Extracting sequence motifs and the phylogenetic features of SNARE-dependent membrane traffic

The SNARE proteins are required for membrane fusion during intracellular vesicular transport and for its specificity. Only the unique combination of SNARE proteins (cognates) can be bound and can lead to membrane fusion, although the characteristics of the possible specificity of the binding combinations encoded in the SNARE sequences have not yet been determined. We discovered by whole genome sequence analysis that sequence motifs (conserved sequences) in the SNARE motif domains for each protein group correspond to localization sites or transport pathways. We claim that these motifs reflect the specificity of the binding combinations of SNARE motif domains. Using these motifs, we could classify SNARE proteins from 48 organisms into their localization sites or transport pathways. The classification result shows that more than 10 SNARE subgroups are kingdom specific and that the SNARE paralogs involved in the plasma membrane-related transport pathways have developed greater variations in higher animals and higher plants than those involved in the endoplasmic reticulum-related transport pathways throughout eukaryotic evolution.     

Using RNA secondary structures to guide sequence motif finding towards single-stranded regions

RNA binding proteins recognize RNA targets in a sequence specific manner. Apart from the sequence, the secondary structure context of the binding site also affects the binding affinity. Binding sites are often located in single-stranded RNA regions and it was shown that the sequestration of a binding motif in a double-strand abolishes protein binding. Thus, it is desirable to include knowledge about RNA secondary structures when searching for the binding motif of a protein. We present the approach MEMERIS for searching sequence motifs in a set of RNA sequences and simultaneously integrating information about secondary structures. To abstract from specific structural elements, we precompute position-specific values measuring the single-strandedness of all substrings of an RNA sequence. These values are used as prior knowledge about the motif starts to guide the motif search. Extensive tests with artificial and biological data demonstrate that MEMERIS is able to identify motifs in single-stranded regions even if a stronger motif located in double-strand parts exists. The discovered motif occurrences in biological datasets mostly coincide with known protein-binding sites. This algorithm can be used for finding the binding motif of single-stranded RNA-binding proteins in SELEX or other biological sequence data.     

Retinoblastoma Protein Contains a C-terminal Motif That Targets It for Phosphorylation by Cyclin-cdk Complexes

Stable association of certain proteins, such as E2F1 and p21, with cyclin-cdk2 complexes is dependent upon a conserved cyclin-cdk2 binding motif that contains the core sequence ZRXL, where Z and X are usually basic. In vitro phosphorylation of the retinoblastoma tumor suppressor protein, pRB, by cyclin A-cdk2 and cyclin E-cdk2 was inhibited by a short peptide spanning the cyclin-cdk2 binding motif present in E2F1. Examination of the pRB C terminus revealed that it contained sequence elements related to ZRXL. Site-directed mutagenesis of one of these sequences, beginning at residue 870, impaired the phosphorylation of pRB in vitro. A synthetic peptide spanning this sequence also inhibited the phosphorylation of pRB in vitro. pRB C-terminal truncation mutants lacking this sequence were hypophosphorylated in vitro and in vivo despite the presence of intact cyclin-cdk phosphoacceptor sites. Phosphorylation of such mutants was restored by fusion to the ZRXL-like motif derived from pRB or to the ZRXL motifs from E2F1 or p21. Phospho-site-specific antibodies revealed that certain phosphoacceptor sites strictly required a C-terminal ZRXL motif whereas at least one site did not. Furthermore, this residual phosphorylation was sufficient to inactivate pRB in vivo, implying that there are additional mechanisms for directing cyclin-cdk complexes to pRB. Thus, the C terminus of pRB contains a cyclin-cdk interaction motif of the type found in E2F1 and p21 that enables it to be recognized and phosphorylated by cyclin-cdk complexes.     

Sequence motif in control regions of the H+/K+ ATPase alpha and beta subunit genes recognized by gastric specific nuclear protein(s).

A nuclear protein(s) from rat or pig stomach recognized a conserved sequence in the 5'-upstream regions of the rat and human H+/K(+)-ATPase alpha subunit genes. A gel retardation assay suggested that part of the binding site was located in the TAATCAGCTG sequence. No nuclear proteins capable of the binding could be detected in other tissues of rat (liver, brain, kidney, spleen and lung) or pig liver. The sequence motif (GATAGC) located 5'-upstream of the beta-subunit gene also seemed to be recognized by the same protein, because the binding of nuclear protein to the sequence motifs in the alpha and beta subunits was mutually competitive. Considering the sense-strand sequence of the binding motif in the alpha-subunit gene, we conclude that (G/C)PuPu(G/C)NGAT(A/T)PuPy is a core sequence motif for the gastric specific DNA binding protein (PCSF, parietal cell specific factor).     

Molecular model for DNA recognition by the family of basic-helix-loop-helix-zipper proteins.

The basic-helix-loop-helix-zipper (bHLH-Zip) motif is a conserved region of approximately 70 amino acids that mediates both sequence-specific DNA binding and protein dimerization. This motif is found in protein sequences from many eukaryotic organisms and is contained in the protein sequence of the oncogene myc and its partner max, and a shortened version of the motif (bHLH) is found in the muscle determination factor myoD and its partner E12. An evaluation of the conserved amino acids that define the motif coupled with the published mutagenic studies of this region has led to our formulation of a molecular model for the binding of this motif as a dimer to specific sequences of DNA. This model has the dimeric protein interacting with an abutted, dyad-symmetric DNA sequence. Helix 2 of each monomer is modeled as a coiled-coil extension of the C-terminal "leucine zipper." Helix 1 does not interact with helix 1 from its partner in the dimer but with the hydrophobic surface created when the helix 2 regions of the dimer interact with each other as a coiled-coil. Sequence-specific interactions are proposed between the basic region and the invariant cis elements that all bHLH-Zip proteins bind.     

