Situation determinants of heroin consumption in opiate-dependent subjects: a psychometric approach

BACKGROUND: Chymotrypsin inhibitor 2 (CI2) is a member of the class of fast-folding small proteins, which is very suitable for testing theories of folding. CI2 folds around a diffuse extended nucleus consisting of the single alpha helix and a set of hydrophobic residues. In particular, Ala16 has been predicted and independently found to interact with Leu49 and Ile57, hydrophobic residues that are highly conserved among homologues. We have characterised in detail the interactions between these residues in the folding nucleus of the protein by using double-mutant cycles. RESULTS: Surprisingly, we find that there is some destabilising strain in the transition state for folding of the wild-type protein between Ala16 and Ile57. Further, we find that the strain is larger in the native state of the protein. This is shown directly in the unfolding kinetics, which clearly show a release of strain. The net result of this is that the presence of both residues speeds up folding. Ala16 and Leu49 interact favourably in the transition state, but have no net interaction energy in the native state. CONCLUSIONS: Part of the folding nucleus of the protein fits together more snugly in the transition state than it does in the native state. Interactions between some of the closely packed residues in the folding nucleus of CI2 may perhaps be optimised for the rate of folding and not for stability.     

Refolding rate of stability-enhanced cytochrome c is independent of thermodynamic driving force

N52I iso-2 cytochrome c is a variant of yeast iso-2 cytochrome c in which asparagine substitutes for isoleucine 52 in an alpha helical segment composed of residues 49-56. The N52I substitution results in a significant increase in both stability and cooperativity of equilibrium unfolding, and acts as a "global suppressor" of destabilizing mutations. The equilibrium m-value for denaturant-induced unfolding of N52I iso-2 increases by 30%, a surprisingly large amount for a single residue substitution. The folding/unfolding kinetics for N52I iso-2 have been measured by stopped-flow mixing and by manual mixing, and are compared to the kinetics of folding/unfolding of wild-type protein, iso-2 cytochrome c. The results show that the observable folding rate and the guanidine hydrochloride dependence of the folding rate are the same for iso-2 and N52I iso-2, despite the greater thermodynamic stability of N52I iso-2. Thus, there is no linear free-energy relationship between mutation-induced changes in stability and observable refolding rates. However, for N52I iso-2 the unfolding rate is slower and the guanidine hydrochloride dependence of the unfolding rate is smaller than for iso-2. The differences in the denaturant dependence of the unfolding rates suggest that the N52I substitution decreases the change in the solvent accessible hydrophobic surface between the native state and the transition state. Two aspects of the results are inconsistent with a two-state folding/unfolding mechanism and imply the presence of folding intermediates: (1) observable refolding rate constants calculated from the two-state mechanism by combining equilibrium data and unfolding rate measurements deviate from the observed refolding rate constants; (2) kinetically unresolved signal changes ("burst phase") are observed for both N52I iso-2 and iso-2 refolding. The "burst phase" amplitude is larger for N52I iso-2 than for iso-2, suggesting that the intermediates formed during the "burst phase" are stabilized by the N52I substitution.     

Interaction of GroEL with a highly structured folding intermediate: iterative binding cycles do not involve unfolding

The GroE proteins are molecular chaperones involved in protein folding. The general mechanism by which they facilitate folding is still enigmatic. One of the central open questions is the conformation of the GroEL-bound nonnative protein. Several suggestions have been made concerning the folding stage at which a protein can interact with GroEL. Furthermore, the possibility exists that binding of the nonnative protein to GroEL results in its unfolding. We have addressed these issues that are basic for understanding the GroE-mediated folding cycle by using folding intermediates of an Fab antibody fragment as molecular probes to define the binding properties of GroEL. We show that, in addition to binding to an early folding intermediate, GroEL is able to recognize and interact with a late quaternary-structured folding intermediate (Dc) without measurably unfolding it. Thus, the prerequisite for binding is not a certain folding stage of a nonnative protein. In contrast, general surface properties of nonnative proteins seem to be crucial for binding. Furthermore, unfolding of a highly structured intermediate does not necessarily occur upon binding to GroEL. Folding of Dc in the presence of GroEL and ATP involves cycles of binding and release. Because in this system no off-pathway reactions or kinetic traps are involved, a quantitative analysis of the reactivation kinetics observed is possible. Our results indicate that the association reaction of Dc and GroEL in the presence of ATP is rather slow, whereas in the absence of ATP association is several orders of magnitude more efficient. Therefore, it seems that ATP functions by inhibiting reassociation rather than promoting release of the bound substrate.     

