Missense mutation of c.635 T > C in CAPN3 impairs muscle injury repair in a Limb-Girdel Muscular Dystropy Model.

Limb-girdle muscular dystrophy recessive 1 (LGMDR1), previously known as LGMD2A, is a specific LGMD caused by a gene mutation encoding the calcium-dependent neutral cysteine protease calpain-3 (CAPN3). In our study, the compound heterozygosity with two missense variants c.635 T > C (p.Leu212Pro) and c.2120A > G (p.Asp707Gly) was identified in patients with LGMDR1. However, the pathogenicity of c.635 T > C has not been investigated. To evaluate the effects of this novel likely pathogenic variant to the motor system, the mouse model with c.635 T > C variant was prepared by CRISPR/Cas9 gene editing technique. The pathological results revealed that a limited number of inflammatory cells infiltrated the endomyocytes of certain c.635 T > C homozygous mice at 10 months of age. Compared with wild-type mice, motor function was not significantly impaired in Capn3 c. 635 T > C homozygous mice. Western blot and immunofluorescence assays further indicated that the expression levels of the Capn3 protein in muscle tissues of homozygous mice were similar to those of wild-type mice. However, the arrangement and ultrastructural alterations of the mitochondria in the muscular tissues of homozygous mice were confirmed by electron microscopy. Subsequently, muscle regeneration of LGMDR1 was simulated using cardiotoxin (CTX) to induce muscle necrosis and regeneration to trigger the injury modification process. The repair of the homozygous mice was significantly worse than that of the control mice at day 15 and day 21 following treatment, the c.635 T > C variant of Capn3 exhibited a significant effect on muscle regeneration of homozygous mice and induced mitochondrial damage. RNA-sequencing results demonstrated that the expression levels of the mitochondrial-related functional genes were significantly downregulated in the mutant mice. Taken together, the results of the present study strongly suggested that the LGMDR1 mouse model with a novel c.635 T > C variant in the Capn3 gene was significantly dysfunctional in muscle injury repair via impairment of the mitochondrial function.

Loss of Protein Function Causing Severe Phenotypes of Female-Restricted Wieacker Wolff Syndrome due to a Novel Nonsense Mutation in the ZC4H2 Gene.

Pathogenic variants of zinc finger C4H2-type containing (ZC4H2) on the X chromosome cause a group of genetic diseases termed ZC4H2-associated rare disorders (ZARD), including Wieacker-Wolff Syndrome (WRWF) and Female-restricted Wieacker-Wolff Syndrome (WRWFFR). In the current study, a de novo c.352C>T (p.Gln118*) mutation in ZC4H2 (NM_018684.4) was identified in a female neonate born with severe arthrogryposis multiplex congenita (AMC) and Pierre-Robin sequence (cleft palate and micrognathia). Plasmids containing the wild-type (WT), mutant-type (MT) ZC4H2, or GFP report gene (N) were transfected in 293T cell lines, respectively. RT-qPCR and western blot analysis showed that ZC4H2 protein could not be detected in the 293T cells transfected with MT ZC4H2. The RNA seq results revealed that the expression profile of the MT group was similar to that of the N group but differed significantly from the WT group, indicating that the c.352C>T mutation resulted in the loss of function of ZC4H2. Differentially expressed genes (DEGs) enrichment analysis showed that c.352C>T mutation inhibited the expression levels of a series of genes involved in the oxidative phosphorylation pathway. Subsequently, expression levels of ZC4H2 were knocked down in neural stem cells (NSCs) derived from induced pluripotent stem cells (iPSCs) by lentiviral-expressed small hairpin RNAs (shRNAs) against ZC4H2. The results also demonstrated that decreasing the expression of ZC4H2 significantly reduced the growth of NSCs by affecting the expression of genes related to the oxidative phosphorylation signaling pathway. Taken together, our results strongly suggest that ZC4H2 c.352C>T (p.Gln118*) mutation resulted in the loss of protein function and caused WRWFFR.

Rapid screening for chromosomal aneuploidies using array-MLPA.

