over-expressed. Interestingly, Ras2 and phospho-Kss1 were up-regulated by Rck1 independently. Together, these results suggest that Rck1 promotes pseudohyphal growth by activating Ras2 and Kss1 via independent pathways in S. cerevisiae.

A novel protein, Pho92, has a conserved YTH domain and regulates phosphate metabolism by decreasing the mRNA stability of PHO4 in Saccharomyces cerevisiae.

The homologue of human YTHDF2, Ydr374c (Pho92), is the only protein that has a YTH (YT521-B homology) domain in Saccharomyces cerevisiae. Based on microarray analysis, genes involved in the phosphate signal transduction (PHO) pathway were up-regulated in the Δpho92 strain, as were genes regulated by Pho4, which is an important transcription factor in the PHO pathway. To identify the exact mechanism of Pho92 action with respect to phosphate metabolism, we investigated the effect of Pho92 on PHO4 expression. The half-life of PHO4 mRNA was increased in the Δpho92 strain; this phenotype was also observed in the deletion mutants UPF1 and POP2, which are components of the NMD (nonsense-mediated decay) pathway and the Pop2-Ccr4-Not deadenylase complex respectively. Pho92 interacts physically with Pop2 of the Pop2-Ccr4-Not deadenylase complex. Furthermore, Pho92 binding to the 3'-UTR of PHO4 was dependent on the phosphate concentration. Deletion of the PHO4 3'-UTR resulted in PHO4 mRNA resistance to Pho92-dependent degradation. The results of the present study indicate that Pho92 regulates Pho4 expression at the post-transcriptional level via the regulation of mRNA stability. Taken together, Pho92 participates in cellular phosphate metabolism, specifically via the regulation of PHO4 mRNA stability by binding to the 3'-UTR in a phosphate-dependent manner.

Rck1 up-regulates Hog1 activity by down-regulating Slt2 activity in Saccharomyces cerevisiae.

We previously reported that the over-expression of KDX1 up-regulates RCK1 gene expression. To further understand the function of Rck1, microarray analysis was performed using a RCK1 over-expressing strain. Based on microarray and Northern blot analyses, we determined that the expression of KDX1 was down-regulated when RCK1 was over-expressed. Furthermore, we determined that phosphorylated forms of Slt2 and Mkk2 were down-regulated by the over-expression of RCK1. Ptp2, a phosphatase that is regulated by the Slt2 MAP kinase pathway, was down-regulated by the over-expression of RCK1. Ptp2 is a negative regulator of Hog1; thus, the phosphorylated form of Hog1 was up-regulated by RCK1 over-expression. A point mutation of lysine 152 to arginine resulted in a failure to up-regulate Hog1 and the subsequent down-regulation of CTT1, which is a Hog1 pathway target gene. Furthermore, using microarray and Northern blot analyses, we determined that genes that are regulated by Msn2/Msn4 were up-regulated by Rck1 and that this was the result of Hog1 activation by RCK1 over-expression. Together, our results suggest that Rck1 inhibits Slt2 MAP kinase pathway activity and then Ptp2, which subsequently activates Hog1.

Kdx1 regulates RCK1 gene expression by interacting with Rlm1 in Saccharomyces cerevisiae.

Kdx1 is known as a stress-responsive protein. To better understand the function of Kdx1, we performed microarray analysis in KDX1 overexpressing cells and found that the overexpression of KDX1 dramatically induced the expression of RCK1, a stress-responsive gene. This result was confirmed by northern blot analysis. Furthermore, the overexpression of RCK1 partially rescued the growth defect caused by zymolyase stress. The expression of RCK1 was regulated independently by Slt2 and Hog1, and Kdx1 failed to induce the expression of RCK1 in a HOG1 deletion strain. The transcriptional factors Smp1, Sko1, Msn2, Msn4, and Hot1, which are regulated by Hog1, did not affect RCK1 expression, but Rlm1 did. Furthermore, the mutation of certain phosphorylation sites in RLM1 inhibited the induction of RCK1 expression by Kdx1. We found a conserved Rlm1 binding site in the 5' untranslated region (UTR) of RCK1, and the mutation of these Rlm1 binding sites also inhibited the induction of RCK1 expression by Kdx1. Finally, we showed that Kdx1 physically interacts with Rlm1 and that this interaction affects the ability of Rlm1 to bind to the RCK1 5' UTR. Taken together, these data suggest that Kdx1 interacts with Rlm1 to activate RCK1 gene expression in response to stress in Saccharomyces cerevisiae.

Cadmium inhibits the protein degradation of Sml1 by inhibiting the phosphorylation of Sml1 in Saccharomyces cerevisiae.

