Short form of the heparin-binding EGF-like growth factor: Communication II

The structure of the green monkey Chlorocebus aethiops heparin-binding EGF-like growth factor (HB-EGF) gene was compared with that of the corresponding human gene. Exon 3a, characteristic of the short form of HB-EGF (SF-HB-EGF), was mapped between exons 3 and 4, approximately 700 bp away from the latter. In several human and simian cell lines, most of the SF-HB-EGF mRNA proved to lack exons 4 and 5, specific to the HB-EGF mRNA. In contrast to the HB-EGF mRNA, the SF-HB-EGF mRNA occurred predominantly in the P, rather than L, form, which codes for a protein with a different propeptide structure. Labeled SF-HB-EGF competed with HB-EGF and EGF for binding to the surface of A431 cells, suggesting its interaction with the specific EGF receptor. The results indicate that SF-HB-EGF plays a specific role in cell signaling.     

Model for tissue specific Calcitonin/CGRP-I RNA processing from in vitro experiments.

The Calcitonin/CGRP-I (CALC-I) gene is known to be expressed in a tissue specific fashion resulting in the production of Calcitonin mRNA in thyroid C-cells and CGRP-I mRNA in particular nerve cells. The alternative RNA processing reactions include splicing of exons 1, 2 and 3 to exon 4 and poly (A) addition at exon 4 (Calcitonin mRNA) or splicing of exons 1, 2 and 3 to exons 5 and 6 and poly (A) addition at exon 6 (CGRP-I mRNA). Using a model precursor RNA containing the exon 3 to exon 5 region of the human CALC-I gene we have investigated the Calcitonin- and CGRP-I mRNA-specific processing reactions in vitro, in nuclear extracts of Hela, PC12 and Ewing-1B cells, respectively. Extracts of PC12- and Ewing-1B cells were expected to perform CGRP mRNA-specific splicing, whereas Calcitonin mRNA specific processing was expected to occur in Hela cell extracts. Surprisingly, CGRP mRNA-specific splicing of exon 3 to exon 5 was the predominant reaction in all three extracts. Significant Calcitonin mRNA-specific splicing of exon 3 to exon 4 only took place upon elimination of the dominant downstream 3' splice site used in CGRP mRNA-specific splicing. This elimination occurs most definitively by cleavage at the Calcitonin mRNA specific poly (A) site at exon 4 which may then be the major regulatory mechanism for tissue-specific expression of the CALC-I gene.     

Unusual branch point selection involved in splicing of the alternatively processed Calcitonin/CGRP-I pre-mRNA.

To study splice site selection in alternative RNA processing we used the human Calcitonin/CGRP-I (CALC-I) gene. Expression of the CALC-I gene in thyroid C-cells results predominantly in calcitonin (CT) mRNA (containing exons 1 to 4) whereas CGRP-I mRNA (containing exons 1,2,3,5 and 6) is the exclusive product in particular nerve cells. We previously reported that a model precursor RNA containing the exon 3 to exon 5 region is predominantly processed into CGRP-I mRNA in vitro using nuclear extracts of three different cell types. To study CT specific processing in Hela cell nuclear extracts we have used precursor RNAs corresponding to the exon 3 to exon 4 region containing only CT specific processing signals. The results revealed the usage of a uridine residue 23 nucleotides upstream of the 3' splice site as the major site of lariat formation in CT specific splicing. The implications of this finding for the alternative, tissue specific processing of the CALC-I pre-mRNA and for branch point selection in general are discussed.     

A short form of the heparin-binding EGF-like growth factor with a changed EGF domain

In all secreted proteins related to the epidermal growth factor (EGF), EGF domains that occur in a mature factor are each encoded by two exons, and those that do not, by one exon. During splicing, additional exon 3a can be inserted between exons 3 and 4, which code for the EGF domain of the mature heparin-binding EGF-like growth factor (HB-EGF). The resulting mRNA codes for the short form of HB-EGF (SF HB-EGF), which retains the signal peptide, the propeptide, and the heparin-binding domain. However, its EGF domain lacks the C-terminal subdomain essential for the interaction with the EGF receptor (EGFR). Structural analysis suggested that SF HB-EGF is a secreted polypeptide that has high affinity for heparin, but weakly, if at all, interacts with EGFR. Data obtained in three different systems indicated that SF HB-EGF possesses a mitogenic activity but utilizes a signal transduction pathway other than that of HB-EGF.     

A Short Form of the Heparin-binding EGF-like Growth Factor with a Changed EGF Domain

In all secreted proteins related to the epidermal growth factor (EGF), EGF domains that occur in a mature factor are each encoded by two exons, and those that do not, by one exon. During splicing, additional exon 3a can be inserted between exons 3 and 4, which code for the EGF domain of the mature heparin-binding EGF-like growth factor (HB-EGF). The resulting mRNA codes for the short form of HB-EGF (SF HB-EGF), which retains the signal peptide, the propeptide, and the heparin-binding domain. However, its EGF domain lacks the C-terminal subdomain essential for the interaction with the EGF receptor (EGFR). Structural analysis suggested that SF HB-EGF is a secreted polypeptide that has high affinity for heparin but weakly, if at all, interacts with EGFR. Data obtained in three different systems indicated that SF HB-EGF possesses a mitogenic activity but utilizes a signal transduction pathway other than that of HB-EGF.     

Uridine branch acceptor is a cis-acting element involved in regulation of the alternative processing of calcitonin/CGRP-l pre-mRNA.

