TaqMan-based real-time polymerase chain reaction for detection of FUT2 copy number variations: identification of novel Alu-mediated deletion

Impact of KIT Editing on Coat Pigmentation and Fresh Meat Color in Yorkshire Pigs

The white coat color of Yorkshire pigs is caused by the dominant white I allele, which has been associated with at least one copy of the 450-kb duplication encompassing the entire KIT gene and a splice mutation (G > A) at the first base of intron 17. The splice mutation in KIT has an adverse effect on pigmentation in mice. Therefore, removing the 450 kb duplications harboring the KIT copy with splice mutations is expected to affect Yorkshire pig pigmentation. In this study, we describe the use of a Yorkshire pig kidney cell strain with the I^?/I^Be-ed genotype, previously created by CRISPR-Cas9, as donor cells for somatic cell nuclear transfer to generate gene-edited Yorkshire pigs. The removal of the 450 kb duplications harboring the KIT copy with splice mutation did not alter the white coat color of Yorkshire pigs, which was confirmed by the absence of fully mature melanocytes and melanin accumulation in the hair follicles. Except for the improved transcription of tyrosinase, and slight increase in microphthalmia transcription factor and tyrosinase-related protein 1 protein expression, there was no significant impact of the removal of splice mutations on genes and signaling pathways (PI3K/AKT) involved in melanogenesis. However, the removal of the 450 kb duplications harboring the KIT copy with splice mutation substantially improved fresh meat color accompanied by significantly increased red blood cell number, which merits further investigation. Our study provides new insights into the role of structural mutations of the KIT gene in the formation of white coat color and erythropoiesis in Yorkshire pigs.

ABO, secretor, and Lewis carbohydrate histo-blood groups are associated with autoimmune neutropenia of early childhood in Danish patients

Background

Autoimmune neutropenia of early childhood (AIN) is caused by autoantibodies directed against antigens on the neutrophil membrane. The ABO, secretor, and Lewis histo‐blood group systems control the expression of carbohydrate antigens and have previously been linked to autoimmune diseases. We aimed to investigate the association between genotypes and the risk of AIN in Danish patients.

Study Design and Methods

One hundred fifty‐four antibody‐positive AIN patients were included. Controls (n = 400) were healthy unrelated Danish blood donors. Molecular determination of ABO, secretor (FUT2), and Lewis (FUT3) genotypes were determined using real‐time polymerase chain reaction (qPCR) or Sanger sequencing to infer the prevalence of Lewis antigens (Le^a and Le^b) and secretor (SeSe or Sese) or nonsecretor (sese) phenotypes.

Results

Blood type O was more common in controls (46.8%) than in AIN patients (36.4%) (OR = 0.65; p = 0.028). Secretors of H Le^b antigens were less frequent among AIN patients (25.2%) than controls (35.0%) (OR = 0.62; p = 0.037).

Discussion

ABO blood group antigens and the secretion of these antigens are associated with a diagnosis of AIN. The mechanism underlying the association between autoimmunity and interaction among ABO, secretor, and Lewis genotypes has not yet been elucidated, but several studies indicate a connection to the gut microbiota.

Real-time PCR-based detection of the Alu-mediated deletion of FUT2 (sedel2)

Secretor status of the ABH(O) histoblood group antigens is regulated by secretor type α(1,2)fucosyltransferase encoded by FUT2. The se^del2 allele is a complete deletion of the FUT2 coding region generated by Alu-mediated homologous recombination. This deletion seems to be exclusively encountered in certain Oceanian populations. From the perspective of forensic science, se^del2 is considered to be one of ancestry informative markers for these populations. Real-time PCR followed by melting curve analysis was employed to find primer set to specifically amplify se^del2. We designed primers which produced a 231-bp amplicon specific to se^del2. The specificity of these primers was also confirmed by gel electrophoresis and sequencing of the PCR product. Then, two real-time PCR methods based on melting curve analysis and a hydrolysis probe were designed to determine se^del2 zygosity by adding FUT2-specific primers. These two methods were validated by analyzing 24 Samoan subjects. The results obtained from 24 Samoan subjects by the two methods were fully in accordance with those obtained by a previous conventional PCR method that amplified a 2.7-kb fragment of se^del2. Therefore, these two methods seemed to accurately determine the zygosity of se^del2 and were useful for investigation of the distribution and origin of this deletion.

