The Role of Plastids in the Expression of Nuclear Genes for Thylakoid Proteins Studied with Chimeric [beta]-Glucuronidase Gene Fusions

We have analyzed plastid and nuclear gene expression in tobacco seedlings using the carotenoid biosynthesis inhibitor nor-flurazon. mRNA levels for three nuclear-encoded chlorophyll-binding proteins of photosystem I and photosystem II (CAB I and II and the CP 24 apoprotein) are no longer detectable in photobleached seedlings, whereas those for other components of the thylakoid membrane (the 33- and 23-kD polypeptides and Rieske Fe/S polypeptide) accumulate to some extent. Transgenic tobacco seedlings with promoter fusions from genes for thylakoid membrane proteins exhibit a similar expression behavior: a CAB-[beta]-glucuronidase (GUS) gene fusion is not expressed in herbicide-treated seedlings, whereas PC-, FNR-, PSAF-, and ATPC-promoter fusions are expressed, although at reduced levels. All identified segments in nuclear promoters analyzed that have been shown to respond to light also respond to photodamage to the plastids. Thus, the regulatory signal pathways either merge prior to gene regulation or interact with closely neighboring cis elements. These results indicate that plastids control nuclear gene expression via different and gene-specific cis-regulatory elements and that CAB gene expression is different from the expression of the other genes tested. Finally, a plastid-directing import sequence from the maize Waxy gene is capable of directing the GUS protein into the photodamaged organelle. Therefore, plastid import seems to be functional in photobleached organelles.     

Definition of a Sequence Unique in βII Spectrin Required for Its Axon-Specific Interaction with Fodaxin (A60)

Abstract: Spectrin isotypes segregate in neurons and are differentially distributed between axons and somatodendritic compartments. Their functions in those compartments are likely to be mediated by proteins that interact selectively with one or other isotype. Fodaxin (an axon-specific protein previously termed A60) colocalizes in CNS neurons with axonal spectrin and in vitro binds brain spectrin (a mixture of αI, βI, αII, and βII polypeptides) but not erythrocyte spectrin (αI and βI). Because αII and βII spectrin polypeptides are enriched in axons, we investigated a possible binding of fodaxin to the types of spectrin found in axons. Fodaxin did not bind to isolated brain α chains. Bacterially expressed C-terminal segments 18–19 of βII spectrin bound to fodaxin and inhibited the binding of fodaxin to whole brain spectrin. By contrast, recombinant segments 18–19 of the somatodendritic βIΣ2 spectrin showed no interaction with fodaxin. Within βII, fodaxin binding activity was localized to residues 2,087–2,198, which are unique to βII and link between the end of segment 18 and the pleckstrin homology domain in segment 19. The divergent regions of sequence in segments 19 of βII and βIΣ2 are candidates to mediate the isotype-specific functions of spectrin. Fodaxin is the first protein to be described that discriminates between the unique regions of β spectrin isoforms.     

Sequence similarity between Photosystems I and II. Identification of a Photosystem I reaction center transmembrane helix that is similar to transmembrane helix IV of the D2 subunit of Photosystem II and the M subunit of the non-sulfur purple and flexible green bacteria

There are basic structural similarities between plant PS II and bacterial RCs of the Chloroflexaceae and Rhodospirillaceae. These RCs are referred to as PS II-type RCs. A similar relationship of PS I RC to PS II-type RCs has not been established. Although plant PS I and PS II RCs show structural and functional differences, they also share similarities. Therefore, the A and B polypeptides of PS I were searched for PS II D1 and D2 polypeptide-like sequences. An alignment without gaps was found between PS II-type D2/M helix IV and PS I B helix X, as well as a weaker alignment of PS II-type D1/L with PS I B helix X. No comparable alignment with PS I A was found. In the M/D2 alignment there were eight identities and some conservative substitutions in twenty nine residues. PS I B helix X appeared to contain a modified chlorophyll dimer and monomer binding site and a modified non-heme iron-quinone binding site. The conserved residue sequence was found only in RC polypeptides. The proposed chlorophyll dimer-monomer binding site was located transmembrane from the iron-sulfur cluster X binding site. The conserved residues generally are those that interact with prosthetic groups. Half of the conserved residues are located on the same side of the helix. Thus, although there are impediments to concluding firmly that PS I B helix X has a functional and evolutionary relatedness to the D2 PS II and bacterial M RC polypeptides, our analysis gives reasonable support to the idea.Abbreviation RC reaction center     

Cloning and expression of two human p70 S6 kinase polypeptides differing only at their amino termini.

