CN114451358A - Animal model for preeclampsia diseases and construction method and application thereof - Google Patents

Abstract

The invention discloses an animal model of preeclampsia diseases, which is prepared from Sirt1^+/‑The pregnant mouse with heterozygote knocked out systemically is an animal model with preeclampsia diseases. The invention also discloses a construction method and application thereof. The preeclampsia disease animal model does not need external medicine and operation intervention, does not need special feed and special feeding environment for reproduction, can completely reduce preeclampsia diseases, can be used for helping to clarify the pathogenesis and mechanism of the preeclampsia diseases and can also be used for helping to screen and evaluate the efficacy of the medicines for preventing and treating the preeclampsia diseases.

Description

Animal model for preeclampsia diseases and construction method and application thereof

Technical Field

The invention relates to the technical field of animal model construction, in particular to an animal model for preeclampsia diseases and a construction method and application thereof.

Background

Preeclampsia (PE) is a specific multisystemic progressive disease during pregnancy, mainly manifested as late gestational or postpartum onset of new hypertension and proteinuria; or new onset hypertension and significant end organ dysfunction, with or without urinary protein. The method is characterized in that the method often causes poor pregnancy outcome of the mother and the child and increases the occurrence risk of long-term cardiovascular diseases, the current cause is unknown, and no effective treatment means exists. However, since clinical symptoms subside after delivery, recent guidelines are attributed to placental and maternal vascular dysfunction.

An ideal animal model should present the clinical features of the disease. PE, which is specific for the middle and late gestation, manifests as insufficient trophoblast infiltration, recanalization of spiral arteries, concomitant hypertension, diffuse vascular endothelial dysfunction, and further causes kidney damage, urinary protein, and other end organ dysfunction. Because the pathogenic factors are unknown and the overall disease symptoms are wide, the currently known models cannot completely present all symptoms of PE. At present, common rat and mouse models comprise an inflammation model induced by lipopolysaccharide, a vascular contraction model induced by RUPP (Rupp) for reducing uterus-placenta perfusion pressure, an anti-angiogenesis model induced by soluble fms-like tyrosine kinase 1 and the like, which usually focus on blood pressure and urine protein signs only, cannot better reduce the course of disease, cannot give consideration to trophoblast invasion disorder and terminal organ dysfunction such as kidney and the like specific to preeclampsia, and cannot reduce the clinical characteristics of the disease. And the molding cost is higher, the operation is more tedious, and no matter the medicine dosage or the operation mode, the individual difference of experiment operators exists, and then the molding success rate is influenced.

Sirt1 is a Nicotinamide Adenine Dinucleotide (NAD)⁺) The dependent protein deacetylase is a homolog of Sir2 protein in mammals, and belongs to the family of mammalian Sirtuins proteins. Current studies suggest that Sirt1 is distributed in both the nucleus and cytoplasm. Sirt1 exerts anti-inflammatory, antioxidant stress, anti-aging, T cell immunity activation and even mitochondrial generation by deacetylating lysine residues of various proteins.

Aiming at a series of technical problems of high molding cost, complicated molding process and pathophysiology process which can not be completely recovered of model animals, the invention provides a novel animal model, Sirt1^+/-The pathophysiological process of the disease can be reduced by knocking out heterozygote all over the bodyWithdrawal of the pregnancy state or recovery with agonist treatment. In addition, external medicines and surgical intervention are not needed, and special feed and special feeding environment are not needed for propagation, so that a brand-new animal model is provided for the research of the preeclampsia morbidity process and mechanism.

Disclosure of Invention

The invention aims to provide an animal model for preeclampsia diseases and a construction method and application thereof, so as to solve the defects of the prior art.

The invention adopts the following technical scheme:

the first aspect of the invention provides application of the Sirt1 gene in constructing an animal model of preeclampsia diseases.

In a second aspect, the invention provides an animal model of preeclampsia diseases, which is Sirt1^+/-The pregnant mouse with heterozygote knocked out systemically is an animal model with preeclampsia diseases.

Further, the Sirt1^+/-The whole-body knockout heterozygote pregnant mouse is obtained by the following steps: mix Sirt1^flox/floxThe gene editing mice were propagated and crossed with Dppa3-IRES-Cre mice and bred via decrepit.

