The Duffy antigen receptor for chemokines regulates asthma pathophysiology

BACKGROUND

The Duffy antigen receptor for chemokines (DARC) is an atypical receptor that regulates pro-inflammatory cytokines. However, the role of DARC in asthma pathophysiology is unknown.

OBJECTIVE

To determine the role of DARC in allergic airways disease in mice, and the association between DARC single nucleotide polymorphisms (SNPs) and clinical outcomes in patients with asthma.

METHODS

Mice with targeted disruption of the Darc gene (Darc∆E2 ) or WT mice were challenged over 3 weeks with house dust mite (HDM) antigen. Allergic airways disease was assessed 24 hours and 7 days following the final challenge. Additionally, associations between DARC SNPs and clinical outcomes were analysed in a cohort of poorly controlled asthmatics.

RESULTS

Total airway inflammation following HDM did not differ between Darc∆E2 and WT mice. At 24 hours, Darc∆E2 mice had increased airway hyperresponsiveness; however, at 7 days airway hyperresponsiveness had completely resolved in Darc∆E2 but persisted in WT mice. In poorly controlled asthmatics, DARC SNPs were associated with worse asthma control at randomization and subsequent increased risk of healthcare utilization (odds ratio 3.13(1.37-7.27), P=.0062).

CONCLUSIONS AND CLINICAL RELEVANCE

Our animal model and human patient data suggest a novel role for DARC in the temporal regulation in asthma pathophysiology and symptoms.

Effect of citrus juice and SLCO2B1 genotype on the pharmacokinetics of montelukast

Previously the authors found that a common polymorphism, rs12422149 (SLCO2B1{NM_007256.2}:c.935G>A), in the gene coding for OATP2B1, was associated with absorption of and response to montelukast in humans. In vitro studies showed that citrus juice could reduce the permeability of montelukast consistent with known inhibition of organic anion-transporting polypeptides. To study the clinical significance of c.935G>A, the authors conducted a single-dose, pharmacokinetic study of montelukast co-ingested with citrus juice. On average, co-ingestion with either orange juice or 4× concentrated grapefruit juice had a minimal effect on the area under the plasma concentration-time curve from time zero extrapolated to infinite time (AUC(0→∞)) of montelukast relative to co-ingestion with Gatorade control (n = 24). However when the data were stratified by genotype at c.935 (G/G n = 21, A/G n = 5), a significant reduction in AUC(0→∞) was detected with orange juice in G/G homozygotes (AUC(0→∞), G/G, Gatorade = 2560 ± 900 ng·h·mL(-1) vs AUC(0→∞), G/G, orange juice = 2010 ± 650 ng·h·mL(-1), P = .032). Significantly, A/G heterozygotes showed reduced AUC(0→∞) relative to G/G homozygotes, independent of treatment (AUC(0→∞), G/G, combined treatments = 2310 ± 820 ng·h·mL(-1) vs AUC(0→∞), A/G, combined treatments = 1460 ± 340 ng·h·mL(-1), P = 2.0 × 10(-5)) replicating previous observations.

Determination of human beta(2)-adrenoceptor haplotypes by denaturation selective amplification and subtractive genotyping

OBJECTIVE

beta(2)-Adrenoceptor haplotype may be better associated with asthma severity and drug response than a polymorphic variant at any single site. Because present methods of haplotype determination are time consuming and impractical for large population studies, we sought to develop a simple and efficient method of determining haplotype of 3 common polymorphisms at codons -19 (Arg/Cys), 16 (Arg/Gly) and 27 (Glu/Gln).

DESIGN

Preliminary studies showed that the C/G base pair of the Arg(-19) allele increases the local melting temperature over the T/A base pair of the Cys(-19) allele by 3.6 degrees C and establishes a new local maximum denaturation temperature. By choosing a suitable denaturation temperature and appropriate primers and coupling them with restriction fragment length polymorphism (RFLP) analysis, we hypothesized that the genotype of one separately amplified allele followed by subtraction from the combined genotype of two alleles would yield the beta(2) haplotype in > 99% of the population.