Rapid detection of phenotypes Bombay sedel and nonsecretor rs200157007 SNP (302C > T) by real-time PCR-based methods

The sedel allele is one of the nonsecretor alleles (se) of FUT2 generated by an Alu-mediated recombination event and was first found in Indian Bombay phenotype individuals who have anti-H, anti-A, and anti-B antibodies in their serum. As well as anti-A, and anti-B antibodies, anti-H is clinically significant because it causes sever hemolytic transfusion reactions. Like sedel, se302 having a missense single nucleotide polymorphism (SNP), 302C > T, is characteristic of South Asians with a frequency of 10-30%. We developed a real-time PCR melting curve analysis for detection of sedel using a 127-bp amplicon encompassing the breakpoint junction. In addition, by performing duplex PCR by amplifying a 65-bp amplicon of the FUT2 coding region at the same time, we could determine the zygosity of sedel in a single tube. We also developed an Eprobe-mediated PCR assay (Eprobe-PCR) for detection of 302C > T of FUT2. These methods were validated by analyzing 58 Tamils and 54 Sinhalese in Sri Lanka. Both the duplex PCR melting curve analysis for determination of sedel zygosity and the Eprobe-PCR assay for detection of 302C > T exactly determined three genotypes. In addition, the results of the present methods were in complete agreement with those obtained by previously established methods. The two present methods were reliable and seem to be advantageous for large-scale association studies of FUT2 polymorphisms in South Asian populations.

High-resolution melting analysis for detection of fusion allele of FUT2

The secretor status of ABH antigens, determined by FUT2 polymorphisms, affects susceptibility to various infectious diseases. In addition to many SNPs responsible for the nonsecretor phenotype, five nonfunctional alleles (se) resulting from copy number variations have been reported. One of the five alleles generated by an unequal crossover between FUT2 and a pseudogene (SEC1), is sefus . This allele may be misidentified as a functional allele if only common inactivating SNPs are genotyped because it contains the 3' region of the functional FUT2. Therefore, accurate detection of sefus is desirable. For this purpose, a high-resolution melting (HRM) analysis is developed for detection of sefus in which a 284bp fragment of SEC1 and sefus but not FUT2, are amplified. This HRM analysis detected sefus reliably. Thus, an initial screening or prescreening for sefus using HRM analysis seems to be useful for association studies of FUT2.

FUT2 polymorphism in Latin American populations

BACKGROUND

The secretor type α(1,2)fucosyltransferase gene (FUT2) is known to be rich in population-specific polymorphisms. However, genetic variations of FUT2 have not been well examined in Latin American populations in which nonsecretors are rare.

METHODS

Conventional polymerase chain reactions and direct sequencing were performed to detect single nucleotide polymorphisms (SNPs) and copy number variations (CNVs) of FUT2 in Mexicans including Americans of Mexican ancestry, Puerto Ricans, Caribbeans, and Colombians. FUT2 alleles were determined by cloning into plasmids or PHASE software. The impact of uncharacterized missense SNPs on the enzyme activity were examined by transient transfection assays and estimated by several software programs.

RESULTS

Three alleles, Se357, Se, and se428, were common, and the frequency of nonsecretors was relatively low in the studied populations. We also encountered several alleles specific to Africans, Europeans, and South and East Asians including a South Asian-specific sedel. In contrast to the in silico prediction, a transient expression study suggested that both of two missense SNPs, 235G > A and 304G > A, did not impair the enzyme activity.

CONCLUSIONS

The allelic polymorphism of FUT2 suggests that the modern Latin American populations were formed via genetic admixture among Native Americans and populations whose ancestors migrated from other continents. In this study, we have observed a discrepancy between in silico and functional analyses for FUT2 for the first time. Therefore, experimental functional analysis is required for evaluation of SNPs of FUT2.

Cyclophilin a knokdown inhibits cell migration and invasion through the suppression of epithelial-mesenchymal transition in colorectal cancer cells

Enhanced expression of cyclophilin A (CypA) in colorectal cancer (CRC) was reported; however, how CypA influences CRC progression is not clear. Therefore, we examine the effects of CypA on CRC cell progression. Knockdown of CypA in SW480 cells significantly inhibited cell migration and invasion but had no effect on cell proliferation. In addition, upregulation of E-cadherin and downregulation of N-cadherin and Snail expression were observed by CypA knockdown. These results suggested that CypA knockdown inhibited cell migration and invasion by suppressing epithelial-mesenchymal transition. CypA knockdown was also associated with increased p38 phosphorylation, and the p38 inhibitor treatment led to increase in the number of invasive CypA-knockdown SW480 cells. Therefore, CypA may be a potential therapeutic target in preventing CRC metastasis.