Four distinct nuclear proteins recognize in vitro the proximal promoter of the bean seed storage protein β-phaseolin gene conferring spatial and temporal control

A proximal promoter (-422/-13) of the bean seed storage protein beta-phaseolin gene contains cis-regulatory elements conferring spatial and temporal gene regulation. To correlate trans-acting elements with these cis-elements, we performed gel mobility shift and exonuclease III protection assays using bean seed nuclear proteins, and identified target sequences of four DNA-binding proteins associated with this promoter. Three CANNTG motifs, CACGTG (-248/-243), CACCTG (-163/-158), and CATATG (-100/-95), were determined as target sequences of the same DNA-binding protein designated CAN. Competition assays using oligonucleotides containing the wild-type or mutated CANNTG motif indicated that the CANNTG motif appears to be a preferred target sequence for CAN binding. Competition assays also demonstrated that DNA-binding protein AG-1 binds to AAAAAG(A/G)CAA (-356/-347, -191/-182), CA-1 binds to two CA-rich sequences (-201/-192, -175/-160), and that a TATA-box binding protein binds to either TATATAA (-43/-37) or TATAAA (-32/-27) or both. Based on these and other results, it is proposed that CACGTG motif (-248/-243) is a major cis-acting regulatory element conferring spatial and temporal control of the beta-phaseolin gene.     

Do eukaryotic mRNA 5' noncoding sequences base-pair with the 18 S ribosomal RNA 3' terminus?

Protein synthesis initiation on prokaryotic mRNAs involves base-pairing of a site preceding the initiation codon with the 3' terminal sequence of 16 S rRNA. It has been suggested that a similar situation may prevail in eukaryotic mRNAs. This suggestion is not based on experiments, but on observation of complementarities between mRNA 5' noncoding sequences and a conserved sequence near the 18 S rRNA 3' terminus. The hypothesis can be evaluated by comparing the number of potential binding sites found in the 5' noncoding sequences with the number of such sites expected to occur by chance. A method for computing this number is presented. The 5' noncoding sequences contain more binding sites than expected for a random RNA chain, but the same is true for 3' noncoding sequences. The effect can be traced to a clustering of purines and pyrimidines, common to noncoding sequences. In conclusion, a close inspection of the available mRNA sequences does not reveal any indication of a specific base-pairing ability between their 5' noncoding segments and the 18 S rRNA 3' terminus.     

A protein target site in an early replicated human DNA sequence: a highly conserved binding motif

We have previously reported that a human nuclear factor, probably corresponding to the USF/MLTF protein [1,2], is able to bind specifically to a DNA sequence present in DNA replicated at the onset of S-phase [3]. Here we demonstrate that the same factor binds also to several other similar sequences, present in eukaryotic and viral genomes. Mutations or methylation in a CpG dinucleotide, central in the palindromic binding site, completely abolish binding. Furthermore, we present evidence for the existence of at least two other nuclear proteins in human cells with the same DNA binding specificity. The data presented suggest a strong evolutionary conservation, among distantly related organisms, of the binding motif, which is probably the target of a number of nuclear factors that share the same DNA binding specificity albeit in the context of different functions.     

Sequence requirements for RNA binding by HuR and AUF1

The stability of RNAs bearing AU-rich elements in their 3'-UTRs, and thus the level of expression of their protein products, is regulated by interactions with cytoplasmic RNA-binding proteins. Binding by HuR generally leads to mRNA stabilization and increased protein production, whereas binding by AUF1 isoforms generally lead to rapid degradation of the mRNA and reduced protein production. The exact nature of the interplay between these and other RNA-binding proteins remains unclear, although recent studies have shown close interactions between them and even suggested competition between the two for binding to their cognate recognition sequences. Other recent reports have suggested that the sequences recognized by the two proteins are different. We therefore performed a detailed in vitro analysis of the binding site(s) for HuR and AUF1 present in androgen receptor mRNA to define their exact target sequences, and show that the same sequence is contacted by both proteins. Furthermore, we analysed a proposed HuR target within the 3'-UTR of MTA1 mRNA, and show that the contacted bases lie outside of the postulated motif and are a better match to a classical ARE than the postulated motif. The defining features of these HuR binding sites are their U-richness and single strandedness.     

Isolation and sequencing of NOP1. A yeast gene encoding a nucleolar protein homologous to a human autoimmune antigen

We have identified the gene for the yeast nucleolar protein p38 and deduced the primary structure of p38 from its sequence. We propose the name NOP1 (nucleolar protein 1) for this gene. NOP1 encodes a 327 amino acid protein of 34,470 daltons and is flanked by potential promoter and polyadenylation sequences. Blot analyses indicate that the mRNA transcribed from NOP1 is approximately 1.3 kilobases in size and that there is one NOP1 gene per haploid genome. The amino-terminal sequence of p38 is homologous with the 31 known amino-terminal residues of the autoimmune antigen fibrillarin, confirming the previously observed similarity between p38 and this mammalian nucleolar protein. Consistent with this, p38 cross-reacts with serum from a patient with the autoimmune disease scleroderma. A putative nuclear localization signal can be identified in p38. Interestingly, a repetitive amino acid sequence motif begins near the amino terminus of p38. This motif is approximately 80 residues long, is rich in glycine and arginine, and shows striking sequence homology to mammalian nucleolins and certain nucleic acid binding proteins.