Metabolic and neurobehavioral disturbances induced by purine recycling deficiency in Drosophila

Adenine phosphoribosyltransferase (APRT) and hypoxanthine-guanine phosphoribosyltransferase (HGPRT) are two structurally related enzymes involved in purine recycling in humans. Inherited mutations that suppress HGPRT activity are associated with Lesch-Nyhan disease (LND), a rare X-linked metabolic and neurological disorder in children, characterized by hyperuricemia, dystonia, and compulsive self-injury. To date, no treatment is available for these neurological defects and no animal model recapitulates all symptoms of LND patients. Here, we studied LND-related mechanisms in the fruit fly. By combining enzymatic assays and phylogenetic analysis, we confirm that no HGPRT activity is expressed in Drosophila melanogaster, making the APRT homolog (Aprt) the only purine-recycling enzyme in this organism. Whereas APRT deficiency does not trigger neurological defects in humans, we observed that Drosophila Aprt mutants show both metabolic and neurobehavioral disturbances, including increased uric acid levels, locomotor impairments, sleep alterations, seizure-like behavior, reduced lifespan, and reduction of adenosine signaling and content. Locomotor defects could be rescued by Aprt re-expression in neurons and reproduced by knocking down Aprt selectively in the protocerebral anterior medial (PAM) dopaminergic neurons, the mushroom bodies, or glia subsets. Ingestion of allopurinol rescued uric acid levels in Aprt-deficient mutants but not neurological defects, as is the case in LND patients, while feeding adenosine or N6-methyladenosine (m6A) during development fully rescued the epileptic behavior. Intriguingly, pan-neuronal expression of an LND-associated mutant form of human HGPRT (I42T), but not the wild-type enzyme, resulted in early locomotor defects and seizure in flies, similar to Aprt deficiency. Overall, our results suggest that Drosophila could be used in different ways to better understand LND and seek a cure for this dramatic disease.

Drosophila ammonium transporter Rh50 is required for integrity of larval muscles and neuromuscular system

Rhesus glycoproteins (Rh50) have been shown to be ammonia transporters in many species from bacteria to human. They are involved in various physiological processes including acid excretion and pH regulation. Rh50 proteins can also provide a structural link between the cytoskeleton and the plasma membranes that maintain cellular integrity. Although ammonia plays essential roles in the nervous system, in particular at glutamatergic synapses, a potential role for Rh50 proteins at synapses has not yet been investigated. To better understand the function of these proteins in vivo, we studied the unique Rh50 gene of Drosophila melanogaster, which encodes two isoforms, Rh50A and Rh50BC. We found that Drosophila Rh50A is expressed in larval muscles and enriched in the postsynaptic regions of the glutamatergic neuromuscular junctions. Rh50 inactivation by RNA interference selectively in muscle cells caused muscular atrophy in larval stages and pupal lethality. Interestingly, Rh50-deficiency in muscles specifically increased glutamate receptor subunit IIA (GluRIIA) level and the frequency of spontaneous excitatory postsynaptic potentials. Our work therefore highlights a new role for Rh50 proteins in the maintenance of Drosophila muscle architecture and synaptic physiology, which could be conserved in other species.

The lysosomal membrane protein LAMP2A promotes autophagic flux and prevents SNCA-induced Parkinson disease-like symptoms in the Drosophila brain

The autophagy-lysosome pathway plays a fundamental role in the clearance of aggregated proteins and protection against cellular stress and neurodegenerative conditions. Alterations in autophagy processes, including macroautophagy and chaperone-mediated autophagy (CMA), have been described in Parkinson disease (PD). CMA is a selective autophagic process that depends on LAMP2A (lysosomal-associated membrane protein 2A), a mammal and bird-specific membrane glycoprotein that translocates cytosolic proteins containing a KFERQ-like peptide motif across the lysosomal membrane. Drosophila reportedly lack CMA and use endosomal microautophagy (eMI) as an alternative selective autophagic process. Here we report that neuronal expression of human LAMP2A protected Drosophila against starvation and oxidative stress, and delayed locomotor decline in aging flies without extending their lifespan. LAMP2A also prevented the progressive locomotor and oxidative defects induced by neuronal expression of PD-associated human SNCA (synuclein alpha) with alanine-to-proline mutation at position 30 (SNCAA30P). Using KFERQ-tagged fluorescent biosensors, we observed that LAMP2A expression stimulated selective autophagy in the adult brain and not in the larval fat body, but did not increase this process under starvation conditions. Noteworthy, we found that neurally expressed LAMP2A markedly upregulated levels of Drosophila Atg5, a key macroautophagy initiation protein, and that it increased the density of Atg8a/LC3-positive puncta, which reflects the formation of autophagosomes. Furthermore, LAMP2A efficiently prevented accumulation of the autophagy defect marker Ref(2)P/p62 in the adult brain under acute oxidative stress. These results indicate that LAMP2A can potentiate autophagic flux in the Drosophila brain, leading to enhanced stress resistance and neuroprotection.

