Mitogenic properties of two distinct forms of toxic shock syndrome toxin-1 separated on hydroxyapatite by high-performance liquid chromatography

COVID-19 during Pregnancy and Postpartum

As the COVID-19 pandemic intensified the global health crisis, the containment of SARS-CoV-2 infection in pregnancies, and the inherent risk of vertical transmission of virus from mother-to-fetus (or neonate) poses a major concern. Most COVID-19-Pregnancy patients showed mild to moderate COVID-19 pneumonia with no pregnancy loss and no congenital transmission of the virus; however, an increase in hypoxia-induced preterm deliveries was apparent. Also, the breastmilk of several mothers with COVID-19 tested negative for the virus. Taken together, the natural barrier function during pregnancy and postpartum seems to deter the SARS-CoV-2 transmission from mother-to-child. This clinical observation warrants to explore the maternal-fetal interface and identify the innate defense factors for prevention and control of COVID-19-Pregnancy. Lactoferrin (LF) is a potent antiviral iron-binding protein present in the maternal-fetal interface. In concert with immune co-factors, maternal-LF modulates chemokine release and lymphocyte migration and amplify host defense during pregnancy. LF levels during pregnancy may resolve hypertension via down-regulation of ACE2; consequently, may limit the membrane receptor access to SARS-CoV-2 for cellular entry. Furthermore, an LF-derived peptide (LRPVAA) has been shown to block ACE receptor activity in vitro. LF may also reduce viral docking and entry into host cells and limit the early phase of COVID-19 infection. An in-depth understanding of LF and other soluble mammalian milk-derived innate antiviral factors may provide insights to reduce co-morbidities and vertical transmission of SARS-CoV-2 infection and may lead to the development of effective nutraceutical supplements.

Surface hydrophobicity and electrophoretic mobilities of staphylococcal exotoxins with special reference to toxic shock syndrome toxin-1

The surface hydrophobicities of eleven staphylococcal toxins were estimated and compared with those of standard proteins on an octyl agarose column by high-performance hydrophobic-interaction chromatography (HP-HIC). Staphylococcal enterotoxins (SE) D, C3, C2, C1 and B showed a low surface hydrophobicity whereas alpha-toxin and gamma-toxin had a moderate surface hydrophobicity. SEA, toxic shock syndrome toxin-1 (TSST-1) and staphylococcal epidermolytic toxin (SET) showed high surface hydrophobicity and delta-toxin was the most hydrophobic protein. The electrophoretic mobility of the toxins was determined by free zone electrophoresis (FZE). All toxins except SEC1 and one of the two SEA species showed negative charge at pH 8.6. Charge heterogeneity was observed in SEA, SEC1, SEC3 and TSST-1: SEA and SEC1 had two overlapping components, whereas SEC3 and TSST-1 were resolved into two distinct components. The mobilities of the two TSST-1 components were estimated at -2.12 x 10(-5) and -3.60 x 10(-5) cm2v-1s-1, respectively, at 10 degrees C, and both fractions were immunologically indistinguishable as tested by specific TSST-1 antibodies with ELISA. An asymmetric peak was obtained in hydrophobic-interaction chromatography of TSST-1 indicating heterogeneity.