Two new HLA-DQB1*03:02:01 variants with substitutions in intron 2: HLA-DQB1*03:02:01:19 and -DQB1*03:02:01:21.

Two different single nucleotide substitutions in intron 2 give rise to novel HLA-DQB1*03:02:01 alleles.

Detection of two HLA-B*35 variants: HLA-B*35:01:01:39 and -B*35:03:01:32.

Two nucleotide substitutions in intronic regions give rise to the novel alleles: HLA-B*35:01:01:39 and -B*35:03:01:32.

Discovery of three HLA-DQB1*03:01:01 variants: HLA-DQB1*03:01:01:54, -DQB1*03:01:01:56 and -DQB1*03:01:01:58.

Three nucleotide substitutions in intronic regions give rise to the novel alleles: HLA-DQB1*03:01:01:54, -DQB1*03:01:01:56, -DQB1*03:01:01:58.

HLA-DPA1*02:01:25, a novel allele with a synonymous transition in exon 2 identified by next-generation sequencing.

HLA-DPA1*02:01:25 differs from DPA1*02:01:01:02 by a synonymous transition in exon 2.

Characterization of seven novel HLA-DPA1*01:03:01 non-coding variants by next-generation sequencing.

Seven different single nucleotide substitutions in non-coding regions gave rise to novel HLA-DPA1*01:03:01 variants.

Next-generation sequencing identifies four novel HLA class I alleles with nucleotide substitutions in the 3' UTR.

Characterization by next-generation sequencing of four novel HLA alleles: C*17:03:01:07, C*16:01:01:39, B*15:17:01:07, and B*44:03:01:57.

Characterization of the first HLA-DQA1 allele with Aspartic Acid in the transmembrane domain, HLA-DQA1*05:71.

HLA-DQA1*05:71, the first HLA-DQA1 allele with Aspartic Acid at residue 208 in the transmembrane domain.

Transitions in intronic regions result in two novel HLA-DQB1 alleles: -DQB1*05:02:01:13 and -DQB1*05:02:01:14.

Two transitions in intronic regions give rise to the novel alleles: HLA-DQB1*05:02:01:13 and HLA-DQB1*05:02:01:14.

The novel HLA-DQB1*03:02:01:14 allele was possibly generated by a recombination event.

The novel HLA-DQB1*03:02:01:14 was likely generated by a recombination event between DQB1*03:02:01:01 and DQB1*03:03:02:01.

A missense substitution in exon 1 generates the first HLA-DRB1 allele with Valine at residue -17, DRB1*04:354.

A missense nucleotide substitution in codon -17 in the leader peptide results in the novel HLA-DRB1*04:354 allele.

Detection and characterization of the novel HLA-DPA1*02:66:02N allele, with a premature stop codon in exon 2.

The failure to identify HLA null alleles in bone marrow transplantation could be life-threatening because this could result in an HLA mismatch with the ability to trigger the graft-vs-host disease (GVHD) and to reduce patient's survival. In this report we describe the identification and characterization of the novel HLA-DPA1*02:66:02N allele with a non-sense codon in exon 2. This new allele was discovered in two unrelated bone marrow donors during routine HLA-typing using next-generation sequencing (NGS). DPA1*02:66:02N is homologous to DPA1*02:01:01:03 with a single nucleotide difference in exon 2, codon 50, where the replacement of C located at genomic position 3825 by T, causes the formation of a premature stop codon (TGA), resulting in a null allele. This description illustrates the benefits of HLA typing by NGS since it permits to reduce ambiguities, identify new alleles, analyze multiple HLA loci and improve transplantation outcome.

Hemodialysis-Associated Immune Dysregulation in SARS-CoV-2-Infected End-Stage Renal Disease Patients.