ABBREVIATIONS

Act5C: actin 5C; a.E.: after eclosion; Atg5: autophagy-related 5; Atg8a/LC3: autophagy-related 8a; CMA: chaperone-mediated autophagy; DHE: dihydroethidium; elav: embryonic lethal abnormal vision; eMI: endosomal microautophagy; ESCRT: endosomal sorting complexes required for transport; GABARAP: GABA typeA receptor-associated protein; Hsc70-4: heat shock protein cognate 4; HSPA8/Hsc70: heat shock protein family A (Hsp70) member 8; LAMP2: lysosomal associated membrane protein 2; MDA: malondialdehyde; PA-mCherry: photoactivable mCherry; PBS: phosphate-buffered saline; PCR: polymerase chain reaction; PD: Parkinson disease; Ref(2)P/p62: refractory to sigma P; ROS: reactive oxygen species; RpL32/rp49: ribosomal protein L32; RT-PCR: reverse transcription polymerase chain reaction; SING: startle-induced negative geotaxis; SNCA/α-synuclein: synuclein alpha; SQSTM1/p62: sequestosome 1; TBS: Tris-buffered saline; UAS: upstream activating sequence.

Functional interaction between CFTR and the sodium-phosphate co-transport type 2a in Xenopus laevis oocytes

Background

A growing number of proteins, including ion transporters, have been shown to interact with Cystic Fibrosis Transmembrane conductance Regulator (CFTR). CFTR is an epithelial chloride channel that is involved in Cystic Fibrosis (CF) when mutated; thus a better knowledge of its functional interactome may help to understand the pathophysiology of this complex disease. In the present study, we investigated if CFTR and the sodium-phosphate co-transporter type 2a (NPT2a) functionally interact after heterologous expression of both proteins in Xenopus laevis oocytes.

Methodology/Findings

NPT2a was expressed alone or in combination with CFTR in X. laevis oocytes. Using the two-electrode voltage-clamp technique, the inorganic phosphate-induced current (IPi) was measured and taken as an index of NPT2a activity. The maximal IPi for NPT2a substrates was reduced when CFTR was co-expressed with NPT2a, suggesting a decrease in its expression at the oolemna. This was consistent with Western blot analysis showing reduced NPT2a plasma membrane expression in oocytes co-expressing both proteins, whereas NPT2a protein level in total cell lysate was the same in NPT2a- and NPT2a+CFTR-oocytes. In NPT2a+CFTR- but not in NPT2a-oocytes, IPi and NPT2a surface expression were increased upon PKA stimulation, whereas stimulation of Exchange Protein directly Activated by cAMP (EPAC) had no effect. When NPT2a-oocytes were injected with NEG2, a short amino-acid sequence from the CFTR regulatory domain that regulates PKA-dependent CFTR trafficking to the plasma membrane, IPi values and NPT2a membrane expression were diminished, and could be enhanced by PKA stimulation, thereby mimicking the effects of CFTR co-expression.

Conclusion/Perspectives

We conclude that when both CFTR and NPT2a are expressed in X. laevis oocytes, CFTR confers to NPT2a a cAMPi-dependent trafficking to the membrane. This functional interaction raises the hypothesis that CFTR may play a role in phosphate homeostasis.

Structural involvement in substrate recognition of an essential aspartate residue conserved in Mep/Amt and Rh-type ammonium transporters

Ammonium transport proteins belonging to the Mep/Amt/Rh family are spread throughout all domains of life. A conserved aspartate residue plays a key role in the function of Escherichia coli AmtB. Here, we show that the analogous aspartate residue is critical for the transport function of eukaryotic family members as distant as the yeast transporter/sensor Mep2 and the human RhAG and RhCG proteins. In yeast Mep2, replacement of aspartate(186) with asparagine produced an inactive transporter localized at the cell surface, whilst replacement with alanine was accompanied by stacking of the protein in the endoplasmic reticulum. Introduction of an acidic residue, glutamate, produced a partially active protein. A carboxyl group at position 186 of Mep2 therefore appears mandatory for function. Kinetic analysis shows the Mep2(D186E) variant to be particularly affected at the level of substrate affinity, suggesting an involvement of aspartate(186) in ammonium recognition. Our data also put forward that ammonium recognition and/or transport by Mep2 is required for the sensor role played in the development of pseudohyphal growth. Finally, replacement of the conserved aspartate with asparagine in human RhAG and RhCG proteins resulted in the loss of bi-directional transport function. Hence, this aspartate residue might play a preserved functional role in Mep/Amt/Rh proteins.

