Voltage-gated H + channels associated with human phagocyte superoxide-generating NADPH oxidases: Sequence comparisons,structural predictions,and phylogenetic analyses

The N-terminal domain of the human phagocyte flavocytochrome b 558 NADPH oxidase, gp91 phox, is believed to be a heme-containing voltage-gated H + channel. The authors have conducted structural, sequence and phylogenetic analyses of the putative transmembrane channel/heme-binding domains of all homologous proteins in the NCBI GenBank database as of May 2001, as well as of the full-length proteins. Fifty-six homologues were identified, including 26 from animals, 19 from plants, seven from yeast, one from a slime mould and three from bacteria. Six well-defined sub-families were revealed by phylogenetic tree construction, two consisting of animal proteins, two of plant proteins, and one each of yeast and bacterial homologues, with the slime mould protein clustering loosely with one of the animal clusters. Signature sequences for the entire family as well as for the sub-families were determined. Most proteins have six putative TMSs, four of which may comprise the heme-binding H + channel. The hydrophobic and amphipathic characteristics of each of the putative &#102 -helical transmembrane segments were defined, and conserved residues that may be involved in heme binding, channel formation, and/or conformational changes were identified. The analyses lead to the suggestion that the oxidase domain became associated with the channel/heme-binding domain to form a single polypeptide chain early in evolutionary history, before eukaryotes diverged from prokaryotes, and that genetic transmission to present day organisms occurred primarily by vertical descent.     

The YedZ family: possible heme binding proteins that can be fused to transporters and electron carriers

YedZ of Escherichia coli is an integral 6 transmembrane spanning (TMS) protein of unknown function. We have identified homologues of YedZ in bacteria and animals but could not find homologues in Archaea or the other eukaryotic kingdoms. YedZ homologues exhibit conserved histidyl residues in their transmembrane domains that may function in heme binding. Some of the homologues encoded in the genomes of magnetotactic bacteria and cyanobacteria have YedZ domains fused to transport and electron transfer proteins, respectively. One of the animal homologues is the 6 TMS epithelial plasma membrane antigen of the prostate (STAMP1) that is overexpressed in prostate cancer. Animal homologues have YedZ domains fused C-terminal to homologues of coenzyme F420-dependent NADP oxidoreductases. YedZ homologues are shown to have arisen by intragenic triplication of a 2 TMS-encoding element. They exhibit slight but statistically significant sequence similarity to two families of putative heme export systems and one family of cytochrome-containing electron carriers. We propose that YedZ homologues function as heme-binding proteins that can facilitate or regulate oxidoreduction, transmembrane electron flow and transport.     

A novel ubiquitous family of putative efflux transporters

We describe a novel family of putative efflux transporters (PET) found in bacteria, yeast and plants. None of the members of the PET family has been functionally characterized. The bacterial and yeast proteins display a duplicated internal repeat element consisting of an N-terminal hydrophobic sequence of about 170 residues, exhibiting six putative transmembrane alpha-helical spanners (TMSs), followed by a large (230 residue), C-terminal, hydrophilic, cytoplasmic domain. The plant proteins exhibit only one such unit, but they have a larger C-terminal cytoplasmic domain. Arabidopsis thaliana encodes at least seven paralogues of the PET family. The gram-negative bacterial proteins are sometimes encoded by genes that are found in operons that also contain genes that encode membrane fusion proteins. This fact strongly suggests that PET family proteins are efflux pumps. The sequence, topological and phylogenetic characteristics of these proteins as well as the operonic structures of their encoded genes when relevant are described.     