RESULTS

Haplotype determined by our method was in complete agreement with haplotype determined by cloning and sequencing in 29 samples. The frequencies of haplotype pairs in 78 healthy adults, according to our method, were in agreement with published values that were inferred, and were: RGE/CRQ, 26.9%; CRQ/CRQ, 25.6%; RGE/CGQ, 16.7%; CRQ/CGQ, 10.3%; RGE/RGE, 11.5%; CGQ/CGQ, 7.7%. The haplotype pair in one individual was RRE/CRQ (1.3%).

CONCLUSION

Our method of determining beta(2)-adrenoceptor haplotype is simple, accurate and cost effective for haplotyping large populations.

Heart-specific splice-variant of a human mitochondrial ribosomal protein (mRNA processing; tissue specific splicing)

It has been proposed that splice-variants of proteins involved in mitochondrial RNA processing and translation may be involved in the tissue specificity of mitochondrial DNA disease mutations (Fischel-Ghodsian, 1998. Mol. Genet. Metab. 65, 97-104). To identify and characterize the structural components of mitochondrial RNA processing and translation, the Mammalian Mitochondrial Ribosomal Consortium has been formed. The 338 amino acid (aa) residues long MRP-L5 was identified (O'Brien et al., 1999. J. Biol. Chem. 274, 36043-36051), and its transcript was screened for tissue specific splice-variants. Screening of the EST databases revealed a single putative splice-variant, due to the insertion of an exon consisting of 89 nucleotides prior to the last exon. Screening of multiple cDNA libraries revealed this inserted exon to be present only in heart tissue, in addition to the predominant MRP-L5 transcript. Sequencing of this region confirmed the EST sequence, and showed in the splice-variant a termination triplet at the beginning of the last exon. Thus the inserted exon replaces the coding sequence of the regular last exon, and creates a new 353 aa long protein (MRP-L5V1). Sequence analysis and 3D modeling reveal similarity between MRP-L5 and threonyl-t-RNA synthetases, and a likely RNA binding site within MRP-L5, with the C-terminus in proximity to the RNA binding site. Sequence analysis of MRP-L5V1 also suggests a likely transmembrane domain at the C-terminus. Thus it is possible that the MRP-L5V1 C-terminus could interfere with RNA binding and may have gained a transmembrane domain. Further studies will be required to elucidate the functional significance of MRP-L5V1.

Mammalian mitochondrial ribosomal proteins (4). Amino acid sequencing, characterization, and identification of corresponding gene sequences

Mitochondrial ribosomal proteins (MRPs) are required for the translation of all 13 mitochondrial encoded genes in humans. It has been speculated that mutations and polymorphisms in the human MRPs may be a primary cause of some oxidative phosphorylation disorders or modulate the severity and tissue specificity of pathogenic mitochondrial DNA mutations. Although the sequences of most of the yeast MRPs are known, only very few mammalian and nearly no human MRPs have been completely characterized. MRPs differ greatly in sequence, and sometimes biochemical properties, between different species, not allowing easy recognition by sequence homology. Therefore, the Mammalian Mitochondrial Ribosomal Consortium is using a direct approach of purifying individual mammalian (bovine) MRPs, determining their N-terminal and/or internal peptide sequences using different protein sequencing techniques, and using the resulting sequence information for screening expressed sequence tags and genomic data bases to determine human, mouse, and rat homologues of the bovine proteins. Two proteins of the large and three proteins of the small ribosomal subunit have been analyzed in this manner. Three of them represent "new," i.e. formerly unknown mammalian mitochondrial ribosomal protein classes. Only one of these three different MRPs shows significant sequence similarities to known ribosomal proteins. In one case, the corresponding human genomic DNA sequences were found in the data bases, and the exon/intron structure was determined.

