Mooring Stone-Like Arg114 Pulls Diverse Bulged Peptides: First Insight into African Swine Fever Virus-Derived T Cell Epitopes Presented by Swine Major Histocompatibility Complex Class I.

African swine fever virus (ASFV) is the causative agent of African swine fever (ASF), which is a devastating pig disease threatening the global pork industry. However, currently, no commercial vaccines are available. During the pig immune response, major histocompatibility complex class I (MHC-I) molecules select viral peptide epitopes and present them to host cytotoxic T lymphocytes, thereby playing critical roles in eliminating viral infections. Here, we screened peptides derived from ASFV and determined the molecular basis of ASFV-derived peptides presented by the swine leukocyte antigen 1*0101 (SLA-1*0101). We found that peptide binding in SLA-1*0101 differs from the traditional mammalian binding patterns. Unlike the typical B and F pockets used by the common MHC-I molecule, SLA-1*0101 uses the D and F pockets as major peptide anchor pockets. Furthermore, the conformationally stable Arg114 residue located in the peptide-binding groove (PBG) was highly selective for the peptides. Arg114 draws negatively charged residues at positions P5 to P7 of the peptides, which led to multiple bulged conformations of different peptides binding to SLA-1*0101 and creating diversity for T cell receptor (TCR) docking. Thus, the solid Arg114 residue acts as a "mooring stone" and pulls the peptides into the PBG of SLA-1*0101. Notably, the T cell recognition and activation of p72-derived peptides were verified by SLA-1*0101 tetramer-based flow cytometry in peripheral blood mononuclear cells (PBMCs) of the donor pigs. These results refresh our understanding of MHC-I molecular anchor peptides and provide new insights into vaccine development for the prevention and control of ASF. IMPORTANCE The spread of African swine fever virus (ASFV) has caused enormous losses to the pork industry worldwide. Here, a series of ASFV-derived peptides were identified, which could bind to swine leukocyte antigen 1*0101 (SLA-1*0101), a prevalent SLA allele among Yorkshire pigs. The crystal structure of four ASFV-derived peptides and one foot-and-mouth disease virus (FMDV)-derived peptide complexed with SLA-1*0101 revealed an unusual peptide anchoring mode of SLA-1*0101 with D and F pockets as anchoring pockets. Negatively charged residues are preferred within the middle portion of SLA-1*0101-binding peptides. Notably, we determined an unexpected role of Arg114 of SLA-1*0101 as a "mooring stone" which pulls the peptide anchoring into the PBG in diverse "M"- or "n"-shaped conformation. Furthermore, T cells from donor pigs could activate through the recognition of ASFV-derived peptides. Our study sheds light on the uncommon presentation of ASFV peptides by swine MHC-I and benefits the development of ASF vaccines.

Molecular basis of Coxsackievirus A10 entry using the two-in-one attachment and uncoating receptor KRM1.

KREMEN1 (KRM1) has been identified as a functional receptor for Coxsackievirus A10 (CV-A10), a causative agent of hand-foot-and-mouth disease (HFMD), which poses a great threat to infants globally. However, the underlying mechanisms for the viral entry process are not well understood. Here we determined the atomic structures of different forms of CV-A10 viral particles and its complex with KRM1 in both neutral and acidic conditions. These structures reveal that KRM1 selectively binds to the mature viral particle above the canyon of the viral protein 1 (VP1) subunit and contacts across two adjacent asymmetry units. The key residues for receptor binding are conserved among most KRM1-dependent enteroviruses, suggesting a uniform mechanism for receptor binding. Moreover, the binding of KRM1 induces the release of pocket factor, a process accelerated under acidic conditions. Further biochemical studies confirmed that receptor binding at acidic pH enabled CV-A10 virion uncoating in vitro. Taken together, these findings provide high-resolution snapshots of CV-A10 entry and identify KRM1 as a two-in-one receptor for enterovirus infection.

Severe Hypokalemia Complicated by Acute Myopathy: Initial Manifestation of Primary Sjögren's Syndrome-Associated Renal Tubular Acidosis.

BACKGROUND Severe hypokalemia, which often causes life-threatening malignant arrhythmias, is usually first diagnosed in the Emergency Department (ED). It is important to note that hypokalemia is often closely and complexly related to renal tubular acidosis (RTA) associated with autoimmune diseases such as Sjögren's syndrome (SS), especially in females with acute myopathy or acute liver injury (ALI). Severe hypokalemia can directly cause muscle injury, which can lead to hyper-creatine kinaseemia (HCK) and ALI, while SS can also directly cause hypokalemia, HCK, and even ALI and renal tubular/interstitial injury. Therefore, by reporting a rare case of SS-associated RTA (SS-RTA), we systematically reviewed the relationship between SS-RTA and severe hypokalemia, which may be beneficial to increase attention on this topic. CASE REPORT A 35-year-old female patient who presented to the ED primarily for limb weakness symptoms was initially diagnosed with severe hypokalemia, acute myopathy, and ALI. She was eventually diagnosed with primary SS (pSS) and SS-RTA, although she did not present with the typical dry mouth, dry eyes, and other clinical manifestations of SS. CONCLUSIONS Severe hypokalemia is a serious life-threatening emergency, and although the differential diagnosis is very broad, we should be aware of RTA associated with autoimmune diseases such as SS in female patients, especially when combined with clinical manifestations such as acute myopathy and ALI that cannot be explained by other causes. Simultaneously, we hope to be able to guide emergency physicians encountering similar patients to complete the diagnostic and therapeutic process.

Application and comparison in biosynthesis and biodegradation by Fusarium solani and Aspergillus fumigatus cutinases.

In this study, two synthesized cutinase genes from Fusarium solani and Aspergillus fumigatus were expressed in Pichia pastoris X33. The characteristics of these two cutinases were investigated and compared. The results indicated that F. solani and A. fumigatus cutinases hydrolyzed p-nitrophenyl substrates with different carbon chain lengths. A. fumigatus cutinase predominately hydrolyzed p-nitrophenyl butyrate, but F. solani cutinase preferred p-nitrophenyl decanoate. The abilities of polymer synthesis and bioplastic degradation were tested and compared between F. solani and A. fumigatus cutinases. The results showed that F. solani cutinase had degradation ability on poly(ε-caprolactone) (PCL) and synthesized polymer with a molecular weight (MW) of 2300 in organic solvent. However, A. fumigatus cutinase completely degraded PCL and synthesized molecules with a MW of 25,000, suggesting that A. fumigatus cutinase has more promising applications.