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Query: UMLS:C0085580 (
essential hypertension
)
14,686
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Persons participating in a 5-day diagnostic protocol were routinely typed for ABO, Rh,
MNS
, Kell, Kidd, Duffy, P, Haptoglobin, phosphoglucomutase-1 (PGM-1), and acid phosphatase (AcP). The study population was composed of 164 normotensive whites, 34 normotensive blacks, 161 whites and 43 blacks with
essential hypertension
, and 52 whites with secondary forms of hypertension (18 atherosclerotic renovascular hypertensives, 17 patients with fibromuscular disease, and 17 patients with primary aldosteronism). There were no significant differences in phenotype frequencies in ABO, Rh, Kidd, Kell, Duffy, P, Haptoglobin, PGM-1 or AcP in any of the comparisons. However, there was a significantly different distribution of
MNS
phenotypes in comparisons of essential and atherosclerotic renovascular hypertensives with normotensive controls. Essential hypertensives had a lower frequency of the S gene and a higher frequency of s in whites (X2 = 12.21, p less than 0.005). Atherosclerotic renovascular hypertensives differed from the normotensive population in the frequencies of both MN (X 2 = 4.34, p less than 0.05) and Ss (X2 = 4.21, p less than 0.05). The finding of disease-blood group associations supports the hypothesis that there may be significant physiological differences between individuals of different blood types.
...
PMID:Association of blood groups with essential and secondary hypertension. A possible association of the MNS system. 16 54
An approach to evaluating the genetic components of
essential hypertension
using an animal model, the Milan hypertensive strain (MHS) of rats, and studies in human families with positive and negative histories for high blood pressure are described and discussed. Differences at renal and cellular levels between MHS and its normotensive control strain,
MNS
, show many similarities to those between offspring from hyper- and normotensive families in humans. These include, with respect to the former group of each species, lower erythrocyte volume and Na content, higher Na-K cotransport across red blood cell (RBC) membranes higher Na excretion after load, and greater pressor effect in transplanted kidneys. A novel protein found in rat RBC cytoskeleton appears to have a function in Na-K cotransport and it may, eventually, be possible to demonstrate in man.
...
PMID:Renal abnormalities at the prehypertensive stage of essential hypertension. 246 5
Environmental factors, genetic polymorphisms, and different experimental designs have been the main impediments to evaluating a genetic association between cell membrane cation transport abnormalities and human essential or genetic hypertension. We review the results obtained in the Milan hypertensive strain of rats (MHS) and in its appropriate control normotensive strain (
MNS
) to illustrate our approach to defining the role of cation transport abnormality in a type of genetic hypertension. Before the development of a difference in blood pressure between the two strains, the comparison of kidney and erythrocyte functions showed that MHS had an increased glomerular filtration rate and urinary output, and lower plasma renin and urine osmolality. Kidney cross-transplantation between the strains showed that hypertension is transplanted with the kidney. Proximal tubular cell volume and sodium content were lower in MHS while sodium transport across the brush border membrane vesicles of MHS was faster. Erythrocytes in MHS were smaller and had lower sodium concentration, and Na+-K+ cotransport and passive permeability were faster. The differences in volume, sodium content, and Na+-K+ cotransport between erythrocytes of the two strains persisted after transplantation of bone marrow to irradiated F1 (MHS X
MNS
) hybrids. Moreover, in normal segregating F2 hybrid populations there was a positive correlation between blood pressure and Na+-K+ cotransport. These results suggest a genetic and functional link in MHS between cell membrane cation transport abnormalities and hypertension. Thus erythrocyte cell membrane may be used for approaching the problem of defining the genetically determined molecular mechanism underlying the development of a type of
essential hypertension
.
...
PMID:The Milan hypertensive rat as a model for studying cation transport abnormality in genetic hypertension. 331 5
The significance of the erythrocyte abnormalities described in rats and humans with spontaneous hypertension is far from clear. This study, in two highly inbred strains of rats, was designed to evaluate whether these abnormalities are primary and thus genetically related to hypertension. The Milan hypertensive strain (MHS) and its normotensive control strain (
MNS
) were used to carry out two types of experiments. In two groups of lethally irradiated (MHS X
MNS
) F1 hybrids, bone marrow from MHS or
MNS
was transplanted. The differences in red cell function between the recipients of bone marrow from MHS and recipients of bone marrow from
MNS
were similar to those existing between the parental donor MHS and
MNS
: Na+-K+ cotransport was increased (p less than 0.02) and intracellular Na+ content (p less than 0.05) and cell volume (p less than 0.02) were decreased in MHS. The same pattern was observed when this experiment was repeated in different groups of F1 hybrids. In individuals of the segregating F2 population, obtained by crossing the (MHS X
MNS
) F1 hybrids, there was a positive correlation (p less than 0.001) between the red blood cell Na+-K+ cotransport and the mean blood pressure. These results indicate that the erythrocyte abnormalities may well be genetically associated with the primary cause of spontaneous hypertension in rats. Because of the many similarities demonstrated when young prehypertensive MHS or humans prone to develop hypertension are compared with their respective controls, it is possible that the findings described here in rats are relevant to human
essential hypertension
.