Expression of the human erythroid Rh glycoprotein (RhAG) enhances both NH3 and NH4+ transport in HeLa cells

The erythroid Rh-associated glycoprotein (RhAG) is strictly required for the expression of the Rh blood group antigens carried by Rh (D,CE) proteins. A biological function for RhAG in ammonium transport has been suggested by its ability to improve survival of an ammonium-uptake-deficient yeast. We investigated the function of RhAG by studying the entry of NH3/NH4+ in HeLa cells transiently expressing the green fluorescent protein (GFP)-RhAG fusion protein and using a fluorescent proton probe to measure intracellular pH (pHi). Under experimental conditions that reduce the intrinsic Na/H exchanger activity, exposure of control cells to a 10 mM NH4Cl- containing solution induces the classic pHi response profile of cells having a high permeability to NH3 (PNH3) but relatively low permeability to NH4+ (PNH4). In contrast, under the same conditions, the pHi profile of cells expressing RhAG clearly indicated an increased PNH4, as evidenced by secondary reacidification during NH4Cl exposure and a pHi undershoot below the initial resting value upon its removal. Measurements of pHi during methylammonium exposure showed that RhAG expression enhances the influx of both the unprotonated and ionic forms of methylammonium. Using a mathematical model to adjust passive permeabilities for a fit to the pHi profiles, we found that RhAG expression resulted in a threefold increase of PNH4 and a twofold increase of PNH3. Our results are the first evidence that the human erythroid RhAG increases the transport of both NH3 and NH4+.

NH3 is involved in the NH4+ transport induced by the functional expression of the human Rh C glycoprotein

Renal ammonium (NH3 + NH4+) transport is a key process for body acid-base balance. It is well known that several ionic transport systems allow NH4+ transmembrane translocation without high specificity NH4+, but it is still debated whether NH3, and more generally, gas, may be transported by transmembrane proteins. The human Rh glycoproteins have been proposed to mediate ammonium transport. Transport of NH4+ and/or NH3 by the epithelial Rh C glycoprotein (RhCG) may be of physiological importance in renal ammonium excretion because RhCG is mainly expressed in the distal nephron. However, RhCG function is not yet established. In the present study, we search for ammonium transport by RhCG. RhCG function was investigated by electrophysiological approaches in RhCG-expressing Xenopus laevis oocytes. In the submillimolar concentration range, NH4Cl exposure induced inward currents (IAM) in voltage-clamped RhCG-expressing cells, but not in control cells. At physiological extracellular pH (pHo) = 7.5, the amplitude of IAM increased with NH4Cl concentration and membrane hyperpolarization. The amplitude of IAM was independent of external Na+ or K+ concentrations but was enhanced by alkaline pHo and decreased by acid pHo. The apparent affinity of RhCG for NH4+ was affected by NH3 concentration and by changing pHo, whereas the apparent affinity for NH3 was unchanged by pHo, consistent with direct NH3 involvement in RhCG function. The enhancement of methylammonium-induced current by NH3 further supported this conclusion. Exposure to 500 microm NH4Cl induced a biphasic intracellular pH change in RhCG-expressing oocytes, consistent with both NH3 and NH4+ enhanced influx. Our results support the hypothesis of a specific role for RhCG in NH3 and NH4+ transport.

The human Rhesus-associated RhAG protein and a kidney homologue promote ammonium transport in yeast

The Rhesus blood-group antigens are defined by a complex association of membrane polypeptides that includes the non-glycosylated Rh proteins (RhD and RhCE) and the RHag glycoprotein, which is strictly required for cell surface expression of these antigens. RhAG and the Rh polypeptides are erythroid-specific transmembrane proteins belonging to the same family (36% identity). Despite their importance in transfusion medicine, the function of RhAG and Rh proteins remains unknown, except that their absence in Rh(null) individuals leads to morphological and functional abnormalities of erythrocytes, known as the Rh-deficiency syndrome. We recently found significant sequence similarity between the Rh family proteins, especially RhAG, and Mep/Amt ammonium transporters. We show here that RhAG and also RhGK, a new human homologue expressed in kidney cells only, function as ammonium transport proteins when expressed in yeast. Both specifically complement the growth defect of a yeast mutant deficient in ammonium uptake. Moreover, ammonium efflux assays and growth tests in the presence of toxic concentrations of the analogue methylammonium indicate that RhAG and RhGK also promote ammonium export. Our results provide the first experimental evidence for a direct role of RhAG and RhGK in ammonium transport. These findings are of high interest, because no specific ammonium transport system has been characterized so far in human.