Patients on hemodialysis show dysregulated immunity, basal hyperinflammation and a marked vulnerability to COVID-19. We evaluated the immune profile in COVID-19 hemodialysis patients and the changes associated with clinical deterioration after the hemodialysis session. Recruited patients included eight hemodialysis subjects with active, PCR-confirmed SARS-CoV-2 infection, five uninfected hemodialysis patients and five healthy controls. In SARS-CoV-2-infected hemodialysis patients TNF-α, IL-6 and IL-8 were particularly increased. Lymphopenia was mostly due to reduction in CD4+ T, B and central memory CD8+ T cells. There was a predominance of classical and intermediate monocytes with reduced HLA-DR expression and enhanced production of pro-inflammatory molecules. Immune parameters were analysed pre- and post-hemodialysis in three patients with COVID-19 symptoms worsening after the hemodialysis session. There was a higher than 2.5-fold increase in GM-CSF, IFN-γ, IL-1ß, IL-2, IL-6, IL-17A and IL-21 in serum, and augmentation of monocytes-derived TNF-α, IL-1ß and IL-8 and CXCL10 (p < 0.05). In conclusion, COVID-19 in hemodialysis patients associates with alteration of lymphocyte subsets, increasing of pro-inflammatory cytokines and monocyte activation. The observed worsening during the hemodialysis session in some patients was accompanied by augmentation of particular inflammatory cytokines, which might suggest biomarkers and therapeutic targets to prevent or mitigate the hemodialysis-related deterioration during SARS-CoV-2 infection.

Identification of the novel HLA-DQA1*01:04:07 allele with a synonymous substitution and an intronic insertion.

A synonymous substitution in exon 2 and intronic insertion results in the novel HLA-DQA1*01:04:07 allele.

Identification of two novel HLA-DQB1*03:01:01 intronic variants: HLA-DQB1*03:01:01:47 and -DQB1*03:01:01:48.

Two different single nucleotide substitutions in intron 1 give rise to the alleles HLA-DQB1*03:01:01:47 and DQB1*03:01:01:48.

Identification of the novel HLA-DQA1*02:01:09:01 allele by two different next-generation sequencing platforms.

A synonymous nucleotide substitution in exon 3 results in the novel HLA-DQA1*02:01:09:01 allele.

The novel HLA-DQB1*03:493 allele, the first with glutamic acid at position-10 in the leader peptide.

A nonsynonymous nucleotide substitution in exon 1 results in the novel HLA-DQB1*03:493 allele.

Effective Natural Killer Cell Degranulation Is an Essential Key in COVID-19 Evolution.

NK degranulation plays an important role in the cytotoxic activity of innate immunity in the clearance of intracellular infections and is an important factor in the outcome of the disease. This work has studied NK degranulation and innate immunological profiles and functionalities in COVID-19 patients and its association with the severity of the disease. A prospective observational study with 99 COVID-19 patients was conducted. Patients were grouped according to hospital requirements and severity. Innate immune cell subpopulations and functionalities were analyzed. The profile and functionality of innate immune cells differ between healthy controls and severe patients; CD56dim NK cells increased and MAIT cells and NK degranulation rates decreased in the COVID-19 subjects. Higher degranulation rates were observed in the non-severe patients and in the healthy controls compared to the severe patients. Benign forms of the disease had a higher granzymeA/granzymeB ratio than complex forms. In a multivariate analysis, the degranulation capacity resulted in a protective factor against severe forms of the disease (OR: 0.86), whereas the permanent expression of NKG2D in NKT cells was an independent risk factor (OR: 3.81; AUC: 0.84). In conclusion, a prompt and efficient degranulation functionality in the early stages of infection could be used as a tool to identify patients who will have a better evolution.

An Early Th1 Response Is a Key Factor for a Favorable COVID-19 Evolution.

