Diagnostic incisional biopsies in clinically indeterminate choroidal tumours.

Most intraocular tumours are reliably diagnosed by a careful clinical examination combined with one or more non-invasive diagnostic techniques. However, in a small percentage of tumours, typically small and clinically amelanotic, the features are insufficiently distinct for a confident clinical diagnosis and tissue is required for diagnosis. We used a 23-G vitreous cutter to access the biopsy site in 43 patients with clinically indeterminate tumours. After retinotomy, an incisional choroidal biopsy yielded a specimen of ∼1 mm(3). Obtained tissue was routinely processed for light microscopy including an immunohistochemical panel of monoclonal antibodies. Adequate tissue for diagnosis was provided in 41/43 (95%) patients. The sensitivity and specificity to detect malignant disease were 0.97 and 1.00, respectively. The positive predictive value was 1.00. Complications included progression of pre-existing retinal detachment in 5/43 (12%) patients and transient rise in intraocular pressure to >40 mm Hg in 6/43 (14%) patients; 4 of these 6 patients had a pre-existing retinal detachment. No patient with a pre-operatively attached retina had a retinal detachment. We conclude that an incisional transretinal choroidal biopsy yields abundant material and may adequately confirm or exclude malignancy in patients with clinically indeterminate tumours. The complication rate can be minimised when patients with pre-existing retinal detachment are excluded from biopsy.

Distinct but parallel evolutionary patterns between alcohol and aldehyde dehydrogenases: addition of fish/human betaine aldehyde dehydrogenase divergence.

Alcohol dehydrogenases (ADHs) of the MDR type (medium-chain dehydrogenases/reductases) have diverged into two evolutionary groups in eukaryotes: a set of 'constant' enzymes (class III) typical of basal enzymes, and a set of 'variable' enzymes (remaining classes) suggesting 'evolving' forms. The variable set has larger overall variability, different segment variability, and variability also in functional segments. Using a major aldehyde dehydrogenase (ALDH) from cod liver and fish ALDHs deduced from the draft genome sequence of Fugu rubripes (Japanese puffer fish), we found that ALDHs form more complex patterns than the ADHs. Nevertheless, ALDHs also group into 'constant' and 'variable' sets, have separate segment variabilities, and distinct functions. Betaine ALDH (class 9 ALDH) is 'constant,' has three segments of variability, all non-functional, and a limited fish/human divergence, reminiscent of the ADH class III pattern. Enzymatic properties of fish betaine ALDH were also determined. Although all ALDH patterns are still not known, overall patterns are related to those of ADH, and group separations may be distinguished. The results can be interpreted functionally, support ALDH isozyme distinctions, and assign properties to the multiplicities of the ADH and ALDH enzymes.

Amphioxus alcohol dehydrogenase is a class 3 form of single type and of structural conservation but with unique developmental expression.

The coding region of amphioxus alcohol dehydrogenase class 3 (ADH3) has been characterized from two species, Branchiostoma lanceolatum and Branchiostoma floridae. The species variants have residue differences at positions that result in only marginal functional distinctions. Activity measurements show a class 3 glutathione-dependent formaldehyde dehydrogenase, with kcat/Km values about threefold those of the human class 3 ADH enzyme. Only a single ADH3 form is identified in each of the two amphioxus species, and no ethanol activity ascribed to other classes is detectable, supporting the conclusion that evolution of ethanol-active ADH classes by gene duplications occurred at early vertebrate radiation after the formation of the amphioxus lineage. Similarly, Southern blot analysis indicated that amphioxus ADH3 is encoded by a single gene present in the methylated fraction of the amphioxus genome and northern blots revealed a single 1.4-kb transcript. In situ experiments showed that amphioxus Adh3 expression is restricted to particular cell types in the embryos. Transcripts were first evident at the neurula stage and then located at the larval ventral region, in the intestinal epithelium. This tissue-specific pattern contrasts with the ubiquitous Adh3 expression in mammals.

De novo sequencing of proteolytic peptides by a combination of C-terminal derivatization and nano-electrospray/collision-induced dissociation mass spectrometry.

