Enzymatic Sialylation of N-Linked Oligosaccharides Using an α-(2,3)-Specific trans-Sialidase from Trypanosoma cruzi: Structural Identification Using a Three-Dimensional Elution Mapping Technique

α-(2,3)-Sialylated biantennary and triantennary oligosaccharides were enzymatically prepared from pyridyl-2-amino-oligosaccharides with terminal Gal residues, using an α-(2,3)-specific trans-sialidase from Trypanosoma cruzi (Lee, K. B., and Lee, Y. C. (1994) Anal. Biochem. 216, 358-364). From the pyridyl-2-amino-derivatives of neutral and α-(2,6)-monosialylated biantennary oligosaccharides from human fibrinogen, 5 different sialyl biantennary oligosaccharides were obtained. From two different asialo-triantennary oligosaccharides from fetuin, 35 sialyl oligosaccharides were obtained. The trans-sialidase transferred sialic acids effectively and indiscriminately to different galactosyl residues in the different positions on the substrates. Since the starting materials are neutral oligosaccharide of established structure, and the only α-(2,3)-sialyl residues are added to the nonreducing Gal terminal residues, the structures of these oligosaccharides could be identified unambiguously by using the three-dimensional mapping technique (Takahashi, N., Nakagawa, H., Fujikawa, K., Kawamura, Y., and Tomiya, N. (1995) Anal. Biochem. 226, 139-146.) in combinations with strategic digestion with β-galactosidase, β-N-hexosaminidase, and sialidase L.     

Mercaptoethanesulfonic acid (CoM imitator) interaction studies with nickel(II) complexes of pyridyl groups containing tetradentate ligands: Synthesis, structure, spectra and redox properties

Nickel(II) complexes of N,N′-dimethyl-N,N′-bis(pyridyl-2yl-methyl)ethylene-diamine (L¹), N,N′-dimethyl-N,N′-bis(pyridyl-2-ylmethyl)-1,2-diaminopropane (L²) and N,N′-dimethyl-N,N′-bis(pyridyl-2-ylmethyl)-1,3-diaminopropane (L³) were prepared and their spectroscopic and redox properties studied. The distorted octahedral structure was determined for [NiL³ClCH₃OH](ClO₄) by using X-ray crystallography. The electronic spectral behavior of the complexes at different pHs was analyzed; it is shown that a new band grew at the expense of the other band intensity in acid media. The redox properties of ligands and their complexes show the peaks of Ni(II) → Ni(III) and Ni(II) → Ni(0) as these were detected at low concentration while Ni(II) → Ni(I) process was detectable clearly at high concentration. Furthermore, the interaction studies of 2-mercaptoethanesulfonic acid as a simulator of coenzyme M reductase (CoM) with NiN₄ chromophores are discussed.     

Synthesis of Pyridyl-4-Oxy-Substituted <Emphasis Type="Italic">N</Emphasis>-Hydroxy Amides of Cinnamic Acid as New Inhibitors of Histone Deacetylase Activity and Hepatitis C Virus Replication

Three structural isomers of pyridyl-4-oxy-substituted N-hydroxy amides of cinnamic acid (PyOCHA) have been synthesized for the first time. The relationship between their antiviral activity against hepatitis C virus (HCV) and inhibition of histone deacetylases of different cellular localization has been studied.     

Transfer of Man9GlcNAc tol-fucose by endo-β-N-acetylglucosaminidase fromArthrobacter protophormiae