The single helix in protein L is largely disrupted at the rate-limiting step in folding

To investigate the role of helix formation in the folding of protein L, a 62 residue alpha/beta protein, we studied the consequences of both single and multiple mutations in the helix on the kinetics of folding. A triple mutant with 11 additional carbon atoms in core residues in the amino-terminal portion of the helix folded substantially faster than wild type, suggesting that hydrophobic association with residues elsewhere in the protein occurs at the rate-limiting step in folding. However, helix-destabilizing mutations had little effect on the rate of folding; in particular, a triple glycine substitution on the solvent-exposed side of the helix increased the unfolding rate 56-fold while reducing the folding rate less than threefold. Thus, in contrast to the predictions of models of folding involving the coalescence of well-formed secondary structure elements, the single helix in protein L appears to be largely disrupted at the rate-limiting step in folding and unfolding.     

Protein folding and protein evolution: common folding nucleus in different subfamilies of c-type cytochromes?

Amino acid sequences of seven subfamilies of cytochromes c (mitochondrial cytochromes c, c1; chloroplast cytochromes c6, cf; bacterial cytochromes c2, c550, c551; in total 164 sequences) have been compared. Despite extensive homology within eukaryotic subfamilies, homology between different subfamilies is very weak. Other than the three heme-binding residues (Cys13, Cys14, His18, in numeration of horse cytochrome c) there are only four positions which are conserved in all subfamilies: Gly/Ala6, Phe/Tyr10, Leu/Val/Phe94 and Tyr/Trp/Phe97. In all 17 cytochromes c with known 3D-structures, these residues form a network of conserved contacts (6-94, 6-97, 10-94, 10-97 and 94-97). Especially strong is the contact between aromatic groups in positions 10 and 97, which corresponds to 13 interatomic contacts. As residues 6, 10 and residues 94, 97 are in (i, i+4) and (i, i+3) positions in the N and C-terminal helices, respectively, the above mentioned system of conserved contacts consists mainly of contacts between one turn of N-terminal helix and one turn of C-terminal helix. The importance of the contacts between interfaces of these helices has been confirmed by the existence of these contacts in both equilibrium and kinetic molten globule-like folding intermediates, as well as by mutational evidence that these contacts are involved in tight packing between the N and C-helices. Since these four residues are not involved in heme binding and have no other apparent functional role, their conservation in highly diverged cytochromes c suggests that they are of a critical importance for protein folding. The author assumes that they are involved in a common folding nucleus of all subfamilies of c-type cytochromes.     

The folding kinetics and thermodynamics of the Fyn-SH3 domain

The equilibrium unfolding and the kinetic folding and unfolding of the 67 residue Fyn-SH3 domain have been investigated. Equilibrium unfolding experiments indicate that, despite the lack of both disulfide bonds and prosthetic groups, Fyn-SH3 is relatively stable with a free energy of folding of -6.0 +/- 0.6 kcal mol-1 at 20 degrees C. Kinetic experiments indicate that the domain refolds in a rapid two-state manner without significant population of intermediates (k = 94.3 s-1 in H2O at 20 degrees C). Despite the presence of two proline residues, the refolding of the domain is monophasic, and no significant proline isomerization-like refolding phase is observed. This can be attributed to an extremely low level of the incorrect (cis) isomer of the structurally important Pro134 residue in the protein denatured in 8 M guanidine hydrochloride. Analysis of the temperature and guanidine hydrochloride dependence of the folding rate suggests that the folding transition state of this protein is relatively well organized. A comparison with the refolding kinetics and thermodynamics of other homologous SH3 domains indicates that these exhibit an equivalent degree of transition state organization. This potentially arises from conservation of key features of the transition state conformation despite sometimes relatively low overall sequence identity. Such a comparison further suggests that relative thermodynamic stability is an important factor in determining the relative folding rates of natural proteins with a common fold, but that specific details of the amino acid sequence can also play a significant role in individual cases.     