The members of the RH gene family (RH50 and RH30) followed different evolutionary pathways

The evolution of the RH gene family is characterized by two major duplication events, the first one originating the RH50 and RH30 genes and the second one giving rise to RHCE and RHD, the two paralogous RH30 genes which encode the Rh blood group antigens in human. The new sequence data obtained here for mouse RH50 and RH30 and for macaque RH50 allowed us to compare the evolutionary rates of the two genes and to show that RH50 evolved about 2.6 times more slowly than RH30 at nonsynonymous positions. This result implies that Rh50 proteins were evolutionarily more conserved compared to Rh30 polypeptides, thus being indicative of the functional significance of the former protein in species as distantly related as sponge and human. The duplication event leading to RH50 and RH30 genes was estimated to have occurred between 250 and 346 million years ago. Moreover, we could also estimate that the duplication event producing the RHCE and RHD genes occurred some 8.5 +/- 3.4 million years ago, in the common ancestor of human, chimpanzee, and gorilla. Interestingly, this event seems to coincide with the appearance in these species of a G-to-T mutation in the RH50 gene which created a stop codon in the corresponding transcript. This led to an Rh50 C-terminal cytoplasmic domain shorter than that found in orangutan and early primates.

Rh-deficiency of the regulator type caused by splicing mutations in the human RH50 gene

The Rh polypeptides and the glycoproteins Rh50, CD47, LW, and glycophorin B, which interact in the red blood cell membrane to form a multisubunit complex, are lacking or are severely reduced in the Rh-deficiency syndrome. We previously reported that in several Rhnull patients the RH50 gene was altered at the coding sequence level, resulting in either a single amino acid substitution or the synthesis of a truncated polypeptide. In the present report, we have detected two mutations in the intronic region of the RH50 gene that identify a new molecular mechanism involved in Rh-deficiency. The first mutation affected the invariant G residue of the 3' acceptor splice-site of intron 6, causing the skipping of the downstream exon and the premature termination of translation. The second mutation occurred at the first base of the 5' donor splice-site of intron 1. Both these mutations were found in homozygote state. RNase protection assays demonstrated that the Rh50 mRNA level was strongly reduced or undetectable in the 3' and 5' splice mutants, respectively. The different mutations affecting the RH50 gene are indicative of an heterogeneous mutational pattern, which further supports the hypothesis that the lack of the Rh50 protein may prevent the assembly or transport of the Rh membrane complex to the red blood cell surface.

Shift from Rh-positive to Rh-negative phenotype caused by a somatic mutation within the RHD gene in a patient with chronic myelocytic leukaemia

We report a female patient whose Rh phenotype shifted from RhD-positive to RhD-negative over a 3-year period (1991-94), during which time she was treated with mastectomy (1992) and local irradiation for a low-grade recurrent breast cancer. She was diagnosed with chronic myeloid leukaemia in 1994, and has since then received chemotherapy. The patient was repeatedly typed as O, RhD-positive between 1965 and 1991 and was repeatedly found RhD-negative after 1994. Bcr-Abl transcripts typical of Ph1 chromosome were detected. Molecular analysis indicated that the patient was heterozygous at the RH locus, carrying one haplotype in which the RHD gene exhibited a single nucleotide deletion (G600) resulting in a frameshift and premature stop codon, and a normal RHCE gene (allele Ce). The second haplotype contained only the RHCE gene (allele ce) and was normal. Further analysis carried out on total leucocytes, purified neutrophils, EBV-lymphoblastoid cell line and cultured erythroblasts indicated that the G600 deletion was restricted to the myeloid lineage. No modification of other blood group antigens could be detected. These findings suggest a somatic mutation which most probably occurred in a stem cell common to the myeloid lineage.

Molecular defects of the RHCE gene in Rh-deficient individuals of the amorph type

The deficiency of Rh proteins on the red blood cells from individuals of the Rhnull amorph type may be the result of homozygosity for a silent allele at the RH locus. This phenotype is also associated with the lack or reduced expression of glycoproteins (Rh50, CD47, LW, and glycophorin B), which interact with Rh polypeptides to form the multisubunit Rh membrane complex. In this study, we describe two molecular alterations affecting the RHCE gene in two unrelated Rhnull amorph individuals bearing Rh50 and CD47 normal transcripts. The first type of mutation, located at the donor splice-site in intron 4, induced the activation of two cryptic splice-sites within this intron and one such site in exon 4 that all generated aberrant transcripts. The second type of mutation affected the coding region and introduced a frameshift and a premature stop codon resulting in a shorter predicted protein (398 v 417 residues), including a completely different C-terminus of 76 amino acids. This suggests that protein folding and/or protein-protein interaction mediated by the C-terminal domain of the Rh proteins may play a role in the routing and/or stability of the Rh membrane complex.

