Introduction
The new coronavirus severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has spread worldwide, raising multiple health concerns given the high frequency of cardiovascular comorbidities, particularly hypertension, among patients with severe forms of coronavirus disease (COVID)-19 and those who die1.
The functional receptor that internalizes SARS-CoV-2 in human cells is known to be a transmembrane enzyme, a variant of the angiotensin-converting enzyme (ACE) called ACE22-4, which is involved in counteracting the effects of ACE on the renin-angiotensin system (RAS)5. Furthermore, ACE inhibitors (ACEis) and angiotensin II receptor blockers (ARBs) have been shown to dysregulate the ACE/ACE2 balance in preclinical trials6,7.
Because both ACEis and ARBs are first-line drugs in the management of high blood pressure, heart failure, and diabetic nephropathy8-10, it was hypothesized that these RAS blockers could have negative implications in the pathogenicity or virulence in susceptible patients11-13. However, other studies support the cardiac and pulmonary benefits, due to the dysregulation of ACE/ACE2 in patients treated with ACEis and ARBs infected by SARS-CoV-2, equally based on observations in animal models14,15, opening a controversy: whether to encourage or discourage the use of ACEis or ARBs in patients susceptible to COVID-19.
Considering that hypertension is a public health problem in Mexico16, and recognizing the context of current controversy, several instances have called for caution in the interpretation of preclinical observations and advising against changes in the management of hypertensive patients17-21. Therefore, the purpose of this paper was to review the implications of the use of RAS blockers on the pathogenicity or virulence of SARS-CoV-2 and to make recommendations for the management of adults and children with hypertension.
Human SARS-CoV-2 receptor and its associated pathogenicity
The membrane that surrounds the coronaviruses has glycoproteins embedded in the form of spines called S-proteins. Such structures contain the binding site to the human cell receptor22. In the SARS-CoV-2 virus, certain S-binding site amino acids that are important for receptor recognition in human cells have undergone genetic modifications that are energetically favorable to S-protein coupling with ACE4,23, increasing their pathogenicity considerably, compared with other coronaviruses2,24,25.
Furthermore, ACE2 is a transmembrane metalloenzyme2,3 with carboxypeptidase activity22,26, whose expression is abundant in the small intestine, kidney, and cardiac muscle but scarce in the pulmonary alveolar epithelium25,27.
The pathogenicity of SARS-CoV-2 is very efficient in cells with low membrane ACE2 expression. Recent observations suggest that more non-described human receptors could contribute to its virulence28. In addition, a soluble fraction of ACE2 does not internalize the virus into the cell but may mediate the immune response at the respiratory mucosa29.
Effects of COVID-19 on RAS components
Two angiotensin (Ang) oligopeptides that mediate antagonistic effects in RAS, known as Ang-II and Ang-(1-7), are involved in the pathophysiology of hypertension and other cardiovascular conditions, as well as in SARS-CoV-2 infection5,7. Moreover, ACE transforms Ang-I into Ang-II, whose interaction with the Ang-II type 1 receptor (AT1) produces vasoconstriction, endothelial dysfunction in the vascular walls, as well as inflammation and cell growth5. ACE2 transforms Ang-I and II, producing Ang-(1-9) and Ang-(1-7), respectively. The latter binds to the Mas receptor, enhancing the vasodilation effects of bradykinins, inhibiting smooth muscle proliferation in arteries, the synthesis of collagen and certain cardiac proteins induced by Ang-II26,30, as well as mediating anti-inflammatory effects and improving the sensitivity of baroreceptors5,31,32. ACE is not only enzyme that produces Ang-(1-7) from Ang oligopeptides. Oligopeptidases thimet and prolyligopeptidase also produce Ang (1-7) in the vascular endothelium and smooth muscle; in the kidney, neprilysin produces the largest amount of Ang-(1-7) found in the bloodstream (Fig. 1)26.