Denaturation and association of DNA sequences by certain polypropylene surfaces

UDP-galactose 4-epimerase from yeast Kluyveromyces fragilis is a dimeric molecule of 75 kDa per subunit with one molecule of cofactor NAD per dimer. It undergoes unfolding and complete dissociation in presence of 8 M urea at pH 7.0 by 10 min. It can be functionally reconstituted almost quantitatively in 2 h by dilution with 20 mM sodium phosphate buffer, pH 7 containing 1 mM extraneous NAD under a second order kinetics [Bhattacharyya, D. (1993) Biochemistry 32, 9726-9734]. Denaturation between 10-60 min inversely affects both the rate and maximum recovery of activity upon refolding. Aggregation of this protein has not been observed under these conditions. The time dependent reaction at the unfolded state is independent of pH between 5.4-10.4 but strongly dependent on temperature of denaturation between 0-20 degrees C. Unfolding at 0 degrees C divides the protein largely into two populations-34% of fast folding species following an apparent first order kinetics and 59% of slow folding species following a second order kinetics of reactivation. A very fast folding species of low abundance 3.5-7.5% depending on temperature of denaturation has been identified, which gets active status within the dead time of mixing. Interaction with the active site directed fluorescence probe 1-anilino 8-naphthalene sulfonic acid (1-ANS) and estimation of bound NAD suggest that the catalytic region of this enzyme is not formed in the long term denatured samples. The whole process of reactivation is catalysed by peptidyl prolyl cis-trans isomerase and thus suggests that one or more proline residues stereochemically control the rate limiting step of reactivation.     

Identification of a conserved hydrophobic cluster in partially folded bovine beta-lactoglobulin at pH 2

BACKGROUND: NMR studies of denatured states, both fully unfolded and partially folded, give insight into the conformations and interactions formed during folding. Although the complete structural characterization of partially folded proteins is a very difficult task, the identification of structured subsets, such as hydrophobic clusters, is of value in understanding the structural organization of such states. Here, we report the NMR characterization, in acidic conditions (pH 2), of a well-defined hydrophobic cluster localized in the core of bovine beta-lactoglobulin. RESULTS: The existence of a small hydrophobic cluster present in the lipocalin protein family has been assessed on the basis of structural alignment and NRM data obtained for the partially folded bovine beta-lactoglobulin. The presence of the cluster had been predicted identifying those residues that are highly conserved in most members of the family. An NMR study conducted at pH 2, where the protein exhibits a very stable beta-core together with disordered regions, reveals the presence of NOEs among sidechains of 11 hydrophobic residues centered around Trp19 and pointing towards the interior of the protein. This buried cluster is found to be unusually stable at pH 2, not only at room temperature but also at 323K. Furthermore, conserved hydrophobic residues pointing towards the surface of the protein define a hydrophobic surface patch located in a groove between the strands and the helix. CONCLUSIONS: The detected buried cluster most likely plays an important role in bovine beta-lactoglobulin stability. The analysis of five structurally related proteins reveals that the same extended cluster is present in these structures. We propose that the buried cluster may represent the internal binding site as well and that the hydrophobic surface patch is involved in a second external binding site.     

Definition, distribution, and use of a conserved Bovidae retroposon element sequence motif

Based on a data-base search, the sequences of 32 Bovidae retroposon elements have been compared. Two conserved areas are identified, and one of the corresponding sequences of the derived bovine consensus was used to design oligonucleotides as primer molecules for random DNA amplification of Bovidae DNA. Such a primer binding site should occur on average every 10,000 bp in the bovine genome, as suggested by a survey of published sequences. This estimate about the distribution of these possible primer binding sites was experimentally substantiated by mapping four of these primer binding sites within 40 kb of contiguous bovine DNA, carrying the heretofore undescribed bovine lactoferrin gene. Furthermore, these conserved, ubiquitous sequence motifs prove to be useful for mapping of bovine DNA.     