A series of synthetic peptides (3-15 residues), C-terminally derivatized with 4-aminonaphthalenesulfonic acid (ansa), have been analyzed on a hybrid magnetic sector-orthogonal acceleration time-of-flight tandem mass spectrometer, fitted with a nano-electrospray (nano-ES) interface. Deprotonated molecules generated by negative-ion ES were subjected to collision-induced dissociation (CID) using either methane or xenon as the collision gas, at a collision energy of 400 eV (laboratory frame of reference). As a consequence of charge localization on the sulfonate group, only C-terminal fragment ions were formed, presumably by charge-remote fragmentation mechanisms. Interpretable CID spectra were obtained from fmol amounts of the small peptides (up to 6 residues), whereas low pmol amounts were required for the larger peptides. CID spectra were also recorded of derivatized, previously noncharacterised peptides obtained by proteolysis of cytosolic hamster liver aldehyde dehydrogenase. Interpretation of these CID spectra was based on rules established for the fragmentation of the synthetic peptides. This study shows that derivatization with ansa may be useful in the de novo sequencing of peptides.

Genetic polymorphism of alcohol dehydrogenase in europeans: the ADH2*2 allele decreases the risk for alcoholism and is associated with ADH3*1.

Polymorphism at the ADH2 and ADH3 loci of alcohol dehydrogenase (ADH) has been shown to have an effect on the predisposition to alcoholism in Asian individuals. However, the results are not conclusive for white individuals. We have analyzed the ADH genotype of 876 white individuals from Spain (n = 251), France (n = 160), Germany (n = 184), Sweden (n = 88), and Poland (n = 193). Peripheral blood samples from healthy controls and groups of patients with viral cirrhosis and alcohol-induced cirrhosis, as well as alcoholics with no liver disease, were collected on filter paper. Genotyping of the ADH2 and ADH3 loci was performed using polymerase chain reaction-restriction fragment length polymorphism methods on white cell DNA. In healthy controls, ADH2*2 frequencies ranged from 0% (France) to 5.4% (Spain), whereas ADH3*1 frequencies ranged from 47. 6% (Germany) to 62.5% (Sweden). Statistically significant differences were not found, however, between controls from different countries, nor between patients with alcoholism and/or liver disease. When all individuals were grouped in nonalcoholics (n = 451) and alcoholics (n = 425), ADH2*2 frequency was higher in nonalcoholics (3.8%) than in alcoholics (1.3%) (P =.0016), whereas the ADH3 alleles did not show differences. Linkage disequilibrium was found between ADH2 and ADH3, resulting in an association of the alleles ADH2*2 and ADH3*1, both coding for the most active enzymatic forms. In conclusion, the ADH2*2 allele decreases the risk for alcoholism, whereas the ADH2*2 and ADH3*1 alleles are found to be associated in the European population.

Novel mutations in the TULP1 gene causing autosomal recessive retinitis pigmentosa.

PURPOSE: To assess the contribution of TULP1 to autosomal recessive retinitis pigmentosa (arRP). METHODS: Fifteen exons of the gene were screened by single-strand conformation polymorphism analysis of 7 (of 49) arRP pedigrees showing cosegregation with TULP1 locus markers. RESULTS: In one of the seven families two allelic mutations, IVS4-2delAGA and c.937delC, were found in exons 5 and 10, respectively. CONCLUSIONS: Two novel mutations in TULP1 were found to be associated with arRP. That they both compromise the gene product supports their pathogenicity. This gene was present in no more than 2% of a panel of 49 Spanish families affected by arRP.

An ethanol-inducible MDR ethanol dehydrogenase/acetaldehyde reductase in Escherichia coli: structural and enzymatic relationships to the eukaryotic protein forms.

