Novel SnoRNAs from Naja naja atra (Taiwan cobra) and Bungarus multicinctus (Taiwan banded krait), form extended sequence complementarity to 5S rRNA

Molecular evolution of toxin genes in Elapidae snakes

The venom of the sea krait, Laticauda semifasciata, consists primarily of two toxic proteins, phospholipase A(2) (PLA(2)) and a three-finger-structure toxin. We have cloned both toxic protein genes, including the upstream region. PLA(2) genes contain three types of inserted sequences: an AG-rich region, a chicken repeat 1-like long interspersed nucleotide element sequence and an intron II 3' side repeat sequence. The molecular divergence of L. semifasciata PLA(2) genes was defined on the basis of the inserted sequences and their sequence homology. The length of intron I in the three-finger-structure toxin genes differs from species to species. The alignment analysis of intron I of the three-finger-structure toxin genes revealed that the intron I sequence of the ancestral gene comprised ten genetic regions. A hypothetical evolutionary process for the three-finger-structure toxin genes has also been developed.

Differential expression of human 5S snoRNA genes

Four novel small nucleolar RNAs (snoRNAs), h5sn1, h5sn2, h5sn3, and h5sn4, were successfully amplified from human total RNAs using RT-PCR. They exhibited the structural hallmarks of box H/ACA snoRNAs and formed sequence complementarity to 5S rRNA. The nucleotide sequences of the snoRNAs from different donors were highly conserved as evidenced by single-stranded conformational polymorphism and direct nucleotide sequence analysis. Although their host genes had no protein-coding potential, the expression of the snoRNAs was differentially displayed in different tissues. Noticeably, h5sn2 was highly expressed in normal brain, but its expression drastically decreased in meningioma. This opens the fascinating possibility of the relationship between the processing of snoRNAs and carcinogenesis.

Postsynaptic α-Neurotoxin Gene of the Spitting Cobra, Naja naja sputatrix: Structure, Organization, and Phylogenetic Analysis

The venom of the spitting cobra, Naja naja sputatrixcontains highly potent α-neurotoxins (NTXs) in addition to phospholipase A2 (PLA2) and cardiotoxin (CTX). In this study, we report the complete characterization of three genes that are responsible for the synthesis of three isoforms of α-NTX in the venom of a single spitting cobra. DNA amplification by long-distance polymerase chain reaction (LD-PCR) and genome walking have provided information on the gene structure including their promoter and 5′ and 3′ UTRs. Each NTX isoform is ∼4 kb in size and contains three exons and two introns. The sequence homology among these isoforms was found to be 99%. Two possible transcription sites were identified by primer extension analysis and they corresponded to the adenine (A) nucleotide at positions +1 and −45. The promoter also contains two TATA boxes and a CCAAT box. Putative binding sites for transcriptional factors AP-2 and GATA are also present. The high percentage of similarity observed among the NTX gene isoforms of N. n. sputatrix as well as with the α-NTX and κ-NTX genes from other land snakes suggests that the NTX gene has probably evolved from a common ancestral gene.

[The genomic DNA sequences reported in this paper have been submitted to GenBank databases under accession nos. AF096999 to AF097001.]

Differentially expressed snoRNAs in Bungarus multicinctus (Taiwan banded krait)

Twenty novel snoRNAs forming extensive sequence complementarities to mature 5S rRNA were identified from Bungarus multicinctus by reverse transcription-polymerase chain reaction. It was found that the snoRNA species were differentially transcribed in different tissues as evidenced by single stranded conformational polymorphism analysis and direct nucleotide sequence analysis. Although the diversity in the sequences of snoRNAs is observed, comparison of these snoRNA genes reveals that the regions involved in binding to 5S rRNA are highly conserved and form two 12-nt-15-nt tracts of complementarity to phylogenetically invariant sequences in eukaryotic 5S rRNAs. Nevertheless, the lower conservation of box C/D or box H/ACA in these snoRNAs was observed. Likewise, the sequences in several fish and human genes forming perfect duplexes with 5S rRNA also did not highly retain these box elements. These results may infer that the box elements are dispensable for the function of snoRNA species identified in the present study. Moreover, the novel finding of the differentially expressed snoRNA variants in B. multicinctus suggests that the snoRNA genes are selectively processed in different tissues and are likely associated with tissue-specific regulation of their host gene transcripts.

Small RNA database

The small RNA database is a compilation of all the small size RNA sequences available to date, including nuclear, nucleolar, cytoplasmic and mitochondria small RNAs from eukaryotic organisms and small RNAs from prokaryotic cells as well as viruses. Currently, approximately 600 small RNA sequences are in our database. It also gives the sources of individual RNAs and their GenBank accession numbers. The small RNA database can be accessed through the WWW (World Wide Web). Our WWW URL address is: http://mbcr.bcm.tmc. edu/smallRNA/smallrna.html . The new small RNA sequences published since our last compilation are listed in this paper (Table 1).

Genomic structures of cardiotoxin 4 and cobrotoxin from Naja naja atra (Taiwan cobra)

Two genomic DNAs with the size of 2.3 kb and 2.4 kb, which were isolated from the liver of Naja naja atra (Taiwan cobra), encoded the precursors of cardiotoxin 4 and cobrotoxin, respectively. Both genes shared virtually identical overall organization with three exons separated by two introns, which were inserted in the similar positions of the gene's coding regions. Moreover, their nucleotide sequences shared approximately 84.2% identity. This result reveals the evolutionary relationship between cardiotoxin and cobrotoxin. The exon/intron structures of cardiotoxin 4 and cobrotoxin genes were similar to that reported for erabutoxin c gene, a neurotoxin genomic DNA from a sea snake (Laticauda semifasciata). However, in contrast to the finding that the intron 2 of these genes had a similar size, a notable variation with the size of intron 1 was observed (1233 bp, 1269 bp and 197 bp for cardiotoxin 4, cobrotoxin and erabutoxin c genes, respectively). The different size with intron 1 is due to the middle region at the first intron of cardiotoxin 4 and cobrotoxin genes, which encoded small nucleolar RNA (snoRNA), being absent in that of erabutoxin c gene. These results, together with the finding of the potential mobility of snoRNA genes during evolution, suggest that intron insertions or deletions of snoRNA genes occur with the evolutionary divergence of snake neurotoxins and cardiotoxins.