A scanning electron microscopy study of micro-arterial damage and repair.

The effects of microvascular clamps on the femoral vessels of rats were studied, using the SEM. The early changes observed were (1) local fusiform dilatation of the area secondary to necrosis of the muscular wall, (2) flattening of the longitudinal ridges in the endothelial (3) loss of laminar flow, (4) endothelial sloughing, (5) platelet aggregation, and (6) leukocyte adherence and diapedesis. The repair of the endothelium occurred by an early replication of the adjacent undamaged endothelial cells -- with their subsequent migration across a platelet bed. The coverage was complete in one week, although reorientation of the neo-endothelial cells took longer. On the basis of this study and our clinical experience, we think the ideal microvascular clamp would possess the following characteristics: small size, light weight, mechanical simplicity, flat jaws (one to two mm in diameter) coated with a non-slip surface, and calibrated to produce a pressure less than 30 gm per mm2. In addition the clamp should be unaffected by blood, autoclaving, or repeated use. No such clamp is commercially available now, but we hope that one will be available in the near future.     

Structure of the fluorescent nucleoside of yeast phenylalanine transfer ribonucleic acid

The structure of enzymatically isolated Y nucleoside of yeast phenylalanine tRNA was established by comparing its absorption, fluorescence, and mass spectra to that of the free base. The site of ribosylation was tentatively deduced by comparing the behavior under acid conditions of the natural nucleoside to that of synthetic Y nucleoside analogs. Our results indicate that the aglycone of the enzymatically isolated nucleoside has the same structure as the free base excised by acid treatment of phenylalanine tRNA, and that the ribose is probably attached to the N-3 position of the tricyclic nucleus.     

Effects of lysolecithin on the surface properties of human erythrocytes

Human red blood cells (RBCs), transformed by incubation with the amphiphatic compound lysolecithin from their normal discocyte shape into echinocytes, have increased rates of agglutination in the presence of either poly- -lysine (PLL) or soybean agglutinin (SBA). Removal of lysolecithin by washing caused a reversal of shape back to the discocyte configuration and a lowering of agglutination rates. Methochlorpromazine, another amphiphatic echinocytogenic substance produced a similar increase in agglutination rates, suggesting that increased agglutinability may be a general property of echinocytes. Lysolecithin treatment of RBCs caused a decrease in the binding of cationized ferritin (CF) particles/μm² of RBC surface. The decrease in CF binding is due to a rearrangement of negative charge bearing molecules on the RBC surface rather than shedding of charged groups. These observations support the hypothesis that integral membrane proteins which bear negative charges and receptors are associated with a cytoskeleton within the red cell. Alterations in cell shape which result in distortion of the cytoskeleton may cause a redistribution of integral membrane proteins which bear charged groups at the RBC surface.     

Ca2+-dependent mechanism of membrane insertion and destabilization by the SARS-CoV-2 fusion peptide

Cell penetration after recognition of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) virus by the ACE2 receptor and the fusion of its viral envelope membrane with cellular membranes are the early steps of infectivity. A region of the Spike protein of the virus, identified as the “fusion peptide” (FP), is liberated at its N-terminal site by a specific cleavage occurring in concert with the interaction of the receptor-binding domain of the Spike. Studies have shown that penetration is enhanced by the required binding of Ca²⁺ ions to the FPs of coronaviruses, but the mechanisms of membrane insertion and destabilization remain unclear. We have predicted the preferred positions of Ca²⁺ binding to the SARS-CoV-2-FP, the role of Ca²⁺ ions in mediating peptide-membrane interactions, the preferred mode of insertion of the Ca²⁺-bound SARS-CoV-2-FP, and consequent effects on the lipid bilayer from extensive atomistic molecular dynamics simulations and trajectory analyses. In a systematic sampling of the interactions of the Ca²⁺-bound peptide models with lipid membranes, SARS-CoV-2-FP penetrated the bilayer and disrupted its organization only in two modes involving different structural domains. In one, the hydrophobic residues F833/I834 from the middle region of the peptide are inserted. In the other, more prevalent mode, the penetration involves residues L822/F823 from the LLF motif, which is conserved in CoV-2-like viruses, and is achieved by the binding of Ca²⁺ ions to the D830/D839 and E819/D820 residue pairs. FP penetration is shown to modify the molecular organization in specific areas of the bilayer, and the extent of membrane binding of the SARS-CoV-2 FP is significantly reduced in the absence of Ca²⁺ ions. These findings provide novel mechanistic insights regarding the role of Ca²⁺ in mediating SARS-CoV-2 fusion and provide a detailed structural platform to aid the ongoing efforts in rational design of compounds to inhibit SARS-CoV-2 cell entry.     

ENaC and ROMK channels in the connecting tubule regulate renal K+ secretion

We measured the activities of epithelial Na channels (ENaC) and ROMK channels in the distal nephron of the mouse kidney and assessed their role in the process of K⁺ secretion under different physiological conditions. Under basal dietary conditions (0.5% K), ENaC activity, measured as amiloride-sensitive currents, was high in cells at the distal end of the distal convoluted tubule (DCT) and proximal end of the connecting tubule (CNT), a region we call the early CNT (CNTe). In more distal parts of the CNT (aldosterone-sensitive portion [CNTas]), these currents were minimal. This functional difference correlated with alterations in the intracellular location of ENaC, which was at or near the apical membrane in CNTe and more cytoplasmic in the CNTas. ROMK activity, measured as TPNQ-sensitive currents, was substantial in both segments. A mathematical model of the rat nephron suggested that K⁺ secretion by the CNTe predicted from these currents provides much of the urinary K⁺ required for K balance on this diet. In animals fed a K-deficient diet (0.1% K), both ENaC and ROMK currents in the CNTe decreased by ∼50%, predicting a 50% decline in K⁺ secretion. Enhanced reabsorption by a separate mechanism is required to avoid excessive urinary K⁺ losses. In animals fed a diet supplemented with 3% K, ENaC currents increased modestly in the CNTe but strongly in the CNTas, while ROMK currents tripled in both segments. The enhanced secretion of K⁺ by the CNTe and the recruitment of secretion by the CNTas account for the additional transport required for K balance. Therefore, adaptation to increased K⁺ intake involves the extension of robust K⁺ secretion to more distal parts of the nephron.     

Preparation and Characterization of a Fully Active Biotinylated Probe of Cholecystokinin

In this study we describe the synthesis and purification of biotinylated cholecystokinin-8 (Bio-CCK-8) and characterize its use as a probe for the pancreatic cholecystokinin receptor. CCK-8 (0.1 umoles) was reacted with either radiolabeled d-[8,9-³H]biotin succinimide ester (0.5 umoles) or N-hydroxysuccinimidyl-biotin in dimethylformamide and triethylamine, and purified by anion exchange chromatography. Concentrations of Bio-CCK-8 and CCK-8 needed for half-maximal inhibition of [l25]I-CCK-8 binding to pancreatic membranes were the same (1.0 and 1.3 nM). Bio-CCK-8 retained full biological activity as determined by stimulation of pancreatic protein secretion from rats, and the biotin group bound to CCK-8 retained its high sensitivity for avidin.