DNA molecule encoding a variant alpha-2B-adrenoaceptor protein and uses thereof

Abstract

This invention relates to a DNA sequence comprising a nucleotide sequence encoding a variant α2B-adrenoceptor protein and to the variant α2B-adrenoceptor protein as well as a method for screening a subject to determine if the subject is a carrier of a variant gene that encodes the variant α2B-adrenoceptor protein. This invention also relates to a method for treating a mammal suffering from vascular contraction of coronary arteries, the method comprising the step of administering a selective α2B-adrenoceptor antagonist to the mammal. This invention further relates to transgenic animals comprising a human DNA molecule encoding human α2B-adrenoceptor protein or the variant α2B-adrenoceptor protein.

Description

FIELD OF THE INVENTION

[0002] This invention relates to a DNA molecule encoding a variant human α2B-adrenoceptor, said variant α2B-adrenoceptor protein and a method to assess the risk of individuals to suffer from vascular contraction of coronary arteries in mammals as well as a method for the treatment of vascular contraction of coronary arteries. This invention also relates to transgenic animals comprising a human DNA molecule encoding human α2B-adrenoceptor or said variant α2B-adrenoceptor.

BACKGROUND OF THE INVENTION

[0003] The publications and other materials used herein to illuminate the background of the invention, and in particular, cases to provide additional details respecting the practice, are incorporated by reference.

[0004] The α2-adrenoceptors (α2-ARs) mediate many of the physiological effects of the catecholamines norepinephrine and epinephrine. Three genetic subtypes of α2-adrenoceptors are known in humans and other mammals, denoted as α2A-, α2B- and α2C-adrenoceptors. The human genes encoding the receptors are located on chromosomes 10, 2 and 4, respectively. No splice variants are known to exist of these receptors, as the genes are intronless. The tissue distributions and physiological and pharmacological functions of the receptor subtypes have been reviewed e.g. by MacDonald et al. (1997) and Docherty (1998). Based on recent studies with gene-targeted and transgenic mice, α2A-adrenoceptors mediate most of the pharmacological actions ascribed to currently available α2-adrenoceptor agonists, including inhibition of neurotransmitter release, central hypotensive and bradycardic effects, sedation and anesthesia, and analgesia. The same studies indicate that α2B-adrenoceptors mediate peripheral vasoconstriction in response to agonist activation (Link et al. 1996, Macmillan et al. 1996). Other physiological or pharmacological effects have not been associated with certainty with this receptor subtype. The α2C-adrenoceptor subtype appears to be involved in regulation of complex behaviors. It is not known that this subtype would have important functions in peripheral tissues outside the central nervous system or in cardiovascular regulation.

[0005] Coronary heart disease (CHD), like many other common disorders, arises from complex interactions between genetic and environmental factors. It is reasonable to assume that functionally important genetic variation in mechanisms important for the regulation of vascular functions, including the coronary vasculature, will be found to be associated with the pathogenesis and therapy of CHD. A variant form of the human α2B-AR gene was recently identified (Heinonen et al., 1999). The variant allele encodes a receptor protein with a deletion of three glutamate residues in an acidic stretch of 18 amino acids (of which 15 are glutamates) located in the third intracellular loop of the receptor polypeptide. This acidic stretch is a unique feature in the primary structure of α2B-AR in comparison to α2A-AR and α2C-AR, suggesting that the motif has a distinct role in the function of α2B-AR. Amino acid sequence alignment of α2B-AR polypeptides of different mammals reveals that the acidic stretch is highly conserved among the α2B-ARs of mammals and that the acidic stretch is long in humans in comparison to other species. This suggests that the motif is important for the functionality of the receptor, and that the short form (D for “deletion”) probably represents the ancestral form and the long form (I for “insertion”) could well represent a more recent allelic variant in humans. Jewell-Motz and Liggett (1995) studied the in vitro functions of this stretch using site-directed mutagenesis to delete as well as to substitute 16 amino acids of the stretch. Their results suggest that this acidic motif is necessary for full agonist-promoted receptor phosphorylation and desensitization.

[0006] Based on the vasoconstrictive property of α2B-AR in mice and the involvement of this acidic region in the desensitization mechanism of the receptor, we hypothesized that the deletion variant confers reduced receptor desensitization and therefore augmented vasoconstriction that could be associated with cardiovascular pathologies. To test this hypothesis, we carried out a 4-year prospective study in 912 middle-aged Finnish men.