An ethanol-active medium-chain dehydrogenase/reductase (MDR) alcohol dehydrogenase was isolated and characterized from Escherichia coli. It is distinct from the fermentative alcohol dehydrogenase and the class III MDR alcohol dehydrogenase, both already known in E. coli. Instead, it is reminiscent of the MDR liver enzyme forms found in vertebrates and has a K(m) for ethanol of 0.7 mM, similar to that of the class I enzyme in humans, however, it has a very high k(cat), 4050 min(-1). It is also inhibited by pyrazole (K(i) = 0.2 microM) and 4-methylpyrazole (K(i)= 44 microM), but in a ratio that is the inverse of the inhibition of the human enzyme. The enzyme is even more efficient in the reverse direction of acetaldehyde reduction (K(m) = 30 microM and k(cat) = 9800 min(-1)), suggesting a physiological function like that seen for the fermentative non-MDR alcohol dehydrogenase. Growth parameters in complex media with and without ethanol show no difference. The structure corresponds to one of 12 new alcohol dehydrogenase homologs present as ORFs in the E. coli genome. Together with the previously known E. coli MDR forms (class III alcohol dehydrogenase, threonine dehydrogenase, zeta-crystallin, galactitol-1-phosphate dehydrogenase, sensor protein rspB) there is now known to be a minimum of 17 MDR enzymes coded for by the E. coli genome. The presence of this bacterial MDR ethanol dehydrogenase, with a structure compatible with an origin separate from that of yeast, plant and animal ethanol-active MDR forms, supports the view of repeated duplicatory origins of alcohol dehydrogenases and of functional convergence to ethanol/acetaldehyde activity. Furthermore, this enzyme is ethanol inducible in at least one E. coli strain, K12 TG1, with apparently maximal induction at an enthanol concentration of approximately 17 mM. Although present in several strains under different conditions, inducibility may constitute an explanation for the fairly late characterization of this E. coli gene product.

Sorbitol dehydrogenase of Drosophila. Gene, protein, and expression data show a two-gene system.

The Drosophila melanogaster sorbitol dehydrogenase (SDH) is characterized as a two-enzyme system of the medium chain dehydrogenase/reductase family (MDR). The SDH-1 enzyme has an enzymology with Km and kcat values an order of magnitude higher than those for the human enzyme but with a similar kcat/Km ratio. It is a tetramer with identical subunits of approximately 38 kDa. At the genomic level, two genes, Sdh-1 and Sdh-2, have a single transcriptional start site and no functional TATA box. Expression is greater in larvae and adults than in pupae, where it is very low. At all three stages, Sdh-1 constitutes the major transcript. Sdh-1 and Sdh-2 genes were located at positions 84E-F and 86D in polytene chromosomes. The deduced amino acid sequences of the two genes show 90% residue identity. Evaluation of the sequence and modeling of the structure toward that of class I alcohol dehydrogenase (ADH) show altered loop and gap arrangements as in mammalian SDH and establishes that SDH, despite gene multiplicity and larger variability than the "constant" ADH of class III, is an enzyme conserved over wide ranges.

Structure of betaine aldehyde dehydrogenase at 2.1 A resolution.

The three-dimensional structure of betaine aldehyde dehydrogenase, the most abundant aldehyde dehydrogenase (ALDH) of cod liver, has been determined at 2.1 A resolution by the X-ray crystallographic method of molecular replacement. This enzyme represents a novel structure of the highly multiple ALDH, with at least 12 distinct classes in humans. This betaine ALDH of class 9 is different from the two recently determined ALDH structures (classes 2 and 3). Like these, the betaine ALDH structure has three domains, one coenzyme binding domain, one catalytic domain, and one oligomerization domain. Crystals grown in the presence or absence of NAD+ have very similar structures and no significant conformational change occurs upon coenzyme binding. This is probably due to the tight interactions between domains within the subunit and between subunits in the tetramer. The oligomerization domains link the catalytic domains together into two 20-stranded pleated sheet structures. The overall structure is similar to that of the tetrameric bovine class 2 and dimeric rat class 3 ALDH, but the coenzyme binding with the nicotinamide in anti conformation, resembles that of class 2 rather than of class 3.

Acetyl xylan esterase II from Penicillium purpurogenum is similar to an esterase from Trichoderma reesei but lacks a cellulose binding domain.

Penicillium purpurogenum produces at least two acetyl xylan esterases (AXE I and II). The AXE II cDNA, genomic DNA and mature protein sequences were determined and show that the axe 2 gene contains two introns, that the primary translation product has a signal peptide of 27 residues, and that the mature protein has 207 residues. The sequence is similar to the catalytic domain of AXE I from Trichoderma reesei (67% residue identity) and putative active site residues are conserved, but the Penicillium enzyme lacks the linker and cellulose binding domain, thus explaining why it does not bind cellulose in contrast to the Trichoderma enzyme. These results point to a possible common ancestor gene for the active site domain, while the linker and the binding domain may have been added to the Trichoderma esterase by gene fusion.