BACKGROUND: Chromosome abnormalities, especially trisomy of chromosome 21, 13, or 18 as well as sex chromosome aneuploidy, are a well-established cause of pregnancy loss. Cultured cell karyotype analysis and FISH have been considered reliable detectors of fetal abnormality. However, results are usually not available for 3-4 days or more. Multiplex ligation-dependent probe amplification (MLPA) has emerged as an alternative rapid technique for detection of chromosome aneuploidies. However, conventional MLPA does not allow for relative quantification of more than 50 different target sequences in one reaction and does not detect mosaic trisomy. A multiplexed MLPA with more sensitive detection would be useful for fetal genetic screening. METHODS: We developed a method of array-based MLPA to rapidly screen for common aneuploidies. We designed 116 universal tag-probes covering chromosomes 13, 18, 21, X, and Y, and 8 control autosomal genes. We performed MLPA and hybridized the products on a 4-well flow-through microarray system. We determined chromosome copy numbers by analyzing the relative signals of the chromosome-specific probes. RESULTS: In a blind study of 161 peripheral blood and 12 amniotic fluid samples previously karyotyped, 169 of 173 (97.7%) including all the amniotic fluid samples were correctly identified by array-MLPA. Furthermore, we detected two chromosome X monosomy mosaic cases in which the mosaism rates estimated by array-MLPA were basically consistent with the results from karyotyping. Additionally, we identified five Y chromosome abnormalities in which G-banding could not distinguish their origins for four of the five cases. CONCLUSIONS: Our study demonstrates the successful application and strong potential of array-MLPA in clinical diagnosis and prenatal testing for rapid and sensitive chromosomal aneuploidy screening. Furthermore, we have developed a simple and rapid procedure for screening copy numbers on chromosomes 13, 18, 21, X, and Y using array-MLPA.

[Multiplex ligation-dependent probe amplification and its application].

Multiplex ligation-dependent probe amplification (MLPA) is a semiquantitative analysis based on polymerase chain reaction (PCR). It possesses many advantages such as high efficiency, simple operation, low cost and has been wildly applied in researches of diseases associated with copy number variation, point mutation and methylation. Recently, MLPA is combined with DNA chip to become a real high-throughput method and get great improvement in reliability. Here, the progresses of methods and application of MLPA, as well as its limitations are reviewed.

Array-MLPA: comprehensive detection of deletions and duplications and its application to DMD patients.

Multiplex ligation-dependent probe amplification (MLPA) is widely used to screen genes of interest for deletions and duplications. Since MLPA is usually based on size-separation of the amplification products, the maximum number of target sequences that can be screened in parallel is usually limited to approximately 40. We report the design of a robust array-based MLPA format that uses amplification products of essentially uniform size (100-120 bp) and distinguishes between them by virtue of incorporated tag sequences. We were thus able to increase probe complexity to 124, with very uniform product yields and signals that have a low coefficient of variance. The assay designed was used to screen the largest set studied so far (249 patients) of unrelated Duchenne muscular dystrophy (DMD) cases from the Chinese population. In a blind study we correctly assigned 98% of the genotypes and detected rearrangements in 181 cases (73%); i.e., 163 deletions (65%), 13 duplications (5%), and five complex rearrangements (2%). Although this value is significantly higher for Chinese patients than previously reported, it is similar to that found for other populations. The location of the rearrangements (76% in the major deletion hotspot) is also in agreement with other findings. The 96-well flow-through microarray system used in this research provides high-throughput and speed; hybridization can be completed in 5 to 30 minutes. Since array processing and data analysis are fully automated, array-MLPA should be easy to implement in a standard diagnostic laboratory. The universal array can be used to analyze any tag-modified MLPA probe set.

[Preliminary application of MLPA-based array in detecting Y chromosome abnormalities].