A novel single missense mutation identified along the RH50 gene in a composite heterozygous Rhnull blood donor of the regulator type

Rare individuals who lack all of the Rh blood group antigens are called Rhnull and may be classified as "regulator" or "amorph" types. The suppression of Rh antigen expression for regulator types may be attributed to mutations of the RH50 gene, which is independent of the RH locus. The RH50 gene encodes a glycoprotein that interacts with the Rh proteins to form a functional complex within the red blood cell membrane. This report describes an RH50 gene mutation for a previously unclassified Rhnull donor. Sequencing cDNA clones from Rh50 mRNA revealed a single base change (G836A) yielding a missense and nonconservative mutation (Gly279Glu) within a predicted hydrophobic domain for this membrane protein. Genomic DNA studies using polymerase chain reaction (PCR) restriction analysis and sequencing showed that the Rhnull propositus was a composite heterozygote for this mutation, carrying two alleles with the A and G at nucleotide 836, respectively. In contrast, cDNA studies showed that only the A836 sequence was present, suggesting that the second allele with G836 was apparently silent (no transcript detected). Family studies showed that the mutant RH50 allele (836A) was inherited maternally, whereas the silent RH50 allele (836G) was from paternal transmission. These findings provide further evidence that rare but diverse genetic alterations may occur along the RH50 gene where the Rhnull syndrome of the regulator type occurs. The single amino acid change (Gly to Glu) provides insight into the critical value of these residues for assembly of the Rh antigen complex within the membrane.

Organization of the human RH50A gene (RHAG) and evolution of base composition of the RH gene family

Human Rh (rhesus) antigens are expressed in the red cell membrane as a multi-subunit complex, the central core of which is presumably composed of a tetramer made of two Rh and two Rh50 protein subunits. The interaction between Rh and Rh50 polypeptides is thought to be crucial to the correct assembly and transport of the complex to the cell surface. Here, we show that the human RH50A gene (RHAG) is composed of 10 exons whose size and exon/intron junctions are well conserved compared to those of the RH genes. We have also analyzed the RH50A 5' flanking region where the transcription initiation site has been identified. These results conclusively establish that the RH50A and RH genes do belong to the same gene family. Moreover, we show that the RH50A and RH genes are embedded in different compositional genomic contexts (i.e., different isochores) that are likely to drive the evolution of these genes, the base compositions (G + C content) of which differ drastically. Finally, we propose a scenario in which an RH50-like gene is likely to have played a founding role in the evolution of the RH gene family.

Characterization of the recombination hot spot involved in the genomic rearrangement leading to the hybrid D-CE-D gene in the D(VI) phenotype

In the Caucasian population, the RH locus of RhD-positive individuals is composed of two homologous genes, RHD and RHCE, arranged in tandem but of a single gene, RHCE, in RhD-negative individuals. Many variants recently characterized carry rearranged RH genes, most often by an unidirectional segmental DNA-exchange (gene-conversion) event. In D(VI) variants of type II, RHD is a D-CE-D hybrid gene in which the DNA fragment carrying exons 4-6 has been replaced by the corresponding sequences from the RHCE gene. To identify precisely and characterize the two transition sites, we have studied, by both PCR and sequence analysis, a genomic region between the 3' end of intron 3 and exon 7 in normal RHCE and RHD genes as well as in D(VI) DNA. We show that the D-CE breakpoint is located in intron 3, within a 250-bp fragment comprising an Alu S sequence, and that the CE-D breakpoint lies within a 39-bp fragment in intron 6. This Alu S sequence (and the 100-bp region immediately downstream) most likely defines a recombination hot spot, since there lies also the 5' breakpoint of different rearrangement events leading to D-CE and CE-D transitions in hybrid D(VI),DFR and Dc-,R(N) gene complexes, respectively.