SARS-CoV-2 may decrease tissue expression of ACE2, as observed in mouse lung tissue. The immediate effects of this decrease were increased levels of Ang-II at the lung33, increased vascular permeability, neutrophil accumulation, pulmonary edema and injury, and impaired respiratory function6,31,33,34. Clinically, this RAS imbalance has been observed in adults with severe COVID-19. These patients developed pneumonia and acute respiratory distress syndrome35, accompanied by increased Ang-II levels in the circulation, which correlates directly with SARS-CoV-2 viral load36. More evidence of RAS disorders in the cardiovascular system has been described. The severity of COVID-19 was associated with acute heart damage37. Considering that local ACE2 produces most of the Ang-(1-7) in heart tissue (which is a component of cardiovascular regulation26,30,38,39), the loss of membrane ACE2 will favor the overexpression of pro-inflammatory mechanisms, leading to damage40,41.
COVID-19 in hypertensive patients
A meta-analysis showed that high blood pressure is the most common comorbidity among patients hospitalized for COVID-19, with a frequency of 10.1%-23.6%42. Furthermore, high blood pressure is associated with an increased disease progression (odds ratio [OR] = 3.0; 95% confidence interval [CI] 1.5-5.9), admission to intensive care (OR = 2.1, 95% CI 1.3-3.3), poor outcomes during hospitalization (OR = 2.2, 95% CI 1.8-2.4), and mortality in patients hospitalized for COVID-19 (OR = 2.11, 95% CI 1.7-2.8)43. These associations with hypertension also appear to be influenced by gender in adults43, possibly because men express more ACE2 in lung cells than women44.
Interestingly, only 3% of children with COVID-19 develop a severe or critical illness; however, the characteristic signs and symptoms of the disease differ between children and adults. Furthermore, SARS-CoV-2 appears less pathogenic in children than SARS-CoV45,46. The overall prevalence of childhood hypertension is low (4%)47 and is predominantly secondary to other identifiable causes (57%)10,48. Therefore, the information available regarding RAS in children is scarce.
Consequently, it is important to explore the role of age and aging on the function of RAS components. Although the occurrence of chronic disease is associated with age49, and both with mortality in patients with COVID-1950-52, it is not clear that the enzyme components of RAS are modified only by age in adults53, where gender appears to play a differentiating role during aging54,55. In contrast, age does exert an important influence on Ang-I and Ang-II concentrations among children and adolescents. Although these enzymes decrease progressively from birth and during childhood, they remain higher than in healthy adults except for Ang-(1-7), of which there are few studies in children and adolescents56. Recently, gene expression of ACE2 in nasal epithelial cells has been reported to be positively correlated with age in patients between 4 and 60 years, with and without asthma (being lower at younger ages)57, suggesting an explanation for the limited severity of COVID-19 in children.
The absence of differences between the expression of ACE2 and other RAS components by age groups53 may be explained by the fact that the accumulated fraction in bronchoalveolar lavage fluid, as well as concentrations in human plasma, is not quantitatively representative of expression at the cell membrane29,58, thus being inappropriate indicators of ACE2 activity59. Moreover, there are other hypotheses about the lower virulence of SARS-CoV-2 in children, not related to ACE2 but rather to children’s mobility, absence of comorbidities, better respiratory tract status, increased innate immune response efficiency, and the supposed benefit attributed to certain vaccines60-62.
Despite the above, it is not yet possible to affirm that patients with arterial hypertension are more likely to be infected with COVID-19, since neither the increase in membrane level of ACE2 in hypertensive patients nor the increased SARS-CoV-2 pathogenicity, alone are sufficient factors for this to occur. Studies evaluating comparative cohorts of hypertensive patients using RAS-blocking drugs that include hypertensive patients not treated by these drugs, and healthy individuals are required to confirm whether the infection rate is different between these groups. Since 81% of the COVID-19 cases are mild and will not seek medical attention52,63, hospital selection bias is relevant in the epidemiological reports available so far. Only in one sufficiently large but not yet published report, history of hypertension was observed in 24% of individuals with confirmed COVID-19, covering those with outpatient and inpatient care64, but there are no cohorts and no distinction between ACEi or ARB users, but rather a large number of cases, so it is not yet possible to draw any conclusions.