We have reported that transglycosylation activity of endo--N-acetylglucosaminidase fromArthrobacter protophormiae (endo-A) can be enhanced to near completion using GlcNAc as an acceptor in a medium containing 30% acetone (Fan J-Q, Takegawa K, Iwahara S, Kondo A, Kato I, Abeygunawardana C, Lee YC (1995)J Biol Chem 270: 17723–29). In this paper, we found that the endo-A can also transfer an oligosaccharide, Man₉GlcNAc, tol-Fuc using Man₉GlcNAc₂Asn as donor substrate in a medium containing 35% acetone. The transglycosylation yield was greater than 25% when 0.2m l-Fuc was used as acceptor. The transglycosylation product was purified by high performance liquid chromatography on a graphitized carbon column and the presence ofl-Fuc was confirmed by sugar composition analysis and electrospray mass spectrometry. Sequential exo-glycosidase digestion of pyridyl-2-aminated transglycosylation product, Man₉GlcNAc-l-Fuc-PA, revealed that a -anomeric configuration linkage was formed between GlcNAc andl-Fuc. The GlcNAc was found to be 1,2-linked tol-Fuc by two methods; i) collision-induced decomposition on electrospray mass spectrometry after periodate oxidation, reduction and permethylation of Man₉GlcNAc-l-Fuc; and ii) preparation of Man₉GlcNAc-l-Fuc-PA, its periodate oxidation and reduction, followed by hydrolysis and HPLC analysis. Thus, the structure of the oligosaccharide synthesized by endo-A transglycosylation was determined to be Man₉GlcNAc(1,2)-l-Fuc. Methyl -l-fucopyranoside,l-Gal are also acceptors for the enzymic transglycosylation. However, transglycosylation failed when methyl -l-fucopyranoside,d-Fuc andd-Gal were used. These results indicate that the endo-A requires not only 3-OH and 4-OH to be equatorial but also a⁴C₁-conformation or equivalent conformation of the acceptor to perform transglycosylation.Abbreviations endo-A endo--N-acetylglucosaminidase fromArthrobacter protophormiae - PA pyridyl-2-amino- - AP aminopyridine - GlcNAc N-acetyl-d-glucosamine - Man mannose - Gal galactose - Fuc fucose - Glc glucose - PA-C₂ PA-glycolaldehyde - PA-C₃ PA-l-glyceraldehyde - PA-C₄ PA-d-threose - HPAEC-PAD high performance anion exchange chromatography with pulsed amperometric detector - HPLC high performance liquid chromatography - ODS octadecylsilyl - ES-MS electrospray mass spectrometry - CID collision-induced decomposition     

Theoretical design and characterisation on the fluorinated nitrophenyl azidotriazoles

Fluorinated molecules containing pyridyl- or phenyl-triazole moiety are useful materials in high-energy applications. In this work, based on the structure of N-(2, 4-dinitrophenyl)-3-azido-1H-1, 2, 4-triazole (I), two fluorinated nitrophenyl azidotriazoles (II and III) were designed by modifying I with the –CF₃ or –NF₂ group and were studied using the density functional theory (DFT). Compound I is a synthesised nitrophenyl azidotriazole with high heat of formation and acceptable detonation performance and thermal stability. Compared with I, the density and detonation properties of II and III are obviously improved, especially those of II. To better characterise II, the spectra (IR and UV/vis), thermal stability and pyrolysis mechanism were investigated. The thermal decomposition mechanism of II is similar to that of I, i.e. the azido triazole fragment is the initial spot of decomposition, while the thermal stability of II is better. The better performance of II suggests that it is worth further experimental investigations.     

Stabilization of dimethyliron(II) and methylcobalt(I) complexes bearing a hemilabile 2-benzoylpyridine ligand in octahedral and square-pyramidal coordination

Octahedral cis-Fe(CH₃)₂{2-(benzoyl)pyridyl-N,O}(PMe₃)₂ (1), square-pyramidal Co(CH₃){2-(benzoyl)pyridyl-N,O}(PMe₃)₂ (2), and triangular-planar Ni{2-(benzoyl)pyridyl-η²-C,O}(PMe₃)₂ (3) have been synthesized by reaction of 2-benzoylpyridine with thermally labile Fe(CH₃)₂(PMe₃)₄ and Co(CH₃)(PMe₃)₄ complexes. With Ni(CH₃)₂(PMe₃)₃, reductive elimination of ethane is observed when a η²-C,O-coordination is constituted. The complexes were investigated by NMR spectroscopic methods and the molecular structures of 1 and 2 were determined by X-ray crystallography.     

Chemistry of molecular and supramolecular structures of vanadium(IV) and dioxygen-bridged V(V) complexes incorporating tridentate hydrazone ligands

Four hydrazone ligands: 2-benzoylpyridine benzoyl hydrazone (HBPB), di-2-pyridyl ketone nicotinoyl hydrazone (HDKN), quinoline-2-carbaldehyde benzoyl hydrazone (HQCB), and quinoline-2-carbaldehyde nicotinoyl hydrazone (HQCN) and four of their complexes with vanadyl salts have been synthesized and characterized. Single crystals of HBPB and complexes [VO(BPB)(μ₂-O)]₂ (1) and [VO(DKN)(μ₂-O)]₂·½H₂O (2) were isolated and characterized by X-ray crystallography. Each of the complexes exhibits a binuclear structure where two vanadium(V) atoms are bridged by two oxygen atoms to form distorted octahedral structures within cis-N₂O₄ donor sets. In most complexes, the uninegative anions function as tridentate ligands, coordinating through the pyridyl- and azomethine-nitrogen atoms and enolic oxygen whereas in complex [VO(HQCN)(SO₄)]SO₄·4H₂O (4) the ligand is coordinated in the keto form. Complexes [VO(QCB)(OMe)]·1.5H₂O (3) and 4 are found to be EPR active and showed well-resolved axial anisotropy with two sets of eight line pattern.     