OBJECT AND SUMMARY OF THE INVENTION

[0007] One object of this invention is to provide a DNA sequence of a variant human α2B-adrenoceptor gene and the corresponding variant α2B-adrenoceptor protein.

[0008] Another object of the invention is to provide a method for screening a subject to assess if an individual is at risk to suffer from vascular contraction of coronary arteries.

[0009] A third object of the invention is to provide a method for the treatment of vascular contraction of coronary arteries of mammals.

[0010] A fourth object of the invention is to provide a transgenic animal with a gene encoding a human α2B-adrenoceptor or said variant thereof.

[0011] Thus, according to one aspect the invention concerns a DNA sequence comprising a nucleotide sequence encoding a variant α2B-adrenoceptor protein with a deletion of at least 1 glutamate from a glutamic acid repeat element of 12 glutamates, amino acids 298-309, in an acidic stretch of 18 amino acids 294-311, located in the 3rd intracellular loop of the receptor polypeptide.

[0012] The invention further concerns a variant α2B-adrenoceptor protein with a deletion of at least 1 glutamate from a glutamic acid repeat element of 12 glutamates, amino acids 298-309, in an acidic stretch of 18 amino acids 294-311, located in the 3rd intracellular loop of the receptor polypeptide.

[0013] According to another aspect the invention concerns a method for screening a subject to determine if said subject is a carrier of a said variant gene with both alleles encoding a said variant α2B-adrenoceptor, i.e. to determine if said subject's genotype of the human α2B-adrenoceptor is of the deletion/deletion (D/D) type, comprising the steps of

[0014] a) providing a biological sample of the subject to be screened,

[0015] b) providing an assay for detecting in the biological sample the presence of

[0016] i) the insertion/insertion (I/I) or deletion/insertion (D/I) genotypes of the human α2B-adrenoceptor, or

[0017] ii) the D/D genotype of the human α2B-adrenoceptor, and

[0018] c) assessing at least one of the two following

[0019] i) an individual's risk to develop a disease involving vascular contraction of coronary arteries, or

[0020] ii) an individual's need for α2B-selective or α2B-nonselective α2-adrenoceptor antagonist therapy,

[0021] based on whether said subject is of said D/D genotype or not.

[0022] According to a third aspect the present invention concerns a method for treating a mammal suffering from vascular contraction of coronary arteries, said method comprising the step of administering a selective α2B-adrenoceptor antagonist to said mammal.

[0023] According to a fourth aspect the present invention concerns a transgenic animal which carries a human DNA sequence comprising a nucleotide sequence encoding a human α2B-adrenoceptor protein or a variant thereof.

DETAILED DESCRIPTION OF THE INVENTION

[0024] The present invention relates to a DNA molecule encoding a variant human α2BB-adrenoceptor, said variant α2B-adrenoceptor protein and a method to assess the risk of individuals to suffer from vascular contraction of coronary arteries in mammals as well as a method for the treatment of vascular contraction of coronary arteries. The present invention also relates to transgenic animals comprising a human DNA molecule encoding a human α2B-adrenoceptor or said variant α2B-adrenoceptor protein.

[0025] The word treating shall also be understood to include preventing.

[0026] The concept “a deletion of at least 1 glutamate from a glutamic acid repeat element of 12 glutamates” refers to any deletion of 1 to 12 glutamates irrespective of the specific location in, or how many glutamates from said repeat element of 12 glutamates, amino acids 298-309 (SEQ ID NO: 4), in an acidic stretch of 18 amino acids 294-311 located in the 3rd intracellular loop of the receptor polypeptide are deleted.

[0027] The concept “deletion/deletion (D/D) genotype of the human α2B-adrenoceptor”, in short “D/D genotype”, refers to a genotype of an individual having both α2B-adrenoceptor alleles code for a variant α2B-adrenoceptor with a deletion of at least 1 glutamate from a glutamic acid repeat element of 12 glutamates, amino acids 298-309, in an acidic stretch of 18 amino acids 294-311 (SEQ ID NO: 4), located in the 3rd intracellular loop of the receptor polypeptide. Correspondingly “deletion/insertion (D/I) genotype” refers to a genotype having one of the gene alleles code for an α2B-adrenoceptor with a said deletion and the other without a said deletion, i.e. with a respective insertion, and thus the “insertion/insertion (I/I) genotype” refers to a genotype having both alleles code for an α2B-adrenoceptor without said deletion or deletions.