The pressure dependence of hydrophobic interactions is consistent with the observed pressure denaturation of proteins

Proteins can be denatured by pressures of a few hundred MPa. This finding apparently contradicts the most widely used model of protein stability, where the formation of a hydrophobic core drives protein folding. The pressure denaturation puzzle is resolved by focusing on the pressure-dependent transfer of water into the protein interior, in contrast to the transfer of nonpolar residues into water, the approach commonly taken in models of protein unfolding. Pressure denaturation of proteins can then be explained by the pressure destabilization of hydrophobic aggregates by using an information theory model of hydrophobic interactions. Pressure-denatured proteins, unlike heat-denatured proteins, retain a compact structure with water molecules penetrating their core. Activation volumes for hydrophobic contributions to protein folding and unfolding kinetics are positive. Clathrate hydrates are predicted to form by virtually the same mechanism that drives pressure denaturation of proteins.     

Human, mouse, and rat calnexin cDNA cloning: identification of potential calcium binding motifs and gene localization to human chromosome 5

Calnexin is a 90-kDa integral membrane protein of the endoplasmic reticulum (ER). Calnexin binds Ca2+ and may function as a chaperone in the transition of proteins from the ER to the outer cellular membrane. We have purified human calnexin in association with the human interferon-gamma receptor and cloned calnexin cDNA from placenta. Fragments of calnexin have been prepared as glutathione S-transferase fusion proteins and analyzed for their abilities to bind 45Ca2+ and ruthenium red. A subdomain containing four internal repeats binds Ca2+ with the highest affinity. This sequence is highly conserved when compared to calreticulin (a luminal ER protein), an Onchocerca surface antigen, and yeast and plant calnexin homologues. Consequently, this sequence represents a conserved motif for the high-affinity binding of Ca2+, which is clearly distinct from the "E-F hand" motif. An adjacent subdomain, also highly conserved and containing four internal repeats, fails to bind Ca2+. The carboxyl-terminal, cytosolic domain is highly charged and binds Ca2+ with moderate affinity, presumably by electrostatic interactions. The calnexin amino-terminal domain (residues 1-253) also binds Ca2+, in contrast to the amino-terminal domain of calreticulin, which is relatively less acidic. We have also determined the cDNA sequences of mouse and rat calnexins. Comparison of the known mammalian calnexin sequences reveals very high conservation of sequence identity (93-98%), suggesting that calnexin performs important cellular functions. The gene for human calnexin is located on the distal end of the long arm of human chromosome 5, at 5q35.     

Rat and calf thioredoxin reductase are homologous to glutathione reductase with a carboxyl-terminal elongation containing a conserved catalytically active penultimate selenocysteine residue

We have determined the sequence of 23 peptides from bovine thioredoxin reductase covering 364 amino acid residues. The result was used to identify a rat cDNA clone (2.19 kilobase pairs), which contained an open reading frame of 1496 base pairs encoding a protein with 498 residues. The bovine and rat thioredoxin reductase sequences revealed a close homology to glutathione reductase including the conserved active site sequence (Cys-Val-Asn-Val-Gly-Cys). This also confirmed the identity of a previously published putative human thioredoxin reductase cDNA clone. Moreover, one peptide of the bovine enzyme contained a selenocysteine residue in the motif Gly-Cys-SeCys-Gly (where SeCys represents selenocysteine). This motif was conserved at the carboxyl terminus of the rat and human enzymes, provided that TGA in the sequence GGC TGC TGA GGT TAA, being identical in both cDNA clones, is translated as selenocysteine and that TAA confers termination of translation. The 3'-untranslated region of both cDNA clones contained a selenocysteine insertion sequence that may form potential stem loop structures typical of eukaryotic selenocysteine insertion sequence elements required for the decoding of UGA as selenocysteine. Carboxypeptidase Y treatment of bovine thioredoxin reductase after reduction by NADPH released selenocysteine from the enzyme with a concomitant loss of enzyme activity measured as reduction of thioredoxin or 5,5'-dithiobis(2-nitrobenzoic acid). This showed that the carboxyl-terminal motif was essential for the catalytic activity of the enzyme.     