Mammalian mitochondrial ribosomal proteins (2). Amino acid sequencing, characterization, and identification of corresponding gene sequences

Four different classes of mammalian mitochondrial ribosomal proteins were identified and characterized. Mature proteins were purified from bovine liver and subjected to N-terminal or matrix-assisted laser-desorption mass spectroscopic amino acid sequencing after tryptic in-gel digestion and high pressure liquid chromatography separation of the resulting peptides. Peptide sequences obtained were used to virtually screen expressed sequence tag data bases from human, mouse, and rat. Consensus cDNAs were assembled in silico from various expressed sequence tag sequences identified. Deduced mammalian protein sequences were characterized and compared with ribosomal protein sequences of Escherichia coli and yeast mitochondria. Significant sequence similarities to ribosomal proteins of other sources were detected for three out of four different mammalian protein classes determined. However, the sequence conservation between mitochondrial ribosomal proteins of mammalian and yeast origin is much less than the sequence conservation between cytoplasmic ribosomal proteins of the same species. In particular, this is shown for the mammalian counterparts of the E. coli EcoL2 ribosomal protein (MRP-L14), that do not conserve the specific and functional highly important His(229) residue of E. coli and the corresponding yeast mitochondrial Rml2p.

Expression of the components of the insulin-like growth factor axis across the growth-plate

Linear bone growth occurs as the result of proliferation and differentiation of growth-plate chondrocytes. These two phases of chondrocyte growth are regulated separately, with insulin-like growth factor I (IGF-I) being the primary stimulator of proliferation. We studied the expression of the components of the growth hormone GH/IGF system to learn if this proliferative signal is altered as chondrocytes undergo differentiation. Growth-plate chondrocytes were isolated from fetal cows and fractionated on discontinuous Percoll gradients. Five populations were recovered, ranging from high density cells (proliferative chondrocytes) to low density cells (hypertrophic chondrocytes). Messenger RNAs (mRNAs) were analyzed by a reverse transcriptase/quantitative polymerase chain reaction (RT/qPCR) technique. Results showed that mRNA of IGF-I and IGF-II in proliferative chondrocytes was 32 and five fold more abundant, respectively, than in hypertrophic chondrocytes. Of the four major IGF-I mRNA transcripts, the class 1-Ea transcript was predominant. Messenger RNA levels for IGFBP-3, -4, and -5 were also reduced in hypertrophic chondrocytes. Levels of GH receptor, the type 1 IGF receptor, and IGF binding protein-2 (IGFBP-2) mRNAs were unchanged across the growth-plate. Since IGF-I and -II are potent stimulators of proliferation, the down-regulation of these genes may be necessary in order for hypertrophy to proceed.

Virtually the entire Xenopus laevis rDNA multikilobase intergenic spacer serves to stimulate polymerase I transcription

The promoter-distal half of the spacer separating the tandem Xenopus laevis rRNA genes consists of "0" and "1" repetitive elements that have been considered unimportant in polymerase I transcriptional activation. Utilizing oocyte microinjection, we now demonstrate that the 0/1 region, as well as its component 0 and 1 repeats, substantially stimulate transcription from a ribosomal promoter in cis and inhibit transcription when located in trans. Both the cis and trans responses increase linearly with increasing numbers of 0 or 1 repeats until saturation is approached. The 0/1 block and its component elements stimulate transcription in both orientations, over distances, and when placed downstream of the initiation site, properties for which the 60/81-base pair (bp) repeats have been defined as polymerase I enhancers. In their natural promoter-distal rDNA location, the 0/1 repeats can stimulate transcription from the rRNA gene promoter, above the level afforded by the intervening 60/81-bp repeats and spacer promoter. In addition, as with the 60/81-bp repeats, the 0/1 repeats bind a factor in common with the rDNA promoter. Thus, the entire X. laevis rDNA intergenic spacer (the 0 repeats, 1 repeats, spacer promoter repeats, and 60/81-bp repeats) acts together to enhance ribosomal transcription.