The third aspect of the invention provides a method for constructing an animal model of preeclampsia diseases, which comprises the following steps: mix Sirt1^flox/floxAfter propagation, the gene editing mice are crossed with Dppa3-IRES-Cre mice, and after Cre removal propagation, Sirt1 is obtained^+/-And (3) knocking out the heterozygous pregnant mouse in the whole body to obtain the constructed preeclampsia disease animal model.

The fourth aspect of the invention provides the application of the preeclampsia disease animal model in researching the pathogenesis and mechanism of preeclampsia diseases.

The fifth aspect of the invention provides application of the preeclampsia disease animal model in screening of drugs for preventing and treating preeclampsia diseases and evaluation of drug effects.

The sixth aspect of the invention provides application of the Sirt1 gene in preparing a medicament for preventing and treating preeclampsia diseases.

The invention has the beneficial effects that:

the invention provides a novel preeclampsia disease animal model which does not need external medicine and operation intervention, does not need special feed and special feeding environment for propagation, and can completely reduce preeclampsia diseases.

According to the method, the Sirt1 gene expression of the target animal is partially knocked out, so that the target animal shows more typical preeclampsia characteristics, the rise of blood pressure in the late gestation period is spontaneously formed, the target animal recovers after delivery, and fetal rat genes and Sirt1 are found^+/-The pregnant mouse has relativity to the blood pressure difference value in the early and late gestation period; in addition, Sirt1 was found in the late gestation^+/-The proportion of the placenta function layer of the pregnant mouse is reduced, which prompts the functional disorders of placenta trophoblast invasion, spiral artery recasting and the like, and proteinuria and kidney lesion appear; under the action of the gene agonist, relevant pathological manifestations can be restored, the successful construction of a disease model is prompted, and the fact that the gene is one of the pathogenic genes in preeclampsia is demonstrated.

The preeclampsia disease animal model can be used for helping to clarify the pathogenesis and mechanism of preeclampsia diseases and can also be used for helping to screen and evaluate the drug effect of the preeclampsia diseases.

Drawings

FIG. 1A shows Sirt1^+/-Schematic diagram of construction of a whole-body knockout heterozygote pregnant mouse.

FIG. 1B is PCR agarose gel electrophoresis analysis of Sirt1^+/-The genotype of the offspring of the heterozygous pregnant mouse (fetal mouse, E18.5: 18.5 days of pregnancy) is knocked out in a whole body. In the figure, M is a DNA indicator band, WT is Sirt1^flox/floxPregnant mouse tail control, KO knockout gene band indicated size: 500bp, HO: homozygote, HE: heterozygote, WT wild gene band indicates size: 900 bp. B33-1, B33-2 and B33-4 are heterozygote Sirt1^+/-B33-3 and B33-5 are homozygote Sirt1^-/-。

FIG. 1C shows Sirt1^+/-Group sum Sirt1^flox/floxImmunofluorescence of Sirt1 in group placenta (E18.5) tissues. CK7 labeled trophoblasts and DAPI labeled nuclei. Sirt1 can be seen^+/-The expression of the trophoblast Sirt1 in the group placenta is obviously reduced, and the knockout efficiency is verified.

FIG. 1D shows Sirt1^+/-Group sum Sirt1^flox/floxMice of group origin (E18.5) andappearance of placenta (E18.5). Sirt1 can be seen^+/-Both fetal rat and placenta of group were less than Sirt1^flox/floxAnd (4) grouping.

FIG. 1E shows Sirt1^+/-Group sum Sirt1^flox/floxGroup embryo uptake rate. Sirt1^+/-Groups had an ascending trend but no statistical difference.

FIG. 1F shows Sirt1^+/-Group sum Sirt1^flox/floxGroup placenta (E18.5) weight. Sirt1^+/-Groups showed no statistical difference, although they tended to decline.

FIG. 1G shows Sirt1^+/-Group sum Sirt1^flox/floxGroup fetal rat (E18.5) weight. Sirt1^+/-Group comparison Sirt1^flox/floxThe group decreased significantly.

FIG. 1H shows Sirt1^+/-Group sum Sirt1^flox/floxThe ratio of genes in E18.5 and P28 in the mice. E18.5: day 18.5 of gestation, P28: postnatal 28 days, HO: homozygote, HE: heterozygote, WT: and (4) a wild type. After 28 days of birth, the survival rate of the homozygote is extremely low, and the lethal phenomenon of the homozygote in the perinatal period is verified.