Characterization of the arabidopsis formin-like protein AFH1 and its interacting protein

A partial cDNA encoding an Arabidopsis thaliana FH (Formin Homology) protein (AFH1) was used as a probe to clone a full length AFH1 cDNA. The deduced protein encoded by the cDNA contains a FH1 domain rich in proline residues and a C-terminal FH2 domain which is highly conserved amongst FH proteins. In contrast to FH proteins of other organisms, the predicted AFH1 protein also contains a putative signal peptide and a transmembrane domain suggesting its association with membrane. Cell fractionation by differential centrifugation demonstrated the presence of AFH1 in the Triton X-100 insoluble microsomal fraction. An Arabidopsis cDNA library was screened to identify proteins that interact with the C-terminal region of AFH1 using yeast two-hybrid assays, and one of the isolated cDNAs encoded a novel protein, FIP2. Experiments using recombinant proteins expressed in E. coli demonstrated that FIP2 interacted directly with AFH1. The amino acid sequence of FIP2 has partial homology to bacterial putative membrane proteins and animal A-type K+ ATPases. AFH1 may form a membrane anchored complex with FIP2, which might be involved in the organization of the actin cytoskeleton.     

The “+70 Pause”: Hypothesis of a Translational Control of Membrane Protein Assembly

Sequences of 66 genes encoding bacterial or yeast membrane proteins have been examined for the respective positioning of putative transmembrane domains and translational pauses. The latter were operationally defined as clusters of at least 17 non-preferred codons along the mRNA. The putative transmembrane domains were defined as stretches of at least 17 hydrophobic amino acids in the encoded protein. For yeast non-mitochon drial membrane proteins, it was observed that clusters of non-preferred codons occur more frequently about 56 to 75 codons after a hydrophobic stretch in the encoded protein. About 40 amino acid residues are required to span the large ribosomal subunit. Such clusters were thus predicted to cause a severe slow-down in peptide elongation, just when the hydrophobic stretch fully protrudes from the ribosome. This transient slow-down of the ribosome pace has consequently been named the “+70 pause”. This pause was not observed for mitochondrial or bacterial membrane proteins, which are thought to insert post-translationally in their respective membranes. Because insertion of yeast proteins in the endoplasmic reticulum membrane is generally cotranslational instead, it is possible that the “+70 pause” reflects the coupling of translation, targeting, insertion and folding in this case. The pause may, for instance, give time for productive interaction of the newly synthesized hydrophobic domain with the proper targeting/insertion machineries. Thus, it would favor entrance of the stalled protein domain into the proper pathway.     

Homologues of archaeal rhodopsins in plants, animals and fungi: structural and functional predications for a putative fungal chaperone protein

The microbial rhodopsins (MR) are homologous to putative chaperone and retinal-binding proteins of fungi. These proteins comprise a coherent family that we have termed the MR family. We have used modeling techniques to predict the structure of one of the putative yeast chaperone proteins, YRO2, based on homology with bacteriorhodopsins (BR). Availability of the structure allowed depiction of conserved residues that are likely to be of functional significance. The results lead us to predict an extracellular protein folding function and a transmembrane proton transport pathway. We suggest that protein folding is energized by a novel mechanism involving the proton motive force. We further show that MR family proteins are distantly related to a family of fungal, animal and plant proteins that include the human lysosomal cystine transporter (LCT) of man (cystinosin), mutations in which cause cystinosis. Sequence and phylogenetic analyses of both the MR family and the LCT family are reported. Proteins in both families are of the same approximate size, exhibit seven putative transmembrane alpha-helical spanners (TMSs) and show limited sequence similarity. We show that the LCT family arose by an internal gene duplication event and that TMSs 1-3 are homologous to TMSs 5-7. Although the same could not be demonstrated statistically for MR family members, homology with the LCT family suggests (but does not prove) a common evolutionary pathway. Thus, TMSs 1-3 and 5-7 in both LCT and MR family members may share a common origin, accounting for their shared structural features.     

Characterization of a protein of the plastid inner envelope having homology to animal inorganic phosphate,chloride and organic-anion transporters