Metazoan rDNA enhancer acts by making more genes transcriptionally active

Enhancers could, in principle, function by increasing the rate of reinitiation on individual adjacent active promoters or by increasing the probability that an adjacent promoter is activated for transcription. We have addressed this issue for the repetitive metazoan rDNA enhancer by microinjecting Xenopus oocytes with enhancer-less and enhancer-bearing genes and determining by EM the frequency that each gene type forms active transcription units and their transcript density. We use conditions where transcription requires the normal rDNA promoter and is stimulated 30-50-fold by the enhancer. (In contrast, at saturating template conditions as used in previous EM studies, an aberrant mode of transcription is activated that is not affected by the rDNA enhancer or by the generally recognized rDNA promoter). The active transcription units on enhancer-less genes are found to be as densely packed with nascent transcripts and polymerases as those on enhancer-bearing genes and on the endogenous rRNA genes. Significantly, the enhancer-bearing genes are approximately 30-50-fold more likely to form such active transcription units than enhancer-less genes, consistent with their amounts of transcript. Complementary studies confirm that the enhancer does not affect elongation rate, the stability of the transcription complex, or transcript half-life. These data demonstrate that the repetitive metazoan rDNA enhancer causes more genes to be actively transcribed and does not alter the reinitiation rate on individual active genes.

A U3 small nuclear ribonucleoprotein-requiring processing event in the 5' external transcribed spacer of Xenopus precursor rRNA

A processing site has been identified within the 5' external transcribed spacer (ETS) of Xenopus laevis and X. borealis pre-RNAs, and this in vivo processing can be reproduced in vitro. It involves a stable and specific association of the pre-rRNA with factors in the cell extract, including at least four RNA-contacting polypeptides, yielding a distinct complex that sediments at 20S. Processing also requires the U3 small nuclear RNA. This processing, at residue +105 of the 713-nucleotide X. laevis 5' ETS, is highly reminiscent of the initial processing cleavage of mouse pre-rRNA within its 3.5-kb 5' ETS, previously thought to be mammal specific. The frog and mouse processing signals share a short essential sequence motif, and mouse factors can faithfully process the frog pre-rRNA. This conservation suggests that this 5' ETS processing site serves an evolutionarily selective function.

The terminal balls characteristic of eukaryotic rRNA transcription units in chromatin spreads are rRNA processing complexes

When spread chromatin is visualized by electron microscopy, active rRNA genes have a characteristic Christmas tree appearance: From a DNA "trunk" extend closely packed "branches" of nascent transcripts whose ends are decorated with terminal "balls." These terminal balls have been known for more than two decades, are shown in most biology textbooks, and are reported in hundreds of papers, yet their nature has remained elusive. Here, we show that a rRNA-processing signal in the 5'-external transcribed spacer (ETS) of the Xenopus laevis ribosomal primary transcript forms a large, processing-related complex with factors of the Xenopus oocyte, analogous to 5' ETS processing complexes found in other vertebrate cell types. Using mutant rRNA genes, we find that the same rRNA residues are required for this biochemically defined complex formation and for terminal ball formation, analyzed electron microscopically after injection of these cloned genes into Xenopus oocytes. This, plus other presented evidence, implies that rRNA terminal balls in Xenopus, and by inference, also in the multitude of other species where they have been observed, are the ultrastructural visualization of an evolutionarily conserved 5' ETS processing complex that forms on the nascent rRNA.