The Th1/Th2 balance plays a crucial role in the progression of different pathologies and is a determining factor in the evolution of infectious diseases. This work has aimed to evaluate the early, or on diagnosis, T-cell compartment response, T-helper subsets and anti-SARS-CoV-2 antibody specificity in COVID-19 patients and to classify them according to evolution based on infection severity. A unicenter, randomized group of 146 COVID-19 patients was divided into four groups in accordance with the most critical events during the course of disease. The immunophenotype and T-helper subsets were analyzed by flow cytometry. Asymptomatic SARS-CoV-2 infected individuals showed a potent and robust Th1 immunity, with a lower Th17 and less activated T-cells at the time of sample acquisition compared not only with symptomatic patients, but also with healthy controls. Conversely, severe COVID-19 patients presented with Th17-skewed immunity, fewer Th1 responses and more activated T-cells. The multivariate analysis of the immunological and inflammatory parameters, together with the comorbidities, showed that the Th1 response was an independent protective factor for the prevention of hospitalization (OR 0.17, 95% CI 0.03-0.81), with an AUC of 0.844. Likewise, the Th1 response was found to be an independent protective factor for severe forms of the disease (OR 0.09, 95% CI: 0.01-0.63, p = 0.015, AUC: 0.873). In conclusion, a predominant Th1 immune response in the acute phase of the SARS-CoV-2 infection could be used as a tool to identify patients who might have a good disease evolution.

Immunogenicity of Anti-SARS-CoV-2 Vaccines in Common Variable Immunodeficiency.

Common variable immunodeficiency (CVID) is characterized by hypogammaglobulinemia and/or a defective antibody response to T-dependent and T-independent antigens. CVID response to immunization depends on the antigen type, the vaccine mechanism, and the specific patient immune defect. In CVID patients, humoral and cellular responses to the currently used COVID-19 vaccines remain unexplored. Eighteen CVID subjects receiving 2-dose anti-SARS-CoV-2 vaccines were prospectively studied. S1-antibodies and S1-specific IFN-γ T cell response were determined by ELISA and FluoroSpot, respectively. The immune response was measured before the administration and after each dose of the vaccine, and it was compared to the response of 50 healthy controls (HC). The development of humoral and cellular responses was slower in CVID patients compared with HC. After completing vaccination, 83% of CVID patients had S1-specific antibodies and 83% had S1-specific T cells compared with 100% and 98% of HC (p = 0.014 and p = 0.062, respectively), but neutralizing antibodies were detected only in 50% of the patients. The strength of both humoral and cellular responses was significantly lower in CVID compared with HC, after the first and second doses of the vaccine. Absent or discordant humoral and cellular responses were associated with previous history of autoimmunity and/or lymphoproliferation. Among the three patients lacking humoral response, two had received recent therapy with anti-B cell antibodies. Further studies are needed to understand if the response to COVID-19 vaccination in CVID patients is protective enough. The 2-dose vaccine schedule and possibly a third dose might be especially necessary to achieve full immune response in these patients.

Longitudinal dynamics of SARS-CoV-2-specific cellular and humoral immunity after natural infection or BNT162b2 vaccination.

The timing of the development of specific adaptive immunity after natural SARS-CoV-2 infection, and its relevance in clinical outcome, has not been characterized in depth. Description of the long-term maintenance of both cellular and humoral responses elicited by real-world anti-SARS-CoV-2 vaccination is still scarce. Here we aimed to understand the development of optimal protective responses after SARS-CoV-2 infection and vaccination. We performed an early, longitudinal study of S1-, M- and N-specific IFN-γ and IL-2 T cell immunity and anti-S total and neutralizing antibodies in 88 mild, moderate or severe acute COVID-19 patients. Moreover, SARS-CoV-2-specific adaptive immunity was also analysed in 234 COVID-19 recovered subjects, 28 uninfected BNT162b2-vaccinees and 30 uninfected healthy controls. Upon natural infection, cellular and humoral responses were early and coordinated in mild patients, while weak and inconsistent in severe patients. The S1-specific cellular response measured at hospital arrival was an independent predictive factor against severity. In COVID-19 recovered patients, four to seven months post-infection, cellular immunity was maintained but antibodies and neutralization capacity declined. Finally, a robust Th1-driven immune response was developed in uninfected BNT162b2-vaccinees. Three months post-vaccination, the cellular response was comparable, while the humoral response was consistently stronger, to that measured in COVID-19 recovered patients. Thus, measurement of both humoral and cellular responses provides information on prognosis and protection from infection, which may add value for individual and public health recommendations.