A protein from Arabidopsis thaliana (L.) Heynh. showing homology to animal proteins of the NaPi-1 family, involved in the transport of inorganic phosphate, chloride, glutamate and sialic acid, has been characterized. This protein, named ANTR2 (for anion transporters) was shown by chloroplast subfractionation to be localized to the plastid inner envelope in both A. thaliana and Spinacia oleracea (L.). Immunolocalization revealed that ANTR2 was expressed in the leaf mesophyll cells as well as in the developing embryo at the upturned-U stage. Five additional homologues of ANTR2 are found in the Arabidopsis genome, of which one was shown by green fluorescent protein (GFP) fusion to be also located in the chloroplast. All ANTR proteins share homology to the animal NaPi-1 family, as well as to other organic-anion transporters that are members of the Anion:Cation Symporter (ACS) family, and share the main features of transporters from this family, including the presence of 12 putative transmembrane domains and of a 7-amino acid motif in the fourth putative transmembrane domain. ANTR2 thus represent a novel protein of the plastid inner envelope that is likely to be involved in anion transport.Abbreviations ACS Anion:Cation Symporter - GFP green fluorescent protein - Pi inorganic phosphate     

Unusual Membrane-Associated Protein Kinases in Higher Plants

Plant genomes encode a variety of protein kinases, and while some are functional homologues of animal and fungal kinases, others have a novel structure. This review focuses on three groups of unusual membrane-associated plant protein kinases: receptor-like protein kinases (RLKs), calcium-dependent protein kinases (CDPKs), and histidine protein kinases. Animal RLKs have a putative extracellular domain, a single transmembrane domain, and a protein kinase domain. In plants, all of the RLKs identified thus far have serine/threonine signature sequences, rather than the tyrosine-specific signature sequences common to animals. Recent genetic experiments reveal that some of these plant kinases function in development and pathogen resistance. The CDPKs of plants and protozoans are composed of a single polypeptide with a protein kinase domain fused to a C-terminal calmodulin-like domain containing four calcium-binding EF hands. No functional plant homologues of protein kinase C or Ca²⁺/calmodulin-dependent protein kinase have been identified, and no animal or fungal CDPK homologues have been identified. Recently, histidine kinases have been shown to participate in signaling pathways in plants and fungi. ETR1, an Arabidopsis histidine kinase homologue with three transmembrane domains, functions as a receptor for the plant hormone ethylene. G-protein-coupled receptors, which often serve as hormone receptors in animal systems, have not yet been identified in plants. Received: 18 August 1997/Revised: 23 December 1997     

Localization of Sed5, a putative vesicle targeting molecule, to the cis- Golgi network involves both its transmembrane and cytoplasmic domains

The yeast Sed5 protein, which is required for vesicular transport between ER and Golgi complex, is a membrane protein of the syntaxin family. These proteins are thought to provide the specific targets that are recognized by transport vesicles. We have investigated the mechanism by which Sed5 protein is itself localized. Expression of epitope-tagged versions of the yeast, Drosophila and rat Sed5 homologues in COS cells results in a perinuclear distribution; immuno- EM reveals that the majority of the protein is in a tubulo-vesicular compartment on the cis side of the Golgi apparatus. A similar distribution was obtained with a chimeric molecule consisting of a plasma membrane syntaxin with the Drosophila Sed5 transmembrane domain. This indicates that the membrane-spanning domain contains targeting information, as is the case with resident Golgi enzymes. However, alterations to the transmembrane domain of Drosophila Sed5 itself did not result in its mistargeting, implying that an additional targeting mechanism exists which involves only the cytoplasmic part of the protein. This was confirmed by modifying the transmembrane domain of the yeast Sed5 protein: substitution with the corresponding region from the Sso1 protein (a plasma membrane syntaxin homologue) did not affect yeast Sed5 function in vivo.     

The Arabidopsis thaliana ABC protein superfamily, a complete inventory

We describe the first complete inventory of ATP-binding cassette (ABC) proteins from a multicellular organism, the model plant Arabidopsis thaliana. By the application of several search criteria, Arabidopsis was found to contain a total of 129 open reading frames (ORFs) capable of encoding ABC proteins, of which 103 possessed contiguous transmembrane spans and were identified as putative intrinsic membrane proteins. Fifty-two of the putative intrinsic membrane proteins contained at least two transmembrane domains (TMDs) and two nucleotide-binding folds (NBFs) and could be classified as belonging to one of five subfamilies of full-molecule transporters. The other 51 putative membrane proteins, all of which were half-molecule transporters, fell into five subfamilies. Of the remaining ORFs identified, all of which encoded proteins lacking TMDs, 11 could be classified into three subfamilies. There were no obvious homologs in other organisms for 15 of the ORFs which encoded a heterogeneous group of non-intrinsic ABC proteins (NAPs). Unrooted phylogenetic analyses substantiated the subfamily designations. Notable features of the Arabidopsis ABC superfamily was the presence of a large yeast-like PDR subfamily, and the absence of genes encoding bona fide cystic fibrosis transmembrane conductance regulator (CFTR), sulfonylurea receptor (SUR), and heavy metal tolerance factor 1 (HMT1) homologs. Arabidopsis was unusual in its large allocation of ORFs (a minimum of 0.5%) to members of the ABC protein superfamily.     

