Exon

About: Exon is a research topic. Over the lifetime, 38308 publications have been published within this topic receiving 1745408 citations. The topic is also known as: exons.

A second gene, VpreB in the lambda 5 locus of the mouse, which appears to be selectively expressed in pre-B lymphocytes.

Abstract: The murine gene lambda 5 is selectively expressed in pre-B lymphocytes. Of the three exons encoding lambda 5, exons II and III show strong homologies to immunoglobulin lambda light (L) chain gene segments, i.e. to J lambda intron and exon, and C lambda exon sequences respectively. We have now found, 4.6 kb upstream of lambda 5, another gene composed of two exons which is selectively expressed in pre-B cell lines as a 0.85 kb mRNA potentially coding for a protein of 142 amino acids including a 19 amino acid-long signal peptide. The 5' sequences of this gene show homologies to sequences encoding the variable regions of kappa and lambda L chains and of heavy (H) chains. The deduced amino acid sequence contains the consensus cysteine residues as well as other consensus amino acids at positions which characterize immunoglobulin (Ig) domains. We call the second gene VpreB. The 3' end of VpreB encoding the 26 carboxyl terminal amino acids shows no homology to any known nucleotide sequence. The putative protein encoded by VpreB is a potential candidate for association with the putative protein encoded by lambda 5, and thereby a candidate for association with H chains in pre-B cells. Southern blot analysis of DNA from liver (germ line) and 70Z/3 pre-B cell lines reveals two genes which hybridize to the VpreB gene. We call VpreB1 the gene which is found 5' of lambda 5. The other gene, called VpreB2, which has not yet been located within the genome, shows 97% nucleotide sequence homology to VpreB1 in an area of 1 kb which covers the coding region of the gene.(ABSTRACT TRUNCATED AT 250 WORDS)

Transcriptional Silencing of the p73 Gene in Acute Lymphoblastic Leukemia and Burkitt’s Lymphoma Is Associated with 5′ CpG Island Methylation

Abstract: The p73 gene is located on 1p36.2-3, a region that is frequently deleted in human cancer. Because p73 encodes for a protein that is both structurally and functionally homologous to the p53 protein, p73 has been postulated to be a candidate tumor suppressor gene. To date, however, mutations of p73 have not been found. To study methylation of the p73 5'CpG island, a human bacterial artificial chromosome clone containing exon 1 and the 5' region of p73 was isolated. There was no evidence for p73 exon 1 methylation in normal tissues. In contrast, p73 was aberrantly methylated in approximately 30% of primary acute lymphoblastic leukemias (ALLs) and Burkitt's lymphomas. There was no evidence for methylation in any other types of hematological malignancies or solid tumors examined. In both leukemia cell lines and primary ALLs, methylation was associated with transcriptional loss of p73 by reverse transcription-PCR. We used single-strand conformational polymorphisms to screen for point mutations in a series of primary ALLs and found no mutations leading to a change in protein structure. Our results show that methylation of p73 is a frequent event in specific types of hematological malignancies and suggest that epigenetic silencing of p73 could have important consequences for cell-cycle regulation.

Noisy Splicing Drives mRNA Isoform Diversity in Human Cells

Abstract: While the majority of multiexonic human genes show some evidence of alternative splicing, it is unclear what fraction of observed splice forms is functionally relevant. In this study, we examine the extent of alternative splicing in human cells using deep RNA sequencing and de novo identification of splice junctions. We demonstrate the existence of a large class of low abundance isoforms, encompassing approximately 150,000 previously unannotated splice junctions in our data. Newly-identified splice sites show little evidence of evolutionary conservation, suggesting that the majority are due to erroneous splice site choice. We show that sequence motifs involved in the recognition of exons are enriched in the vicinity of unconserved splice sites. We estimate that the average intron has a splicing error rate of approximately 0.7% and show that introns in highly expressed genes are spliced more accurately, likely due to their shorter length. These results implicate noisy splicing as an important property of genome evolution.