The human calcitonin/CGRP-I (CALC-I) gene contains 6 exons and encodes two polypeptide precursors. In thyroid C-cells, calcitonin (CT) mRNA is produced by splicing of exons 1-2-3 to exon 4 (CT-encoding) and polyadenylation at exon 4. CGRP-I mRNA is produced in particular neural cells by splicing of exons 1-2-3 to exon 5 (CGRP-I-encoding) and the polyadenylated exon 6. We previously reported that model precursor RNAs containing the exon 3 to exon 5 region of the CALC-I gene are processed predominantly into CGRP-I mRNA in vitro, in nuclear extracts of several cell types (neural and non-neural). Using truncated precursor RNAs containing only the exon 3 to exon 4 region of the CALC-I gene it was shown that CT splicing is an inefficient reaction in which a uridine residue serves as the major site of lariat formation. Here we report that the low CT splicing efficiency and the dominance of CGRP-I splicing over CT splicing in vitro are primarily due to the usage of the CT-specific uridine branch acceptor. Mutation of this uridine residue into an adenosine residue resulted in a strong increase in CT splicing efficiency causing a reversal of the splicing pattern. In addition, it was shown that this point mutation also increased CT splicing efficiency in vivo. These results and data obtained from other experiments involving mutation of the CT splice acceptor site suggest that the uridine branch acceptor is a cis-acting element involved in regulation of the alternative processing of the CALC-I pre-mRNA.     

In vitro splicing analysis of mini-gene constructs of the alternatively processed human calcitonin/CGRP-I pre-mRNA

The human calcitonin/CGRP-I (CALC-I) gene can be alternatively expressed into calcitonin mRNA in thyroid C-cells and into CGRP-I mRNA in particular nerve cells. Formation of calcitonin mRNA requires splicing of exons 1, 2, 3 and 4 and addition of poly(A) at exon 4, whereas splicing of exons 1, 2, 3, 5 and 6 and addition of poly(A) at exon 6 yields CGRP-I mRNA. The calcitonin and CGRP-I mRNA-specific splicing reactions were investigated in vitro, in nuclear extracts of HeLa cells, using model precursor RNAs containing the exon 3 to exon 5 region of the gene. A precursor RNA containing the full-length exon 3 to exon 5 region was only poorly spliced in vitro. Therefore, a systematic analysis was performed of the effect of deletions introduced in the intron 3, exon 4 and intron 4 of this precursor RNA on calcitonin/CGRP mRNA-specific splicing. The deletions increased the efficiency of splicing considerably. In all cases CGRP mRNA-specific splicing is strongly favoured over calcitonin mRNA-specific splicing. In addition, splicing reactions using cryptic 5' splice sites were detected which interfered with the usage of processing signals for calcitonin and CGRP mRNA-specific splicing. The results imply a major regulatory role for the exon 4 poly(A) addition reaction in the generation of calcitonin mRNA.     

Exons of the human pancreatic polypeptide gene define functional domains of the precursor

Pancreatic polypeptide is a 36-amino acid peptide which inhibits pancreatic exocrine function. We have previously determined from the nucleotide sequence of a cDNA that pancreatic polypeptide is derived from a 95-amino acid precursor, prepropancreatic polypeptide. Pulse-chase studies have suggested that the precursor is cleaved to produce three peptides: pancreatic polypeptide, an icosapeptide, and a smaller peptide. In the present study, we have used the cloned cDNA as a hybridization probe to isolate the pancreatic polypeptide gene from a human bacteriophage genomic library. The nucleotide sequence of 2.8 kilobases of DNA representing the entire human pancreatic polypeptide gene was determined. The gene contains four exons and three introns. Exon 1 encodes the 5'-untranslated region of the mRNA, exon 2 encodes the signal sequence and the sequence of pancreatic polypeptide, exon 3 encodes the icosapeptide, and exon 4 encodes a carboxyl-terminal heptapeptide and the 3'-untranslated region of the mRNA. By Southern blot analysis, the gene detected in a pancreatic polypeptide-producing islet cell tumor was indistinguishable from that in normal human leukocytes. The structure of the human pancreatic polypeptide gene is consistent with the hypothesis that prepropancreatic polypeptide generates three distinct peptides, each encoded by a separate exon. Increased expression of pancreatic polypeptide in the islet cell tumor does not appear to be correlated with major alterations in pancreatic polypeptide gene structure.     

Structure of the human genomic region homologous to the bovine prochymosin-encoding gene

Two human genomic libraries were probed with bovine prochymosin (bPC) cDNA. Recombinant clones covering a genomic region homologous to the entire coding region and flanking sequences of the bPC gene were isolated. Human sequences homologous to exons of the bPC gene are distributed in a DNA fragment of 10 kb. Alignment of the human sequences and the exons of bPC reveals that the human 'exons' 1-3, 5 and 7-9 have sizes identical to the corresponding bovine exons, but a nucleotide (nt) has been deleted in the human exon 4 and two nt in the human exon 6. The aligned human sequence and the coding part of bPC gene share 82% nt homology, the value ranging, in separate exons, from 76 (exon 1) to 84% (exons 5 and 6). 150 bp of 5'-flanking sequence of the human gene has 75% homology to the corresponding region of bPC gene and contains a TATA-box in a similar position. A 1-nt deletion in the human exon 4 would shift the translational reading frame of a putative human PC mRNA relative to bPC mRNA, and result in an in-phase terminator spanning codons 163 and 164 in bPC mRNA. Another terminator in-phase with the amino-acid sequence encoded by the bPC gene occurs in the human exon 5 and the second frameshift mutation in exon 6. Thus, the nt sequence analysis of the human genomic region has revealed the presence of mutations that have rendered it unable to produce a full-length protein homologous to bPC and, therefore, we refer to this gene as a human prochymosin pseudogene (hPC psi). Blot-hybridization analysis of human genomic DNA indicates that hPC psi is a single gene in the human genome.