Two classes of human cDNA encoding the insulin/mitogen-activated p70 S6 kinase have been isolated; the two classes differ only in the 5' region, such that the longer polypeptide (p70 S6 kinase alpha I; calculated Mr 58,946) consists of 525 amino acids, of which the last 502 residues are identical in sequence to the entire polypeptides encoded by the second cDNA (p70 S6 kinase alpha II; calculated Mr 56,153). Both p70 S6 kinase polypeptides predicted by these cDNAs are present in p70 S6 kinase purified from rat liver, and each is thus expressed in vivo. Moreover, both polypeptides are expressed from a single mRNA transcribed from the (longer) p70 S6 kinase alpha I cDNA through the utilization of different translational start sites. Although the two p70 S6 kinase polypeptides differ by only 23 amino acid residues, the slightly longer alpha I polypeptide exhibits anomalously slow mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), migrating at an apparent Mr of 90,000 probably because of the presence of six consecutive Arg residues immediately following the initiator methionine. Transient expression of p70 alpha I and alpha II S6 kinase cDNA in COS cells results in a 2.5- to 4-fold increase in overall S6 kinase activity. Upon immunoblotting, the recombinant p70 polypeptides appear as a closely spaced ladder of four to five bands between 65 and 70 kDa (alpha II) and 85 and 90 kDa (alpha I). Transfection with the alpha II cDNA yields only the smaller set of bands, while transfection with the alpha I cDNA generates both sets of bands. Mutation of Met-24 in the alpha I cDNA to Leu or Thr suppresses synthesis of the alpha II polypeptides. Only the p70 alpha I and alpha II polypeptides of slowest mobility on SDS-PAGE comigrate with the 70- and 90-kDa proteins observed in purified rat liver S6 kinase. Moreover, it is the recombinant p70 polypeptides of slowest mobility that coelute with S6 kinase activity on anion-exchange chromatography. The slower mobility and higher enzymatic activity of these p70 proteins is due to Ser/Thr phosphorylation, inasmuch as treatment with phosphatase 2A inactivates kinase activity and increases the mobility of the bands on SDS-PAGE in an okadaic acid-sensitive manner. Thus, the recombinant p70 S6 kinase undergoes multiple phosphorylation and partial activation in COS cells. Acquisition of S6 protein kinase catalytic function, however, is apparently restricted to the most extensively phosphorylated recombinant polypeptides.     

The alpha 2 beta 1 integrin cell surface collagen receptor binds to the alpha 1 (I)-CB3 peptide of collagen

We have previously shown that platelets adhere to collagen substrates via a Mg2(+)-dependent mechanism mediated by the surface glycoprotein Ia-IIa (human leukocyte very late activation protein 2, alpha 2 beta 1 integrin) complex. The adhesion is specific for collagen and is supported by collagen types I, II, III, IV, and VI. Several other members of the integrin family of adhesive protein receptors recognize discrete linear amino acid sequences within their adhesive glycoprotein ligands. Experiments with both intact platelets and with liposomes containing the purified receptor complex indicated that the alpha 2 beta 1 receptor recognized denatured type I collagen in a Mg2(+)-dependent manner. To further localize the binding site, the alpha 1 and alpha 2 chains of type I collagen were purified by gel filtration and ion exchange chromatography and tested as adhesive substrates. Both the alpha 1(I) and alpha 2(I) chains effectively supported Mg2(+)-dependent platelet adhesion. The purified alpha 1(I) collagen chain was then subjected to cleavage with cyanogen bromide, and the resultant peptides were separated by chromatography on carboxymethylcellulose. Only the alpha 1(I)-CB3 fragment supported Mg2(+)-dependent platelet adhesion. The monoclonal antibody P1H5 which recognizes an epitope on the alpha 2 subunit of the integrin receptor and which inhibits the adhesion of both intact platelets and liposomes bearing the purified receptor to collagen also inhibited platelet adhesion to the alpha 1(I)-CB3 fragment. These results indicate that the alpha 2 beta 1 receptor recognizes a sequence of amino acids present in the alpha 1(I)-CB3 fragment of type I collagen. An identical or similar sequence likely mediates binding of the receptor to other collagen polypeptides.     