FIG. 1I is Sirt1^+/-Group sum Sirt1^flox/floxBlood pressure of each pregnancy period of the pregnant mice. Basic condition: basal status (non-pregnant), EarlyPG: early pregnancy, MidPG: middle trimester, latex g: in the late gestation period. Sirt1 can be seen^+/-Blood pressure of pregnant mice in the late gestation period is obviously increased.

FIG. 1J shows Sirt1^+/-Group sum Sirt1^flox/floxBlood pressure difference of early and late gestation of the pregnant rats. Sirt1 can be seen^+/-The blood pressure in the late pregnancy of the group shows a remarkably rising trend compared with the blood pressure in the early pregnancy.

FIG. 1K is Sirt1^+/-And (3) analyzing the correlation between the blood pressure difference of the pregnant mouse in the early and late gestation period and the ratio of the fetal mouse (E18.5) knockout gene, namely the Sirt1 gene. Therefore, the proportion of the knockout gene in fetal mice and the blood pressure difference of pregnant mice in early and late pregnancy have certain linear relation and have statistical significance.

FIG. 1L is Sirt1^+/-Group sum Sirt1^flox/floxMasson staining and PAS staining of kidney tissue of gestating mice (E18.5). Sirt1 can be seen^+/-Diffuse increase of endothelial cells of glomerular capillaries in late pregnancy of pregnant mouseBirth and swelling, narrowing of the capillary lumen, and presenting with more typical preeclampsia renal lesions.

FIG. 1M is Sirt1^+/-Group sum Sirt1^flox/floxUrine protein concentration of pregnant mice (E17.5-E18.5). Sirt1 can be seen^+/-The urine protein of pregnant mice in the later gestation period is obviously increased.

FIG. 1N is Sirt1^+/-Group sum Sirt1^flox/floxPlacental longitudinal sections of pregnancies rats (E18.5). Labyrinth layer: consists of maternal blood sinuses and villi, mediates the exchange of nutrient, gas and metabolic waste between the mother and the fetus, and is the functional layer of the pregnant mouse placenta, the connecting area: i.e., the sponge layer, has primarily endocrine function, often indicating the area of placental active function as the labyrinth/junction zone.

Fig. 1O is a statistical plot of the placental labyrinth layer/junction area described above. Sirt1 can be seen^+/-The active functional area of the pregnant mouse placenta is compared with Sirt1^flox/floxPregnant mice were significantly narrower.

FIG. 1P shows Sirt1^+/-Group sum Sirt1^flox/floxBlood pressure of pregnant mice in late gestation period and postpartum blood pressure. E17/18: blood pressure at day 17.5 of pregnancy, P2/3: 2.5 days after delivery. Sirt1 can be seen^+/-Pregnant mice recover from elevated blood pressure after delivery.

FIG. 1Q is Sirt1^+/-Group sum Sirt1^flox/floxThe postpartum urine protein (P2.5-P3.5) of the pregnant mice. Sirt1 can be seen^+/-Pregnant mice recover from elevated urine protein after delivery.

Figure 2A is a dosing regimen. After embolus appears in 0.5 day of pregnancy, Sirt1 is added^+/-Pregnant mice were randomly divided into two groups, SRT2104 and Vehicle (solvent) groups, from E1.5 to E17.5 (day 1.5 to day 17.5 of pregnancy), SRT2104 group was intraperitoneally injected with SRT 2104200 mg/kg every other day, and Vehicle group was injected with an equal amount of solvent.

Fig. 2B shows the appearance of fetal rats (E18.5) and placenta (E18.5) in the Vehicle group and SRT2104 group. The SRT2104 group of fetal mice was significantly larger than the Vehicle group.

FIG. 2C shows the absorbance of the Vehicle group and SRT2104 group embryos. There was a trend of decreasing uptake of SRT2104 group embryos, but there was no statistical difference.

FIG. 2D shows placenta (E18.5) weights of the Vehicle group and the SRT2104 group. The SRT2104 placenta group was heavier than the Vehicle group.

FIG. 2E shows the weights of fetal mice (E18.5) from the Vehicle group and the SRT2104 group. The SRT2104 group of fetal mice was heavier than the Vehicle group.