Fucosyltransferase Gene Polymorphisms and Lewisb-Negative Status Are Frequent in Swedish Newborns, With Implications for Infectious Disease Susceptibility and Personalized Medicine

BACKGROUND

Single-nucleotide polymorphisms (SNPs) in the fucosyltransferase genes FUT2 and FUT3 have been associated with susceptibility to various infectious and inflammatory disorders. FUT variations influence the expression of human histo-blood group antigens (HBGAs) (H-type 1 and Lewis), which are highly expressed in the gut and play an important role in microbial attachment, metabolism, colonization, and shaping of the microbiome. In particular, FUT polymorphisms confer susceptibility to specific rotavirus and norovirus genotypes, which has important global health implications.

METHODS

We designed a genotyping method using a nested polymerase chain reaction approach to determine the frequency of SNPs in FUT2 and FUT3, thereby inferring the prevalence of Lewisb-positive, Lewisb-negative, secretor, and nonsecretor phenotypes in 520 Swedish newborns.

RESULTS

There was an increased frequency of homozygotes for the minor allele for 1 SNP in FUT2 and 4 SNPs in FUT3. Overall, 37.3% of newborns were found to have Lewis b negative phenotypes (Le (a+b-) or Le (a-b-). Using our new, sensitive genotyping method, we were able to genetically define the Le (a-b-) individuals based on their secretor status and found that the frequency of Lewis b negative newborns in our cohort was 28%.

CONCLUSIONS

Given the high frequency of fucosyltransferase polymorphisms observed in our newborn cohort and the implications for disease susceptibility, FUT genotyping might play a future role in personalized health care, including recommendations for disease screening, therapy, and vaccination.

Genetic variation of FUT2 in a Peruvian population: identification of a novel LTR-mediated deletion and characterization of 4 nonsynonymous single-nucleotide polymorphisms

BACKGROUND

The human FUT2 gene, which encodes a secretor type α(1,2)fucosyltransferase, is reported to have several population-specific single-nucleotide polymorphisms (SNPs) and copy number variations. However, little is known about genetic variation of FUT2 in Native Americans.

STUDY DESIGN AND METHODS

To detect SNPs and copy number variations of the FUT2 gene in Peruvians, direct sequencing and digital polymerase chain reaction were performed. Haplotypes of observed SNPs were estimated by PHASE software or cloning into plasmids. The functional significance of nonsynonymous SNPs was examined by transient transfection assay.

RESULTS

We identified three novel nonfunctional alleles (se178,357 , se841 , and sedel4 ) due to two nonsynonymous SNPs (178C > T and 841G > A) and a novel long terminal repeat-mediated recombination with a 4.3-kb deletion in 70 Peruvians. The frequency of nonfunctional alleles was relative low (20.7%). Because se841 has a relatively high frequency (5.7%), it might be a suitable genetic marker for Peruvians.

CONCLUSION

We identified three novel nonfunctional alleles in 70 Peruvians. To our knowledge, this is the first time a long terminal repeat-mediated gene recombination event at the FUT2 locus has been detected.

Highly efficient correction of structural mutations of 450 kb KIT locus in kidney cells of Yorkshire pig by CRISPR/Cas9

The white coat colour of Yorkshire and Landrace pig breeds is caused by the dominant white I allele of KIT, associated with 450-kb duplications and a splice mutation (G > A) at the first base in intron 17. To test whether genome editing can be employed to correct this structural mutation, and to investigate the role of KIT in the control of porcine coat colour, we designed sgRNAs targeting either intron 16 or intron 17 of KIT, and transfected Cas9/sgRNA co-expression plasmids into the kidney cells of Yorkshire pigs. The copy number of KIT was reduced by about 13%, suggesting the possibility of obtaining cells with corrected structural mutations of the KIT locus. Using single cell cloning, from 24 successfully expanded single cell clones derived from cells transfected with sgRNA targeting at intron 17, we obtained 3 clones with a single copy of KIT without the splice mutation. Taken together, the 12.5% (3/24) efficiency of correction of structural mutations of 450 kb fragments is highly efficient, providing a solid basis for the generation of genome edited Yorkshire pigs with a normal KIT locus. This provides an insight into the underlying genetic mechanisms of porcine coat colour.