Emergence of polyproline II-like structure at early stages of experimental evolution from random polypeptides

To examine whether a primordial functional protein at the early stages of evolution has structural features, we carried out experimental evolution consisting of 25 cycles (generations) of mutation and selection toward DNA-binding function using a random-sequence polypeptide of 139 amino acid residues with no secondary structure as the initial sequence. In each generation, 16 clones were sampled arbitrarily for sequence analysis, and a phylogenetic tree was constructed. Polypeptide evolution proceeded from the initial point on branch I in 2 main directions of branches II and III. The initial and 2 evolved polypeptides (one at the 24th generation on branch III and the other at the 25th generation on branch II) were purified to examine their functional and structural properties. Although binding of the initial polypeptide to the target DNA was not detected by surface plasmon resonance measurements, the 2 evolved polypeptides bound to the DNA with dissociation constants of 1.6 and 1.0 microM, respectively, indicating an increase in affinity during the experimental evolution. Circular dichroism spectra of the evolved polypeptides, but not of the initial polypeptide, showed features characteristic of the polyproline II (PPII)-like structure, a left-handed helical structure commonly found in natural proteins, suggesting that the structure emerged through the experimental evolution. The same structural feature was found in another experimental evolution toward catalytic activity. These results demonstrate that the PPII-like structure is one of the common features that could have appeared in the early evolutionary stages of primordial functional protein.     

Topological and segmental phylogenetic analyses of the anion exchanger (band 3) family of transporters

Eleven sequenced anion exchanger (AE; band 3) proteins, including five AE1, four AE2 and two AE3 proteins, comprise the anion exchanger family (AEF) of homologous proteins. Eliminating the rat and rabbit proteins that are nearly Identical to the corresponding mouse proteins, seven dissimilar members of this family were selected for study, divided into N-terminal, central and C-terminal segments (designated segments 0, 1 and 2, respectively) and analysed separately for sequence similarity and phylogenetic relatedness. Segments 0 are variable in length and sequence, are essentially lacking in some of the members of the AEF, and are not demonstrably homologous in other members of the family. All segments 1 and 2 are homologous, but they exhibit widely differing degrees of sequence divergence. Segments 2 are highly conserved in all AEF proteins. Segments 1 of the AE2 and AE3 proteins are as conserved as are segments 2, but segments 1 of the AE1 proteins have diverged from each other and from the AE2 and AE3 segments 1 much more than have segments 2 of these same proteins.

The distributions of various types of amino acid residues in the putative transmembrane helical spanners of the seven dissimilar members of the AEF, based on a modification of the 14-spanner model of Wang et al. (1994) was determined, and this distribution was compared with those of other transmembrane transport proteins of known structure (bacterial rhodopsins, outer membrane porins of Gram-negative bacteria and bacterial photosynthetic reaction centres). Anion exchangers exhibit a predominance of aromatic residues (F, W, Y) at the ends of the putative spanners and of aliphatic residues (L, I, V, M) in the centres of these spanners. This feature was also a characteristic of bacteriorhodopsins (of λ- structure) and of bacterial porins (of β-structure) but not of photosynthetic reaction centres (of a-structure). Almost all membrane-embedded charged residues in the AEF proteins occur in odd-numbered spanners, a unique characteristic of anion exchangers.     

Distinct C-terminal sequences of isozymes I and II of the human erythrocyte L-isoaspartyl/D-aspartyl protein methyltransferase

We have purified the more acidic major isozyme (II) of the human erythrocyte L-isoaspartyl/D-aspartyl methyltransferase and compared its structure to that of the previously sequenced isozyme I. These isozymes are both monomers of 25,000 molecular weight polypeptides and have similar enzymatic properties, but have isoelectric points that differ by one pH unit. Analysis of 16 tryptic peptides of isozyme II accounting for 89% of the sequence of isozyme I revealed no differences between these enzyme forms. However, analysis of a Staphylococcal V8 protease C-terminal fragment revealed that the last two residues of these proteins differed. The Trp-Lys-COOH terminus of isozyme I is replaced by a Asp-Asp-COOH terminus in isozyme II. Southern blot analysis of genomic DNA suggests that the human genome [corrected] may contain only a single gene encoding the enzyme. We propose that the distinct C-termini of isozymes I and II can arise from the generation of multiple mRNA's by alternative splicing.     