FIG. 2F shows the blood pressure of pregnant mice in both the Vehicle group and the SRT2104 group during pregnancy. Basic condition: basal status (non-pregnant), EarlyPG: early pregnancy, MidPG: middle trimester, latex g: in the late gestation period. Showing Sirt1 after administration of SRT2104^+/-The blood pressure of pregnant mice in the late gestation period due to gene increase is corrected.

FIG. 2G shows the blood pressure difference between the early and late gestation in pregnant mice in the Vehicle group and the SRT2104 group. It can be seen that after administration of SRT2104, Sirt1^+/-The blood pressure of pregnant mice in the late gestation period due to gene increase is corrected.

FIG. 2H shows the urinary protein levels of pregnant mice in the Vehicle group and SRT2104 group (E17.5-E18.5). Showing Sirt1 after administration of SRT2104^+/-The urinary protein of pregnant mice in the late gestation period due to gene increase is corrected.

FIG. 2I shows Masson staining and PAS staining of kidney tissues of pregnant mice (E18.5) in the Vehicle group and SRT2104 group. It can be seen that after administration of SRT2104, Sirt1^+/-The kidney lesion caused by the gene in the late gestation period of the pregnant mouse is corrected.

FIG. 2J shows placental longitudinal sections of pregnant mice (E18.5) from both the Vehicle group and the SRT2104 group.

Fig. 2K is a statistical map of the placental labyrinth layer/junction area described above. Suggesting that SRT2104 post-dose Sirt1^+/-The labyrinthic layer of pregnant mice in the late gestation period due to gene constriction is corrected.

Detailed Description

The invention is explained in more detail below with reference to exemplary embodiments and the accompanying drawings. The following examples are provided only for illustrating the present invention and are not intended to limit the scope of the present invention.

1 preeclampsia disease animal model: sirt1^+/-Construction of whole-body knockout heterozygote pregnant mouse

As required by subsequent experiments, the promoter-driven Cre-loxP system is adopted in the invention. Sirt1 was introduced from JAX (the Jackson laboratory)^flox/floxGene editing mice (B6.129-Sirt 1)^tm3Fwa/DsinJ). And order Nanmo BioCorp (Shanghai, Square model Biotechnology, Inc.)Limited corporation) Dppa3-IRES-Cre mouse, because Dppa3-Cre can effectively play the activity of Cre recombinase in early embryonic stage and germ cell line, the mouse is an effective commercial tool mouse for constructing a whole-body knockout model. The south Mount Biometrics company was entrusted with crossing and propagated via Cre elimination to obtain Sirt1^+/-Heterozygous pregnant mice were knocked out systemically and the mating strategy is shown in figure 1A:

1) introduction of Sirt1 from JAX^flox/floxGene editing mice (B6.129-Sirt 1)^tm3FwaDsinJ, numbering: 029603 also known as Sirt1^flox/floxMouse).

2) Order the commercially available Dppa3-IRES-Cre mouse from south mous biology.

3) Mix Sirt1^flox/floxMouse and wild type Sirt1^+/+Hybridizing and propagating the mice to obtain Sirt1^flox/+A mouse.

4) Mix Sirt1^flox/+The mice were crossed with Dppa3-IRES-Cre mice to obtain Sirt1^flox/+DPPA3-CRE⁺A mouse.

5) Mix Sirt1^flox/+DPPA3-CRE⁺Mouse and wild type Sirt1^+/+Hybridizing the mice, removing DPPA3-CRE gene, and further expanding propagation to obtain Sirt1^+/-Heterozygote mice were knockout systemically.

6) Mix Sirt1^+/-The heterozygote mouse is knocked out and combined with the cage all over the body to obtain Sirt1^+/-Whole-body knockout heterozygote pregnant mouse (hereinafter simply called Sirt 1)^+/-Pregnant mice) i.e. the preeclampsia disease animal model.

7).Sirt1^+/-The pregnant mouse is bred to obtain offspring, and the genotype is represented as follows: 1/2 heterozygote: sirt1^+/-1/4 wild type: sirt1^flox/floxAnd 1/4 homozygotes: sirt1^-/-(less survival in perinatal period). Mix Sirt1^flox/floxMice were caged to obtain Sirt1^flox/floxAnd (5) pregnant mice.

8) Verifying the fetal mouse genotype through PCR agarose gel electrophoresis and verifying the Sirt1 protein expression down-regulation in the placenta tissue through an immunofluorescence technology, as shown in figures 1B and 1C; and confirmed literature reports of homozygote fetal rat perinatal lethality, as shown in FIG. 1H.

