The photosynthetic F1-α3β3 and α1β1 catalytic core complexes

Minimal photosynthetic catalytic F₁() core complexes, containing equimolar ratios of the and subunits, were isolated from membrane-bound spinach chloroplast CF₁ and Rhodospirillum rubrum chromatophore RrF₁. A CF₁-₃₃ hexamer and RrF₁-₁₁ dimer, which were purified from the respective F₁() complexes, exhibit lower rates and different properties from their parent F₁-ATPases. Most interesting is their complete resistance to inhibition by the general F₁ inhibitor azide and the specific CF₁ inhibitor tentoxin. These inhibitors were earlier reported to inhibit multisite, but not unisite, catalysis in all sensitive F₁-ATPases and were therefore suggested to block catalytic site cooperativity. The absence of this typical property of all F₁-ATPases in the ₁₁ dimer is consistant with the view that the dimer contains only a single catalytic site. The ₃₃ hexamer contains however all F₁ catalytic sites. Therefore the observation that CF₁-₃₃ can bind tentoxin and is stimulated by it suggests that the F₁ subunit, which is required for obtaining inhibition by tentoxin as well as azide, plays an important role in the cooperative interactions between the F₁-catalytic sites.Abbreviations CF₀F₁ chloroplast F₀F₁ - CF₁ chloroplast F₁ - CF₁ chloroplast F₁ subunit - CF₁ chloroplast F₁ subunit - CF₁() a complex containing equal amounts of the CF₁ and subunits - MF₁ mitochondrial F₁ - RrF₀F₁ Rhodospirillum rubrum F₀F₁ - RrF₁ R. rubrum F₁ - RrF₁ R. rubrum F₁ subunit - RrF₁ R. rubrum F₁ subunit - RrF₁() a complex containing equal amounts of the RrF₁ and subunits - Rubisco Ribulose-1,5-bisphosphate carboxylase - TF₁ thermophilic bacterium PS3 F₁     

Automated NMR determination of protein backbone dihedral angles from cross-correlated spin relaxation

The simultaneous interpretation of a suite of dipole-dipole and dipole-CSA cross-correlation rates involving the backbone nuclei ¹³C, ¹H,¹³CO, ¹⁵N and ¹H^N can be used to resolve the ambiguities associated with each individual cross-correlation rate. The method is based on the transformation of experimental cross-correlation rates via calculated values based on standard peptide plane geometry and solid-state ¹³CO CSA parameters into a dihedral angle probability surface. Triple resonance NMR experiments with improved sensitivity have been devised for the quantification of relaxation interference between ¹H(i)-¹³C(i)/¹⁵N(i)-¹H^N(i) and ¹H(i–1)-¹³C(i–1)/¹⁵N(i)-¹H^N(i) dipole-dipole mechanisms in ¹⁵N,¹³C-labeled proteins. The approach is illustrated with an application to ¹³C,¹⁵N-labeled ubiquitin.     

An α-spectrin mutation responsible for hereditary elliptocytosis associated in cis with the αV/41 polymorphism

The 207 LeuPro mutation in spectrin has recently been identified as a cause of ^I/50-46a hereditary elliptocytosis (HE) or pyropoikilocytosis among Black people. We have found this mutation in a Moroccan family in both the heterozygous and homozygous states. The mutated -spectrin allele carried, in cis, the ^V/41 polymorphism, a common polymorphism altering the peptide maps and associated with a low-expression level. This is the first report of the cis combination of an HE mutation and the ^V/41 polymorphism. Presumably, such a combination accounts for the very low expression of the abnormal allele in the heterozygous state.     

Evolution of the response patterns to dietary carbohydrates and the developmental differentiation of gene expression of α-amylase in Drosophila

Intraspecific variation of -amylase activity in D. melanogaster and D. immigrans, which is distantly related to D. melanogaster, and interspecific variation of -amylase activity in 18 Drosophila species were examined. The amount of intraspecific variation of -amylase activities measured in terms of coefficient of variation in D. melanogaster and D. immigrans was one-half and one-tenth or less, respectively, of the interspecific variation in 18 Drosophila species. We also surveyed the response patterns of -amylase activity to dietary carbohydrates at the larval and adult stages. The levels of -amylase activity depended on both repression by dietary glucose (glucose repression) and induction by dietary starch (starch induction). In general, our data suggest that glucose repression was conserved among species at both stages while starch induction was mainly observed in larvae, although the degree of the response depended on species. In D. lebanonensis lebanonensis and D. serrata, larvae expressed electrophoretically different -amylase variants (isozymes) from those of adult flies. These results may suggest that the regulatory systems responsible both for the response to environment and developmental expression are different among species in Drosophila. Correspondence to: T. Yamazaki     