Contrasting roles for symmetrically disposed beta-turns in the folding of a small protein

To investigate the role of turns in protein folding, we have characterized the effects of combinatorial and site-directed mutations in the two beta-turns of peptostreptococcal protein L on folding thermodynamics and kinetics. Sequences of folded variants recovered from combinatorial libraries using a phase display selection method were considerably more variable in the second turn than in the first turn. These combinatorial mutants as well as strategically placed point mutants in the two turns had a similar range of thermodynamic stabilities, but strikingly different folding kinetics. A glycine to alanine substitution in the second beta-turn increased the rate of unfolding more than tenfold but had little effect on the rate of folding, while mutation of a symmetrically disposed glycine residue in the first turn had little effect on unfolding but slowed the rate of folding nearly tenfold. These results demonstrate that the role of beta-turns in protein folding is strongly context-dependent, and suggests that the first turn is formed and the second turn disrupted in the folding transition state.     

How evolution makes proteins fold quickly

Sequences of fast-folding model proteins (48 residues long on a cubic lattice) were generated by an evolution-like selection toward fast folding. We find that fast-folding proteins exhibit a specific folding mechanism in which all transition state conformations share a smaller subset of common contacts (folding nucleus). Acceleration of folding was accompanied by dramatic strengthening of interactions in the folding nucleus whereas average energy of nonnucleus interactions remained largely unchanged. Furthermore, the residues involved in the nucleus are the most conserved ones within families of evolved sequences. Our results imply that for each protein structure there is a small number of conserved positions that are key determinants of fast folding into that structure. This conjecture was tested on two protein superfamilies: the first having the classical monophosphate binding fold (CMBF; 98 families) and the second having type-III repeat fold (47 families). For each superfamily, we discovered a few positions that exhibit very strong and statistically significant "conservatism of conservatism"-amino acids in those positions are conserved within every family whereas the actual types of amino acids varied from family to family. Those amino acids are in spatial contact with each other. The experimental data of Serrano and coworkers [Lopez-Hernandez, E. & Serrano, L. (1996) Fold. Des. (London) 1, 43-55]. for one of the proteins of the CMBF superfamily (CheY) show that residues identified this way indeed belong to the folding nucleus. Further analysis revealed deep connections between nucleation in CMBF proteins and their function.     

Cold denaturation of yeast phosphoglycerate kinase: kinetics of changes in secondary structure and compactness on unfolding and refolding

Under mildly destabilizing conditions (0.7 M GuHCl), phosphoglycerate kinase from yeast undergoes a reversible two-step equilibrium unfolding transition when the temperature is lowered from 30 to 1 degree C (Griko, Y. V., Venyaminov, S. Y., & Privalov, P. L. (1989) FEBS Lett. 244, 276-278). The kinetics of the changes in compactness and secondary structure have been studied by means of dynamic light scattering and far-UV circular dichroism, respectively. It turned out that unfolding and refolding after an appropriate temperature jump (T-jump) was performed proceeded in substantially different ways. After a T-jump from 30 to 1 degree C, a multiphasic unfolding behavior was observed, reflecting the independent unfolding of the N-terminal and C-terminal domains with time constants of about 7 and 45 min, respectively. A remarkable feature of the unfolding process is the simultaneous change of compactness and secondary structure. Refolding after a T-jump from 1 degree C to higher temperatures occurs in two stages. At the first stage an appreciable amount of secondary structure is formed rapidly within the dead time of the T-jump, while the overall dimensions of the polypeptide chain remain essentially unchanged. Thus, an extended folding intermediate is formed at an early stage of folding. Further information of secondary structure proceeds slowly within a time range of minutes in parallel with the increase of compactness. At 30 degrees C, both domains refold simultaneously, while at 15 degrees C, independent folding can be observed. These findings are discussed with respect to predictions of existing models of folding.     

