Structure and expression of the human oocyte-specific histone H1 gene elucidated by direct RT-nested PCR of a single oocyte

Oocyte-specific histone H1 is expressed during oogenesis and early embryogenesis. It has been described in mice and some nonmammalian species, but not in humans. Here, we identified the cDNA in unfertilized human oocytes using direct RT-nested PCR of a single cell. Sequencing of this cDNA indicated an open reading frame encoding a 347-amino acid protein. Expression was oocyte-specific. Homology was closest with the corresponding gene of mouse (H1oo; 42.3%), and, to lesser extent, with that of Xenopus laevis (B4; 25.0%). The gene, named osH1, included five exons as predicted by the NCBI annotation project of the human genome, although the actual splicing site at the 3(') end of exon 3 was different by 48 nucleotides from the prediction. The presence of polyadenylation signals and successful amplification of cDNA by RT-PCR using an oligo(dT) primer suggested that the osH1 mRNA is polyadenylated unlike somatic H1 mRNA. Our technique and findings should facilitate investigation of human fertilization and embryogenesis.     

基于RefSeq的人类基因荧光定量PCR引物库的构建

利用NCBI提供的RefSeq序列,通过BLAT、Sim4和自主开发的剪接比对程序Ealter1.0对人类RefSeq转录本进行外显子预测,根据预测的外显子信息,采用自主开发SYBR Green I Real Time PCR引物设计程序E-qPCR-Design1.0高通量设计21,118对SYBR Green I Real Time PCR引物,同时选取5000条基因进行SYBR Green I Real Time PCR引物验证,95.92%的基因引物取得良好效果,1.64%的基因引物产生引物二聚体,1.08%的基因引物有非特异性扩增,通过生物信息技术分析与实验验证,建立了基于RefSeq的人类基因荧光定量PCR引物库。     

Rapid screening of an SH2-containing gene using PCR amplification method

Summary To isolate a novel gene that contains an SH2 domain, we devised a rapid and nonradioactive cDNA library screening method using polymerase chain reaction (PCR). For PCR amplification, we designed degenerate oligonucleotide primers from the multialigned DNA sequences of SH2 domains. This method offers an inexpensive and efficient approach for the isolation of clones of interest from cDNA libraries.     

Genomic analysis of human multigene families using chromosome-specific vectorette PCR.

We report a technique for the rapid determination of genomic structure of individual members of human interspersed multigene families which circumvents the requirement for genomic clone isolation. In this approach, vectorette libraries were constructed from human/rodent somatic cell hybrid DNA harbouring single members of the gene family. Using these libraries as PCR templates with nested gene-specific primers in combination with a common vectorette primer resulted in the amplification of gene-specific products suitable for the subsequent determination of intron/exon structure. We have applied this technique to characterise members of two gene families.     

Global amplification of cDNA from limiting amounts of tissue. An improved method for gene cloning and analysis

In this study we present an improved polymerase chain reaction (PCR)-based methodology to generate large amounts of high-quality complementary DNA (cDNA) from small amounts of initial total RNA. Global amplification of cDNA makes it possible to simultaneously clone many cDNAs and to construct directional cDNA libraries from a sequence-abundance-normalized cDNA population, and also permits rapid amplification of cDNA ends (RACE), from a limited amount of starting material. The priming of cDNAs with an adapter oligo-deoxythymidine (oligo-dT) primer and the ligation of a modified oligonucleotide to the 3′ end of single-stranded cDNAs, through the use of T4 RNA ligase, generates known sequences on either end of the cDNA population. This helps in the global amplification of cDNAs and in the sequence-abundance normalization of the cDNA population through the use of PCR. Utilization of a long-range PCR enzyme mix to amplify the cDNA population helps to reduce bias toward the preferential amplification of shorter molecules. Incorporation of restriction sites in the PCR primers allows the amplified cDNAs to be directionally cloned into appropriate cloning vectors to generate cDNA libraries. RACE-PCR done with biotinylated primers and streptavidin-coated para-magnetic particles are used for the efficient isolation of either full-length coding or noncoding strands.     

Mouse connexin 45: genomic cloning and exon usage

Connexin 45 is a gap junction protein that is prominent in early embryos and is widely expressed in many mature cell types. To elucidate its gene structure, expression, and regulation, we isolated mouse Cx45 genomic clones. Alignment of the genomic DNA and cDNA sequences revealed the presence of three exons and two introns. The first two exons contained only 5' untranslated sequences, while exon 3 contained the remaining 5' UTR, the entire coding region, and the 3' UTR. An RT-PCR with exon-specific primers was utilized to examine exon usage in F9 mouse embryonal carcinoma cells and adult mouse tissues. In all samples, PCR products amplified using exon 2/exon 3 or exon 3/exon 3 primer pairs were much more abundant than products produced using exon 1/exon 2 or exon 1/exon 3 primer pairs, suggesting that Cx45 mRNAs containing exon 1 were relatively rare compared with mRNAs containing the other exons. Rapid amplification of cDNA ends (5'-RACE) was performed using antisense primers from within exon 3 and template RNA prepared from F9 cells or from adult mouse kidney. We obtained multiple RACE products from both templates, including products that contained all three exons and were spliced identically to the cDNA. However, clones were also isolated (from kidney) that began within the region previously identified as intron 1 and continued upstream with a sequence identical to the cDNA, including splicing to exon 3. These results show that mouse Cx45 has a gene structure that differs from that of previously studied connexins and allows the production of heterogeneous Cx45 mRNAs with differing 5' UTRs. These differences might contribute to regulation of Cx45 protein levels by modulating mRNA stability or translational efficiency.     