Intracellular catalysis of disulfide bond formation by the human sulfhydryl oxidase, QSOX1

The discovery that the flavoprotein oxidase, Erv2p, provides oxidizing potential for disulfide bond formation in yeast, has led to investigations into the roles of the mammalian homologues of this protein. Mammalian homologues of Erv2p include QSOX (sulfhydryl oxidases) from human lung fibroblasts, guinea-pig endometrial cells and rat seminal vesicles. In the present study we show that, when expressed in mammalian cells, the longer version of human QSOX1 protein (hQSOX1a) is a transmembrane protein localized primarily to the Golgi apparatus. We also present the first evidence showing that hQSOX1a can act in vivo as an oxidase. Overexpression of hQSOX1a suppresses the lethality of a complete deletion of ERO1 (endoplasmic reticulum oxidase 1) in yeast and restores disulfide bond formation, as assayed by the folding of the secretory protein carboxypeptidase Y.     

ADM-1, a protein with metalloprotease- and disintegrin-like domains, is expressed in syncytial organs, sperm, and sheath cells of sensory organs in Caenorhabditis elegans.

A search was carried out for homologues of possible fusogenic proteins to study their function in a genetically tractable animal. The isolation, molecular, and cellular characterization of the Caenorhabditis elegans adm-1 gene (a disintegrin and metalloprotease domain) are described. A glycoprotein analogous to viral fusion proteins has been identified on the surface of guinea pig sperm (PH-30/fertilin) and is implicated in sperm-egg fusion. adm-1 is the first reported invertebrate gene related to PH-30 and a family of proteins containing snake venom disintegrin- and metalloprotease-like domains. ADM-1 shows a domain organization identical to PH-30. It contains prepro, metalloprotease, disintegrin, cysteine rich with putative fusion peptide, epidermal growth factor-like repeat, transmembrane, and cytoplasmic domains. Antibodies which recognize ADM-1 protein in immunoblots were generated. Using immunofluorescence and in situ hybridization, the products of adm-1 have been detected in specific cells during different stages of development. The localization of ADM-1 to the plasma membrane of embryonic cells and to the sheath cells of sensory organs suggests a function in cell adhesion. ADM-1 expression in the hypodermis, pharynx, vulva, and mature sperm is consistent with a putative role in somatic and gamete cell fusions.     

Phylogeny, sequence conservation, and functional complementation of the SBDS protein family

The Shwachman-Bodian-Diamond syndrome (SBDS) protein family occurs widely in nature, although its function has not been determined. Comprehensive database searches revealed SBDS homologues from 159 species, including examples from all sequenced archaeal and eukaryotic genomes and all eukaryotic kingdoms. Sequence alignment with ClustalX and MUSCLE algorithms led to the identification of conserved residues that occurred predominantly in the amino-terminal FYSH domain where they appeared to contribute to protein folding or stability. Only SBDS residue Gly91 was invariant in all species. Four distantly related protists were found to have two divergent SBDS genes in their genomes. In each case, phylogenetic analyses and the identification of shared sequence features suggested that one gene was derived from lateral gene transfer. We also identified a shared C-terminal zinc finger domain fusion in flowering plants and chromalveolates that may shed light on the function of the protein family and the evolutionary histories of these kingdoms. To assess the extent of SBDS functional conservation, we carried out complementation studies of SBDS homologues and interspecies chimeras in Saccharomyces cerevisiae. We determined that the FYSH domain was widely interchangeable among eukaryotes, while domain 2 imparted species specificity to protein function. Domain 3 was largely dispensable for function in our yeast complementation assay. Overall, the phylogeny of SBDS was shared with a group of proteins that were markedly enriched for RNA metabolism and/or ribosome-associated functions. These findings link Shwachman-Diamond syndrome to other bone marrow failure syndromes with defects in nucleolus-associated processes, including Diamond-Blackfan anemia, cartilage-hair hypoplasia, and dyskeratosis congenita.     

