Localization of DNA sequences governing alternative mRNA production of rat kininogen genes

The two types of the rat kininogen genes show different modes of mRNA production. The K gene encodes two distinct mRNAs for high molecular weight (HMW) and low molecular weight (LMW) kininogens. These two mRNAs are generated by differential usage of the 3'-terminal exon (LMW exon) and the one next to this exon (HMW exon) through alternative polyadenylation and splicing. In contrast, the two T genes selectively generate the LMW form of the mRNA, although the T genes are extremely homologous to the K gene, including the sequence (psi HMW region) corresponding to the HMW exon of the K gene. In this study, we constructed a series of chimeric kininogen genes by exchanging equivalent restriction fragments of the K and T genes and examined the sequences and the mechanisms governing the different expression patterns of the kininogen genes by introducing the chimeric genes into heterologous COS cells. The results indicate that the formation of the two forms of the mRNA is controlled by two separate 3' sequences of the kininogen genes. One is located within the internal sequence of the HMW/psi HMW region, whereas the other is within the LMW exon and its preceding region. Our data also suggest that the different expression patterns of the kininogen genes are primarily governed by differing splicing efficiency.     

A set of U1 snRNA-complementary sequences involved in governing alternative RNA splicing of the kininogen genes

The rat K and T kininogen genes show different modes of mRNA production. The K gene encodes two distinct mRNAs for high molecular weight (HMW) and low molecular weight (LMW) kininogens. These two mRNAs are generated by differential usage of the 3'-terminal exon (LMW exon) and the exon next to and upstream from the LMW exon (HMW exon) through alternative splicing and polyadenylation. In contrast, the T gene generates one mRNA by using selectively the LMW exon, although the T gene is extremely homologous to the K gene. In this study, we constructed a series of chimeric kininogen genes by not only exchanging equivalent restriction fragments of the two genes but also replacing nucleotides that differ between the two genes. We then examined the sequences and the mechanisms governing the different expression patterns of the two genes by transfecting the chimeric genes into heterologous COS cells. The results indicated that the different expression patterns of the K and T genes are governed by two separate internal sequences of the HMW and LMW exons. The internal HMW sequence contains a set of five repetitive sequences, and these repetitive sequences are highly complementary to the 5' portion of U1 snRNA. Furthermore, the nucleotide differences in the U1 snRNA-complementary sequences between the K and T genes have marked effects on the relative formation of the HMW and LMW mRNAs; this indicates that the repetitive sequences complementary to U1 snRNA play a crucial role in determining the relative expression of the two mRNAs. Based on these findings, we discuss a novel mechanism for alternative RNA processing, in which splicing efficiency is controlled by the interaction of U1 small nuclear ribonucleoproteins and the U1 snRNA-complementary repetitive sequences of the kininogen pre-mRNA.     

Functional characterization of the two alcohol oxidase genes from the yeast Pichia pastoris.

In Pichia pastoris, alcohol oxidase (AOX) is the first enzyme in the methanol utilization pathway and is encoded by two genes, AOX1 and AOX2. The DNA and predicted amino acid sequences of the protein-coding portions of the genes are closely homologous, whereas flanking sequences share no homology. The functional roles of AOX1 and AOX2 in the metabolism of methanol were examined. Studies of strains with disrupted AOX genes revealed that AOX1 was the major source of methanol-oxidizing activity in methanol-grown P. pastoris. The results of two types of experiments each suggested that the difference in AOX activity contributed by the two genes was a consequence of sequences located 5' of the protein-coding portions of the genes. First, the coding portion of AOX2 was able to functionally substitute for that of AOX1 when placed under the control of AOX1 regulatory sequences. Second, when labeled oligonucleotide probes specific for the 5' nontranslated region of each gene were used, it was apparent that the steady-state level of AOX1 mRNA was much higher than that of AOX2. Except for the difference in the amount of mRNA present, the two genes appeared to be regulated in the same manner. A physiological reason for the existence of AOX2 was sought but was not apparent.     

Differing expression patterns and evolution of the rat kininogen gene family

The present investigation using molecular cloning and sequence analysis concerns the examination of the molecular basis for different expression patterns of two types of the rat kininogen genes. We show that the low molecular weight and high molecular weight forms of K kininogens are produced from a single gene through alternative usage of two 3'-coding regions, whereas only the low molecular weight forms of T kininogens are generated as a result of several mutational changes in the high molecular weight-specifying regions of both T-I and T-II kininogen genes. The mutational changes include a nucleotide substitution at the polyadenylation/processing signal site, nucleotide deletions resulting in the frame-shift mutation, and an insertion of the type 2 Alu-equivalent sequence. Because kininogens represent a multifunctional protein comprising the proteinase-inhibitory activity, the kinin moiety, and the clotting activity, these results present evidence indicating the molecular basis for the disappearance of a part of the gene functions. We also show that the K and T kininogen genes as well as the two T kininogen genes are extremely homologous, excluding and including the above mutational changes, respectively. These structural relationships allow us to envisage evolutionary processes for the generation of the rat kininogen gene family, particularly for the disappearance of a part of the gene functions.