[0028] We recently identified a common variant form (SEQ ID NO: 1) of the human α2B-AR gene (SEQ ID NO: 3). This variant gene encodes a receptor protein (SEQ ID NO: 2) with a deletion of 3 glutamates, amino acids 307-309, from a glutamic acid (Glu) repeat element of 12 glutamates, amino acids 298-309, in an acidic stretch of 18 amino acids 294-311 (SEQ ID NO: 4), located in the 3rd intracellular loop of the receptor polypeptide. This variant gene (SEQ ID NO: 1) was associated with decreased basal metabolic rate (BMR) in a group of obese Finnish subjects (Heinonen et al. 1999). Of the 166 obese subjects, 47 (28%) were homozygous for the long 12 glutamate repeat element (Glu12/Glu12), whereas 90 (54%) were heterozygous (Glu12/Glu9) and 29 (17%) were homozygous for the short form (Glu9/Glu9).

[0029] The results to be presented below show that in a population-based cohort of 912 Finnish middle-aged men subjects homozygous for the short form (Glu9/Glu9) described above, thus representing a deletion/deletion (D/D) genotype of the α2B-adrenoceptor, have a significantly elevated risk for acute coronary events in a four-year follow-up study. The risk for an acute coronary event, defined as definite or possible acute myocardial infarction (AMI) or prolonged (>20 min) chest pain requiring hospitalization, was increased 2.5 fold in subjects who had this D/D genotype. This increase in the risk for acute coronary events is as great as so far observed for any other genetic risk factor for acute coronary events or acute myocardial infarction in a prospective population study. Also the frequency of a study subject having a history of coronary heart disease (CHD) as well as CHD in an exercise test was associated with this D/D genotype.

[0030] Based on these results and previous publications referred to above it can be postulated that this D/D genotype is related to an impaired capacity to downregulate α2B-adrenoceptor function during sustained receptor activation. Since altered α2B-adrenoceptor function seems to be of relevance in the pathogenesis of a significant fraction of all cases of acute coronary events in subjects with this D/D genotype (homozygous Glu9/Glu9) we believe it could also be of relevance in subjects with the insertion/deletion (IID) (heterozygous Glu12/Glu9) and insertion/insertion (I/I) (homozygous Glu12/Glu12) genotypes when other risk factors for AMI are present. Further, since this specific deletion of 3 glutamates, amino acids 307-309, from said glutamic acid repeat element of 12 glutamates, amino acids 298-309, in said acidic stretch of 18 amino acids 294-311, located in the 3rd intracellular loop of the receptor polypeptide seems to be of relevance in cases of AMI we believe that also other deletions, i.e. deletions of at least 1 glutamate, from said glutamic acid repeat element of 12 glutamates, amino acids 298-309, could be of relevance in the pathogenesis of AMI, because the 3rd intracellular loop of the receptor polypeptide it is located in seems to have an essential role in the downregulation of the α2B-adrenoceptor.

[0031] Thus based on the results to be presented below and the publications referred to above an α2B-adrenoceptor antagonist would be useful for treating a mammal suffering from vascular contraction of coronary arteries.

[0032] Furthermore, an α2B-adrenoceptor antagonist selective for the α2B-adrenoceptor subtype would be therapeutically beneficial for the treatment of a disease involving said vascular contraction of coronary arteries. Such a disease could be clinically expressed as chronic angina pectoris, specifically e.g. AMI, unstable angina pectoris or Prinzmetal's variant form of angina pectoris. If α2B-adrenoceptor dependent vasoconstriction is a causative factor in some cases of AMI, then antagonism of these receptors should restore coronary circulation and reduce the ischemic myocardial damage. An α2B-adrenoceptor antagonist will relieve the vasoconstrictive component in the sustained ischemic episode of unstable angina pectoris, thus alleviating the symptoms and preventing AMI. Vasoconstriction is a key factor in the pathogenesis of Prinzmetal's angina, and an α2B-adrenoceptor antagonist may resolve and prevent attacks. An α2B-adrenoceptor antagonist will help to alleviate the vasoconstrictive component in all types of CHD, providing both symptomatic relief and protection from AMI.