To explore the feasibility and accuracy of MLPA-based array (Array-MLPA) in detecting sex chromosome abnormalities, MLPA probes were designed to target against three gene loci, TSPY (p11.2), PRY (q11), and RBMY (q11.2) in human Y chromosome. Array-MLPA approach was applied to test abnormalities of Y chromosome in 15 patient samples with known karyotypes. The data were compared with karyotyping and PCR analyses. The results showed that the copy number of each site detected by Array-MLPA was basically consistent with karyotyping analysis. Moreover, small deletions of chromosomes that were not found by routine karyotyping analysis were identified by the approach described, which fully agreed with PCR analysis, indicating that Array-MLPA was able to detect small abnormalities of chromosomes that cannot be found by karyotyping analysis. Compared to the routine karyotyping method, Array-MLPA has the advantages of high efficiency and reliability in chromosomal analysis, which has great potential in clinical application of diagnosis of chromosome abnormalities.

[Mitochondrial and oocyte development].

Oocyte development and maturation is a complicated process. The nuclear maturation and cytoplasmic maturation must synchronize which can ensure normal oocyte fertilization and following development. Mitochondrial is the most important cellular organell in cytoplasm, and the variation of its distribution during oocyte maturation, the capacity of OXPHOS generating ATP as well as the content or copy number or transcription level of mitochondrial DNA play an important role in oocyte development and maturation. Therefore, the studies on the variation of mitochondrial distribution, function and mitochondrial DNA could enhance our understanding of the physiology of reproduction and provide new insight to solve the difficulties of assisted reproduction as well as cloning embryo technology.

Dysfunctions of mitochondria in close association with strong perturbation of long noncoding RNAs expression in down syndrome.

Trisomy 21 is the most common chromosomal disorder and underlies Down syndrome. Epigenetics, such as DNA methylation and post-translational histone modifications, plays a vital role in Down syndrome. However, the functions of epigenetics-related long noncoding RNAs (lncRNAs), found to have an impact on neural diseases such as Alzheimer's disease, remain unknown in Down syndrome. In this study, we analyzed the RNA sequencing data from Down syndrome-induced pluripotent stem cells (iPSCs) and normal iPSCs. A large number of lncRNAs were identified differentially expressed in Down syndrome-iPSCs. Notably, stronger perturbation was shown in the expression of lncRNAs compared to protein coding genes (Kolmogorov-Smirnov test, P<0.05), suggesting that lncRNAs play more important roles in Down syndrome. Through gene set enrichment analysis and bi-clustering, we also found that most of the differential expressed lncRNAs were closely associated with mitochondrial functions (e.g. mitochondrion organization, P=3.21×10-17; mitochondrial ATP synthesis coupled electron transport, P=1.73×10-19 and mitochondrial membrane organization, P=4.04×10-8). PCR-array and qRT-PCR results revealed that almost all genes related to mitochondria were down-regulated in Down syndrome-iPSCs, implying that mitochondria were dysfunctional in Down syndrome (e.g. ATP5B, Fold Change=-8.2317; COX6A1, Fold Change=-12.7788 and SLC25A17, Fold Change=-22.1296). All in all, our study indicated that a stronger perturbation of lncRNAs expression may lead to the dysfunction of mitochondria in Down syndrome.

Construction and characteristics of 3-end enriched cDNA library from individual embryos of cattle.

To analyze stage-specific gene expression profiles of pre-implantation embryos and evaluate potential viability, techniques were adapted to generate 3-end enriched cDNA libraries from individual embryos of cattle based on RT-PCR methodology. The reproducibility of constructing a cDNA library was tested by five independent PCR experiments with specific primers for the presence of several rare genes such as DNMT1 (DNA methylation transferase 1), DNMT2, DNMT3A, Oct-4/3 (octmer-binding transcription factor), IFN-iota, IGF-2r (insulin like growth factor 2 receptor), and the housekeeping genes, H2A and beta-actin. Results indicated repeatability and that a proportion of expressed genes in the cDNA library from an individual embryo was not affected by limited PCR amplification. From the cDNA library, 134 clones were randomly selected for sequencing and showed that structure related elements accounted for 33.5% of transcripts and the energy- and metabolism-related genes were also an important component being 11.9% in the cDNA library. Approximately 14% of genes in the library were functionally unknown including greater than 5% of genes that were likely novel because there was no identity in Genbank. The frequency of structure-related genes such as beta-actin and ribosomal proteins in the cDNA library corresponded to other reports and suggested that the cDNA library constructed by RT-PCR might be proportional to the mRNA populations. The cDNA libraries constructed from different stage embryos will provide a powerful tool to explore novel genes relevant to embryogenesis, determine the profiling of stage-specific gene expression, and evaluate the potential viability of embryos.