2 the pre-eclampsia disease animal model constructed by the method has pre-eclampsia-like symptoms

The invention further carries out systematic evaluation on preeclampsia related performance of the constructed preeclampsia disease animal model, and comprises the steps of collecting 24h urine of a pregnant mouse, observing basic conditions of pregnancy blood pressure, fetal mouse size, fetal mouse weight, embryo absorption rate of the pregnant mouse and the like, carrying out cervical dislocation and sacrifice after 18.5 days of pregnancy, and taking kidney and placenta tissues for further morphological observation. Random selection of Sirt1 in the same batch grouping^+/-The pregnant mouse is kept until parturition, and the blood pressure recovery condition, the urine protein improvement condition and the like are observed. Hybrid group Sirt1^+/-The pregnant mice in the group were Sirt1^+/-Pregnant mice, control group Sirt1^flox/floxThe pregnant mice of the group were Sirt1^flox/floxAnd (5) pregnant mice.

We have found Sirt1^+/-Embryo uptake in pregnant mice was almost normal (fig. 1E). The weight differences between the two placenta groups were not statistically significant (FIG. 1F, Sirt 1)^+/-Sirt1 group vs^flox/floxGroups). Since preeclampsia can cause Fetal Growth Restriction (FGR), we analyzed Sirt1^flox/floxGroup sum Sirt1^+/-The live tires of the group were heavy and found to be Sirt1^+/-Group live carcass weight significantly decreased (FIG. 1G, Sirt 1)^+/-Sirt1, group vs^flox/floxGroup (2): 0.7803 + -0.1651 vs.0.8559 + -0.1585 g). Representative images of groups of fetal mice and placenta are shown in FIG. 1D, along with Sirt1^flox/floxGroup comparison, Sirt1^+/-The group born mice were small. Subsequently, we analyzed the change in Systolic Blood Pressure (SBP). Interestingly, Sirt1^+/-Significantly elevated SBP levels in the late gestation of the gestating mice (FIG. 1I, Sirt 1)^+/-Sirt1, group vs^flox/floxGroup (2): 119.6 +/-9.952 vs.108 +/-6.340 mmHg). To understand the level of blood pressure rise, we calculated the difference Δ BP between the late-gestation systolic pressure and the early-gestation systolic pressure. We have found that Δ BP is at Sirt1^+/-Higher levels were present in the group (FIG. 1J, Sirt 1)^+/-Sirt1, group vs^flox/floxGroup (2): 12.45 ± 9.186vs. -1.562 ± 10.47 mmHg). Interestingly, Δ BP levels were positively correlated with Sirt1 gene values in fetal mice (fig. 1K). Sirt1^+/-Recovering blood pressure and urine protein level after parturition of pregnant mouse, as shown in figure 1P and figure1Q.

Renal injury is another characteristic of preeclampsia. Typical manifestations are urine protein and renal pathologies, including glomerular enlargement and reduced blood supply, due to endothelial cell swelling, with associated membrane cells and capillary lumen occlusion. In this study, we examined Sirt1^+/-Concentration of urine protein in early and late gestation of pregnant mice, Sirt1^+/-The concentration of urine protein in the late pregnancy of pregnant mice is obviously increased (figure 1M, Sirt 1)^+/-Sirt1, group vs^flox/floxGroup (2): 2.316 + -0.05245 vs.2.189 + -0.05252 ug/ml). We also observed pathological changes in the kidneys of each group with Masson staining and PAS staining. And Sirt1^flox/floxGroup comparison, Sirt1^+/-The gestating mice exhibited typical preeclampsia-associated glomerular injury (FIG. 1L). In addition, placental abnormalities are a substantial change in patients with preeclampsia. In our mouse model, we observed Sirt1 in Masson staining results^+/-Labyrinth layer comparison Sirt1^flox/floxNarrow (fig. 1N). We measured the labyrinth layer/junction area ratio for each group of placentas and found Sirt1^+/-Group and Sirt1^flox/floxThe labyrinthine layer/junction area ratio decreased significantly compared to the group (fig. 1O). The labyrinth layer is a dense structure formed by trophoblasts and associated fetal blood vessels undergoing extensive villous branching. The labyrinthine layer is the functional layer of the placenta, and narrowing of the labyrinthine layer means dysfunction of the placenta. However, as we previously mentioned, there was no significant difference in the weight of the two groups of placentas (fig. 1F), which is likely due to the difference in handling caused by the residual decidua of part of the placentas at the time of primary exfoliation.