[0033] α2B-adrenoceptors mediate vascular contraction of coronary arteries, and genetic polymorphism present in the α2B-adrenoceptor gene renders some subjects more susceptible to α2B-adrenoceptor mediated vasoconstriction of coronary arteries and associated clinical disorders. These subjects will especially benefit from treatment with an α2B-adrenoceptor antagonist, and will be at increased risk for adverse effects if subtype-nonselective α2-agonists are administered to them. Therefore, a gene test recognizing subjects with a deletion variant of the α2B-adrenoceptor gene will be useful in diagnostics and patient selection for specific therapeutic procedures. A gene test recognizing the D/D genotype of the α2B-adrenoceptor is useful in assessing an individual's risk to develop AMI and other clinical disorders involving vascular contraction of coronary arteries related to the D/D genotype. A gene test recognizing the D/D genotype of the α2B-adrenoceptor is useful in selecting drug therapy for patients with diseases involving vascular contraction of coronary arteries associated with the D/D genotype; subjects with the D/D genotype will especially benefit from therapy with α2-adrenoceptor antagonists (α2B-selective or nonselective). A gene test recognizing the D/D genotype of the α2B-adrenoceptor is useful in selecting drug therapy for patients who might be at increased risk for adverse effects of α2-adrenergic agonists; either, it will be possible to avoid the use of α2-agonists in such patients, or it will be possible to include a specific α2B-antagonist in their therapeutic regimen.

[0034] The DNA sequence can be used for screening a subject to determine if said subject is a carrier of a variant gene. The determination can be carried out either as a DNA analysis according to well known methods, which include direct DNA sequencing of the normal and variant gene, allele specific amplification using the polymerase chain reaction (PCR) enabling detection of either normal or variant sequence, or by indirect detection of the normal or variant gene by various molecular biology methods including e.g. PCR-single stranded conformation polymorphism (SSCP) method or denaturing gradient gel electrophoresis (DGGE). Determination of the normal or variant gene can also be done by using a restriction fragment length (polymorphism (RFLP) method, which is particularly suitable for genotyping large numbers of samples. Similarly, a test based on gene chip technology can be easily developed in analogy with many currently existing such tests for single-nucleotide polymorphisms.

[0035] The determination can also be carried out at the level of RNA by analyzing RNA expressed at tissue level using various methods. Allele specific probes can be designed for hybridization. Hybridization can be done e.g. using Northern blot, RNase protection assay or in situ hybridization methods. RNA derived from the normal or variant gene can also be analyzed by converting tissue RNA first to cDNA and thereafter amplifying cDNA by an allele specific PCR method.

[0036] As examples of useful α2B-adrenoceptor antagonists can be mentioned imiloxan [2-(1-ethyl-2-imidazoyl)methyl-1,4-benzodioxan, ARC-239 [2-[2-(4-(2-methoxyphenyl)piperazin-1-yl)ethyl]-4,4-dimethyl-1,3-(2H,4H)-isoquinolindione], prazosin [1-(4-amino-6,7-dimethoxy-2-quinazo-linyl)-4-(2-furanylcarbonyl)piperazine] and chlorpromazine [2-chloro-N,N-dimethyl-10H-pheno-thiazine-10-propanamine].

[0037] The required dosage of the compounds will vary with the particular condition being treated, the severity of the condition, the duration of the treatment, the administration route and the specific compound being employed. A typical therapeutically effective daily dose administered, e.g. orally or by infusion, can vary from e.g. 0.1 μg to 10 mg per kilogram body weight of an adult person.

[0038] Influence of the variant gene sequence can be investigated in transgenic animals. A transgenic animal can be generated e.g. using targeted homologous recombination methodology. This will provide an ideal preclinical model to investigate and screen new drug molecules, which are designed to modify the influence of the variant gene.

[0039] The invention will be described in more detail in the experimental section.