ACEis, ARBs, and the modification of RAS components in preclinical models
The administration of losartan in mice reversed the dysregulation of RAS components produced by SARS-CoV and the severity of lung damage33,34. Multiple preclinical trials have shown that the administration of ACEi increases the expression of ACE2 in ranges of 50% up to 5 times, while ARBs increase it between 30% and 9 times. These drugs also increase the tissue concentration of Ang-(1-7), ARBs increase it between 10% and 2 times and ACEis between 20% and 70%. The extent of the effect may be due to methodological variations, use of different animal species or models, tissues analyzed, multiple compared groups (healthy or sick without treatment), and drugs tested65-74.
Of these trials, four evaluated the effects of RAS blockers in healthy animals66,67,71,75. In three of these, administration of lisinopril, telmisartan, or losartan did not have consistent results in increasing the expression of messenger RNA (mRNA) of ACE2 in the cardiac muscle66,67 or renal arterioles71. Nevertheless, the administration of ARBs produced an increase in ACE2 activity66,67,71, as well as a tissue increase in Ang-(1-7) and Ang-II substantially reflected in plasma66,67,71,75. In addition, one study demonstrated the paradoxical reduction of the expression of the Ang-(1-7) Mas receptor in cardiac muscle67; no RAS blocker modified the expression of endothelial neprilysin66,67.
In animal models with some cardiovascular pathology, it was observed that the administration of ACEis (lisinopril or enalapril) or ARBs (losartan or olmesartan) produced an increase in ACE2 mRNA, both in renal smooth muscle and cardiac muscle, including the carotid artery65,68-70,73; in two studies, increased ACE mRNA expression was also observed69,70. Although in most trials, increases in ACE2 cell activity in kidney, heart, and plasma were equally seen after ACEis and ARBs treatment68-70,72, the expression in cardiac tissue was not always different with and without treatment73,74. Finally, models of hypertension showed that ACEis and ARBs effect on the Mas and AT1 receptors expression is tissue dependent, both reduced the AT1 receptor expression in the kidney, in addition to normalizing its expression in the heart; only lisinopril reduced the Mas expression in the kidney69.
Clinical use of ACEis or ARB-II and how it is associated with COVID-19 patients
It has been observed that in users of ACEis, with various cardiovascular conditions, the risk of severe pneumonia is reduced by 45-20%. Furthermore, they present 27% reduction in mortality; this reduction is not observed among users of ARBs76. Similarly, in a prognostic study, it was reported that mortality from sepsis at 90 days was reduced among patients using ACEis or ARBs compared to non-users77. Furthermore, the ACE2 soluble fraction could be increased in hypertensive patients treated with ACEis and ARB-II, since in a cohort study, an increase in urinary excretion of this enzyme was observed in users compared to non-users78. In such cases, ACEis or ARBs users, who are susceptible to infection with SARS-CoV-2, may have a reduced risk of severe pneumonia and progression to respiratory failure, being complications of severe COVID-1935,50,79; therefore, it is not recommended to discontinue RAS blocking medications.
Among patients with chronic heart failure, treatment with ACEis allows a reduction of Ang II and improves the plasma ratio of Ang-(1-7)/Ang-II, which prevents ventricular remodeling. In contrast, blockade of the AT1 receptor in patients with acute heart failure with decreased ejection fraction may increase mortality and prolong hospitalization80,81; in such cases, therapeutic management should avoid the accumulation of Ang-II and reduction of the Ang-(1-7)/Ang-II ratio, preferably with ACEis.
Therefore, the following consideration should be made; Ang-(1-7) levels are associated with the degree of heart failure, when cardiomyopathy or advanced heart failure is present, Ang-II levels are much higher, despite ACEis80. This may indicate that plasma levels of Ang-(1-7) are dependent on neprilysin and other peptidases when the severity of the imbalance between ACE and ACE2 is too pronounced26. Recently, in a cohort of 42 patients infected with SARS-CoV-2 with Grade II and III hypertension, severe cases were observed less frequently among ACEis or ARBs users (24% users vs. 48% non-users), but without statistical significance due to the small size of the cohorts82. There was no difference in viral load between RAS blocker users and non-users82, indicating that the mechanisms of protection of RAS blocker antihypertensive drugs against SARS-CoV-2 infection may be much more complex and indirect and that the levels of ACE2 and Ang-(1-7) vary by the age and sex of individuals44.