Identification and functional analysis of long non-coding RNAs in human and mouse early embryos based on single-cell transcriptome data.

Epigenetics regulations have an important role in fertilization and proper embryonic development, and several human diseases are associated with epigenetic modification disorders, such as Rett syndrome, Beckwith-Wiedemann syndrome and Angelman syndrome. However, the dynamics and functions of long non-coding RNAs (lncRNAs), one type of epigenetic regulators, in human pre-implantation development have not yet been demonstrated. In this study, a comprehensive analysis of human and mouse early-stage embryonic lncRNAs was performed based on public single-cell RNA sequencing data. Expression profile analysis revealed that lncRNAs are expressed in a developmental stage-specific manner during human early-stage embryonic development, whereas a more temporal-specific expression pattern was identified in mouse embryos. Weighted gene co-expression network analysis suggested that lncRNAs involved in human early-stage embryonic development are associated with several important functions and processes, such as oocyte maturation, zygotic genome activation and mitochondrial functions. We also found that the network of lncRNAs involved in zygotic genome activation was highly preservative between human and mouse embryos, whereas in other stages no strong correlation between human and mouse embryo was observed. This study provides insight into the molecular mechanism underlying lncRNA involvement in human pre-implantation embryonic development.

In utero transplantation of human hematopoetic stem cells into fetal goats under B-type ultrasonographic scan: an experimental model for the study of potential prenatal therapy.

OBJECTIVE: Using fetal goats as animal models, to establish the methodology of in utero transplantation of human hematopoeitic stem cell (HSC) under B-scan ultrasonographic guidance for prenatal therapy. STUDY DESIGN: Human HSC were directly injected into the peritoneal cavities of the recipient fetal goats at 45-55 days of gestation (term: 145 days) under the guidance of B-type ultrasound scan. After birth, the peripheral blood was collected for fluorescence assisted cell sorting (FACS), quantitative real-time PCR and fluorescence in situ hybridization (FISH) to detect and analyze the presence of human cells in the recipients. RESULTS: The 32 recipients were born alive except one miscarriage. To test for the presence of human-goat chimeras, cells from 13 randomly selected transplanted goats were collected. FACS analyses showed the presence of human cells in all the transplanted goats tested. The average proportion of CD34+ cells and GPA+(glycophorin A) cells in the peripheral blood were 1.34 +/- 1.10% and 2.80 +/- 2.10%, respectively. No CD34+ or GPA+ cells were found in the non-transplanted goats tested. The results of the quantitative real-time PCR in three engraftment goats were 1.2 x 10(4), 2.9 x 10(4), and 3.2 x 10(4) copies of human GPA DNA per mug of genomic DNA. FISH experiments showed that cells containing human specific alpha-satellite DNA sequence were present in the peripheral blood of the transplanted goats. CONCLUSIONS: The method described herein is safe and reliable, with low miscarriage risk and high chimerism rate. This approach may provide a promising animal model for potential prenatal treatment.

[Suppression of enhanced green fluorescent protein expression in cells by RNA interference].

OBJECTIVE: To evaluate the role of RNA interference (RNAi) in silencing the enhanced green fluorescent protein (eGFP) expression in 293T and Mel cells. METHODS: Nested-PCR was used to amplify H1 promoter from human 293T cells for driving RNAi synthesis. RNAi vectors (TR1) for silencing the eGFP expression was constructed. The eGFP vector and RNAi vector (TR1) were then co-transfected into the 293T and Mel cells, in which the silencing effect on eGFP expression was investigated by fluorescence microscopy, reverse transcription-PCR(RT-PCR), fluorescence-assited cell sorting(FACS) analysis and real-time RT-PCR. RESULTS: RNAi could effectively reduce more than 50 percent of eGFP expression in 293T cells as well as in Mel cells. CONCLUSION: The RNAi vector constructed in this way paper can effectively inhibit eGFP expression in cells.