[0040] Experimental Section

[0041] Determination of Genomic Alleles Encoding the α2B-Adrenoceptor

[0042] PCR-SSCA Analysis

[0043] The polymerase chain reaction-single stranded conformational analysis (PCR-SSCA) used to identify the genomic alleles encoding the α2B-adrenoceptor was carried out as follows: The genomic DNA encoding the α2B-adrenergic receptor was amplified in two parts specific for the intronless α2B-adrenoceptor gene sequence (Lomasney et al. 1990). The PCR primer pairs for PCR amplification were as follows: Pair 1: 5′-GGGGCGACGCTCTTGTCTA-3′ (SEQ ID NO: 5) and 5′-GGTCTCCCCCTCCTCCTTC-3′ (SEQ ID NO: 6) (product size 878 bp), and pair 2: 5′-GCAGCAACCGCAGAGGTC-3′ (SEQ ID NO: 7) and 5′-GGGCAAGAAGCAGGG-TGAC-3′ (SEQ ID NO: 8) (product size 814 bp). The primers were delivered by KeboLab (Helsinki, Finland). PCR amplification was conducted in a 5 μl volume containing 100 ng genomic DNA (isolated from whole blood), 2.5 mmol/l of each primer, 1.0 mmol/l deoxy-NTPs, 30 nmol/l 33P-dCTP and 0.25 U AmpliTaq DNA polymerase (Perkin Elmer Cetus, Norwalk, Conn.). PCR conditions were optimized using the PCR Optimizer™ kit (Invitrogen, San Diego, Calif.). Samples were amplified with a GeneAmp PCR System 9600 (Perkin Elmer Cetus). PCR products were digested with restriction enzymes for SSCA analysis. The product of primer pair 1 was digested with Dde I and Dra III (Promega Corp., Madison, Wis.). The product of primer pair 2 was digested with Alu I and Hinc II (Promega Corp.). The digested samples were mixed with SSCA buffer containing 95% formamide, 10 mmol/l NaOH, 0.05% xylene cyanol and 0.05% bromophenol blue (total volume 25 μl). Before loading, the samples were denatured for 5 min at 95° C. and kept 5 min on ice. Three microliters of each sample were loaded on MDE™ high-resolution gel (FMC, BioProducts, Rockland, Mass.). The gel electrophoresis was performed twice, at two different running conditions: 6% MDE gel at +4° C. and 3% MDE gel at room temperature, both at 4 W constant power for 16 h. The gels were dried and autoradiography was performed by apposing to Kodak BioMax MR film for 24 h at room temperature.

[0044] Sequencing and Genotyping

[0045] DNA samples migrating at different rates in SSCA were sequenced with the Thermo Sequenas™ Cycle Sequencing Kit (Amersham Life Science, Cleveland, Ohio). For genotyping the identified 3-glutamic acid deletion, DNA was extracted from peripheral blood using standard methods. The α2B-AR I/D genotype was determined by separating PCR-amplified DNA fragments with electrophoresis. Based on the nature of the I/D variant, identification of the long and short alleles was achieved by their different electrophoretic migration rates due to their 9 bp size difference.

[0046] The region of interest was amplified using a sense primer 5′-AGGGTGTTTGTGGG-GCATCT-3′ (SEQ ID NO: 9) and an anti-sense primer 5′-CAAGCTGAGGCCGGAGACACT-3′ (SEQ ID NO: 10) (Oligold, Eurogentec, Belgium), yielding a product size of 112 bp for the long allele (I) and 103 bp for the short allele (D). PCR amplification was conducted in a 10 μL volume containing ˜100 ng genomic DNA, 1× buffer G (Invitrogen, San Diego, Calif., USA), 0.8 mM dNTPs, 0.3 μM of each primer and 0.25 units of AmpliTaq DNA polymerase (Perkin Elmer Cetus, Norwalk, Conn., USA). Samples were amplified with a GeneAmp PCR System 9600 (Perkin Elmer Cetus). After initial denaturation at 94° C. for 2 minutes, the samples were amplified over 35 cycles. PCR amplification conditions were 96° C. (40 s), 69° C. (30 s) and 72° C. (30 s) followed by final extension at 72° C. for 6 minutes. The PCR products representing the long and short alleles were identified by two alternative methods.

[0047] 1)The amplified samples were mixed with 4 μl of stop solution (Thermo Sequenase™ Cycle Sequencing kit), heated to 95° C. for 2 min, and loaded hot onto sequencing gels (Long Ranger™, FMC). The gels were dried and autoradiography was performed as previously described.