Differential binding specificities of oral streptococcal antigen I/II family adhesins for human or bacterial ligands

The antigen I/II (AgI/II) family polypeptides, ranging from 1310 to 1653 amino acid (aa) residues, are cell wall anchored adhesins expressed by most indigenous species of oral streptococci. The polypeptides interact with a wide range of host molecules, in particular salivary agglutinin glycoprotein (SAG or gp340), and with ligands on other oral bacteria. To determine the receptor recognition properties of six different AgI/II family polypeptides from strains of Streptococcus gordonii, Streptococcus intermedius and Streptococcus mutans, the genes were cloned and expressed on the surface of the surrogate host Lactococcus lactis. The S. gordonii SspA and SspB polypeptides mediated higher binding levels of L. lactis cells to surface immobilized gp340 than did S. intermedius Pas protein, or S. mutans SpaP or PAc proteins. However, the AgI/II proteins were all similar in their abilities to mediate aggregation of lactococci by fluid phase gp340. The SpaP(I) polypeptide from S. mutans Ingbritt, which was C-terminally truncated by approximately 400 aa residues, did not bind gp340. Lactococci expressing AgI/II proteins, including SpaP(I), were aggregated by a synthetic 16 aa residue peptide SRCRP2 derived from the aa repeat block sequences within gp340. In coaggregation assays, SspB from S. gordonii was unique in mediating coaggregation with only group A and group E strains of Actinomyces naeslundii. All the other AgI/II polypeptides mediated coaggregation with group C and group D strains of A. naeslundii. Analysis of chimeric protein constructs revealed that coaggregation specificity was determined by sequences within the N-terminal half of AgI/II protein. A synthetic peptide (20 aa residues), which defines a putative adhesion epitope within the C-terminal region of polypeptide, inhibited AgI/II-mediated aggregation by gp340 but did not affect coaggregation with A. naeslundii. These results suggest that different mechanisms operate in interactions of AgI/II family polypeptides with native gp340, gp340 SRCR domain peptide, and A. naeslundii. Specificity of these interactions appears to be determined by discontinuous but interacting regions of the polypeptides, thus providing flexibility in receptor recognition for streptococcal colonization of the human host.     

Deduced protein sequence of bone small proteoglycan I (biglycan) shows homology with proteoglycan II (decorin) and several nonconnective tissue proteins in a variety of species

The small proteoglycans (PG) of bone consist of two different molecular species: one containing one chondroitin sulfate chain (PG II) and the other, two chains (PG I). These two proteoglycans are found in many connective tissues and have Mr = 45,000 core proteins with clear differences in their NH2-terminal sequences. Using antisera produced against synthetic peptides derived from the human PG I and PG II NH2 termini, we have isolated several cDNA clones from a lambda gt11 expression library made against mRNA isolated from human bone-derived cells. The clones, which reacted with antisera to the PG II peptide, were sequenced and found to be identical with the PG II class of proteoglycan from human fibroblasts known as PG-40 or decorin. The clones reacting to the PG I antisera, however, had a unique sequence. The derived protein sequence of PG I showed sufficient homology with the PG II sequence (55% of the amino acids are identical, with most others involving chemically similar amino acid substitutions) to strongly suggest that the two proteins were the result of a gene duplication. PG II (decorin) contains one attached glycosaminoglycan chain, while PG I probably contains two chains. For this reason, we suggest that PG I be called biglycan. The biglycan protein sequence contains 368 residues (Mr = 42,510 for the complete sequence and Mr = 37,983 for the secreted form) that appears to consist predominantly of a series of 12 tandem repeats of 24 residues. The repeats are recognized by their conserved leucines (and leucine-like amino acids) in positions previously reported for a diverse collection of proteins (none of which is thought to be proteoglycans) including: two morphogenic proteins (toll and chaoptin) in the fruit fly; a yeast adenylate cyclase; and two human proteins, the von Willebrand Factor-binding platelet membrane protein, GPIb, and a rare serum protein, leucine-rich glycoprotein.     

Evolutionary conservation of the chlorophyll a/b-binding proteins: cDNAs encoding type I, II and III LHC I polypeptides from the gymnosperm Scots pine

Summary cDNAs encoding three different LHC I polypeptides (Type I, Type II and Type III) from the gymnosperm Scots pine (Pinus sylvestris L.) were isolated and sequenced. Comparisons of the deduced amino acid sequences with the corresponding tomato sequences showed that all three proteins were highly conserved although less so than the LHC II proteins. The similarities between mature Scots pine and tomato Types I, II and III LHC I proteins were 80%, 87% and 85%, respectively. Two of the five His residues that are found in AXXXH sequences, which have been identified as putative chlorophyll ligands in the Type I and Type II proteins, were not conserved. The same two regions of high homology between the different LHC proteins, which have been identified in tomato, were also found in the Scots pine proteins. Within the conserved regions, the Type I and Type II proteins had the highest similarity; however, the Type II and Type III proteins also showed a similarity in the central region. The results suggest that all flowering plants (gymnosperms and angiosperms) probably have the same set of LHC polypeptides. A new nomenclature for the genes encoding LHC polypeptides (formerly cab genes) is proposed. The names lha and lhb are suggested for genes encoding LHC I and LHC II proteins, respectively, analogous to the nomenclature for the genes encoding other photosynthetic proteins.     