A chimeric mouse model established by allogenic in utero transplantation.

In utero stem cells transplantation is a promising approach to the prenatal treatment of diseases. In order to investigate the fate of the stem cells after in utero transplantation, we have established a chimeric mouse model with the method of in utero transplantation. Mononuclear cells (including stem cells/progenitor cells) derived from male mouse bone marrow were injected into fetal mouse peritoneal cavity during the pre-immune period. The donor cells in the circulatory blood of female recipients were identified by fluorescence in situ hybridization (FISH), and the Y-chromosome specific DNA was detected by PCR as well as real-time quantitative PCR after the recipient mice were born. The results showed that a total of 4 female recipient mice were chimeric in their peripheral blood. Significantly, the donor cells in three chimeric mice persisted up to six months.

[Isolation and identification of a gene: attractin related to inhibiting erythroid differentiation in K562 cells].

Differential display PCR method was used to isolate four differential display fragments between the wild type K562 cell line and the variant type K562 cell line that expressed the human beta-globin gene. After sequencing, the most remarkable different fragment,named dd1,was selected for further study. The analysis of RT-PCR and Northern blot hybridization showed that dd1 was exactly the differentiation fragment between the two cell lines. The homology analysis indicated that dd1 was matched to Attractin (GeneBank registration No.AF106861). It might be an adhesion receptor related to inhibiting erythroid differentiation based on its structure.

[Chromosomal abnormalities in two cases of goats with sexual deformity].

We herein report two cases of goats with sexual deformity. They had two systems of reproductive organs and the karyotype analysis showed mosaicism for their sex chromosomes, i.e., 60, XX / XY. The proportion of XX cell line was 42% and 54%, while XY cell line was 58% and 46%, respectively, in the two abnormal goats.

[Mammary gland dual-expression construct containing prolactin and foreign DNAs can promote the expression of foreign proteins in mammary cells].

To investigate the feasibility in the promotion of the expression of foreign proteins, such as human lactinferrin (hLF) and thrombopoietin (TPO), in the transgenic animals-mammary gland bioreactor by bovine prolactin (bPRL), two types of mammary gland dual-expression vectors containing bPRL and foreign DNAs were constructed. In one type of vector, both foreign and bPRL DNAs were linked by internal ribosome entry site (IRES) which shared one goat 6.7 kb of beta-casein promoter; while in the other type of vector, the transcriptions of the foreign gene as well as bPRL were respectively directed by 6.7 kb goat beta-casein promoter and 2.0 kb of goat beta-casein promoter. After transfection of the vectors with lipofectin method, the expression of foreign proteins were measured by RT-PCR as well as ELISA assay. The results showed that bPRL could obviously promote the expression of foreign proteins (hLF and TPO) in cultured cells. The hLF expression level was increased from 12.6 microg/L to 18.4 microg/L and 37.2 microg/L in the COS-7 cells (African green monkey kidney cell) (P<0.05), and from 13.7 microg/L to 20.7 microg/L and 19.9 microg/L in the HC-11 cells (epithelial cell of mouse mammary gland) (P<0.05) by two vectors, respectively. TPO expression level was increased from 572 ng/L to 1340 ng/L in the COS-7 cell (P<0.05), and from 783 ng/L to 1040 ng/L in the HC-11 cell (P<0.05) by the vector which have two promoters. This work indicate that bovine prolactin can effectively increase the expression of foreign genes in mammal cells.

Rapid detection of G1138A and G1138C mutations of the FGFR3 gene in patients with achondroplasia using high-resolution melting analysis.