α-Amylase structural genes in rye

Summary Rye -Amy1, -Amy2, and -Amy3 genes were studied in the cross between inbred lines using wheat -amylase cDNA probes. The -Amy1 and -Amy2 probes uncovered considerable restriction fragment length polymorphism, whereas the -Amy3 region was much more conserved. The numbers of restriction fragments found and the F₂ segregation data suggest that there are three -Amy1 genes, two or three -Amy2 genes, and three -Amy3 genes in rye. These conclusions were supported by a simultaneous study of -amylase isozyme polymorphism. The F₂ data showed the three individual -Amy1 genes to span a distance of 3cM at the locus on chromosome 6RL. The genes were mapped relative to other RFLP markers on 6RL. On chromosome 7RL two -Amy2 genes were shown to be separated by 5 cM. Linkage data within -Amy3 on 5RL were not obtained since RFLP could be detected at only one of the genes.     

Proximity of the CTLA-1 serine esterase and Tcr α loci in mouse and man

The serine esterase CTLA-1 gene was shown by in situ hybridization to map to the D segment of mouse chromosome 14, the same localization as a member of the immunoglobulin super family, Tcr . To further demonstrate the proximity of CTLA-1 and Tcr , genetic linkage was tested in mouse using restriction fragment length polymorphisms and a backcross progeny, and no recombination was observed in the 100 backcross products studied. Recombination events between Tcr /CTLA-1 and the markers Gdh-X and NP-1 show that the most probable order of these loci in the mouse 14D region is NP-1-Tcr /Ctla-1-Gdh-X. In man, the human homologue of CTLA-1 was shown by in situ hybridization to map on chromosome 14, at 14q11-q12, where Tcr also maps. Using the human cell line SUP-Tl, bearing the inversion inv(14)(q11;q32), we further demonstrated the loci order in man to be centromere-NP-1-Tcr -CTLA-1. To complement the cytogenetic and genetic mapping data, we tried to determine the physical distance between the two genes by pulsed field gel electrophoresis (PFGE). DNA prepared from various cell types, both mouse and human, were digested with a panel of rare cutter enzymes and hybridized first with CTLA-1, then with Tcr probes. None of the bands identified hybridized with both Tcr and CTLA-1 probes for either mouse or human cells. Although the physical mapping by PFGE is inconclusive, the cytogenetic and genetic data support close linkage of the Tcr and CTLA-1 genes in both mouse and man, suggesting homology between the D region of mouse chromosome 14 and the q11–q12 region of human chromosome 14, encompassing the Tcr and CTLA-1 loci. These findings also provide another example of proximity of genes coding for a member of the Ig super-family and a serine esterase.     

Homology of a 130-kb region enclosing the α-globin gene cluster,the α-locus controlling region,and two non-globin genes in human and mouse

The human -globin gene cluster (30 kb) is embedded in a GC-rich isochore very close to the telomere of Chromosome (Chr) 16p. The -Locus Controlling Region (-LCR) is located upstream of the adult -globin genes and has been shown to be essential for their expression. In this study we have been looking for expressed genes in the region upstream of the -globin cluster to understand the role of the LCR-like element in the expression and replication timing of flanking gene clusters. We show that the upstream -globin region is conserved over a 75-kb range and includes at least two oppositely transcribed non-globin genes, here referred to as Mid1 and Dist1. Complementary DNA sequences of 250 bp and 2.5 kb from Mid1 (coordinate-68) and Dist1 (coordinate-90 to-99), respectively, were isolated from human and mouse. The deduced partial amino acid sequences of these cDNAs are 81% and 95% identical for the Mid1 and Dist1 gene respectively. We have cloned a mouse cosmid contig which includes Dist1, Mid1, and the entire murine -globin cluster. The murine homolog of the -LCR was mapped upstream of the mouse globin genes at approximately the same position as in the human locus. Our results indicate that, in mouse and human, the -globin loci and their flanking sequences are homologous over a range of at least 130 kb. The structural homology of this region in both mammals suggests also a functional one and indicates the mouse as a potential model for studying the role of the -LCR controlling element in the regulation of expression and replication timing of the flanking gene clusters.The nucleotide sequence data reported in this paper have been submitted to GenBank and have been assigned the accession numbers M99623, M99624, M99625, and M99626.     