The changing faces of Streptococcus antigen I/II polypeptide family adhesins

Streptococcus mutans antigen I/II (AgI/II) protein was one of the first cell wall‐anchored adhesins identified in Gram‐positive bacteria. It mediates attachment of S. mutans to tooth surfaces and has been a focus for immunization studies against dental caries. The AgI/II family polypeptides recognize salivary glycoproteins, and are also involved in biofilm formation, platelet aggregation, tissue invasion and immune modulation. The genes encoding AgI/II family polypeptides are found among Streptococcus species indigenous to the human mouth, as well as in Streptococcus pyogenes, S. agalactiae and S. suis. Evidence of functionalities for different regions of the AgI/II proteins has emerged. A sequence motif within the C‐terminal portion of Streptococcus gordonii SspB (AgI/II) is bound by Porphyromonas gingivalis, thus promoting oral colonization by this anaerobic pathogen. The significance of other epitopes is now clearer following resolution of regional crystal structures. A new picture emerges of the central V (variable) region, predicted to contain a carbohydrate‐binding trench, being projected from the cell surface by a stalk formed by an unusual association between an N‐terminal α‐helix and a C‐terminal polyproline helix. This presentation mode might be important in determining functional conformations of other Gram‐positive surface proteins that have adhesin domains flanked by α‐helical and proline‐rich regions.     

Super-motifs and evolution of tandem leucine-rich repeats within the small proteoglycans--biglycan, decorin, lumican, fibromodulin, PRELP, keratocan, osteoadherin, epiphycan, and osteoglycin

Leucine-rich repeats (LRRs) with 20-30 amino acids in unit length are present in many proteins from prokaryotes to eukaryotes. The LRR-containing proteins include a family of nine small proteoglycans, forming three distinct subfamilies: class I contains biglycan/PG-I and decorin/PG-II; class II: lumican, fibromodulin, PRELP, keratocan, and osteoadherin; and class III: epiphycan/PG-Lb and osteoglycin or osteoinductive factor. Comparative sequence analysis of the 34 available protein sequences reveals that these proteoglycans have two types of LRRs, which we call S and T. The type S LRR is 21 residues long and has the consensus sequence of xxaPzxLPxxLxxLxLxxNxI. The type T LRR has 26 residues; its consensus sequence is zzxxaxxxxFxxaxxLxxLxLxxNxL. In both "x" indicates variable residue; "z" is frequently a gap; "a" is Val, Leu, or Ile; and I is Ile or Leu. These type S and TLRRs are ordered into two super-motifs--STT with about 73 residues in classes I and II and ST with about 47 residues in class III. The 12 LRRs in the small proteoglycans of I and II are best represented as (STT)4; the seven LRRs of class III as (ST)T(ST)2. Our analyses indicate that classes I/II and III evolved along different paths after the establishment of the precursor ST, and classes I and II also diverged after the establishment of the precursor (STT)4.     

Structure, function and immunogenicity of streptococcal antigen I/II polypeptides

The antigen I/II family of cell-surface-anchored polypeptides in oral streptococci are structurally complex multi-functional adhesins, with multiple ligand-binding sites. Discrete regions within these polypeptides bind human salivary glycoproteins, other microbial cells, and calcium. Sequences within the N-terminal region bind preferentially fluid-phase glycoproteins, while the C-terminal half of the polypeptide contains species-specific adhesion-mediating sequences that bind surface-immobilized glycoproteins. These features may assist streptococcal adhesion to oral surface receptors despite the presence of excess fluid-phase receptors. Immunological studies reveal an array of T-cell and B-cell epitopes presented by antigen I/II polypeptides and suggest the occurrence of natural suppression of human antibodies to the adhesion-mediating sequences. The functional and immunological properties of antigen I/II proteins may account to a major extent for the success of oral streptococci colonizing and surviving within the human host.     