利用RT-PCR技术验证基于小鼠外显子芯片发现的缺血相关基因的表达

目的:利用RT-PCR技术验证并确认基于小鼠外显子芯片发现的部分缺血相关基因的表达,以鉴定候选基因的外显子是否发生可变剪接,从而实现对外显子芯片结果的鉴定。方法:根据生物信息学分析结果,选取小鼠外显子芯片中的3个基因(Ube3c,6330439K17Rik,Atp7a),在预测发生可变剪接的外显子两侧设计上下游引物,PCR后进行凝胶回收,再克隆到载体中进行测序。结果:RT-PCR及测序结果表明,Ube3c基因在6号外显子、6330439K17Rik基因在12号外显子、Atp7a基因在3号外显子发生可变剪接,与芯片预测结果一致。结论:RT-PCR技术可针对外显子芯片的结果进行可靠性验证,为可变剪接基因表达研究提供了一种有效手段。     

Structure of the murine lactotransferrin gene is similar to the structure of other transferrin-encoding genes and shares a putative regulatory region with the murine myeloperoxidase gene

The structure and nucleotide sequence of the murine lactotransferrin-encoding gene (LTF) deduced partly by direct sequencing of genomic clones in the λ phage vector and partly by enzymatic amplification of genomic DNA segments primed with the oligodeoxyribonucleic primers homologous to the cDNA sequence. The λ phage clones contained the 5′ half of the gene corresponding to the first eight exons and an incomplete ninth exon interrupted by eight introns. Genomic clones corresponding to the 3′ half of the LTF gene could not be obtained on repeated attempts from two different mouse genomic libraries, suggesting the possible presence of unclonable sequences in this part of the gene. Hence, PCR was used to clone the rest of the gene. Four out of the presumed eight remaining introns were cloned along with the flanking exons using PCR. Comparison of the structure of the LTF gene with those of the two other known transferrin-encoding genes, human serum transferrin-encoding gene and chicken ovotransferrin-encoding gene reveals that all three genes have a very similar intron-exon distribution pattern. The hypothesis that the present-day transferrin-encoding genes have originated from duplication of a common ancestral gene is confirmed here at the gene level. An interesting finding is the identification of a region of shared nucleotides between the 5′ flanking regions of the murine LTF and myeloperoxidase-encoding genes, the two genes expressed specifically in neutrophilic granulocytes.     

An efficient and rapid method for gene cloning from eukaryotic genomic DNA using overlap-PCR: With an example of cattle Ghrelin gene

In this study, overlap-PCR, an efficient and rapid method, was used to clone cattle Ghrelin gene CDS (coding sequence) from genomic DNA. The procedure included seven primers and three-step PCRs. Cattle Ghrelin gene consists of four exons and the CDS contains 351 bps. In the first step three PCRs were performed to generate extended exon1, exon2, and exon3 that contained overlapped nucleotides and were used as the templates for second ligation PCR. Secondly, exon1 and exon2 were spliced together. And it was same with exon3 and exon4. Lastly, the four exons were linked together with outermost primers and the templates from the second step. Comparison analysis on the obtained CDS of Ghrelin gene and cDNA by RT-PCR showed that the two sequences were same. As an efficient and rapid method, overlap-PCR is feasible and acceptable for gene cloning from genomic DNA.     

Assembling genes from predicted exons in linear time with dynamic programming.

In a number of programs for gene structure prediction in higher eukaryotic genomic sequences, exon prediction is decoupled from gene assembly: a large pool of candidate exons is predicted and scored from features located in the query DNA sequence, and candidate genes are assembled from such a pool as sequences of nonoverlapping frame-compatible exons. Genes are scored as a function of the scores of the assembled exons, and the highest scoring candidate gene is assumed to be the most likely gene encoded by the query DNA sequence. Considering additive gene scoring functions, currently available algorithms to determine such a highest scoring candidate gene run in time proportional to the square of the number of predicted exons. Here, we present an algorithm whose running time grows only linearly with the size of the set of predicted exons. Polynomial algorithms rely on the fact that, while scanning the set of predicted exons, the highest scoring gene ending in a given exon can be obtained by appending the exon to the highest scoring among the highest scoring genes ending at each compatible preceding exon. The algorithm here relies on the simple fact that such highest scoring gene can be stored and updated. This requires scanning the set of predicted exons simultaneously by increasing acceptor and donor position. On the other hand, the algorithm described here does not assume an underlying gene structure model. Indeed, the definition of valid gene structures is externally defined in the so-called Gene Model. The Gene Model specifies simply which gene features are allowed immediately upstream which other gene features in valid gene structures. This allows for great flexibility in formulating the gene identification problem. In particular it allows for multiple-gene two-strand predictions and for considering gene features other than coding exons (such as promoter elements) in valid gene structures.