Wheat germ and yeast RNA polymerase II: photoaffinity labeling by 4-thiouracil 5'-monophosphate positioned uniquely at the 3' end of an enzyme-bound [32P]-containing transcript

A stable ternary transcription complex was formed with either wheat germ or yeast RNA polymerase II using a ribotrinucleotide primer (GpCpG) to initiate transcription on a short synthetic single-strand DNA template. The template was designed to limit the incorporation of a photoprobe S4-UMP (4-thio-UMP) to a unique position at the 3' terminus of the transcript. The resulting stable ternary transcription complex was photolyzed to cross-link the bound transcript ([32P]-labeled by the incorporation of [alpha-32P]CMP) with the protein domain at or near the active site. Separation of the protein components by electrophoresis in polyacrylamide gel containing SDS and analysis by autoradiography and silver staining revealed that for either enzyme only the largest subunit was [32P] labeled.

Expression of mouse and frog rRNA genes: transcription and processing

This article summarizes a number of lines of investigation of rRNA gene expression that are ongoing in the laboratory. These studies focus on mouse and frog, two distant vertebrate species. One major conclusion is that the basic properties of rRNA gene expression appear remarkably well conserved in evolution, with only relatively minor perturbations between frog and mouse, contrary to the common interpretation of the species-selectively between mouse and human rDNA transcription (e.g., 1). This is true both for the process of rDNA transcription and for the subsequent rRNA processing event.

News from the nucleolus: rRNA gene expression

Although the typical, actively growing eukaryotic cell contains over 10,000 different transcripts, half of its RNA synthetic capacity is devoted to the production of a single kind of RNA. This is the pre-ribosomal RNA, which is synthesized in a special compartment of the nucleus, the nucleolus, and is the exclusive product of transcription by RNA polymerase I. In vivo and in vitro approaches have revealed the major features of rRNA gene transcription and of the subsequent processing of the primary transcript.

The Xenopus ribosomal DNA 60- and 81-base-pair repeats are position-dependent enhancers that function at the establishment of the preinitiation complex: analysis in vivo and in an enhancer-responsive in vitro system

Although it is generally believed that the 60- and 81-base-pair (60/81-bp) repeats of the Xenopus laevis ribosomal DNA (rDNA) spacer are position-independent transcriptional enhancers, this has not been shown directly. We have now developed a critical assay which proves that the 60/81-bp repeats do, in fact, stimulate transcription from promoters in cis and that they function in both orientations and when up to 1 kilobase pair from the initiation site. However, contrary to the widely accepted view, these elements are found to be highly position dependent, for they have no net effect when downstream of the initiation site within the transcribed region and they behave as transcriptional silencers of promoters in cis when moved greater than 2 kilobase pairs upstream of the initiation site. The 60/81-bp elements therefore are position-dependent 5' enhancers. We also found that this rDNA enhancer was polymerase I specific and that it was composed of duplicated, individually functional elements. Finally, we report an in vitro system that reproduces both cis enhancement and trans competition by the 60/81-bp repeats. Sequential-addition studies in this system demonstrated that the rDNA enhancer functions in trans at or before establishment of the stable transcription complex, not subsequently at each round of transcription.

Formation and characterization of precise eucaryotic transcription complexes using a semisynthetic DNA template and specific oligoribonucleotide primers

An artificial template of defined sequence which supports specific in vitro initiation and elongation by yeast RNA polymerase II has been constructed. This template is a pBR322 derivative which contains a synthetic oligonucleotide inserted into the BamHI cloning site. The sequence of this oligonucleotide is such that when the plasmid is restricted with SacI the two ends obtained are identical. The addition of an oligodeoxycytidylate chain to the 3' hydroxy termini produces a DNA template, (poly dC-p+22), with the sequence: 3'(C)nTCGA-GAGTCTCCTA. . . . The underlined position denotes the beginning of the duplex region. When initiation is primed with the diribonucleotide GpC the predicted sequence of the transcript obtained is: 5'GCUCUCAGAGGAU. . . . Kinetic and product analyses indicate that a ternary complex containing a precise length of transcript can be produced which is subsequently resistant to heparin inactivation. Initiation can also be directed to a specific position dictated by a tri or tetraribonucleotide primer.