Trifluoromethyl-substituted 3,5-bis(arylidene)-4-piperidones as potential anti-hepatoma and anti-inflammation agents by inhibiting NF-кB activation

Some methoxy-, hydroxyl-, pyridyl-, or fluoro-substituted 3,5-bis(arylidene)-4-piperidones (BAPs) could reduce inflammation and promote hepatoma cell apoptosis by inhibiting activation of NF-κB, especially after introduction of trifluoromethyl. Herein, a series of trifluoromethyl-substituted BAPs (4-30) were synthesised and the biological activities were evaluated. We successfully found the most potential 16, which contains three trifluoromethyl substituents and exhibits the best anti-tumour and anti-inflammatory activities. Preliminary mechanism research revealed that 16 could promote HepG2 cell apoptosis in a dose-dependent manner by down-regulating the expression of Bcl-2 and up-regulating the expression of Bax, C-caspase-3. Meanwhile, 16 inhibited activation of NF-κB by directly inhibiting the phosphorylation of p65 and IκBα induced by LPS, together with indirectly inhibiting MAPK pathway, thereby exhibiting both anti-hepatoma and anti-inflammatory activities. Molecular docking confirmed that 16 could bind to the active sites of Bcl-2, p65, and p38 reasonably. The above results suggested that 16 has enormous potential to be developed as a multifunctional agent for the clinical treatment of liver cancers and inflammatory diseases.     

Reactivity of chloro(N-methyliminodiacetato)palladium(II) and chloro(pyridyl-2,6-dicarboxylato)palladium(II) complexes with purine based 5′-nucleotides and glutathione: antitumor activity of platinum(II)-analogs

The interaction of [Pd^II(mida)(Cl)]⁻ (1) (mida²⁻ = N-methyliminodiacetate) and [Pd^II(pydc)(Cl)]⁻ (2) (pydc²⁻ = pyridyl-2,6-dicarboxylate) with adenosine-5′-monophosphate (AMP), inosine-5′-monophosphate (IMP) and glutathione (GSH) was studied kinetically as a function of [L] (L = AMP, IMP, GSH) and [Cl⁻] and temperatures (10-35 °C) at pH 4.0. The kinetic results suggest that the reaction of 1 and 2 with the 5′-nucleotides (AMP, IMP) is characterized by the hydrolysis of chloro-complexes followed by the aquo-substitution with purine based 5′-nucleotides through its N7 atom. The reaction of 1 and 2 with GSH takes place through the direct chloride replacement with GSH. Kinetic data and activation parameters are interpreted in terms of an associative mechanism and discussed in reference to the data reported earlier. The [Pt^II(mida)(Cl)]⁻ (3) and [Pt^II(pydc)(Cl)]⁻ (4) complexes were prepared and allowed to interact with AMP and IMP and their reaction products were characterized by ¹H NMR studies. The antitumor activity of 3 and 4 was examined against MCF-7 (breast cancer), NCI-H460 (lung cancer) and SF-268 (CNS) cell lines.     

A new oxo-vanadium complex employing an imidazole-rich tripodal ligand: A bioinspired bromide and hydrocarbon oxidation catalyst

A vanadyl complex with the ligand (bis(1-methylimidazol-2-yl)methyl)(2-(pyridyl-2-yl)ethyl)amine was synthesized and fully characterized by X-ray crystallography, elemental analyses, cyclic voltammetry and infrared, electronic and electron paramagnetic resonance spectroscopies. This compound was designed under the so called hybrid concept. It shows to be able to promiscuously use hydrogen peroxide to oxidize bromide and to catalyze the oxidation of benzene and cyclohexane with very good selectivities.     