[0048] Separation of the amplified PCR products was performed with electrophoresis on a high-resolution 4% Metaphor agarose gel (FMC Bioproducts, Rockland, Me.) and the bands were visualized by ethidium bromide staining. In both methods, the long (Glu12) and short (Glu9) alleles were identified based on their different electrophoretic migration rates.

[0049] Follow-Up Study

[0050] The above referred four-year follow-up study of 912 Finnish middle-aged men subjects including 192 subjects with a specific deletion/deletion (D/D) genotype of the α2B-adrenoceptor is described in more detail in the following:

[0051] Knowing the vasoconstrictive property of α2B-AR in mice and the possible involvement of the investigated acidic region in the desensitization mechanism of the receptor we hypothesized that the observed insertion/deletion allelic variation could be associated with cardiovascular pathologies such as AMI. To test this hypothesis, we carried out a four-year follow-up study in 912 middle-aged Finnish men with no prior history of AMI. The study was carried out as part of the Kuopio Ischemic Heart Disease Risk Factor Study (KIHD), which is an ongoing population-based study designed to investigate risk factors for cardiovascular diseases and related outcomes in men from eastern Finland (Salonen 1988). This area is known for its homogenous population (Sajantila et al. 1996) and high coronary morbidity and mortality rates (Keys 1980).

[0052] Of the 912 subjects, 192 (21%) had the D/D genotype, 256 (28%) had the I/I genotype and 464 (51%) were heterozygous i.e. I/D. This genotype distribution is in Hardy-Weinberg equilibrium (p=0.46).

[0053] Of the 37 cases that had an acute coronary event during the follow-up, 18 were classified as definite AMI, 12 as possible AMI and seven as prolonged chest pain. Among the subjects with the D/D genotype, 15 (8%) had an acute coronary event during the follow-up time. The corresponding incidences for the I/I and the heterozygous genotypes i.e. I/D were 10 (4%) and 12 (3%). The observed cumulative incidence of acute coronary events differed significantly among the different genotypes (p=0.008). No significant difference in the cumulative incidence of acute coronary events was found between the I/D and the H genotypes (p=0.4) (table 1). There was a significant difference (log-rank p=0.0045) between the D/D subgroup and the other two genotypes combined in the cumulative event-free time in the Kaplan-Meier survival function, demonstrating that there is a consistently increased incidence of acute coronary events in the D/D subgroup.

[0054] The D/D genotype was associated with a 2.5 fold increased risk for an acute coronary event (95% CI=1.3-4.8, p=0.006) in comparison to the other two genotypes combined. The relative risk remained above 2 after adjustment for major CHD risk factors (table 2).

[0055] The D/D subgroup was not significantly different from the I/D+I/I subgroup in terms of many known major risk factors for CHD. From 87 variables in the study database only 5 were significantly different between the D/D and the I/D+I/I genotype subgroups: 1. there were more acute coronary events in the D/D subgroup (8% vs. 3%, p=0.006), 2. history of CHD was more prevalent in the D/D subgroup (37% vs. 29%, p=0.043), 3. the prevalence of CHD in exercise test was higher in the D/D subgroup (30% vs. 22%, p=0.036), 4. mean hemoglobin level was higher in the D/D subgroup (149.0 g/l vs. 146.8 g/l, p=0.005) and 5. mean dietary cholesterol intake (4-days) was lower in the D/D subgroup (411.6 mg vs. 440.1 mg, p=0.033) (table 3). The first four observed differences support our hypothesis that the D/D genotype confers reduced receptor desensitization and therefore augmented vasoconstriction. This augmented vasoconstriction is the reason for the increased incidence of acute coronary events, the higher prevalence of CHD in exercise and history of CHD. We hypothesize that the increased level of hemoglobin is due to relative anoxia of tissues because of this augmented vasoconstriction.

[0056] To examine the possibility that the D/D genotype is a genetic marker for acute coronary events rather than a causative factor, we have searched the literature for known genetic risk factors for acute coronary events and AMI and their chromosomal localization. All but one (Apo-B) are on different chromosomes than the α2B-AR gene (chromosome 2) and the gene for Apo-B is neither in the physical nor the genetic vicinity of the α2B-AR gene. Cox regression analysis revealed that the increased RR for acute coronary events in the D/D subgroup is not affected by the serum Apo-B concentration.