Dark-colored maple syrup treatment induces S-phase cell cycle arrest via reduced proliferating cell nuclear antigen expression in colorectal cancer cells

Maple syrup is a natural sweetener that is consumed worldwide. It has been previously reported that dark-colored maple syrup exerts an inhibitory effect on colorectal cancer (CRC) proliferation and invasion. In the present study, the underlying mechanism of CRC cell growth inhibition was examined with dark-colored maple syrup treatment using a shotgun liquid chromatography-tandem mass spectrometry-based global proteomic approach. Applying a semi-quantitative method based on spectral counting, 388 proteins were identified with expression changes of >1.5-fold following dark-colored maple syrup treatment. Gene Ontology analysis revealed that these proteins possessed cell cycle-associated functions. It was also indicated that CRC cells treated with dark-colored maple syrup exhibited decreased proliferating cell nuclear antigen (PCNA) expression and S-phase cell cycle arrest. Dark-colored maple syrup treatment also resulted in altered expression of cell cycle-associated genes, including cyclin-dependent kinase (CDK)4 and CDK6. In conclusion, these data suggested that dark-colored maple syrup induced S-phase cell cycle arrest in CRC cells by reducing the expression of PCNA and regulating cell cycle-associated genes. These findings suggest that dark-colored maple syrup may be a source of compounds for the development of novel drugs for colorectal cancer treatment.

TaqMan real-time polymerase chain reaction for detection of SEC1-FUT2 hybrid alleles: identification of novel hybrid allele

BACKGROUND

Two hybrid alleles between the secretor type α(1,2)fucosyltransferase gene (FUT2) and a pseudogene of FUT2 (SEC1) have been reported so far; parts of the SEC1 and FUT2 sequences are suggested to be susceptible to recombination. The se(fus), one of the two hybrid alleles, is found in Japanese populations at relative high frequencies.

METHODS

A TaqMan assay to distinguish SEC1 and SEC1-FUT2 hybrid alleles was designed for the purpose of dealing with large number of samples.

RESULTS

The results of the present method were fully consistent with those of the previous method for detection of se(fus) in the Japanese population. In addition, a novel SEC1-FUT2-SEC1 hybrid allele, which contains a 35-bp sequence (between positions 418 and 452) that is identical to the FUT2 sequence including a 13-bp FUT2-specific region (between positions 436 and 448), was encountered in an individual of European descent.

CONCLUSIONS

The present TaqMan assay is a reliable and powerful method for the large scale association study between disease susceptibility and FUT2 genotypes especially in the Japanese populations because of relative high frequency of se(fus). In addition, this method is a useful tool to find novel SEC1-FUT2 hybrid alleles.

Genetic variation of FUT2 in a Vietnamese population: identification of two novel Se enzyme-inactivating mutations

BACKGROUND

The human FUT2 gene encodes a secretor-type α(1,2)fucosyltransferase, and many population-specific polymorphisms have been reported in the coding region.

STUDY DESIGN AND METHODS

Direct sequencing, real-time polymerase chain reaction, and high-resolution melt (HRM) analysis were done to detect single-nucleotide polymorphism (SNPs) and copy number variations (CNVs) in a Vietnamese population. The impacts of two novel mutations on the encoded enzyme were examined by a transient expression study.

RESULTS

The major nonfunctional allele in the 294 Vietnamese was se(357,385), whereas no CNV was detected. Two novel SNPs, 818C>A (Thr273Asn) and 853G>A (Ala285Thr), distributed at low frequency, were shown to remarkably affect the enzyme activity.

CONCLUSION

The allelic polymorphism of FUT2 in Vietnamese is similar to that of other East and Southeast Asian populations. This result may reflect the history and gene flow of this population. In addition, HRM analysis seems to be a simple and effective method for screening rare SNPs of FUT2 in a large number of samples. [Correction statement added after online publication 21-Dec-2011: Thr273Ala has been updated to Thr273Asn throughout.]