Evolution of murine α1-proteinase inhibitors: Gene amplification and reactive center divergence

The organization and sequence of genes encoding the ₁-proteinase inhibitor (₁PI), a major serine proteinase inhibitor of the mammalian bloodstream, have been compared in several species, including murine rodents (genus Mus). Analysis of gene copy number indicates that amplification of ₁PI genes occurred at some time during evolution of the Mus genus, leading to fixation of a family of about three to five genes in several existing species (e.g., M. domesticus and M. saxicola), and only a single gene in others (e.g., M. caroli). A phylogeny for the various mammalian ₁PI mRNAs was constructed based upon synonymous substitutions within coding regions. The mRNAs in different murine species diverged from a common ancestor before the formation of the first species lineages of the Mus genus, i.e., about 10–13 million years ago. Thus, ₁PI gene amplification must have occurred prior to Mus speciation; gene families were retained in some, but not all, murine species. The reactive center region of the ₁PI polypeptide, which determines target protease specificity, has diverged rapidly during evolution of the Mus species, but not during evolution of other mammalian species included in the analysis. It is likely that this accelerated evolution of the reactive center, which has been noted previously for serine proteinase inhibitors, was driven by some sort of a positive Darwinian selection that was exerted in a taxon-specific manner. We suggest that evolution of ₁PI genes of murine rodents has been characterized by both modification of gene copy number and rapid reactive center divergence. These processes may have resulted in a broadened repertoire of proteinase inhibitors that was evolutionarily advantageous during Mus speciation.Correspondence to: F.G. Berger     

A novel wheat alpha-amylase gene (alpha-Amy3)

Summary A genomic clone of a wheat -amylase gene (Amy3/33) was identified, on the basis of hybridisation properties, as different from -Amy1 and -Amy2 genes which had been characterised previously. The nucleotide sequence revealed that this gene has the normal sequence motifs of an active gene and an open reading frame interrupted by two introns. The protein sequence encoded by this open reading frame is recognisably similar to that of -amylase from the -Amy1 and -Amy2 genes and there is high sequence homology in all three proteins at the putative active sites and Ca⁺⁺ binding region. In addition, the introns are at positions equivalent to the position of introns in the -Amy1 and -Amy2 genes. However, the sequence was less similar to -Amy1 and -Amy2 than these are to each other. Southern blot analysis showed that the Amy3/33 DNA is one of a small multigene family carried on a different chromosome (group 5) from either the -Amy1 or -Amy2 genes. A further difference from the -Amy1 and -Amy2 genes was the pattern of expression. Amy3/33 was expressed only in immature grains and, unlike the -Amy1 and -Amy2 genes, not at all in germinating aleurones. These data suggested therefore that this gene represents a third type of -amylase gene, not described before, which shares a common evolutionary ancestor with the -Amy1 and -Amy2 genes.     

The transport of class I major histocompatibility complex antigens is determined by sequences in the α1 and α2 protein domains