Molecular analysis of the structure and expression of the RH locus in individuals with D--, Dc-, and DCw- gene complexes

Rh blood group antigens of the D, C/c, and E/e series are carried by at least three red cell membrane polypeptides encoded by two highly related genes, RHD and RHCE. Homozygous individuals carrying the D--, Dc-, and DCw- gene complexes are characterized by a total or partial lack of expression of the RHCE-encoded antigens. Analysis of the molecular genetic basis of these rare conditions indicates that complete or partial expression defect of Cc/Ee antigens result from different alterations at the RH locus, but not from gross deletions. No rearrangement or mutation of the RHCE gene could be detected in donors homozygous for the D-- complex, suggesting that the lack of the Cc and Ee antigens might result from a reduced transcriptional activity of the RHCE gene. The Dc- and DCw- gene complexes, however, exhibited an important rearrangement of the RHCE gene. Instead of the normal RHCE gene, both variants carried a hybrid RHCE-D-CE gene in which exons 4 to 9 (Dc- complex) and 2 (or 3) to 9 (DCw- complex) of the RHCE gene, respectively, have been substituted by the equivalent region of the RHD gene. These gene conversion events provide an explanation for the well-described abnormal antigen profiles associated with the Dc- and DCw- complexes, like the increased expression of RhD, the reduced expression of RhC/c or RhCw, and the absence of RhE/e.

Chimpanzee Rh-like blood group genes map to chromosome region 1p36.1-->p34.2 by in situ hybridization

A human Rh cDNA probe was used to map the Rh-like genes in the chimpanzee. The data gathered made it possible to uniquely localize these genes to chimpanzee chromosome region 1p36.1-->p34.2. This chromosomal localization is homologous to the location of the Rh genes in the human genome.

Organization of the gene (RHCE) encoding the human blood group RhCcEe antigens and characterization of the promoter region

The human RH (rhesus) locus is composed of two genes, RHD and RHCE, encoding the D, Cc, and Ee blood group antigens. The RHCE gene was isolated from a human genomic library and characterized. It is organized into 10 exons distributed over 75 kb. Exons 4-8 are alternatively spliced in the different RNA isoforms previously identified. Primer extension analysis indicated that the transcription initiation site is located 83 bp upstream of the initiation codon. The 5' flanking region of the RHCE gene, from nucleotide -600 to +42, exhibited a significant transcriptional activity after transfection in the erythroleukemic cell line K562, but not in the nonhematopoietic cell line HeLa. This result was in agreement with Northern blot analysis, suggesting that the expression of the RH locus is restricted to the erythroid/megakaryocytic lineage. Accordingly, putative binding sites for SP1, GATA-1, and Ets proteins, nuclear factors known to be involved in the erythroid and megakaryocytic gene expression, were identified in this Rh promoter.

Molecular genetic basis of the human Rhesus blood group system

The Rhesus (RH) blood group locus is composed of two related structural genes, D and CcEe, that encode red cell membrane proteins carrying the D, Cc and Ee antigens. As demonstrated previously, the RhD-positive/RhD-negative polymorphism is associated with the presence or the absence of the D gene. Sequence analysis of transcripts and genomic DNA from individuals that belong to different Rh phenotypes were performed to determine the molecular basis of the C/c and E/e polymorphisms. The E and e alleles differ by a single nucleotide resulting in a Pro226Ala substitution, whereas the C and c alleles differ by six nucleotides producing four amino acid substitutions Cys16Trp, Ile60Leu, Ser68Asn and Ser103Pro. With the recent cloning of the RhD gene, these findings provide the molecular genetic basis that determine D, C, c, E and e specificities.

Prenatal determination of fetal RhD type by DNA amplification

BACKGROUND

An RhD-negative woman whose partner is heterozygous may have preexisting anti-RhD antibodies that may or may not affect a subsequent fetus, depending on whether it is heterozygous. A safe method of determining fetal RhD type early in pregnancy would eliminate the risks to an RhD-negative fetus of fetal-blood sampling or serial amniocenteses.

METHODS

We determined the RhD type in 15 fetuses using the polymerase chain reaction in amniotic cells and serologic methods in fetal blood collected simultaneously. In another 15 fetuses, the RhD type determined from chorionic-villus samples was compared with that identified by typing of DNA from the fetus itself.

RESULTS

RhD typing of DNA from amniotic cells correctly indicated the serologic type in every fetus. Of 10 fetuses with RhD-negative mothers, 4 were identified as RhD-negative and 6 as RhD-positive. Of five fetuses with RhD-positive mothers, four were identified as RhD-positive and one as RhD-negative. There was also complete agreement between the results of RhD typing of DNA from chorionic-villus samples and the results of typing of DNA from fetal tissue. Eleven fetuses were RhD-positive, and 4 were RhD-negative. Four RhD-positive fetuses had RhD-negative mothers. Three RhD-negative fetuses had RhD-positive mothers. There was no contamination by maternal RhD-positive DNA of the samples from RhD-negative fetuses.