Sirt1^+/-Typical preeclampsia-like symptoms appear in the pregnant period of the pregnant mice, and are shown as hypertension, urine protein, low fetal weight, kidney injury and reduction of proportion of placenta labyrinth layer, so that successful construction of a preeclampsia-like mouse model is prompted.

The 3 Sirt1 agonist SRT2104 significantly improved Sirt1^+/-Preeclampsia-like symptom of pregnant mouse

Furthermore, we have experimentally found that supplementation with Sirt1 agonists can reverse the onset of the above pathological manifestations. To verify the effect of Sirt1 in preeclampsia, we ranged from E1.5 to E17.5 (day 1.5 to day 17.5 of pregnancy), every dayIntraperitoneal injection of SRT 2104200 mg/kg (working solution concentration 3mg/ml) to Sirt1 every other day^+/-Pregnant mice, as SRT2104 group. The Vehicle (solvent) group was injected with equal amount of solvent (solvent for SRT 2104: 5% DMSO + 40% PEG300+ 5% Tween80+ 50% ddH₂O), as a control group. The course of treatment of mice is shown in figure 2A.

Administering SRT2104 treatment Sirt1^+/-After pregnancy, there was no significant change in embryo absorption rate (FIG. 2C), a slight increase in placenta weight (FIG. 2D, Vehicle group vs. SRT2104 group: 0.08519 + -0.01009 vs.0.09237 + -0.01213 g), and a significant increase in fetal mouse weight (FIG. 2E, Vehicle group vs. SRT2104 group: 0.6808 + -0.08630 vs.0.7719 + -0.1483 g). These results are consistent with representative images of fetal mice and placenta (fig. 2B). It is evident that both the systolic blood pressure levels in the late gestation period in group SRT2104 (FIG. 2F, group Vehicle vs. SRT2104: 117.8 + -8.311 vs.107.4 + -10.21 mmHg) and Δ BP (FIG. 2G, group Vehicle vs. SRT2104: 8.158 + -9.212 vs. -5.234 + -12.86 mmHg) were significantly reduced compared to group Vehicle. SRT2104 ameliorated kidney injury, decreased urine protein concentration in late gestation (FIG. 2H, Vehicle group vs. SRT2104 group: 7.397 + -3.293 vs.3.392 + -0.7711 ug/ml), and glomerular morphology was essentially normal (FIG. 2I). Following intraperitoneal injection using SRT2104, the placenta also showed labyrinthine layer broadening (fig. 2J-2K).

These results demonstrate that increased expression of Sirt1 can reverse preeclampsia-like behavior, further demonstrating that Sirt1 is an important causative factor in preeclampsia.

Claims (7)

1. Application of Sirt1 gene in constructing preeclampsia disease animal model.
2. 2. An animal model of preeclampsia diseases is characterized by using Sirt1^+/-The pregnant mouse with heterozygote knocked out systemically is an animal model with preeclampsia diseases.
3. 3. The pre-eclamptic disease animal model of claim 2, wherein said Sirt1^+/-The whole-body knockout heterozygote pregnant mouse is obtained by the following steps: mix Sirt1^flox/floxThe gene editing mice were propagated and crossed with Dppa3-IRES-Cre miceAnd (5) carrying out Cre removal breeding.
4. 4. The construction method of the animal model of the preeclampsia disease is characterized by comprising the following steps: mix Sirt1^{flox /flox}After propagation, the gene editing mice are crossed with Dppa3-IRES-Cre mice, and after Cre removal propagation, Sirt1 is obtained^+/-The heterozygous pregnant mouse is knocked out systemically, and the established preeclampsia disease animal model is obtained.
5. 5. Use of the preeclampsia disease animal model of claim 2 or 3 in studying the pathogenesis and mechanism of preeclampsia disease.
6. 6. The use of the preeclampsia disease animal model of claim 2 or 3 in screening of drugs for prevention and treatment of preeclampsia diseases and evaluation of drug efficacy.
7. Application of Sirt1 gene in preparation of medicine for preventing and treating preeclampsia diseases.

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