The transport of human-mouse hybrid class I histocompatibility antigens has been studied in a mutant human cell line, 174 × CEM.T2 (T2). T2, a somatic cell hybrid of human B- and T-lymphoblastoid cell lines (B-LCL and T-LCL, respectively), synthesizes HLA-A2 and HLA-B5 glycoproteins, but expresses only low levels of A2 and undetectable levels of B5 at the cell surface. We have previously shown that the products of human class I genes introduced into T2 by transfection behave like the endogenous HLA-B5 glycoproteins, while the products of mouse class I alleles similarly introduced are transported normally to the cell surface. We have now determined that the surface expression of class I glycoproteins in T2 depends on the origin of the ₁ and ₂ domains. Human (HLA-B7) and mouse (H-2D ^p ) hybrid class I genes, encoding the leader, ₁, and ₂ sequences of one species fused to the ₃, transmembrane, and cytoplasmic domains of the other, were transfected into T2. Normal surface expression of the hybrid class I molecule was observed in T2 only when the leader, ₁, and ₂-encoding exons were derived from the mouse gene. The reciprocal construct, encoding human leader, ₁, and ₂ domains fused to the mouse ₃, transmembrane, and cytoplasmic regions, resulted in biosynthesis of a hybrid glycoprotein which was not transported to the cell surface. The products of both constructs were expressed normally in control cells. The effects of glycosylation on class I antigen transport were also studied using mutant class I constructs with altered glycosylation sites. Two mutant B7 genes encoding either an extra glycosylation site at position 176 or no glycosylation sites were transfected into T2. These mutant products were expressed at the cell surface in control cells, but were synthesized and not surface-expressed in T2. These data demonstrate that the HLA/H-2 transport dichotomy in T2 is a function of the origin of the ₁ and/or ₂ domains of the class I glycoprotein, and is not a reflection of glycosylation differences between the human and mouse molecules. Offprint requests to: P. Cresswell.     

DNA sequence analysis of the rat RT1. B α gene

The major histocompatibility complex (MHC) of the rat (RT1 complex) encodes two sets of class II molecules referred to as RT1.B and RT1.D. The RT1. B gene was isolated for a Sprague-Dawley (RT1^b) rat genomic library using a rat RT1.B chain cDNA as a hybridization probe. The coding and the majority of the intron DNA sequence was determined. The structure of the RT1. B gene is equivalent to that of H-2 and HLA chain genes. Comparison of the nucleotide and predicted amino acid sequences of the RT1.B gene with those of the H-2 and HLA genes revealed a high degree of overall sequence conservation. However, two regions of the first external domain (l), residues 19–23 and 45–78, exhibit marked sequence variation. Two blocks of conserved nucleotide sequence were identified in the 5 promoter region of the RT1. B gene that have been described in all MHC class II genes sequenced to date. These conserved sequences may be involved in the coordinate regulation of expression of class II genes. The cloned RT1.B gene was efficiently transcribed when transfected to mouse L cells.     

Differential expression of α-amylase genes in germinating rice and barley seeds

Steady-state levels of mRNA from individual -amylase genes were measured in the embryo and aleurone tissues of rice (Oryza sativa) and two varieties of barley (Hordeum vulgare L. cv. Himalaya and cv. Klages) during germination. Each member of the -amylase multigene families of rice and barley was differentially expressed in each tissue. In rice, -amylase genes displayed tissue-specific expression in which genes RAmy3B, RAmy3C, and RAmy3E were preferentially expressed in the aleurone layer, genes RAmy1A, RAmy1B and RAmy3D were expressed in both the embryo and aleurone, and genes RAmy3A and RAmy2A were not expressed in either tissue. Whenver two or more genes were expressed in any tissue, the rate of mRNA accumulation from each gene was unique. In contrast to rice, barley -amylase gene expression was not tissue-specific. Messenger RNAs encoding low- and high-pI -amylase isozymes were detectable in both the embryo and aleurone and accumulated at different rates in each tissue. In particular, peak levels of mRNA encoding high-pI -amylases always preceded those encoding low-pI -amylases. Two distinct differences in -amylase gene expression were observed between the two barley varieties. levels of high-pI -amylase mRNA peaked two days earlier in Klages embryos than in Himalaya embryos. Throughout six days of germination, Klages produced three times as much high-pI -amylase mRNA and nearly four times as much low-pI -amylase mRNA than the slower-germinating Himalaya variety.     

Evidence for the adaptive significance of enzyme activity levels: Interspecific variation in α-GPDH and ADH in Drosophila

The activity levels of alcohol dehydrogenase and -glycerophosphate dehydrogenase were compared among nine species of Drosophila representing three phylogenetic groups. For any given life stage, interspecific variability in activity level was much greater for ADH than for -GPDH. Patterns of ontogenetic expression of enzyme activity were also much more variable among species for ADH than for -GPDH. These results are consistent with the interpretation that -GPDH is involved with a relatively uniform adaptive function among species, whereas ADH levels may reflect variable adaptive capabilities. There is a significant correlation between ADH activities and survivorship on alcohol-treated media for these nine species.This research was supported by Contract AT(04-3)-34 200 with ERDA. The authors are supported by an NIH training grant in genetics.     