CONCLUSIONS

Determining fetal RhD type in amniotic cells without invading the fetomaternal circulation is a reliable method that will be valuable in the management of Rh alloimmunization.

Structure and expression of the RH locus in the Rh-deficiency syndrome

Red blood cell deficiency of Rh proteins is associated with morphologic and functional abnormalities of erythrocytes and with a chronic hemolytic anemia of varying severity. Rh-deficiency may be the result of homozygosity either for a silent allele at the RH locus (Rhnull amorph type) or for a recessive inhibitor gene(s) at an autosomal locus unlinked to RH locus (Rhnull regulator and Rhmod). In this report, we investigated the RH locus structure of Rh-deficient individuals by Southern analysis using cDNA and exon-specific probes deduced from the recent cloning of Rh genes (CcEe and D). As expected from family studies indicating that Rhmod and Rhnull regulator individuals are unable to express Rh antigens but are able to convey functional Rh genes from one generation to another, no alteration of the Rh genes was detected in these variants. Although Rhnull of the amorph type arose by inheritance of a pair of silent alleles at the RH locus, the general organization of the unique CcEe gene in the genome of the particular individual under examination was apparently normal and indistinguishable from a Rh-negative chromosome. More surprisingly, no mutation could be detected by sequencing the polymerase chain reaction (PCR)-amplified reticulocyte mRNAs, suggesting that the RH locus of this patient might be altered in its transcriptional activity. Through hybridization with exon-specific probes, we were also able to determine the zygosity for the D gene in DNA samples from individuals of known genotypes; using this approach, we found that Rhnull regulator variants could be either of the DD, Dd, or dd genotypes. These findings suggest that the postulated inhibitor gene(s) can negatively suppress the RH locus expression from chromosomes carrying either one or two of the Rh genes.

Molecular cloning and primary structure of the human blood group RhD polypeptide

The RH (rhesus) blood group locus from RhD-positive donors is composed of two homologous structural genes, one of which encodes the Cc and Ee polypeptides, whereas the other, which is missing in the RhD-negative condition, encodes the D protein that carries the major antigen of the RH system. Recently, different splicing isoforms transcribed from the CcEe gene were isolated. We report now the characterization of two other Rh clones, RhII and RhXIII, generated by alternative choices for poly(A) addition sites that were identified as the RhD gene transcripts. That these cDNAs represented the RhD messenger and that the previously described Rh clones were derived from the CcEe gene was demonstrated by amplification of RhII/XIII sequences only from D-positive genomes and by cloning and sequencing of D- and CcEe-specific gene fragments. The predicted translation product of the RhD mRNA is a 417-amino acid protein (M(r) = 45,500) that exhibited a similar membrane organization with 13 bilayer-spanning domains compared with the polypeptide encoded by the CcEe gene. The D and Cc/Ee polypeptides differ by 36 amino acid substitutions (8.4% divergence), but the NH2- and COOH-terminal regions of the two proteins are well conserved. Similarly, five of the six cysteine residues of the Cc/Ee proteins were conserved in the D protein, including the unique exofacial cysteine, which is critical for antigenic reactivity. The sequence homology between the Cc/Ee and D proteins supports the concept that the genes encoding these polypeptides have evolved by duplication of a common ancestor gene.

Multiple Rh messenger RNA isoforms are produced by alternative splicing

Three Rh-related cDNAs have been isolated from a human bone marrow cDNA library and by polymerase chain reaction (PCR) amplification of human bone marrow and erythroblast mRNAs. They potentially encode a family of Rh protein isoforms that exhibit several unexpected structural properties as compared with the Rh polypeptide encoded by the cDNA clone identified previously. These modifications include several peptide deletions, the predicted alteration of Rh protein topology within the cell membrane, variations in the number and surface exposition of cysteine residues, and the generation of new C-terminal polypeptide segments caused by frameshift mutations. The four Rh mRNAs now described correspond to different splicing isoforms transcribed from the same Rh gene, and all exist in the same cell lineage (erythroid). Moreover, PCR experiments indicated that at least three of these RNA species exist in reticulocytes from donors with different commonly expressed Rh phenotypes. Although the translated proteins have not yet been characterized, these results suggest that the two genes at the RH locus may direct the synthesis of several protein species possibly corresponding to different Rh antigenic variants.