Structural and functional characterization of <Emphasis Type="Italic">IbMYB1</Emphasis> genes in recent Japanese purple-fleshed sweetpotato cultivars

To elucidate further the genetic mechanism underlying anthocyanin accumulation in the storage roots of recent Japanese purple-fleshed sweetpotato cultivars, we compared the structure of the IbMYB1 gene in cultivar Ayamurasaki and its spontaneous mutant, AYM96, whose storage roots do not accumulate anthocyanin. Amplification of the IbMYB1 genomic fragment covering the coding sequences suggested that the genome of Ayamurasaki contained three types of IbMYB1 sequences, named IbMYB1-1, IbMYB1-2a and IbMYB1-2b, whereas AYM96 had only IbMYB1-1. Although these three IbMYB1 sequences had identical coding sequences, IbMYB1-1 had a 7-bp insertion in the first intron. IbMYB1-2a and IbMYB1-2b were characterized by a single nucleotide polymorphism in the second intron. Further cloning and sequencing of the flanking regions of these IbMYB1 sequences showed that the promoter and 3′ flanking regions of IbMYB1-2a and IbMYB1-2b were different from those of IbMYB1-1. Genetic analysis using an F₁ population derived from a cross between the purple-fleshed cultivar Murasakimasari and AYM96 suggested that IbMYB1-2 sequences are responsible for anthocyanin accumulation in the storage roots. The structural features of these three IbMYB1 sequences and identification of the IbMYB1-2null sequence, which contained sequences very similar to those of the flanking regions of IbMYB1-2a and IbMYB1-2b, but which lacked the sequence around the coding region, suggested that IbMYB1 genes in recent Japanese purple-fleshed cultivars had been established through multiple gene-duplication events.     

Synthesis of Several Fructo-oligosaccharides by Asparagus Fructosyltransferases

Nine fructo-oligosaccharides, synthesized in vitro from sucrose by an enzyme preparation from asparagus roots, were isolated and their structures were elucidated to be 1^F (1-β-fructofuranosyl)_n sucrose [n = 1 (1-kestose), 2 (nystose) and 3], 6^G (1-β-fructofuranosyl)_n sucrose [n=1 (neokestose), 2 and 3] and 1^F (1-β-fructofuranosyl)_m-6^G (1-β-fructofuranosyl)_n sucrose [m=1, n=1; m=2, n =1; and m =1, n=2]. These saccharides are all known to occur naturally in asparagus roots, but 6^G (1-β-fructofuranosyl)₃ sucrose and 1^F (1-β-fructofuranosyl)_m-6^G-(1-β-fructofuranosyl)_n sucrose (m=1, n =1; and m=1, n=2) were the first saccharides enzymatically synthesized in vitro. Also three types of fructosyltransferases were presumed to be involved in the biosynthesis of these oligosaccharides in asparagus roots.     

Genetic interaction of DED1 encoding a putative ATP-dependent RNA helicase with SRM1 encoding a mammalian RCC1 homolog in Saccharomyces cerevisiae

 The Saccharomyces cerevisiae temperature-sensitive mutants srm1-1, mtr1-2 and prp20-1 carry alleles of a gene encoding a homolog of mammalian RCC1. In order to identify a protein interacting with RCC1, a series of suppressors of the srm1-1 mutation were isolated as cold-sensitive mutants and one of the mutants, designated ded1-21, was found to be defective in the DED1 gene. The double mutant, srm1-1 ded1-21, could grow at 35° C, but not at 37° C. A revertant of srm1-1 ded1-21 that became able to grow at 37° C acquired another mutation in the SRM1 gene, indicating the tight relationship between SRM1 and DED1. In all the rcc1 ^- strains examined, the amount of mutated SRM1 proteins was reduced or not detectable at the nonpermissive temperature. While mutated SRM1 protein was stabilized in all of the rcc1 ^- strains by the ded1-21 mutation, the ded1-21 mutation suppressed both srm1-1 and mtr1-2, but not the prp20-1 mutation, contrary to the previous finding that overproduction of the S. cerevisiae Ran homolog GSP1 suppresses prp20-1, but not srm1-1 or mtr1-2. Received: 20 March 1996/Accepted: 1 July 1996     

Expression of the SNF1 gene from Candida tropicalis is required for growth on various carbon sources, including glucose