Class 2 aldehyde dehydrogenase. Characterization of the hamster enzyme, sensitive to daidzin and conserved within the family of multiple forms.

Mitochondrial (class 2) hamster aldehyde dehydrogenase has been purified and characterized. Its primary structure has been determined and correlated with the tertiary structure recently established for this class from another species. The protein is found to represent a constant class within a complex family of multiple forms. Variable segments that occur in different species correlate with non-functional segments, in the same manner as in the case of the constant class of alcohol dehydrogenases (class III type) of another protein family, but distinct from the pattern of the corresponding variable enzymes. Hence, in both these protein families, overall variability and segment architectures behave similarly, with at least one 'constant' form in each case, class III in the case of alcohol dehydrogenases, and at least class 2 in the case of aldehyde dehydrogenases.

Characterization of a marsupial glutathione transferase, a class Alpha enzyme from Brown Antechinus (Antechinus stuartii).

The major form of glutathione transferase from the marsupial Antechinus stuartii has been purified and characterized as an Alpha class enzyme (Ast GST A1-1) with distant sequence relationships to other class Alpha sublines, compatible with the early origin of marsupials. Amino acid replacements toward the closest enzyme characterized (chicken, form A3) involve no less than 79 positions (36%). At the active site, as deduced from comparisons with the known tertiary structure of the corresponding human enzyme, over half of the residues (8 of 15) ascribed to substrate binding interactions are exchanged although the general character of that site is conserved, while only 1 of 11 positions ascribed to interactions with GSH is exchanged. Class variability and species variability appear to coincide, with divergent segments centering around positions 33-49, 103-130 and 205-222. The pattern is reminiscent of that in similarly multiple MDR alcohol dehydrogenases. Both these enzyme families involved in cellular defense reactions have diverged considerably.

Fructose-1,6-bisphosphatase. Primary structure of the rabbit liver enzyme. 'Intermediate' variability of an oligomeric protein.

The primary structure of rabbit liver fructose-1,6-bisphosphatase was determined by peptide analysis of digests with different proteases. The results establish the primary structure, complete data bank entries, and show that this enzyme variant is indeed homologous with other liver fructose-1,6-bisphosphatases. Residue differences with the enzymes from other mammals are 9-15%, with those from plants and yeasts about 50%, and with those from characterized prokaryotes up to 70%, showing an enzyme variability intermediate between those of 'variable' and 'constant' oligomeric dehydrogenases. Structural relationships, conformations and catalytic mechanisms are consistent within the family of fructose-1,6-bisphosphatases, and the rabbit protein is a typical rather than an aberrant form of the enzyme.

Alcoholytic deblocking of N-terminally acetylated peptides and proteins for sequence analysis.

N-terminal acetylation of polypeptides is a common feature preventing direct Edman degradation. We describe a method for the removal of the acetyl group, with only a low extent of internal peptide bond cleavage, also in large proteins, by treatment at room temperature with trifluoroacetic acid and methanol. The alcohol is essential for selective deacetylation, and it is proposed that the deblocking mechanism consists of an acid-catalyzed nucleophilic substitution involving methanol. The extent of deacetylation is limited, but the initial yield in the sequence analysis can be up to 10%. Deblocking of samples spotted or blotted onto sequencer filters is equally possible as the use of isolated samples from column separations. Deblocking on sequencer filters is also possible directly after negative results on initial sequencer attempts with samples proving to be blocked.

Photoaffinity labelling of lactate dehydrogenase from pig heart with a bifunctional NAD(+)-analogue.