Genetic basis of the RhD-positive and RhD-negative blood group polymorphism as determined by Southern analysis

Several lines of evidence have previously indicated that the RhD, c, and E blood group antigens are most likely carried by three distinct but homologous red blood cell membrane proteins. To determine whether these polypeptides are encoded by one or several related genes, we have performed Southern blot analysis of genomic DNA prepared from donors of different Rh phenotypes. Using an entire Rh cDNA probe and several exon-specific probes covering the cloned gene from its 5' to 3' ends, we have shown that the Rh locus carried by the genome of RhD-positive individuals is composed of two different but strongly related genes of identical general organization whether they expressed the C or c and E or e antigens, and, surprisingly, even when they do not express these epitopes, as in the D-- phenotype. The only antigenic variation found to be associated with a consistent genomic polymorphism corresponded to the RhD-positive/RhD-negative phenotypes. Indeed, one of the two Rh genes was completely lacking when the genomes of several unrelated RhD-negative donors were analyzed. From the present study we conclude that one of the two genes of the Rh locus encodes the RhC/c and RhE/e polypeptides while the other encodes the RhD protein. The absence of any D gene and of its postulated allelic form d in the RhD-negative genome explains finally why no Rhd antigen has ever been shown.

Localization of the human Rh blood group gene structure to chromosome region 1p34.3-1p36.1 by in situ hybridization

A cDNA clone, RhIXb (1384 bp), encoding the entire protein sequence of a human blood group Rh polypeptide has been used to map the Rh locus, by in situ hybridization, to the region p34.3-p36.1 of chromosome 1. Two other unrelated cDNA clones, pUCA2 (750 bp) and pUCIII (1600 bp), isolated during the cloning procedure of the Rh cDNA were investigated simultaneously, and assigned to chromosome 3p21.1-3p22 (clone pUCA2) and to chromosome 22q12.1-22q13.1 (clone pUCIII).

Molecular cloning and protein structure of a human blood group Rh polypeptide

cDNA clones encoding a human blood group Rh polypeptide were isolated from a human bone marrow cDNA library by using a polymerase chain reaction-amplified DNA fragment encoding the known common N-terminal region of the Rh proteins. The entire primary structure of the Rh polypeptide has been deduced from the nucleotide sequence of a 1384-base-pair-long cDNA clone. Translation of the open reading frame indicates that the Rh protein is composed of 417 amino acids, including the initiator methionine, which is removed in the mature protein, lacks a cleavable N-terminal sequence, and has no consensus site for potential N-glycosylation. The predicted molecular mass of the protein is 45,500, while that estimated for the Rh protein analyzed in NaDodSO4/polyacrylamide gels is in the range of 30,000-32,000. These findings suggest either that the hydrophobic Rh protein behaves abnormally on NaDodSO4 gels or that the Rh mRNA may encode a precursor protein, which is further matured by a proteolytic cleavage of the C-terminal region of the polypeptide. Hydropathy analysis and secondary structure predictions suggest the presence of 13 membrane-spanning domains, indicating that the Rh polypeptide is highly hydrophobic and deeply buried within the phospholipid bilayer. In RNA blot-hybridization (Northern) analysis, the Rh cDNA probe detects a major 1.7-kilobase and a minor 3.5-kilobase mRNA species in adult erythroblasts, fetal liver, and erythroid (K562, HEL) and megakaryocytic (MEG01) leukemic cell lines, but not in adult liver and kidney tissues or lymphoid (Jurkat) and promyelocytic (HL60) cell lines. These results suggest that the expression of the Rh gene(s) might be restricted to tissues or cell lines expressing erythroid characters.

The initiation of DNA replication in the mitochondrial genome of yeast

We report here the first direct demonstration that the active ori sequences of the mitochondrial genome of Saccharomyces cerevisiae are indeed origins of DNA replication, as previously postulated on the basis of compelling but indirect evidence. Basically, such sequences are formed by four regions: (i) GC clusters A and B, which are separated by a 29-bp AT stretch; (ii) a central 200-bp AT stretch, l; (iii) GC cluster C; (iv) a 16-bp AT stretch r, which comprises a site for transcription initiation. The ori sequences investigated, ori 1 and ori 5, have opposite orientations on the parental wild-type genome; ori 1 has but ori 5 does not have an additional 14-bp AT stretch r', between cluster C and sequence r; they were carried by the genomes of two spontaneous petites. In both ori sequences, nascent DNA chains using as template the strand containing sequence r (the 'r strand') start at the r end of cluster C, are elongated towards sequence l, and follow an RNA primer starting at sequence r. Nascent DNA chains copied on the 'non-r strand' start within cluster C, are elongated towards sequence r, and follow an RNA primer starting in sequence l just before cluster C. Ori 1 and 5 are, therefore, used as sites for RNA-primed bidirectional replication of mitochondrial DNA. Several aspects of this process are discussed.