The novel coronavirus called as severe acute respiratory syndrome coronavirus 2 (SARSCoV-2) was detected for the first time in December 2019 in Wuhan (China) and the disease it causes is named as coronavirus disease 2019 (COVID-19). COVID-19 is an emerging health threat in the world. To June 8, 2020 there were 7,106,010 confirmed cases and 406,395 deaths (5.7%) from COVID-19.1,2 Several factors have been associated with higher death as age, some comorbidities (arterial hypertension, diabetes mellitus, smoking, chronic obstructive pulmonary disease, cerebrovascular or cardiovascular diseases), blood biomarkers (of inflammation, muscle injury, cardiac injury, liver dysfunction, coagulation alterations and kidney dysfunction), and clinical data as the development of acute respiratory distress syndrome (ARDS).3–8

Human Leukocyte Antigen (HLA), located in the short arm of human chromosome 6 (6p21.3), represents one of the most highly polymorphic systems in the human genome and plays a central role in the regulation of immune response. The HLA system include near to 27,000 alleles in three distinct classes of genes (Class I, II and III). Of the three classes of genes, HLA class I-A, B, C and class II-DR, DP, DQ play a crucial role in various immunological functions in human including antigen presentation to T lymphocytes and recognition of self and non-self proteins. HLA class I and II gene polymorphisms provide the strongest and most consistent alleles for autoimmune diseases susceptibility.9,10

HLA plays a central role in antigen presentation and therefore different allelic polymorphism could be involved in the susceptibility to infectious diseases. Different genetic polymorphisms of HLA have been associated with predisposition and/or outcome of different infectious diseases such as hepatitis B virus (HBV), hepatitis C virus (HCV), Chikungunya, Chagas, dengue, influenza A(H1N1) and tuberculosis.11–30 In addition, a recently published study found a higher rate of some HLA alleles in 82 COVID-19 non-critically ill patients than in control subjects.31 However, we have not found data about HLA and prognosis of COVID-19 patients. Thus, the objectives of this study were to determine whether there is an association between HLA genetic polymorphisms and susceptibility to and mortality of COVID-19 patients.

Genotyping of HLA-A, HLA-B, HLA-C, HLA-DRB1 and HLA-DQB1 loci was performed in 3886 healthy controls and 72 COVID-19 patients (Supplementary Tables 1–5). We found a trend to a higher rate of the alleles HLA-A*32 (p=0.004) in healthy controls than in COVID-19 patients, and of the alleles HLA-A*03 (p=0.047), HLA-B*39 (p=0.02) and HLA-C*16 (p=0.02) in COVID-19 patients than in healthy controls; however, all these p-values no were significant after correction for multiple comparisons.

We found that non-surviving (n=10) compared to surviving patients (n=62) showed higher APACHE-II (p<0.001) and SOFA (p<0.001) (Tables 1 and 2). We found a trend to a higher rate of the alleles HLA-A*11 (p=0.051), HLA-C*01 (p=0.09) and HLA-DQB1*04 (p=0.051) in non-surviving than in surviving patients (Supplementary Tables 1–5). Logistic regression analysis showed that the presence of allele HLA-A*11 was associated with higher mortality after controlling for SOFA (OR=7.693; 95% CI=1.063–55.650; p=0.04) or APACHE-II (OR=11.858; 95% CI=1.524–92.273; p=0.02). In addition, the allele HLA-C*01 was associated with higher mortality after controlling for SOFA (OR=11.182; 95% CI=1.053–118.700; p=0.04) or APACHE-II (OR=17.604; 95% CI=1.629–190.211; p=0.02). Besides, the presence of allele HLA-DQB1*04 was associated with higher mortality after controlling for SOFA (OR=9.963; 95% CI=1.235–80.358; p=0.03), but no controlling for APACHE-II (Table 3).

To our knowledge, this is the first study reporting data on HLA genetic polymorphisms and susceptibility to and prognosis in COVID-19 patients. We found a trend to a higher rate of alleles HLA-A*32 in healthy controls than in COVID-19 patients, and of alleles HLA-A*03, HLA-B*39 and HLA-C*16 in COVID-19 patients than in healthy controls. The small sample size of our COVID-19 population could explain the absence of significant differences after Bonferroni correction in those and other HLA genetic polymorphisms.