"Miguel F. Jiménez lecture. The paradigm of modern medicine: molecular genetics

The sequence for bovine link protein cDNA, including 108 bases of the 5' untranslated region (UTR) and 768 nucleotides of the 3' UTR, was determined from polymerase chain reaction products and bovine articular chondrocyte cDNA clones. The deduced primary structure for bovine link protein predicts a protein 354 amino acid residues in length. Comparative analysis with link protein sequence from several other species revealed overall high conservation of protein coding sequence. High nucleotide sequence conservation was observed within the extensive 5' and 3' UTRs of bovine, human, pig, chick and rat link protein mRNA. As evidence that the UTRs might play a role in regulation of link protein mRNA turnover, multiple occurrences of the adenosine-uridine binding factor motif A(Ua)A were found to be conserved between species within 3' UTRs. A polyadenylation signal was conserved between the bovine and chicken sequence, use of which would result in the smallest of multiple bovine link protein mRNA species observed by Northern blot analysis.     

The burst-phase intermediate in the refolding of beta-lactoglobulin studied by stopped-flow circular dichroism and absorption spectroscopy

The kinetics of the guanidine hydrochloride-induced unfolding and refolding of bovine beta-lactoglobulin, a predominantly beta-sheet protein in the native state, have been studied by stopped-flow circular dichroism and absorption measurements at pH 3.2 and 4.5 degrees C. The refolding reaction was a complex process composed of different kinetic phases, while the unfolding was a single-phase reaction. Most notably, a burst-phase intermediate of refolding, which was formed during the dead time of stopped-flow measurements (approximately 18 ms), showed more intense ellipticity signals in the peptide region below 240 nm than the native state, yielding overshoot behavior in the refolding curves. We have investigated the spectral properties and structural stability of the burst-phase intermediate and also the structural properties in the unfolded state in 4.0 M guanidine hydrochloride of the protein and its disulfide-cleaved derivative. The main conclusions are: (1) the more intense ellipticity of the intermediate in the peptide region arises from formation of non-native alpha-helical structure in the intermediate, apparently suggesting that the folding of beta-lactoglobulin is not represented by a simple sequential mechanism. (2) The burst-phase intermediate has, however, a number of properties in common with the folding intermediates or with the molten globule states of other globular proteins whose folding reactions are known to be represented by the sequential model. These properties include: the presence of the secondary structure without the specific tertiary structure; formation of a hydrophobic core; broad unfolding transition of the intermediate; and rapidity of formation of the intermediate. The burst-phase intermediate of beta-lactoglobulin is thus classified as the same species as the molten globule state. (3) The circular dichroism spectra of beta-lactoglobulin and its disulfide-cleaved derivative in 4.0 M guanidine hydrochloride suggests the presence of the residual beta-structure in the unfolded state and the stabilization of the beta-structure by disulfide bonds. Thus; if this residual beta-structure is part of the native beta-structure and forms a folding initiation site, the folding reaction of beta-lactoglobulin may not necessarily be inconsistent with the sequential model. The non-native alpha-helices in the burst-phase intermediate may be formed in an immature part of the protein molecule because of the local alpha-helical propensity in this part.     

Preferential sites of proteolytic cleavage of bovine, human and rat thyroglobulin. The use of limited proteolysis to detect solvent-exposed regions of the primary structure