When the surface tells what lies beneath: combinatorial phage-display mutagenesis reveals complex networks of surface-core interactions in the pacifastin protease inhibitor family

Pacifastin protease inhibitors are small cysteine-rich motifs of approximately 35 residues that were discovered in arthropods. The family is divided into two related groups on the basis of the composition of their minimalist inner core. In group I, the core is governed by a Lys10-Trp26 interaction, while in group II it is organized around Phe10. Group I inhibitors exhibit intriguing taxon specificity: potent arthropod-trypsin inhibitors from this group are almost inactive against vertebrate enzymes. The group I member SGPI-1 and the group II member SGPI-2 are extensively studied inhibitors. SGPI-1 is taxon-selective, while SGPI-2 is not. Individual mutations failed to explain the causes underlying this difference. We deciphered this phenomenon using comprehensive combinatorial mutagenesis and phage display. We produced a complete chimeric SGPI-1 / SGPI-2 inhibitor-phage library, in which the two sequences were shuffled at the highest possible resolution of individual residues. The library was selected for binding to bovine trypsin and crayfish trypsin. Sequence analysis of the selectants revealed that taxon specificity is due to an intra-molecular functional coupling between a surface loop and the Lys10-Trp26 core. Five SGPI-2 surface residues transplanted into SGPI-1 resulted in a variant that retained the "taxon-specific" core, but potently inhibited both vertebrate and arthropod enzymes. An additional rational point mutation resulted in a picomolar inhibitor of both trypsins. Our results challenge the generally accepted view that surface residues are the exclusive source of selectivity for canonical inhibitors. Moreover, we provide important insights into general principles underlying the structure-function properties of small disulfide-rich polypeptides, molecules that exist at the borderline between peptides and proteins.     

Conformational and sequence signatures in beta helix proteins

beta helix proteins are characterized by a repetitive fold, in which the repeating unit is a beta-helical coil formed by three strand segments linked by three loop segments. Using a data set of left- and right-handed beta helix proteins, we have examined conformational features at equivalent positions in successive coils. This has provided insights into the conformational rules that the proteins employ to fold into beta helices. Left-handed beta helices attain their equilateral prism fold by incorporating "corners" with the conformational sequence P(II)-P(II)-alpha(L)-P(II), which imposes sequence restrictions, resulting in the first and third P(II) residues often being G and a small, uncharged residue (V, A, S, T, C), respectively. Right-handed beta helices feature mid-sized loops (4, 5, or 6 residues) of conserved conformation, but not of conserved sequence; they also display an alpha-helical residue at the C-terminal end of L2 loops. Backbone conformational parameters (phi,psi) that permit the formation of continuous, loopless beta helices (Perutz nanotubes) have also been investigated.     

The extended GLUT-family of sugar/polyol transport facilitators: nomenclature,sequence characteristics,and potential function of its novel members

During the last 2 years, several novel genes that encode glucose transporter-like proteins have been identified and characterized. Because of their sequence similarity with GLUT1, these genes appear to belong to the family of solute carriers 2A ( SLC2A, protein symbol GLUT). Sequence comparisons of all 13 family members allow the definition of characteristic sugar/polyol transporter signatures: (1) the presence of 12 membrane-spanning helices, (2) seven conserved glycine residues in the helices, (3) several basic and acidic residues at the intracellular surface of the proteins, (4) two conserved tryptophan residues, and (5) two conserved tyrosine residues. On the basis of sequence similarities and characteristic elements, the extended GLUTfamily can be divided intothree subfamilies, namely class I (the previously known glucose transporters GLUT1-4), class II (the previously known fructose transporter GLUT5, the GLUT7, GLUT9 and GLUT11), and class III (GLUT6, 8, 10, 12, and the myoinositol transporter HMIT1). Functional characteristics have been reported for some of the novel GLUTs. Like GLUT1-4, they exhibit a tissue/cell-specific expression (GLUT6, leukocytes, brain; GLUT8, testis, blastocysts, brain, muscle, adipocytes; GLUT9, liver, kidney; GLUT10, liver, pancreas; GLUT11, heart, skeletal muscle). GLUT6 and GLUT8 appear to be regulated by sub-cellular redistribution, because they are targeted to intracellular compartments by dileucine motifs in a dynamin dependent manner. Sugar transport has been reported for GLUT6, 8, and 11; HMIT1 has been shown to be a H + /myo-inositol co-transporter. Thus, the members of the extended GLUT family exhibit a surprisingly diverse substrate specificity, and the definition of sequence elements determining this substrate specificity will require a full functional characterization of all members.