We found that non-surviving compared to surviving patients showed higher APACHE-II and SOFA. We also found a trend to higher rate of the alleles HLA-A*11, HLA-C*01 and HLA-DQB1*04 in non-surviving than in surviving patients. As previously mentioned, the small sample size of our study could have explained these results. Therefore, we decided performed regression analyses to test the potential association of those HLA alleles and mortality. As 10 was the number of non-surviving patients at 30 days, we constructed several multiple binomial logistic regression models with only two predictor variables in each model to avoid over fitting effect. We included HLA-A*11 and SOFA in the first model, HLA-A*11 and APACHE-II in the second model, HLA-C*01 and SOFA in the third model, HLA-C*01 and APACHE-II in the fourth model, HLA-DQB1*04 and SOFA in the fifth model, and HLA-DQB1*04 and APACHE-II in the sixth model. An important finding is that all 3 alleles were associated with the mortality after controlling for SOFA, and the same was observed for alleles HLA-A*11 and HLA-C*01when controlled for APACHE-II.

The results of our study are in line with those of other studies in patients with other infectious diseases. Regarding to susceptibility, higher rate of HLA-A*32 has been found in patients with chronic HCV infection than in control subjects.11 A restricted response of cytotoxic T lymphocytes for HCV in presence of HLA-A*03 has been reported.12 Higher rate of HLA-B*39 was also found in patients with tuberculosis,13 Chagas disease14 and osteoarticular complications due to brucellosis15 in comparison with controls. There has been found higher rate of HLA-A*11 in patients with panbronchiolitis,17 dengue disease,18 HBV infection,19 influenza A(H1N1)pdm09 virus infection20 or invasive meningococcal disease than in control subjects.21 Higher frequency of HLA-C*01 has been found in patients with acute viral encephalitis than in control subjects.24 There has been found higher rate of HLA-DQB1*04 in patients with HBV,25 human papillomavirus (HPV) infection,26 post-histoplasmosis fibrosing mediastinitis27 or chikungunya viral infection encephalitis than in control subjects.28 In a recently published study has been found a higher rate of HLA-C*07:29 and HLA-B*15:27 in 82 COVID-19 non-critically ill patients than in control subjects.31 However, our study was underpowered to find an association between HLA genetic polymorphism and susceptibility to COVID-19 patients.

Interestingly, we found certain HLA genetic polymorphisms that could increase the risk of death in patients COVID-19. Previously, regarding to prognosis, the presence of HLA-C*16 increase the risk of rapid progression in patients with Acquired Immune Deficiency Syndrome.16 Also, the presence of HLA-A*11 has been associated with poor evolution of patients with HBV22 or active pulmonary tuberculosis.23 Besides, the presence of HLA-DQB1*04 has been associated with poor evolution of patients with HBV.29,30 However, to the best of our knowledge, no study has evaluated this aspect in patients with COVID-19.

We must recognize some limitations of our study. First, we only included two variables in each regression analysis model due to that the small number of death patients in our study, which precludes the inclusion of several variables,35 as previously has been reported in other researchs.36,37 That small number of death patients in our study was due to the small sample size and to the low mortality rate in our series (14%), which was in the lower limit of the range published by other series from ICU of our country (15–34%).38–40 Second, we studied mortality at 30 days and mortality at other moment of time have been not studied. Third, the rate of SDRA was higher, not statistically significant, in survivor than in non-survivor patients, possibly due to the small sample size. However, we think that the strengths of the study were that two HLA alleles in our study (HLA-A*11 and HLA-C*01) were associated with the mortality after controlling for SOFA or APACHE-II. In addition, the three HLA alleles associated with the mortality in our study (HLA-A*11, HLA-DQB1*04 and HLA-C*01), previously were associated with poor evolution in other infectious diseases (HLA-A*1122,23 and HLA-DQB1*0429,30) or with the risk of other infectious diseases (HLA-C*0124).

The new finding from our preliminary study of small sample size was that HLA genetic polymorphisms could be associated with COVID-19 mortality; however, studies with a larger sample size before definitive conclusions can be drawn.

LLo conceived, designed and coordinated the study, participated in acquisition and interpretation of data, and drafted the manuscript.

MMM, JJC, JSV, AP, JAMR, LRG, SL, APC, APL, LU, JAF, AE, PV, LuG, LoG, RA, MFZ, ROL, NO, ARP and CD participated in acquisition of data.

AF and YB carried out the determinations of HLA genetic polymorphisms.

AJ participated in the interpretation of data.

All authors revised the manuscript critically for important intellectual content and made the final approval of the version to be published.

This study was supported by a grant from Instituto de Salud Carlos III (PI-18-00500) (Madrid, Spain) and co-financed with Fondo Europeo de Desarrollo Regional (FEDER).

The authors declare that they have no competing interests.