...
PMID:Red blood cell abnormalities and spontaneous hypertension in the rat. A genetically determined link. 388 35
Net fluxes of sodium and potassium ions were determined in sodium-loaded, potassium-depleted erythrocytes from 370 white subjects, 194 of whom had
essential hypertension
or had been born to parents with
essential hypertension
. Findings were compared with those in 86 controls who were normotensive and did not have a family history of hypertension. Compared with controls all patients with
essential hypertension
had a low sodium to potassium ratio secondary to a deficit in the sodium-potassium cotransport system. A similar abnormality was found in subjects born to parents with
essential hypertension
, the prevalences of a deficient cotransport system in such subjects being 53.6% (52 out of 97) among those with one hypertensive parent and 73.7% (14 out of 19) among those with two hypertensive parents. Both sexes were equally affected. Studies in 14 families over two or three generations showed the erythrocyte cation abnormality in one or more members of each consecutive generation. No close association was evident between the deficient erythrocyte sodium-potassium cotransport system and either blood groups ABO, Rh, Kidd, Duffy, P, and
MNS
or the major histocompatibility HLA antigens. Out of 90 consecutive unrelated and normotensive white blood donors, 36 showed a low erythrocyte sodium-potassium net flux ratio. It is concluded that in white people abnormal erythrocyte cation transport is a biochemical disorder characteristic of
essential hypertension
and transmitted by a dominant and autosomal mode expressing a single abnormal gene.
...
PMID:Inheritance of abnormal erythrocyte cation transport in essential hypertension. 678 58
The Milan hypertensive strain of rats (MHS) develops a genetic form of renal hypertension that, when compared to its normotensive control (
MNS
), shows renal dysfunction similar to that of a subset of human patients with
primary hypertension
. MHS and
MNS
were shown to be homozygous by multilocus minisatellite analysis and monolocus microsatellite markers. We show here that one point mutation in each of two genes coding for the membrane skeleton protein adducin is associated with blood pressure in the Milan strain of rats. Adducin is a heterodimer formed by alpha and beta subunits that promotes the assembly of actin with spectrin. MHS and
MNS
differ, respectively, by the amino acids Y and F at position 316 of the alpha subunit. In the beta-adducin locus, MHS is always homozygous for R at position 529 while in
MNS
either R or Q occurs in that position. The R/Q heterozygotes showed lower blood pressure than any of the homozygotes. In vitro phosphorylation studies suggest that both of these amino acid substitutions occur within protein kinase recognition sites. Analysis of an F2 generation demonstrated that Y alleles segregated with a significant increment in blood pressure. This effect is modulated by the presence of the R allele of the beta subunit. Taken together, these findings strongly support a role for adducin polymorphisms in causing variation of blood pressure in the Milan strain of rats.
...
PMID:Two point mutations within the adducin genes are involved in blood pressure variation. 817 Oct 25
1. High blood pressure is a complex phenotype that involves many body control systems operating at each level of the biological organization. 2. One possible approach to try to identify the major genes involved in the development of hypertension is to dissect the sequence of events that go from a primary protein abnormality that is responsible for organ and cellular dysfunction to arterial hypertension and, then, to go back to the gene coding the protein of interest. 3. Using this approach, our group has been able to identify a candidate protein, adducin, and two point mutations within the two genes coding for the subunits of this protein that are involved in blood pressure variation both in an animal model of
primary hypertension
and in
essential hypertension
patients. 4. In the present paper we review the results obtained in the Milan hypertensive rat strain (MHS) and in its appropriate normotensive controls (
MNS
) to define, at each level of the biological organization, the intermediate phenotypes associated with the development of hypertension. 5. We also demonstrate that this model has many similarities with human hypertension and, in particular, that the same genetic mechanisms linked to a mutation in the adducin gene can explain some of the blood pressure variation in both rats and, at least, in a subgroup of patients. 6. This portion of the increase in blood pressure seems to be able to be selectively inhibited by compounds that interfere with the sequence of events that are triggered by the adducin gene abnormality.
...
PMID:A genetic approach to the pathogenesis of primary hypertension and to its treatment. 884 4