[0057] Taken together, the known biological properties of the α2B-AR, the homogeneity of the Finnish population with its relatively high incidence of CHD, the study design, the relatively large representative study population and the clustering of the findings around one trait suggest that the D/D receptor allele is a causal genetic risk factor for acute coronary events.

TABLE 1
The cumulative incidence of acute coronary events among
men with different genotypes of the α2B-AR (p
values are stated below)
Genotype		Events (% of men at risk)	Men at risk (% of all)
D/D	observed	15 (8)	192 (21)
	expected	7.8
I/D	observed	12 (3)	464 (51)
	expected	18.8
I/I	observed	10 (4)	256 (28)
	expected	10.4
I/D + I/I	observed	22 (3)	720 (79)
	expected	29.2
Total	observed	37 (4)	912 (100)
P values for the above table:
D/D vs. I/D vs. I/I p = 0.008
D/D vs. I/D p = 0.002
D/D vs. I/I p = 0.038
I/D vs. I/I p = 0.389
D/D vs. I/D + I/I p = 0.005

[0058]

TABLE 2
Relative risk (RR) and its 95% confidence interval (CI)
for an acute coronary event-a comparison of each of the
genotypes with the other two combined. Results of a
Cox regression model for 37 acute coronary events in
a population sample of 912 subjects
		RR (95% CI)	Adjusted RR (95% CI)
Genotype	Events/men at risk	P	P
D/D	15/192	2.5 (1.3-4.8)	2.3 (1.2-4.5)
		0.006	0.014
I/D	12/464	0.44 (0.2-0.9)	0.5 (0.2-1.0)
		0.020	0.052
I/I	10/256	1.03 (0.5-2.1)	0.96 (0.5-2.0)
		0.940	0.901
Adjustment was done for age, CHD in the family, high cholesterol in the family, hypertension and smoking

[0059]

TABLE 3
List of all significant differences (p < 0.05) between the
D/D and the I/D + I/I genotype subgroups among 87 variables
in the study database
Variable	D/D	I/D + I/I	P
Acute coronary events [event/n (%)]	15/192 (8)	22/720 (3)	0.006
Ischemic findings in exercise	57/192 (30)	160/720 (22)	0.036
test [case/n (%)]
History of CHD [case/n (%)]	71/192 (37)	209/720 (29)	0.043
Mean blood haemoglobin [g/L]	149.0	146.8	0.005
Mean 4 day dietary cholesterol	411.6	440.1	0.033
intake [mg]
% = Percent of men at risk

[0060] It will be appreciated that the methods of the present invention can be incorporated in the form of a variety of embodiments, only a few of which are disclosed herein. It will be apparent for the specialist in the field that other embodiments exist and do not depart from the spirit of the invention. Thus, the described embodiments are illustrative and should not be construed as restrictive.

[0061] References

[0062] Docherty J R: Subtypes of functional α1- and α2-receptors. Eur J Pharmacol 1998;361:1-15

[0063] Heinonen P, Koulu M, Pesonen U, Karvonen M, Rissanen A, Laakso M, Valve R, Uusitupa M, Scheinin M: Identification of a three amino acid deletion in the alpha-2B-adrenergic receptor which is associated with reduced basal metabolic rate in obese subjects. J Clin Endocrinol Metab 1999;84:2429-2433

[0064] Jewell-Motz E, Liggett S B: An acidic motif within the third intracellular loop of the alpha2C2 adrenergic receptor is required for agonist-promoted phosphorylation and desensitization. Biochemistry 1995;34:11946-11953

[0065] Keys A: Seven Countries: A Multivariate Analysis of Death and Coronary Heart Disease. Cambridge, Mass, Harvard University Press, 1980

[0066] Link R E, Desai K, Hein L, Stevens M E, Chruscinski A, Bernstein D, Barsh G S, Kobilka B K: Cardiovascular regulation in mice lacking alpha2-adrenergic receptor subtypes b and c. Science 1996;273:803-805

[0067] Lomasney J W, Lorenz W, Allen L F, King K, Regan J W, Yang-Feng T L, Caron M C, Lefkowitz R J: Expansion of the alpha-2 adrenergic receptor family: cloning and characterization of a human alpha-2 adrenergic receptor subtype, the gene for which is located on chromosome 2. Proc Natl Acad Sci USA. 1990;87:5094-5098.