The sites and the sequence of the proteolytic cleavages of bovine, human and rat thyroglobulin, during the limited proteolysis with thermolysin and trypsin, were determined by sequencing the NH2 termini of the peptides produced and comparing them to the cDNA-derived sequences of bovine, human and rat thyroglobulin. Major cleavage sites of bovine thyroglobulin included residues 240, 502, 993, 1218, 1784 with thermolysin, and 240, 520, 1142, 1783, 2515 with trypsin. Cleavage sites of human thyroglobulin included residues 503, 982, 990, 1405, 1831 with thermolysin, and 522, 1627, 2513 with trypsin. Those of rat thyroglobulin included residues 501, 1776, 1784 with thermolysin, and 522, 1771, 1825, 2515 with trypsin (numbered as in bovine thyroglobulin). Thus, thyroglobulin from various species presents well localized and conserved regions particularly sensitive to proteolysis. The most sensitive region extended for 30 residues after residue 500. Another major cluster of cleavages was centered around residue 1800; this region was only partially sensitive in human thyroglobulin. A conserved tryptic site lay at the COOH terminus of the molecule. Most cleavage sites occurred within the inserted sequences that disrupt the Cys-rich, tandem repeats of thyroglobulin and either contain or are located near exon-intron junctions. Several cleavage sites lay in proximity of early iodinated or hormonogenic tyrosyl residues or of putative N-linked glycosylation sites. While a predominantly beta-type secondary structure and a rigid three-dimensional structure were predicted for the Cys-rich repeats, stretches of predicted alpha-helices, beta-strands and irregular structure were interspersed in the regions surrounding the cleavage sites. These data demonstrate the existence of conserved regions of thyroglobulin inherently sensitive to proteolysis, which most likely represent solvent-exposed regions of the primary structure, possibly forming loops at the surface of thyroglobulin.     

Adhesive interactions between medically important yeasts and bacteria

Yeasts are being increasingly identified as important organisms in human infections. Adhesive interactions between yeasts and bacteria may contribute to yeast retention at body sites. Methods for studying adhesive interactions between bacterial strains are well known, and range from simple macroscopic methods to flow chamber systems with complex image analysis capabilities. The adhesive interactions between bacteria and yeasts have been studied employing several of the methods originally developed for studying adhesive interactions between bacteria. However, in many of the methods employed the larger size of the yeasts as compared with bacteria results in strong sedimentation of the yeasts, often invalidating the method adapted. In addition, most methods are semi-quantitative and do not properly control mass transport. Consequently, adhesive interaction mechanisms between yeasts and bacteria identified hitherto, including lectin binding and protein-protein interactions, must be regarded with caution. Extensive physico-chemical characteristics of yeast cell surfaces are not available and a physico-chemical mechanism has not yet been put forth. A new method for quantifying adhesive interactions between yeasts and bacteria is proposed, based on the use of a parallel plate flow chamber, in which the influence of adhering bacteria upon the kinetics of yeast adhesion and aggregation of the adhering yeasts is quantitatively evaluated, under carefully controlled mass transport.     

Molecular evolutionary analysis of the thiamine-diphosphate-dependent enzyme, transketolase

Members of the transketolase group of thiamine-diphosphate-dependent enzymes from 17 different organisms including mammals, yeast, bacteria, and plants have been used for phylogenetic reconstruction. Alignment of the amino acid and DNA sequences for 21 transketolase enzymes and one putative transketolase reveals a number of highly conserved regions and invariant residues that are of predicted importance for enzyme activity, based on the crystal structure of yeast transketolase. One particular sequence of 36 residues has some similarities to the nucleotide-binding motif and we designate it as the transketolase motif. We report further evidence that the recP protein from Streptococcus pneumoniae might be a transketolase and we list a number of invariant residues which might be involved in substrate binding. Phylogenies derived from the nucleotide and the amino acid sequences by various methods show a conventional clustering for mammalian, plant, and gram-negative bacterial transketolases. The branching order of the gram-positive bacteria could not be inferred reliably. The formaldehyde transketolase (sometimes known as dihydroxyacetone synthase) of the yeast Hansenula polymorpha appears to be orthologous to the mammalian enzymes but paralogous to the other yeast transketolases. The occurrence of more than one transketolase gene in some organisms is consistent with several gene duplications. The high degree of similarity in functionally important residues and the fact that the same kinetic mechanism is applicable to all characterized transketolase enzymes is consistent with the proposition that they are all derived from one common ancestral gene. Transketolase appears to be an ancient enzyme that has evolved slowly and might serve as a model for a molecular clock, at least within the mammalian clade.