Chromosomal localization and genomic organization of α-amylase genes in rice (Oryza sativa L.)

Summary Genes for -amylase, alcohol dehydrogenase, andEm, an ABA-regulated gene expressed late in embryogenesis, were localized on rice chromosomes by the analysis of primary trisomies. The validity of the mapping approach was confirmed usingAdh-1 as a control. TheAdh-1 gene has previously been assigned to chromosome 11 using conventional techniques. In this study we confirm this assignment and report an additional locus for alcohol dehydrogenase (Adh-2) on chromosome 9. The -amylase genes were located on chromosomes 1, 2, 6, 8, and 9 while theEm gene was mapped to chromosome 5. To facilitate trisomic analysis and correlation of cloned genes with bands observed on Southern blots, a nomenclature for the rice -amylase genes has been proposed. In addition to mapping nine cloned -amylase genes, we have identified two previously uncloned -amylase genes as part of this study. Polymorphism for -amylase genes belonging to each of the three subfamilies was observed between M202 and IR36. The maximum degree of polymorphism was found among genes belonging to the RAmy3 subfamily, which also has the most diverse group of genes.     

Sequence analysis of 22 kDa-like α-coixin genes and their comparison with homologous zein and kafirin genes reveals highly conserved protein structure and regulatory elements

Several genomic and cDNA clones encoding the 22 kDa-like -coixin, the -prolamin of Coix seeds, were isolated and sequenced. Three contiguous 22 kDa-like -coixin genes designated -3A, -3B and -3C were found in the 15 kb -3 genomic clone. The -3A and -3C genes presented in-frame stop codons at position +652. The two genes with truncated ORFs are flanking the -3B gene, suggesting that the three -coixin genes may have arisen by tandem duplication and that the stop codon was introduced before the duplication.Comparison of the deduced amino acid sequences of -coixin clones with the published sequences of 22 kDa -zein and 22 kDa-like -kafirin revealed a highly conserved protein structure. The protein consists of an N-terminus, containing the signal peptide, followed by ten highly conserved tandem repeats of 15–20 amino acids flanked by polyglutamines, and a short C-terminus. The difference between the 22 kDa-like -prolamins and the 19 kDa -zein lies in the fact that the 19 kDa protein is exactly one repeat motif shorter than the 22 kDa proteins.Several putative regulatory sequences common to the zein and kafirin genes were identified within both the 5 and 3 flanking regions of -3B. Nucleotide sequences that match the consensus TATA, CATC and the ca. –300 prolamin box are present at conserved positions in -3B relative to zein and kafirin genes. Two putative Opaque-2 boxes are present in -3B that occupies approximately the same positions as those identified for the 22 kDa -zein and -kafirin genes. Southern hybridization, using a fragment of a maize Opaque-2 cDNA clone as a probe, confirmed the presence of Opaque-2 homologous sequences in the Coix and sorghum genomes.The overall results suggest that the structural and regulatory genes involved in the expression of the 22 kDa-like -prolamin genes of Coix, sorghum and maize, originated from a common ancestor, and that variations were introduced in the structural and regulatory sequences after species separation.     

Molecular cloning and preliminary expression analysis of banded dogfish (Triakis scyllia) CC chemokine cDNAs by use of suppression subtractive hybridization

Suppression subtractive hybridization was carried out by using cDNAs of peripheral white blood cells (PWBCs) of banded dogfish (Triakis scyllia) after phorbol 12-myristate 13-acetate (PMA) stimulation. The Trsc-SCYA107, MIP31 and MIP32 clones contained an open reading frame encoding 97, 99 and 97 amino acids, respectively. Comparison of the deduced amino acids showed that the banded dogfish MIP31 and MIP32 sequences shared 42.3% and 40.0% identity with human SCYA20, respectively, while the Trsc-SCYA107 sequence shared 50.6, 44.2 and 42.0% identity with the catshark (Scyliorhinus canicula) Scca-SCYA107, rainbow trout (Oncorhynchus mykiss) CK4A and CK4B, respectively. The genomic sequences of banded dogfish Trsc-SCYA107, MIP31 and MIP32 contain four exons and three introns, and MIP31 and MIP32 shared the same intron/exon organization with that of human. The MIP31 and MIP32 genes of lipopolysaccharide (LPS)-unstimulated banded dogfish were expressed in gill, kidney and liver, while Trsc-SCYA107 mRNA was detected in various tissues except for brain. However, the constitutive expression of MIP32 gene was much lower than the Trsc-SCYA107 and MIP31 genes. RT-PCR analysis of the Trsc-SCYA107 expression in tissues of LPS-stimulated fish showed enhanced expression at 24 h poststimulation in the gill, heart, leydig, spleen and testes, while the expression of MIP31 and MIP32 was not influenced by LPS-stimulation in vivo. Furthermore, a relative increase in the expression of the Trsc-SCYA107 and MIP32 genes in PWBCs was observed at 1–12 h poststimulation with PMA and LPS, with maximal expression observed at 3 h, while MIP31 expression was observed at 3–12 h poststimulation only with PMA.     