SNF1 of Saccharomyces cerevisiae is an essential gene for the derepression of glucose repression. A homolog of SNF1 (CtSNF1) was isolated from an n-alkane-assimilating diploid yeast, Candida tropicalis. CtSNF1 could complement the snf1 mutant of S. cerevisiae. The previously published method for introducing the exogenous DNA into C. tropicalis was employed to construct SNF1/ snf1 heterozygote and snf1/snf1 homozygote strains. The successfully constructed SNF1/snf1 heterozygote was named KO-1. Disruption of the second CtSNF1 allele was unsuccessful, suggesting that CtSNF1 might be essential for cell viability. Therefore, in order to control the expression of CtSNF1, a strain (named KO-1G) in which the promoter region of CtSNF1 was replaced with the GAL10 promoter of C. tropicalis was constructed, and the growth of strains KO-1 and KO-1G was compared with that of the parental strain. The growth of strain KO-1 on glucose, sucrose, or acetate did not differ from the growth of the parental strain, but strain KO-1 showed a slight growth retardation on n-alkane. The growth of strain KO-1G on galactose was normal, but the cells stopped growing when transferred to glucose-, acetate-, or n-alkane-containing medium. Northern blot analysis against mRNA from the n-alkane-grown KO-1G strain demonstrated a close relationship between the presence of CtSNF1 mRNA and the growth of the cells, indicating that CtSNF1 is essential for cell viability. Moreover, mRNA levels of isocitrate lyase, which is localized in peroxisomes of C. tropicalis, were significantly affected by the level of CtSNF1 mRNA. Received: 3 May 1999 / Accepted: 14 July 1999     

Effects of altered α‐ and β‐branch carotenoid biosynthesis on photoprotection and whole‐plant acclimation of Arabidopsis to photo‐oxidative stress

Functions of α‐ and β‐branch carotenoids in whole‐plant acclimation to photo‐oxidative stress were studied in Arabidopsis thaliana wild‐type (wt) and carotenoid mutants, lut ein deficient (lut2, lut5), n on‐p hotochemical q uenching1 (npq1) and s uppressor of z eaxanthin‐l ess1 (szl1) npq1 double mutant. Photo‐oxidative stress was applied by exposing plants to sunflecks. The sunflecks caused reduction of chlorophyll content in all plants, but more severely in those having high α‐ to β‐branch carotenoid composition (α/β‐ratio) (lut5, szl1npq1). While this did not alter carotenoid composition in wt or lut2, which accumulates only β‐branch carotenoids, increased xanthophyll levels were found in the mutants with high α/β‐ratios (lut5, szl1npq1) or without xanthophyll‐cycle operation (npq1, szl1npq1). The PsbS protein content increased in all sunfleck plants but lut2. These changes were accompanied by no change (npq1, szl1npq1) or enhanced capacity (wt, lut5) of NPQ. Leaf mass per area increased in lut2, but decreased in wt and lut5 that showed increased NPQ. The sunflecks decelerated primary root growth in wt and npq1 having normal α/β‐ratios, but suppressed lateral root formation in lut5 and szl1npq1 having high α/β‐ratios. The results highlight the importance of proper regulation of the α‐ and β‐branch carotenoid pathways for whole‐plant acclimation, not only leaf photoprotection, under photo‐oxidative stress.     

Effects of varying Notch1 signal strength on embryogenesis and vasculogenesis in compound mutant heterozygotes

Background  

Identifying developmental processes regulated by Notch1 can be addressed in part by characterizing mice with graded levels of Notch1 signaling strength. Here we examine development in embryos expressing various combinations of Notch1 mutant alleles. Mice homozygous for the hypomorphic Notch1 ^12f allele, which removes the single O-fucose glycan in epidermal growth factor-like repeat 12 (EGF12) of the Notch1 ligand binding domain (lbd), exhibit reduced growth after weaning and defective T cell development. Mice homozygous for the inactive Notch1 ^lbd allele express Notch1 missing an ~20 kDa internal segment including the canonical Notch1 ligand binding domain, and die at embryonic day ~E9.5. The embryonic and vascular phenotypes of compound heterozygous Notch1 ^12f/lbd embryos were compared with Notch1 ^+/12f , Notch1 ^12f/12f , and Notch1 ^lbd/lbd embryos. Embryonic stem (ES) cells derived from these embryos were also examined in Notch signaling assays. While Notch1 signaling was stronger in Notch1 ^12f/lbd compound heterozygotes compared to Notch1 ^lbd/lbd embryos and ES cells, Notch1 signaling was even stronger in embryos carrying Notch1 ^12f and a null Notch1 allele.     