P1-N6-(4-azidophenylethyl)adenosine-P2-4-(3-azidopyridinio)b utyl diphosphate was synthesized with an [8-14C]adenine label. This bifunctional photoaffinity labelling reagent inactivates lactate dehydrogenase from pig heart upon irradiation with light of wavelength 300-380 nm. Stoichiometry of binding and enzymatic parameters suggest that the analogue is bound to the coenzyme binding site and that adjacent residues are modified. Four radioactive peptides were isolated by reverse-phase HPLC after tryptic digestion of the labelled protein. Amino-acid sequence analysis identified the peptides and correlation with the three-dimensional structure of dogfish lactate dehydrogenase reveals that the peptides correspond to positions affecting the coenzyme binding site, consistent with proper affinity labelling. Two of the peptides, Ile-77 --> Lys-81 and Asp-82 --> Asn-88, are located close to the adenine binding site. Low recovery of Thr-86 in combination with the detection of additional products in the sequence analysis indicates that this residue is modified by the photoaffinity label. The two other peptides (positions 119-124 and 318-328) are located next to the substrate binding site; their label is lost upon treatment with pyrophosphatase, showing that they are linked to the pyridinio moiety of the coenzyme analogue.

Linking of isozyme and class variability patterns in the emergence of novel alcohol dehydrogenase functions. Characterization of isozymes in Uromastix hardwickii.

The nature of the isozyme differences in the class-I alcohol dehydrogenase structure from the lizard, Uromastix hardwickii, was determined and related to those in the human and horse enzymes, for which isozyme structures have also been established. The Uromastix isozymes differ much (at a total of 72 positions, 19%) but, in spite of this, have similar properties and were not obtained resolved. Their structures were analyzed in mixture, and the two sub-sets of peptides obtained could be distinguished by evaluation of the recovery ratios within the peptide pairs. The isozymes have class-I activities, with an ethanol dehydrogenase activity of 0.6 U/mg and no formaldehyde dehydrogenase activity, have typical class-I structures, and are composed of N-terminally acetylated 375-residue subunits (a and b). Importantly, variability patterns between the isozymes are reminiscent of those both in the other two lines with isozymes (primates and horse) and in the class distinctions of the enzyme. Hence, the variability pattern since the distant stage of class-I emergence is also visible within the more recent isozyme divergence, illustrating a continuity in the evolution of isozymes to classes (and then to enzymes). The pattern also links the different levels of multiplicity and may suggest an acceptability in common to duplications and mutations, compatible with the emergence of novel functions.

Liver class-I alcohol dehydrogenase isozyme relationships and constant patterns in a variable basic structure. Distinctions from characterization of an ethanol dehydrogenase in cobra, Naja naja.

The major ethanol dehydrogenase of cobra liver was characterized in order to clarify isozyme relationships and functional motifs of the vertebrate enzyme. The cobra protein is a class-I form, most related to one of the isozyme subunits (the a form) in Uromastix (lizard) liver. This positions the isozyme duplication and defines the main-line alternative. The new structure also allows extensive correlations with structure/function relationships for alcohol dehydrogenases in general, of which 38 animal variants (still disregarding strain and allelic differences) now have been characterized. Architectural features are discerned, distinguishing the enzyme at large, the classes, and the functional interactions at the sites of substrate binding and coenzyme binding. Variability is greater at the substrate-binding site, with only one of 13 residues strictly conserved (His67, one of the active-site zinc ligands) but all other residues differing among and frequently within classes. However, many substrate-interacting residues are class preferential and may be used in predictive assignments. Class-I/III differences concern position 48 (typically Ser in class I, Thr in class III), position 93 (Phe versus Tyr), position 141 (branch-chained aliphatic residue versus methionine), position 57 (hydrophobic residue versus Asp), position 115 (Asp versus Arg), position 116 (Leu or Ile versus Val), position 306 (Met or Leu/Ile versus Phe), position 309 (Phe or Leu/Ile versus Val) and position 318 (Val or Ile versus Ala). In contrast, coenzyme binding is more conserved. A characteristic coenzyme-binging motif, covering only a 50-residue stretch, is defined as tVDiK (residues 178, 203, 223, 224, 228; capital letters for residues strictly conserved and small-cases letters for residues nearly so). This motif is class independent and unique to animal alcohol dehydrogenases. Therefore, the novel enzyme structure establishes class-I isozyme relationships, shows characteristic 'constant' residues also in the 'variable' class-I line, and defines residue-specific patterns which may have a predictive value in functional assignments of an increasing number of undefined further forms expected to result from gene projects.