Genes encoding the H,K-ATPase α and Na,K-ATPase α3 subunits are linked on mouse Chromosome 7 and human Chromosome 19

We have used linkage analysis and fluorescence in situ hybridization to determine the chromosomal organization and location of the mouse (Atp4a) and human (ATP4A) genes encoding the H,K-ATPase subunit. Linkage analysis in recombinant inbred (BXD) strains of mice localized Atp4a to mouse Chromosome (Chr) 7. Segregation of restriction fragment length polymorphisms in backcross progeny of Mus musculusxMus spretus mating confirmed this assignment and indicates that Atp4a and Atp1a3 (gene encoding the murine Na,K-ATPase 3 subunit) are linked and separated by a distance of 2 cM. Analysis of the segregation of simple sequence repeats suggested the gene order centromere-D7Mit21-D7Mit57/Atpla3-D7Mit72/Atp4a. A human Chr 19-enriched cosmid library was screened with both H,K-ATPase and Na,K-ATPase 3 subunit cDNA probes to isolate the corresponding human genes (ATP4A and ATP1A3, respectively). Fluorescence in situ hybridization with gene-specific cosmid clones localized ATP4A to the q13.1 region, and proximal to ATP1A3, which maps to the q13.2 region, of Chr 19. These results indicate that ATP4A and ATP1A3 are linked in both the mouse and human genomes.     

Long-range physical mapping of the alpha-amylase-1 (alpha-Amy-1) loci on homoeologous group 6 chromosomes of wheat

Summary Long-range physical maps of the small multigene family of the malt -amylase genes (-Amy-1) located on the long arms of wheat chromosomes 6A (the -Amy-A1 locus) and 6B (-Amy-B1) were generated by pulsed-field gel electrophoresis analysis. By using three methylation-sensitive rare-cutter restriction endonucleases, NotI, NruI and MluI, and an -Amy-1 cDNA probe and four gene-specific genomic probes from the -Amy-B1 locus, the size of the -Amy-B1 locus was estimated to be about 700 kb and of the -Amy-B1 locus to be about approximately 4300 kb. These two maps indicate clustering of GC-rich and C-methylation-sensitive restriction enzyme recognition sites. At least five regions reminiscent of CpG islands are apparent in -Amy-B1, and three in -Amy-A1. Correlation between recombination frequency and physical distance within the -Amy-B1 locus suggests that 1 cM approximates to 1 Mb in physical distance.     

ααααanti-3.7 type II: a new α-globin gene rearrangement suggesting that the α-globin gene duplication could be caused by intrachromosomal recombination

Summary We report here a new human -globin gene rearrangement carrying the two normal, 2 and 1, and two hybrid, 1/2, globin genes in the order 5-2-1/2-1/2-1-3. Both the hybrid genes, subtyped with ApaI and RsaI restriction enzymes, were found to be of the uncommon anti 3.7 type II. The hybrid genes were expressed at the biosynthetic level and their interaction with the -thalassaemia IVS 1 nt 1 GA mutation caused thalassaemia intermedia. We also report a case of an -globin gene rearrangement in the twin of one of the -globin gene carriers; the duplicated gene was of the anti 4.2 type and was associated with the absence of RsaI polymorphism. The singular finding of an -anti 3.7 cluster with two identical rare hybrid genes suggests that the reciprocal unequal recombination causing the -globin gene rearrangements could be of the intra-chromosomal rather than the interchromosomal type.