Identification of a new <Emphasis Type="Italic">Vrn</Emphasis>-<Emphasis Type="Italic">B1</Emphasis> allele using two near-isogenic wheat lines with difference in heading time

We conducted a molecular analysis of the Vrn-B1 gene in two near-isogenic lines (NILs) carrying the dominant Vrn-B1 ^S and Vrn-B1 ^Dm alleles from the Saratovskaya 29 and Diamant 2 cultivars, respectively. These lines are characterized by different times of ear emergence. PCR analysis and subsequent sequencing of the regulatory regions of Vrn-B1 revealed the full identity of the promoter region in both alleles. Simultaneously, we found significant differences in the structure of the first intron of the Vrn-B1 ^S allele when compared to Vrn-B1 ^Dm ; specifically, the deletion of 0.8 kb coupled with the duplication of 0.4 kb. We suggest that these changes in intron 1 of Vrn-B1 ^S caused earlier ear emergence in the corresponding NIL. The unusual structure of intron 1 within the Vrn-B1 ^S allele was described for the first time in this study. The allele Vrn-B1 ^Dm was almost identical with the previously studied sequence of the Vrn-B1a allele of T. aestivum, Triple Dirk B. We designated the new Vrn-B1 ^S allele as Vrn-B1c. PCR analysis of the Vrn-B1 gene in 26 spring wheat cultivars of both Russian and foreign breeding revealed that 16 of them contain the Vrn-B1a allele and 6 contain the Vrn-B1c allele. Other cultivars studied contained the recessive vrn-B1 gene, except for Novosibirskaya 67. This study demonstrates that the traditional system of Vrn-1 markers does not fully encompass the allelic diversity of these genes because none of the cultivars containing the Vrn-B1c allele gave a PCR product using the previously developed set of primers for identification of the Vrn-B1 locus. We showed that the newly characterized Vrn-B1c allele is widely distributed among different genotypes of spring wheat. The findings indicate the impact of structural changes in the first intron of Vrn-1 on the vernalization response and heading time.     

Polymorphism of the DQA1 promoter region (QAP) and DRB1, QAP,DQA1, DQB1 haplotypes in systemic lupus erythematosus

We have investigated the DNA polymorphism for the DQA1 promoter region (QAP) and HLA-class II DRB1, DQA1, and DQB1 genes in 178 central European patients with Systemic lupus erythematosus (SLE) using polymerase chain reaction and Dig-ddUTP labeled oligonucleotides. Increased frequencies of DRB1*02 and *03 are confirmed by DNA typing. In addition, the frequencies of DQA1*0501, *0102 and DQB1*0201, *0602 alleles are increased in the patients as compared to controls. The strongest association to SLE is found with DRB1*03 and DQB1*0201 alleles (p<10^–7, p corr. <10^–5 and p<10^–6, p corr. <10^–4, respectively). By investigating the DQA1 promoter region in the SLE patients we have detected nine different QAP variants. Increased frequencies of QAP1.2 and QAP4.1 are observed in patients as compared to controls (p <0.05, p corr. = n. s.). Analysis of linkage disquilibria demonstrates a very strong association between QAP variants and DQA1, DRB1 alleles. Certain QAP variants are completely associated with DQA1 and DRB1 alleles, whereas others can combine with different DQA1 and DRB1 alleles. All DRB1*02-positive patients and controls carry QAP1.2, and all DRB1*03-positive patients and controls carry QAP4.1. Conversely, the QAP1.2 variant appears only in DRB1*02 haplotypes, while the QAP4.1 variant can be observed in DRB1*03, *11, and *1303 haplotypes. Based on the strong linkage disequilibria between DRB1-DQA1-DQB1 genes and between DRB1-QAP-DQA1, we have deduced the four-point haplotypes for DRB1-QAP-DQA1-DQB1 in patients and controls. Two haplotypes DRB1*02-QAP1.2-DQA1*0102-DQB1*0602-and DRB1*03-QAP4.1-DQA1*0501-DQB1*0201 are significantly increased in patient as compared to controls (p<0.01, p corr. = n.s., RR = 1.8 and p <10^–7, p corr. <10^–5, RR = 3.1, respectively). The analysis of relative risks attributed to the various alleles of QAP, DQA1, and DQB1 as well as the investigation of the deduced DRB1-QAP-DQA1-DQB1 haplotypes leads to the conclusion that QAP4.1 and DQA1*0501 on the DR3 haplotypes are probably not involved in SLE susceptibility. There is no evidence for the involvement of DQ2 / dimers coded in transposition. Thus, susceptibility to SLE is on the DR3 haplotype most probably localized at DRB1 or telomeric of DRB1, while for the DR2 haplotype such orientation cannot be given. SLE study group members: M. Baur, A. Corvetta, H. Ehrfeld, J. Frey, J. R. Kalden, F. Krapf, B. Lang, G. G. Lange, K. Pirner, C. Rittner, E. Röther, P. Schneider, H. P. Seelig, S. Seuchter, W. Stangel, C. Specker, P. Späth, H. Deicher. Correspondence to: Z. Yao.