In this regard, other hypotheses indicate that patients treated by RAS blockers would benefit by avoiding, to some extent, the cytopenia of CD3+ and CD8+ T cells82,83 observed in 64% of patients hospitalized with COVID-1939,79,84, and whose magnitude is greater among the deceased compared to survivors50,79. Considering the association between inflammation and the worsening of COVID-1925,50,51,79,84, it is desirable to continue treatments with ACEis and ARBs in all susceptible patients.
Two additional aspects should be considered: first, the progression of cardiovascular disease in patients with hypertension may facilitate complications of COVID-19. At the community level, 64% of antihypertensive drugs prescribed in adults are ACEis and 16% are ARBs. However, in Mexico City, only 38% and 27% of ACEis and ARB users have their hypertension under control, respectively85, so the benefits of increased ACE2 may be greater in patients with less advanced chronic conditions80. Second, from a pharmacological point of view, ACEis and ARBs differ considerably in their histological distribution: ACEis usually have larger distribution volumes than ARBs, influencing their ability to modify the local intrinsic RAS system8, which is responsible for the higher concentration of Ang-II and Ang-(1-7) in tissues5. Possibly for that reason, ACEis and ARBs do not regulate mRNA, ACE, and ACE2 expression equally in all tissues73,74, and this regulation may be dose dependent32.
Particularly in children with essential or renovascular hypertension, no reports are warning of any risk from the use of antihypertensive ACEis or ARBs concerning COVID-19. In these patients, the plasma concentration of Ang-(1-7) is increased by 1.5 times as a compensation for the dysregulation of Ang-I and Ang-II ratio, being especially beneficial the use of ACEis in hypertensive children who are not in a terminal stage86,87. It should be noted that the safety and efficacy of adult-related antihypertensive drugs have not been reassessed in pediatric populations10,48, and therefore, it is not advisable to change treatment regimens either. It should also be noted that, unlike hypertensive adults, not all cases of childhood hypertension require pharmacological treatment10.
Other drugs that affect the ACE2 expression
In preclinical models, statins and ibuprofen have been shown to increase the expression of ACE2, reversing atherosclerosis in rabbits, and cardiac fibrosis in rats88,89. Furthermore, cohort studies showed that continuing statin therapy during hospitalization in patients with viral pneumonia is associated with 74% mortality risk reduction; likewise, continuing treatment with ACEis or ARBs in hospitalized patients is associated with 75% reduction in mortality. Continuing both treatments are also associated with reduced hospital stay and risk of intubation90,91. For hospital management of ACEis and statin users, discontinuation of RAS blockers on admission is associated with an increased risk of mortality (OR = 3.02, CI 1.3-7.0)91.
Few mild cases of COVID-19 have been reported that worsened after taking ibuprofen92,93. Ibuprofen increases both ACE2 and Ang-(1-7) in tissues89, this generated a discussion similar to that presented with RAS blockers about whether its use increases the risk of infection or protects against certain pathophysiological processes produced by SARS-CoV-2; the resolution of this conflict is theoretically unsolvable. However, it has been suggested that previous use of nonsteroidal anti-inflammatory analgesics could complicate the hospital course of cases with pneumonia94. In such circumstances, replacement with paracetamol does not involve any underlying complications, in contrast with any change in the anti-hypertension therapies, which involve periods of adaptation and medical monitoring for the risk of adverse events.
Preclinical studies are a guide, not always easy to interpret, for translational research in the clinical field, so it is not appropriate to extrapolate their results. The evidence presented here does not allow us to state that patients with hypertension become more ill with COVID-19 as a result of receiving treatment with ACEis or ARBs. However, it is possible that the use of ACEis or ARBs in infected patients may confer some protection against the occurrence of respiratory complications, cardiovascular damage, and severe inflammation produced by the new coronavirus virulence mechanisms. In the absence of stronger evidence and the ever-present risk of adverse events, it is desirable and advisable that the administration of RAS blocking drugs be continued during hospitalization and not to modify the antihypertensive therapy of adult or child patients.