[0068] MacDonald E, Kobilka B K, Scheinin M: Gene targeting—homing in on α2-adrenoceptor subtype function. Trends Pharmacol Sci 1997; 18:211-219

[0069] MacMillan L B, Hein L, Smith M S, Piascik M T, Limbird L E: Central hypotensive effects of the alpha2a-adrenergic receptor subtype. Science 1996;273:801-803

[0070] Sajantila A, Salem A H, Savolainen P, Bauer K, Gierig C, Paabo S: Paternal and maternal DNA lineages reveal a bottleneck in the founding of the Finnish population. Proc.Natl.Acad.Sci. U.S.A. 1996;93:12035-12039

[0071] Salonen J T: Is there a continuing need for longitudinal epidemiologic research? The Kuopio Ischaemic Heart Disease Risk Factor Study. Ann. Clin Res 1988;20:46-50

Claims

1. A nucleic acid encoding a variant C2B-adrenoceptor protein, the variant protein comprises a deletion of at least 1 glutamate from a glutamic acid repeat element of 12 glutamates, amino acids 298-309, in an acidic stretch of 18 amino acids 294-311, located in a 3rd intracellular loop of the receptor protein.

2. The nucleic acid of claim 1, wherein the variant protein comprises a deletion of 3 glutamates, amino acids 307-309, from said glutamic acid repeat element of 12 glutamates, amino acids 298-309, in said acidic stretch of 18 amino acids 294-311, located in the 3rd intracellular loop of the receptor polypeptide.

3. The nucleic acid of claim 2 comprising a genomic nucleotide sequence as set forth in SEQ ID NO:1.

4. The nucleic acid of claim 1, wherein said nucleic acid is cDNA.

5. An RNA sequence fully complementary to the DNA sequence of claim 1.

6. A variant α2B-adrenoceptor protein comprising a deletion of at least 1 glutamate from said glutamic acid repeat element of 12 glutamates, amino acids 298-309, in said acidic stretch of 18 amino acids 294-311, located in the 3rd intracellular loop of the receptor polypeptide.

7. The variant α2B-adrenoceptor protein of claim 6, wherein the protine comprises a deletion of 3 glutamates, amino acids 307-309, from said glutamic acid repeat element of 12 glutamates, amino acids 298-309, in said acidic stretch of 18 amino acids 294-311, located in the 3rd intracellular loop of the receptor polypeptide.

8. The variant α2B-adrenoceptor protein of claim 7 comprising an amino acid sequence set forth in SEQ ID NO: 2.

9. An assay for determining the presence or absence of the nucleic acid of claim 1.

10. The assay of claim 9, wherein the assay is a DNA-assay.

11. A method for determining the presence or absence in a biological sample of the nucleic acid of claim 1 comprising contacting a single-stranded form of said nucleic acid if present in the sample with a capturing nucleic acid probe and a detector nucleic acid probe to form a complex and detecting the presence or absence of the complex.

12. The method of claim 11, wherein the capturing nucleic acid probe is attached or capable of attaching to a solid phase, and comprises a cDNA encoding the variant α2B-adrenoceptor protein, wherein a detected signal from the solid phase is an indication of the presence in the sample of said nucleic acid.

13. The method according to claim 11, wherein the capturing nucleic acid probe is attached or capable of attaching to a solid phase, and comprises a cDNA encoding a non-variant α2B-adrenoceptor protein, wherein a detected signal from the solid phase is an indication of the absence in the sample of said nucleic acid.

14. A method for screening a subject to determine if the subject is at risk for developing a disease involving vascular contraction of coronary arteries or is in need of α2B-selective or α2B-nonselective α2-adrenoceptor antagonist therapy, said method comprises obtaining a biological sample of the subject and determining whether the subject (i) has the insertion/insertion (I/I) or deletion/insertion (D/I) genotypes of the human α2B-adrenoceptor protein or (ii) has the D/D genotype of the human α2B-adrenoceptor protein, wherein if the subject has the D/D genotype, the subject is at risk for developing a disease involving vascular contraction of coronary arteries or is in need of α2B-selective α2-adrenoceptor antagonist therapy.

15. The method of claim 14, wherein the assay is a DNA-assay.

16. A capturing probe which comprises a single strand of the cDNA of claim 4.

17. A capturing probe which comprises a single strand of a cDNA encoding a non-variant α2B-adrenoceptor protein.