Cadmium is a toxic metal, and the mechanism of cadmium toxicity in living organisms has been well studied. Here, we used Saccharomyces cerevisiae as a model system to examine the detailed molecular mechanism of cell growth defects caused by cadmium. Using a plate assay of a yeast deletion mutant collection, we found that deletion of SML1, which encodes an inhibitor of Rnr1, resulted in cadmium resistance. Sml1 protein levels increased when cells were treated with cadmium, even though the mRNA levels of SML1 remained unchanged. Using northern and western blot analyses, we found that cadmium inhibited Sml1 degradation by inhibiting Sml1 phosphorylation. Sml1 protein levels increased when cells were treated with cadmium due to disruption of the dependent protein degradation pathway. Furthermore, cadmium promoted cell cycle progression into the G2 phase. The same result was obtained using cells in which SML1 was overexpressed. Deletion of SML1 delayed cell cycle progression. These results are consistent with Sml1 accumulation and with growth defects caused by cadmium stress. Interestingly, although cadmium treatment led to increase Sml1 levels, intracellular dNTP levels also increased because of Rnr3 upregulation due to cadmium stress. Taken together, these results suggest that cadmium specifically affects the phosphorylation of Sml1 and that Sml1 accumulates in cells.

Cd2+ binds to Atx1 and affects the physical interaction between Atx1 and Ccc2 in Saccharomyces cerevisiae.

The ATX1 deletion strain of Saccharomyces cerevisiae is more resistant to Cd(2+) than the wild-type. To investigate the function of Atx1 in Cd(2+) toxicity, we used a metal-binding assay to study the interaction between Atx1 and Cd(2+) in vitro. Using circular dichroism and two-hybrid analyses, we found that Atx1 can bind Cd(2+) specifically and that Cd(2+) binding to Atx1 affects the physical interaction between Atx1 and Ccc2. These results imply that Atx1 delivers Cd(2+) to Ccc2 and that this delivery is, at least in part, responsible for Cd(2+) toxicity in S. cerevisiae.

Cadmium regulates copper homoeostasis by inhibiting the activity of Mac1, a transcriptional activator of the copper regulon, in Saccharomyces cerevisiae.

Cadmium is a toxic metal and the mechanism of its toxicity has been studied in various model systems from bacteria to mammals. We employed Saccharomyces cerevisiae as a model system to study cadmium toxicity at the molecular level because it has been used to identify the molecular mechanisms of toxicity found in higher organisms. cDNA microarray and Northern blot analyses revealed that cadmium salts inhibited the expression of genes related to copper metabolism. Western blotting, Northern blotting and chromatin immunoprecipitation experiments indicated that CTR1 expression was inhibited at the transcriptional level through direct inhibition of the Mac1 transcriptional activator. The decreased expression of CTR1 results in cellular copper deficiency and inhibition of Fet3 activity, which eventually impairs iron uptake. In this way, cadmium exhibits a negative effect on both iron and copper homoeostasis.

FgEnd1 is a putative component of the endocytic machinery and mediates ferrichrome uptake in F. graminearum.

The function of endocytic pathway in filamentous fungi has remained elusive. Recently, we have identified that FgEnd1, which has a 27% amino acid homology and shares specific EH3 domain with ScEnd3 of Saccharomyces cerevisiae, is a putative member of the endocytic machinery in Fusarium graminearum. The failure of the scend3 mutant to uptake Lucifer yellow (LY) was recovered by introducing FgEnd1 into S. cerevisiae. The deletion of fgend1 in F. graminearum resulted in a 2-fold decrease in the rate of uptake of the endocytic marker FM4-64 when compared to wild-type cells. The rate of uptake was similar to that seen in latrunculin A (Lat-A)-treated cells. Furthermore, fgend1 deletion strain of F. graminearum showed lower ferrichrome (FC) uptake activity than wild-type F. graminearum, and the same rate as LatA-treated cells. Taken together, these results suggest that FgEnd1 is a putative member of the endocytic machinery, although it acts through a different mechanism from ScEnd3 or ScEnd4 of S. cerevisiae.

A novel function of Aft1 in regulating ferrioxamine B uptake: Aft1 modulates Arn3 ubiquitination in Saccharomyces cerevisiae.

Aft1 is a transcriptional activator in Saccharomyces cerevisiae that responds to iron availability and regulates the expression of genes in the iron regulon, such as FET3, FTR1 and the ARN family. Using a two-hybrid screen, we found that Aft1 physically interacts with the FOB (ferrioxamine B) transporter Arn3. This interaction modulates the ability of Arn3 to take up FOB. The interaction between Arn3 and Aft1 was confirmed by beta-galactosidase, co-immunoprecipitation and SPR (surface plasmon resonance) assays. Truncated Aft1 had a stronger interaction with Arn3 and caused a higher FOB-uptake activity than full-length Aft1. Interestingly, only full-length Aft1 induced the correct localization of Arn3 in response to FOB. Furthermore, we found Aft1 affected Arn3 ubiquitination. These results suggest that Aft1 interacts with Arn3 and may regulate the ubiquitination of Arn3 in the cytosolic compartment.