Functional analysis of skunk cabbage SfUCPB, a unique uncoupling protein lacking the fifth transmembrane domain, in yeast cells

Skunk cabbage, Symplocarpus foetidus, expresses two uncoupling proteins (UCPs), termed SfUCPA and SfUCPB, in the thermogenic organ spadix. SfUCPB exhibits unique structural features characterized by the absence of the putative fifth transmembrane domain (TM5) observed in SfUCPA, which is structurally similar to UCP1, and is abundantly expressed in the thermogenic spadix. Here, we conducted a series of comparative analyses of UCPs with six transmembrane domains, SfUCPA and rat UCP1, and TM5-deficient SfUCPB, using a heterologous yeast expression system. All UCPs were successfully expressed and targeted to the mitochondria, although the expression level of SfUCPB protein was approximately 10% of rat UCP1. The growth rate, mitochondrial membrane potential, and ATP content were significantly lower in cells expressing SfUCPB than in those expressing rat UCP1 and SfUCPA. These results suggest that SfUCPB, a novel TM5-deficient UCP, acts as an uncoupling protein in yeast cells.     

Identification and characterization of a putative C. elegans potassium channel gene (Ce-slo-2) distantly related to Ca(2+)-activated K(+) channels

Two putative homologues of large conductance Ca(2+)-activated K(+) channel alpha-subunit gene (slowpoke or slo) were revealed by C. elegans genome sequencing. One of the two genes, F08B12.3 (Ce-slo-2), shows a relatively low amino acid sequence similarity to other Slo sequences and lacks key functional motifs, which are important for calcium and voltage sensing. However, its overall structure and regions of homology, which are conserved in all Slo proteins, suggest that Ce-SLO-2 should belong to the Slo channel family. We have cloned a full-length cDNA of the Ce-slo-2, which encodes a protein containing six putative transmembrane segments with a K(+)-selective pore and a large C-terminal cytosolic domain. Green fluorescent protein (GFP) and whole-mount immunostaining analyses revealed that Ce-slo-2 is specifically expressed in neuronal cells at the nerve ring, at the ventral nerve cord of the mid-body, and at the tail region. We have also identified a putative human counterpart of Ce-slo-2 from a human brain EST database, which shows a stretch of highly conserved amino acid residues. Northern blot and mRNA dot blot analyses revealed a strong and specific expression in brain and skeletal muscle. Taken together, our data suggest that Ce-slo-2 may constitute an evolutionarily conserved gene encoding a potassium channel that has specific functions in neuronal cells.     

A yeast DnaJ homologue, Scj1p, can function in the endoplasmic reticulum with BiP/Kar2p via a conserved domain that specifies interactions with Hsp70s

Eukaryotic cells contain multiple Hsp70 proteins and DnaJ homologues. The partnership between a given Hsp70 and its interacting DnaJ could, in principle, be determined by their cellular colocalization or by specific protein-protein interactions. The yeast SCJ1 gene encodes one of several homologues of the bacterial chaperone DnaJ. We show that Scj1p is located in the lumen of the endoplasmic reticulum (ER), where it can function with Kar2p (the ER-lumenal BiP/Hsp70 of yeast). The region common to all DnaJ homologues (termed the J domain) from Scj1p can be swapped for a similar region in Sec63p, which is known to interact with Kar2p in the ER lumen, to form a functional transmembrane protein component of the secretory machinery. Thus, Kar2p can interact with two different DnaJ proteins. On the other hand, J domains from two other non-ER DnaJs, Sis1p and Mdj1p, do not function when swapped into Sec63p. However, only three amino acid changes in the Sis1p J domain render the Sec63 fusion protein fully functional in the ER lumen. These results indicate that the choice of an Hsp70 partner by a given DnaJ homologue is specified by the J domain.     