Achondroplasia (ACH) is a genetic disorder with autosomal dominant inheritance and is the cause of one of the most common forms of short limb dwarfism in humans. Mutations of special sites in the fibroblast growth factor receptor-3 gene (FGFR3) are reported as a cause of ACH, and almost 98% of cases are caused by mutations in nucleotide 1138 (Gly380Arg), with 97% involving a c.1138G>A mutation and 1% involving a c.1138G>C mutation. Therefore, the development of a simple, reliable, and rapid approach for molecular detection of nucleotide 1138 mutations is of great significance for prevention and early diagnosis of ACH. High-resolution melting (HRM) is a new, rapid, and inexpensive molecular detection method that has been generally applied to mutation scanning. In this study, 12 cases of ACH, including 10 sporadic cases and 2 cases in a pedigree, were detected simultaneously using HRM analysis and restriction fragment length polymorphism-polymerase chain reaction (RFLP-PCR). Eleven cases were identified as carrying the c.1138 G>A heterozygous mutation, and one case was identified as carrying the c.1138 G>C heterozygous mutation. Compared with RFLP-PCR, HRM analysis provided a more rapid, simpler, and less expensive approach for detecting the most common FGFR3 mutations carried by patients with ACH.

Application of high-resolution melting for genotyping bovine mitochondrial DNA.

Recent studies have demonstrated that mitochondrial DNA (mtDNA) haplotype has a significant impact on the efficiency of bovine somatic cell nuclear transfer. Conventional methods for detecting mtDNA variations and haplotypes, such as restriction fragment length polymorphism (RFLP), temporal temperature gradient gel electrophoresis, dHPLC and sequencing, are labor intensive or expensive and have low sensitivity. High-resolution melting (HRM) analysis is a new technique for mutation detection and has the advantages of speed, cost, and accuracy. Here, we describe the genotyping of bovine mtDNA using HRM analysis. DNA samples containing mtDNA were extracted from 75 Holstein cows and subjected to rapid-cycle (<20 min) PCR of small amplicons (<120 bp) using specific primer sets. Capillaries containing the PCR products were then subjected to HRM analysis; data were acquired in 2 min and analyzed using the instrument's software. Five common bovine mtDNA single nucleotide polymorphisms were identified: 9602 G>A, 169 A>G, 166A>G with 173A>G, and 363C>G. These results agree with both sequencing and RFLP analysis. In addition, a very small amount of heteroplasmic variants (<5%) was sufficiently to be distinguished by HRM analysis that would be very useful to differentiate heteroplasmy vs. homoplasmy. HRM analysis thus provides a new approach to genotyping bovine mtDNA sequence variations and has many advantages over other methods, including speed of analysis, cost, and accuracy. We believe this will be a valuable technique for determining the efficiency of nuclear transfer in cloned embryos and for studying maternal effects on nuclear-cytoplasm interactions.

Correction of ß654-thalassaemia mice using direct intravenous injection of siRNA and antisense RNA vectors.

Although the therapeutic efficacy of ß(654)-thalassaemia treatment using a combination of RNAi and antisense RNA to balance the synthesis of α- and ß-globin chains has been demonstrated previously, and the safety of lentiviral delivery remains unclear. Herein, we used the same ß(654)-thalassaemia mouse model to develop a therapy involving direct delivery of siRNA and antisense RNA plasmids via intravenous injection to simultaneously knock down α-globin transcript levels and restore correct ß-globin splicing. The amount of α-globin mRNAs in siRNA-treated MEL cells decreased significantly, and the properly spliced ß-globin mRNA was restored in HeLaß(654) cells transfected with pcDNA-antisense plasmid. Furthermore, treatment of ß(654)-thalassaemic mice with siRNA and antisense RNA plasmids resulted in significant reduction of poikilocytosis and reticulocyte counts in blood samples, decreased nucleated cell populations in bone marrow, and reduced intrasinusoidal extramedullary haematopoiesis loci and iron accumulation in liver. RT-PCR analysis revealed that treatment resulted in down-regulation of α-globin mRNA synthesis by ~50% along with an increase in the presence of normally spliced ß-globin transcripts, indicating that the phenotypic changes observed in ß(654)-thalassaemic mice following treatment resulted from restoration of the balance of α/ß-globin biosynthesis.