Bioinformatics of the TULIP domain superfamily

Proteins of the BPI (bactericidal/permeability-increasing protein)-like family contain either one or two tandem copies of a fold that usually provides a tubular cavity for the binding of lipids. Bioinformatic analyses show that, in addition to its known members, which include BPI, LBP [LPS (lipopolysaccharide)-binding protein)], CETP (cholesteryl ester-transfer protein), PLTP (phospholipid-transfer protein) and PLUNC (palate, lung and nasal epithelium clone) protein, this family also includes other, more divergent groups containing hypothetical proteins from fungi, nematodes and deep-branching unicellular eukaryotes. More distantly, BPI-like proteins are related to a family of arthropod proteins that includes hormone-binding proteins (Takeout-like; previously described to adopt a BPI-like fold), allergens and several groups of uncharacterized proteins. At even greater evolutionary distance, BPI-like proteins are homologous with the SMP (synaptotagmin-like, mitochondrial and lipid-binding protein) domains, which are found in proteins associated with eukaryotic membrane processes. In particular, SMP domain-containing proteins of yeast form the ERMES [ER (endoplasmic reticulum)-mitochondria encounter structure], required for efficient phospholipid exchange between these organelles. This suggests that SMP domains themselves bind lipids and mediate their exchange between heterologous membranes. The most distant group of homologues we detected consists of uncharacterized animal proteins annotated as TM (transmembrane) 24. We propose to group these families together into one superfamily that we term as the TULIP (tubular lipid-binding) domain superfamily.     

Size comparisons among integral membrane transport protein homologues in bacteria, Archaea, and Eucarya

Integral membrane proteins from over 20 ubiquitous families of channels, secondary carriers, and primary active transporters were analyzed for average size differences between homologues from the three domains of life: Bacteria, Archaea, and Eucarya. The results showed that while eucaryotic homologues are consistently larger than their bacterial counterparts, archaeal homologues are significantly smaller. These size differences proved to be due primarily to variations in the sizes of hydrophilic domains localized to the N termini, the C termini, or specific loops between transmembrane alpha-helical spanners, depending on the family. Within the Eucarya domain, plant homologues proved to be substantially smaller than their animal and fungal counterparts. By contrast, extracytoplasmic receptors of ABC-type uptake systems in Archaea proved to be larger on average than those of their bacterial homologues, while cytoplasmic enzymes from different organisms exhibited little or no significant size differences. These observations presumably reflect evolutionary pressure and molecular mechanisms that must have been operative since these groups of organisms diverged from each other.     

The C-terminal C1 cassette of the N -methyl-D-aspartate receptor 1 subunit contains a bi-partite nuclear localization sequence

The N -methyl-D-aspartate receptor (NMDAR) is a multimeric transmembrane protein composed of at least two subunits. One subunit, NR1, is derived from a single gene and can be subdivided into three regions: the N-terminal extracellular domain, the transmembrane regions, and the C-terminal intracellular domain. The N-terminal domain is responsible for Mg2+ metal ion binding and channel activity, while the transmembrane domains are important for ion channel formation. The intracellular C-terminal domain is involved in regulating receptor activity and subcellular localization. Our recent experiments indicated that the intracellular C-terminal domain, when expressed independently, localizes almost exclusively in the nucleus. An examination of the amino acid sequence reveals the presence of a putative nuclear localization sequence (NLS) in the C1 cassette of the NR1 intracellular C-terminus. Using an expression vector designed to test whether a putative NLS sequence is a valid, functional NLS, we have demonstrated that a bi-partite NLS does in fact exist within the NR1-1 C-terminus. Computer algorithms identified a putative helix-loop-helix motif that spanned the C0C1 cassettes of the C-terminus. These data suggest that the NR1 subunit may represent another member of a family of transmembrane proteins that undergo intramembrane proteolysis, releasing a cytosolic peptide that is actively translocated to the nucleus leading to alterations in gene regulation.